Dell EMC Networking OS Configuration Guide for the Z9100 ON System 9.13.0.
Notes, cautions, and warnings NOTE: A NOTE indicates important information that helps you make better use of your product. 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 © 2017 Dell Inc. or its subsidiaries. All rights reserved. Dell, EMC, and other trademarks are trademarks of Dell Inc. or its subsidiaries.
Contents 1 About this Guide...........................................................................................................................................35 Audience........................................................................................................................................................................... 35 Conventions.....................................................................................................................................................
Verify Software Images Before Installation...................................................................................................................58 4 Management............................................................................................................................................... 60 Configuring Privilege Levels...........................................................................................................................................
Reloading the system....................................................................................................................................................... 81 Restoring the Factory Default Settings.........................................................................................................................82 Important Points to Remember................................................................................................................................
Configuring Match Routes....................................................................................................................................... 113 Configuring Set Conditions...................................................................................................................................... 114 Configure a Route Map for Route Redistribution..................................................................................................
9 Border Gateway Protocol IPv4 (BGPv4).....................................................................................................167 Autonomous Systems (AS)........................................................................................................................................... 167 Sessions and Peers........................................................................................................................................................ 169 Establish a Session........
Changing the WEIGHT Attribute...........................................................................................................................205 Enabling Multipath...................................................................................................................................................205 Filtering BGP Routes...............................................................................................................................................
Ethernet Enhancements in Data Center Bridging......................................................................................................242 Priority-Based Flow Control................................................................................................................................... 243 Enhanced Transmission Selection..........................................................................................................................
Auto-Detection and Manual Configuration of the DCBx Version...................................................................... 268 DCBx Example......................................................................................................................................................... 269 DCBx Prerequisites and Restrictions.....................................................................................................................269 Configuring DCBx....................................
Managing ECMP Group Paths............................................................................................................................... 307 Creating an ECMP Group Bundle.......................................................................................................................... 307 Modifying the ECMP Group Threshold.................................................................................................................
Protocol Overview......................................................................................................................................................... 332 Ring Status............................................................................................................................................................... 333 Multiple FRRP Rings...............................................................................................................................................
Removing a Group-Port Association.....................................................................................................................358 Disabling Multicast Flooding...................................................................................................................................358 Specifying a Port as Connected to a Multicast Router...................................................................................... 358 Configuring the Switch as Querier...................
Configuration Tasks for Port Channel Interfaces.................................................................................................380 Creating a Port Channel......................................................................................................................................... 380 Adding a Physical Interface to a Port Channel......................................................................................................381 Reassigning an Interface to a New Port Channel..
IP Addresses....................................................................................................................................................................413 Implementation Information.................................................................................................................................... 413 Configuration Tasks for IP Addresses..........................................................................................................................
Addressing................................................................................................................................................................ 434 Implementing IPv6 with Dell EMC Networking OS................................................................................................... 435 ICMPv6...........................................................................................................................................................................
Implementation Information..........................................................................................................................................458 Configuration Information.............................................................................................................................................459 Configuration Tasks for IS-IS..................................................................................................................................
Manage the MAC Address Table................................................................................................................................. 499 Clearing the MAC Address Table........................................................................................................................... 499 Setting the Aging Time for Dynamic Entries........................................................................................................499 Configuring a Static MAC Address..........
Viewing Information Advertised by Adjacent LLDP Neighbors................................................................................525 Examples of Viewing Information Advertised by Neighbors.............................................................................. 525 Configuring LLDPDU Intervals..................................................................................................................................... 526 Configuring Transmit and Receive Mode..............................
Protocol Overview.........................................................................................................................................................560 Spanning Tree Variations............................................................................................................................................... 561 Implementation Information....................................................................................................................................
Autonomous System (AS) Areas........................................................................................................................... 603 Area Types................................................................................................................................................................ 604 Networks and Neighbors........................................................................................................................................605 Router Types.......
Protocol Overview.........................................................................................................................................................654 Requesting Multicast Traffic.................................................................................................................................. 654 Refuse Multicast Traffic..........................................................................................................................................
Private VLAN Concepts................................................................................................................................................684 Using the Private VLAN Commands...........................................................................................................................685 Configuration Task List..................................................................................................................................................
Displaying Default and Configured WRED Profiles.............................................................................................. 724 Displaying WRED Drop Statistics........................................................................................................................... 724 Displaying egress–queue Statistics........................................................................................................................724 Pre-Calculating Available QoS CAM Space..........
Enabling SNMP Traps for Root Elections and Topology Changes...........................................................................759 Influencing RSTP Root Selection.................................................................................................................................760 Configuring an EdgePort..............................................................................................................................................
Display Information About User Roles....................................................................................................................810 Two Factor Authentication (2FA)................................................................................................................................. 812 Handling Access-Challenge Message....................................................................................................................
sFlow Show Commands................................................................................................................................................ 841 Displaying Show sFlow Global.................................................................................................................................841 Displaying Show sFlow on an Interface.................................................................................................................
MIB Support to Display the Available Partitions on Flash......................................................................................... 870 Viewing the Available Partitions on Flash..............................................................................................................870 MIB Support to Display the ECN Marked Packets ....................................................................................................871 MIB Support to Display Egress Queue Statistics...........
Important Points to Remember................................................................................................................................... 898 Configuring Interfaces for Layer 2 Mode....................................................................................................................899 Enabling Spanning Tree Protocol Globally..................................................................................................................
Configuring a Tunnel......................................................................................................................................................930 Configuring Tunnel Keepalive Settings.........................................................................................................................931 Configuring a Tunnel Interface.....................................................................................................................................
VLT and Stacking.....................................................................................................................................................962 VLT and IGMP Snooping........................................................................................................................................ 962 VLT IPv6...................................................................................................................................................................
VXLAN on VLT.............................................................................................................................................................. 1016 Configuration........................................................................................................................................................... 1017 59 VLT Proxy Gateway.................................................................................................................................
VRF Configuration........................................................................................................................................................1047 Loading VRF CAM..................................................................................................................................................1047 Creating a Non-Default VRF Instance.................................................................................................................
Mini Core Dumps..........................................................................................................................................................1095 Enabling TCP Dumps...................................................................................................................................................1096 64 Standards Compliance............................................................................................................................1098 IEEE Compliance.
1 About this Guide This guide describes the protocols and features the Dell EMC Networking Operating System (OS) supports and provides configuration instructions and examples for implementing them. For complete information about all the CLI commands, see the Dell EMC Command Line Reference Guide for your system. The Z9100–ON platform is available with Dell EMC Networking OS version 9.8(1.0) and beyond. Though this guide contains information about protocols, it is not intended to be a complete reference.
2 Configuration Fundamentals The Dell EMC 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.
CLI Modes Different sets of commands are available in each mode. A command found in one mode cannot be executed from another mode (except for EXEC mode commands with a preceding do command (refer to the do Command section). You can set user access rights to commands and command modes using privilege levels. The Dell EMC 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.
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 GRUB Navigating CLI Modes The Dell EMC Networking OS prompt changes to indicate the CLI mode.
CLI Command Mode Prompt Access Command AS-PATH ACL DellEMC(config-as-path)# ip as-path access-list 10 Gigabit Ethernet Interface DellEMC(conf-if-te-1/1/1)# interface (INTERFACE modes) 25 Gigabit Ethernet Interface DellEMC(conf-if-tf-1/1/1)# interface(INTERFACE modes) 40 Gigabit Ethernet Interface DellEMC(conf-if-fo-1/1/1)# interface (INTERFACE modes) 50 Gigabit Ethernet Interface DellEMC(conf-if-fi-1/1/1)# interface(INTERFACE modes) 100 Gigabit Ethernet Interface DellEMC(conf-if-hu-1/1)#
CLI Command Mode Prompt BGP ADDRESS-FAMILY DellEMC(conf-router_bgp_af)# (for address-family {ipv4 multicast | ipv6 unicast} (ROUTER BGP IPv4) DellEMC(conf-routerZ_bgpv6_af)# Mode) (for IPv6) ROUTER ISIS DellEMC(conf-router_isis)# router isis ISIS ADDRESS-FAMILY DellEMC(conf-router_isisaf_ipv6)# address-family ipv6 unicast (ROUTER ISIS Mode) ROUTER OSPF DellEMC(conf-router_ospf)# router ospf ROUTER OSPFV3 DellEMC(conf-ipv6router_ospf)# ipv6 router ospf ROUTER RIP DellEMC(conf-router_rip)# r
CLI Command Mode Prompt Access Command VRRP DellEMC(conf-if-interface-type- vrrp-group slot/port-vrid-vrrp-group-id)# UPLINK STATE GROUP DellEMC(conf-uplink-stategroup-groupID)# uplink-state-group The following example shows how to change the command mode from CONFIGURATION mode to PROTOCOL SPANNING TREE.
interface tenGigabitEthernet 1/17/1 ip address 192.168.10.1/24 no shutdown DellEMC(conf-if-te-1/17/1)#no ip address DellEMC(conf-if-te-1/17/1)#show config ! interface TenGigabitEthernet 1/17/1 no ip address no shutdown Layer 2 protocols are disabled by default. To enable Layer 2 protocols, use the no disable command. For example, in PROTOCOL SPANNING TREE mode, enter no disable to enable Spanning Tree.
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.
Example of the grep Keyword DellEMC#show system brief | grep Management 1 Management online Z9100-ON Z9100-ON DellEMC# 9.8(1.0) 130 NOTE: Dell EMC 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. The except keyword displays text that does not match the specified text. The following example shows this command used in combination with the show system brief command.
If either of these messages appears, Dell EMC Networking recommends coordinating with the users listed in the message so that you do not unintentionally overwrite each other’s configuration changes. Configuring alias command You can configure shorter alias names for single–line command input using the alias command. To configure the alias name, perform the following steps: 1 Configure the terminal to enter the Global Configuration mode.
EXEC Privilege mode DellEMC#show alias details DellEMC# show alias details -----------------------------------------------------------------Name: showipbr10 Definition: show ip interface brief | grep tengig ignore-case ----------------------------------------------------------------------------------------------------------------------------------Name: showipbr40 Definition: show ip interface brief | grep fortygig ignore-case -----------------------------------------------------------------DellEMC# 3 Displ
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) and system then loads the Dell EMC Networking Operating System. Boot messages scroll up the terminal window during this process. No user interaction is required if the boot process proceeds without interruption. When the boot process completes, the system status LEDs remain online (green) and the console monitor displays the EXEC mode prompt.
Console Access The device has one RJ-45/RS-232 console port, an out-of-band (OOB) Ethernet port, and a micro USB-B console port. Serial Console The RS-232 console port is on the left-hand side of the system as you face the I/O side of the chassis, as shown in the following illustration. Figure 1. RJ-45 Console Port 1 RJ-45 console port. 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.
Table 2. Pin Assignments Between the Console and a DTE Terminal Server Console Port RJ-45 to RJ-45 Rollover RJ-45 to RJ-45 Rollover RJ-45 to DB-9 Adapter Cable Cable Terminal Server Device Signal RJ-45 Pinout RJ-45 Pinout DB-9 Pin Signal RTS 1 8 8 CTS NC 2 7 6 DSR TxD 3 6 2 RxD GND 4 5 5 GND GND 5 4 5 GND RxD 6 3 3 TxD NC 7 2 4 DTR CTS 8 1 7 RTS Micro USB-B Access The Micro USB type B console port is on the I/O side.
Default Configuration Although a version of Dell EMC Networking OS is pre-loaded onto the system, the system is not configured when you power up the system first time (except for the default hostname, which is DellEMC). You must configure the system using the CLI. Configuring a Host Name The host name appears in the prompt. The default host name is DellEMC. • Host names must start with a letter and end with a letter or digit. • Characters within the string can be letters, digits, and hyphens.
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. • Configure a management route to the network from which you are accessing the system.
NOTE: dynamic-salt option is shown only with secret and password options. In dynamic-salt configuration, the length of type 5 secret and type 7 password is 32 and 16 characters more compared to the secret and password length without dynamic-salt configuration. An error message appears if the username command reaches the maximum length, which is 256 characters. The dynamic-salt support for the user configuration is added in REST API.
• To copy a remote file to Dell EMC Networking system, combine the file-origin syntax for a remote file location with the file-destination syntax for a local file location. Table 3.
Table 4. Mounting an NFS File System File Operation Syntax To mount an NFS file system: mount nfs rhost:path mountpoint username password The foreign file system remains mounted as long as the device is up and does not reboot. You can run the file system commands without having to mount or un-mount the file system each time you run a command. When you save the configuration using the write command, the mount command is saved to the startup configuration.
24 bytes successfully copied DellEMC# DellEMC#copy tftp://10.16.127.35/username/dv-maa-test ? flash: Copy to local file system ([flash://]filepath) nfsmount: Copy to nfs mount file system (nfsmount:///filepath) running-config remote host: Destination file name [test.c]: ! 225 bytes successfully copied DellEMC# Save the Running-Configuration The running-configuration contains the current system configuration. Dell EMC Networking recommends coping your running-configuration to the startup-configuration.
dir flash: View the running-configuration. • EXEC Privilege mode show running-config View the startup-configuration. • EXEC Privilege mode show startup-config 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.
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.
In the Dell EMC Networking OS release 9.8(0.0), HTTP services support the VRF-aware functionality. If you want the HTTP server to use a VRF table that is attached to an interface, configure that HTTP server to use a specific routing table. You can use the ip http vrf command to inform the HTTP server to use a specific routing table. After you configure this setting, the VRF table is used to look up the destination address.
• flash: (Optional) Specifies the flash drive. The default uses the flash drive. You can enter the image file name. • hash-value: (Optional). Specify the relevant hash published on iSupport.
4 Management This chapter describes the different protocols or services used to manage the Dell EMC Networking system.
Creating a Custom Privilege Level Custom privilege levels start with the default EXEC mode command set. You can then customize privilege levels 2-14 by: • restricting access to an EXEC mode command • moving commands from EXEC Privilege to EXEC mode • restricting access A user can access all commands at his privilege level and below.
• removes the resequence command from EXEC mode by requiring a minimum of privilege level 4 • allows access to CONFIGURATION mode with the banner command • allows access to INTERFACE tengigabitethernet and LINE modes are allowed with no commands • Remove a command from the list of available commands in EXEC mode. CONFIGURATION mode • privilege exec level level {command ||...|| command} Move a command from EXEC Privilege to EXEC mode. CONFIGURATION mode • privilege exec level level {command ||...
exit Exit from interface configuration mode DellEMC(conf-if-te-1/26/1)#exit DellEMC(conf)# DellEMC(conf)#line ? console Primary terminal line vty Virtual terminal DellEMC(conf)#line vty 0 DellEMC(config-line-vty)#exit DellEMC(conf)# Applying a Privilege Level to a Username To set the user privilege level, use the following command. • Configure a privilege level for a user.
CONFIGURATION mode no logging console Audit and Security Logs This section describes how to configure, display, and clear audit and security logs. The following is the configuration task list for audit and security logs: • Enabling Audit and Security Logs • Displaying Audit and Security Logs • Clearing Audit Logs Enabling Audit and Security Logs You enable audit and security logs to monitor configuration changes or determine if these changes affect the operation of the system in the network.
Example of Enabling Audit and Security Logs DellEMC(conf)#logging extended Displaying Audit and Security Logs To display audit logs, use the show logging auditlog command in Exec mode. To view these logs, you must first enable the logging extended command. Only the RBAC system administrator user role can view the audit logs. Only the RBAC security administrator and system administrator user role can view the security logs.
Figure 2. Setting Up a Secure Connection 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 DellEMC(conf)#ip ssh server enable 2 On the syslog server, create a reverse SSH tunnel from the syslog server to the Dell OS switch, using following syntax: ssh -R :: user@remote_host -nNf In the following example the syslog server IP address is 10.156.166.
Log Messages in the Internal Buffer All error messages, except those beginning with %BOOTUP (Message), are log in the internal buffer.
• Configure a UNIX system as a syslog server by adding the following lines to /etc/syslog.conf on the UNIX system and assigning write permissions to the file. • 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.
Display Login Statistics To view the login statistics, use the show login statistics command. Example of the show login statistics Command The show login statistics command displays the successful and failed login details of the current user in the last 30 days or the custom defined time period. DellEMC#show login statistics -----------------------------------------------------------------User: admin Last login time: 12:52:01 UTC Tue Mar 22 2016 Last login location: Line vty0 ( 10.16.127.
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. DellEMC# show login statistics user admin -----------------------------------------------------------------User: admin Last login time: 12:52:01 UTC Tue Mar 22 2016 Last login location: Line vty0 ( 10.16.127.
login concurrent-session limit number-of-sessions Example of Configuring Concurrent Session Limit The following example limits the permitted number of concurrent login sessions to 4. DellEMC(config)#login concurrent-session limit 4 Enabling the System to Clear Existing Sessions To enable the system to clear existing login sessions, follow this procedure: • Use the following command.
Enabling Secured CLI Mode The secured CLI mode prevents the users from enhancing the permissions or promoting the privilege levels. • Enter the following command to enable the secured CLI mode: CONFIGURATION Mode secure-cli enable After entering the command, save the running-configuration. Once you save the running-configuration, the secured CLI mode is enabled. If you do not want to enter the secured mode, do not save the running-configuration.
To view the logging buffer and configuration, use the show logging command in EXEC privilege mode, as shown in the example for Display the Logging Buffer and the Logging Configuration. 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.
• lpr (for line printer system messages) • mail (for mail system messages) • news (for USENET news messages) • sys9 (system use) • sys10 (system use) • sys11 (system use) • sys12 (system use) • sys13 (system use) • sys14 (system use) • syslog (for syslog messages) • user (for user programs) • uucp (UNIX to UNIX copy protocol) Example of the show running-config logging Command To view nondefault settings, use the show running-config logging command in EXEC mode.
• limit: the range is from 20 to 300. The default is 20. To view the logging synchronous configuration, use the show config command in LINE mode. Enabling Timestamp on Syslog Messages By default, syslog messages do not include a time/date stamp stating when the error or message was created. To enable timestamp, use the following command. • Add timestamp to syslog messages.
Enabling the FTP Server To enable the system as an FTP server, use the following command. To view FTP configuration, use the show running-config ftp command in EXEC privilege mode. • Enable FTP on the system. CONFIGURATION mode ftp-server enable Example of Viewing FTP Configuration DellEMC#show running ftp ! ftp-server enable ftp-server username nairobi password 0 zanzibar DellEMC# Configuring FTP Server Parameters After you enable the FTP server on the system, you can configure different parameters.
• For a 50-Gigabit Ethernet interface, enter the keyword fiftyGigE then the slot/port/subport information. • For a 100-Gigabit Ethernet interface, enter the keyword hundredGigE 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 VLAN interface, enter the keyword vlan then a number from 1 to 4094.
NOTE: If you already have configured generic IP ACL on a terminal line, then you cannot further apply IPv4 or IPv6 specific filtering on top of this configuration. Similarly, if you have configured either IPv4 or IPv6 specific filtering on a terminal line, you cannot apply generic IP ACL on top of this configuration. Before applying any of these configurations, you must first undo the existing configuration using the no access-class access-list-name [ipv4 | ipv6] command.
tacacs+ 1 Prompt for a username and password and use a TACACS+ server to authenticate. Configure an authentication method list. You may use a mnemonic name or use the keyword default. The default authentication method for terminal lines is local and the default method list is empty. CONFIGURATION mode aaa authentication login {method-list-name | default} [method-1] [method-2] [method-3] [method-4] [method-5] [method-6] 2 Apply the method list from Step 1 to a terminal line.
line console 0 exec-timeout 0 0 DellEMC(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.
You can then send any user a message using the send command from EXEC Privilege mode. Alternatively, you can clear any line using the clear command from EXEC Privilege mode. If you clear a console session, the user is returned to EXEC mode. Example of Locking CONFIGURATION Mode for Single-User Access DellEMC(conf)#configuration mode exclusive auto BATMAN(conf)#exit 3d23h35m: %RPM0-P:CP %SYS-5-CONFIG_I: Configured from console by console DellEMC#config ! Locks configuration mode exclusively.
The following example shows how to reload the system into Dell diagnostics mode: DellEMC#reload dell-diag Proceed with reload [confirm yes/no]: yes The following example shows how to reload the system into ONIE mode: DellEMC#reload onie Proceed with reload [confirm yes/no]: yes The following example shows how to reload the system into ONIE prompt and enter the install mode directly: DellEMC#reload onie install Proceed with reload [confirm yes/no]: yes Restoring the Factory Default Settings Restoring the fa
When you use the flash boot procedure to boot the device, the boot loader checks if the primary or the secondary partition contains a valid image. If the primary partition contains a valid image, then the primary boot line is set to A: and the secondary and default boot lines are set to a Null String. If the secondary partition contains a valid image, then the primary boot line is set to B: and the secondary and default boot lines are set to a Null String.
5 802.1X 802.1X is a port-based Network Access Control (PNAC) that provides an authentication mechanism to devices wishing to attach to a LAN or WLAN. 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 is verified (through a username and password, for example). 802.
Figure 4. 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.
• Configuring Timeouts • Configuring Dynamic VLAN Assignment with Port Authentication • Guest and Authentication-Fail VLANs Port-Authentication Process The authentication process begins when the authenticator senses that a link status has changed from down to up: 1 When the authenticator senses a link state change, it requests that the supplicant identify itself using an EAP Identity Request frame. 2 The supplicant responds with its identity in an EAP Response Identity frame.
Figure 6. EAP Over RADIUS RADIUS Attributes for 802.1X Support Dell EMC Networking systems include the following RADIUS attributes in all 802.1X-triggered Access-Request messages: Attribute 31 Calling-station-id: relays the supplicant MAC address to the authentication server. Attribute 41 NAS-Port-Type: NAS-port physical port type. 15 indicates Ethernet. Attribute 61 NAS-Port: the physical port number by which the authenticator is connected to the supplicant.
Enabling 802.1X Enable 802.1X globally. Figure 7. 802.1X Enabled 1 Enable 802.1X globally. CONFIGURATION mode 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.
In the following example, the bold lines show that 802.1X is enabled. DellEMC#show running-config | find dot1x dot1x authentication ! [output omitted] ! interface TenGigabitEthernet 2/1/1 no ip address dot1x authentication no shutdown ! DellEMC# To view 802.1X configuration information for an interface, use the show dot1x interface command. In the following example, the bold lines show that 802.1X is enabled on all ports unauthorized by default. DellEMC#show dot1x interface TenGigabitEthernet 2/1/1 802.
802.1x profile information ----------------------------Dot1x Profile test Profile MACs 00:00:00:00:01:11 Configuring the Static MAB and MAB Profile Enable MAB (mac-auth-bypass) before using the dot1x static-mab command to enable static mab. To enable static MAB and configure a static MAB profile, use the following commands. • Configure static MAB and static MAB profile on dot1x interface. INTERFACE mode dot1x static-mab profile profile-name Eenter a name to configure the static MAB profile name.
• Enable critical VLAN for users or devices INTERFACE mode dot1x critical-vlan [{vlan-id}] Specify a VLAN interface identifier to be configured as a critical VLAN. The VLAN ID range is 1– 4094. Example of Configuring a Critical VLAN for an Interface DellEMC(conf-if-Te-2/1)#dot1x critical-vlan 300 DellEMC(conf-if-Te 2/1)#show config ! interface TenGigabitEthernet 2/1 switchport dot1x critical-vlan 300 no shutdown DellEMC#show dot1x interface tengigabitethernet 2/1 802.
dot1x profile sample mac 00:50:56:aa:01:10 mac 00:50:56:aa:01:11 DellEMC(conf-dot1x-profile)# DellEMC(conf-dot1x-profile)#exit DellEMC(conf)# Configuring Request Identity Re-Transmissions When the authenticator sends a Request Identity frame and the supplicant does not respond, the authenticator waits for 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 retransmits can be configured.
Example of Configuring and Verifying Port Authentication The following example shows configuration information for a port for which the authenticator re-transmits 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.
Port Control: Port Auth Status: Re-Authentication: Untagged VLAN id: Tx Period: Quiet Period: ReAuth Max: Supplicant Timeout: Server Timeout: Re-Auth Interval: Max-EAP-Req: Auth Type: Auth PAE State: Backend State: Auth PAE State: Backend State: FORCE_AUTHORIZED UNAUTHORIZED Disable None 90 seconds 120 seconds 2 30 seconds 30 seconds 3600 seconds 10 SINGLE_HOST Initialize Initialize Initialize Initialize Re-Authenticating a Port You can configure the authenticator for periodic re-authentication.
Auth Type: Auth PAE State: Backend State: Auth PAE State: Backend State: SINGLE_HOST Initialize Initialize Initialize Initialize Configuring Timeouts If the supplicant or the authentication server is unresponsive, the authenticator terminates the authentication process after 30 seconds by default. You can configure the amount of time the authenticator waits for a response.
Configuring Dynamic VLAN Assignment with Port Authentication Dell EMC Networking OS supports dynamic VLAN assignment when using 802.1X. The basis for VLAN assignment is RADIUS attribute 81, Tunnel-Private-Group-ID.
5 Verify that the port has been authorized and placed in the desired VLAN (refer to the illustration in Dynamic VLAN Assignment with Port Authentication). Guest and Authentication-Fail VLANs Typically, the authenticator (the Dell system) denies the supplicant access to the network until the supplicant is authenticated.
Configure a port to be placed in the VLAN after failing the authentication process as specified number of times using the dot1x authfail-vlan command from INTERFACE mode. Configure the maximum number of authentication attempts by the authenticator using the keyword max-attempts with this command.
6 Access Control List (ACL) VLAN Groups and Content Addressable Memory (CAM) This section 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 ACL VLAN group is deleted and it does not contain VLAN members. • The ACL is applied or removed from a group and the ACL group does not contain a VLAN member. • The description of the ACL group is added or removed. Guidelines for Configuring ACL VLAN Groups Keep the following points in mind when you configure ACL VLAN groups: • The interfaces where you apply the ACL VLAN group function as restricted interfaces.
description description 3 Apply an egress IP ACL to the ACL VLAN group. CONFIGURATION (conf-acl-vl-grp) mode ip access-group {group name} out implicit-permit 4 Add VLAN member(s) to an ACL VLAN group. CONFIGURATION (conf-acl-vl-grp) mode member vlan {VLAN-range} 5 Display all the ACL VLAN groups or display a specific ACL VLAN group, identified by name.
EXEC Privilege mode DellEMC#show cam-usage switch Stackunit|Portpipe| CAM Partition | Total CAM | Used CAM |Available CAM ========|========|=================|============|============|============= 1 | 0 | IN-L2 ACL | 1536 | 0 | 1536 | | OUT-L2 ACL | 206 | 9 | 197 Codes: * - cam usage is above 90%. Viewing CAM Usage View the amount of CAM space available, used, and remaining in each partition (including IPv4Flow and Layer 2 ACL sub- partitions) using the show cam-usage command in EXEC Privilege mode.
| | OUT-V6 ACL | Codes: * - cam usage is above 90%.
Restrictions for ACL Optimization After you enable ACL optimization, the system does not support the following features: • Mirroring dropped packets • Ability to specify filtering for routed traffic only • ACLs applied on physical ports with VRF ranges • ACLs with filter parameters such as DSCP and ECN • PIM VLT • Filtering noninitial fragments of a datagram If your ACL rules contain the following keywords, the system accepts the configuration and shows a message stating that these features are
7 Access Control Lists (ACLs) 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.
Topics: • IP Access Control Lists (ACLs) • Configure ACL Range Profiles • Important Points to Remember • IP Fragment Handling • Configure a Standard IP ACL • Configure an Extended IP ACL • Configure Layer 2 and Layer 3 ACLs • Assign an IP ACL to an Interface • Applying an IP ACL • Configure Ingress ACLs • Configure Egress ACLs • Configuring UDF ACL • IP Prefix Lists • ACL Resequencing • Route Maps IP Access Control Lists (ACLs) In Dell EMC Networking switch/routers, you can cre
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. The total space allocated must equal 9 FP blocks. (There are 12 FP blocks, but System Flow requires three blocks that cannot be reallocated.) Enter the ipv6acl allocation as a factor of 3 (3, 6, 9).
Allocating ACL VLAN CAM CAM optimization for ACL VLAN groups is not enabled by default. You must allocate blocks of ACL VLAN CAM to enable ACL CAM optimization by using the cam-acl-vlan command. By default, 0 blocks of CAM are allocated for VLAN services in the VLAN Content Aware Processor (VCAP), an application that modifies VLAN settings before forwarding packets on member interfaces.
ACL Optimization If an access list contains duplicate entries, Dell EMC Networking OS deletes one entry to conserve CAM space. Standard and extended ACLs take up the same amount of CAM space. A single ACL rule uses two CAM entries to identify whether the access list is a standard or extended ACL.
NOTE: If you enable this feature, router traffic is not filtered by the ACL. 2 Create a range profile after entering the ACL Profile Configuration mode.
• • • • Create a route map (mandatory) Configure route map filters (optional) Configure a route map for route redistribution (optional) Configure a route map for route tagging (optional) Creating a Route Map Route maps, ACLs, and prefix lists are similar in composition because all three contain filters, but route map filters do not contain the permit and deny actions found in ACLs and prefix lists. Route map filters match certain routes and set or specific values.
tag 35 level stub-area DellEMC# 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.
DellEMC(conf)#route-map force deny 30 DellEMC(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 as-path as-path-name Match routes with COMMUNITY list attributes in their path. CONFIG-ROUTE-MAP mode • match community community-list-name [exact] Match routes whose next hop is a specific interface.
• Match routes with a specific value. CONFIG-ROUTE-MAP mode • match metric metric-value Match BGP routes based on the ORIGIN attribute. CONFIG-ROUTE-MAP mode • match origin {egp | igp | incomplete} Match routes specified as internal or external to OSPF, ISIS level-1, ISIS level-2, or locally generated. CONFIG-ROUTE-MAP mode • match route-type {external [type-1 | type-2] | internal | level-1 | level-2 | local } Match routes with a specific tag.
• 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. CONFIG-ROUTE-MAP mode • set tag tag-value Specify a value as the route’s weight. CONFIG-ROUTE-MAP mode set weight value To create route map instances, use these commands. There is no limit to the number of set commands per route map, but the convention is to keep the number of set filters in a route map low.
Example of the redistribute Command Using a Route Tag ! router rip redistribute ospf 34 metric 1 route-map torip ! route-map torip permit 10 match route-type internal set tag 34 ! Continue Clause Normally, when a match is found, set clauses are executed, and the packet is then forwarded; no more route-map modules are processed. If you configure the continue command at the end of a module, the next module (or a specified module) is processed even after a match is found.
DellEMC(conf-ext-nacl)#deny ip any 10.1.1.1/32 fragments DellEMC(conf-ext-nacl) Example of Denying Second and Subsequent Fragments To deny the second/subsequent fragments, use the same rules in a different order. These ACLs deny all second and subsequent fragments with destination IP 10.1.1.1 but permit the first fragment and non-fragmented packets with destination IP 10.1.1.1. DellEMC(conf)#ip access-list extended ABC DellEMC(conf-ext-nacl)#deny ip any 10.1.1.
When an ACL filters packets, it looks at the fragment offset (FO) to determine whether it is a fragment. • FO = 0 means it is either the first fragment or the packet is a non-fragment. • FO > 0 means it is dealing with the fragments of the original packet. Configure a Standard IP ACL To configure an ACL, use commands in IP ACCESS LIST mode and INTERFACE mode. For a complete list of all the commands related to IP ACLs, refer to the Dell EMC Networking OS Command Line Interface Reference Guide.
Configuring a Standard IP ACL Filter If you are creating a standard ACL with only one or two filters, you can let Dell EMC 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.
Configuring Filters with a Sequence Number To configure filters with a sequence number, use the following commands. 1 Enter IP ACCESS LIST mode by creating an extended IP ACL. CONFIGURATION mode ip access-list extended access-list-name 2 Configure a drop or forward filter.
The following example shows the configuration to filter ICMP packets using IPv4 ACL: DellEMC(config-ext-nacl)#show config ! ip access-list extended icmp seq 5 permit icmp any any echo count seq 10 permit icmp any any echo-reply count seq 15 permit icmp any any host-unreachable count seq 20 permit icmp any any host-unknown count seq 25 permit icmp any any network-unknown count seq 30 permit icmp any any net-unreachable count seq 35 permit icmp any any packet-too-big count seq 40 permit icmp any any parameter
Configure Filters, TCP Packets To create a filter for TCP packets with a specified sequence number, use the following commands. 1 Create an extended IP ACL and assign it a unique name. CONFIGURATION mode ip access-list extended access-list-name 2 Configure an extended IP ACL filter for TCP packets.
CONFIG-EXT-NACL mode {deny | permit} {source mask | any | host ip-address} [count [byte]] [order] [monitor [session-id]] [fragments] • Configure a deny or permit filter to examine TCP packets. CONFIG-EXT-NACL mode {deny | permit} tcp {source mask] | any | host ip-address}} [count [byte]] [order] [monitor [session-id]] [fragments] • Configure a deny or permit filter to examine UDP packets.
L2 ACL Behavior L3 ACL Behavior Decision on Targeted Traffic Permit Deny L3 ACL denies. Permit Permit L3 ACL permits. NOTE: If you configure an interface as a vlan-stack access port, only the L2 ACL filters the packets. The L3 ACL applied to such a port does not affect traffic. That is, existing rules for other features (such as trace-list, policy-based routing [PBR], and QoS) are applied to the permitted traffic. For information about MAC ACLs, refer to Layer 2.
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 show ip accounting access-list EXEC Privilege mode View the number of packets matching the ACL.
To create an egress ACL, use the ip access-group command in EXEC Privilege mode. The example shows viewing the configuration, applying rules to the newly created access group, and viewing the access list. NOTE: VRF based ACL configurations are not supported on the egress traffic. Example of Applying ACL Rules to Egress Traffic and Viewing ACL Configuration To specify ingress, use the out keyword. Begin applying rules to the ACL with the ip access-list extended abcd command.
3 Create a Layer 3 ACL using permit rules with the count option to describe the desired CPU traffic. CONFIG-NACL mode permit ip {source mask | any | host ip-address} {destination mask | any | host ip-address} count [monitor [session-id]] Dell EMC Networking OS Behavior: Virtual router redundancy protocol (VRRP) hellos and internet group management protocol (IGMP) packets are not affected when you enable egress ACL filtering for CPU traffic.
Ipv4Acl : Ipv6Acl : Ipv4Qos : L2Qos : L2PT : IpMacAcl : VmanQos : EcfmAcl : FcoeAcl : ipv4pbr : vrfv4Acl : Openflow : fedgovacl : nlbclusteracl: 2 0 2 1 0 0 0 2 4 0 0 0 0 0 8(UdfEnabled) 2 0 2 0 0 0 0 0 0 0 0 0 0 DellEMC# 4 Create a UDF packet format in the UDF TCAM table. CONFIGURATION mode udf-tcam name seq number DellEMC(conf)#udf-tcam ipnip seq 1 5 Configure a UDF ID to parse packet headers using the specified number of offset and required bytes.
CONFIGURATION-UDF-Qualifier-Value Profile mode udf-id 1-12 value mask DellEMC(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.
Implementation Information In Dell EMC Networking OS, prefix lists are used in processing routes for routing protocols (for example, router information protocol [RIP], open shortest path first [OSPF], and border gateway protocol [BGP]). NOTE: It is important to know which protocol your system supports prior to implementing prefix-lists. Configuration Task List for Prefix Lists To configure a prefix list, use commands in PREFIX LIST, ROUTER RIP, ROUTER OSPF, and ROUTER BGP modes.
seq 12 deny 134.23.0.0/16 seq 15 deny 120.0.0.0/8 le 16 seq 20 permit 0.0.0.0/0 le 32 DellEMC(conf-nprefixl)# NOTE: The last line in the prefix list Juba contains a “permit all” statement. By including this line in a prefix list, you specify that all routes not matching any criteria in the prefix list are forwarded. To delete a filter, use the no seq sequence-number command in PREFIX LIST mode.
Examples of the show ip prefix-list Command The following example shows the show ip prefix-list detail command. DellEMC>show ip prefix detail Prefix-list with the last deletion/insertion: filter_ospf ip prefix-list filter_in: count: 3, range entries: 3, sequences: 5 - 10 seq 5 deny 1.102.0.0/16 le 32 (hit count: 0) seq 6 deny 2.1.0.0/16 ge 23 (hit count: 0) seq 10 permit 0.0.0.0/0 le 32 (hit count: 0) ip prefix-list filter_ospf: count: 4, range entries: 1, sequences: 5 - 10 seq 5 deny 100.100.1.
network 10.0.0.0 DellEMC(conf-router_rip)#router ospf 34 Applying a Filter to a Prefix List (OSPF) To apply a filter to routes in open shortest path first (OSPF), use the following commands. • Enter OSPF mode. CONFIGURATION mode router ospf • Apply a configured prefix list to incoming routes. You can specify an interface. If you enter the name of a non-existent prefix list, all routes are forwarded.
Rules Resquencing seq 7 permit any host 1.1.1.3 seq 10 permit any host 1.1.1.4 Rules After Resequencing: seq 5 permit any host 1.1.1.1 seq 10 permit any host 1.1.1.2 seq 15 permit any host 1.1.1.3 seq 20 permit any host 1.1.1.4 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.
Remarks that do not have a corresponding rule are incremented as a rule. These two mechanisms allow remarks to retain their original position in the list. The following example shows remark 10 corresponding to rule 10 and as such, they have the same number before and after the command is entered. Remark 4 is incremented as a rule, and all rules have retained their original positions.
8 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.
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 9. BFD in IPv4 Packet Format Field Description Diagnostic Code The reason that the last session failed. State The current local session state. Refer to BFD Sessions. Flag A bit that indicates packet function.
Field Description 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. My Discriminator A random number generated by the local system to identify the session. Your Discriminator A random number generated by the remote system to identify the session. Discriminator values are necessary to identify the session to which a control packet belongs because there can be many sessions running on a single interface.
Demand mode If one system requests Demand mode, the other system stops sending periodic control packets; it only sends a response to status inquiries from the Demand mode initiator. Either system (but not both) can request Demand mode at any time. NOTE: Dell EMC Networking OS supports Asynchronous mode only. A session can have four states: Administratively Down, Down, Init, and Up. State Description Administratively Down The local system does not participate in a particular session.
Figure 10.
Session State Changes The following illustration shows how the session state on a system changes based on the status notification it receives from the remote system. For example, if a session on a system is down and it receives a Down status notification from the remote system, the session state on the local system changes to Init. Figure 11.
• Configure BFD for OSPF • Configure BFD for OSPFv3 • Configure BFD for IS-IS • Configure BFD for BGP • Configure BFD for VRRP • Configuring Protocol Liveness 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.
Example of Viewing Session Parameters R1(conf-if-te-4/24/1)#bfd interval 100 min_rx 100 multiplier 4 role passive R1(conf-if-te-4/24/1)#do show bfd neighbors detail Session Discriminator: 1 Neighbor Discriminator: 1 Local Addr: 2.2.2.1 Local MAC Addr: 00:01:e8:09:c3:e5 Remote Addr: 2.2.2.
2 Configure static routes on both routers on the system (either local or remote). 3 Configure an IP route to connect BFD on the static routes using the ip route bfd command. Related Configuration Tasks • Changing Static Route Session Parameters • Disabling BFD for Static Routes Establishing Sessions for Static Routes for Default VRF Sessions are established for all neighbors that are the next hop of a static route on the default VRF. Figure 12.
Establishing Static Route Sessions on Specific Neighbors You can selectively enable BFD sessions on specific neighbors based on a destination prefix-list. When you establish a BFD session using the ip route bfd command, all the next-hop neighbors in the static route become part of the BFD session. Starting with Dell EMC Networking OS release 9.11.0.0, you can enable BFD sessions on specific next-hop neighbors.
CONFIGURATION mode ip route bfd [prefix-list prefix-list-name] interval milliseconds min_rx milliseconds multiplier value role [active | passive] To view session parameters, use the show bfd neighbors detail command. Disabling BFD for Static Routes If you disable BFD, all static route BFD sessions are torn down. A final Admin Down packet is sent to all neighbors on the remote systems, and those neighbors change to the Down state. To disable BFD for static routes, use the following command.
Establishing Sessions with OSPF Neighbors for the Default VRF 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 13. Establishing Sessions with OSPF Neighbors To establish BFD with all OSPF neighbors or with OSPF neighbors on a single interface, use the following commands. • Enable BFD globally.
INTERFACE mode 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 2/1/1 Up 100 100 3 O 2.2.3.
B C I O O3 R M V VT - BGP CLI ISIS OSPF OSPFv3 Static Route (RTM) MPLS VRRP Vxlan Tunnel LocalAddr * 5.1.1.1 RemoteAddr 5.1.1.2 Interface Po 30 State Rx-int Tx-int Mult Up 200 200 3 Clients O * 6.1.1.1 6.1.1.2 Vl 30 Up 200 200 3 O * 7.1.1.1 7.1.1.2 Te 1/21/1 Up 200 200 3 O The following example shows the show bfd vrf neighbors command output showing the nondefault VRF.
Number of messages communicated b/w Manager and Agent: 4 Session Discriminator: 7 Neighbor Discriminator: 2 Local Addr: 6.1.1.1 Local MAC Addr: 00:a0:c9:00:00:02 Remote Addr: 6.1.1.
ROUTER-OSPF mode 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.
• Establish sessions with OSPFv3 neighbors on a single interface. INTERFACE mode ipv6 ospf bfd all-neighbors To view the established sessions, use the show bfd neighbors command. The following example shows the show bfd neighbors command output for default VRF. DellEMC#show bfd neighbors * - Active session role Ad Dn - Admin Down B - BGP C - CLI I - ISIS O - OSPF O3 - OSPFv3 R - Static Route (RTM) M - MPLS V - VRRP VT - Vxlan Tunnel LocalAddr * 1.1.1.1 RemoteAddr 1.1.1.
The following example shows the configuration to establish sessions with all OSPFv3 neighbors on a single interface in a specific VRF: interface vlan 102 ip vrf forwarding vrf vrf1 ipv6 ospf bfd all-neighbors The following example shows the show bfd vrf neighbors command output for nondefault VRF: DellEMC#show bfd vrf vrf1 neighbors * - Active session role Ad Dn - Admin Down B - BGP C - CLI I - ISIS O - OSPF O3 - OSPFv3 R - Static Route (RTM) M - MPLS V - VRRP VT - Vxlan Tunnel LocalAddr Clients * 10.1.1.
• Change parameters for OSPFv3 sessions on a single interface. INTERFACE mode ipv6 ospf bfd all-neighbors interval milliseconds min_rx milliseconds multiplier value role [active | passive] Disabling BFD for OSPFv3 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.
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 14. 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.
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 2.2.2.1 Te 2/1/1 Up 100 100 3 I Changing IS-IS Session Parameters BFD sessions are configured with default intervals and a default role. The parameters that you can configure are: Desired TX Interval, Required Min RX Interval, Detection Multiplier, and system role. These parameters are configured for all IS-IS sessions or all IS-IS sessions out of an interface.
Before configuring BFD for BGP, you must first configure BGP on the routers that you want to interconnect. For more information, refer to Border Gateway Protocol IPv4 (BGPv4). For example, the following illustration shows a sample BFD configuration on Router 1 and Router 2 that use eBGP in a transit network to interconnect AS1 and AS2. The eBGP routers exchange information with each other as well as with iBGP routers to maintain connectivity and accessibility within each autonomous system. Figure 15.
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. Prerequisites Before configuring BFD for BGP, you must first configure the following settings: • Configure BGP on the routers that you want to interconnect, as described in Border Gateway Protocol IPv4 (BGPv4).
DellEMC(conf-router_bgp)#neighbor 20::2 remote-as 2 DellEMC(conf-router_bgp)#neighbor 20::2 no shutdown DellEMC(conf-router_bgp)#address-family ipv6 unicast DellEMC(conf-router_bgpv6_af)#neighbor 20::2 activate DellEMC(conf-router_bgpv6_af)#exit DellEMC(conf-router_bgp)#bfd all-neighbors DellEMC(conf-router_bgp)#show config ! router bgp 1 neighbor 10.1.1.2 remote-as 2 neighbor 10.1.1.
NOTE: Before performing this step, create the required VRF. 9 Activate the neighbor in IPv6 address family. CONFIG-ROUTERBGPv6_ADDRESSFAMILY mode neighbor ipv6-address activate 10 Configure parameters for a BFD session established with all neighbors discovered by BGP. Or establish a BFD session with a specified BGP neighbor or peer group using the default BFD session parameters.
Displaying BFD for BGP Information You can display related information for BFD for BGP. To display information about BFD for BGP sessions on a router, use the following commands and refer to the following examples. • Verify a BFD for BGP configuration. EXEC Privilege mode show running-config bgp • Verify that a BFD for BGP session has been successfully established with a BGP neighbor. A line-by-line listing of established BFD adjacencies is displayed.
The bold lines show the BFD session parameters: TX (packet transmission), RX (packet reception), and multiplier (maximum number of missed packets). R2# show bfd neighbors detail Session Discriminator: 9 Neighbor Discriminator: 10 Local Addr: 1.1.1.3 Local MAC Addr: 00:01:e8:66:da:33 Remote Addr: 1.1.1.
2.2.2.2 3.3.3.2 1 1 273 282 273 281 0 0 0 0 (0) 0 04:32:26 00:38:12 0 0 The following example shows viewing BFD information for a specified neighbor. The bold lines show the message displayed when you enable a BFD session with different configurations: • • • Message displays when you enable a BFD session with a BGP neighbor that inherits the global BFD session settings configured with the global bfd all-neighbors command.
... Neighbor is using BGP peer-group mode BFD configuration Peer active in peer-group outbound optimization ... Configure BFD for VRRP When using BFD with VRRP, the VRRP protocol registers with the BFD manager on the route processor module (RPM). BFD sessions are established with all neighboring interfaces participating in VRRP. If a neighboring interface fails, the BFD agent on the line card notifies the BFD manager, which in turn notifies the VRRP protocol that a link state change occurred.
• Establish sessions with all VRRP neighbors. INTERFACE mode vrrp bfd all-neighbors Establishing VRRP Sessions on VRRP Neighbors The master router does not care about the state of the backup router, so it does not participate in any VRRP BFD sessions. VRRP BFD sessions on the backup router cannot change to the UP state. Configure the master router to establish an individual VRRP session the backup router. To establish a session with a particular VRRP neighbor, use the following command.
To change parameters for all VRRP sessions or for a particular VRRP session, use the following commands. • Change parameters for all VRRP sessions. INTERFACE mode vrrp bfd all-neighbors interval milliseconds min_rx milliseconds multiplier value role [active | passive] • Change parameters for a particular VRRP session.
9 Border Gateway Protocol IPv4 (BGPv4) This chapter provides a general description of BGPv4 as it is supported in the Dell EMC 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.
IBGP provides routers inside the AS with the knowledge to reach routers external to the AS. EBGP routers exchange information with other EBGP routers as well as IBGP routers to maintain connectivity and accessibility. Figure 17. 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.
Figure 18. 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.
State Description Idle BGP initializes all resources, refuses all inbound BGP connection attempts, and initiates a TCP connection to the peer. Connect In this state the router waits for the TCP connection to complete, transitioning to the OpenSent state if successful. If that transition is not successful, BGP resets the ConnectRetry timer and transitions to the Active state when the timer expires. Active The router resets the ConnectRetry timer to zero and returns to the Connect state.
Figure 19. BGP Router Rules 1 Router B receives an advertisement from Router A through eBGP. Because the route is learned through eBGP, Router B advertises it to all its iBGP peers: Routers C and D. 2 Router C receives the advertisement but does not advertise it to any peer because its only other peer is Router D, an iBGP peer, and Router D has already learned it through iBGP from Router B.
In non-deterministic mode (the bgp non-deterministic-med command is applied), paths are compared in the order in which they arrive. This method can lead to Dell EMC Networking OS choosing different best paths from a set of paths, depending on the order in which they were received from the neighbors because MED may or may not get compared between the adjacent paths.
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.
Figure 21. 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. One AS assigns the MED a value and the other AS uses that value to decide the preferred path.
Figure 22. 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.
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).
NOTE: It is possible to configure BGP peers that exchange both unicast and multicast network layer reachability information (NLRI), but you cannot connect multiprotocol BGP with BGP. Therefore, you cannot redistribute multiprotocol BGP routes into BGP. Implement BGP with Dell EMC Networking OS The following sections describe how to implement BGP on Dell EMC Networking OS.
Ignore Router-ID in Best-Path Calculation You can avoid unnecessary BGP best-path transitions between external paths under certain conditions. The bgp bestpath routerid ignore command reduces network disruption caused by routing and forwarding plane changes and allows for faster convergence. Four-Byte AS Numbers You can use the 4-Byte (32-bit) format when configuring autonomous system numbers (ASNs). The 4-Byte support is advertised as a new BGP capability (4-BYTE-AS) in the OPEN message.
ASDOT representation combines the ASPLAIN and ASDOT+ representations. AS numbers less than 65536 appear in integer format (asplain); AS numbers equal to or greater than 65536 appear in the decimal format (asdot+). For example, the AS number 65526 appears as 65526 and the AS number 65546 appears as 1.10. Dynamic AS Number Notation Application Dell EMC Networking OS applies the ASN notation type change dynamically to the running-config statements.
DellEMC(conf-router_bgp)#sho conf ! router bgp 100 neighbor 172.30.1.250 local-as 65057 DellEMC(conf-router_bgp)#do show ip bgp BGP table version is 28093, local router ID is 172.30.1.57 AS Number Migration With this feature you can transparently change the AS number of an entire BGP network and ensure that the routes are propagated throughout the network while the migration is in progress.
3 Prepend "65001 65002" to as-path. Local-AS is prepended before the route-map to give an impression that update passed through a router in AS 200 before it reached Router B. BGP4 Management Information Base (MIB) The FORCE10-BGP4-V2-MIB enhances support for BGP management information base (MIB) 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.
• Multiple BPG process instances are not supported. Thus, the f10BgpM2PeerInstance field in various tables is not used to locate a peer. • Multiple instances of the same NLRI in the BGP RIB are not supported and are set to zero in the SNMP query response. • The f10BgpM2NlriIndex and f10BgpM2AdjRibsOutIndex fields are not used. • Carrying MPLS labels in BGP is not supported. The f10BgpM2NlriOpaqueType and f10BgpM2NlriOpaquePointer fields are set to zero. • 4-byte ASN is supported.
Item Default reuse = 750 suppress = 2000 max-suppress-time = 60 minutes external distance = 20 Distance internal distance = 200 local distance = 200 keepalive = 60 seconds Timers holdtime = 180 seconds Add-path Disabled Enabling BGP By default, BGP is not enabled on the system. Dell EMC Networking OS supports one autonomous system (AS) and assigns the AS number (ASN). To establish BGP sessions and route traffic, configure at least one BGP neighbor or peer.
NOTE: Use it only if you support 4-Byte AS numbers or if you support AS4 number representation. If you are supporting 4-Byte ASNs, enable this command. Disable 4-Byte support and return to the default 2-Byte format by using the no bgp four-octet-as-support command. You cannot disable 4-Byte support if you currently have a 4-Byte ASN configured. b Disabling 4-Byte AS numbers also disables ASDOT and ASDOT+ number representation. All AS numbers are displayed in ASPLAIN format.
The following example shows the show ip bgp summary command output (4–byte AS number displays). R2#show ip bgp summary BGP router identifier 192.168.10.2, local AS number 48735.
BGP state IDLE, in this state for 17:12:40 Last read 17:12:40, hold time is 180, keepalive interval is 60 seconds Received 0 messages, 0 notifications, 0 in queue Sent 0 messages, 0 notifications, 0 in queue Received 0 updates, Sent 0 updates Minimum time between advertisement runs is 5 seconds For address family: IPv4 Unicast BGP table version 0, neighbor version 0 0 accepted prefixes consume 0 bytes Prefix advertised 0, rejected 0, withdrawn 0 Connections established 0; dropped 0 Last reset never No activ
To configure AS4 number representations, use the following commands. • Enable ASPLAIN AS Number representation. CONFIG-ROUTER-BGP mode bgp asnotation asplain • NOTE: ASPLAIN is the default method Dell EMC 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.
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.
When you add a peer to a peer group, it inherits all the peer group’s configured parameters.
BGP version 4 Minimum time between advertisement runs is 5 seconds For address family: IPv4 Unicast BGP neighbor is zanzibar, peer-group internal, Number of peers in this group 26 Peer-group members (* - outbound optimized): 10.68.160.1 10.68.161.1 10.68.162.1 10.68.163.1 10.68.164.1 10.68.165.1 10.68.166.1 10.68.167.1 10.68.168.1 10.68.169.1 10.68.170.1 10.68.171.1 10.68.172.1 10.68.173.1 10.68.174.1 10.68.175.1 10.68.176.1 10.68.177.1 10.68.178.1 10.68.179.1 10.68.180.1 10.68.181.1 10.68.182.1 10.68.183.
BGP neighbor is 100.100.100.100, remote AS 65517, internal link Member of peer-group test for session parameters BGP version 4, remote router ID 30.30.30.
neighbor 100.100.100.100 no shutdown DellEMC# Configuring Passive Peering When you enable a peer-group, the software sends an OPEN message to initiate a TCP connection. If you enable passive peering for the peer group, the software does not send an OPEN message, but it responds to an OPEN message.
• No Prepend: specifies that local AS values are not prepended to announcements from the neighbor. Format: IP Address: A.B.C.D. You must Configure Peer Groups before assigning it to an AS. This feature is not supported on passive peer groups. Example of the Verifying that Local AS Numbering is Disabled The first line in bold shows the actual AS number. The second two lines in bold show the local AS number (6500) maintained during migration.
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 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.
• The default is 120 seconds. 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.
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. CONFIGURATION mode ip as-path access-list as-path-name 2 Enter the parameter to match BGP AS-PATH for filtering. CONFIG-AS-PATH mode {deny | permit} filter parameter This is the filter that is used to match the AS-path. The entries can be any format, letters, numbers, or regular expressions.
Regular Expressions as Filters Regular expressions are used to filter AS paths or community lists. A regular expression is a special character used to define a pattern that is then compared with an input string. For an AS-path access list, as shown in the previous commands, if the AS path matches the regular expression in the access list, the route matches the access list. The following lists the regular expressions accepted in Dell EMC Networking OS.
DellEMC(config-as-path)#deny 32$ DellEMC(config-as-path)#ex DellEMC(conf)#router bgp 99 DellEMC(conf-router_bgp)#neighbor AAA filter-list Eagle in DellEMC(conf-router_bgp)#show conf ! router bgp 99 neighbor AAA peer-group neighbor AAA filter-list Eaglein neighbor AAA no shutdown neighbor 10.155.15.2 remote-as 32 neighbor 10.155.15.2 filter-list 1 in neighbor 10.155.15.
Enabling Additional Paths The add-path feature is disabled by default. NOTE: Dell EMC Networking OS recommends not using multipath and add path simultaneously in a route reflector. To allow multiple paths sent to peers, use the following commands. 1 Allow the advertisement of multiple paths for the same address prefix without the new paths replacing any previous ones. CONFIG-ROUTER-BGP mode bgp add-path [both|received|send] path-count count The range is from 2 to 64.
• • • • • local-AS: routes with the COMMUNITY attribute of NO_EXPORT_SUBCONFED. no-advertise: routes with the COMMUNITY attribute of NO_ADVERTISE. no-export: routes with the COMMUNITY attribute of NO_EXPORT. quote-regexp: then any number of regular expressions. The software applies all regular expressions in the list. regexp: then a regular expression.
deny 701:20 deny 702:20 deny 703:20 deny 704:20 deny 705:20 deny 14551:20 deny 701:112 deny 702:112 deny 703:112 deny 704:112 deny 705:112 deny 14551:112 deny 701:667 deny 702:667 deny 703:667 deny 704:666 deny 705:666 deny 14551:666 DellEMC# 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.
Manipulating the COMMUNITY Attribute In addition to permitting or denying routes based on the values of the COMMUNITY attributes, you can manipulate the COMMUNITY attribute value and send the COMMUNITY attribute with the route information. By default, Dell EMC Networking OS does not send the COMMUNITY attribute. To send the COMMUNITY attribute to BGP neighbors, use the following command. • Enable the software to send the router’s COMMUNITY attribute to the BGP neighbor or peer group specified.
Example of the show ip bgp community Command To view the BGP configuration, use the show config command in CONFIGURATION ROUTER BGP mode. To view a route map configuration, use the show route-map command in EXEC Privilege mode. To view BGP routes matching a certain community number or a pre-defined BGP community, use the show ip bgp community command in EXEC Privilege mode. DellEMC>show ip bgp community BGP table version is 3762622, local router ID is 10.114.8.
• Change the LOCAL_PREF value. 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 runningconfig 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.
• If you do not use the all keyword, the next hop of only eBGP-learned routes is updated by the route reflector. If you use the all keyword, the next hop of both eBGP- and iBGP-learned routes are updated by the route reflector. Sets the next hop address. CONFIG-ROUTE-MAP mode set next-hop ip-address If the set next-hop command is applied on the out-bound interface using a route map, it takes precedence over the neighbor next-hop-self command.
NOTE: Dell EMC Networking OS supports up to 255 characters in a set community statement inside a route map. NOTE: You can create inbound and outbound policies. Each of the commands used for filtering has in and out parameters that you must apply. In Dell EMC Networking OS, the order of preference varies depending on whether the attributes are applied for inbound updates or outbound updates.
• 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). • After a route matches a filter, the filter’s action is applied. No additional filters are applied to the route.
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 Filter routes based on the criteria in the configured route map.
To view a route reflector configuration, use the show config command in CONFIGURATION ROUTER BGP mode or the show running-config bgp in EXEC Privilege mode. Aggregating Routes Dell EMC Networking OS provides multiple ways to aggregate routes in the BGP routing table. At least one specific route of the aggregate must be in the routing table for the configured aggregate to become active. To aggregate routes, use the following command.
To view the configuration, use the show config command in CONFIGURATION ROUTER BGP mode. Enabling Route Flap Dampening When EBGP routes become unavailable, they “flap” and the router issues both WITHDRAWN and UPDATE notices. A flap is when a route: • is withdrawn • is readvertised after being withdrawn • has an attribute change The constant router reaction to the WITHDRAWN and UPDATE notices causes instability in the BGP process.
• • reuse: the range is from 1 to 20000. This number is compared to the flapping route’s Penalty value. If the Penalty value is less than the reuse value, the flapping route is once again advertised (or no longer suppressed). The default is 750. • suppress: the range is from 1 to 20000. This number is compared to the flapping route’s Penalty value. If the Penalty value is greater than the suppress value, the flapping route is no longer advertised (that is, it is suppressed). The default is 2000.
BGP table version is 855562, main routing table version 780266 122836 network entrie(s) and 221664 paths using 29697640 bytes of memory 34298 BGP path attribute entrie(s) using 1920688 bytes of memory 29577 BGP AS-PATH entrie(s) using 1384403 bytes of memory 184 BGP community entrie(s) using 7616 bytes of memory 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.
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 routerefresh request is not negotiated with the peer.
2 In ROUTER BGP mode, enter the following command: ROUTER BGP Mode shutdown all You can use the no shutdown all command in the ROUTER BGP mode to re-enable all the BGP interface. You can also enable or disable BGP neighbors corresponding to the IPv4 unicast or multicast groups and the IPv6 unicast groups.
NOTE: This behavior applies to all BGP neighbors. Meaning, BGP neighbors that were explicitly disabled before global shutdown also remain in disabled state. Enable these neighbors individually using the no shutdown command. Route Map Continue The BGP route map continue feature, continue [sequence-number], (in ROUTE-MAP mode) allows movement from one routemap entry to a specific route-map entry (the sequence number).
• If the peer has not been activated in any AFI/SAFI, the peer remains in Idle state. Most Dell EMC Networking OS BGP IPv4 unicast commands are extended to support the IPv4 multicast RIB using extra options to the command. For a detailed description of the MBGP commands, refer to the Dell EMC Networking OS Command Line Interface Reference Guide. • Enables support for the IPv4 multicast family on the BGP node.
EXEC Privilege mode debug ip bgp {ip-address | peer-group-name} soft-reconfiguration To enhance debugging of soft reconfig, use the bgp soft-reconfig-backup command only when route-refresh is not negotiated to avoid the peer from resending messages. In-BGP is shown using the show ip protocols command. Dell EMC Networking OS displays debug messages on the console. To view which debugging commands are enabled, use the show debugging command in EXEC Privilege mode.
Last notification (len 21) sent 00:26:02 ago ffffffff ffffffff ffffffff ffffffff 00160303 03010000 Last notification (len 21) received 00:26:20 ago ffffffff ffffffff ffffffff ffffffff 00150306 00000000 Last PDU (len 41) received 00:26:02 ago that caused notification to be issued ffffffff ffffffff ffffffff ffffffff 00290200 00000e01 02040201 00024003 04141414 0218c0a8 01000000 Local host: 1.1.1.1, Local port: 179 Foreign host: 1.1.1.
The following example shows how to view space requirements for storing all the PDUs. With full internet feed (205K) captured, approximately 11.8MB is required to store all of the PDUs. DellEMC(conf-router_bgp)#do show capture bgp-pdu neighbor 172.30.1.250 Incoming packet capture enabled for BGP neighbor 172.30.1.250 Available buffer size 29165743, 192991 packet(s) captured using 11794257 bytes [. . .] DellEMC(conf-router_bgp)#do sho ip bg s BGP router identifier 172.30.1.
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 192.168.128.1/24 no shutdown R1(conf-if-lo-0)#int te 1/21/1 R1(conf-if-te-1/21/1)#ip address 10.0.1.21/24 R1(conf-if-te-1/21/1)#no shutdown R1(conf-if-te-1/21/1)#show config ! interface TengigabitEthernet 1/21/1 ip address 10.0.1.
R1(conf-router_bgp)#neighbor 192.168.128.3 no shut R1(conf-router_bgp)#neighbor 192.168.128.3 update-source loop 0 R1(conf-router_bgp)#show config ! router bgp 99 network 192.168.128.0/24 neighbor 192.168.128.2 remote-as 99 neighbor 192.168.128.2 update-source Loopback 0 neighbor 192.168.128.2 no shutdown neighbor 192.168.128.3 remote-as 100 neighbor 192.168.128.
! interface TengigabitEthernet 3/11/1 ip address 10.0.3.33/24 no shutdown R3(conf-if-lo-0)#int te 3/21/1 R3(conf-if-te-3/21/1)#ip address 10.0.2.3/24 R3(conf-if-te-3/21/1)#no shutdown R3(conf-if-te-3/21/1)#show config ! interface TengigabitEthernet 3/21/1 ip address 10.0.2.3/24 no shutdown R3(conf-if-te-3/21/1)# R3(conf-if-te-3/21/1)#router bgp 100 R3(conf-router_bgp)#show config ! router bgp 100 R3(conf-router_bgp)#network 192.168.128.0/24 R3(conf-router_bgp)#neighbor 192.168.128.
MULTIPROTO_EXT(1) ROUTE_REFRESH(2) CISCO_ROUTE_REFRESH(128) Update source set to Loopback 0 Peer active in peer-group outbound optimization For address family: IPv4 Unicast BGP table version 1, neighbor version 1 Prefixes accepted 1 (consume 4 bytes), withdrawn 0 by peer Prefixes advertised 1, denied 0, withdrawn 0 from peer Connections established 2; dropped 1 Last reset 00:00:57, due to user reset Notification History 'Connection Reset' Sent : 1 Recv: 0 Last notification (len 21) sent 00:00:57 ago fffffff
2 neighbor(s) using 9216 bytes of memory Neighbor AS MsgRcvd MsgSent TblVer InQ OutQ Up/Down State/Pfx 192.168.128.1 99 140 136 2 0 (0) 00:11:24 1 192.168.128.3 100 138 140 2 0 (0) 00:18:31 1 Example of Enabling Peer Groups (Router 3) R3#conf R3(conf)#router bgp 100 R3(conf-router_bgp)# neighbor AAA peer-group R3(conf-router_bgp)# neighbor AAA no shutdown R3(conf-router_bgp)# neighbor CCC peer-group R3(conf-router_bgp)# neighbor CCC no shutdown R3(conf-router_bgp)# neighbor 192.168.128.
Last read 00:00:45, last write 00:00:44 Hold time is 180, keepalive interval is 60 seconds Received 138 messages, 0 in queue 7 opens, 2 notifications, 7 updates 122 keepalives, 0 route refresh requests Sent 140 messages, 0 in queue Border Gateway Protocol IPv4 (BGPv4) 225
10 Content Addressable Memory (CAM) CAM is a type of memory that stores information in the form of a lookup table. On Dell EMC 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.
The following additional CAM allocation settings are supported. Table 11. Additional Default CAM Allocation Settings Additional CAM Allocation Setting FCoE ACL (fcoeacl) 0 You must enter l2acl, ipv4acl, l2qos, l2pt, ipv4qos, ipv4pbr, vrfv4acl, and fcoe allocations as a factor of 2, ipv6acl, openflow, and vman_qos allocations as a factor of 3. Ipv4 acl region should also be in multiples of 3 when ipv4udf option is enabled. All other profile allocations can use either even or odd numbered ranges.
4 Reload the system. EXEC Privilege mode reload Test CAM Usage To determine whether sufficient CAM space is available to enable a service-policy, use the test-cam-usage command. To verify the actual CAM space required, create a Class Map with all required ACL rules, then execute the test cam-usage command in Privilege mode. The Status column in the command output indicates whether or not you can enable the policy.
Example of Viewing CAM-ACL Settings NOTE: If you change the cam-acl setting from CONFIGURATION mode, the output of this command does not reflect any changes until you save the running-configuration and reload the chassis.
Codes: * - cam usage is above 90%. DellEMC# Configuring CAM Threshold and Silence Period This section describes how to configure CAM threshold and silence period between CAM threshold syslog warnings. The CAM threshold and silence period configuration is applicable only for Ingress L2, IPv4, IPv6 and Egress L2, IPv4, and IPv6 ACL CAM groups. For other ACL CAM regions, the CAM threshold and silence period is fixed and the values are 90 percent and 0 respectively.
Table 12. Possible Scenarios of Syslog Warning Old CAM Threshold New CAM Threshold Current CAM Usage Syslog 90 80 85 DellEMC(conf)#Nov 5 19:55:12 %S6000:0 %ACL_AGENT-4ACL_AGENT_CAM_USAGE_OVER_THE_THRESHOLD: The Ipv4Acl cam region on stack-unit 0 Portpipe 0 Pipeline 0 is more than 80% Full. 90 95 91 DellEMC(conf)#Nov 5 19:55:12 %S6000:0 %ACL_AGENT-4ACL_AGENT_CAM_USAGE_BELOW_THE_THRESHOLD: The cam-usage of Ipv4Acl cam region on stack-unit 0 Portpipe 0 Pipeline 0 is below 95%.
Syslog Error When the Table is Full In the Dell EMC Networking OS, the table full condition is displayed as CAM full only for LPM. But now the LPM is split into two tables. There are two syslog errors that are displayed: 1 /65 to /128 Table full. 2 0/0 – 0/64 Table full. A table-full error message is displayed once the number of entries is crossed the table size. Table-full message is generated only once when it crosses the threshold.
scaled-l3-hosts Forwarding table mode for scaling L3 host entries scaled-l3-routes Forwarding table mode for scaling L3 route entries DellEMC(conf)#hardware forwarding-table mode scaled-l3-hosts Hardware forwarding-table mode is changed. Save the configuration and reload to take effect.
11 Control Plane Policing (CoPP) 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 26. CoPP Implemented Versus CoPP Not Implemented Configure Control Plane Policing The system can process a maximum of 8500 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.
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. Configuring CoPP for Protocols This section lists the commands necessary to create and enable the service-policies for CoPP. For complete information about creating ACLs and QoS rules, refer to Access Control Lists (ACLs) and Quality of Service (QoS).
8 Assign the protocol based the service policy on the control plane. Enabling this command on a port-pipe automatically enables the ACL and QoS rules creates with the cpu-qos keyword. 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.
DellEMC(conf-policy-map-in-cpuqos)#class-map class-ipv6 qos-policy rate_limit_200k DellEMC(conf-policy-map-in-cpuqos)#exit The following example shows creating the control plane service policy. DellEMC(conf)#control-plane-cpuqos DellEMC(conf-control-cpuqos)#service-policy rate-limit-protocols egressFP_rate_policy DellEMC(conf-control-cpuqos)#exit Configuring CoPP for CPU Queues Controlling traffic on the CPU queues does not require ACL rules, but does require QoS policies.
The following example shows creating the control plane service policy. DellEMC#conf DellEMC(conf)#control-plane DellEMC(conf-control-plane)#service-policy rate-limit-cpu-queues cpuq_rate_policy Protocol to CPU Queue Mapping CoPP enables you to rate-limit control-plane packets that are destined to the CPU there by, preventing undesired or malicious traffic from entering the CPU queues. You can rate-limit CPU bound traffic both on a per protocol as well as per queue basis.
CPU-PROTOCOL-GROUP protocol-list protocol1, protocol2, protocol3,..... The list of protocols that you specify using this command are associated with the protocol group that you created in Step1. 3 Exit the CPU PROTOCOL GROUP mode. CPU-PROTOCOL-GROUP exit The command prompt enters the configuration mode. 4 Create a CoPP profile. CONFIGURATION copp-profile profile-name The system enters the CoPP profile mode. 5 Assign a protocol group or a QoS policy to the CoPP profile that you have created.
Q10 Q11 600 300 50 50 Example of Viewing Queue Mapping To view the queue mapping for each configured protocol, use the show ip protocol-queue-mapping command.
12 Data Center Bridging (DCB) Data center bridging (DCB) refers to a set of enhancements to Ethernet local area networks used in data center environments, particularly with clustering and storage area networks.
DCB refers to a set of IEEE Ethernet enhancements that provide data centers with a single, robust, converged network to support multiple traffic types, including local area network (LAN), server, and storage traffic. Through network consolidation, DCB results in reduced operational cost, simplified management, and easy scalability by avoiding the need to deploy separate application-specific networks.
Figure 27. Illustration of Traffic Congestion The system supports loading two DCB_Config files: • FCoE converged traffic with priority 3. In the Dell EMC Networking OS, PFC is implemented as follows: • PFC is supported on specified 802.1p priority traffic (dot1p 0 to 7) and is configured per interface. However, only one lossless queue is supported on an interface: one for Fibre Channel over Ethernet (FCoE) converged traffic. Configure the same lossless queues on all ports.
NOTE: Use the following command to enable etsacl: cam-acl l2acl 2 ipv4acl 2 ipv6acl 0 ipv4qos 0 l2qos 0 l2pt 0 ipmacacl 0 vman-qos 0 fcoeacl 2 etsacl 3. After executing this command, you must save the configuration and then reload the system. The following figure shows how ETS allows you to allocate bandwidth when different traffic types are classed according to 802.1p priority and mapped to priority groups. Figure 28.
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.
DCB Status: Enabled, PFC Queue Count: 2 Total Buffer: Total available buffer excluding the buffer pre-allocated for guaranteed services like global headroom, queue's min guaranteed buffer and CPU queues. PFC Total Buffer: Maximum buffer available for lossless queues. PFC Shared Buffer: Buffer used by ingress priority groups for shared usage. PFC Headroom Buffer: Buffer used by ingress priority group for shared headroom usage.
PFC Shared Buffer: Buffer used by ingress priority groups for shared usage. PFC Headroom Buffer: Buffer used by ingress priority group for shared headroom usage. PFC Available Buffer: Current buffer available for new lossless queues to be Provisioned. stack-unit Total Buffer PFC Total Buffer PFC Shared Buffer PFC Headroom Buffer PFC Available Buffer PP (KB) (KB) (KB) (KB) (KB) ---------------------------------------------------------------------------------------------------1 0.
DCB Maps and its Attributes This topic contains the following sections that describe how to configure a DCB map, apply the configured DCB map to a port, configure PFC without a DCB map, and configure lossless queues. DCB Map: Configuration Procedure A DCB map consists of PFC and ETS parameters. By default, PFC is not enabled on any 802.1p priority and ETS allocates equal bandwidth to each priority. To configure user-defined PFC and ETS settings, you must create a DCB map.
The default dot1p priority-queue assignments are applied as follows: DellEMC(conf)#do show qos dot1p-queue-mapping Dot1p Priority : 0 1 2 3 4 5 6 7 Queue : 1 0 2 3 4 5 6 7 PFC is not applied on specific dot1p priorities. ETS: Equal bandwidth is assigned to each port queue and each dot1p priority in a priority group. To configure PFC and ETS parameters on an interface, you must specify the PFC mode, the ETS bandwidth allocation for a priority group, and the 802.
NOTE: You cannot enable PFC and link-level flow control at the same time on an interface. Configuring Lossless Queues DCB also supports the manual configuration of lossless queues on an interface when PFC mode is turned off. Prerequisite: A DCB with PFC configuration is applied to the interface with the following conditions: • PFC mode is off (no pfc mode on). • No PFC priority classes are configured (no pfc priority priority-range).
3 Configure to drop the unknown unicast packets flooding on lossless priorities. CONFIGURATION mode pfc-nodrop-priority l2-dlf drop 4 View the packets drop count corresponding to the priority.
applying a DCB map with PFC enabled, you enable PFC operations on ingress port traffic. To achieve complete lossless handling of traffic, configure PFC priorities on all DCB egress ports. When you apply or remove a DCB input policy from an interface, one or two CRC errors are expected to be noticed on the ingress ports for each removal or attachment of the policy. This behavior occurs because the port is brought down when PFC is configured.
Table 18. DCB Map to an Ethernet Port Step Task Command Command Mode 1 Enter interface configuration mode on an Ethernet port. interface interface-type } CONFIGURATION 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 DellEMC# interface tengigabitEthernet 1/1 DellEMC(config-if-te-1/1/1)# dcb-map SAN_A_dcb_map1 Repeat Steps 1 and 2 to apply a DCB map to more than one port.
halting the transmission of data packets. The sending device requests the recipient to restart the transmission of data traffic when the congestion eases and reduces. The time period that is specified in the pause frame defines the duration for which the flow of data packets is halted. When the time period elapses, the transmission restarts. 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.
traffic is set per ingress port and per PG. Retaining the same ingress admission control capabilities, headroom pool can also be used to manage the headroom buffer as a shared resource. Each PG can use the shared headroom pool only up to its PG headroom limit. The shared headroom feature provides the capability to share the headroom buffer between all the ingress ports or PGs. It also provides ways to learn statistical data on shared buffer usage, thereby, reducing the overall headroom buffer allocation.
Table 21.
NOTE: The detail option display the current headroom pool usage in each of the Pipelines in the device.
Configuration Example for DSCP and PFC Priorities Consider a scenario in which the following DSCP and PFC priorities are necessary: DSCP 0 – 5, 10 - 15 Expected PFC Priority 1 20 – 25, 30 – 35 2 To configure the aforementioned DSCP and PFC priority values, perform the following tasks: 1 Create class-maps to group the DSCP subsets class-map match ip ! class-map match ip 2 match-any dscp-pfc-1 dscp 0-5,10-15 match-any dscp-pfc-2 dscp 20-25,30-35 Associate above class-maps to Queues Queue assignment a
dellNetFpStatsPerP gTable This table fetches the Allocated Min cells, Shared cells, and Headroom cells per Priority Group, the mode in which the buffer cells are allocated — Static or Dynamic and the Used Min Cells, Shared cells and Headroom cells per Priority Group. The table fetches a value of 0 if the mode of allocation is Static and a value of 1 if the mode of allocation is Dynamic. This table lists thestack-unit number, port number and priority group number.
Operations on Untagged Packets The below is example for enabling PFC for priority 2 for tagged packets. Priority (Packet Dot1p) 2 will be mapped to PG6 on PRIO2PG setting. All other Priorities for which PFC is not enabled are mapped to default PG – PG7. Classification rules on ingress (Ingress FP CAM region) matches incoming packet-dot1p and assigns an internal priority (to select queue as per Table 1 and Table 2).
priority-group group-num {bandwidth bandwidth | strict-priority} pfc off The range for priority group is from 0 to 7. Set the bandwidth in percentage. The percentage range is from 1 to 100% in units of 1%. Committed and peak bandwidth is in megabits per second. The range is from 0 to 40000. Committed and peak burst size is in kilobytes. Default is 50. The range is from 0 to 10000. 3 Configure the 802.1p priorities for the traffic on which you want to apply an ETS output policy.
• ETS TLVs are supported in DCBx versions CEE and IEEE2.5. • The DCBx port-role configurations determine the ETS operational parameters (refer to Configure a DCBx Operation). • ETS configurations received from TLVs from a peer are validated. • If there is a hardware limitation or TLV error: • • DCBx operation on an ETS port goes down. • New ETS configurations are ignored and existing ETS configurations are reset to the default ETS settings.
ETS Prerequisites and Restrictions On a switch, ETS is enabled by default on Ethernet ports with equal bandwidth assigned to each 802.1p priority. You can change the default ETS configuration only by using a DCB map. The following prerequisites and restrictions apply when you configure ETS bandwidth allocation or strict-priority queuing in a DCB map: • Because all the priorities mapped to a priority group is scheduled using a single queue, the priorities are treated with first come first served basis.
Therefore, in this example, scheduling traffic to priority group 1 (mapped to one strict-priority queue) takes precedence over scheduling traffic to priority group 3 (mapped to two strict-priority queues).
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.
or propagate internal or external configurations. Unlike other user-configured ports, the configuration of DCBx ports in Manual mode is saved in the running configuration. On a DCBx port in a manual role, all PFC, application priority, ETS recommend, and ETS configuration TLVs are enabled.
• The port is enabled with link up and DCBx enabled. • The port has performed a DCBx exchange with a DCBx peer. • The switch is capable of supporting the received DCB configuration values through either a symmetric or asymmetric parameter exchange. A newly elected configuration source propagates configuration changes received from a peer to the other auto-configuration ports.
DCBx Example The following figure shows how to use DCBx. The external 40GbE ports on the base module (ports 33 and 37) of two switches are used for uplinks configured as DCBx auto-upstream ports. The device is connected to third-party, top-of-rack (ToR) switches through uplinks. The ToR switches are part of a Fibre Channel storage network. The internal ports (ports 1-32) connected to the 10GbE backplane are configured as auto-downstream ports. Figure 30.
interface type slot/port 2 Enter LLDP Configuration mode to enable DCBx operation. INTERFACE mode [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 | ieee-v2.5} • cee: configures the port to use CEE (Intel 1.01). • ieee-v2.5: configures the port to use IEEE 802.1Qaz (Draft 2.5). The default is Auto.
NOTE: To disable TLV transmission, use the no form of the command; for example, no advertise DCBx-applntlv. To verify the DCBx configuration on a port, use the show interface DCBx detail command. Configuring DCBx Globally on the Switch To globally configure the DCBx operation on a switch, follow these steps. 1 Enter Global Configuration mode. EXEC PRIVILEGE mode configure 2 Enter LLDP Configuration mode to enable DCBx operation.
NOTE: To disable TLV transmission, use the no form of the command; for example, no advertise DCBx-applntlv. 6 Configure the FCoE priority advertised for the FCoE protocol in Application Priority TLVs. PROTOCOL LLDP mode [no] fcoe priority-bits priority-bitmap The priority-bitmap range is from 1 to FF. The default is 0x8. DCBx Error Messages The following syslog messages appear when an error in DCBx operation occurs.
Verifying the DCB Configuration To display DCB configurations, use the following show commands. Table 23. Displaying DCB Configurations Command Output show qos dot1p-queue mapping Displays the current 802.1p priority-queue mapping. Displays the data center bridging status, number of PFC-enabled ports, and number of PFC-enabled queues. show interface port-type pfc {summary | detail} Displays the PFC configuration applied to ingress traffic on an interface, including priorities and link delay.
Admin mode is on Admin is enabled Remote is enabled, Priority list is 4 Remote Willing Status is enabled Local is enabled Oper status is Recommended PFC DCBx Oper status is Up State Machine Type is Feature TLV Tx Status is enabled PFC Link Delay 45556 pause quantams Application Priority TLV Parameters : -------------------------------------FCOE TLV Tx Status is disabled Local FCOE PriorityMap is 0x8 Remote FCOE PriorityMap is 0x8 DellEMC# show interfaces tengigabitethernet 1/1/4 pfc detail Interface TenGiga
Fields Description • • Recommend: Remote PFC configuration parameters were received from peer. Internally propagated: PFC configuration parameters were received from configuration source. PFC DCBx Oper status Operational status for exchange of PFC configuration on local port: match (up) or mismatch (down).
Admin is enabled PG-grp Priority# BW-% BW-COMMITTED BW-PEAK TSA % Rate(Mbps) Burst(KB) Rate(Mbps) Burst(KB) ---------------------------------------------------------------------------------0 3 25 ETS 1 4 25 ETS 2 0,1,2,5,6,7 50 ETS 3 4 5 6 7 Remote Parameters : ------------------Remote is disabled Local Parameters : -----------------Local is enabled PG-grp Priority# BW-% BW-COMMITTED BW-PEAK TSA % Rate(Mbps) Burst(KB) Rate(Mbps) Burst(KB) -----------------------------------------------------------------
7 Remote Parameters: ------------------Remote is disabled Local Parameters : -----------------Local is enabled TC-grp Priority# 0 0,1,2,3,4,5,6,7 1 2 3 4 5 6 7 12% ETS Bandwidth 100% 0% 0% 0% 0% 0% 0% 0% TSA ETS ETS ETS ETS ETS ETS ETS ETS 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 Pkts TSA ETS ETS ETS ETS
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.
Local DCBx TLVs Transmitted: ErPFi Local DCBx Status ----------------DCBx Operational Version is 0 DCBx Max Version Supported is 0 Sequence Number: 1 Acknowledgment Number: 1 Protocol State: In-Sync Peer DCBx Status: ---------------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 D
Field Description 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. Total DCBx Frames received Number of DCBx frames received from remote peer port. Total DCBx Frame errors Number of DCBx frames with errors received.
3 Configure the number of PFC queues. CONFIGURATION mode dcb enable pfc-queues pfc-queues The number of ports supported based on lossless queues configured depends on the buffer. The default number of PFC queues in the system is two. 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.
Figure 31. 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 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.
13 Dynamic Host Configuration Protocol (DHCP) 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 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. Assign an IP Address using DHCP The following section describes DHCP and the client in a network. When a client joins a network: 1 The client initially broadcasts a DHCPDISCOVER message on the subnet to discover available DHCP servers.
• • • • IP source address validation is a sub-feature of DHCP Snooping; the Dell EMC Networking OS uses access control lists (ACLs) internally to implement this feature and as such, you cannot apply ACLs to an interface which has IP source address validation. If you configure IP source address validation on a member port of a virtual local area network (VLAN) and then to apply an access list to the VLAN, Dell EMC Networking OS displays the first line in the following message.
To create an address pool, follow these steps. 1 Access the DHCP server CLI context. CONFIGURATION mode ip dhcp server 2 Create an address pool and give it a name. DHCP mode pool name 3 Specify the range of IP addresses from which the DHCP server may assign addresses. 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.
Specifying an Address Lease Time To specify an address lease time, use the following command. • Specify an address lease time for the addresses in a pool. DHCP lease {days [hours] [minutes] | infinite} 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.
netbios-name-server address 2 Specify the NetBIOS node type for a Microsoft DHCP client. Dell EMC Networking recommends specifying clients as hybrid. DHCP mode netbios-node-type type Creating Manual Binding Entries An address binding is a mapping between the IP address and the media access control (MAC) address of a client. The DHCP server assigns the client an available IP address automatically, and then creates an entry in the binding table.
EXEC Privilege mode. clear ip dhcp binding ip address Configure the System to be a DHCP Client A DHCP client is a network device that requests an IP address and configuration parameters from a DHCP server. Implement the DHCP client functionality as follows: • The switch can obtain a dynamically assigned IP address from a DHCP server. A start-up configuration is not received. Use bare metal provisioning (BMP) to receive configuration parameters (Dell EMC Networking OS version and a configuration file).
address, use the renew DHCP command in EXEC Privilege mode or the ip address dhcp command in INTERFACE Configuration mode. To manually configure a static IP address on an interface, use the ip address command. A prompt displays to release an existing dynamically acquired IP address. If you confirm, the ability to receive a DHCP server-assigned IP address is removed.
DHCP Client on a Management Interface These conditions apply when you enable a management interface to operate as a DHCP client. • The management default route is added with the gateway as the router IP address received in the DHCP ACK packet. It is required to send and receive traffic to and from other subnets on the external network. The route is added irrespective when the DHCP client and server are in the same or different subnets.
• If you enable DHCP snooping globally on a switch and you enable a DHCP client on an interface, the trust port, source MAC address, and snooping table validations are not performed on the interface by DHCP snooping for packets destined to the DHCP client daemon. The following criteria determine packets destined for the DHCP client: • • DHCP is enabled on the interface. • The user data protocol (UDP) destination port in the packet is 68.
The relay agent strips Option 82 from DHCP responses before forwarding them to the client. 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.
NOTE: If you enable DHCP Option 82 using the ip dhcp relay command, by default, the remote-ID field contains the MAC address of the relay agent. If you configure the remote ID as the host name in a VLT setup, configure different host names on both VLT peers. If you configure the remote ID with your own string, ensure that your strings are different on both VLT peers. DHCP Snooping in a VLT Setup In a VLT setup, the DHCP snooping binding table synchronizes between the VLT nodes.
EXEC Privilege mode ip dhcp snooping binding mac mac-address vlan-id vlan-id ip ip-address interface interfacetype interface-number lease lease-value If multiple IP addresses are expected for the same MAC address, repeat this step for all IP addresses. Adding a Static IPV6 DHCP Snooping Binding Table To add a static entry in the snooping database, use the following command. • Add a static entry in the snooping binding table.
IP IP IP IP DHCP DHCP DHCP DHCP Snooping Snooping Mac Verification Relay Information-option Relay Trust Downstream : : : : Enabled. Disabled. Disabled. Disabled.
The following example shows a sample output of the show ip dhcp snooping binding command for a device connected to the peer VLT node, but not to itself. The Po 10 interface is the VLTi link between the VLT peers. DellEMC#show ip dhcp snooping binding Codes : S - Static D - Dynamic IP Address MAC Address Expires(Sec) Type VLAN Interface ========================================================================= 10.1.1.10 00:00:a0:00:00:00 39735 S Vl 200 Po 10 10.1.1.
To view the number of entries in the table, use the show ip dhcp snooping binding command. This output displays the snooping binding table created using the ACK packets from the trusted port. DellEMC#show ip dhcp snooping binding Codes : S - Static D - Dynamic IP Address MAC Address Expires(Sec) Type VLAN Interface ================================================================ 10.1.1.251 00:00:4d:57:f2:50 172800 D Vl 10 Te 1/2/1 10.1.1.252 00:00:4d:57:e6:f6 172800 D Vl 10 Te 1/1/1 10.1.1.
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. SystemFlow has 102 entries by default. This region comprises two sub-regions: L2Protocol and L2SystemFlow. L2Protocol has 87 entries; L2SystemFlow has 15 entries. Six L2SystemFlow entries are used by Layer 2 protocols, leaving nine for DAI.
• Specify an interface as trusted so that ARPs are not validated against the binding table. INTERFACE mode arp inspection-trust Dynamic ARP inspection is supported on Layer 2 and Layer 3. Source Address Validation Using the DHCP binding table, Dell EMC Networking OS can perform three types of source address validation (SAV). Table 28.
NOTE: Before enabling SAV With VLAN option, allocate at least one FP block to the ipmacacl CAM region. DHCP MAC Source Address Validation DHCP MAC source address validation (SAV) validates a DHCP packet’s source hardware address against the client hardware address field (CHADDR) in the payload. Dell EMC Networking OS ensures that the packet’s source MAC address is checked against the CHADDR field in the DHCP header only for packets from snooped VLANs. • Enable DHCP MAC SAV.
Viewing the Number of SAV Dropped Packets The following output of the show ip dhcp snooping source-address-validation discard-counters command displays the number of SAV dropped packets.
14 Equal Cost Multi-Path (ECMP) This chapter describes configuring ECMP. This chapter describes configuring ECMP. ECMP for Flow-Based Affinity ECMP for flow-based affinity includes 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.
ECMP bundle - 1 Utilization[In Percent] - 44 Alarm State - Active Interface Line Protocol Utilization[In Percent] Te 1/1/1 Up 36 Te 1/1/1 Up 52 Managing ECMP Group Paths To avoid path degeneration, configure the maximum number of paths for an ECMP route that the L3 CAM can hold. When you do not configure the maximum number of routes, the CAM can hold a maximum ECMP per route. To configure the maximum number of paths, use the following command.
• Modify the threshold for monitoring ECMP group bundles. CONFIGURATION mode link-bundle-distribution trigger-threshold {percent} The range is from 1 to 90%. • The default is 60%. Display details for an ECMP group bundle. EXEC mode show link-bundle-distribution ecmp-group ecmp-group-id The range is from 1 to 64. Viewing an ECMP Group NOTE: An ecmp-group index is generated automatically for each unique ecmp-group when you configure multipath routes to the same network.
Support for ECMP in host table ECMP support in the L3 host table is available on the system. IPv6 /128 prefix route entries and IPv4 /32 prefix entries which are moved to host table can have ECMP. For other platforms, only the IPv6 /128 prefix route entries is stored in the L3 host table without ECMP support. The software supports a command to program IPv6 /128 route prefixes in the host table. The output of show IPv6 cam command has been enhanced to include the ECMP field in the Neighbor table of Ipv6 CAM.
15 FIP Snooping 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 switch stack.
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). The following table lists the FIP functions. Table 29.
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). On a FIP snooping bridge, ACLs are created dynamically as FIP login frames are processed.
Figure 35. FIP Snooping on a Dell EMC Networking Switch The following sections describe how to configure the FIP snooping feature on a switch: • Allocate CAM resources for FCoE. • 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.
Using FIP Snooping There are four steps to configure FCoE transit. 1 Enable the FCoE transit feature on a switch. 2 Enable FIP snooping globally on all Virtual Local Area Networks (VLANs) or individual VLANs on a FIP snooping bridge. 3 Configure the FC-Map value applied globally by the switch on all VLANs or an individual VLAN. 4 Configure FCF mode for a FIP snooping bridge-to-FCF link. For a sample FIP snooping configuration, refer to FIP Snooping Configuration Example.
CAM ACL Table -- Chassis Cam ACL -Current Settings(in block sizes) 1 block = 256 entries L2Acl : 2 Ipv4Acl : 0 Ipv6Acl : 0 Ipv4Qos : 2 L2Qos : 0 L2PT : 0 IpMacAcl : 0 VmanQos : 0 EtsAcl : 1 FcoeAcl : 2 iscsiOptAcl : 2 ipv4pbr : 0 vrfv4Acl : 0 Openflow : 0 fedgovacl : 0 nlbclusteracl: 0 -- stack-unit 1 -Current Settings(in block sizes) 1 block = 256 entries L2Acl : 2 Ipv4Acl : 0 Ipv6Acl : 0 Ipv4Qos : 2 L2Qos : 0 L2PT : 0 IpMacAcl : 0 VmanQos : 0 EtsAcl : 1 FcoeAcl : 2 iscsiOptAcl : 2 ipv4pbr : 0 vrfv4Acl : 0
Enable FIP Snooping on VLANs You can enable FIP snooping globally on a switch on all VLANs or on a specified VLAN. When you enable FIP snooping on VLANs: • FIP frames are allowed to pass through the switch on the enabled VLANs and are processed to generate FIP snooping ACLs. • FCoE traffic is allowed on VLANs only after a successful virtual-link initialization (fabric login FLOGI) between an ENode and an FCF. All other FCoE traffic is dropped.
Table 30. Impact of Enabling FIP Snooping Impact Description MAC address learning MAC address learning is not performed on FIP and FCoE frames, which are denied by ACLs dynamically created by FIP snooping on server-facing ports in ENode mode. MTU auto-configuration MTU size is set to mini-jumbo (2500 bytes) when a port is in Switchport mode, the FIP snooping feature is enabled on the switch, and FIP snooping is enabled on all or individual VLANs.
Displaying FIP Snooping Information Use the following show commands to display information on FIP snooping. Table 31. Displaying FIP Snooping Information Command Output show fip-snooping sessions [interface vlan vlan-id] Displays information on FIP-snooped sessions on all VLANs or a specified VLAN, including the ENode 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).
Table 32. 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. FCF Interface Slot/port number of the interface to which the FCF is connected. VLAN VLAN ID number used by the session. FCoE MAC MAC address of the FCoE session assigned by the FCF. FC-ID Fibre Channel ID assigned by the FCF. Port WWPN Worldwide port name of the CNA port.
Table 34. show fip-snooping fcf Command Description Field Description FCF MAC MAC address of the FCF. FCF Interface Slot/port number of the interface to which the FCF is connected. VLAN VLAN ID number used by the session. FC-MAP FC-Map value advertised by the FCF. ENode Interface Slot/port number of the interface connected to the ENode. FKA_ADV_PERIOD Period of time (in milliseconds) during which FIP keep-alive advertisements are transmitted.
The following example shows the show fip-snooping statistics port-channel command.
Field Description Number of FDISC Accepts Number of FIP FDISC accept frames received on the interface. Number of FDISC Rejects Number of FIP FDISC reject frames received on the interface. Number of FLOGO Accepts Number of FIP FLOGO accept frames received on the interface. Number of FLOGO Rejects Number of FIP FLOGO reject frames received on the interface. Number of CVLs Number of FIP clear virtual link frames received on the interface.
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 36. Configuration Example: FIP Snooping on a Switch In this example, DCBx and PFC are enabled on the FIP snooping bridge and on the FCF ToR switch.
Example of Configuring the ENode Server-Facing Port DellEMC(conf)# interface tengigabitethernet 1/1/1 DellEMC(conf-if-te-1/1/1)# portmode hybrid DellEMC(conf-if-te-1/1/1)# switchport DellEMC(conf-if-te-1/1/1)# protocol lldp DellEMC(conf-if-te-1/1/1-lldp)# dcbx port-role auto-downstream NOTE: A port is enabled by default for bridge-ENode links.
16 Flex Hash and Optimized Boot-Up This chapter describes the Flex Hash and fast-boot enhancements. Topics: • Flex Hash Capability Overview • Configuring the Flex Hash Mechanism • Configuring Fast Boot and LACP Fast Switchover • Optimizing the Boot Time • Interoperation of Applications with Fast Boot and System States • RDMA Over Converged Ethernet (RoCE) Overview • Preserving 802.
When load balancing RRoCE packets using flex hash is enabled, the show ip flow command is disabled. Similarly, when the show ip flow command is in use (ingress port-based load balancing is disabled), the hashing of RRoCE packets is disabled. Flex hash APIs do not mask out unwanted byte values after extraction of the data from the Layer 4 headers for the offset value.
adjacency settings) is learned and installed before the traffic resumes. In a typical network scenario, a traffic disconnection of 150 seconds or more usually occurs. When you employ the optimized booting functionality, the traffic outage duration is reduced drastically.
ports to be 10-Gigabit Ethernet interfaces and 8 ports as 40-Gigabit Ethernet interfaces. You must configure the switch to operate with an uplink speed of 40 Gigabit Ethernet per second. Interoperation of Applications with Fast Boot and System States This functionality is supported on the platform.
BGP Graceful Restart When the system contains one or more BGP peerings configured for BGP graceful restart, fast boot performs the following actions: • A closure of the TCP sessions is performed on all sockets corresponding to BGP sessions on which Graceful Restart has been negotiated. This behavior is to force the peer to perform the helper role so that any routes advertised by the restarting system are retained and the peering session will not go down due to BGP Hold timeout.
Changes to BGP Multipath When the system becomes active after a fast-boot restart, a change has been made to the BGP multipath and ECMP behavior. The system delays the computation and installation of additional paths to a destination into the BGP routing information base (RIB) and forwarding table for a certain period of time.
enabled, the packets comprise TCP and UDP packets and they can be marked with DSCP code points. Multicast is not supported in that network. RRoCE packets are received and transmitted on specific interfaces called lite-subinterfaces. These interfaces are similar to the normal Layer 3 physical interfaces except for the extra provisioning that they offer to enable the VLAN ID for encapsulation. You can configure a physical interface or a Layer 3 Port Channel interface as a lite subinterface.
17 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) and may require 4 to 5 seconds to reconverge.
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. Ring Checking At specified intervals, the Master node sends a ring health frame (RHF) through the ring.
Member VLAN Spanning Two Rings Connected by One Switch A member VLAN can span two rings interconnected by a common switch, in a figure-eight style topology. A switch can act as a Master node for one FRRP group and a Transit for another FRRP group, or it can be a Transit node for both rings. In the following example, FRRP 101 is a ring with its own Control VLAN, and FRRP 202 has its own Control VLAN running on another ring. A Member VLAN that spans both rings is added as a Member VLAN to both FRRP groups.
• One Master node per ring — all other nodes are Transit. • Each node has two member interfaces — primary and secondary. • There is no limit to the number of nodes on a ring. • Master node ring port states — blocking, pre-forwarding, forwarding, and disabled. • Transit node ring port states — blocking, pre-forwarding, forwarding, and disabled. • STP disabled on ring interfaces. • Master node secondary port is in blocking state during Normal operation.
Concept Explanation • Hello RHF (HRHF) — These frames are processed only on the Master node’s Secondary port. The Transit nodes pass the HRHF through without processing it. An HRHF is sent at every Hello interval. • Topology Change RHF (TCRHF) — These frames contains ring status, keepalive, and the control and member VLAN hash. The TCRHF is processed at each node of the ring.
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.
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. no disable Configuring and Adding the Member VLANs 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 the Layer 2 chapter.
• For a 100-Gigabit Ethernet interface, enter the keyword hundredGigE then the slot/port information. VLAN ID: Identification number of the Control VLAN. 4 Configure a Transit node. CONFIG-FRRP mode. mode transit 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 this FRRP group on this switch. CONFIG-FRRP mode.
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. EXEC or EXEC PRIVELEGED mode. show frrp ring-id • Ring ID: the range is from 1 to 255. Show the state of all FRRP groups. EXEC or EXEC PRIVELEGED mode. show frrp summary Ring ID: the range is from 1 to 255. Troubleshooting FRRP To troubleshoot FRRP, use the following information.
interface Vlan 201 no ip address tagged TenGigabitEthernet 1/24/1,131/1 no shutdown ! protocol frrp 101 interface primary TenGigabitEthernet 1/24/1 secondary TenGigabitEthernet 1/31/1 control-vlan 101 member-vlan 201 mode master no disable Example of R2 TRANSIT interface TenGigabitEthernet 1/14/1 no ip address switchport no shutdown ! interface TenGigabitEthernet 1/11/1 no ip address switchport no shutdown ! interface Vlan 101 no ip address tagged TenGigabitEthernet 1/14/1,11/1 no shutdown ! interface Vlan
mode transit no disable FRRP Support on VLT Using FRRP rings, you can inter-connect VLT domains across data centers. These FRRP rings make use of Layer2 VLANs that spawn across Data Centers and provide resiliency by detecting node or link level failures. You can configure a simple FRRP ring that connects a VLT device in one data center to a VLT devices in two or more Data Centers.
and the FRRP ring itself. In addition to the control VLAN, multiple member VLANS are configured (for example, M1 through M10) that carry the data traffic across the FRRP rings. The secondary port P1 is tagged to the control VLAN (V1). VLTi is implicitly tagged to the member VLANs when these VLANs are configured in the VLT peer. As a result of the VLT Node1 configuration, the FRRP ring R1 becomes active by blocking the secondary interface P1 for the member VLANs (M1 to M10). VLT Node2 is the transit node.
• Only RSTP and PVST are supported in the VLT environment. Enabling either RSTP or PVST effects FRRP functionality even though these features are disabled on FRRP enabled interfaces. • Dell EMC Networking OS does not support coexistence of xSTP and FRRP configurations. Meaning, if there is any active FRRP ring in the system, then you cannot enable xSTP in the system globally or at the interface level. Similarly, if xSTP is enabled, then you cannot configure FRRP in the system.
18 GARP VLAN Registration Protocol (GVRP) The generic attribute registration protocol (GARP) VLAN registration protocol (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 deregister 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, GVRP is configured on VLAN trunk ports. Figure 40.
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 DellEMC(conf)#protocol gvrp DellEMC(config-gvrp)#no disable DellEMC(config-gvrp)#show config ! protocol gvrp no disable DellEMC(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.
Based on the configuration in the following example, the interface is not removed from VLAN 34 or VLAN 35 despite receiving a GVRP Leave message. Additionally, the interface is not dynamically added to VLAN 45 or VLAN 46, even if a GVRP Join message is received.
19 Internet Group Management Protocol (IGMP) Internet group management protocol (IGMP) is a Layer 3 multicast protocol that hosts use to join or leave a multicast group. Multicast is premised on identifying many hosts by a single destination IP address; hosts represented by the same IP address are a multicast group. Multicast routing protocols (such as protocol-independent multicast [PIM]) use the information in IGMP messages to discover which groups are active and to populate the multicast routing table.
leaves a multicast group by sending an IGMP message to its IGMP Querier. The querier is the router that surveys a subnet for multicast receivers and processes survey responses to populate the multicast routing table. IGMP messages are encapsulated in IP packets, as shown in the following illustration. Figure 41.
3 Any remaining hosts respond to the query according to the delay timer mechanism (refer to Adjusting Query and Response Timers). If no hosts respond (because there are none remaining in the group), the querier waits a specified period and sends another query. If it still receives no 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.
Figure 43. 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 44. 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.
Figure 45. 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.
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 DellEMC#show ip igmp interface TenGigabitEthernet 1/10/1 Inbound IGMP access group is not set Internet address is 165.87.34.
EXEC Privilege mode show ip igmp groups Example of the show ip igmp groups Command DellEMC#show ip igmp groups Total Number of Groups: 2 IGMP Connected Group Membership Group Address Interface 225.1.1.1 TenGigabitEthernet 1/1/1 225.1.2.1 TenGigabitEthernet 1/1/1 Mode IGMPV2 IGMPV2 Uptime 00:11:19 00:10:19 Expires 00:01:50 00:01:50 Last Reporter 165.87.34.100 165.87.31.100 Adjusting Timers The following sections describe viewing and adjusting timers.
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).
no ip igmp snooping Related Configuration Tasks • Removing a Group-Port Association • Disabling Multicast Flooding • Specifying a Port as Connected to a Multicast Router • Configuring the Switch as Querier Example of ip igmp snooping enable Command DellEMC(conf)#ip igmp snooping enable DellEMC(conf)#do show running-config igmp ip igmp snooping enable DellEMC(conf)# Removing a Group-Port Association To configure or view the remove a group-port association feature, 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. show ip igmp snooping mrouter Configuring the Switch as Querier To configure the switch as a querier, use the following command. Hosts that do not support unsolicited reporting wait for a general query before sending a membership report.
Egress Interface Selection (EIS) for HTTP and IGMP Applications You can use the Egress Interface Selection (EIS) feature to isolate the management and front-end port domains for HTTP and IGMP traffic. Also, EIS enables you to configure the responses to switch-destined traffic by using the management port IP address as the source IP address. This information is sent out of the switch through the management port instead of the front-end port.
Application Name Port Number Client Server FTP 20/21 Supported Supported Syslog 514 Supported Telnet 23 Supported TFTP 69 Supported Radius 1812,1813 Supported Tacacs 49 Supported HTTP 80 for httpd Supported Supported 443 for secure httpd 8008 HTTP server port for confd application 8888 secure HTTP server port for confd application If you configure a source interface is for any EIS management application, EIS might not coexist with that interface and the behavior is undefined in su
• For management applications, route lookup is preferentially done in the management EIS routing table for all traffic. management port is the preferred egress port. For example, if SSH is a management application, an SSH session to a front-panel port IP on the peer box is initiated via management port only, if the management port is UP and management route is available.
• To ensure that protocol separation is done only for switch initiated traffic where the application acts as client, only the destination TCP/UDP port is compared and not the source TCP/UDP port. The source TCP/UDP port becomes a known port number when the box acts as server. • TFTP is an exception to the preceding logic. • For TFTP, data transfer is initiated on port 69, but the data transfer ports are chosen independently by the sender and receiver during initialization of the connection.
takes a preference for ip1 as source IP and uses the management network to reach the destination. If the management port is down or the route lookup in EIS routing table fails, ip2 is the source IP and the front-panel port is used to reach the destination. The fallback route between the management and data networks is used in such a case. At any given time, end users can access Dell EMC Networking OS applications using either ip1 or ip2.
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 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 Default Behavior icmp (ping and traceroute) EIS Behavior for ICMP Default Behavior Behavior of Various Applications for Switch-Destined Traffic This section describes the different system
Interworking of EIS With Various Applications Stacking • The management EIS is enabled on the master and the standby unit. • Because traffic can be initiated from the Master unit only, the preference to management EIS table for switch-initiated traffic and all its related ARP processing is done in the Master unit only. • ARP-related processing for switch-destined traffic is done by both master and standby units. VLT VLT feature is for the front-end port only.
20 Interfaces This chapter describes interface types, both physical and logical, and how to configure them with Dell EMC Networking Operating System (OS). The system supports 10–Gigabit, 25–Gigabit, 40–Gigbit, 50–Gigabit, and 100–Gigabit QSFP 28 interfaces. NOTE: Only Dell-qualified optics are supported on these interfaces. Non-Dell optics for 40–Gigbit, 25–Gigabit, 50–Gigabit, and 100–Gigabit are set to error-disabled state.
• Loopback Interfaces • Null Interfaces • Port Channel Interfaces • Bulk Configuration • Defining Interface Range Macros • Monitoring and Maintaining Interfaces • Non Dell-Qualified Transceivers • Splitting 100G Ports • Link Dampening • Link Bundle Monitoring • Using Ethernet Pause Frames for Flow Control • Configure the MTU Size on an Interface • Configuring wavelength for 10–Gigabit SFP+ optics • Port-Pipes • CR4 Auto-Negotiation • Setting the Speed of Ethernet Interfaces •
EXEC mode show interfaces This command has options to display the interface status, IP and MAC addresses, and multiple counters for the amount and type of traffic passing through the interface. If you configured a port channel interface, this command lists the interfaces configured in the port channel. NOTE: To end output from the system, such as the output from the show interfaces command, enter CTRL+C and Dell EMC Networking OS returns to the command prompt.
TenGigabitEthernet 1/6/3 TenGigabitEthernet 1/6/4 unassigned unassigned NO NO Manual administratively down down Manual administratively down down To view only configured interfaces, use the show interfaces configured command in the EXEC Privilege mode. 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 system.
All the applied configurations are removed and the interface is set to the factory default state. Enabling a Physical Interface After determining the type of physical interfaces available, to enable and configure the interfaces, enter INTERFACE mode by using the interface interface command. 1 Enter the keyword interface then the type of interface and slot/port[/subport] information.
Overview of Layer Modes On all systems running Dell EMC Networking OS, you can place physical interfaces, port channels, and VLANs in Layer 2 mode or Layer 3 mode. By default, VLANs are in Layer 2 mode. Table 41. Layer Modes Type of Interface Possible Modes Requires Creation Default State 10 Gigabit Ethernet, 25–Gigabit Ethernet, 40–Gigabit Ethernet, 50–Gigabit Ethernet, and 100– Gigabit Ethernet.
INTERFACE mode • no shutdown Place the interface in Layer 2 (switching) mode. INTERFACE mode switchport To view the interfaces in Layer 2 mode, use the show interfaces switchport command in EXEC mode. Configuring Layer 3 (Network) Mode When you assign an IP address to a physical interface, you place it in Layer 3 mode. To enable Layer 3 mode on an individual interface, use the following commands.
The ip-address must be in dotted-decimal format (A.B.C.D) and the mask must be in slash format (/xx). Add the keyword secondary if the IP address is the interface’s backup IP address. Example of the show ip interface Command You can only configure one primary IP address per interface. You can configure up to 255 secondary IP addresses on a single interface.
application {all | application-type} NOTE: If you configure SNMP as the management application for EIS and you add a default management route, when you perform an SNMP walk and check the debugging logs for the source and destination IPs, the SNMP agent uses the destination address of incoming SNMP packets as the source address for outgoing SNMP responses for security. Management Interfaces The system supports the Management Ethernet interface as well as the standard interface on any port.
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.
! tagged TenGigabitEthernet 5/1/1 ip ospf authentication-key force10 ip ospf cost 1 ip ospf dead-interval 60 ip ospf hello-interval 15 no shutdown Loopback Interfaces A Loopback interface is a virtual interface in which the software emulates an interface. Packets routed to it are processed locally. Because this interface is not a physical interface, you can configure routing protocols on this interface to provide protocol stability. You can place Loopback interfaces in default Layer 3 mode.
Port Channel Definition and Standards Link aggregation is defined by IEEE 802.3ad as a method of grouping multiple physical interfaces into a single logical interface—a link aggregation group (LAG) or port channel. A LAG is “a group of links that appear to a MAC client as if they were a single link” according to IEEE 802.3ad. In Dell EMC Networking OS, a LAG is referred to as a port channel interface. A port channel provides redundancy by aggregating physical interfaces into one logical interface.
Interfaces in Port Channels When interfaces are added to a port channel, the interfaces must share a common speed. When interfaces have a configured speed different from the port channel speed, the software disables those interfaces. The common speed is determined when the port channel is first enabled. Then, the software checks the first interface listed in the port channel configuration. If you enabled that interface, its speed configuration becomes the common speed of the port channel.
Adding a Physical Interface to a Port Channel The physical interfaces in a port channel can be on any line card in the chassis, but must be the same physical type. NOTE: Port channels can contain a mix of Ethernet interfaces, but Dell EMC Networking OS disables the interfaces that are not the same speed of the first channel member in the port channel (refer to 10/100/1000 Mbps Interfaces in Port Channels). You can add any physical interface to a port channel if the interface configuration is minimal.
Internet address is 1.1.120.
INTERFACE PORT-CHANNEL mode channel-member interface Example of Moving an Interface to a New Port Channel The following example shows moving an interface from port channel 4 to port channel 3.
untagged port-channel id number • An interface without tagging enabled can belong to only one VLAN. Remove the port channel with tagging enabled from the VLAN. INTERFACE VLAN mode no tagged port-channel id number or no untagged port-channel id number • Identify which port channels are members of VLANs.
ip address ip-address mask [secondary] • ip-address mask: enter an address in dotted-decimal format (A.B.C.D). The mask must be in slash format (/24). • secondary: the IP address is the interface’s backup IP address. You can configure up to eight secondary IP addresses. Deleting or Disabling a Port Channel To delete or disable a port channel, use the following commands. • Delete a port channel. CONFIGURATION mode no interface portchannel channel-number • Disable a port channel.
• tcp-udp enable — Distribute traffic based on the TCP/UDP source and destination ports. • ingress-port — Option to Source Port Id for ECMP/ LAG hashing. • ipv6-selection— Set the IPV6 key fields to use in hash computation. • tunnel— Set the tunnel key fields to use in hash computation. Changing the Hash Algorithm The load-balance command selects the hash criteria applied to port channels.
• dest-ip — uses destination IP address as part of the hash key. • lsb — uses the least significant bit of the hash key to compute the egress port. • xor1 — uses Upper 8 bits of CRC16-BISYNC and lower 8 bits of xor1 • xor2 — Upper 8 bits of CRC16-BISYNC and lower 8 bits of xor2 • xor4 —Upper 8 bits of CRC16-BISYNC and lower 8 bits of xor4 • xor8 — Upper 8 bits of CRC16-BISYNC and lower 8 bits of xor8 • xor16 — uses 16 bit XOR.
• Add Ranges Create a Single-Range The following is an example of a single range. Example of the interface range Command (Single Range) DellEMC(config)# interface range tengigabitethernet 1/1/1 - 1/2/3 DellEMC(config-if-range-te-1/1/1-1/2/3)# no shutdown DellEMC(config-if-range-te-1/1/1-1/2/3)# DellEMC(config)# interface range hundredGigE 1/1-1/8 DellEMC(config-if-range-te-1/1-1/8)# no shutdown DellEMC(config-if-range-te-1/1-1/8)# Create a Multiple-Range The following is an example of multiple range.
Commas The following is an example of how to use commas to add different interface types to a range of interfaces. Example of Adding Interface Ranges DellEMC(config-if)# interface range tengigabitethernet 1/1/1 - 1/4/4, fo 1/5/1 - 1/6/1 DellEMC(config-if-range-te-1/1/1-1/4/4,fo1/5/1-1/6/2)# no shutdown Add Ranges The following example shows how to use commas to add VLAN and port-channel interfaces to the range.
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.
q DellEMC# Maintenance Using TDR The time domain reflectometer (TDR) is supported on all Dell EMC Networking switches. 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.
LineSpeed 40000 Mbit
• number: enter the port number of the 100G port to be split. The range is from 1 to 32. Link Dampening Interface state changes occur when interfaces are administratively brought up or down or if an interface state changes. Every time an interface changes a state or flaps, routing protocols are notified of the status of the routes that are affected by the change in state. These protocols go through the momentous task of re-converging.
Configuration Example of Link Dampening The figure shows a how link dampening works in a sample scenario when an interface is configured with dampening. The following figure shows the interface state change, accumulation and decay of penalty, and the interface advertised state based on the set dampening parameters.
Figure 46. Interface State Change Consider an interface periodically flaps as shown above. Every time the interface goes down, a penalty (1024) is added. In the above example, during the first interface flap (flap 1), the penalty is added to 1024. And, the accumulated penalty will exponentially decay based on the set half-life, which is set as 10 seconds in the above example.
accumulated. When the accumulated penalty exceeds the configured suppress threshold (2400), the interface state is set to Error-Disabled state. After the flap (flap 3), the interface flap stops. Then, the accumulated penalty decays exponentially and when it reaches below the set reuse threshold (300), the interface is unsuppressed and the interface state changes to “up” state. Enabling Link Dampening To enable link dampening, use the following command. • Enable link dampening.
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. • show interfaces dampening • show interfaces dampening summary • show interfaces interface slot/port/subport Configure MTU Size on an Interface In Dell EMC Networking OS, Maximum Transmission Unit (MTU) is defined as the entire Ethernet packet (Ethernet header + FCS + payload).
link-bundle-distribution trigger-threshold DellEMC(conf)#link-bundle-distribution trigger-threshold • View the link bundle monitoring status. show link-bundle-distribution Using Ethernet Pause Frames for Flow Control Ethernet pause frames and threshold settings are supported on the Dell EMC 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 flow control sender and receiver must be on the same port-pipe. Flow control is not supported across different port-pipes. To enable pause frames, use the following command. • Control how the system responds to and generates 802.3x pause frames on the Ethernet ports. INTERFACE mode flowcontrol {rx [off | on] tx [off | on] | monitor session-ID} • rx on: enter the keywords rx on to process the received flow control frames on this port.
For example, the VLAN contains tagged members with Link MTU of 1522 and IP MTU of 1500 and untagged members with Link MTU of 1518 and IP MTU of 1500. The VLAN’s Link MTU cannot be higher than 1518 bytes and its IP MTU cannot be higher than 1500 bytes. Configuring wavelength for 10–Gigabit SFP+ optics You can set the wavelength for tunable 10–Gigabit SFP+ optics using the wavelength command. To set the wavelength, follow these steps: • Enter the interface mode and set the wavelength.
• • For 100-Gigabit Ethernet interfaces, CR4 auto-negotiation is enabled by default. For 40–Gigbit, 25–Gigabit and 50–Gigabit Ethernet interfaces, CR4 auto-negotiation is disabled by default. Setting the Speed 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.
Te 1/2/1 Te 1/2/2 Te 1/2/3 Te 1/2/4 Fo 1/3 Fo 1/4 Fo 1/5 [output omitted] Up Up Up Up Down Down Down 10000 10000 Auto 10000 40000 40000 Auto Mbit Mbit Mbit Mbit Mbit Mbit Mbit Full Full Full Full Auto Auto Auto 2-5 2-5 2-5 2-5 ---- 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.
• To disable FEC, use the no fec enable command. Set to default FEC value. INTERFACE mode • fec default Verify the configuration. INTERFACE mode show config Example of the fec enable Command example for the fec enable command for a 100G interface.
0 throttles, 0 discarded, 0 collisions, 0 wreddrops Rate info (interval 299 seconds): Input 00.00 Mbits/sec, 0 packets/sec, 0.00% of line-rate Output 00.00 Mbits/sec, 0 packets/sec, 0.00% of line-rate Time since last interface status change: 00:27:30 View Advanced Interface Information The following options have been implemented for the show [ip | running-config] interfaces commands for (only) stack-unit interfaces.
The following example shows how to configure rate interval when changing the default value. To configure the number of seconds of traffic statistics to display in the show interfaces output, use the following command. • Configure the number of seconds of traffic statistics to display in the show interfaces output. INTERFACE mode rate-interval Example of the rate-interval Command The bold lines shows the default value of 299 seconds, the change-rate interval of 100, and the new rate interval set to 100.
Configuring the Traffic Sampling Size Globally You can configure the traffic sampling size for an interface in the global configuration mode. All LAG members inherit the rate interval configuration from the LAG. 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. The following example shows how to configure rate interval when changing the default value.
Minimum number of links to bring Port-channel up is 1 Internet address is not set Mode of IPv4 Address Assignment : NONE DHCP Client-ID :4c7625f4ab02 MTU 1554 bytes, IP MTU 1500 bytes LineSpeed 80000 Mbit Members in this channel: Fo 1/1/7/1(U) Fo 1/1/8/1(U) ARP type: ARPA, ARP Timeout 04:00:00 Queueing strategy: fifo Input Statistics: 13932 packets, 1111970 bytes 5588 64-byte pkts, 8254 over 64-byte pkts, 89 over 127-byte pkts 1 over 255-byte pkts, 0 over 511-byte pkts, 0 over 1023-byte pkts 13761 Multicast
clear counters [interface] [vrrp [vrid] | learning-limit] (OPTIONAL) Enter the following interface keywords and slot/port or number information: • For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/port/subport information. • For a 25-Gigabit Ethernet interface, enter the keyword twentyFiveGigE then the slot/port/subport information. • For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port/subport information.
Table 43. Standard and Compressed Configurations int vlan 2 int vlan 3 int vlan 4 int vlan 5 int vlan 100 int vlan 1000 no ip address tagged te 1/1/1 tagged te 1/1/1 tagged te 1/1/1 no ip address ip address 1.1.1.1/16 no shut no ip address no ip address no ip address no shut no shut shut shut shut int te 1/1/1 int te 1/2/1 int te 1/3/1 int te 1/4/1 int te 1/10/1 int te 1/34/1 no ip address no ip address no ip address no ip address no ip address ip address 2.1.1.
! shutdown interface TenGigabitEthernet 1/34/1 ! ip address 2.1.1.1/16 interface Vlan 1000 shutdown ip address 1.1.1.1/16 ! no shutdown interface Vlan 2 ! no ip address no shutdown Compressed config size – 27 lines. ! interface Vlan 3 tagged te 1/1/1 no ip address shutdown ! interface Vlan 4 tagged te 1/1/1 no ip address shutdown ! interface Vlan 5 tagged te 1/1/1 no ip address shutdown ! interface Vlan 100 no ip address no shutdown ! interface Vlan 1000 ip address 1.1.1.
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.
21 IPv4 Routing The Dell EMC 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 EMC Networking OS.
• Configurations Using UDP Helper • UDP Helper with Broadcast-All Addresses • UDP Helper with Subnet Broadcast Addresses • UDP Helper with Configured Broadcast Addresses • UDP Helper with No Configured Broadcast Addresses • Troubleshooting UDP Helper IP Addresses Dell EMC Networking OS supports IP version 4 (as described in RFC 791), classful routing, and variable length subnet masks (VLSM). With VLSM, you can configure one network with different masks.
2 • For a 25-Gigabit Ethernet interface, enter the keyword twentyFiveGigE then the slot/port/subport information. • For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port/subport information. • For a 50-Gigabit Ethernet interface, enter the keyword fiftyGigE then the slot/port/subport information. • For a 100-Gigabit Ethernet interface, enter the keyword hundredGigE then the slot/port information.
• permanent: keep the static route in the routing table (if you use the interface option) even if you disable the interface with the route. (optional) • tag tag-value: the range is from 1 to 4294967295. (optional) Example of the show ip route static Command To view the configured routes, use the show ip route static command. DellEMC#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 6.1.2.2/32 via 6.1.20.2, S 6.1.2.3/32 via 6.1.20.2, S 6.1.2.
10.16.0.0/16 172.16.1.0/24 ManagementEthernet 1/1 10.16.151.4 Connected Active Connected Static Using the Configured Source IP Address in ICMP Messages ICMP error or unreachable messages are now sent with the configured IP address of the source interface instead of the front-end port IP address as the source IP address. Enable the generation of ICMP unreachable messages through the ip unreachable command in Interface mode.
DellEMC>show ip tcp reduced-syn-ack-wait Enabling Directed Broadcast By default, Dell EMC Networking OS drops directed broadcast packets destined for an interface. This default setting provides some protection against denial of service (DoS) attacks. To enable Dell EMC Networking OS to receive directed broadcasts, use the following command. • Enable directed broadcast. INTERFACE mode ip directed-broadcast To view the configuration, use the show config command in INTERFACE mode.
-------- ----- ---ks (perm, OK) patch1 (perm, OK) tomm-3 (perm, OK) gxr (perm, OK) f00-3 (perm, OK) DellEMC> - ---IP IP IP IP IP ------2.2.2.2 192.68.69.2 192.68.99.2 192.71.18.2 192.71.23.1 To view the current configuration, use the show running-config resolve command. Specifying the Local System Domain and a List of Domains If you enter a partial domain, Dell EMC Networking OS can search different domains to finish or fully qualify that partial domain.
Example of the traceroute Command The following text is example output of DNS using the traceroute command. DellEMC#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.
• ip-address: IP address in dotted decimal format (A.B.C.D). • mac-address: MAC address in nnnn.nnnn.nnnn format. • interface: enter the interface type slot/port information. Example of the show arp Command These entries do not age and can only be removed manually. To remove a static ARP entry, use the no arp ip-address command. To view the static entries in the ARP cache, use the show arp static command in EXEC privilege mode.
ARP Learning via Gratuitous ARP Gratuitous ARP can mean an ARP request or reply. In the context of ARP learning via gratuitous ARP on Dell EMC Networking OS, the gratuitous ARP is a request.
Figure 48. ARP Learning via ARP Request with ARP Learning via Gratuitous ARP Enabled Whether you enable or disable ARP learning via gratuitous ARP, the system does not look up the target IP. It only updates the ARP entry for the Layer 3 interface with the source IP of the request. Configuring ARP Retries You can configure the number of ARP retries. The default backoff interval remains at 20 seconds. To set and display ARP retries, use the following commands. • Set the number of ARP retries.
Configuration Tasks for ICMP The following lists the configuration tasks for ICMP. • Enabling ICMP Unreachable Messages For a complete listing of all commands related to ICMP, refer to the Dell EMC Networking OS Command Line Reference Guide. 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.
• Enable UPD helper. ip udp-helper udp-ports Example of Enabling UDP Helper and Using the UDP Helper show Command To view the interfaces and ports on which you enabled UDP helper, use the show ip udp-helper command from EXEC Privilege mode. DellEMC#show ip udp-helper -------------------------------------------------Port UDP port list -------------------------------------------------te 1/1/1 1000 Configuring a Broadcast Address To configure a broadcast address, use the following command.
UDP Helper with Broadcast-All Addresses When the destination IP address of an incoming packet is the IP broadcast address, Dell EMC Networking OS rewrites the address to match the configured broadcast address. In the following illustration: 1 Packet 1 is dropped at ingress if you did not configure UDP helper address.
Figure 50. UDP Helper with Subnet Broadcast Addresses 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.
Troubleshooting UDP Helper To display debugging information for troubleshooting, use the debug ip udp-helper command. Example of the debug ip udp-helper Command DellEMC(conf)# debug ip udp-helper 01:20:22: Pkt rcvd on Te 5/1/1 with IP DA (0xffffffff) will be sent on Te 5/1/2 Te 5/1/3 Vlan 3 01:44:54: Pkt rcvd on Te 7/1/1 is handed over for DHCP processing. 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.
22 IPv6 Routing 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 EMC Networking support of IPv6. This chapter is not intended to be a comprehensive description of IPv6.
Extended Address Space The address format is extended from 32 bits to 128 bits. This not only provides room for all anticipated needs, it allows for the use of a hierarchical address space structure to optimize global addressing. Stateless Autoconfiguration When a booting device comes up in IPv6 and asks for its network prefix, the device can get the prefix (or prefixes) from an IPv6 router on its link.
• Flow Label (20 bits) • Payload Length (16 bits) • Next Header (8 bits) • Hop Limit (8 bits) • Source Address (128 bits) • Destination Address (128 bits) IPv6 provides for extension headers. Extension headers are used only if necessary. There can be no extension headers, one extension header or more than one extension header in an IPv6 packet. Extension headers are defined in the Next Header field of the preceding IPv6 header.
The platforms uses only IPv6 /0 – 0/64 prefix route entries. Support for /0 – /128 IPv6 prefix route entries is available, although they are not utilized. A total of eight pools or regions are present with each region containing 1024 210-bit entries (supports up to 0/64 prefix). To support up to /128 prefixes, you must use 2 banks (410-bit entries). It is necessary to partition the LPM. The optimized booting functionality does not use Openflow and therefore SDN support is not available.
Next Header (8 bits) The Next Header field identifies the next header’s type. If an Extension header is used, this field contains the type of Extension header (as shown in the following table). If the next header is a transmission control protocol (TCP) or user datagram protocol (UDP) header, the value in this field is the same as for IPv4. The Extension header is located between the IP header and the TCP or UDP header. The following lists the Next Header field values.
Source Address (128 bits) The Source Address field contains the IPv6 address for the packet originator. Destination Address (128 bits) The Destination Address field contains the intended recipient’s IPv6 address. This can be either the ultimate destination or the address of the next hop router. Extension Header Fields Extension headers are used only when necessary. Due to the streamlined nature of the IPv6 header, adding extension headers do not severely impact performance.
10 Discard the packet and send an ICMP Parameter Problem Code 2 message to the packet’s Source IP Address identifying the unknown option type. 11 Discard the packet and send an ICMP Parameter Problem, Code 2 message to the packet’s Source IP Address only if the Destination IP Address is not a multicast address. The second byte contains the Option Data Length. The third byte specifies whether the information can change en route to the destination.
the same IPv6 address to a particular computer, and never to assign that IP address to another computer. This allows static IPv6 addresses to be configured in one place, without having to specifically configure each computer on the network in a different way. In IPv6, every interface, whether using static or dynamic address assignments, also receives a local-link address automatically in the fe80::/64 subnet.
IPv6 Neighbor Discovery The IPv6 neighbor discovery protocol (NDP) is a top-level protocol for neighbor discovery on an IPv6 network. In place 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.
The lifetime parameter configures the amount of time the IPv6 host can use the IPv6 RDNSS address for name resolution. The lifetime range is 0 to 4294967295 seconds. When the maximum lifetime value, 4294967295, or the infinite keyword is specified, the lifetime to use the RDNSS address does not expire. A value of 0 indicates to the host that the RDNSS address should not be used. You must specify a lifetime using the lifetime or infinite parameter.
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 1/1/1.
Configuration Tasks for IPv6 The following are configuration tasks for the IPv6 protocol. • Adjusting Your CAM-Profile • Assigning an IPv6 Address to an Interface • Assigning a Static IPv6 Route • Configuring Telnet with IPv6 • SNMP over IPv6 • Showing IPv6 Information • Clearing IPv6 Routes Adjusting Your CAM-Profile Although adjusting your CAM-profile is not a mandatory step, if you plan to implement IPv6 ACLs, adjust your CAM settings. The CAM space is allotted in FP blocks.
The total number of groups is 4. Assigning an IPv6 Address to an Interface Essentially, IPv6 is enabled in Dell EMC 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. To assign an IPv6 address to an interface, use the ipv6 address command.
• For a Null interface, enter the keyword null then the Null interface number. • For a VLAN interface, enter the keyword vlan then a number from 1 to 4094. Configuring Telnet with IPv6 The Telnet client and server in Dell EMC Networking OS supports IPv6 connections. You can establish a Telnet session directly to the router using an IPv6 Telnet client, or you can initiate an IPv6 Telnet connection from the router. NOTE: Telnet to link local addresses is supported on the system.
ospf pim prefix-list route rpf DellEMC# OSPF information PIM V6 information List IPv6 prefix lists IPv6 routing information RPF table Displaying an IPv6 Interface Information To view the IPv6 configuration for a specific interface, use the following command. • Show the currently running configuration for the specified interface.
Showing IPv6 Routes To view the global IPv6 routing information, use the following command. • Show IPv6 routing information for the specified route type. EXEC mode show ipv6 route [vrf vrf-name] type The following keywords are available: • To display information about a network, enter ipv6 address (X:X:X:X::X). • To display information about a host, enter hostname. • To display information about all IPv6 routes (including non-active routes), enter all.
Direct, Nu 0, 00:34:42 DellEMC# The following example shows the show ipv6 route static command.
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. To configure the IPv6 RA guard, perform the following steps: 1 Configure the terminal to enter the Global Configuration mode. EXEC Privilege mode configure terminal 2 Enable the IPv6 RA guard. CONFIGURATION mode ipv6 nd ra-guard enable 3 Create the policy.
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 Set the maximum transmission unit (MTU) value. POLICY LIST CONFIGURATION mode mtu value 13 Set the advertised reachability time. POLICY LIST CONFIGURATION mode reachable—time value The reachability time range is from 0 to 3,600,000 milliseconds. 14 Set the advertised retransmission time.
23 iSCSI Optimization This chapter describes how to configure internet small computer system interface (iSCSI) optimization, which enables quality-of-service (QoS) treatment for iSCSI traffic.
• iSCSI QoS — A user-configured iSCSI class of service (CoS) profile is applied to all iSCSI traffic. Classifier rules are used to direct the iSCSI data traffic to queues that can be given preferential QoS treatment over other data passing through the switch. Preferential treatment helps to avoid session interruptions during times of congestion that would otherwise cause dropped iSCSI packets. • iSCSI DCBx TLVs are supported.
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.
including jumbo frames and flow-control on all ports; no storm control and spanning-tree port fast to be enabled on the port of detection. After you execute the iscsi profile-compellent command, the following actions occur: • Jumbo frame size is set to the maximum for all interfaces on all ports and port-channels, if it is not already enabled. • Spanning-tree portfast is enabled on the interface. • Unicast storm control is disabled on the interface.
Default iSCSI Optimization Values The following table lists the default values for the iSCSI optimization feature. Table 44. iSCSI Optimization Defaults Parameter Default Value iSCSI Optimization global setting Disabled. iSCSI CoS mode (802.1p priority queue mapping) dot1p priority 4 without the remark setting when you enable iSCSI. If you do not enable iSCSI, this feature is disabled.
CONFIGURATION mode iscsi enable 3 For a DCB environment: Configure DCB and iSCSI. 4 Save the configuration on the switch. 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...
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 (Optional) Configures the advertised priority bitmap in iSCSI application TLVs. LLDP CONFIGURATION mode [no] iscsi priority-bits.
Target: iqn.2001-05.com.equallogic:0-8a0906-0e70c2002-10a0018426a48c94-iom010 Initiator: iqn.1991-05.com.microsoft:win-x9l8v27yajg ISID: 400001370000 VLT PEER2 Session 0: -----------------------------------------------------------------------------------Target: iqn.2001-05.com.equallogic:0-8a0906-0f60c2002-0360018428d48c94-iom011 iqn.1991-05.com.microsoft:win-x9l8v27yajg ISID: 400001370000 The following example shows the show iscsi session detailed command.
24 Intermediate System to Intermediate System The intermediate system to intermediate system (IS-IS) protocol that uses a shortest-path-first algorithm. Dell EMC Networking supports both IPv4 and IPv6 versions of IS-IS.
• 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 (47.0005.0001) are the area address. The system portion is 000c.000a.4321 and the last byte is always 0. Figure 56.
Interface Support MT IS-IS is supported on physical Ethernet interfaces, physical synchronous optical network technologies (SONET) interfaces, portchannel interfaces (static and dynamic using LACP), and virtual local area network (VLAN) interfaces. Adjacencies Adjacencies on point-to-point interfaces are formed as usual, where IS-IS routers do not implement MT extensions.
IPv6 Reachability and IPv6 Interface Address. Also, a new IPv6 protocol identifier has also been included in the supported TLVs. The new TLVs use the extended metrics and up/down bit semantics. Multi-topology IS-IS adds TLVs: • MT TLV — contains one or more Multi-Topology IDs in which the router participates. This TLV is included in IIH and the first fragment of an LSP. • MT Intermediate Systems TLV — appears for every topology a node supports.
Configuration Tasks for IS-IS The following describes the configuration tasks for IS-IS. • Enabling IS-IS • Configure Multi-Topology IS-IS (MT IS-IS) • Configuring IS-IS Graceful Restart • Changing LSP Attributes • Configuring the IS-IS Metric Style • Configuring IS-IS Cost • Changing the IS-Type • Controlling Routing Updates • Configuring Authentication Passwords • Setting the Overload Bit • Debugging IS-IS Enabling IS-IS By default, IS-IS is not enabled.
4 • For a 25-Gigabit Ethernet interface, enter the keyword twentyFiveGigE then the slot/port/subport information. • For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port/subport information. • For a 50-Gigabit Ethernet interface, enter the keyword fiftyGigE then the slot/port/subport information. • For a 100-Gigabit Ethernet interface, enter the keyword hundredGigE then the slot/port information.
Distance: 115 Generate narrow metrics: Accept narrow metrics: Generate wide metrics: Accept wide metrics: DellEMC# level-1-2 level-1-2 none none To view IS-IS protocol statistics, use the show isis traffic command in EXEC Privilege mode.
Use this command for IPv6 route computation only when you enable multi-topology. If using single-topology mode, to apply to both IPv4 and IPv6 route computations, use the spf-interval command in CONFIG ROUTER ISIS mode. 4 Implement a wide metric-style globally. ROUTER ISIS AF IPV6 mode isis ipv6 metric metric-value [level-1 | level-2 | level-1-2] To configure wide or wide transition metric style, the cost can be between 0 and 16,777,215.
ROUTER-ISIS mode graceful-restart t3 {adjacency | manual seconds} • 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.
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 DellEMC# Changing LSP Attributes IS-IS routers flood link state PDUs (LSPs) to exchange routing information.
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. If you configure wide or wide transition metric style, the cost can be a number between 0 and 16,777,215.
Distance: 115 Generate narrow metrics: Accept narrow metrics: Generate wide metrics: Accept wide metrics: DellEMC# level-1-2 level-1-2 none none Configuring the IS-IS Cost When you change from one IS-IS metric style to another, the IS-IS metric value could be affected. For each interface with IS-IS enabled, you can assign a cost or metric that is used in the link state calculation. To change the metric or cost of the interface, use the following commands. • Assign an IS-IS metric.
Changing the IS-Type To change the IS-type, use the following commands. You can configure the system to act as a Level 1 router, a Level 1-2 router, or a Level 2 router. To change the IS-type for the router, use the following commands. • Configure IS-IS operating level for a router. ROUTER ISIS mode is-type {level-1 | level-1-2 | level-2-only} • Default is level-1-2. Change the IS-type for the IS-IS process.
• For a 100-Gigabit Ethernet interface, enter the keyword hundredGigE 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 VLAN interface, enter the keyword vlan then a number from 1 to 4094. Distribute Routes Another method of controlling routing information is to filter the information through a prefix list.
Applying IPv6 Routes To apply prefix lists to incoming or outgoing IPv6 routes, use the following commands. NOTE: These commands apply to IPv6 IS-IS only. To apply prefix lists to IPv4 routes, use ROUTER ISIS mode, previously shown. • Apply a configured prefix list to all incoming IPv6 IS-IS routes.
ROUTER ISIS mode 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.
• metric value: the range is from 0 to 16777215. The default is 0. • match external: the range is 1 or 2. • match internal • metric-type: external or internal. • map-name: name of a configured route map. To view the IS-IS configuration globally (including both IPv4 and IPv6 settings), use the show running-config isis command in EXEC Privilege mode. To view the current IPv4 IS-IS configuration, use the show config command in ROUTER ISIS mode.
ROUTER ISIS mode no set-overload-bit Example of Viewing the Overload Bit Setting When the bit is set, a 1 is placed in the OL column in the show isis database command output. The overload bit is set in both the Level-1 and Level-2 database because the IS type for the router is Level-1-2. DellEMC#show isis database IS-IS Level-1 Link State Database LSPID LSP Seq Num LSP Checksum B233.00-00 0x00000003 0x07BF eljefe.00-00 * 0x0000000A 0xF963 eljefe.01-00 * 0x00000001 0x68DF eljefe.
• View sent and received LSPs. EXEC Privilege mode debug isis update-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. Dell EMC Networking OS displays debug messages on the console. To view which debugging commands are enabled, use the show debugging command in EXEC Privilege mode.
Maximum Values in the Routing Table IS-IS metric styles support different cost ranges for the route. The cost range for the narrow metric style is 0 to 1023, while all other metric styles support a range of 0 to 0xFE000000. Change the IS-IS Metric Style in One Level Only By default, the IS-IS metric style is narrow. When you change from one IS-IS metric style to another, the IS-IS metric value (configured with the isis metric command) could be affected.
Beginning Metric Style Final Metric Style Resulting IS-IS Metric Value narrow transition transition original value wide transition wide original value wide transition narrow default value (10) if the original value is greater than 63. A message is sent to the console. 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).
Level-1 Metric Style Level-2 Metric Style Resulting Metric Value wide transition truncated 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
Figure 57. 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. DellEMC(conf-if-te-3/17/1)#show config ! interface TenGigabitEthernet 3/17/1 ip address 24.3.1.
exit-address-family DellEMC(conf-router_isis)# DellEMC(conf-if-te-3/17/1)#show config ! interface TenGigabitEthernet 3/17/1 ipv6 address 24:3::1/76 ipv6 router isis no shutdown DellEMC(conf-if-te-3/17/1)# DellEMC(conf-router_isis)#show config ! router isis net 34.0000.0000.AAAA.
25 In-Service Software Upgrade This chapter deals with In-Service Software Upgrade (ISSU) and its dependencies. Topics: • • • • • • • • • ISSU Introduction Fastboot 2.0 (Zero Loss Upgrade) L2 ISSU L3 ISSU CoPP Mirroring flow control packets PFC QoS Tunnel Configuration ISSU Introduction In-service software upgrades (ISSU), also known as warmboot or fastboot 2.0, allow Dell EMC Networking to address software bugs and add new features to switches and routers without interrupting network availability.
and traffic will be treated seamlessly, during reload. After the reload is complete, the running-config and startup-config will be compared and if there is a difference, the device will be programmed based on the startup-config. L2 ISSU This section deals with L2 ISSU related information.
CoPP Control Plane Policing (CoPP) in Dell EMC Networking OS provides a method for protecting CPU bound control plane packets by policing packets punted to CPU with a specified rate and from undesired or malicious traffic.
and if there is a difference, the device will be programmed based on the startup-config. If tunnel keepalive is configured over the tunnel interface then tunnel keepalive threshold should be set to 90 seconds.
26 Link Aggregation Control Protocol (LACP) A link aggregation group (LAG), referred to as a port channel by the Dell EMC Networking OS, can provide both load-sharing and port redundancy across line cards. You can enable LAGs as static or dynamic. Introduction to Dynamic LAGs and LACP A link aggregation group (LAG), referred to as a port channel by Dell EMC Networking OS, can provide both load-sharing and port redundancy across line cards. You can enable LAGs as static or dynamic.
LACP Modes Dell EMC Networking OS provides three modes for configuration of LACP — Off, Active, and Passive. • Off — In this state, an interface is not capable of being part of a dynamic LAG. LACP does not run on any port that is configured to be in this state. • Active — In this state, the interface is said to be in the “active negotiating state.” LACP runs on any link that is configured to be in this state.
The default is 32768. LACP Configuration Tasks The following configuration tasks apply to LACP. • Creating a LAG • Configuring the LAG Interfaces as Dynamic • Setting the LACP Long Timeout • Monitoring and Debugging LACP • Configuring Shared LAG State Tracking Creating a LAG To create a dynamic port channel (LAG), use the following command. First you define the LAG and then the LAG interfaces. • Create a dynamic port channel (LAG).
DellEMC(conf)#interface TenGigabitethernet 4/15/1 DellEMC(conf-if-te-4/15/1)#no shutdown DellEMC(conf-if-te-4/15/1)#port-channel-protocol lacp DellEMC(conf-if-te-4/15/1-lacp)#port-channel 32 mode active ...
• Debug LACP, including configuration and events. EXEC mode [no] debug lacp [config | events | pdu [in | out | [interface [in | out]]]] Shared LAG State Tracking Shared LAG state tracking provides the flexibility to bring down a port channel (LAG) based on the operational state of another LAG. At any time, only two LAGs can be a part of a group such that the fate (status) of one LAG depends on the other LAG.
Example of LAGs in the Same Failover Group DellEMC#config DellEMC(conf)#port-channel failover-group DellEMC(conf-po-failover-grp)#group 1 port-channel 1 port-channel 2 To view the failover group configuration, use the show running-configuration po-failover-group command. DellEMC#show running-config po-failover-group ! port-channel failover-group group 1 port-channel 1 port-channel 2 As shown in the following illustration, LAGs 1 and 2 are members of a failover group.
Important Points about Shared LAG State Tracking The following is more information about shared LAG state tracking. • • • • • This feature is available for static and dynamic LAGs. Only a LAG can be a member of a failover group. You can configure shared LAG state tracking on one side of a link or on both sides. 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.
Port is part of Port-channel 10 Hardware is DellEMCEth, address is 00:01:e8:06:95:c0 Current address is 00:01:e8:06:95:c0 Interface Index is 109101113 Port will not be disabled on partial SFM failure Internet address is not set MTU 1554 bytes, IP MTU 1500 bytes LineSpeed 10000 Mbit, Mode full duplex, Slave Flowcontrol rx on tx on ARP type: ARPA, ARP Timeout 04:00:00 Last clearing of "show interface" counters 00:02:11 Queueing strategy: fifo Input statistics: 132 packets, 163668 bytes 0 Vlans 0 64-byte pkts,
Figure 61.
Figure 62.
Figure 63.
Summary of the LAG Configuration on Bravo Bravo(conf-if-te-3/21/1)#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 tengig 3/21/1 Bravo(conf)#no ip address Bravo(conf)#no switchport Bravo(conf)#shutdown Bravo(conf-if-te-3/21/1)#port-channel-protocol lacp Bravo(conf-if-te-3/21/1-lacp)#port-channel 10 mode activ
Figure 64.
Figure 65.
Figure 66. 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.
27 Layer 2 This chapter describes the Layer 2 features supported on the device. Manage the MAC Address Table You can perform the following management tasks in 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.
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.
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. NOTE: The CAM-check failure message beginning in Dell EMC Networking OS version 8.3.1.0 is different from versions 8.2.1.
When you enable sticky mac on an interface, dynamically-learned MAC addresses do not age, even if you enabled mac-learninglimit dynamic. If you configured mac-learning-limit and mac-learning-limit dynamic and you disabled sticky MAC, any dynamically-learned MAC addresses ages. mac learning-limit station-move The mac learning-limit station-move command allows a MAC address already in the table to be learned from another interface.
Setting Station Move Violation Actions no-station-move is the default behavior. You can configure the system to take an action if a station move occurs using one the following options with the mac learning-limit command. To display a list of interfaces configured with MAC learning limit or station move violation actions, use the following commands. • Generate a system log message indicating a station move. INTERFACE mode station-move-violation log • Shut down the first port to learn the MAC address.
Disabling MAC Address Learning on the System You can configure the system to not learn MAC addresses from LACP and LLDP BPDUs. To disable source MAC address learning from LACP and LLDP BPDUs, follow this procedure: • Disable source MAC address learning from LACP BPDUs. CONFIGURATION mode mac-address-table disable-learning lacp • Disable source MAC address learning from LLDP BPDUs. CONFIGURATION mode mac-address-table disable-learning lldp • Disable source MAC address learning from LACP and LLDP BPDUs.
NOTE: If you have configured the no mac-address-table station-move refresh-arp command, traffic continues to be forwarded to the failed NIC until the ARP entry on the switch times out. Figure 68.
Figure 69. 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. Initially, the primary interface is active and transmits traffic and the backup interface remains down. If the primary fails for any reason, the backup transitions to an active Up state. If the primary interface fails and later comes back up, it remains as the backup interface for the redundant pair.
Important Points about Configuring Redundant Pairs • • • • You may not configure any interface to be a backup for more than one interface, no interface can have more than one backup, and a backup interface may not have a backup interface. The active or backup interface may not be a member of a LAG. The active and standby do not have to be of the same type (1G, 10G, and so on). You may not enable any Layer 2 protocol on any interface of a redundant pair or to ports connected to them.
DellEMC#show interfaces switchport backup Interface Status Paired Interface Port-channel 1 Active Port-chato mannel 2 Port-channel 2 Standby Port-channel 1 DellEMC# Status Standby Active DellEMC(conf-if-po-1)#switchport backup interface tengigabitethernet 1/2/1 Apr 9 00:16:29: %STKUNIT0-M:CP %IFMGR-5-L2BKUP_WARN: Do not run any Layer2 protocols on Po 1 and Te 1/2/1 DellEMC(conf-if-po-1)# Far-End Failure Detection Far-end failure detection (FEFD) is a protocol that senses remote data link errors in a netw
FEFD State Changes FEFD has two operational modes, Normal and Aggressive. When you enable Normal mode on an interface and a far-end failure is detected, no intervention is required to reset the interface to bring it back to an FEFD operational state. When you enable Aggressive mode on an interface in the same state, manual intervention is required to reset the interface.
Configuring FEFD You can configure FEFD for all interfaces from CONFIGURATION mode, or on individual interfaces from INTERFACE mode. To enable FEFD globally on all interfaces, use the following command. • Enable FEFD globally on all interfaces. CONFIGURATION mode fefd-global To report interval frequency and mode adjustments, use the following commands. 1 Setup two or more connected interfaces for Layer 2 or Layer 3.
fefd [mode {aggressive | normal}] • Disable FEFD protocol on one interface. INTERFACE mode fefd disable Disabling an interface shuts down all protocols working on that interface’s connected line. It does not delete your previous FEFD configuration which you can enable again at any time. 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.
2w1d22h: %RPM0-P:CP %IFMGR-5-INACTIVE: Changed Vlan interface state to inactive: Vl 1 2w1d22h : FEFD state on Te 4/1/1 changed from Bi-directional to Unknown DellEMC#debug fefd packets DellEMC#2w1d22h : FEFD packet sent via interface Te 1/1/1 Sender state -- Bi-directional Sender info -- Mgmt Mac(00:01:e8:14:89:25), Slot-Port-Subport(Te 1/1/1) Peer info -- Mgmt Mac (00:01:e8:14:89:25), Slot-Port-Subport(Te 4/1/1) Sender hold time -- 3 (second) 2w1d22h : FEFD packet received on interface Te 4/1/1 Sender stat
28 Link Layer Discovery Protocol (LLDP) This chapter describes how to configure and use the link layer discovery protocol (LLDP). 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 51. Type, Length, Value (TLV) Types Type TLV Description 0 End of LLDPDU Marks the end of a 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 73. 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 EMC Networking system to advertise any or all of these TLVs. Table 52. Optional TLV Types Type TLV Description 4 Port description A user-defined alphanumeric string that describes the port. Dell EMC Networking OS does not currently support this TLV.
Type TLV Description in the Dell EMC Networking OS implementation of LLDP, but is available and mandatory (non-configurable) in the LLDPMED implementation. 127 Link Aggregation Indicates whether the link is capable of being aggregated, whether it is currently in a LAG, and the port identification of the LAG. Dell EMC Networking OS does not currently support this TLV. 127 Maximum Frame Size Indicates the maximum frame size capability of the MAC and PHY.
Type SubType TLV Description • LLDP device class 127 2 Network Policy Indicates the application type, VLAN ID, Layer 2 Priority, and DSCP value. 127 3 Location Identification Indicates that the physical location of the device expressed in one of three possible formats: • • • 127 4 Inventory Management TLVs Implementation of this set of TLVs is optional in LLDP-MED devices. None or all TLVs must be supported. Dell EMC Networking OS does not currently support these TLVs.
When you enable LLDP-MED in Dell EMC Networking OS (using the advertise med command), the system begins transmitting this TLV. Figure 74. LLDP-MED Capabilities TLV Table 54. Dell EMC Networking OS LLDP-MED Capabilities Bit Position TLV Dell EMC 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 55.
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 56.
• Configuring LLDPDU Intervals • Configuring Transmit and Receive Mode • Configuring a Time to Live • Debugging LLDP Important Points to Remember • LLDP is enabled by default. • Dell EMC Networking systems support up to eight neighbors per interface. • Dell EMC 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.
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.
LLDP-MANAGEMENT-INTERFACE mode. management-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.
Figure 76. Configuring LLDP Storing and Viewing Unrecognized LLDP TLVs Dell EMC Networking OS provides support to store unrecognized (reserved and organizational specific) LLDP TLVs. Also, support is extended to retrieve the stored unrecognized TLVs using SNMP. When the incoming TLV from LLDP neighbors is not recognized, the TLV is categorized as unrecognized TLV.
NOTE: The system increments the TLV discard counter and does not store unrecognized LLDP TLV information in following scenarios: • If there are multiple TLVs with the same information is received • If DCBX is down on the receiving interface The organizational specific TLV list is limited to store 256 entries per neighbor. If TLV entries are more than 256, then the oldest entry (of that neighbor) in the list is replaced.
protocol lldp DellEMC(conf-if-te-1/31/1-lldp)# Viewing Information Advertised by Adjacent LLDP Neighbors 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.
Remote TTL: 120 Information valid for next 43 seconds Time since last information change of this neighbor: 00:01:17 UnknownTLVList: ( 9, 4) ( 10, 4) ( 11, 4) ( 12, 4) ( 13, 4) ( 14, 4) ( 15, 4) ( 19, 4) ( 20, 4) ( 21, 4) ( 22, 4) ( 23, 4) ( 24, 4) ( 25, 4) ( 29, 4) ( 30, 4) ( 31, 4) ( 32, 4) ( 33, 4) ( 34, 4) ( 35, 4) ( 39, 4) ( 40, 4) ( 41, 4) ( 42, 4) ( 43, 4) ( 44, 4) ( 45, 4) ( 49, 4) ( 50, 4) ( 51, 4) ( 52, 4) ( 53, 4) ( 54, 4) ( 55, 4) ( 59, 4) ( 60, 4) ( 61, 4) ( 62, 4) ( 63, 4) ( 64, 4) ( 65, 4) ( 6
• Configure a non-default transmit interval.
R1(conf-lldp)#mode ? rx Rx only tx Tx only R1(conf-lldp)#mode tx 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 mode tx no disable R1(conf-lldp)#no mode 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 no disable R1(conf
Debugging LLDP You can view the TLVs that your system is sending and receiving. To view the TLVs, use the following commands. • • View a readable version of the TLVs. debug lldp brief View a readable version of the TLVs plus a hexadecimal version of the entire LLDPDU, including unrecognized TLVs. debug lldp detail To stop viewing the LLDP TLVs sent and received by the system, use the no debug lldp command. Figure 77.
Dec Dec Dec 4 22:38:29 : 40 4 22:38:29 : TLV: UNKNOWN TLV, Type: 125 Len: 1, Value: @ 4 22:38:29 : TLV: ENDOFPDU, Len: 0 Relevant Management Objects Dell EMC 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 57.
Table 58.
Table 59. LLDP 802.
TLV Sub-Type TLV Name TLV Variable Tagged Flag VLAN ID L2 Priority DSCP Value 3 Location Identifier Location Data Format Location ID Data System LLDP-MED MIB Object Remote lldpXMedLocMediaPolicyUn known Local lldpXMedLocMediaPolicyTa gged Remote lldpXMedLocMediaPolicyTa gged Local lldpXMedLocMediaPolicyVl anID Remote lldpXMedRemMediaPolicyV lanID Local lldpXMedLocMediaPolicyPri ority Remote lldpXMedRemMediaPolicyP riority Local lldpXMedLocMediaPolicyDs cp Remote lldpXMedRemMedi
29 Microsoft Network Load Balancing 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 Multicast NLB mode, the data forwards to all the servers based on the port specified using the following Layer 2 multicast command in CONFIGURATION MODE: mac-address-table static multicast vlan output-range , Limitations of the NLB Feature The following limitations apply to switches on which you configure NLB: • The NLB Unicast mode uses switch flooding to transmit all packets to all the servers that are part of the VLAN.
• Enter the ip vlan-flooding command to specify that all Layer 3 unicast routed data traffic going through a VLAN member port floods across all the member ports of that VLAN. CONFIGURATION mode ip vlan-flooding There might be some ARP table entries that are resolved through ARP packets, which had the Ethernet MAC SA different from the MAC information inside the ARP packet. This unicast data traffic flooding occurs only for those packets that use these ARP entries.
30 Multicast Source Discovery Protocol (MSDP) Multicast source discovery protocol (MSDP) is supported on Dell EMC 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).
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 79.
With Anycast RP, all the RPs are configured to be MSDP peers of each other. When a source registers with one RP, an SA message is sent to the other RPs informing them that there is an active source for a particular multicast group. The result is that each RP is aware of the active sources in the area of the other RPs. If any of the RPs fail, IP routing converges and one of the RPs becomes the active RP in more than one area. New sources register with the backup RP.
Figure 80.
Figure 81.
Figure 82.
Figure 83. 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. CONFIGURATION mode ip msdp peer connect-source Examples of Configuring and Viewing MSDP R3(conf)#ip multicast-msdp R3(conf)#ip msdp peer 192.168.0.
R3(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). The system does not create entries in the multicast routing table until there is a local receiver for the corresponding multicast group. R3#show ip msdp peer Peer Addr: 192.168.0.1 Local Addr: 192.168.0.
show ip msdp sa-limit If the total number of active sources is already larger than the limit when limiting is applied, the sources that are already in Dell EMC Networking OS are not discarded. To enforce the limit in such a situation, use the clear ip msdp sa-cache command to clear all existing entries. Clearing the Source-Active Cache To clear the source-active cache, use the following command. • Clear the SA cache of all, local, or rejected entries, or entries for a specific group.
Figure 84.
Figure 85.
Figure 86. 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.
GroupAddr 229.0.50.2 229.0.50.3 229.0.50.4 SourceAddr 24.0.50.2 24.0.50.3 24.0.50.4 RPAddr 200.0.0.50 200.0.0.50 200.0.0.50 LearnedFrom 10.0.50.2 10.0.50.2 10.0.50.2 DellEMC#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 24.0.50.65 200.0.1.50 00:33:18 229.0.50.66 24.0.50.66 200.0.1.50 Expire 73 73 73 UpTime 00:13:49 00:13:49 00:13:49 LearnedFrom 10.0.50.
R1_E600(conf)#do show ip msdp sa-cache R1_E600(conf)#do show ip msdp sa-cache rejected-sa MSDP Rejected SA Cache 1 rejected SAs received, cache-size 1000 UpTime GroupAddr SourceAddr RPAddr LearnedFrom 00:02:20 239.0.0.1 10.11.4.2 192.168.0.1 local Reason Redistribute Preventing MSDP from Caching a Remote Source To prevent MSDP from caching a remote source, use the following commands. 1 OPTIONAL: Cache sources that the SA filter denies in the rejected SA cache.
Example of Verifying the System is not Advertising Local Sources In the following example, R1 stops advertising source 10.11.4.2. Because it is already in the SA cache of R3, the entry remains there until it expires. [Router 1] R1(conf)#do show run msdp ! ip multicast-msdp ip msdp peer 192.168.0.3 connect-source Loopback 0 ip msdp sa-filter out 192.168.0.3 list mylocalfilter R1(conf)#do show run acl ! ip access-list extended mylocalfilter seq 5 deny ip host 239.0.0.1 host 10.11.4.
Output (S,G) filter: none [Router 1] R1(conf)#do show ip msdp peer Peer Addr: 192.168.0.3 Local Addr: 0.0.0.0(0) Connect Source: Lo 0 State: Inactive Up/Down Time: 00:00:03 Timers: KeepAlive 30 sec, Hold time 75 sec SourceActive packet count (in/out): 0/0 SAs learned from this peer: 0 SA Filtering: Clearing Peer Statistics To clear the peer statistics, use the following command. • Reset the TCP connection to the peer and clear all peer statistics.
03:17:10 : MSDP-0: Peer 192.168.0.3, 03:17:27 : MSDP-0: Peer 192.168.0.3, Input (S,G) filter: none Output (S,G) filter: none rcvd Keepalive msg sent Source Active msg MSDP with Anycast RP Anycast RP uses MSDP with PIM-SM to allow more than one active group to use RP mapping.
Figure 87. MSDP with Anycast RP 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.
4 Peer each RP with every other RP using MSDP, specifying the unique Loopback address as the connect-source. CONFIGURATION mode ip msdp peer 5 Advertise the network of each of the unique Loopback addresses throughout the network. ROUTER OSPF mode network Reducing Source-Active Message Flooding RPs flood source-active messages to all of their peers away from the RP.
interface Loopback 1 ip address 192.168.0.11/32 no shutdown ! router ospf 1 network 10.11.2.0/24 area 0 network 10.11.1.0/24 area 0 network 10.11.3.0/24 area 0 network 192.168.0.11/32 area 0 ! ip multicast-msdp ip msdp peer 192.168.0.3 connect-source Loopback 1 ip msdp peer 192.168.0.22 connect-source Loopback 1 ip msdp mesh-group AS100 192.168.0.22 ip msdp originator-id Loopback 1! ip pim rp-address 192.168.0.1 group-address 224.0.0.
The following example shows an R3 configuration for MSDP with Anycast RP. ip multicast-routing ! interface TenGigabitEthernet 3/21/1 ip pim sparse-mode ip address 10.11.0.32/24 no shutdown interface TenGigabitEthernet 3/41/1 ip pim sparse-mode ip address 10.11.6.34/24 no shutdown ! interface Loopback 0 ip pim sparse-mode ip address 192.168.0.3/32 no shutdown ! router ospf 1 network 10.11.6.0/24 area 0 network 192.168.0.
interface Loopback 0 ip pim sparse-mode ip address 192.168.0.1/32 no shutdown ! router ospf 1 network 10.11.2.0/24 area 0 network 10.11.1.0/24 area 0 network 192.168.0.1/32 area 0 network 10.11.3.0/24 area 0 ! ip multicast-msdp ip msdp peer 192.168.0.3 connect-source Loopback 0 ! ip pim rp-address 192.168.0.1 group-address 224.0.0.0/4 MSDP Sample Configuration: R2 Running-Config ip multicast-routing ! interface TenGigabitEthernet 1/1/1 ip pim sparse-mode ip address 10.11.4.
ip address 10.11.6.34/24 no shutdown ! interface ManagementEthernet 1/1 ip address 10.11.80.3/24 no shutdown ! interface Loopback 0 ip pim sparse-mode ip address 192.168.0.3/32 no shutdown ! router ospf 1 network 10.11.6.0/24 area 0 network 192.168.0.3/32 area 0 redistribute static redistribute connected redistribute bgp 200 ! router bgp 200 redistribute ospf 1 neighbor 192.168.0.2 remote-as 100 neighbor 192.168.0.2 ebgp-multihop 255 neighbor 192.168.0.2 update-source Loopback 0 neighbor 192.168.0.
31 Multiple Spanning Tree Protocol (MSTP) Multiple spanning tree protocol (MSTP) — specified in IEEE 802.1Q-2003 — is a rapid spanning tree protocol (RSTP)-based spanning tree variation that improves 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. Protocol Overview MSTP — specified in IEEE 802.
• Enable Multiple Spanning Tree Globally • Adding and Removing Interfaces • Creating Multiple Spanning Tree Instances • Influencing MSTP Root Selection • Interoperate with Non-Dell Bridges • Changing the Region Name or Revision • Modifying Global Parameters • Modifying the Interface Parameters • Configuring an EdgePort • Flush MAC Addresses after a Topology Change • MSTP Sample Configurations • Debugging and Verifying MSTP Configurations Spanning Tree Variations The Dell EMC Networki
Related Configuration Tasks The following are the related configuration tasks for MSTP.
• spanning-tree 0 To remove an interface from the MSTP topology, use the no spanning-tree 0 command. Creating Multiple Spanning Tree Instances To create multiple spanning tree instances, use the following command. A single MSTI provides no more benefit than RSTP. To take full advantage of MSTP, create multiple MSTIs and map VLANs to them. • Create an MSTI. PROTOCOL MSTP mode msti Specify the keyword vlan then the VLANs that you want to participate in the MSTI.
Port path cost 20000, Port priority 128, Port Identifier 128.384 Designated root has priority 32768, address 0001.e806.953e Designated bridge has priority 32768, address 0001.e809.c24a Designated port id is 128.384, designated path cost 20000 Number of transitions to forwarding state 1 BPDU (MRecords): sent 39291, received 7547 The port is not in the Edge port mode DellEMC#show spanning-tree msti 1 MSTI 1 VLANs mapped 100 Root Identifier has priority 32768, Address 0001.e806.
MSTI 1 VLAN 100 MSTI 2 VLAN 200,300 MSTI 2 bridge-priority 0 Interoperate with Non-Dell Bridges Dell EMC Networking OS supports only one MSTP region. A region is a combination of three unique qualities: • Name is a mnemonic string you assign to the region. The default region name is null. • Revision is a 2-byte number. The default revision number OS is 0. • VLAN-to-instance mapping is the placement of a VLAN in an MSTI.
NOTE: Dell EMC Networking recommends that only experienced network administrators change MSTP parameters. Poorly planned modification of MSTP parameters can negatively affect network performance. To change the MSTP parameters, use the following commands on the root bridge. 1 Change the forward-delay parameter. PROTOCOL MSTP mode forward-delay seconds The range is from 4 to 30. The default is 15 seconds. 2 Change the hello-time parameter.
Modifying the Interface Parameters You can adjust two interface parameters to increase or decrease the probability that a port becomes a forwarding port. • Port cost is a value that is based on the interface type. The greater the port cost, the less likely the port is selected to be a forwarding port. • 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.
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. The bpduguard shutdown-on-violation option causes the interface hardware to be shut down when it receives a BPDU.
MSTP Sample Configurations The running-configurations support the topology shown in the following illustration. The configurations are from Dell EMC Networking OS systems. Figure 89. 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.
no shutdown ! interface Vlan 200 no ip address tagged TenGigabitEthernet 1/21,31/1 no shutdown ! interface Vlan 300 no ip address tagged TenGigabitEthernet 1/21,31/1 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.
switchport no shutdown ! interface TenGigabitEthernet 2/31/1 no ip address switchport no shutdown ! (Step 3) interface Vlan 100 no ip address tagged TenGigabitEthernet 2/11/1,31/1 no shutdown ! interface Vlan 200 no ip address tagged TenGigabitEthernet 2/11/1,31/1 no shutdown ! interface Vlan 300 no ip address tagged TenGigabitEthernet 2/11/1,31/1 no shutdown Router 3 Running-Configuration This example uses the following steps: 1 Enable MSTP globally and set the region name and revision map MSTP instance
tagged TenGigabitEthernet 1/1/5/1,1/1/5/2 no shutdown (Step 1) protocol spanning-tree mstp no disable name Tahiti revision 123 MSTI 1 VLAN 100 MSTI 2 VLAN 200,300 ! (Step 2) interface TenGigabitEthernet 3/11/1 no ip address switchport no shutdown ! interface TenGigabitEthernet 3/21/1 no ip address switchport no shutdown ! (Step 3) interface Vlan 100 no ip address tagged TenGigabitEthernet 3/11/1,21/1 no shutdown ! interface Vlan 200 no ip address tagged TenGigabitEthernet 3/11/1,21/1 no shutdown ! interface
switchport protected 0 exit (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.
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. DellEMC#debug spanning-tree mstp bpdu MSTP debug bpdu is ON DellEMC# 4w0d4h : MSTP: Sending BPDU on Te 2/21/1 : ProtId: 0, Ver: 3, Bpdu Type: MSTP, Flags 0x6e CIST Root Bridge Id: 32768:0001.e806.953e, Ext Path Cost: 0 Regional Bridge Id: 32768:0001.e806.
32 Multicast Features 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 virtual routing and forwarding (VRFs).
Protocol Ethernet Address 01:00:5e:00:00:06 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 EMC Networking OS implementation of MTRACE is in accordance with IETF draft draft-fenner-traceroute-ipm. • Multicast is not supported on secondary IP addresses. • If you enable multicast routing, egress Layer 3 ACL is not applied to multicast data traffic. Multicast Policies The Dell EMC Networking OS supports multicast features for IPv4.
ip multicast-limit The range is from 1 to . The default is 4000. NOTE: The IN-L3-McastFib CAM partition stores multicast routes and is a separate hardware limit that exists per port-pipe. Any software-configured limit may supersede this hardware space limitation. The opposite is also true, the CAM partition might not be exhausted at the time the system-wide route limit is reached using the ip multicast-limit command.
Figure 90. Preventing a Host from Joining a Group The following table lists the location and description shown in the previous illustration. Table 63. Preventing a Host from Joining a Group — Description Location Description 1/21/1 • • • • Interface TenGigabitEthernet 1/21/1 ip pim sparse-mode ip address 10.11.12.1/24 no shutdown 1/31/1 • • • Interface TenGigabitEthernet 1/21/1 ip pim sparse-mode ip address 10.11.13.
Location Description • no shutdown 2/1/1 • • • • Interface TenGigabitEthernet 2/1/1 ip pim sparse-mode ip address 10.11.1.1/24 no shutdown 2/11/1 • • • • Interface TenGigabitEthernet 1/21/1 ip pim sparse-mode ip address 10.11.12.2/24 no shutdown 2/31/1 • • • • Interface TenGigabitEthernet 1/21/1 ip pim sparse-mode ip address 10.11.23.1/24 no shutdown 3/1/1 • • • • Interface TenGigabitEthernet 1/21/1 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 Setting a Threshold for Switching to the SPT The functionality to specify a threshold for switchover to the shortest path trees (SPTs) is available on the system.
Figure 91. Preventing a Source from Transmitting to a Group The following table lists the location and description shown in the previous illustration. Table 65. Preventing a Source from Transmitting to a Group — Description Location Description 1/21/1 • • • • Interface TenGigabitEthernet 1/21/1 ip pim sparse-mode ip address 10.11.12.1/24 no shutdown 1/31/1 • • • Interface TenGigabitEthernet 1/31/1 ip pim sparse-mode ip address 10.11.13.
Location Description • no shutdown 2/1/1 • • • • Interface TenGigabitEthernet 2/1/1 ip pim sparse-mode ip address 10.11.1.1/24 no shutdown 2/11/1 • • • • Interface TenGigabitEthernet 2/11/1 ip pim sparse-mode ip address 10.11.12.2/24 no shutdown 2/31/1 • • • • Interface TenGigabitEthernet 2/31 ip pim sparse-mode ip address 10.11.23.1/24 no shutdown 3/1/1 • • • • Interface TenGigabitEthernet 3/1/1 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 EMC 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.
Important Points to Remember • Destination address of the mtrace query message can be either a unicast or a multicast address. NOTE: When you use mtrace to trace a specific multicast group, the query is sent with the group's address as the destination. Retries of the query use the unicast address of the receiver. • When you issue an mtrace without specifying a group address (weak mtrace), the destination address is considered as the unicast address of the receiver.
• Forwarding code — error code as present in the response blocks • Source Network/Mask — source mask Example of the mtrace Command to View the Network Path The following is an example of tracing a multicast route. R1>mtrace 103.103.103.3 1.1.1.1 226.0.0.3 Type Ctrl-C to abort. Querying reverse path for source 103.103.103.3 to destination 1.1.1.1 via group 226.0.0.
The response data block filled in by the last-hop router contains a Forwarding code field. Forwarding code can be added at any node and is not restricted to the last hop router. This field is used to record error codes before forwarding the response to the next neighbor in the path towards the source. In a response data packet, the following error codes are supported: Table 67.
Scenario Output -4 103.103.103.3 --> Source ----------------------------------------------------------------- You can issue the mtrace command specifying the source multicast tree and multicast group without specifying the destination. Mtrace traces the complete path traversing through the multicast group to reach the source. The output displays the destination and the first hop (-1) as 0 to indicate any PIM enabled interface on the node. R1>mtrace 103.103.103.3 1.1.1.1 226.0.0.3 Type Ctrl-C to abort.
Scenario Output 103.103.103.0/24 -3 2.2.2.1 PIM 103.103.103.0/24 -4 103.103.103.3 --> Source ----------------------------------------------------------------- You can issue the mtrace command by providing the source and multicast information. However, if the multicast group is a shared group (*,G), then mtrace traces the path of the shared tree until it reaches the RP. The source mask field reflects the shared tree that is being used to trace the path.
Scenario Output -3 10.10.10.1 PIM No route default ----------------------------------------------------------------- If a multicast tree is not formed due to a configuration issue (for example, PIM is not enabled on one of the interfaces on the path), you can invoke a weak mtrace to identify the location in the network where the error has originated. R1>mtrace 6.6.6.6 4.4.4.5 Type Ctrl-C to abort.
Scenario Output -3 2.2.2.1 PIM 99.99.0.0/16 -4 * * * * ----------------------------------------------------------------- If there is no response for mtrace even after switching to expanded hop search, the command displays an error message. R1>mtrace 99.99.99.99 1.1.1.1 Type Ctrl-C to abort. While traversing the path from source to destination, if the mtrace packet exhausts the maximum buffer size of the packet, then NO SPACE error is displayed in the output.
Scenario Output scenario, a corresponding error message is displayed. ---------------------------------------------------------------|Hop| OIF IP |Proto| Forwarding Code |Source Network/ Mask| ---------------------------------------------------------------0 4.4.4.5 --> Destination -1 4.4.4.4 PIM 6.6.6.0/24 -2 20.20.20.2 PIM 6.6.6.0/24 -3 10.10.10.1 PIM Wrong interface 6.6.6.0/24 ----------------------------------------------------------------R1>mtrace 6.6.6.6 4.4.4.5 Type Ctrl-C to abort.
33 Object Tracking IPv4 or IPv6 object tracking is available on Dell EMC Networking OS. Object tracking allows the Dell EMC Networking 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 EMC Networking OS release version 8.4.1.0, object tracking is supported only on VRRP.
Figure 92. 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 or IPv6 address and prefix-length. Optionally specify a tracked route 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.
Set Tracking Delays You can configure an optional UP and/or DOWN timer for each tracked object to set the time delay before a change in the state of a tracked object is communicated to clients. The configured time delay starts when the state changes from UP to DOWN or the opposite way. If the state of an object changes back to its former UP/DOWN state before the timer expires, the timer is cancelled and the client is not notified.
To configure object tracking on the status of a Layer 2 interface, use the following commands. 1 Configure object tracking on the line-protocol state of a Layer 2 interface. CONFIGURATION mode track object-id interface interface line-protocol Valid object IDs are from 1 to 500. 2 (Optional) Configure the time delay used before communicating a change in the status of a tracked interface. OBJECT TRACKING mode delay {[up seconds] [down seconds]} Valid delay times are from 0 to 180 seconds. The default is 0.
• The Layer 3 status of an IPv4 interface goes DOWN when its Layer 2 status goes down (for a Layer 3 VLAN, all VLAN ports must be down) or the IP address is removed from the routing table. For an IPv6 interface, a routing object only tracks the UP/DOWN status of the specified IPv6 interface (the track interface ipv6routing command). • The status of an IPv6 interface is UP only if the Layer 2 status of the interface is UP and the interface has a valid IPv6 address.
Track 103 Interface TenGigabitEthernet 1/11/1 ipv6 routing Description: Austin access point Track an IPv4/IPv6 Route You can create an object that tracks the reachability or metric of an IPv4 or IPv6 route. You specify the route to be tracked by its address and prefix-length values. Optionally, for an IPv4 route, you can enter a VRF instance name if the route is part of a VPN routing and forwarding (VRF) table. The next-hop address is not part of the definition of a tracked IPv4/ IPv6 route.
Tracking Route Reachability Use the following commands to configure object tracking on the reachability of an IPv4 or IPv6 route. To remove object tracking, use the no track object-id command. 1 Configure object tracking on the reachability of an IPv4 or IPv6 route. CONFIGURATION mode track object-id {ip route ip-address/prefix-len | ipv6 route ipv6-address/prefix-len} reachability [vrf vrf-name] Valid object IDs are from 1 to 500.
The following example configures object tracking on the reachability of an IPv6 route: DellEMC(conf)#track 105 ipv6 route 1234::/64 reachability DellEMC(conf-track-105)#delay down 5 DellEMC(conf-track-105)#description Headquarters DellEMC(conf-track-105)#end DellEMC#show track 105 Track 105 IPv6 route 1234::/64 reachability Description: Headquarters Reachability is Down (route not in route table) 2 changes, last change 00:03:03 Tracking a Metric Threshold Use the following commands to configure object trac
threshold metric {[up number] [down number]} The default UP threshold is 254. The routing state is UP if the scaled route metric is less than or equal to the UP threshold. The defult DOWN threshold is 255. The routing state is DOWN if the scaled route metric is greater than or equal to the DOWN threshold. 6 (Optional) Display the tracking configuration.
First-hop interface is TenGigabitEthernet 1/2/1 Tracked by: VRRP TenGigabitEthernet 2/30/1 IPv6 VRID 1 Track 3 IPv6 route 2050::/64 reachability Reachability is Up (STATIC) 5 changes, last change 00:02:16 First-hop interface is TenGigabitEthernet 1/2/1 Tracked by: VRRP TenGigabitEthernet 2/30/1 IPv6 VRID 1 Track 4 Interface TenGigabitEthernet 1/4/1 ip routing IP routing is Up 3 changes, last change 00:03:30 Tracked by: Example of the show track brief Command Router# show track brief ResId State 1 Resource
34 Open Shortest Path First (OSPFv2 and OSPFv3) Open shortest path first (OSPFv2 for IPv4) and OSPF version 3 (OSPF for IPv6) are supported on Dell EMC Networking OS. This chapter provides a general description of OSPFv2 (OSPF for IPv4) and OSPFv3 (OSPF for IPv6) as supported in the Dell EMC 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 93. Autonomous System Areas Area Types The backbone of the network is Area 0. It is also called Area 0.0.0.
• A not-so-stubby area (NSSA) can import AS external route information and send it to the backbone. It cannot receive external AS information from the backbone or other areas. • Totally stubby areas are referred to as no summary areas in the Dell EMC Networking OS. Networks and Neighbors As a link-state protocol, OSPF sends routing information to other OSPF routers concerning the state of the links between them. The state (up or down) of those links is important.
Figure 94. 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 7: External LSA — Routers in an NSSA do not receive external LSAs from ABRs, but are allowed to send external routing information for redistribution. They use Type 7 LSAs to tell the ABRs about these external routes, which the ABR then translates to Type 5 external LSAs and floods as normal to the rest of the OSPF network. • Type 8: Link LSA (OSPFv3) — This LSA carries the IPv6 address information of the local links.
Figure 95. Priority and Cost Examples OSPF with Dell EMC Networking OS The Dell EMC Networking OS supports up to 128,000 OSPF routes for OSPFv2. Dell EMC Networking OS version 9.4(0.0) and later support only one OSPFv2 process per VRF. Dell EMC Networking OS version 9.7(0.0) and later support OSPFv3 in VRF. Also, on OSPFv3, Dell EMC Networking OS supports only one OSPFv3 process per VRF. OSPFv2 and OSPFv3 can co-exist but you must configure them individually.
Graceful Restart When a router goes down without a graceful restart, there is a possibility for loss of access to parts of the network due to ongoing network topology changes. Additionally, LSA flooding and reconvergence can cause substantial delays. It is, therefore, desirable that the network maintains a stable topology if it is possible for data flow to continue uninterrupted.
Fast Convergence (OSPFv2, IPv4 Only) Fast convergence allows you to define the speeds at which LSAs are originated and accepted, and reduce OSPFv2 end-to-end convergence time. Dell EMC Networking OS allows you to accept and originate LSAs as soon as they are available to speed up route information propagation. NOTE: The faster the convergence, the more frequent the route calculations and updates. This impacts CPU utilization and may impact adjacency stability in larger topologies.
ACKs 2 (shown in bold) is printed only for ACK packets. The following example shows no change in the updated packets (shown in bold). ACKs 2 (shown in bold) is printed only for ACK packets. 00:10:41 : OSPF(1000:00): Rcv. v:2 t:5(LSAck) l:64 Acks 2 rid:2.2.2.2 aid:1500 chk:0xdbee aut:0 auk: keyid:0 from:Vl 1000 LSType:Type-5 AS External id:160.1.1.0 adv:6.1.0.0 seq:0x8000000c LSType:Type-5 AS External id:160.1.2.0 adv:6.1.0.0 seq:0x8000000c 00:10:41 : OSPF(1000:00): Rcv. v:2 t:5(LSAck) l:64 Acks 2 rid:2.2.2.
Examples of Setting and Viewing a Dead Interval In the following example, the dead interval is set at 4x the hello interval (shown in bold). DellEMC(conf)#int tengigabitethernet 2/2/1 DellEMC(conf-if-te-2/2/1)#ip ospf hello-interval 20 DellEMC(conf-if-te-2/2/1)#ip ospf dead-interval 80 DellEMC(conf-if-te-2/2/1)# In the following example, the dead interval is set at 4x the hello interval (shown in bold).
• Troubleshooting OSPFv2 1 Configure a physical interface. Assign an IP address, physical or Loopback, to the interface to enable Layer 3 routing. 2 Enable OSPF globally. Assign network area and neighbors. 3 Add interfaces or configure other attributes. 4 Set the time interval between when the switch receives a topology change and starts a shortest path first (SPF) calculation.
The OSPF process ID is the identifying number assigned to the OSPF process. The router ID is the IP address associated with the OSPF process. After the OSPF process and the VRF are tied together, the OSPF process ID cannot be used again in the system.
• 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 BDR, Priority 1 Designated Router (ID) 13.1.1.1, Interface address 10.2.3.2 Backup Designated Router (ID) 11.1.2.1, Interface address 10.2.3.1 Timer intervals configured, Hello 10, Dead 40, Wait 40, Retransmit 5 Hello due in 00:00:05 Neighbor Count is 1, Adjacent neighbor count is 1 Adjacent with neighbor 13.1.1.1 (Designated Router) DellEMC> Loopback interfaces also help the OSPF process.
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. Example of the show ip ospf database database-summary Command To view which LSAs are transmitted, use the show ip ospf database process-id database-summary command in EXEC Privilege mode. DellEMC#show ip ospf 34 database database-summary OSPF Router with ID (10.1.2.
Internet Address 10.1.2.100/24, Area 1.1.1.1 Process ID 34, Router ID 10.1.2.100, Network Type BROADCAST, Cost: 10 Transmit Delay is 1 sec, State DOWN, Priority 1 Designated Router (ID) 10.1.2.100, Interface address 0.0.0.0 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 13:39:46 Neighbor Count is 0, Adjacent neighbor count is 0 TenGigabitEthernet 2/1/1 is up, line protocol is down Internet Address 10.1.3.
Number of area in this router is 0, normal 0 stub 0 nssa 0 DellEMC# The following examples shows how to disable fast-convergence. DellEMC#(conf-router_ospf-1)#no fast-converge DellEMC#(conf-router_ospf-1)#ex DellEMC#(conf)#ex DellEMC##show ip ospf 1 Routing Process ospf 1 with ID 192.168.67.
• NOTE: You can configure a maximum of six digest keys on an interface. Of the available six digest keys, the switches select the MD5 key that is common. The remaining MD5 keys are unused. Change the priority of the interface, which is used to determine the Designated Router for the OSPF broadcast network. CONFIG-INTERFACE mode ip ospf priority number • • number: the range is from 0 to 255 (the default is 1). Change the retransmission interval between LSAs.
Configure a key that is a text string no longer than eight characters. • All neighboring routers must share password to exchange OSPF information. Set the authentication change wait time in seconds between 0 and 300 for the interface. CONFIG-INTERFACE mode ip ospf auth-change-wait-time seconds This setting is the amount of time OSPF has available to change its interface authentication type.
3 Configure the graceful restart role or roles that this OSPFv2 router performs. CONFIG-ROUTEROSPF- id mode graceful-restart role [helper-only | restart-only] Dell EMC Networking OS supports the following options: • Helper-only: the OSPFv2 router supports graceful-restart only as a helper router. • Restart-only: the OSPFv2 router supports graceful-restart only during unplanned restarts. By default, OSPFv2 supports both restarting and helper roles.
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.
• Have you enabled OSPF globally? • Is the OSPF process active on the interface? • Are adjacencies established correctly? • Are the interfaces configured for Layer 3 correctly? • Is the router in the correct area type? • Have the routes been included in the OSPF database? • Have the OSPF routes been included in the routing table (not just the OSPF database)? Some useful troubleshooting commands are: • show interfaces • show protocols • debug IP OSPF events and/or packets • show neighbor
Example of Viewing OSPF Configuration DellEMC#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 10.10.10.10 DellEMC# Sample Configurations for OSPFv2 The following configurations are examples for enabling OSPFv2. These examples are not comprehensive directions. They are intended to give you some guidance with typical configurations. You can copy and paste from these examples to your CLI.
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 3/1/1 ip address 10.1.13.3/24 no shutdown ! interface TenGigabitEthernet 3/2/1 ip address 10.2.13.3/24 no shutdown OSPF Area 0 — Te 2/1 and 2/2 router ospf 22222 network 192.168.100.0/24 area 0 network 10.2.21.
3 No-summary – To act as totally stubby area — NSSA area can be converted intoa totally stubby area to reduce the number of Type-3 LSAs. Once it is configured, NSSA ABR will inject Type-3 LSAs into the NSSA area for default routes. The remaining Type-3 LSAs are not allowed inside this area. Configuration Task List for OSPFv3 (OSPF for IPv6) This section describes the configuration tasks for Open Shortest Path First version 3 (OSPF for IPv6) on the switch.
Assigning IPv6 Addresses on an Interface To assign IPv6 addresses to an interface, use the following commands. 1 Assign an IPv6 address to the interface. CONF-INT-type slot/port mode ipv6 address ipv6 address IPv6 addresses are normally written as eight groups of four hexadecimal digits; separate each group by a colon (:). The format is A:B:C::F/128. 2 Bring up the interface.
• number: the IPv4 address. The format is A.B.C.D. NOTE: Enter the router-id for an OSPFv3 router as an IPv4 IP address. • Disable OSPF. CONFIGURATION mode no ipv6 router ospf process-id • Reset the OSPFv3 process. EXEC Privilege mode clear ipv6 ospf process 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.
• Area ID: a number or IP address assigned when creating the area. You can represent the area ID as a number from 0 to 65536 if you assign a dotted decimal format rather than an IP address. Configuring Passive-Interface To suppress the interface’s participation on an OSPFv3 interface, use the following command. This command stops the router from sending updates on that interface. • Specify whether some or all some of the interfaces are passive.
Configuring a Default Route To generate a default external route into the OSPFv3 routing domain, configure the following parameters. To specify the information for the default route, use the following command. • Specify the information for the default route.
When you enable the helper-reject role on an interface using the ipv6 ospf graceful-restart helper-reject command, you reconfigure OSPFv3 graceful restart to function in a restarting-only role. OSPFv3 does not participate in the graceful restart of a neighbor. NOTE: Enter the ipv6 ospf graceful-restart helper-reject command in Interface configuration mode. • Enable OSPFv3 graceful restart globally by setting the grace period (in seconds).
router-id 200.1.1.1 log-adjacency-changes graceful-restart grace-period 180 network 20.1.1.0/24 area 0 network 30.1.1.0/24 area 0 ! ipv6 router ospf 1 log-adjacency-changes graceful-restart grace-period 180 The following example shows the show ipv6 ospf database database-summary command. DellEMC#show ipv6 ospf database database-summary ! OSPFv3 Router with ID (200.1.1.
IPsec is a set of protocols developed by the internet engineering task force (IETF) to support secure exchange of packets at the IP layer. IPsec supports two encryption modes: transport and tunnel. • Transport mode — encrypts only the data portion (payload) of each packet, but leaves the header untouched. • Tunnel mode — is more secure and encrypts both the header and payload. On the receiving side, an IPsec-compliant device decrypts each packet.
• Both encryption and authentication are used. • IPsec security associations (SAs) are supported only in Transport mode (Tunnel mode is not supported). • ESP with null encryption is supported for authenticating only OSPFv3 protocol headers. • ESP with non-null encryption is supported for full confidentiality. • 3DES, DES, AES-CBC, and NULL encryption algorithms are supported; encrypted and unencrypted keys are supported.
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)).
The configuration of IPSec authentication on an interface-level takes precedence over an area-level configuration. If you remove an interface configuration, an area authentication policy that has been configured is applied to the interface. • Enable IPSec authentication for OSPFv3 packets in an area. CONF-IPV6-ROUTER-OSPF mode area-id authentication ipsec spi number {MD5 | SHA1} [key-encryption-type] key • area area-id: specifies the area for which OSPFv3 traffic is to be authenticated.
• • • authentication-algorithm: specifies the authentication algorithm to use for encryption. The valid values are MD5 or SHA1. • key: specifies the text string used in authentication. All neighboring OSPFv3 routers must share key to exchange information. For MD5 authentication, the key must be 32 hex digits (non-encrypted) or 64 hex digits (encrypted). For SHA-1 authentication, the key must be 40 hex digits (non-encrypted) or 80 hex digits (encrypted).
Policy name Policy refcount Inbound AH SPI Outbound AH SPI Inbound AH Key Outbound AH Key Transform set : : : : : : : OSPFv3-1-500 2 500 (0x1F4) 500 (0x1F4) bbdd96e6eb4828e2e27bc3f9ff541e43faa759c9ef5706ba8ed8bb5efe91e97e bbdd96e6eb4828e2e27bc3f9ff541e43faa759c9ef5706ba8ed8bb5efe91e97e ah-md5-hmac Crypto IPSec client security policy data Policy name : OSPFv3-0-501 Policy refcount : 1 Inbound ESP SPI : 501 (0x1F5) Outbound ESP SPI : 501 (0x1F5) Inbound ESP Auth Key : bbdd96e6eb4828e2e27bc3f9ff541e43faa759
Troubleshooting OSPFv3 The system provides several tools to troubleshoot OSPFv3 operation on the switch. This section describes typical, OSPFv3 troubleshooting scenarios. NOTE: The following troubleshooting section is meant to be a comprehensive list, but only to provide some examples of typical troubleshooting checks.
• 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.
35 Policy-based Routing (PBR) 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 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 on.
• Destination port • TCP Flags After you apply a redirect-list to an interface, all traffic passing through it is subjected to the rules defined in the redirect-list. Traffic is forwarded based on the following: • Next-hop addresses are verified. If the specified next hop is reachable, traffic is forwarded to the specified next-hop. • If the specified next-hops are not reachable, the normal routing table is used to forward the traffic.
• Apply a Redirect-list to an Interface using a Redirect-group PBR Exceptions (Permit) To create an exception to a redirect list, use thepermit command. Exceptions are used when a forwarding decision should be based on the routing table rather than a routing policy. The Dell EMC Networking OS assigns the first available sequence number to a rule configured without a sequence number and inserts the rule into the PBR CAM region next to the existing entries.
• number is the number in sequence to initiate this rule • ip-address is the Forwarding router’s address • tunnel is used to configure the tunnel settings • tunnel-id is used to redirect the traffic • track is used to track the object-id • track is to enable the tracking • FORMAT: A.B.C.
You can apply multiple rules to a single redirect-list. The rules are applied in ascending order, starting with the rule that has the lowest sequence number in a redirect-list displays the correct method for applying multiple rules to one list. Example: Creating Multiple Rules for a Redirect-List DellEMC(conf)#ip redirect-list test DellEMC(conf-redirect-list)#seq 10 redirect 10.1.1.2 ip 20.1.1.0/24 any DellEMC(conf-redirect-list)#seq 15 redirect 10.1.1.3 ip 20.1.1.
Example: Applying a Redirect-list to an Interface DellEMC(conf-if-te-1/1/1)#ip redirect-group xyz Example: Applying a Redirect-list to an Interface DellEMC(conf-if-te-1/1/1)#ip redirect-group DellEMC(conf-if-te-1/1/1)#ip redirect-group DellEMC(conf-if-te-1/1/1)#show config ! interface TenGigabitEthernet 1/1/1 no ip address ip redirect-group test ip redirect-group xyz shutdown DellEMC(conf-if-te-1/1/1)# DellEMC(conf-if-te-1/1/1)#ip redirect-group DellEMC(conf-if-te-1/1/1)#ip redirect-group test xyz test xy
[up], Next-hop reachable (via Po 7) [up], Next-hop reachable (via Te 1/18/1) [up], Next-hop reachable (via Te 1/19/1) , Track 200 , Track 200 , Track 200 Use the show ip redirect-list (without the list name) to display all the redirect-lists configured on the device. DellEMC#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.
Create the Redirect-List GOLD EDGE_ROUTER(conf-if-Te-2/23/1)#ip redirect-list GOLD EDGE_ROUTER(conf-redirect-list)#description Route GOLD traffic to ISP_GOLD. EDGE_ROUTER(conf-redirect-list)#direct 10.99.99.254 ip 192.168.1.0/24 any EDGE_ROUTER(conf-redirect-list)#redirect 10.99.99.254 ip 192.168.2.0/24 any EDGE_ROUTER(conf-redirect-list)# seq 15 permit ip any any EDGE_ROUTER(conf-redirect-list)#show config ! ip redirect-list GOLD description Route GOLD traffic to ISP_GOLD. seq 5 redirect 10.99.99.
View Redirect-List GOLD EDGE_ROUTER#show ip redirect-list IP redirect-list GOLD: Defined as: seq 5 redirect 10.99.99.254 ip 192.168.1.0/24 any, Next-hop reachable (via Te 3/23/1), ARP resolved seq 10 redirect 10.99.99.254 ip 192.168.2.
seq 15 redirect 42.1.1.2 track 3 udp 155.55.0.0/16 host 144.144.144.144, Track 3 [up], Nexthop reachable (via Vl 20) seq 20 redirect 42.1.1.2 track 3 udp any host 144.144.144.144, Track 3 [up], Next-hop reachable (via Vl 20) seq 25 redirect 43.1.1.2 track 4 ip host 7.7.7.7 host 144.144.144.
Apply the Redirect Rule to an Interface: DellEMC#configure terminal DellEMC(conf)#interface TenGigabitEthernet 2/28 DellEMC(conf-if-te-2/28)#ip redirect-group explicit_tunnel DellEMC(conf-if-te-2/28)#exit DellEMC(conf)#end Verify the Applied Redirect Rules: DellEMC#show ip redirect-list explicit_tunnel IP redirect-list explicit_tunnel: Defined as: seq 5 redirect tunnel 1 track 1 tcp 155.55.2.0/24 222.22.2.
36 PIM Sparse-Mode (PIM-SM) Protocol-independent multicast sparse-mode (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.
Refuse Multicast Traffic A host requesting to leave a multicast group sends an IGMP Leave message to the last-hop DR. If the host is the only remaining receiver for that group on the subnet, the last-hop DR is responsible for sending a PIM Prune message up the RPT to prune its branch to the RP. 1 After receiving an IGMP Leave message, the gateway removes the interface on which it is received from the outgoing interface list of the (*,G) entry.
ip multicast-routing Related Configuration Tasks The following are related PIM-SM configuration tasks. • Configuring S,G Expiry Timers • Configuring a Static Rendezvous Point • Configuring a Designated Router • Creating Multicast Boundaries and Domains Enable PIM-SM You must enable PIM-SM on each participating interface. 1 Enable multicast routing on the system. CONFIGURATION mode ip multicast-routing 2 Enable PIM-Sparse mode.
Outgoing interface list: TenGigabitEthernet 1/11/1 TenGigabitEthernet 2/13/1 (10.87.31.5, 192.1.2.1), uptime 00:01:24, expires 00:02:26, flags: FT Incoming interface: TenGigabitEthernet 2/11/1, RPF neighbor 0.0.0.0 Outgoing interface list: TenGigabitEthernet 1/11/1 TenGigabitEthernet 1/12/1 TenGigabitEthernet 2/13/1 --More-- Configuring S,G Expiry Timers By default, S, G entries expire in 210 seconds.
Configuring a Static Rendezvous Point The rendezvous point (RP) is a PIM-enabled interface on a router that acts as the root a group-specific tree; every group must have an RP. • Identify an RP by the IP address of a PIM-enabled or Loopback interface. ip pim rp-address Example of Viewing an RP on a Loopback Interface DellEMC#sh run int loop0 ! interface Loopback 0 ip address 1.1.1.1/32 ip pim sparse-mode no shutdown DellEMC#sh run pim ! ip pim rp-address 1.1.1.1 group-address 224.0.0.
• Change the interval at which a router sends hello messages. INTERFACE mode ip pim query-interval seconds • Display the current value of these parameter. EXEC Privilege mode show ip pim interface 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.
37 PIM Source-Specific Mode (PIM-SSM) PIM source-specific mode (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.
To display the source to which a group is mapped, use the show ip igmp ssm-map [group] command. If you use the group option, the command displays the group-to-source mapping even if the group is not currently in the IGMP group table. If you do not specify the group option, the display is a list of groups currently in the IGMP group table that has a group-to-source mapping. To display the list of sources mapped to a group currently in the IGMP group table, use the show ip igmp groups group detail command.
Electing an RP using the BSR Mechanism Every PIM router within a domain must map a particular multicast group address to the same RP. The group-to-RP mapping may be statically or dynamically configured. RFC 5059 specifies a dynamic, self-configuring method called the Bootstrap Router (BSR) mechanism, by which an RP is elected from a pool of RP candidates (C-RPs). Some routers within the domain are configured to be C-RPs.
ip pim [vrf vrf-name] rp-Candidate interface [priority] [acl-name] The specified acl-list is associated to the rp-candidate. NOTE: You can create the ACL list of multicast prefix using the ip access-list standard command.
38 Port Monitoring Port monitoring (also referred to as mirroring ) allows you to monitor ingress and/or egress traffic on specified ports. The mirrored traffic can be sent to a port to which a network analyzer is connected to inspect or troubleshoot the traffic. 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.
• • Source port (MD) can be a VLAN, where the VLAN traffic received on that port pipe where its members are present is monitored Single MD can be monitored on max. of 4 MG ports. Port Monitoring Port monitoring is supported on both physical and logical interfaces, such as VLAN and port-channel interfaces. The source port (MD) with monitored traffic and the destination ports (MG) to which an analyzer can be attached must be on the same switch.
Layer 3 VLAN, the frames are tagged with the respective Layer 3 VLAN ID. For example, in the configuration source TenGig 1/6/1 destination TeGig 1/6/2 direction tx, if the MD port TenGig 1/6/1 is an untagged member of any VLAN, all monitored frames that the MG port TeGig 1/6/2 receives are tagged with the VLAN ID of the MD port. Similarly, if BPDUs are transmitted, the MG port receives them tagged with the VLAN ID 4095.
DellEMC(conf-mon-sess-1)#exit DellEMC(conf)#do show monitor session SessID Source Destination Dir Mode Gre-Protocol FcMonitor ------ ------------------ -------------- --------0 Te 1/1/1 Te 1/2/1 rx Port A N/A No 0 Po 10 Te 1/2/1 rx Port A N/A No 1 Vl 40 Te 1/3/1 rx Flow A N/A No Source IP Dest IP DSCP TTL Drop Rate --------- -------- ---- --- ---- ---- 0.0.0.0 0.0.0.0 0 0 No N/ 0.0.0.0 0.0.0.0 0 0 No N/ 0.0.0.0 0.0.0.
EXEC mode EXEC Privilege mode show run monitor session DellEMC#show run monitor session ! monitor multicast-queue 7 DellEMC# Flow-Based Monitoring Flow-based monitoring conserves bandwidth by monitoring only the specified traffic instead of all traffic on the interface. It is available for Layer 3 ingress and known unicast egress traffic. You can specify the traffic that needs to be monitored using standard or extended access-lists.
seq sequence-number {deny | permit} {source [mask] | any | host ip-address} [count [byte]] [order] [fragments] [log [threshold-in-msgs count]] [monitor] 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. You cannot apply the same ACL to an interface or a monitoring session context simultaneously.
NOTE: Flow-based monitoring is supported for known unicast egress traffic. 1 Create a monitoring session. CONFIGURATION mode monitor session session-id 2 Enable flow-based monitoring for a monitoring session. MONITOR SESSION mode flow-based enable 3 Specify the source and destination port and direction of traffic. MONITOR SESSION mode source source—port destination destination-port direction rx 4 Define IP access-list rules that include the monitor keyword.
DellEMC(conf)#do show monitor session 0 SessionID Source Destination Direction Mode Rate Gre-Protocol FcMonitor --------- ---------------- --------- ------- ----------- --------0 Te 1/1/1 Te 1/2/1 rx interface A N/A yes Source IP Dest IP DSCP TTL Drop --------- -------- ---- --- ---- 0.0.0.0 0.0.0.0 0 0 No N/ The following is sample configuration for flow-based mirroring with ACLs applied to monitor sessions.
The reserved VLANs transport the mirrored traffic in sessions (blue pipes) to the destination analyzers in the local network. Two destination sessions are shown: one for the reserved VLAN that transports orange-circle traffic; one for the reserved VLAN that transports greencircle traffic. Figure 98.
• You cannot configure a private VLAN or a GVRP VLAN as the reserved RPM VLAN. • The RPM VLAN can’t be a Private VLAN. • The RPM VLAN can be used as GVRP VLAN. • The L3 interface configuration should be blocked for RPM VLAN. • 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.
• 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.
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. 6 flow-based enable Specify flow-based enable for mirroring on a flow by flow basis and also for vlan as source.
DellEMC(conf)#end DellEMC# DellEMC#show monitor session SessID Source Destination ------ ---------------1 Te 1/5/1 remote-vlan 10 2 Vl 100 remote-vlan 20 3 Po 10 remote-vlan 30 DellEMC# Dir --rx rx both Mode Source IP ---- --------Port N/A Flow N/A Port N/A Dest IP -------N/A N/A N/A Configuring the sample Source Remote Port Mirroring DellEMC(conf)#inte te 1/1/1 DellEMC(conf-if-te-1/1/1)#switchport DellEMC(conf-if-te-1/1/1)#no shutdown DellEMC(conf-if-te-1/1/1)#exit DellEMC(conf)#interface te 1/2/1 Dell
1 Enable control plane egress acl using the following command: 2 Create an extended MAC access list and add a deny rule of (0x0180c2xxxxxx) packets using the following commands: mac control-plane egress-acl mac access-list extended mac2 seq 5 deny any 01:80:c2:00:00:00 00:00:00:ff:ff:ff count 3 Apply ACL on that RPM VLAN. In this example RPM vlan is 10.
To configure an ERPM session: Table 70. Configuration steps for ERPM Step Command Purpose 1 configure terminal Enter global configuration mode. 2 monitor session type erpm Specify a session ID and ERPM as the type of monitoring session, and enter the Monitoring-Session configuration mode. The session number needs to be unique and not already defined. 3 source { interface | range } direction {rx | tx | both} Specify the source port or range of ports.
no ip address tagged TenGigabitEthernet 1/1/1-1/1/3 mac access-group flow in <<<<<<<<<<<<<< Only ingress packets are supported for mirroring shutdown ERPM Behavior on a typical Dell EMC Networking OS The Dell EMC 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. Figure 99.
b • The Header that gets attached to the packet is 38 bytes long. In case of a packet with L3 VLAN, it would be 42 bytes long. The original payload /original mirrored data starts from the 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.
VLTi link is added as an implicit member of the RPM vlan. As a result, the mirrored traffic also reaches the peer VLT device effecting VLTi link's bandwidth usage. To mitigate this issue, the L2 VLT egress mask drops the duplicate packets that egress out of the VLT port. If the LAG status of the peer VLT device is OPER-UP, then the other VLT peer blocks the transmission of packets received through VLTi to its port or LAG.
Scenario RPM Restriction Recommended Solution Mirroring Orphan Ports across VLT Devices — In this scenario, an orphan port on the primary VLT device is mirrored to another orphan port on the secondary VLT device through the ICL LAG. The port analyzer is connected to the secondary VLT device. No restrictions apply to the RPM session. The following example shows the configuration on the primary VLT device:source orphan port destination remote vlan direction rx/tx/both.
39 Private VLANs (PVLAN) The private VLAN (PVLAN) feature is supported on Dell EMC Networking OS. For syntax details about the commands described in this chapter, refer to the Private VLANs commands chapter in the Dell EMC Networking OS Command Line Reference Guide. Private VLANs extend the Dell EMC 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.
show vlan private-vlan [community | interface | isolated | primary | primary_vlan | interface interface] • Display primary-secondary VLAN mapping. EXEC mode or EXEC Privilege mode show vlan private-vlan mapping • Set the PVLAN mode of the selected port. INTERFACE switchport mode private-vlan {host | promiscuous | trunk} NOTE: Secondary VLANs are Layer 2 VLANs, so even if they are operationally down while primary VLANs are operationally up, Layer 3 traffic is still transmitted across secondary VLANs.
Example of the switchport mode private-vlan Command NOTE: You cannot add interfaces that are configured as PVLAN ports to regular VLANs. You also cannot add “regular” ports (ports not configured as PVLAN ports) to PVLANs. The following example shows the switchport mode private-vlan command on a port and on a port channel.
You can enter interfaces in numeric or in range format, either comma-delimited (slot/port,port,port) or hyphenated (slot/ port-port). You can only add promiscuous ports or PVLAN trunk ports to the PVLAN (no host or regular ports). 6 (OPTIONAL) Assign an IP address to the VLAN. INTERFACE VLAN mode ip address ip address 7 (OPTIONAL) Enable/disable Layer 3 communication between secondary VLANs.
interface vlan vlan-id 2 Enable the VLAN. INTERFACE VLAN mode no shutdown 3 Set the PVLAN mode of the selected VLAN to isolated. INTERFACE VLAN mode private-vlan mode isolated 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 ports defined as host to the VLAN.
Private VLAN Configuration Example The following example shows a private VLAN topology. Figure 100. 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. • Te 1/24 and Te 1/47 are configured as host ports and assigned to the isolated VLAN, VLAN 4003.
In parallel, on S4810: • Te 1/3 is a promiscuous port and Te 1/25 is a PVLAN trunk port, assigned to the primary VLAN 4000. • Te 1/4-6 are host ports. Te 1/4 and Te 1/5 are assigned to the community VLAN 4001, while Te 1/6 is assigned to the isolated VLAN 4003. The result is that: • The S4810 ports would have the same intra-switch communication characteristics as described for the Z9500.
The following example shows using the show vlan private-vlan mapping command. S50-1#show vlan private-vlan mapping Private Vlan: Primary : 4000 Isolated : 4003 Community : 4001 NOTE: In the following example, notice the addition of the PVLAN codes – P, I, and C – in the left column. The following example shows viewing the VLAN status.
40 Per-VLAN Spanning Tree Plus (PVST+) Per-VLAN spanning tree plus (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). 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).
Table 72. Spanning Tree Variations Dell EMC Networking OS Supports Dell EMC 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 EMC Networking OS implementation of PVST+ is based on IEEE Standard 802.1w. • The Dell EMC Networking OS implementation of PVST+ uses IEEE 802.
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 102. 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.
Number of topology changes 5, last change occurred 00:34:37 ago on Te 1/32/1 Port 375 (TenGigabitEthernet 1/22/1) is designated Forwarding Port path cost 20000, Port priority 128, Port Identifier 128.375 Designated root has priority 4096, address 0001.e80d.b6:d6 Designated bridge has priority 4096, address 0001.e80d.b6:d6 Designated port id is 128.
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 greater the port cost, the less likely the port is selected to be a forwarding port. • 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 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.
Figure 103. PVST+ with Extend System ID • Augment the bridge ID with the VLAN ID. PROTOCOL PVST mode extend system-id Example of Viewing the Extend System ID in a PVST+ Configuration DellEMC(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 1/22,32/1 no shutdown ! interface Vlan 300 no ip address tagged TenGigabitEthernet 1/22,32/1 no shutdown ! protocol spanning-tree pvst no disable vlan 100 bridge-priority 4096 Example of PVST+ Configuration (R2) interface TenGigabitEthernet 2/12/1 no ip address switchport no shutdown ! interface TenGigabitEthernet 2/32/1 no ip address switchport no shutdown ! interface Vlan 100 no ip address tagged TenGigabitEthernet 2/12,32/1 no shutdown ! interface Vlan 200 no ip a
protocol spanning-tree pvst no disable vlan 300 bridge-priority 4096 702 Per-VLAN Spanning Tree Plus (PVST+)
41 Quality of Service (QoS) This chapter describes how to use and configure Quality of Service service (QoS) features on the switch. Differentiated service is accomplished by classifying and queuing traffic, and assigning priorities to those queues. Table 74.
Feature Direction 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 Strict-Priority Queueing Weighted Random Early Detection Egress Create WRED Profiles Egress Figure 104.
• Implementation Information • Port-Based QoS Configurations • Policy-Based QoS Configurations • Enabling QoS Rate Adjustment • Enabling Strict-Priority Queueing • Queue Classification Requirements for PFC Functionality • Support for marking dot1p value in L3 Input Qos Policy • Weighted Random Early Detection • Pre-Calculating Available QoS CAM Space • Specifying Policy-Based Rate Shaping in Packets Per Second • Configuring Policy-Based Rate Shaping • Configuring Weights and ECN for W
Table 75. dot1p-priority Values and Queue Numbers dot1p Queue Number 0 1 1 0 2 2 3 3 4 4 5 5 6 6 7 7 • Change the priority of incoming traffic on the interface.
When priority-tagged frames ingress an untagged port or hybrid port, the frames are classified to the default VLAN of the port and to a queue according to their dot1p priority if you configure service-class dynamic dotp or trust dot1p. When priority-tagged frames ingress a tagged port, the frames are dropped because, for a tagged port, the default VLAN is 0. Dell EMC Networking OS Behavior: Hybrid ports can receive untagged, tagged, and priority tagged frames.
Policy-Based QoS Configurations Policy-based QoS configurations consist of the components shown in the following example. Figure 105. Constructing Policy-Based QoS Configurations 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 EMC Networking OS matches packets against match criteria in the order that you configure them.
Use step 1 or step 2 to start creating a Layer 3 class map. 1 Create a match-any class map. CONFIGURATION mode class-map match-any 2 Create a match-all class map. CONFIGURATION mode class-map match-all 3 Specify your match criteria. CLASS MAP mode [seq sequence number] match {ip | ipv6 | ip-any} After you create a class-map, Dell EMC Networking OS places you in CLASS MAP mode. Match-any class maps allow up to five ACLs. Match-all class-maps allow only one ACL.
Creating a Layer 2 Class Map All class maps are Layer 3 by default; however, you can create a Layer 2 class map by specifying the layer2 option with the class-map command. A Layer 2 class map differentiates traffic according to 802.1p value and/or VLAN and/or characteristics defined in a MAC ACL.. Use Step 1 or Step 2 to start creating a Layer 2 class map. 1 Create a match-any class map. CONFIGURATION mode class-map match-any 2 Create a match-all class map.
Displaying Configured Class Maps and Match Criteria To display all class-maps or a specific class map, use the following command. Dell EMC Networking OS Behavior: An explicit “deny any" rule in a Layer 3 ACL used in a (match any or match all) class-map creates a "default to Queue 0" entry in the CAM, which causes unintended traffic classification. In the following example, traffic is classified in two Queues, 1 and 2. Class-map ClassAF1 is “match any,” and ClassAF2 is “match all”.
The following example shows correct traffic classifications. Dot1p to Queue Mapping Requirement The dot1p to queue mapping on the system is global and this is used to configure the PRIO2COS table configuration. For DSCP based PFC feature on untagged packets, this mapping must be the same as the default dot1p to queue mapping and should not be changed (as in TABLE 1). If a custom dot1p to queue mapping is present it should be reconfigured to the default dot1p to queue mapping.
NOTE: To avoid issues misconfiguration causes, Dell EMC 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.
Allocating Bandwidth to Queue Specifying WRED Drop Precedence 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 The switch schedules packets for egress based on Deficit Round Robin (DRR). This strategy offers a guaranteed data rate. Allocate bandwidth to queues only in terms of percentage in 4-queue and 8-queue systems.
DSCP Color Maps This section describes how to configure color maps and how to display the color map and color map configuration. This sections consists of the following topics: • Creating a DSCP Color Map • Displaying Color Maps • Display Color Map Configuration Creating a DSCP Color Map You can create a DSCP color map to outline the differentiated services codepoint (DSCP) mappings to the appropriate color mapping (green, yellow, red) for the input traffic.
Create the DSCP color map profile, bat-enclave-map, with a yellow drop precedence , and set the DSCP values to 9,10,11,13,15,16 DellEMC(conf)# qos dscp-color-map bat-enclave-map DellEMC(conf-dscp-color-map)# dscp yellow 9,10,11,13,15,16 DellEMC(conf-dscp-color-map)# exit Assign the color map, bat-enclave-map to the interface.
Display detailed information about a color policy for a specific interface DellEMC# show qos dscp-color-policy detail tengigabitethernet 1/10/1 Interface TenGigabitEthernet 1/10/1 Dscp-color-map mapONE yellow 4,7 red 20,30 Create Policy Maps There are two types of policy maps: input and output. Creating Input Policy Maps There are two types of input policy-maps: Layer 3 and Layer 2. 1 Create a Layer 3 input policy map.
Honoring DSCP Values on Ingress Packets Dell EMC Networking OS provides the ability to honor DSCP values on ingress packets using Trust DSCP feature. The following table lists the standard DSCP definitions and indicates to which queues Dell EMC Networking OS maps DSCP values. When you configure trust DSCP, the matched packets and matched bytes counters are not incremented in the show qos statistics. Table 77.
trust dot1p Mapping dot1p Values to Service Queues All traffic is by default mapped to the same queue, Queue 0. If you honor dot1p on ingress, you can create service classes based the queueing strategy in Honoring dot1p Values on Ingress Packets. You may apply this queuing strategy globally by entering the following command from CONFIGURATION mode. • All dot1p traffic is mapped to Queue 0 unless you enable service-class dynamic dot1p on an interface or globally.
Specifying an Aggregate QoS Policy Applying an Output Policy Map to an Interface 3 Apply the policy map to an interface. Applying an Output QoS Policy to a Queue To apply an output QoS policy to a queue, use the following command. • Apply an output QoS policy to queues. INTERFACE mode service-queue Specifying an Aggregate QoS Policy To specify an aggregate QoS policy, use the following command. • Specify an aggregate QoS policy.
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. Enabling Strict-Priority Queueing In strict-priority queuing, the system de-queues all packets from the assigned queue before servicing any other queues. You can assign strict-priority to one unicast queue, using the strict-priority command.
Currently if the ingress is untagged and egress is tagged, then dot1p priority 0(default) will be added as part of the tag header and from the next hop PFC will be based on that dot1p priority. Support is added to mark the dot1p value in the L3 Input Qos Policy in this feature. Hence it is possible to mark both DSCP and Dot1p simultaneously in the L3 Input Qos Policy.
Figure 106. Packet Drop Rate for WRED You can create a custom WRED profile or use one of the five pre-defined profiles. Enabling and Disabling WRED Globally By default, WRED is enabled on the system. You can disable or reenable WRED manually using a single command. Follow these steps to disable or enable WRED in Dell EMC Networking OS.
Applying a WRED Profile to Traffic After you create a WRED profile, you must specify to which traffic Dell EMC Networking OS should apply the profile. Dell EMC 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 EMC 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.
show qos statistics egress-queue Example of show qos statistics egress-queue Command DellEMC#show qos statistics egress-queue tengigabitethernet 1/1/1 Interface Te 1/1/1 Unicast/Multicast Egress Queue Statistics Queue# Q# Type TxPkts TxPkts/s TxBytes TxBytes/s DroppedPkts DroppedPkts/s DroppedBytes DroppedBytes/s ----------------------------------------------------------------------------------------------------------------------------0 UCAST 0 0 0 0 0 0 0 0 1 UCAST 0 0 0 0 0 0 0 0 2 UCAST 0 0 0 0 0 0 0 0 3
NOTE: The show cam-usage command provides much of the same information as the test cam-usage command, but whether a policy-map can be successfully applied to an interface cannot be determined without first measuring how many CAM entries the policy-map would consume; the test cam-usage command is useful because it provides this measurement. • Verify that there are enough available CAM entries.
DellEMC(config-qos-policy-out)# rate shape pps peak-rate burst-packets 2 Alternatively, configure the peak rate and peak burst size in bytes. QOS-POLICY-OUT mode DellEMC(config-qos-policy-out)# rate shape Kbps peak-rate burst-KB 3 Configure the committed rate and committed burst size in pps. QOS-POLICY-OUT mode DellEMC(config-qos-policy-out)# rate shape pps peak-rate burst-packets committed pps committed-rate burst-packets 4 Alternatively, configure the committed rate and committed burst size in bytes.
Global Service Pools With WRED and ECN Settings Support for global service pools is now available. You can configure global service pools that are shared buffer pools accessed by multiple queues when the minimum guaranteed buffers for the queue are consumed. Two service pools are used– one for loss-based queues and the other for lossless (priority-based flow control (PFC)) queues. You can enable WRED and ECN configuration on the global service-pools.
Configuring WRED and ECN Attributes The functionality to configure a weight factor for the WRED and ECN functionality for backplane ports is supported on the platform. WRED drops packets when the average queue length exceeds the configured threshold value to signify congestion. Explicit Congestion Notification (ECN) is a capability that enhances WRED by marking the packets instead of causing WRED to drop them when the threshold value is exceeded.
• Because this functionality forcibly marks all the packets matching the specific match criteria as ‘yellow’, Dell EMC Networking OS does not support Policer based coloring and this feature concurrently. • If single rate two color policer is configured along with this feature, then by default all packets less than PIR would be considered as “Green” But ‘Green’ packets matching the specific match criteria for which ‘color-marking’ is configured will be over-written and marked as “Yellow”.
3 Attach the policy-map to the interface. Dell EMC Networking OS support different types of match qualifiers to classify the incoming traffic. Match qualifiers can be directly configured in the class-map command or it can be specified through one or more ACL which in turn specifies the combination of match qualifiers. Until Release 9.3(0.0), support is available for classifying traffic based on the 6-bit DSCP field of the IPv4 packet.
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 EMC Networking OS drops all the ‘RED’ or ‘violate’ packets.
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 any dscp 40 ecn 2 seq 15 permit any dscp 40 ecn 3 ! ip access-list standard dscp_50_non_ecn seq 5 permit any dscp 50 ecn 0 ! ip access-list standard dscp_40_non_ecn seq 5 permit any dscp 40 ecn 0 ! class-map match-any class_dscp_40 match ip access-group dscp_40_non_ecn set-color yellow match ip access-group dscp_40_ecn ! class-map m
Managing Hardware Buffer Statistics The memory management unit (MMU) is 12.2 MB in size. It contains approximately 60,000 cells, each of which is 208 bytes in size. MMU also has another portion of 3 MB allocated to it. The entire MMU space is shared across a maximum of 104 logical ports to support the egress admission-control functionality to implement scheduling and shaping on per-port and per-queue levels.
Enable this utility to be able to configure the parameters for buffer statistics tracking. By default, buffer statistics tracking is disabled. 3 Use show hardware buffer-stats-snapshot resource interface interface{priority-group { id | all } | queue { ucast{id | all}{ mcast {id | all} | all} to view buffer statistics tracking resource information for a specific interface.
42 Routing Information Protocol (RIP) The Routing Information Protocol (RIP) tracks distances or hop counts to nearby routers when establishing network connections and is based on a distance-vector algorithm. 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.
Implementation Information Dell EMC 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 EMC Networking OS. Table 80.
Enabling RIP Globally By default, RIP is not enabled in Dell EMC Networking OS. To enable RIP globally, use the following commands. 1 Enter ROUTER RIP mode and enable the RIP process on Dell EMC Networking OS. CONFIGURATION mode router rip 2 Assign an IP network address as a RIP network to exchange routing information.
192.161.1.0/24 auto-summary 192.162.3.0/24 [120/1] via 29.10.10.12, 00:01:22, Fa 1/4 192.162.3.0/24 auto-summary DellEMC#show ip rip database Total number of routes in RIP database: 978 160.160.0.0/16 [120/1] via 29.10.10.12, 00:00:26, Fa 1/49 160.160.0.0/16 auto-summary 2.0.0.0/8 [120/1] via 29.10.10.12, 00:01:22, Fa 1/49 2.0.0.0/8 auto-summary 4.0.0.0/8 [120/1] via 29.10.10.12, 00:01:22, Fa 1/49 4.0.0.0/8 auto-summary 8.0.0.0/8 [120/1] via 29.10.10.12, 00:00:26, Fa 1/49 8.0.0.0/8 auto-summary 12.0.0.
neighbor ip-address • You can use this command multiple times to exchange RIP information with as many RIP networks as you want. Disable a specific interface from sending or receiving RIP routing information. ROUTER RIP mode passive-interface interface Assigning a Prefix List to RIP Routes Another method of controlling RIP (or any routing protocol) routing information is to filter the information through a prefix list. A prefix list is applied to incoming or outgoing routes.
• map-name: the name of a configured route map. To view the current RIP configuration, use the show running-config command in EXEC mode or the show config command in ROUTER RIP mode. Setting the Send and Receive Version To change the RIP version globally or on an interface in Dell EMC Networking OS, use the following command. To specify the RIP version, use the version command in ROUTER RIP mode.
Gateway Distance Last Update Distance: (default is 120) DellEMC# Generating a Default Route Traffic is forwarded to the default route when the traffic’s network is not explicitly listed in the routing table. Default routes are not enabled in RIP unless specified. Use the default-information originate command in ROUTER RIP mode to generate a default route into RIP.
distance weight [ip-address mask [access-list-name]] Configure the following parameters: • • weight: the range is from 1 to 255. The default is 120. • ip-address mask: the IP address in dotted decimal format (A.B.C.D), and the mask in slash format (/x). • access-list-name: the name of a configured IP ACL. Apply an additional number to the incoming or outgoing route metrics.
Figure 107. RIP Topology Example RIP Configuration on Core2 The following example shows how to configure RIPv2 on a host named Core2. Example of Configuring RIPv2 on Core 2 Core2(conf-if-te-1/1/2)# Core2(conf-if-te-1/1/2)#router rip Core2(conf-router_rip)#ver 2 Core2(conf-router_rip)#network 10.200.10.0 Core2(conf-router_rip)#network 10.300.10.0 Core2(conf-router_rip)#network 10.11.10.0 Core2(conf-router_rip)#network 10.11.20.0 Core2(conf-router_rip)#show config ! router rip network 10.0.0.
The following example shows the show ip route command to show the RIP setup on Core 2.
Core3(conf-router_rip)#network 192.168.2.0 Core3(conf-router_rip)#network 10.11.30.0 Core3(conf-router_rip)#network 10.11.20.0 Core3(conf-router_rip)#show config ! router rip network 10.0.0.0 network 192.168.1.0 network 192.168.2.0 version 2 Core3(conf-router_rip)# Core 3 RIP Output The examples in this section show the core 2 RIP output. • To display Core 3 RIP database, use the show ip rip database command. • To display Core 3 RIP setup, use the show ip route command.
The following example shows the show ip protocols command to show the RIP configuration activity on Core 3.
! interface TenGigabitEthernet 3/2/1 ip address 10.11.20.1/24 no shutdown ! interface TenGigabitEthernet 3/4/1 ip address 192.168.1.1/24 no shutdown ! interface TenGigabitEthernet 3/5/1 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.
43 Remote Monitoring (RMON) 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 EMC Networking Ethernet interfaces. RMON operates with the simple network management protocol (SNMP) and monitors all nodes on a local area network (LAN) segment. RMON monitors traffic passing through the router and segment traffic not destined for the router.
Setting the RMON Alarm To set an alarm on any MIB object, use the rmon alarm or rmon hc-alarm command in GLOBAL CONFIGURATION mode. • Set an alarm on any MIB object.
CONFIGURATION mode [no] rmon event number [log] [trap community] [description string] [owner string] • number: assigned event number, which is identical to the eventIndex in the eventTable in the RMON MIB. The value must be an integer from 1 to 65,535 and be unique in the RMON Event Table. • log: (Optional) generates an RMON log entry when the event is triggered and sets the eventType in the RMON MIB to log or logand-trap. Default is no log.
[no] rmon collection history {controlEntry integer} [owner ownername] [buckets bucket-number] [interval seconds] • controlEntry: specifies the RMON group of statistics using a value. • integer: a value from 1 to 65,535 that identifies the RMON group of statistics. The value must be a unique index in the RMON History Table. • owner: (Optional) specifies the name of the owner of the RMON group of statistics. The default is a null-terminated string.
44 Rapid Spanning Tree Protocol (RSTP) The Rapid Spanning Tree Protocol (RSTP) is a Layer 2 protocol — specified by IEEE 802.1w — that is essentially the same as spanningtree protocol (STP) but provides faster convergence and interoperability with switches configured with STP and multiple spanning tree protocol (MSTP). Protocol Overview RSTP is a Layer 2 protocol — specified by IEEE 802.
• Dell EMC 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. When using the range command, Dell EMC Networking recommends limiting the range to five ports and 40 VLANs.
no shutdown DellEMC(conf-if-te-1/1/1)# Enabling Rapid Spanning Tree Protocol Globally Enable RSTP globally on all participating bridges; it is not enabled by default. When you enable RSTP, all physical and port-channel interfaces that are enabled and in Layer 2 mode are automatically part of the RST topology. • Only one path from any bridge to any other bridge is enabled. • Bridges block a redundant path by disabling one of the link ports.
Figure 108. 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. DellEMC#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.
Designated bridge has priority 32768, address 0001.e801.cbb4 Designated port id is 128.379, designated path cost 0 Number of transitions to forwarding state 1 BPDU : sent 121, received 5 The port is not in the Edge port mode Port 380 (TenGigabitEthernet 2/4/1) is designated Forwarding Port path cost 20000, Port priority 128, Port Identifier 128.380 Designated root has priority 32768, address 0001.e801.cbb4 Designated bridge has priority 32768, address 0001.e801.cbb4 Designated port id is 128.
The following table displays the default values for RSTP. Table 82.
The default is 20 seconds. To view the current values for global 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, use the following command. • Enable SNMP traps for RSTP, MSTP, and PVST+ collectively. snmp-server enable traps xstp Modifying Interface Parameters On interfaces in Layer 2 mode, you can set the port cost and port priority values.
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. To change the bridge priority, use the following command. • Assign a number as the bridge priority or designate it as the primary or secondary root. PROTOCOL SPANNING TREE RSTP mode bridge-priority priority-value • priority-value The range is from 0 to 65535.
Example of Verifying an EdgePort is Enabled on an Interface To verify that EdgePort is enabled on a port, use the show spanning-tree rstp command from EXEC privilege mode or the show config command from INTERFACE mode. NOTE: Dell EMC Networking recommends using the show config command from INTERFACE mode. In the following example, the bold line indicates that the interface is in EdgePort mode.
45 Software-Defined Networking (SDN) The Dell EMC Networking OS supports software-defined networking (SDN). For more information, see the SDN Deployment Guide.
46 Security This chapter describes several ways to provide security to the Dell EMC Networking system. For details about all the commands described in this chapter, refer to the Security chapter in the Dell EMC Networking OS Command Reference Guide.
• Configuring AAA Accounting for Terminal Lines (optional) • Monitoring AAA Accounting (optional) Enabling AAA Accounting The aaa accounting command allows you to create a record for any or all of the accounting functions monitored. To enable AAA accounting, use the following command. • Enable AAA accounting and create a record for monitoring the accounting function.
Example of Configuring AAA Accounting to Track EXEC and EXEC Privilege Level Command Use In the following sample configuration, AAA accounting is set to track all usage of EXEC commands and commands on privilege level 15.
NOTE: If a console user logs in with RADIUS authentication, the privilege level is applied from the RADIUS server if the privilege level is configured for that user in RADIUS, whether you configure RADIUS authorization. Configuration Task List for AAA Authentication The following sections provide the configuration tasks.
login authentication {method-list-name | default} To view the configuration, use the show config command in LINE mode or the show running-config in EXEC Privilege mode. NOTE: Dell EMC 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.
The following example shows enabling local authentication for console and remote authentication for the VTY lines. DellEMC(config)# aaa authentication enable mymethodlist radius tacacs DellEMC(config)# line vty 0 9 DellEMC(config-line-vty)# enable authentication mymethodlist Server-Side Configuration Using AAA authentication, the switch acts as a RADIUS or TACACS+ client to send authentication requests to a TACACS+ or RADIUS server.
Obscuring Passwords and Keys By default, the service password-encryption command stores encrypted passwords. For greater security, you can also use the service obscure-passwords command to prevent a user from reading the passwords and keys, including RADIUS, TACACS+ keys, router authentication strings, VRRP authentication by obscuring this information. Passwords and keys are stored encrypted in the configuration file and by default are displayed in the encrypted form when the configuration is displayed.
After you configure other privilege levels, enter those levels by adding the level parameter after the enable command or by configuring a user name or password that corresponds to the privilege level. For more information about configuring user names, refer to Configuring a Username and Password. By default, commands in Dell EMC Networking OS are assigned to different privilege levels. You can access those commands only if you have access to that privilege level.
Configuring the Enable Password Command To configure Dell EMC Networking OS, use the enable command to enter EXEC Privilege level 15. After entering the command, Dell EMC Networking OS requests that you enter a password. Privilege levels are not assigned to passwords, rather passwords are assigned to a privilege level. You can always change a password for any privilege level. To change to a different privilege level, enter the enable command, then the privilege level.
• 2 Secret: Specify the secret for the user. Configure a password for privilege level. CONFIGURATION mode enable password [level level] [encryption-mode] password Configure the optional and required parameters: • level level: specify a level from 0 to 15. Level 15 includes all levels. • encryption-type: enter 0 for plain text or 7 for encrypted text. • password: enter a string up to 32 characters long. To change only the password for the enable command, configure only the password parameter.
The following example shows the Telnet session for user john. The show privilege command output confirms that john is in privilege level 8. In EXEC Privilege mode, john can access only the commands listed. In CONFIGURATION mode, john can access only the snmpserver commands. apollo% telnet 172.31.1.53 Trying 172.31.1.53... Connected to 172.31.1.53. Escape character is '^]'.
EXEC Privilege mode enable or enable privilege-level • If you do not enter a privilege level, Dell EMC Networking OS sets it to 15 by default. Move to a lower privilege level. EXEC Privilege mode disable level-number • level-number: The level-number you wish to set. If you enter disable without a level-number, your security level is 1. RADIUS Remote authentication dial-in user service (RADIUS) is a distributed client/server protocol.
Idle Time Every session line has its own idle-time. If the idle-time value is not changed, the default value of 30 minutes is used. RADIUS specifies idle-time allow for a user during a session before timeout. When a user logs in, the lower of the two idle-time values (configured or default) is used. The idle-time value is updated if both of the following happens: • The administrator changes the idle-time of the line on which the user has logged in.
• Monitoring RADIUS (optional) For a complete listing of all Dell EMC Networking OS commands related to RADIUS, refer to the Security chapter in the Dell EMC Networking OS Command Reference Guide. NOTE: RADIUS authentication and authorization are done in a single step. Hence, authorization cannot be used independent of authentication. However, if you have configured RADIUS authorization and have not configured authentication, a message is logged stating this.
Specifying a RADIUS Server Host When configuring a RADIUS server host, you can set different communication parameters, such as the UDP port, the key password, the number of retries, and the timeout. To specify a RADIUS server host and configure its communication parameters, use the following command. • Enter the host name or IP address of the RADIUS server host.
• Configure the number of times Dell EMC Networking OS retransmits RADIUS requests. CONFIGURATION mode radius-server retransmit retries • • retries: the range is from 0 to 100. Default is 3 retries. Configure the time interval the system waits for a RADIUS server host response. CONFIGURATION mode radius-server timeout seconds • seconds: the range is from 0 to 1000. Default is 5 seconds.
4 Log in to switch using console or telnet or ssh with a valid user role. When 1-factor authentication is used, the authentication succeeds enabling you to access the switch. When two-factor authentication is used, the system prompts you to enter a one-time password as a second step of authentication. If a valid one-time password is supplied, the authentication succeeds enabling you to access the switch.
The following tables describe the various types of attributes that identify the NAS and the user sessions: Table 83. NAS Identification Attributes Attribute code Attribute Description 4 NAS-IP-Address IPv4 address of the NAS. 95 NAS-IPv6–Address IPv6 address of the NAS. Table 84. Change of Authorization (CoA) Attribute Attribute code Attribute Description 5 NAS-Port Port associated with the session to be processed for EAP or MAB users or the VTY ID for AAA sessions. Table 85.
Error-cause Values It is possible that a Dynamic Authorization Server cannot honor Disconnect Message request or CoA request packets for some reason. The Error-Cause Attribute provides more detail on the cause of the problem. It may be included within CoA-Nak and Disconnect-Nak packets.
• rejects the CoA-Request containing NAS-IP-Address or NAS-IPV6-Address attribute that does not match the NAS with a CoA-Nak; Error-Cause value is “NAS Identification Mismatch” (403). • responds with a CoA-Nak, if it is configured to prohibit honoring of corresponding CoA-Request messages; Error-Cause value is “Administratively Prohibited” (501). NOTE: The Administratively Prohibited Error-Cause is also applicable to following scenarios: • if the dot1x feature is not enabled in the NAS-port.
• responds with DM-Nak for any internal processing error in NAS; Error-Cause value is “Resources Unavailable” (506). • ignores attributes that are supported as per RFC but are irrelevant to the DM operation. • responds to a disconnect message containing one or more incorrect attributes values with a Disconnect-NAK; Error-Cause value is “Invalid Attribute Value” (407). • responds to a disconnect message containing unsupported attributes with DM-Nak; Error-Cause value is “Unsupported Attributes” (401).
• Shared key is configured in NAS for DAC. • NAS server listens on the Management IP UDP port 3799 (default) or the port configured through CLI. • AAA session for the user is active. NAS uses the user-name or both the user-name as well as the NAS-Port attribute to identify the AAA user session. NAS disconnects all sessions related to the user, if the user-name is provided without NAS-port.
• discards the packet, if simultaneous requests are received for the same NAS Port. Configuring CoA to re-authenticate 802.1x sessions Dell EMC Networking OS provides RADIUS extension commands that enables you to configure re-authentication of 802.1x user sessions. When you configure this feature, the DAC sends the CoA request to re-authenticate the 802.1x uer session when ever the authorization level of the user’s profile changes. Before configuring re-authentication of 802.
NAS uses the calling-station-id or the NAS-port attributes to identify the 802.1x session. In case of the EAP and MAB users, the callingstation-id is the MAC address of the supplicant and the NAS-port attribute is the interface identifier. Using these atrributes, the NAS retrieves the supplicant that is connected to the interface. 1 Enter the following command to configure the dynamic authorization feature: radius dynamic-auth 2 Enter the following command to terminate the 802.
• sends a CoA-Nak with an error-cause value of 506 (resource unavailable), if it is not able to disable the 802.1x enabled port. • discards the packet, if simultaneous requests are received for the same NAS Port. Important points to remember Virtual link truncking (VLT) scenario This section describes how the secondary NAS processes the PE port authorization RADIUS requests to the primary NAS.
NAS considers the rate limit change value from the next interval period. The range is from 10 to 60 packets per minute. The default is 30 packets per minute. Dell(conf-dynamic-auth#)rate-limit 50 Configuring time-out value You can configure a time-out value for the back-end task to respond to CoA or DM requests. This setting enables the DAS to determine the amount of time to wait before a back-end response is received. The default value is 10 minutes.
The TACACS+ method must not be the last method specified. 3 Enter LINE mode. CONFIGURATION mode line {aux 0 | console 0 | vty number [end-number]} 4 Assign the method-list to the terminal line. LINE mode login authentication {method-list-name | default} 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.
debug tacacs+ TACACS+ Remote Authentication The system takes the access class from the TACACS+ server. Access class is the class of service that restricts Telnet access and packet sizes. If you have configured remote authorization, the system ignores the access class you have configured for the VTY line and gets this access class information from the TACACS+ server. The system must know the username and password of the incoming user before it can fetch the access class from the server.
Password: DellEMC# Command Authorization The AAA command authorization feature configures Dell EMC 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. DellEMC(conf)#ip ssh server version 2 DellEMC(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,aes128-ctr,aes192ctr,aes256-ctr. SSH server macs : hmac-md5,hmac-md5-96,hmac-sha1,hmac-sha1-96,hmac-sha2-256,hmacsha2-256-96.
• ip ssh hostbased-authentication enable : enable host-based authentication for the SSHv2 server. • ip ssh password-authentication enable : enable password authentication for the SSH server. • ip ssh pub-key-file : specify the file the host-based authentication uses. • ip ssh rhostsfile : specify the rhost file the host-based authorization uses. • ip ssh rsa-authentication enable : enable RSA authentication for the SSHv2 server. • ip ssh rsa-authentication : add keys for the RSA authentication.
Configuring the SSH Server Key Exchange Algorithm To configure the key exchange algorithm for the SSH server, use the ip ssh server kex key-exchange-algorithm command in CONFIGURATION mode. key-exchange-algorithm : Enter a space-delimited list of key exchange algorithms that will be used by the SSH server.
• hmac-md5-96 When FIPS is enabled, the default HMAC algorithm is hmac-sha2-256,hmac-sha1,hmac-sha1-96. Example of Configuring a HMAC Algorithm The following example shows you how to configure a HMAC algorithm list. DellEMC(conf)# ip ssh server mac hmac-sha1-96 Configuring the HMAC Algorithm for the SSH Client To configure the HMAC algorithm for the SSH client, use the ip ssh mac hmac-algorithm command in CONFIGURATION mode.
• aes192-cbc • aes256-cbc • aes128-ctr • aes192-ctr • aes256-ctr The default cipher list is aes256-ctr, aes256-cbc, aes192-ctr, aes192-cbc, aes128-ctr, aes128-cbc, 3des-cbc. Example of Configuring a Cipher List The following example shows you how to configure a cipher list.
Example of Enabling SSH Password Authentication To view your SSH configuration, use the show ip ssh command from EXEC Privilege mode. DellEMC(conf)#ip ssh server enable DellEMC(conf)#ip ssh password-authentication enable DellEMC# show ip ssh SSH server : enabled. SSH server version : v1 and v2. SSH server vrf : default. SSH server ciphers : 3des-cbc,aes128-cbc,aes192-cbc,aes256-cbc,aes128-ctr,aes192ctr,aes256-ctr. SSH server macs : hmac-md5,hmac-md5-96,hmac-sha1,hmac-sha1-96,hmac-sha2-256,hmacsha2-256-96.
Refer to the first example. 3 Create a list of IP addresses and usernames that are permitted to SSH in a file called rhosts. Refer to the second example. 4 Copy the file shosts and rhosts to the Dell EMC Networking system. 5 Disable password authentication and RSA authentication, if configured CONFIGURATION mode or EXEC Privilege mode no ip ssh password-authentication or no ip ssh rsa-authentication 6 Enable host-based authentication.
Example of Client-Based SSH Authentication DellEMC#ssh 10.16.127.201 ? -c Encryption cipher to use (for v2 clients only) -l User name option -m HMAC algorithm to use (for v2 clients only) -p SSH server port option (default 22) -v SSH protocol version Troubleshooting SSH To troubleshoot SSH, use the following information. You may not bind id_rsa.pub to RSA authentication while logged in via the console. In this case, this message displays:%Error: No username set for this term.
• VTY Line Remote Authentication and Authorization VTY Line Local Authentication and Authorization retrieves the access class from the local database. To use this feature: 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.
DellEMC(config-line-vty)#end (same applies for radius and line authentication) VTY MAC-SA Filter Support 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. To apply a MAC ACL on a VTY line, use the same access-class command as IP ACLs. The following example shows how to deny incoming connections from subnet 10.0.0.0 without displaying a login prompt.
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. User roles are created for job functions and through those roles they acquire the permissions to perform their associated job function. Each user can be assigned only a single role. Many users can have the same role. The Dell EMC Networking OS supports the constrained RBAC model.
You must specify at least local authentication. For consistency, the best practice is to define the same authentication method list across all lines, in the same order of comparison; for example VTY and console port. You could also use the default authentication method to apply to all the LINES; for example, console port and VTY. NOTE: The authentication method list must be in the same order as the authorization method list.
netoperator netadmin Exec Config Interface Router IP Route-map Protocol MAC secadmin Exec Config Line sysadmin Exec Config Interface Line Router IP Route-map Protocol MAC User Roles This section describes how to create a new user role and configure command permissions and contains the following topics.
Verify that the user role, myrole, has inherited the security administrator permissions. The output highlighted in bold indicates that the user role has successfully inherited the security administrator permissions.
The following example allows the security administrator (secadmin) to access Interface mode.
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. DellEMC(conf)#role configure reset protocol Adding and Deleting Users from a Role To create a user name that is authenticated based on a user role, use the username name password encryption-type password role role-name command in CONFIGURATION mode.
Configure AAA Authorization for Roles Authorization services determine if the user has permission to use a command in the CLI. Users with only privilege levels can use commands in privilege-or-role mode (the default) provided their privilege level is the same or greater than the privilege level of those commands. Users with defined roles can use commands provided their role is permitted to use those commands. Role inheritance is also used to determine authorization.
login authentication ucraaa authorization exec ucraaa accounting commands role netadmin line vty 5 login authentication ucraaa authorization exec ucraaa accounting commands role netadmin line vty 6 login authentication ucraaa authorization exec ucraaa accounting commands role netadmin line vty 7 login authentication ucraaa authorization exec ucraaa accounting commands role netadmin line vty 8 login authentication ucraaa authorization exec ucraaa accounting commands role netadmin line vty 9 login authenticat
Role Accounting This section describes how to configure role accounting and how to display active sessions for roles. This sections consists of the following topics: • Configuring AAA Accounting for Roles • Applying an Accounting Method to a Role • Displaying Active Accounting Sessions for Roles Configuring AAA Accounting for Roles To configure AAA accounting for roles, use the aaa accounting command in CONFIGURATION mode.
• Displaying Information About Roles Logged into the Switch • Displaying Active Accounting Sessions for Roles Displaying User Roles To display user roles using the show userrole command in EXEC Privilege mode, use the show userroles and show users commands in EXEC privilege mode.
Two Factor Authentication (2FA) Two factor authentication also known as 2FA, strengthens the login security by providing one time password (OTP) in addition to username and password. 2FA supports RADIUS authentications with Console, Telnet, and SSHv2. To perform 2FA, follow these steps: • When the Network access server (NAS) prompts for the username and password, provide the inputs. • If the credentials are valid: • • RADIUS server sends a request to the SMS–OTP daemon to generate an OTP for the user.
Hostbased Authentication : disabled. RSA Authentication : disabled. Challenge Response Auth : enabled. Vty Encryption HMAC 2 aes128-cbc hmac-md5 4 aes128-cbc hmac-md5 * 5 aes128-cbc hmac-md5 DellEMC# Remote IP 10.16.127.141 10.16.127.141 10.16.127.141 SMS-OTP Mechanism A short message service one time password (SMS-OTP) is a free RADIUS module to implement two factor authentication. There are multiple 2FA mechanisms that can be deployed with the RADIUS.
ICMPv4 message types Timestamp reply (14) Information request (15) Information reply (16) Address mask request (17) Address mask reply (18) NOTE: The Dell EMC Networking OS does not suppress the ICMP message type echo request (8). Table 90.
Dell EMC Networking OS version 9.11(0.0), the SSH protection mechanism has been enhanced to allow 60 login attempts (success or failure) per minute. After 60 attempts, the system blocks the user login for a maximum rate interval which can be specified by the user using the ip ssh connection-rate-interval CLI command. The ip ssh connection-rate-lockout CLI command ensures a minimum blocking time after the rate limit has been exceeded.
3 Save the configuration. EXEC Privilege copy running-configuration startup-configuration After enabling and configuring OS image hash verification, the device verifies the hash checksum of the OS boot image during every reload. DellEMC# verified boot hash system-image A: 619A8C1B7A2BC9692A221E2151B9DA9E Image Verification for Subsequent OS Upgrades After enabling OS image hash verification, for subsequent Dell EMC Networking OS upgrades, you must enter the hash checksum of the new OS image file.
Enabling and Configuring Startup Configuration Hash Verification To enable and configure startup configuration hash verification, follow these steps: 1 Enable the startup configuration hash verification feature. CONFIGURATION mode verified boot 2 Generate the hash checksum for your startup configuration file. EXEC Privilege generate hash {md5 | sha1 | sha256} {flash://filename | startup-config} 3 Verify the hash checksum of the current startup configuration on the local file system.
• A minimum of one special character including a space (" !"#$%&'()*+,-./:;<=>?@[\]^_`{|}~") DellEMC)# show running-config | g root root-access password 7 f4dc0cb9787722dd1084d17f417f164cc7f730d4f03d4f0215294cbd899614e3 Locking Access to GRUB Interface You can configure the Dell EMC Networking OS to lock the GRUB interface using a password. If you configure a GRUB password, the system prompts for the password when you try to access the GRUB interface.
Enter the duration in minutes.
47 Service Provider Bridging Service provider bridging provides the ability to add a second VLAN ID tag in an Ethernet frame and is referred to as VLAN stacking in the Dell EMC 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.
Figure 109. 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 VLAN-Stack-enabled VLAN. • Dell EMC Networking cautions against using the same MAC address on different customer VLANs, on the same VLAN-Stack VLAN.
3 Enabling VLAN-Stacking for a VLAN. Related Configuration Tasks • Configuring the Protocol Type Value for the Outer VLAN Tag • Configuring Dell EMC Networking OS Options for Trunk Ports • Debugging VLAN Stacking • VLAN Stacking in Multi-Vendor Networks Creating Access and Trunk Ports To create access and trunk ports, use the following commands. • Access port — a port on the service provider edge that directly connects to the customer. An access port may belong to only one service provider VLAN.
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-Stackingenabled VLAN are marked with an M in column Q.
[tagged | untagged] Example of Configuring a Trunk Port as a Hybrid Port and Adding it to Stacked VLANs In the following example, TenGigabitEthernet 1/1/1 is a trunk port that is configured as a hybrid port and then added to VLAN 100 as untagged VLAN 101 as tagged, and VLAN 103, which is a stacking VLAN.
VLAN Stacking in Multi-Vendor Networks The first field in the VLAN tag is the tag protocol identifier (TPID), which is 2 bytes. In a VLAN-stacking network, after the frame is double tagged, the outer tag TPID must match the TPID of the next-hop system. While 802.1Q requires that the inner tag TPID is 0x8100, it does not require a specific value for the outer tag TPID.
Figure 110.
Figure 111.
Figure 112. Single and Double-Tag TPID Mismatch VLAN Stacking Packet Drop Precedence VLAN stacking packet-drop precedence is supported on the switch. The drop eligible indicator (DEI) bit in the S-Tag indicates to a service provider bridge which packets it should prefer to drop when congested. Enabling Drop Eligibility Enable drop eligibility globally before you can honor or mark the DEI value. When you enable drop eligibility, DEI mapping or marking takes place according to the defaults.
Table 91. Drop Eligibility Behavior Ingress Egress DEI Disabled DEI Enabled Normal Port Normal Port Retain CFI Set CFI to 0. Trunk Port Trunk Port Retain inner tag CFI Retain inner tag CFI. Retain outer tag CFI Set outer tag CFI to 0. Retain inner tag CFI Retain inner tag CFI Set outer tag CFI to 0 Set outer tag CFI to 0 Access Port Trunk Port To enable drop eligibility globally, use the following command. • Make packets eligible for dropping based on their DEI value.
Marking Egress Packets with a DEI Value On egress, you can set the DEI value according to a different mapping than ingress. For ingress information, refer to Honoring the Incoming DEI Value. To mark egress packets, use the following command. • Set the DEI value on egress according to the color currently assigned to the packet.
NOTE: The ability to map incoming C-Tag dot1p to any S-Tag dot1p requires installing up to eight entries in the Layer 2 QoS and Layer 2 ACL table for each configured customer VLAN. The scalability of this feature is limited by the impact of the 1:8 expansion in these content addressable memory (CAM) tables.
• 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. The default is: 0 FP blocks for vman-qos and vman-qos-dual-fp. 2 The new CAM configuration is stored in NVRAM and takes effect only after a save and reload. EXEC Privilege mode copy running-config startup-config 3 Reload the system. reload 4 Map C-Tag dot1p values to a S-Tag dot1p value.
Figure 114. 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.
Figure 115. VLAN Stacking with L2PT Implementation Information • L2PT is available for STP, RSTP, MSTP, and PVST+ BPDUs. • No protocol packets are tunneled when you enable VLAN stacking. • L2PT requires the default CAM profile. 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.
show cam-profile 2 Enable protocol tunneling globally on the system. CONFIGURATION mode protocol-tunnel enable 3 Tunnel BPDUs the VLAN. INTERFACE VLAN mode protocol-tunnel stp Specifying a Destination MAC Address for BPDUs By default, Dell EMC Networking OS uses a Dell EMC Networking-unique MAC address for tunneling BPDUs. You can configure another value. To specify a destination MAC address for BPDUs, use the following command.
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 802.1Q—Virtual Bridged Local Area Networks so that service providers can use 802.1Q architecture to offer separate VLANs to customers with no coordination between customers, and minimal coordination between customers and the provider. 802.
48 sFlow 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.
hardware sampling rate is backed-off from 512 to 1024. Note that port 1 maintains its sampling rate of 16384; port 1 is unaffected because it maintains its configured sampling rate of 16384.: • If the interface states are up and the sampling rate is not configured on the port, the default sampling rate is calculated based on the line speed. • If the interface states are shut down, the sampling rate is set using the global sampling rate.
Egress Management Interface sFlow services are disabled Global default sampling rate: 32768 Global default counter polling interval: 20 Global default extended maximum header size: 128 bytes Global extended information enabled: switch 1 collectors configured Collector IP addr: 100.1.1.1, Agent IP addr: 1.1.1.
IP SA IP DA srcAS and srcPeerAS dstAS and dstPeerAS Description 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 BGP Exported Exported Extended gateway data is packed. Enabling and Disabling sFlow on an Interface By default, sFlow is disabled on all interfaces. This CLI is supported on physical ports and link aggregation group (LAG) ports.
0 sFlow samples collected stack-unit 1 Port set 0 Hu 1/29: configured rate 131072, actual rate 131072 Example of viewing the sflow max-header-size extended on an Interface Mode DellEMC#show sflow interface hundredgigabitethernet 1/29 Hu 1/29 sFlow type :Ingress Configured sampling rate :131072 Actual sampling rate :131072 Counter polling interval :20 Extended max header size :256 Samples rcvd from h/w :0 Example of the show running-config sflow Command DellEMC#show running-config sflow ! sflow collector 100
Global default sampling rate: 32768 Global default counter polling interval: 20 Global default extended maximum header size: 128 bytes Global extended information enabled: none 1 collectors configured Collector IP addr: 100.1.1.1, Agent IP addr: 1.1.1.
UDP packets exported via RPM UDP packets dropped :0 :36 Configuring Specify Collectors The sflow collector command allows identification of sFlow collectors to which sFlow datagrams are forwarded. You can specify up to two sFlow collectors. If you specify two collectors, the samples are sent to both. • Identify sFlow collectors to which sFlow datagrams are forwarded.
49 Simple Network Management Protocol (SNMP) The Simple Network Management Protocol (SNMP) is designed to manage devices on IP networks by monitoring device operation, which might require administrator intervention. NOTE: On Dell EMC 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).
• Manage VLANs using SNMP • Managing Overload on Startup • Enabling and Disabling a Port using SNMP • Fetch Dynamic MAC Entries using SNMP • Deriving Interface Indices • Monitoring BGP sessions via SNMP • Monitor Port-Channels • Troubleshooting SNMP Operation • Transceiver Monitoring Protocol Overview Network management stations use SNMP to retrieve or alter management data from network elements.
Table 93.
• Reading Managed Object Values • Writing Managed Object Values • Subscribing to Managed Object Value Updates using SNMP • Copying Configuration Files via SNMP • Manage VLANs Using SNMP • Enabling and Disabling a Port using SNMP • Fetch Dynamic MAC Entries using SNMP • Deriving Interface Indices • Monitor Port-channels Important Points to Remember • Typically, 5-second timeout and 3-second retry values on an SNMP server are sufficient for both LAN and WAN applications.
! snmp-server community mycommunity ro Setting Up User-Based Security (SNMPv3) When setting up SNMPv3, you can set users up with one of the following three types of configuration for SNMP read/write operations. Users are typically associated to an SNMP group with permissions provided, such as OID view. • • • noauth — no password or privacy. Select this option to set up a user with no password or privacy privileges. This setting is the basic configuration.
Select a User-based Security Type DellEMC(conf)#snmp-server host 1.1.1.1 traps {oid tree} version 3 ? auth Use the SNMPv3 authNoPriv Security Level noauth Use the SNMPv3 noAuthNoPriv Security Level priv Use the SNMPv3 authPriv Security Level DellEMC(conf)#snmp-server host 1.1.1.1 traps {oid tree} version 3 noauth ? WORD SNMPv3 user name Reading Managed Object Values You may only retrieve (read) managed object values if your management station is a member of the same community as the SNMP agent.
Example of Writing the Value of a Managed Object > snmpset -v 2c -c mycommunity 10.11.131.161 sysName.0 s "R5" SNMPv2-MIB::sysName.0 = STRING: R5 Configuring Contact and Location Information using SNMP You may configure system contact and location information from the Dell EMC Networking system or from the management station using SNMP. To configure system contact and location information from the Dell EMC Networking system and from the management station using SNMP, use the following commands.
• • • RFC 1157-defined traps — coldStart, warmStart, linkDown, linkUp, authenticationFailure, and egpNeighbborLoss. Dell EMC Networking enterpriseSpecific environment traps — fan, supply, and temperature. Dell EMC Networking enterpriseSpecific protocol traps — bgp, ecfm, stp, and xstp. To configure the system to send SNMP notifications, use the following commands. 1 Configure the Dell EMC Networking system to send notifications to an SNMP server.
LINECARDUP: %sLine card %d is up CARD_MISMATCH: Mismatch: line card %d is type %s - type %s required.
%ECFM-5-ECFM_MAC_STATUS_ALARM: MAC Status Defect detected by MEP 1 in Domain provider at Level 4 VLAN 3000 %ECFM-5-ECFM_REMOTE_ALARM: Remote CCM Defect detected by MEP 3 in Domain customer1 at Level 7 VLAN 1000 %ECFM-5-ECFM_RDI_ALARM: RDI Defect detected by MEP 3 in Domain customer1 at Level 7 VLAN 1000 entity Enable entity change traps Trap SNMPv2-MIB::sysUpTime.0 = Timeticks: (1487406) 4:07:54.06, SNMPv2-MIB::snmpTrapOID.0 = OID: SNMPv2-SMI::mib-2.47.2.0.1, SNMPv2-SMI::enterprises.6027.3.6.1.1.2.
MAJOR_TEMP: Major alarm: chassis temperature high (%s temperature reaches or exceeds threshold of %dC) MAJOR_TEMP_CLR: Major alarm cleared: chassis temperature lower (%s %d temperature is within threshold of %dC) 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.
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.
Copy Configuration Files Using SNMP To do the following, use SNMP from a remote client. • copy the running-config file to the startup-config file • copy configuration files from the Dell EMC Networking system to a server • copy configuration files from a server to the Dell EMC Networking system You can perform all of these tasks using IPv4 or IPv6 addresses. The examples in this section use IPv4 addresses; however, you can substitute IPv6 addresses for the IPv4 addresses in all of the examples.
MIB Object OID Object Values Description copyDestFileLocation .1.3.6.1.4.1.6027.3.5.1.1.1.1.6 1 = flash Specifies the location of destination file. 2 = slot0 • 3 = tftp 4 = ftp If copyDestFileLocation is FTP or SCP, you must specify copyServerAddress, copyUserName, and copyUserPassword. 5 = scp copyDestFileName .1.3.6.1.4.1.6027.3.5.1.1.1.1.7 Path (if the file is not in the default directory) and filename. Specifies the name of destination file. copyServerAddress .1.3.6.1.4.1.6027.3.5.1.1.
NOTE: You can use the entire OID rather than the object name. Use the form: OID.index i object-value. To view more information, use the following options in the snmpset command. • -c: View the community, either public or private. • -m: View the MIB files for the SNMP command. • -r: Number of retries using the option • -t: View the timeout. • -v: View the SNMP version (either 1, 2, 2c, or 3). The following examples show the snmpset command to copy a configuration.
FTOS-COPY-CONFIG-MIB::copySrcFileType.7 = INTEGER: runningConfig(3) FTOS-COPY-CONFIG-MIB::copyDestFileType.7 = INTEGER: startupConfig(2) The following example shows how to copy configuration files from a UNIX machine using OID. >snmpset -c public -v 2c 10.11.131.162 .1.3.6.1.4.1.6027.3.5.1.1.1.1.2.8 i 3 .1.3.6.1.4.1.6027.3.5.1.1.1.1.5.8 i 2 SNMPv2-SMI::enterprises.6027.3.5.1.1.1.1.2.8 = INTEGER: 3 SNMPv2-SMI::enterprises.6027.3.5.1.1.1.1.5.
Copy a Binary File to the Startup-Configuration To copy a binary file from the server to the startup-configuration on the Dell EMC Networking system via FTP, use the following command. • Copy a binary file from the server to the startup-configuration on the Dell EMC Networking system via FTP. snmpset -v 2c -c public -m ./f10-copy-config.mib force10system-ip-address copySrcFileType.index i 1 copySrcFileLocation.index i 4 copySrcFileName.index s filepath/ filename copyDestFileType.
MIB Object OID Values Description copy. The state is set to active when the copy is completed. Obtaining a Value for MIB Objects To obtain a value for any of the MIB objects, use the following command. • Get a copy-config MIB object value. snmpset -v 2c -c public -m ./f10-copy-config.mib force10system-ip-address [OID.index | mibobject.index] 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.
Viewing the Reason for Last System Reboot Using SNMP • To view the reason for last system reboot using SNMP, you can use any one of the applicable SNMP commands: The following example shows a sample output of the snmpwalk command to view the last reset reason. [DellEMC ~]$ snmpwalk -c public -v 2c 10.16.133.172 1.3.6.1.4.1.6027.3.26.1.4.3.1.7 DELL-NETWORKING-CHASSIS-MIB::dellNetProcessorResetReason.stack.1.1 = STRING: Reboot by Software DELL-NETWORKING-CHASSIS-MIB::dellNetProcessorResetReason.stack.2.
MIB Support for 25G, 40G, 50G, 100G Optical Transceiver or DAC cable IDPROM user info Dell EMC Networking provides MIB objects to display the information for 25G, 40G, 50G, 100G Optical Transceiver or DAC cable IDPROM. The following table lists the related MIB objects, OID and description for the same: Table 99. MIB Objects to Display support for 25G, 40G, 50G, 100G Optical Transceiver or DAC cable IDPROM user info MIB Object OID Description dellNetIfTransceiverData 1.3.6.1.4.1.6027.3.11.1.
DELL-NETWORKING-IF-EXTENSION-MIB::dellNetIfTransTransmitPowerLane2.2112517 = "" DELL-NETWORKING-IF-EXTENSION-MIB::dellNetIfTransTransmitPowerLane3.2112517 = "" DELL-NETWORKING-IF-EXTENSION-MIB::dellNetIfTransTransmitPowerLane4.2112517 = "" DELL-NETWORKING-IF-EXTENSION-MIB::dellNetIfTransReceivePowerLane1.2112517 = STRING: "-1.433315" dBm DELL-NETWORKING-IF-EXTENSION-MIB::dellNetIfTransReceivePowerLane2.2112517 = STRING: "0.051805" dBm DELL-NETWORKING-IF-EXTENSION-MIB::dellNetIfTransReceivePowerLane3.
MIB Object OID Description chSysCoresFileName 1.3.6.1.4.1.6027.3.10.1.2.10.1.2 Contains the core file names and the file paths. chSysCoresTimeCreated 1.3.6.1.4.1.6027.3.10.1.2.10.1.3 Contains the time at which core files are created. chSysCoresStackUnitNumber 1.3.6.1.4.1.6027.3.10.1.2.10.1.4 Contains information that includes which stack unit or processor the core file was originated from. chSysCoresProcess 1.3.6.1.4.1.6027.3.10.1.2.10.1.
Table 102. MIB Objects to Display the Information for PFC Storm Control MIB Object OID Description dellNetFpPfcStormControl 1.3.6.1.4.1.6027.3.27.1.21 Index for the table. dellNetFpPfcStormControlStatus 1.3.6.1.4.1.6027.3.27.1.21.1 Storm control status. dellNetFpPfcStormControlStatusTable 1.3.6.1.4.1.6027.3.27.1.21.1.1 Table to show counters of Pfc StormControl on per port per priority basis. dellNetFpPfcStormControlStatusEntry 1.3.6.1.4.1.6027.3.27.1.21.1.1.
SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097157.5 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097157.6 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097413.5 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097413.6 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097669.5 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097669.6 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097925.5 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.3.2097925.6 SNMPv2-SMI::enterprises.6027.3.27.1.21.1.1.1.4.2097157.
Table 103. MIB Objects to Display the Information for PFC no-drop-priority L2Dlf Drop MIB Object OID Description dellNetFpPfcL2DlfDropCounterTable 1.3.6.1.4.1.6027.3.27.1.22 Table to show the drop counters of pfcnodrop-priority l2-dlf drop. dellNetFpPfcL2DlfDropCounterEntry 1.3.6.1.4.1.6027.3.27.1.22.1 Table entry to show the drop counters of pfc-nodrop-priority l2-dlf drop. dellNetFpPfcL2DlfDropCounters 1.3.6.1.4.1.6027.3.27.1.22.1.
SNMPv2-SMI::enterprises.6027.3.27.1.23.1.3.1.1.3 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.3.1.1.4 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.4.1.1.1 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.4.1.1.2 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.4.1.1.3 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.4.1.1.4 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.5.1.1.1 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.5.1.1.2 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.5.1.1.3 SNMPv2-SMI::enterprises.6027.3.27.1.23.1.5.1.1.
• 33997973 is the count of green packet-drops (Green Drops). • 329629607 is the count of yellow packet-drops (Yellow Drops). • 31997973 is the count of red packet-drops (Out of Profile Drops). MIB Support to Display the Available Partitions on Flash Dell EMC Networking provides MIB objects to display the information of various partitions such as /flash, /tmp, /usr/pkg, and /f10/ConfD. The dellNetFlashStorageTable table contains the list of all partitions on disk.
.1.3.6.1.4.1.6027.3.26.1.4.8.1.2.3 .1.3.6.1.4.1.6027.3.26.1.4.8.1.2.4 .1.3.6.1.4.1.6027.3.26.1.4.8.1.2.5 .1.3.6.1.4.1.6027.3.26.1.4.8.1.3.1 .1.3.6.1.4.1.6027.3.26.1.4.8.1.3.2 .1.3.6.1.4.1.6027.3.26.1.4.8.1.3.3 .1.3.6.1.4.1.6027.3.26.1.4.8.1.3.4 .1.3.6.1.4.1.6027.3.26.1.4.8.1.3.5 .1.3.6.1.4.1.6027.3.26.1.4.8.1.4.1 .1.3.6.1.4.1.6027.3.26.1.4.8.1.4.2 .1.3.6.1.4.1.6027.3.26.1.4.8.1.4.3 .1.3.6.1.4.1.6027.3.26.1.4.8.1.4.4 .1.3.6.1.4.1.6027.3.26.1.4.8.1.4.5 .1.3.6.1.4.1.6027.3.26.1.4.8.1.5.1 .1.3.6.1.4.1.6027.3.
MIB Support to ECMP Group Count Dell EMC Networking OS provides MIB objects to display the information of the ECMP group count information. The following table lists the related MIB objects: Table 109. MIB Objects to display ECMP Group Count MIB Object OID Description dellNetInetCidrECMPGrpMax 1.3.6.1.4.1.6027.3.9.1.6 Total CAM for ECMP group. dellNetInetCidrECMPGrpUsed 1.3.6.1.4.1.6027.3.9.1.7 Used CAM for ECMP group. dellNetInetCidrECMPGrpAvl 1.3.6.1.4.1.6027.3.9.1.
SNMPv2-SMI::enterprises.6027.3.9.1.5.1.9.1.1.4.10.1.1.0.24.0.0.0.0 = "" SNMPv2-SMI::enterprises.6027.3.9.1.5.1.9.1.1.4.10.1.1.1.32.1.4.10.1.1.1.1.4.10.1.1.1 = HexSTRING: 4C 76 25 F4 AB 02 SNMPv2-SMI::enterprises.6027.3.9.1.5.1.9.1.1.4.10.1.1.2.32.1.4.127.0.0.1.1.4.127.0.0.1 = "" SNMPv2-SMI::enterprises.6027.3.9.1.5.1.9.1.1.4.20.1.1.0.24.0.0.0.0 = "" SNMPv2-SMI::enterprises.6027.3.9.1.5.1.9.1.1.4.20.1.1.1.32.1.4.20.1.1.1.1.4.20.1.1.1 = HexSTRING: 4C 76 25 F4 AB 02 SNMPv2-SMI::enterprises.6027.3.9.1.5.1.9.1.
SNMPv2-SMI::enterprises.6027.3.9.1.5.1.10.1.1.4.100.100.100.0.24.1.4.30.1.1.1.1.4.30.1.1.1 = STRING: "Po 20" SNMPv2-SMI::enterprises.6027.3.9.1.5.1.11.1.1.4.10.1.1.0.24.0.0.0.0 = Gauge32: 0 SNMPv2-SMI::enterprises.6027.3.9.1.5.1.11.1.1.4.10.1.1.1.32.1.4.10.1.1.1.1.4.10.1.1.1 = Gauge32: 0 SNMPv2-SMI::enterprises.6027.3.9.1.5.1.11.1.1.4.10.1.1.2.32.1.4.127.0.0.1.1.4.127.0.0.1 = Gauge32: 0 SNMPv2-SMI::enterprises.6027.3.9.1.5.1.11.1.1.4.20.1.1.0.24.0.0.0.0 = Gauge32: 0 SNMPv2-SMI::enterprises.6027.3.9.1.5.1.
dellNetFpIngPortSTPnotFwdDrops 1.3.6.1.4.1.6027.3.27.1.3.1.3 Packets dropped due to Spanning Tree State not in forwarding state. dellNetFpIngIPv4L3Discards 1.3.6.1.4.1.6027.3.27.1.3.1.4 IPv4 L3 Discards dellNetFpIngPolicyDiscards 1.3.6.1.4.1.6027.3.27.1.3.1.5 Packet dropped due to policy discards. dellNetFpIngPacketsDroppedByDELLNETFP 1.3.6.1.4.1.6027.3.27.1.3.1.6 Packets dropped by forwarding plane. dellNetFpIngL2L3Drops 1.3.6.1.4.1.6027.3.27.1.3.1.7 L2 L3 packets dropped.
dellNetFpWredOutOfProfileDrops 1.3.6.1.4.1.6027.3.27.1.3.1.31 Wred Out-Of-Profile Drops Counter. Viewing the FEC BER Details • To view the FEC BER details using SNMP, use the following command: ~ $ snmpwalk -c public -v 2c 10.16.210.151 1.3.6.1.4.1.6027.3.27.1.3.1.25 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.25.2097166 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.25.2097678 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.25.2098180 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.25.2098308 SNMPv2-SMI::enterprises.6027.3.27.1.
SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2103310 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2103822 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2104334 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2104846 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2105358 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2105870 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2106382 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2106894 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.2107406 SNMPv2-SMI::enterprises.6027.3.27.1.3.1.26.
MIB Support for entAliasMappingTable Dell EMC Networking provides a method to map the physical interface to its corresponding ifindex value. The entAliasMappingTable table contains zero or more rows, representing the logical entity mapping and physical component to external MIB identifiers. The following table lists the related MIB objects: Table 111. MIB Objects for entAliasMappingTable MIB Object OID Description entAliasMappingTable 1.3.6.1.2.1.47.1.3.
MIB Object OID Description dot3adAgg 1.2.840.10006.300.43.1.1 dot3adAggTable 1.2.840.10006.300.43.1.1.1 Contains information about every Aggregator that is associated with a system. dot3adAggEntry 1.2.840.10006.300.43.1.1.1.1 Contains a list of Aggregator parameters and indexed by the ifIndex of the Aggregator. dot3adAggMACAddress 1.2.840.10006.300.43.1.1.1.1.1 Contains a six octet read–only value carrying the individual MAC address assigned to the Aggregator. dot3adAggActorSystemPriority 1.
MIB Object OID Description dot3adAggPortListPorts 1.2.840.10006.300.43.1.1.2.1.1 Contains a complete set of ports currently associated with the Aggregator. Viewing the LAG MIB • To view the LAG MIB generated by the system, use the following command. snmpbulkget -v 2c -c LagMIB 10.16.148.157 1.2.840.10006.300.43.1.1.1.1.1 iso.2.840.10006.300.43.1.1.1.1.1.1258356224 iso.2.840.10006.300.43.1.1.1.1.1.1258356736 iso.2.840.10006.300.43.1.1.1.1.2.1258356224 iso.2.840.10006.300.43.1.1.1.1.2.1258356736 iso.2.
iso.0.8802.1.1.2.1.4.1.1.6.0.3161605.2 = INTEGER: 5 iso.0.8802.1.1.2.1.4.1.1.6.0.4209668.6 = INTEGER: 5 iso.0.8802.1.1.2.1.4.1.1.6.0.4210181.2 = INTEGER: 5 iso.0.8802.1.1.2.1.4.1.1.6.0.9437185.2 = INTEGER: 5 iso.0.8802.1.1.2.1.4.1.1.7.0.2113029.2 = STRING: "fortyGigE 1/50" iso.0.8802.1.1.2.1.4.1.1.7.0.3161092.6 = STRING: "TenGigabitEthernEt 0/39" iso.0.8802.1.1.2.1.4.1.1.7.0.3161605.2 = STRING: "fortyGigE 1/49" iso.0.8802.1.1.2.1.4.1.1.7.0.4209668.6 = STRING: "TenGigabitEthernEt 0/40" iso.0.8802.1.1.2.1.4.
Viewing the Details of Organizational Specific Unrecognized LLDP TLVs • To view the information of organizational specific unrecognized LLDP TLVs using SNMP, use the following commands. snmpwalk -v2c -c public 10.16.150.83 1.0.8802.1.1.2.1.4.4.1.4 iso.0.8802.1.1.2.1.4.4.1.4.0.3161092.1.0.1.102.1.133 iso.0.8802.1.1.2.1.4.4.1.4.0.3161092.1.0.1.102.2.134 iso.0.8802.1.1.2.1.4.4.1.4.0.3161092.1.0.1.102.3.135 iso.0.8802.1.1.2.1.4.4.1.4.0.3161092.1.0.1.102.4.136 iso.0.8802.1.1.2.1.4.4.1.4.0.3161092.1.0.1.102.5.
SNMPv2-SMI::enterprises.6027.3.7.1.1.3.1.12.1.1.3 = INTEGER: 0 SNMPv2-SMI::enterprises.6027.3.7.1.1.3.1.12.1.1.4 = INTEGER: 0 snmpwalk -c public -v 2c 10.16.133.177 1.3.6.1.4.1.6027.3.7.1.1.3.1.16 SNMPv2-SMI::enterprises.6027.3.7.1.1.3.1.16.1.1.1 SNMPv2-SMI::enterprises.6027.3.7.1.1.3.1.16.1.1.2 SNMPv2-SMI::enterprises.6027.3.7.1.1.3.1.16.1.1.3 SNMPv2-SMI::enterprises.6027.3.7.1.1.3.1.16.1.1.
NOTE: For the VLT-LAG interfaces, the snmp-server traps mac-notification command should be enabled on both the interfaces. If the command is configured only on one VLT node, then you cannot see any VLT mismatch in the system. The snmp-server traps mac-notification is not visible under ICL interface and no TRAPS are supported. Manage VLANs using SNMP The qBridgeMIB managed objects in Q-BRIDGE-MIB, defined in RFC 2674, allows you to use SNMP to manage VLANs.
NOTE: Whether adding a tagged or untagged port, specify values for both dot1qVlanStaticEgressPorts and dot1qVlanStaticUntaggedPorts. Example of Adding an Untagged Port to a VLAN using SNMP In the following example, Port 0/2 is added as an untagged 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.
To set time to wait till bgp session are up set 1.3.6.1.4.1.6027.3.18.1.3 and 1.3.6.1.4.1.6027.3.18.1.6 Enabling and Disabling a Port using SNMP To enable and disable a port using SNMP, use the following commands. 1 Create an SNMP community on the Dell system. CONFIGURATION mode snmp-server community 2 From the Dell EMC Networking system, identify the interface index of the port for which you want to change the admin status.
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. For example, the decimal equivalent of E8 is 232, and so the instance number for MAC address 00:01:e8:06:95:ac is.0.1.232.6.149.172. The value of dot1dTpFdbPort is the port number of the port off which the system learns the MAC address.
interface is physical, so represent this type of interface by a 0 bit, and the unused bit is always 0. These 2 bits are not given because they are the most significant bits, and leading zeros are often omitted. To display the interface number, use the following command. • Display the interface index number.
• sho run bgp • router bgp 100 • address-family ipv4 vrf vrf1 • snmp context context1 • neighbor 20.1.1.1 remote-as 200 • neighbor 20.1.1.1 no shutdown • exit-address-family • address-family ipv4 vrf vrf2 • snmp context context2 • timers bgp 30 90 • neighbor 30.1.1.1 remote-as 200 • neighbor 30.1.1.1 no shutdown • exit-address-family To map the context to a VRF instance for SNMPv3, follow these steps: 1 2 Create a community and map a VRF to it.
SNMPv2-SMI::enterprises.6027.20.1.2.3.2.1.3.0.1.20.1.1.2.1.20.1.1.1 SNMPv2-SMI::enterprises.6027.20.1.2.3.2.1.4.0.1.20.1.1.2.1.20.1.1.1 SNMPv2-SMI::enterprises.6027.20.1.2.3.2.1.5.0.1.20.1.1.2.1.20.1.1.1 SNMPv2-SMI::enterprises.6027.20.1.2.3.3.1.1.0.1.20.1.1.2.1.20.1.1.1 SNMPv2-SMI::enterprises.6027.20.1.2.3.3.1.2.0.1.20.1.1.2.1.20.1.1.
Example of Viewing Changed Interface State for Monitored Ports Layer 3 LAG does not include this support. SNMP trap works for the Layer 2 / Layer 3 / default mode LAG. SNMPv2-MIB::sysUpTime.0 = Timeticks: (8500842) 23:36:48.42 SNMPv2-MIB::snmpTrapOID.0 = OID: IF-MIB::linkDown IF-MIB::ifIndex.33865785 = INTEGER: 33865785 SNMPv2-SMI::enterprises.6027.3.1.1.4.1.2 = STRING: "OSTATE_DN: Changed interface state Te 1/1/1" 2010-02-10 14:22:39 10.16.130.4 [10.16.130.4]: SNMPv2-MIB::sysUpTime.
SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.14.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.15.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.16.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.17.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.18.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.19.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.20.2113540 SNMPv2-SMI::enterprises.6027.3.11.1.3.1.1.21.2113540 = = = = = = = = "" "" STRING: "29.109375" STRING: "3.286000" STRING: "7.
50 Storm Control Storm control allows you to control unknown-unicast, muticast, and broadcast traffic on Layer 2 and Layer 3 physical interfaces. Dell EMC Networking Operating System (OS) Behavior: Dell EMC Networking OS supports unknown-unicast, muticast, and broadcast control for Layer 2 and Layer 3 traffic. To view the storm control broadcast configuration show storm-control broadcast | multicast | unknown-unicast | pfc-llfc[interface] command.
• The storm control is calculated in packets per second. • Configure storm control. • INTERFACE mode Configure the packets per second of broadcast traffic allowed on an interface (ingress only). INTERFACE mode storm-control broadcast packets_per_second in • Configure the packets per second of multicast traffic allowed on C-Series or S-Series interface (ingress only) network only.
Detect PFC Storm The following section explains the procedure to detect the PFC storm. You can detect the PFC storm by polling the lossless queues in a port or priority periodically. When the queue depth is not equal to zero or when the queue has traffic after subsequent number of polling, then the port or priority is detected to have the PFC storm. • • • Use the polling—interval {interval in milli-seconds} command to set the polling interval. The queue traffic and egress counters are polled.
-------------------------------------------------------------------------------Te 0/0 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 Te 0/1 3 0 0 0 4 0 0 0 5 0 0 0 6 0 0 0 Te 0/2 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 Te 0/3 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 Te 0/4 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 Te 0/5 3 2 0 0 4 2 0 0 5 2 0 0 6 2 0 0 Te 0/80 3 0 0 0 4 0 0 0 5 0 0 0 6 0 0 0 DellEMC# 896 Storm Control
51 Spanning Tree Protocol (STP) The spanning tree protocol (STP) is supported on Dell EMC Networking OS.
Configure Spanning Tree Configuring spanning tree is a two-step process.
Configuring Interfaces for Layer 2 Mode All interfaces on all switches that participate in spanning tree must be in Layer 2 mode and enabled. Figure 116. Example of Configuring Interfaces for Layer 2 Mode 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.
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. DellEMC(conf-if-te-1/1/1)#show config ! interface TenGigabitEthernet 1/1/1 no ip address switchport no shutdown DellEMC(conf-if-te-1/1/1)# Enabling Spanning Tree Protocol Globally Enable the spanning tree protocol globally; it is not enabled by default.
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.
Adding an Interface to the Spanning Tree Group To add a Layer 2 interface to the spanning tree topology, use the following command. • Enable spanning tree on a Layer 2 interface. INTERFACE mode spanning-tree 0 Modifying Global Parameters You can modify the spanning tree 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 STP.
PROTOCOL SPANNING TREE mode hello-time seconds NOTE: With large configurations (especially those with more ports) Dell EMC Networking recommends increasing the hello-time. The range is from 1 to 10. • the default is 2 seconds. Change the max-age parameter (the refresh interval for configuration information that is generated by recomputing the spanning tree topology). PROTOCOL SPANNING TREE mode max-age seconds The range is from 6 to 40. The default is 20 seconds.
Enabling PortFast The PortFast feature enables interfaces to begin forwarding traffic approximately 30 seconds sooner. Interfaces forward frames by default until they receive a BPDU that indicates that they should behave otherwise; they do not go through the Learning and Listening states. The bpduguard shutdown-on-violation option causes the interface hardware to be shut down when it receives a BPDU.
• 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). • You can clear the Error Disabled state with any of the following methods: • Perform a shutdown command on the interface.
Configured hello time 2, max age 20, forward delay 15 Interface Name PortID Prio ------------ -------Te 1/6/1 128.263 128 Te 1/7/1 128.264 128 Designated Cost Sts Cost Bridge ID PortID ---- ------- --- ------- -------------------20000 FWD 20000 32768 0001.e805.fb07 128.653 20000 EDS 20000 32768 0001.e85d.0e90 128.264 Interface Name Role PortID Prio Cost Sts Cost Link-type Edge ------------ ------ -------- ---- ------- --- ---------------Te 1/6/1 Root 128.263 128 20000 FWD 20000 P2P No Te 1/7/1 ErrDis 128.
Root Guard Scenario For example, as shown in the following illustration (STP topology 1, upper left) Switch A is the root bridge in the network core. Switch C functions as an access switch connected to an external device. The link between Switch C and Switch B is in a Blocking state. The flow of STP BPDUs is shown in the illustration. In STP topology 2 (shown in the upper right), STP is enabled on device D on which a software bridge application is started to connect to the network.
• Spanning Tree Protocol (STP) • Rapid Spanning Tree Protocol (RSTP) • Multiple Spanning Tree Protocol (MSTP) • Per-VLAN Spanning Tree Plus (PVST+) • When enabled on a port, root guard applies to all VLANs configured on the port. • You cannot enable root guard and loop guard at the same time on an STP port. For example, if you configure root guard on a port on which loop guard is already configured, the following error message displays: • % Error: LoopGuard is configured.
Example of Configuring all Spanning Tree Types to be Hitless DellEMC(conf)#redundancy protocol xstp DellEMC#show running-config redundancy ! redundancy protocol xstp DellEMC# 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.
Figure 120. STP Loop Guard Prevents Forwarding Loops Configuring Loop Guard Enable STP loop guard on a per-port or per-port channel basis. The following conditions apply to a port enabled with loop guard: • Loop guard is supported on any STP-enabled port or port-channel interface.
• • 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. For example, when Portfast BPDU guard and loop guard are both configured: • If a BPDU is received from a remote device, BPDU guard places the port in an Err-Disabled Blocking state and no traffic is forwarded on the port.
52 SupportAssist SupportAssist sends troubleshooting data securely to Dell. SupportAssist in this Dell EMC Networking OS release does not support automated email notification at the time of hardware fault alert, automatic case creation, automatic part dispatch, or reports. SupportAssist requires Dell EMC Networking OS 9.9(0.0) and SmartScripts 9.7 or later to be installed on the Dell EMC Networking device. For more information on SmartScripts, see Dell EMC Networking Open Automation guide. Figure 121.
Configuring SupportAssist Using a Configuration Wizard You are guided through a series of queries to configure SupportAssist. The generated commands are added to the running configuration, including the DNS resolve commands, if configured. This command starts the configuration wizard for the SupportAssist. At any time, you can exit by entering Ctrl-C. If necessary, you can skip some data entry. Enable the SupportAssist service.
making such transfers, Dell shall ensure appropriate protection is in place to safeguard the Collected Data being transferred in connection with SupportAssist. If you are downloading SupportAssist on behalf of a company or other legal entity, you are further certifying to Dell that you have appropriate authority to provide this consent on behalf of that entity.
support-assist activity {full-transfer | core-transfer} start now DellEMC#support-assist activity full-transfer start now DellEMC#support-assist activity core-transfer start now Configuring SupportAssist Activity SupportAssist Activity mode allows you to configure and view the action-manifest file for a specific activity. To configure SupportAssist activity, use the following commands. 1 Move to the SupportAssist Activity mode for an activity.
action-manifest remove DellEMC(conf-supportassist-act-full-transfer)#action-manifest remove custom_file1.json DellEMC(conf-supportassist-act-full-transfer)# DellEMC(conf-supportassist-act-event-transfer)#action-manifest remove custom_event_file1.json DellEMC(conf-supportassist-act-event-transfer)# 6 Enable a specific SupportAssist activity. By default, the full transfer includes the core files. When you disable the core transfer activity, the full transfer excludes the core files.
Configuring SupportAssist Person SupportAssist Person mode allows you to configure name, email addresses, phone, method and time zone for contacting the person. SupportAssist Person configurations are optional for the SupportAssist service. To configure SupportAssist person, use the following commands. 1 Configure the contact name for an individual.
[no] server server-name DellEMC(conf-supportassist)#server default DellEMC(conf-supportassist-serv-default)# 2 Configure a proxy for reaching the SupportAssist remote server. SUPPORTASSIST SERVER mode [no] proxy-ip-address {ipv4-address | ipv6-address}port port-number [ username userid password [encryption-type] password ] DellEMC(conf-supportassist-serv-default)#proxy-ip-address 10.0.0.
show running-config support-assist DellEMC# show running-config support-assist ! support-assist enable all ! activity event-transfer enable action-manifest install default ! activity core-transfer enable ! contact-company name Dell street-address F lane , Sector 30 address city Brussels state HeadState country Belgium postalcode S328J3 ! contact-person first Fred last Nash email-address primary des@sed.com alternate sed@dol.
53 System Time and Date System time and date settings and the network time protocol (NTP) are supported on Dell EMC Networking OS. You can set system times and dates and maintained through the NTP. They are also set through the Dell EMC Networking Operating System (OS) command line interfaces (CLIs) and hardware settings. The Dell EMC Networking OS supports reaching an NTP server through different VRFs. You can configure a maximum of eight logging servers across different VRFs or the same VRF.
Following conventions established by the telephone industry [BEL86], the accuracy of each server is defined by a number called the stratum, with the topmost level (primary servers) assigned as one and each level downwards (secondary servers) in the hierarchy assigned as one greater than the preceding level. Dell EMC Networking OS synchronizes with a time-serving host to get the correct time. You can set Dell EMC Networking OS to poll specific NTP time-serving hosts for the current time.
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 EMC Networking system synchronizes. To specify multiple servers, enter the command multiple times. You may specify an unlimited number of servers at the expense of CPU resources. • Specify the NTP server to which the Dell EMC Networking system synchronizes.
Disabling NTP on an Interface By default, NTP is enabled on all active interfaces. If you disable NTP on an interface, Dell EMC 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. INTERFACE mode ntp disable To view whether NTP is configured on the interface, use the show config command in INTERFACE mode. If ntp disable is not listed in the show config command output, NTP is enabled.
startup-configuration from an Dell EMC Networking OS version in which you have configured ntp authentication-key, the system cannot correctly decrypt the key and cannot authenticate the NTP packets. In this case, re-enter this command and save the runningconfig to the startup-config. To configure NTP authentication, use the following commands. 1 Enable NTP authentication. CONFIGURATION mode ntp authenticate 2 Set an authentication key.
rtdel 0219 (8.193970), rtdsp AF928 (10973.266602), refid C0A80101 (192.168.1.1) ref CD7F4F63.6BE8F000 (14:51:15.421 UTC Thu Apr 2 2009) org CD7F4F63.68000000 (14:51:15.406 UTC Thu Apr 2 2009) rec CD7F4F63.6BE8F000 (14:51:15.421 UTC Thu Apr 2 2009) xmt CD7F5368.D0535000 (15:8:24.813 UTC Thu Apr 2 2009) 1w6d23h : NTP: rcv packet from 192.168.1.1 leap 0, mode 4, version 3, stratum 1, ppoll 1024 rtdel 0000 (0.000000), rtdsp AF587 (10959.090820), refid 4C4F434C (76.79.67.76) ref CD7E14FD.43F7CED9 (16:29:49.
ntp authentication-key 345 md5 5A60910F3D211F02 ntp server 11.1.1.1 version 3 ntp trusted-key 345 DellEMC# Configuring a Custom-defined Period for NTP time Synchronization You can configure the system to send an audit log message to a syslog server if the time difference from the NTP server is greater than a threshold value (offset-threshold). However, time synchronization still occurs. To configure the offset-threshold, follow this procedure.
• year: enter a four-digit number as the year. The range is from 1993 to 2035. Example of the clock set Command DellEMC#clock set 16:20:00 9 september 2017 DellEMC# Setting the Timezone Universal time coordinated (UTC) is the time standard based on the International Atomic Time standard, commonly known as Greenwich Mean time. When determining system time, include the differentiator between UTC and your local timezone. For example, San Jose, CA is the Pacific Timezone with a UTC offset of -8.
• start-year: enter a four-digit number as the year. The range is from 1993 to 2035. • start-time: enter the time in hours:minutes. For the hour variable, use the 24-hour format; example, 17:15 is 5:15 pm. • end-month: enter the name of one of the 12 months in English. You can enter the name of a day to change the order of the display to time day month year. • end-day: enter the number of the day. The range is from 1 to 31.
• end-time: Enter the time in hours:minutes. For the hour variable, use the 24-hour format; example, 17:15 is 5:15 pm. • offset: (OPTIONAL) Enter the number of minutes to add during the summer-time period. The range is from 1 to1440. The default is 60 minutes. Examples of the clock summer-time recurring Command The following example shows the clock summer-time recurring command.
54 Tunneling 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.
DellEMC(conf-if-tu-2)#show config ! 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): DellEMC(conf)#interface tunnel 3 DellEMC(conf-if-tu-3)#tunnel source 5::5 DellEMC(conf-if-tu-3)#tunnel destination 8::9 DellEMC(conf-if-tu-3)#tunnel mode ipv6 DellEMC(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. DellEMC(conf-if-te-1/1/1)#show config ! interface TenGigabitEthernet 1/1/1 ip address 20.1.1.
Configuring Tunnel source anylocal Decapsulation The tunnel source anylocal command allows a multipoint receive-only 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. The source anylocal parameters can be used for packet decapsulation instead of the ip address or interface (tunnel allowremote command), but only on multipoint receive-only mode tunnels.
55 Uplink Failure Detection (UFD) 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 123. 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 124. 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.
• If one of the upstream interfaces in an uplink-state group goes down, either a user-configurable set of downstream ports or all the downstream ports in the group are put in an Operationally Down state with an UFD Disabled error. The order in which downstream ports are disabled is from the lowest numbered port to the highest.
NOTE: Downstream interfaces in an uplink-state group are put into a Link-Down state with an UFD-Disabled error message only when all upstream interfaces in the group go down. To revert to the default setting, use the no downstream disable links command. 4 (Optional) Enable auto-recovery so that UFD-disabled downstream ports in the uplink-state group come up when a disabled upstream port in the group comes back up.
Example of Syslog Messages Before and After Entering the clear ufd-disable uplink-state-group Command (S50) The following example message shows the Syslog messages that display when you clear the UFD-Disabled state from all disabled downstream interfaces in an uplink-state group by using the clear ufd-disable uplink-state-group group-id command. All downstream interfaces return to an operationally up state.
• • • • For a 50-Gigabit Ethernet interface, enter the keyword fiftyGigE then the slot/port/subport information. For a 100-Gigabit Ethernet interface, enter the keyword hundredGigE then the slot/port/subport information. For a port channel interface, enter the keywords port-channel then a number. 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.
uplink-state-group 16 no enable description test downstream disable links all downstream TenGigabitEthernet 1/21/1 upstream TenGigabitEthernet 1/22/1 upstream Port-channel 8 Sample Configuration: Uplink Failure Detection The following example shows a sample configuration of UFD on a switch/router in which you configure as follows. • Configure uplink-state group 3. • Add downstream links Tengigabitethernet 1/1/1, 1/2/1, 1/5/1, 1/9/1, 1/11/1, and 1/12/1.
56 Upgrade Procedures To find the upgrade procedures, go to the Dell EMC Networking OS Release Notes for your system type to see all the requirements needed to upgrade to the desired Dell EMC Networking OS version. To upgrade your system type, follow the procedures in the Dell EMC Networking OS Release Notes. You can download the release notes of your platform at http://www.force10networks.com. Use your login ID to log in to the website.
57 Virtual LANs (VLANs) Virtual LANs (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 system supports up to 4093 port-based VLANs and one default VLAN, as specified in IEEE 802.1Q.
Default VLAN When you configure interfaces for Layer 2 mode, they are automatically placed in the Default VLAN as untagged interfaces. Only untagged interfaces can belong to the Default VLAN. The following example displays the outcome of placing an interface in Layer 2 mode. To configure an interface for Layer 2 mode, use the switchport command.
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. 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.
• Configure a port-based VLAN (if the VLAN-ID is different from the Default VLAN ID) and enter INTERFACE VLAN mode. CONFIGURATION mode interface vlan vlan-id To activate the VLAN, after you create a VLAN, assign interfaces in Layer 2 mode to the VLAN. Example of Verifying a Port-Based VLAN To view the configured VLANs, use the show vlan command in EXEC Privilege mode.
Codes: * - Default VLAN, G - GVRP VLANs NUM Status Q * 1 Inactive 2 Active T T 3 Active T T Ports Po1(So 0/0-1) Te 1/1/1 Po1(So 0/0-1) Te 1/2/1 DellEMC#config DellEMC(conf)#interface vlan 4 DellEMC(conf-if-vlan)#tagged po 1 DellEMC(conf-if-vlan)#show conf ! interface Vlan 4 no ip address tagged Port-channel 1 DellEMC(conf-if-vlan)#end DellEMC#show vlan Codes: * - Default VLAN, G - GVRP VLANs NUM Status Q * 1 Inactive 2 Active T T 3 Active T T 4 Active T Ports Po1(So 0/0-1) Te 1/1/1 Po1(So 0/0-1) Te 1/2/1
Codes: * - Default VLAN, G - GVRP VLANs NUM * 1 2 Status Active Active 3 Active Q U T T T T Ports Te 1/2/1 Po1(So 0/0-1) Te 1/3/1 Po1(So 0/0-1) Te 1/1/1 4 Inactive DellEMC#conf DellEMC(conf)#interface vlan 4 DellEMC(conf-if-vlan)#untagged tengigabitethernet 1/2/1 DellEMC(conf-if-vlan)#show config ! interface Vlan 4 no ip address untagged TenGigabitEthernet 1/2/1 DellEMC(conf-if-vlan)#end DellEMC#show vlan Codes: * - Default VLAN, G - GVRP VLANs NUM * 1 2 3 4 Status Q Inactive Active T T Active T T Ac
Native VLAN support breaks this barrier so that you can connect a port to both VLAN-aware and VLAN-unaware stations. Such ports are referred to as hybrid ports. Physical and port-channel interfaces may be hybrid ports. Native VLAN is useful in deployments where a Layer 2 port can receive both tagged and untagged traffic on the same physical port. The classic example is connecting a voice-over-IP (VOIP) phone and a PC to the same port of the switch.
58 Virtual Link Trunking (VLT) Virtual link trunking (VLT) is a Dell EMC technology that provides two Dell EMC switches the ability to function as a single switch. VLT allows physical links between two Dell EMC switches to appear as a single virtual link to the network core or other switches such as Edge, Access, or top-of-rack (ToR). As a result, the two physical switches appear as a single switch to the connected devices.
Figure 127. VLT providing multipath VLT reduces the role of spanning tree protocols (STPs) by allowing link aggregation group (LAG) terminations on two separate distribution or core switches and supporting a loop-free topology. To prevent the initial loop that may occur prior to VLT being established, use a spanning tree protocol. After VLT is established, you may use rapid spanning tree protocol (RSTP) to prevent loops from forming with new links that are incorrectly connected and outside the VLT domain.
Figure 128. Example of VLT Deployment VLT offers the following benefits: • Allows a single device to use a LAG across two upstream devices. • Eliminates STP-blocked ports. • Provides a loop-free topology. • Uses all available uplink bandwidth. • Provides fast convergence if either the link or a device fails. • Optimized forwarding with virtual router redundancy protocol (VRRP). • Provides link-level resiliency. • Assures high availability. • Active-Active load sharing with VRRP.
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 connectivity between the 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. Both ends must be on 10G, 25G, 40G, 50G, or 100G interfaces.
Layer-2 Traffic in VLT Domains In a VLT domain, the MAC address of any host connected to the VLT peers is synchronized between the VLT nodes. In the following example, VLAN 10 is spanned across three VLT domains. Figure 129. Layer-2 Traffic in VLT Domains If Host 1 from a VLT domain sends a frame to Host 2 in another VLT domain, the frame can use any link shown to reach Host 2.
30 30 30 30 30 30 a0:00:a1:00:00:07 a0:00:a1:00:00:08 a0:00:a1:00:00:09 a0:00:a1:00:00:0a a0:00:a1:00:00:0b a0:00:a1:00:00:0c Dynamic Dynamic Dynamic Dynamic Dynamic Dynamic (N) Po 11 Active (N) Po 11 Active (N) Po 11 Active (N) Po 11 Active (N) Po 11 Active Po 11 Active VLT-10-PEER-2#show vlt statistics mac VLT MAC Statistics -------------------L2 Info Pkts sent:0, L2 Mac-sync Pkts Sent:7 L2 Info Pkts Rcvd:0, L2 Mac-sync Pkts Rcvd:9 L2 Reg Request sent:0 L2 Reg Request rcvd:0 L2 Reg Response sent:0 L2
Figure 130. VLT on Core Switches The aggregation layer is mostly in the L2/L3 switching/routing layer. For better resiliency in the aggregation, Dell EMC Networking recommends running the internal gateway protocol (IGP) on the VLTi VLAN to synchronize the L3 routing table across the two nodes on a VLT system. Enhanced VLT Enhanced VLT (eVLT)) refers to the ability to connect two VLT domains.
Figure 131. Enhanced VLT 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 • You cannot enable stacking simultaneously with VLT. If you enable both at the same time, unexpected behavior can occur. • 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.
• When you enable IGMP snooping on the VLT peers, ensure the value of the delay-restore command is not less than the query interval. • When you enable Layer 3 routing protocols on VLT peers, make sure the delay-restore timer is set to a value that allows sufficient time for all routes to establish adjacency and exchange all the L3 routes between the VLT peers before you enable the VLT ports.
• • Each VLT domain has a unique MAC address that you create or VLT creates automatically. • ARP tables are synchronized between the VLT peer nodes. • VLT peer switches operate as separate chassis with independent control and data planes for devices attached on non-VLT ports. • One device in the VLT domain is assigned a primary role; the other device takes the secondary role. The primary and secondary roles are required for scenarios when connectivity between the chassis is lost.
• • • In the backup link between peer switches, heartbeat messages are exchanged between the two chassis for health checks. The default time interval between heartbeat messages over the backup link is 1 second. You can configure this interval. The range is from 1 to 5 seconds. DSCP marking on heartbeat messages is CS6.
• Software features not supported with VLT • • • • In a VLT domain, the following software features are not supported on VLT ports: 802.1x, GVRP, and VXLAN. VLT and VRRP interoperability • In a VLT domain, VRRP interoperates with virtual link trunks that carry traffic to and from access devices (see Overview). The VLT peers belong to the same VRRP group and are assigned master and backup roles. Each peer actively forwards L3 traffic, reducing the traffic flow over the VLT interconnect.
addresses to be re-learned. However, enabling RSTP can detect potential loops caused by non-system issues such as cabling errors or incorrect configurations. To minimize possible topology changes after link or node failure, RSTP is useful for potential loop detection. Configure RSTP using the following specifications.
• Statistics and Counters — Statistical and counter information displays IPv6 information when applicable. • Heartbeat — You can configure an IPv4 or IPv6 address as a backup link destination. You cannot use an IPv4 and an IPv6 address simultaneously. VLT Port Delayed Restoration When a VLT node boots up, if the VLT ports have been previously saved in the start-up configuration, they are not immediately enabled.
Figure 132. PIM-Sparse Mode Support on VLT On each VLAN where the VLT peer nodes act as the first hop or last hop routers, one of the VLT peer nodes is elected as the PIM designated router. If you configured IGMP snooping along with PIM on the VLT VLANs, you must configure VLTi as the static multicast router port on both VLT peer switches. This ensures that for first hop routers, the packets from the source are redirected to the designated router (DR) if they are incorrectly hashed.
Each VLT peer runs its own PIM protocol independently of other VLT peers. To ensure the PIM protocol states or multicast routing information base (MRIB) on the VLT peers are synced, if the incoming interface (IIF) and outgoing interface (OIF) are Spanned, the multicast route table is synced between the VLT peers. To verify the PIM neighbors on the VLT VLAN and on the multicast port, use the show ip pim neighbor, show ip igmp snooping mrouter, and show running config commands.
Figure 133. Packets without peer routing enabled If you enable peer routing, a VLT node acts as a proxy gateway for its connected VLT peer as shown in the image below. Even though the gateway address of the packet is different, Peer-1 routes the packet to its destination on behalf of Peer-2 to avoid sub-optimal routing. Figure 134. Packets with peer routing enabled Benefits of Peer Routing • • Avoids sub-optimal routing • Reduces latency by avoiding another hop in the traffic path.
• You can reduce the number of VLTi port channel members based on your specific design. With peer routing, you need not configure VRRP for the participating VLANs. As both VLT nodes act as a gateway for its peer, irrespective of the gateway IP address, the traffic flows upstream without any latency. There is no limitation for the number of VLANS. VLT Unicast Routing VLT unicast routing is a type of VLT peer routing that locally routes unicast packets destined for the L3 endpoint of the VLT peer.
The advantages of syncing the multicast routes between VLT peers are: • 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.
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.
Configure RSTP on VLT Peers to Prevent Forwarding Loops (VLT Peer 1) Dell_VLTpeer1(conf)#protocol spanning-tree rstp Dell_VLTpeer1(conf-rstp)#no disable Dell_VLTpeer1(conf-rstp)#bridge-priority 4096 Configure RSTP on VLT Peers to Prevent Forwarding Loops (VLT Peer 2) Dell_VLTpeer2(conf)#protocol spanning-tree rstp Dell_VLTpeer2(conf-rstp)#no disable Dell_VLTpeer2(conf-rstp)#bridge-priority 0 Configuring VLT To configure VLT, use the following procedure.
3 Add one or more port interfaces to the port channel. INTERFACE PORT-CHANNEL mode channel-member interface interface: specify one of the following interface types: 4 • For a 10-Gigabit Ethernet interface, enter the keyword TenGigabitEthernet then the slot/port/subport information. • For a 25-Gigabit Ethernet interface, enter the keyword twentyFiveGigE then the slot/port/subport information. • For a 40-Gigabit Ethernet interface, enter the keyword fortyGigE then the slot/port/subport information.
5 (Optional) After you configure a VLT domain on each peer switch and connect (cable) the two VLT peers on each side of the VLT interconnect, the system elects a primary and secondary VLT peer device (see Primary and Secondary VLT Peers). To configure the primary and secondary roles before the election process, use the primary-priority command. Enter a lower value on the primary peer and a higher value on the secondary peer.
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.
To explicitly configure the default values on each peer switch, use the unit-id command. Configure a different unit ID (0 or 1) on each peer switch. Unit IDs are used for internal system operations. 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. Connecting a VLT Domain to an Attached Access Device (Switch or Server) To connect a VLT domain to an attached access device, use the following commands.
Configuring a VLT VLAN Peer-Down (Optional) To configure a VLT VLAN peer-down, 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 is from 1 to 1000. 2 Enter the port-channel number that acts as the interconnect trunk.
5 Configure the IP address of the management interface on the remote VLT peer to be used as the endpoint of the VLT backup link for sending out-of-band hello messages. VLT DOMAIN CONFIGURATION mode back-up destination ip-address [interval seconds] You can optionally specify the time interval used to send hello messages. The range is from 1 to 5 seconds. 6 When you create a VLT domain on a switch, Dell EMC Networking OS automatically creates a VLT-system MAC address used for internal system operations.
13 Enable LACP on the LAN port. INTERFACE mode port-channel-protocol lacp 14 Configure the LACP port channel mode. INTERFACE mode port-channel number mode [active] 15 Ensure that the interface is active. MANAGEMENT INTERFACE mode no shutdown 16 Enable peer routing. VLT DOMAIN CONFIGURATION mode peer-routing If you enable peer routing, a VLT node acts as the proxy gateway for its peer. 17 Repeat steps 1 through 16 for the VLT peer node in Domain 1.
8 Configure the VLT links between VLT peer 1 and VLT peer 2 to the top of rack unit (shown in the following example). 9 Configure the static LAG/LACP between ports connected from VLT peer 1 and VLT peer 2 to the top of rack unit. EXEC Privilege mode show running-config entity 10 Configure the VLT peer link port channel id in VLT peer 1 and VLT peer 2. EXEC mode or EXEC Privilege mode show interfaces interface 11 In the top of rack unit, configure LACP in the physical ports.
interface TenGigabitEthernet 1/4/1 no ip address ! port-channel-protocol LACP port-channel 2 mode active no shutdown configuring VLT peer lag in VLT Dell-2#show running-config interface port-channel 2 ! interface Port-channel 2 no ip address switchport vlt-peer-lag port-channel 2 no shutdown Dell-2#show interfaces port-channel 2 brief Codes: L - LACP Port-channel L LAG 2 Mode L2L3 Status up Uptime 03:33:14 Ports Te 1/4/1 (Up) In the ToR unit, configure LACP on the physical ports.
Local System MAC address Remote System MAC address Remote system version Delay-Restore timer : : : : 00:01:e8:8a:e9:91 00:01:e8:8a:e9:76 6(3) 90 seconds Delay-Restore Abort Threshold Peer-Routing Peer-Routing-Timeout timer Multicast peer-routing timeout DellEMC# : : : : 60 seconds Disabled 0 seconds 150 seconds Verify that the VLT LAG is up in VLT peer unit.
Root Bridge hello time 2, max age 20, forward delay 15 Bridge ID Priority 0, Address 90b1.1cf4.9b79 We are the root of Vlan 1000 Configured hello time 2, max age 20, forward delay 15 Interface Name ---------Po 1 Po 2 Te 1/10/1 Te 1/13/1 128.233 PortID -------128.2 128.3 128.230 128.233 Interface Name ---------Po 1 Po 2 Te 1/10/1 Te 1/10/3 DellEMC# Role -----Desg Desg Desg Desg Prio ---128 128 128 128 Cost -----188 2000 2000 2000 PortID -------128.2 128.3 128.230 128.
Figure 135. Peer Routing Configuration Example Dell-1 Switch Configuration In the following output, RSTP is enabled with a bridge priority of 0. This ensures that Dell-1 becomes the root bridge. DellEMC#1#show run | find protocol protocol spanning-tree pvst no disable vlan 1,20,800,900 bridge-priority 0 The following output shows the existing VLANs.
The following is the configuration in interfaces: DellEMC#1#sh run int ma0/0 interface ManagementEthernet 0/0 description Used_for_VLT_Keepalive ip address 10.10.10.1/24 no shutdown (The management interfaces are part of a default VRF and are isolated from the switch’s data plane.) In Dell-1, te 0/0 and te 0/1 are used for VLTi.
Port channel 2 connects the access switch A1. DellEMC#1#sh run int po2 interface Port-channel 2 description port-channel_to_access_switch_A1 no ip address portmode hybrid switchport vlt-peer-lag port-channel 2 no shutdown Vlan 20 is used in Dell-1, Dell-2, and R1 to form OSPF adjacency. When OSPF is converged, the routing tables in all devices are synchronized. DellEMC#1#sh run int vlan 20 interface Vlan 20 description OSPF PEERING VLAN ip address 192.168.20.
----------------Destination: Peer HeartBeat status: Destination VRF: HeartBeat Timer Interval: HeartBeat Timeout: UDP Port: HeartBeat Messages Sent: HeartBeat Messages Received: 10.10.10.2 Up default 1 3 34998 4 5 Use the show vlt detail command to verify that VLT is functional and that the correct VLANs are allowed.
Verify if peer routing has populated the CAM table with the correct information using the show cam mac command.
no ip address no shutdown The following example shows that te 0/0 and te 0/1 are included in port channel 10. Also note that configuration on the VLTi links does not contain the switchport command. Dell-2#sh run int po10 interface Port-channel 10 description VLTi Port-Channel no ip address channel-member TenGigabitEthernet 0/0-1 no shutdown Te 0/4 connects to the access switch A1.
tagged Port-channel 2 no shutdown The following output shows Dell-2 is configured with VLT domain 1. The peer-link port-channel command makes port channel 10 as the VLTi link. The peer-routing command enables peer routing between VLT peers in VLT domain 1. The IP address configured with the backupdestination command is the management IP address of the VLT peer (Dell-1). A priority value of 55000 makes Dell-2 as the secondary VLT peer.
network 192.168.8.0/24 area 0 network 192.168.9.0/24 area 0 network 172.16.1.0/24 area 0 network 192.168.20.0/29 area 0 passive-interface default no passive-interface vlan 20 While the passive-interface default command prevents all interfaces from establishing an OSPF neighborship, the no passive-interface vlan 20 command allows the interface for VLAN 20, the OSPF peering VLAN, to establish OSPF adjacencies. The following output displays that Dell-1 forms neighborship with Dell-2 and R1.
! interface Loopback4 ip address 4.4.4.2 255.255.255.0 R1#show run int port-channel 1 interface Port-channel1 switchport ip address 192.168.20.3 255.255.255.248 R1#show run | find router router ospf 1 router-id 172.15.1.1 passive-interface default no passive-interface Port-channel1 network 2.2.2.0 0.0.0.255 area 0 network 3.3.3.0 0.0.0.255 area 0 network 4.4.4.0 0.0.0.255 area 0 (The above subnets correspond to loopback interfaces lo2, lo3 and lo4.
This default route is configured for testing purposes, as described in the next section. The access switch (A1) is used to generate ICMP test PINGs to a loopback interface on CR1. This default route points to DellEMC#2’s VLAN 800 SVI interface. It’s in place to ensure that routed test traffic has DellEMC#2’s MAC address as the destination address in the Ethernet frame’s header When A1 sends a packet to R1, the VLT peers act as the default gateway for each other.
Domain_1_Peer1(conf-if-po-100)# vlt-peer-lag port-channel 100 Domain_1_Peer1(conf-if-po-100)# no shutdown Add links to the eVLT port-channel on Peer 1. Domain_1_Peer1(conf)#interface range tengigabitethernet 1/16/1 - 1/16/2 Domain_1_Peer1(conf-if-range-te-1/16/1-2)# port-channel-protocol LACP Domain_1_Peer1(conf-if-range-te-1/16/1-2)# port-channel 100 mode active Domain_1_Peer1(conf-if-range-te-1/16/1-2)# no shutdown Next, configure the VLT domain and VLTi on Peer 2.
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 10.18.130.12 Domain_2_Peer4(conf-vlt-domain)# system-mac mac-address 00:0b:00:0b:00:0b Domain_2_Peer4(conf-vlt-domain)# peer-routing Domain_2_Peer4(conf-vlt-domain)# unit-id 1 Configure eVLT on Peer 4.
Verifying a VLT Configuration To monitor the operation or verify the configuration of a VLT domain, use any of the following show commands on the primary and secondary VLT switches. • Display information on backup link operation. EXEC mode • show vlt backup-link Display general status information about VLT domains currently configured on the switch.
----------------Destination: Peer HeartBeat status: HeartBeat Timer Interval: HeartBeat Timeout: UDP Port: HeartBeat Messages Sent: HeartBeat Messages Received: 10.11.200.18 Up 1 3 34998 1026 1025 Dell_VLTpeer2# show vlt backup-link VLT Backup Link ----------------Destination: Peer HeartBeat status: HeartBeat Timer Interval: HeartBeat Timeout: UDP Port: HeartBeat Messages Sent: HeartBeat Messages Received: 10.11.200.20 Up 1 3 34998 1030 1014 The following example shows the show vlt brief command.
Local System MAC address: 00:01:e8:8a:df:bc Local System Role Priority: 32768 Dell_VLTpeer2# show vlt role VLT Role ---------VLT Role: System MAC address: System Role Priority: Local System MAC address: Local System Role Priority: Secondary 00:01:e8:8a:df:bc 32768 00:01:e8:8a:df:e6 32768 The following example shows the show running-config vlt command. Dell_VLTpeer1# show running-config vlt ! vlt domain 30 peer-link port-channel 60 back-up destination 10.11.200.
Po 111 128.112 128 200000 DIS(vlt) Po 120 128.121 128 2000 FWD(vlt) 800 800 4096 4096 0001.e88a.d656 128.112 0001.e88a.d656 128.121 Dell_VLTpeer2# show spanning-tree rstp brief Executing IEEE compatible Spanning Tree Protocol Root ID Priority 0, Address 0001.e88a.dff8 Root Bridge hello time 2, max age 20, forward delay 15 Bridge ID Priority 0, Address 0001.e88a.
Q: U - Untagged, T - Tagged x - Dot1x untagged, X - Dot1x tagged G - GVRP tagged, M - Vlan-stack, H - Hyperpull tagged NUM Status Description Q Ports 10 Active U Po110(Fo 1/8) T Po100(Fo 1/5,6) Configuring Virtual Link Trunking (VLT Peer 2) Enable VLT and create a VLT domain with a backup-link VLT interconnect (VLTi). Dell_VLTpeer2(conf)#vlt domain 999 Dell_VLTpeer2(conf-vlt-domain)#peer-link port-channel 100 Dell_VLTpeer2(conf-vlt-domain)#back-up destination 10.11.206.
Troubleshooting VLT To help troubleshoot different VLT issues that may occur, use the following information. NOTE: For information on VLT Failure mode timing and its impact, contact your Dell EMC Networking representative. Table 122. Troubleshooting VLT Description Behavior at Peer Up Behavior During Run Time Action to Take Bandwidth monitoring A syslog error message and an SNMP trap is generated when the VLTi bandwidth usage goes above the 80% threshold and when it drops below 80%.
Description Behavior at Peer Up Behavior During Run Time Action to Take 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.
Keep the following points in mind when you configure VLT nodes in a PVLAN: • Configure the VLTi link to be in trunk mode. Do not configure the VLTi link to be in access or promiscuous mode. • You can configure a VLT LAG or port channel to be in trunk, access, or promiscuous port modes when you include the VLT LAG in a PVLAN. The VLT LAG settings must be the same on both the peers. If you configure a VLT LAG as a trunk port, you can associate that LAG to be a member of a normal VLAN or a PVLAN.
PVLAN Operations When One VLT Peer is Down When a VLT port moves to the Admin or Operationally Down state on only one of the VLT nodes, the VLT Lag is still considered to be up. All the PVLAN MAC entries that correspond to the operationally down VLT LAG are maintained as synchronized entries in the device. These MAC entries are removed when the peer VLT LAG also becomes inactive or a change in PVLAN configuration occurs.
Table 123.
VLT LAG Mode Peer1 PVLAN Mode of VLT VLAN Peer2 ICL VLAN Membership Mac Synchronization Peer1 Peer2 - Primary VLAN Y - Primary VLAN X No No Promiscuous Access Primary Secondary No No Trunk Access Primary/Normal Secondary No No Configuring a VLT VLAN or LAG in a PVLAN You can configure the VLT peers or nodes in a private VLAN (PVLAN).
vlt domain domain-id The range of domain IDs is from 1 to 1000. 7 Enter the port-channel number that acts as the interconnect trunk. VLT DOMAIN CONFIGURATION mode peer-link port-channel id-number 8 (Optional) To configure a VLT LAG, enter the VLAN ID number of the VLAN where the VLT forwards packets received on the VLTi from an adjacent peer that is down.
The list of secondary VLANs can be: • Specified in comma-delimited (VLAN-ID,VLAN-ID) or hyphenated-range format (VLAN-ID-VLAN-ID). • Specified with this command even before they have been created. • 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 the other router in a VLT domain.
VLT nodes start performing Proxy ARP when the ICL link goes down. When the VLT peer comes up, proxy ARP stops for the peer VLT IP addresses. When the peer node is rebooted, the IP address synchronized with the peer is not flushed. Peer down events cause the proxy ARP to commence. When a VLT node detects peer up, it does not perform proxy ARP for the peer IP addresses. IP address synchronization occurs again between the VLT peers. Proxy ARP is enabled only if you enable peer routing on both the VLT peers.
Configuring VLAN-Stack over VLT To configure VLAN-stack over VLT, follow these steps. 1 Configure the VLT LAG as VLAN-Stack access or Trunk mode on both the peers. INTERFACE PORT-CHANNEL mode vlan-stack {access | trunk} 2 Configure VLAN as VLAN-stack compatible on both the peers. INTERFACE VLAN mode vlan-stack compatible 3 Add the VLT LAG as a member to the VLAN-stack on both the peers. INTERFACE VLAN mode member port-channel port—channel ID 4 Verify the VLAN-stack configurations.
DellEMC# DellEMC(conf)#interface port-channel 20 DellEMC(conf-if-po-20)#switchport DellEMC(conf-if-po-20)#vlt-peer-lag port-channel 20 DellEMC(conf-if-po-20)#vlan-stack trunk DellEMC(conf-if-po-20)#no shutdown DellEMC#show running-config interface port-channel 20 ! interface Port-channel 20 no ip address switchport vlan-stack trunk vlt-peer-lag port-channel 20 no shutdown DellEMC# Configure the VLAN as a VLAN-Stack VLAN and add the VLT LAG as Members to the VLAN DellEMC(conf)#interface vlan 50 DellEMC(conf-
unit-id 1 DellEMC# Configure the VLT LAG as VLAN-Stack Access or Trunk Port DellEMC(conf)#interface port-channel 10 DellEMC(conf-if-po-10)#switchport DellEMC(conf-if-po-10)#vlt-peer-lag port-channel 10 DellEMC(conf-if-po-10)#vlan-stack access DellEMC(conf-if-po-10)#no shutdown DellEMC#show running-config interface port-channel 10 ! interface Port-channel 10 no ip address switchport vlan-stack access vlt-peer-lag port-channel 10 no shutdown DellEMC# DellEMC(conf)#interface port-channel 20 DellEMC(conf-if-po-
DellEMC# V Po1(Te 1/30-32/1) IPv6 Peer Routing in VLT Domains Overview VLT enables the physical links between two devices that are called VLT nodes or peers, and within a VLT domain, to be considered as a single logical link to external devices that are connected using LAG bundles to both the VLT peers. This capability enables redundancy without the implementation of Spanning tree protocol (STP), thereby providing a loop-free network with optimal bandwidth utilization.
Synchronization of IPv6 ND Entries in a Non-VLT Domain Layer 3 VLT provides a higher resiliency at the Layer 3 forwarding level. Routed VLT allows you to replace VRRP with routed VLT to route the traffic from Layer 2 access nodes. With ND synchronization, both the VLT nodes perform Layer 3 forwarding on behalf of each other. Synchronization of NDPM entries learned on non-VLT interfaces between the non-VLT nodes.
Figure 137. Sample Configuration of IPv6 Peer Routing in a VLT Domain 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.
Figure 138. Sample Configuration of IPv6 Peer Routing in a VLT Domain Neighbor Solicitation from VLT Hosts Consider a case in which NS for VLT node1 IP reaches VLT node1 on the VLT interface and NS for VLT node1 IP reaches VLT node2 due to LAG level hashing in the ToR. When VLT node1 receives NS from VLT VLAN interface, it unicasts the NA packet on the VLT interface. When NS reaches VLT node2, it is flooded on all interfaces including ICL.
Consider a situation in which NA for VLT node1 reaches VLT node1 on a non-VLT interface and NA for VLT node1 reaches VLT node2 on a non-VLT interface. When VLT node1 receives NA on a VLT interface, it learns the Host MAC address on the received interface. This learned neighbor entry is synchronized to VLT node2 as it is learned on ICL.
Non-VLT host to Non-VLT host traffic flow When VLT node receives traffic from non-VLT host intended to the non-VLT host, it does neighbor entry lookup and routes traffic over ICL interface. If traffic reaches wrong VLT peer, it routes the traffic over ICL. Router Solicitation When VLT node receives router Solicitation on VLT interface/non-VLT interface it consumes the packets and will send RA back on the received interface. VLT node will drop the RS message if it is received over ICL interface.
Configuration Configuration steps are covered below: 1 Both Gateway VTEPs need VLT configured. • ICL port configuration interface Port-channel 1 no ip address channel-member TenGigabitEthernet 0/4-5 no shutdown • VLT Domain Configuration vlt domain 100 peer-link port-channel 1 back-up destination 10.11.70.
2 • VXLAN Instance Configuration vxlan-instance 1 static local-vtep-ip 14.14.14.14 no shutdown vni-profile test vnid 200 remote-vtep-ip 3.3.3.3 vni-profile test • VLT Access port configuration interface TengigabitEthernet 0/12 port-channel-protocol lacp port-channel 30 mode active interface Port-channel 30 no ip address vxlan-instance 1 switchport vlt-peer-lag port-channel 30 no shutdown Configure loopback interface and VXLAN instances on both the peers.
59 VLT Proxy Gateway 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, see the Command Line Reference Guide.
Figure 139. Sample Configuration for a VLT Proxy Gateway 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.
• 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 EMC Networking recommends the vlt-peer-mac transmit command only for square VLTs without diagonal links. • The virtual router redundancy (VRRP) protocol and IPv6 routing is not supported. • Private VLANs (PVLANs) are not supported.
• You must configure the interface proxy gateway LLDP to enable or disable a proxy-gateway LLDP TLV on specific interfaces. • The interface is typically a VLT port-channel that connects to a remote VLT domain. • The new proxy gateway TLV is carried on the physical links under the port channel only. • You must have at least one link connection to each unit of the VLT domain. Following are the prerequisites for Proxy Gateway LLDP configuration: • You must globally enable LLDP.
LLDP VLT Proxy Gateway in a Square VLT Topology Figure 140. Sample Configuration for a VLT Proxy Gateway • The preceding figure shows a sample square VLT Proxy gateway topology. 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.
• 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].
Figure 141. VLT Proxy Gateway Sample Topology VLT Domain Configuration Dell-1 and Dell-2 constitute VLT domain 120. Dell-3 and Dell-4 constitute VLT domain 110. These two VLT domains are connected using a VLT LAG P0 50. To know how to configure the interfaces in VLT domains, see the Configuring VLT section. Dell-1 VLT Configuration vlt domain 120 peer-link port-channel 120 back-up destination 10.1.1.
switchport no spanning-tree vlt-peer-lag port-channel 50 no shutdown Note that on the inter-domain link, the switchport command is enabled. On a VLTi link between VLT peers in a VLT domain, the switchport command is not used. VLAN 100 is used as the OSPF peering VLAN between Dell-1 and Dell-2. interface Vlan 100 description OSPF Peering VLAN to Dell-2 ip address 10.10.100.1/30 ip ospf network point-to-point no shutdown VLAN 101 is used as the OSPF peering VLAN between the two VLT domains.
The following output shows that Dell-1 forms OSPF neighborship with Dell-2. Dell-2#sh ip ospf nei Neighbor ID Pri State Dead Time Address Interface Area 4.4.4.4 1 FULL/ - 00:00:33 10.10.100.1 Vl 100 0 Dell-3 VLT Configuration vlt domain 110 peer-link port-channel 110 back-up destination 10.1.1.
The following output shows that Dell-4 and VLT domain 120 form OSPF neighborship with Dell-3. Dell-3#sh ip ospf nei ! Neighbor ID Pri State Dead Time Address Interface Area 4.4.4.4 1 FULL/ - 00:00:33 10.10.101.1 Vl 101 0 1.1.1.1 1 FULL/ - 00:00:34 10.10.102.2 Vl 102 0 Dell-4 VLT Configuration vlt domain 110 peer-link port-channel 110 back-up destination 10.1.1.
60 Virtual Extensible LAN (VXLAN) Virtual Extensible LAN (VXLAN) is supported on Dell EMC 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. Figure 142. VXLAN Gateway NOTE: In a stack setup, the Dell EMC Networking OS does not support VXLAN. In a VLT setup, you can configure static VXLAN.
• Displaying VXLAN Configurations • Static Virtual Extensible LAN (VXLAN) • Preserving 802.1 p value across VXLAN tunnels • Routing in and out of VXLAN tunnels Components of VXLAN network VXLAN provides a mechanism to extend an L2 network over an L3 network. In short, VXLAN is an L2 overlay scheme over an L3 network and this overlay is termed as a VXLAN segment.
• Binds MACs to the VTEP and logical network based on messages from the NVP. • Advertises MACs learnt on south-facing VXLAN capable-ports to the NVP client. VXLAN Hypervisor It is the VTEP that connects the Virtual Machines (VM) to the underlay legacy network to the physical infrastructure. Service Node(SN) It is also another VTEP, but it is fully managed by the controller.
Components of VXLAN Frame Format Some of the important fields of the VXLAN frame format are described below: Outer Ethernet Header: Outer IP Header: 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.
To view the certificate, use the following command: • show file flash://vtep-cert.
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. Figure 146. Create Logical Switch 5 Create Logical Switch Port A logical switch port provides a logical connection point for a VM interface (VIF) and a L2 gateway connection to an external network. It binds the virtual access ports in the GW to logical network (VXLAN) and VLAN. Figure 147.
Figure 148. Add Data center Gateway 2 Create port-to-VLAN mappings. Figure 149. Port-to-VLAN mappings 3 Under the Networks tab, create an L2 domain. Under the L2 domain, create a logical network (VNI) and add access ports of the VTEP in the logical network. Figure 150.
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 Enable the VXLAN feature. CONFIGURATION mode feature vxlan You must configure feature VXLAN to configure vxlan-instance. 2 Create a VXLAN instance that connects to the controller.
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 VXLAN-instance. INTERFACE mode vxlan-instance Displaying VXLAN Configurations To display the VXLAN configurations, use the following commands. Examples of the show vxlan-instance Command The following example shows the show vxlan vxlan-instance command.
The following example shows the show vxlan vxlan-instance physical-locator command. DellEMC#show vxlan vxlan-instance 1 physical-locator Instance : 1 Tunnel : count 1 36.1.1.1 : vxlan_over_ipv4 (up) The following example shows the show vxlan vxlan-instance unicast-mac-local command.
vxlan-instance instance ID [static] You can configure vxlan-instance on INTERFACE mode to enable VXLAN on specific ports. 3 Set the local IP Address that can be used as a source for VXLAN tunnels. VXLAN-INSTANCE mode local-vtep-ip IP Address 4 Create a VNI profile to associate with remote VTEP configuration. VXLAN-INSTANCE mode vni—profile profile name 5 Associate VNID to the VNI profile. VNI-PROFILE mode vnid VNID Range 6 Create a remote tunnel and associate the remote VTEP to the VNID.
Displaying Static VXLAN Configurations To display the static VXLAN configurations, use the following commands. Examples of the show vxlan-instance Command The following example displays the basic configuration details. DellEMC# show vxlan vxlan-instance 1 Instance : 1 Mode : Static Admin State : Up Local vtep ip : 101.101.101.101 Port List : Fo 1/49 The following example displays VTEP to VNI mapping for a specific remote VTEP. DellEMC# show vxlan vxlan-instance 1 vtep-vni-map Remote Vtep IP : 10.10.10.
Routing in and out of VXLAN tunnels VXLAN provides a way to extend a VLAN over a Layer3 tunnel (VXLAN tunnel) across data centers. This functionality can also be extended one step further by enabling routing from a VLAN on one data center to a different VLAN on another data center. This scheme to route in and out of tunnels (RIOT) requires setting up of hardware VTEPs that are capable of routing over a VXLAN tunnel using a physical loopback configuration.
Restrictions The topology to achieve RIOT with a physical loopback is inherently susceptible to Layer 2 loops. To prevent these loops from disrupting the network, the following egress masks need to be applied: • Any frame ingressing on a VXLAN access port is not allowed to egress out of a VXLAN loopback port. • Any frame ingressing on a VXLAN loopback port is not allowed to egress out of a VXLAN access port.
In this topology, P2 and P3 in VTEP 1 are VLT port-channels with corresponding VLT peer LAGs being P2 and P3 in VTEP 2. Similarly, P6 and P7 in VTEP 3 are VLT port-channels with corresponding VLT peer LAGs being P6 and P7 in VTEP 4. NOTE: P2, P3, P6, and P7 can be a single port or multi-port port-channels that are VLT port-channels. NOTE: The VLT VXLAN configuration for RIOT deviates from the standard VLT behavior when these physical loopbacks are provisioned as VLT port-channels.
61 Virtual Routing and Forwarding (VRF) 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 151. 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.
If the next-hop IP in a static route VRF statement is VRRP IP of another VRF, this static route does not get installed on the VRRP master. 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. NOTE: To configure a router ID in a non-default VRF, configure at least one IP address in both the default as well as the nondefault VRF. Table 124.
Feature/Capability Support Status for Default VRF Support Status for Non-default VRF OSPFv3 Yes Yes IS-IS Yes Yes BGP Yes Yes ACL Yes No Multicast No No NDP Yes Yes RAD Yes Yes DHCP DHCP requests are not forwarded across VRF instances. The DHCP client and server must be on the same VRF instance.
Assigning an Interface to a VRF You must enter the ip vrf forwarding command before you configure the IP address or any other setting on an interface. NOTE: You can configure an IP address or subnet on a physical or VLAN interface that overlaps the same IP address or subnet configured on another interface only if the interfaces are assigned to different VRFs. If two interfaces are assigned to the same VRF, you cannot configure overlapping IP subnets or the same IP address on them.
show ip vrf [vrf-name] Assigning an OSPF Process to a VRF Instance OSPF routes are supported on all VRF instances. See the Open Shortest Path First (OSPFv2) chapter 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 Command Mode 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: 10.1.1.100 Authentication: (none) Configuring Management VRF You can assign a management interface to a management VRF. NOTE: The loopback interface cannot be added into the management VRF. 1 Create a management VRF.
Configuring a Static Route • Configure a static route that points to a management interface. CONFIGURATION management route ip-address mask managementethernet ormanagement route ipv6-address prefixlength managementethernet You can also have the management route to point to a front-end port in case of the management VRF. For example: management route 2::/64 tengigabitethernet 1/1/1. • Configure a static entry in the IPv6 neighbor discovery.
Figure 153. Setup VRF Interfaces The following example relates to the configuration shown in the above illustrations. Router 1 ip vrf blue 1 ! ip vrf orange 2 ! ip vrf green 3 ! interface TenGigabitEthernet no ip address switchport no shutdown ! interface TenGigabitEthernet ip vrf forwarding blue ip address 10.0.0.1/24 no shutdown ! interface TenGigabitEthernet ip vrf forwarding orange ip address 20.0.0.
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 3/1/1 no shutdown ! interface Vlan 192 ip vrf forwarding orange ip address 2.0.0.1/24 tagged TenGigabitEthernet 3/1/1 no shutdown ! interface Vlan 256 ip vrf forwarding green ip address 3.0.0.1/24 tagged TenGigabitEthernet 3/1/1 no shutdown ! router ospf 1 vrf blue router-id 1.0.0.1 network 1.0.0.0/24 area 0 network 10.0.0.
ip address 2.0.0.2/24 tagged TenGigabitEthernet 3/1/1 no shutdown ! interface Vlan 256 ip vrf forwarding green ip address 3.0.0.2/24 tagged TenGigabitEthernet 3/1/1 no shutdown ! router ospf 1 vrf blue router-id 1.0.0.2 network 11.0.0.0/24 area 0 network 1.0.0.0/24 area 0 passive-interface TenGigabitEthernet 2/1/1 ! router ospf 2 vrf orange router-id 2.0.0.2 network 21.0.0.0/24 area 0 network 2.0.0.0/24 area 0 passive-interface TenGigabitEthernet 2/2/1 ! ip route vrf green30.0.0.0/24 3.0.0.
DellEMC#show ip route vrf orange Codes: C - connected, S - static, R - RIP, B - BGP, IN - internal BGP, EX - external BGP,LO - Locally Originated, 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 C C O Destination ----------2.0.0.0/24 20.
Dynamic Route Leaking Route Leaking is a powerful feature that enables communication between isolated (virtual) routing domains by segregating and sharing a set of services such as VOIP, Video, and so on that are available on one routing domain with other virtual domains. Inter-VRF Route Leaking enables a VRF to leak or export routes that are present in its RTM to one or more VRFs.
A non-default VRF named VRF-Shared is created and the interface 1/4 is assigned to this VRF. 2 Configure the export target in the source VRF:. ip route-export 1:1 3 Configure VRF-red. ip vrf vrf-red interface-type slot/port[/subport] ip vrf forwarding VRF-red ip address ip—address mask A non-default VRF named VRF-red is created and the interface is assigned to this VRF. 4 Configure the import target in VRF-red. ip route-import 1:1 5 Configure the export target in VRF-red.
ip route-import ! ip vrf VRF-Green ! ip vrf VRF-shared ip route-export ip route-import ip route-import 1:1 1:1 2:2 3:3 Show routing tables of all the VRFs (without any route-export and route-import tags being configured) DellEMC# 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 1/11/1 0/0 00:00:10 22:39:59 DellEMC# 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.
O 44.4.4.4/32 00:00:11 via 144.4.4.4 C Direct, Te 1/4/1 144.4.4.0/24 110/0 0/0 00:32:36 Important Points to Remember • If the target VRF conatins the same prefix as either the sourced or Leaked route from some other VRF, then route Leaking for that particular prefix fails and the following error-log is thrown. SYSLOG (“Duplicate prefix found %s in the target VRF %d”, address, import_vrf_id) with The type/level is EVT_LOGWARNING. • The source routes always take precedence over leaked routes.
A non-default VRF named VRF-red is created and the interface is assigned to this VRF. 2 Define a route-map export_ospfbgp_protocol. DellEMC(config)route-map export_ospfbgp_protocol permit 10 3 Define the matching criteria for the exported routes. DellEMC(config-route-map)match source-protocol ospf DellEMC(config-route-map)match source-protocol bgp This action specifies that the route-map contains OSPF and BGP as the matching criteria for exporting routes from vrf-red.
O 44.4.4.4/32 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. Even though the Target VRF-B has specified filtering options to match BGP, the BGP route is not leaked as that route is not active in the Source VRF.
62 Virtual Router Redundancy Protocol (VRRP) Virtual router redundancy protocol (VRRP) is designed to eliminate a single point of failure in a statically routed network. 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).
Figure 154. 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. In conjunction with Virtual Link Trunking (VLT), you can configure optimized forwarding with virtual router redundancy protocol (VRRP).
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. NOTE: In a VLT environment, VRRP configuration acts as active-active and if route is not present in any of the VRRP nodes, the packet to the destination is dropped on that VRRP node. Table 126.
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. DellEMC(conf)#interface tengigabitethernet 1/1/1 DellEMC(conf-if-te-1/1/1)#vrrp-group 111 DellEMC(conf-if-te-1/1/1-vrid-111)# The following examples how to verify the VRRP configuration.
Example: Migrating an IPv4 VRRP Group from VRRPv2 to VRRPv3 NOTE: Carefully following this procedure, otherwise you might introduce dual master switches issues. To migrate an IPv4 VRRP Group from VRRPv2 to VRRPv3: 1 Set the backup switches to VRRP version to both. Dell_backup_switch1(conf-if-te-1/1/1-vrid-100)#version both Dell_backup_switch2(conf-if-te-1/2/1-vrid-100)#version both 2 Set the master switch to VRRP protocol version 3.
Examples of the Configuring and Verifying a Virtual IP Address The following example shows how to configure a virtual IP address. DellEMC(conf-if-te-1/1/1-vrid-111)#virtual-address 10.10.10.1 DellEMC(conf-if-te-1/1/1-vrid-111)#virtual-address 10.10.10.2 DellEMC(conf-if-te-1/1/1-vrid-111)#virtual-address 10.10.10.3 The following example shows how to verify a virtual IP address configuration. NOTE: In the following example, the primary IP address and the virtual IP addresses are on the same subnet.
• Configure the priority for the VRRP group. INTERFACE -VRID mode priority priority The range is from 1 to 255. The default is 100. Examples of the priority Command DellEMC(conf-if-te-1/2/1)#vrrp-group 111 DellEMC(conf-if-te-1/2/1-vrid-111)#priority 125 To verify the VRRP group priority, use the show vrrp command. Dellshow vrrp -----------------TenGigabitEthernet 1/1/1, VRID: 111, Net: 10.10.10.1 VRF: 0 default State: Master, Priority: 255, Master: 10.10.10.
Examples of the authentication-type Command The bold section shows the encryption type (encrypted) and the password. DellEMC(conf-if-te-1/1/1-vrid-111)#authentication-type ? DellEMC(conf-if-te-1/1/1-vrid-111)#authentication-type simple 7 force10 The following example shows verifying the VRRP authentication configuration using the show conf command. The bold section shows the encrypted password.
Changing the Advertisement Interval By default, the MASTER router transmits a VRRP advertisement to all members of the VRRP group every one second, indicating it is operational and is the MASTER router. If the VRRP group misses three consecutive advertisements, the election process begins and the BACKUP virtual router with the highest priority transitions to MASTER.
Track an Interface or Object You can set Dell EMC Networking OS to monitor the state of any interface according to the virtual group. Each VRRP group can track up to 12 interfaces and up to 20 additional objects, which may affect the priority of the VRRP group. If the tracked interface goes down, the VRRP group’s priority decreases by a default value of 10 (also known as cost). If the tracked interface’s state goes up, the VRRP group’s priority increases by 10.
• (Optional) Display the configuration and the UP or DOWN state of tracked interfaces and objects in VRRP groups, including the time since the last change in an object’s state. EXEC mode or EXEC Privilege mode • show vrrp (Optional) Display the configuration of tracked objects in VRRP groups on a specified interface.
Tracking states for 2 resource Ids: 2 - Up IPv6 route, 2040::/64, priority-cost 20, 00:02:11 3 - Up IPv6 route, 2050::/64, priority-cost 30, 00:02:11 The following example shows verifying the VRRP configuration on an interface.
The default is 0. 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 2/31/1 R2(conf-if-te-2/31/1)#ip address 10.1.1.1/24 R2(conf-if-te-2/31/1)#vrrp-group 99 R2(conf-if-te-2/31/1-vrid-99)#priority 200 R2(conf-if-te-2/31/1-vrid-99)#virtual 10.1.1.3 R2(conf-if-te-2/31/1-vrid-99)#no shut R2(conf-if-te-2/31/1)#show conf ! interface TenGigabitEthernet 2/31/1 ip address 10.1.1.1/24 ! vrrp-group 99 priority 200 virtual-address 10.1.1.
Figure 156. 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.
R2(conf-if-te-1/1/1-vrid-10)#virtual-address fe80::10 R2(conf-if-te-1/1/1-vrid-10)#virtual-address 1::10 R2(conf-if-te-1/1/1-vrid-10)#no shutdown R2(conf-if-te-1/1/1)#show config interface TenGigabitEthernet 1/1/1 ipv6 address 1::1/64 vrrp-group 10 priority 100 virtual-address fe80::10 virtual-address 1::10 no shutdown R2(conf-if-te-1/1/1)#end R2#show vrrp -----------------TenGigabitEthernet 1/1/1, IPv6 VRID: 10, Version: 3, Net:fe80::201:e8ff:fe6a:c59f VRF: 0 default State: Master, Priority: 100, Master: f
VRRP in a VRF: Non-VLAN Scenario The following example shows how to enable VRRP in a non-VLAN. The following example shows a typical use case in which you create three virtualized overlay networks by configuring three VRFs in two switches. The default gateway to reach the Internet in each VRF is a static route with the next hop being the virtual IP address configured in VRRP. In this scenario, a single VLAN is associated with each VRF.
S1(conf)#ip vrf VRF-3 3 ! S1(conf)#interface TenGigabitEthernet 1/1/1 S1(conf-if-te-1/1/1)#ip vrf forwarding VRF-1 S1(conf-if-te-1/1/1)#ip address 10.10.1.5/24 S1(conf-if-te-1/1/1)#vrrp-group 11 % Info: The VRID used by the VRRP group 11 in S1(conf-if-te-1/1/1-vrid-101)#priority 100 S1(conf-if-te-1/1/1-vrid-101)#virtual-address S1(conf-if-te-1/1/1)#no shutdown ! S1(conf)#interface TenGigabitEthernet 1/2/1 S1(conf-if-te-1/2/1)#ip vrf forwarding VRF-2 S1(conf-if-te-1/2/1)#ip address 10.10.1.
! S2(conf)#interface TenGigabitEthernet 1/3/1 S2(conf-if-te-1/3/1)#ip vrf forwarding VRF-3 S2(conf-if-te-1/3/1)#ip address 20.1.1.6/24 S2(conf-if-te-1/3/1)#vrrp-group 15 % Info: The VRID used by the VRRP group 15 in VRF 3 will be 243. S2(conf-if-te-1/3/1-vrid-105)#priority 100 S2(conf-if-te-1/3/1-vrid-105)#virtual-address 20.1.1.
DellEMC#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) DellEMC#show vrrp vrf vrf2 port-channel 1 -----------------Port-channel 1, IPv4 VRID: 1, Version: 2, Net: 10.1.1.
S2(conf-if-vl-300)#no shutdown DellEMC#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 158. VRRP for IPv6 Topology NOTE: 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. Be sure you make the necessary changes to support your own IP addresses, interfaces, names, and so on.
NOTE: The virtual IPv6 address you configure should be the same as the IPv6 subnet to which the interface belongs.
Virtual MAC address: 00:00:5e:00:02:ff Virtual IP address: 10:1:1::255 fe80::255 DellEMC#show vrrp tengigabitethernet 2/8/1 TenGigabitEthernet 2/8/1, IPv6 VRID: 255, Version: 3, Net: fe80::201:e8ff:fe8a:e9ed VRF: 0 default State: Master, Priority: 110, 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: 120 Virtual MAC address: 00:00:5e:00:02:ff Virtual IP address: 10:1:1:
63 Debugging and Diagnostics 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.
diag stack-unit stack-unit-number When the tests are complete, the system displays the following message and automatically reboots the unit. Diagnostic results are printed to a file in the flash using the filename format TestReport-SU-.txt. Log messages differ somewhat when diagnostics are done on a standalone unit and on a stack member. 4 View the results of the diagnostic tests. EXEC Privilege mode show file flash://TestReport-SU-stack-unit-id.
Example of the show interfaces transceiver Command DellEMC#show interfaces tengigabitethernet 1/26/1 transceiver QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP QSFP 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 26/1 Serial ID Base Fields Id = Ext Id = Connector = Transceiver Code = Encoding = Length(SFM) Km = Length(OM3) 2m = Length(OM2) 1m = Length(OM1) 1m = Length(Copper) 1m = Vendor Rev = Laser Wavelength =
Troubleshoot an Over-temperature Condition To troubleshoot an over-temperature condition, use the following information. 1 Use the show environment commands to monitor the temperature levels. 2 Check air flow through the system. Ensure that the air ducts are clean and that all fans are working correctly. 3 After the software has determined that the temperature levels are within normal limits, you can re-power the card safely. To bring back the line card online, use the power-on command in EXEC mode.
OID String OID Name Description .1.3.6.1.4.1.6027.3.27.1.4 dellNetFpPacketBufferTable View the modular packet buffers details per stack unit and the mode of allocation. .1.3.6.1.4.1.6027.3.27.1.5 dellNetFpStatsPerPortTable View the forwarding plane statistics containing the packet buffer usage per port per stack unit. .1.3.6.1.4.1.6027.3.27.1.6 dellNetFpStatsPerCOSTable View the forwarding plane statistics containing the packet buffer statistics per COS per port.
• • • • • • • • • • • • • • • • show hardware stack-unit stack-unit-number cpu data-plane statistics show hardware stack-unit stack-unit-number cpu party-bus statistics show hardware stack-unit stack-unit-number drops unit unit-number show hardware stack-unit stack-unit-number unit unit-number {counters | details | port-stats [detail] | register | ipmc-replication | table-dump} show hardware {ip | ipv6 | mac} {eg-acl | in-acl} stack-unit stack-unit-number port-set 0 pipeline 0-3 show hardware ip qos stack-
HOL DROPS on COS6 : 0 HOL DROPS on COS7 : 0 HOL DROPS on COS8 : 0 HOL DROPS on COS9 : 0 HOL DROPS on COS10 : 0 HOL DROPS on COS11 : 0 HOL DROPS on COS12 : 0 HOL DROPS on COS13 : 0 HOL DROPS on COS14 : 0 HOL DROPS on COS15 : 0 HOL DROPS on COS16 : 0 HOL DROPS on COS17 : 0 HOL DROPS on COS18 : 0 HOL DROPS on COS19 : 0 TxPurge CellErr : 0 Aged Drops : 0 --- Egress MAC counters--Egress FCS Drops : 0 --- Egress FORWARD PROCESSOR Drops --IPv4 L3UC Aged & Drops : 0 TTL Threshold Drops : 0 INVALID VLAN CNTR Drops :
rxPkt(COS5 ) :0 rxPkt(COS6 ) :0 rxPkt(COS7 ) :0 rxPkt(COS8 ) :773 rxPkt(COS9 ) :0 rxPkt(COS10) :0 rxPkt(COS11) :0 rxPkt(UNIT0) :773 transmitted :12698 txRequested :12698 noTxDesc :0 txError :0 txReqTooLarge :0 txInternalError :0 txDatapathErr :0 txPkt(COS0 ) :0 txPkt(COS1 ) :0 txPkt(COS2 ) :0 txPkt(COS3 ) :0 txPkt(COS4 ) :0 txPkt(COS5 ) :0 txPkt(COS6 ) :0 txPkt(COS7 ) :0 txPkt(COS8 ) :0 txPkt(COS9 ) :0 txPkt(COS10) :0 txPkt(COS11) :0 txPkt(UNIT0) :0 Example of Viewing Party Bus Statistics DellEMC#sh hardwar
Example of Displaying Counter Information for a Specific Interface DellEMC#show hardware counters interface hundredGigE 1/1 unit: 0 port: 50 (interface Hu 1/1) Description Value 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 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 1094 - IPV4 L3 Unicast Frame Counter IPV4 L3 Routed Multicast Packets IPV6 L3 Unicast Frame Counter IPV6 L3 Routed Multicast Packets Unicas
TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX TX - Byte Counter Control Frame Counter Pause Control Frame Counter Oversized Frame Counter Jabber Counter VLAN Tag Frame Counter Double VLAN Tag Frame Counter RUNT Frame Counter Fragment Counter PFC Frame Priority 0 PFC Frame Priority 1 PFC Frame Priority 2 PFC Frame Priority 3 PFC Frame Priority 4 PFC Frame Priority 5 PFC Frame Priority 6 PFC Frame Priority 7 Debug Counter 0 Debug Counter 1 Debug Counter 2 Debug Counter
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 drwx drwx drwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx -rwx 4096 4096 4096 512 1868977 1553622 1523296 1523523 1527504 1738282 1525213 765783 784725 787785 797852 1552883 803356 1523099 1828006 161797 43275928 1810311 1812442 1810601 1800256 1798111 1887496 1913790 Jul Jan Jul Sep Jul Jul Jul Jul Jul Jul Jul Jul Jul Jul Jul Jul Jul Jul Aug Aug Sep Sep
You can use the capture-duration timer and the packet-count counter at the same time. The TCP dump stops when the first of the thresholds is met. That means that even if the duration timer is 9000 seconds, if the maximum file count parameter is met first, the dumps stop. To enable a TCP dump, use the following command. • Enable a TCP dump for CPU bound traffic.
64 Standards Compliance This chapter describes standards compliance for Dell EMC Networking products. NOTE: Unless noted, when a standard cited here is listed as supported by the Dell EMC Networking OS, the system also supports predecessor standards. One way to search for predecessor standards is to use the http://tools.ietf.org/ website. Click “Browse and search IETF documents,” enter an RFC number, and inspect the top of the resulting document for obsolescence citations to related RFCs.
SFF-8431 SFP+ Direct Attach Cable (10GSFP+Cu) MTU 12,000 bytes RFC and I-D Compliance Dell EMC Networking OS supports the following standards. The standards are grouped by related protocol. The columns showing support by platform indicate which version of Dell EMC Networking OS first supports the standard. General Internet Protocols The following table lists the Dell EMC Networking OS support per platform for general internet protocols. Table 128.
R F C # Full Name S-Series S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 24 Definition of 7.7.1 74 the Differentiated Services Field (DS Field) in the IPv4 and IPv6 Headers 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 26 PPP over 15 SONET/SDH 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 26 A Two Rate 9 Three Color 8 Marker 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.
General IPv4 Protocols The following table lists the Dell EMC Networking OS support per platform for general IPv4 protocols. Table 129. General IPv4 Protocols RF C# Full Name S-Series S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 791 Internet Protocol 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 826 An Ethernet Address Resolution 7.6.1 Protocol 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.
General IPv6 Protocols The following table lists the Dell EMC Networking OS support per platform for general IPv6 protocols. Table 130. General IPv6 Protocols RFC # Full Name S-Series 1886 DNS Extensions to support IP 7.8.1 version 6 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 1981 Path MTU Discovery for IP (Part version 6 ial) 7.8.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.
Border Gateway Protocol (BGP) The following table lists the Dell EMC Networking OS support per platform for BGP protocols. Table 131. Border Gateway Protocol (BGP) RFC# Full Name S-Series/ZSeries S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 1997 BGP ComAmtturnibituitees 7.8.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 2385 Protection of BGP Sessions via the TCP MD5 Signature Option 7.8.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 2439 BGP Route Flap Damping 7.8.
Open Shortest Path First (OSPF) The following table lists the Dell EMC Networking OS support per platform for OSPF protocol. Table 132. Open Shortest Path First (OSPF) RFC # Full Name S-Series/ZSeries S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 1587 The OSPF Not-SoStubby Area (NSSA) Option 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 2154 OSPF with Digital Signatures 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 2370 The OSPF Opaque LSA Option 7.6.1 9.8(0.
RFC# Full Name S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 3784 Intermediate System to Intermediate System (IS-IS) Extensions in Support of Generalized Multi-Protocol Label Switching (GMPLS) 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 5120 MT-ISIS: Multi Topology (MT) 9.8(0.0P2) Routing in Intermediate System to Intermediate Systems (ISISs) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 5306 Restart Signaling for IS-IS 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.
Multicast The following table lists the Dell EMC Networking OS support per platform for Multicast protocol. Table 135. Multicast RFC# Full Name S-Series S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 1112 Host Extensions for IP Multicasting 7.8.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 2236 Internet Group Management Protocol, Version 2 7.8.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.10(0.1) 9.10(0.1) 3376 Internet Group Management Protocol, Version 3 7.8.1 9.8(0.0P2) 9.8(0.
RFC# Full Name S4810 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) dot1dTpLearnedEntryDiscards object] 1724 RIP Version 2 MIB Extension 1850 OSPF Version 2 Management Information Base 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 1901 Introduction to Community-based SNMPv2 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 2011 SNMPv2 Management Information Base for the Internet Protocol using SMIv2 7.6.1 9.8(0.
RFC# Full Name S4810 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON Internet-standard Network Management Framework 2578 Structure of Management Information Version 2 (SMIv2) 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 2579 Textual Conventions for SMIv2 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 2580 Conformance Statements for SMIv2 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.
RFC# Full Name S4810 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON Network Management Protocol (SNMP) 3418 Management Information Base (MIB) for the Simple Network Management Protocol (SNMP) 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 3434 Remote Monitoring MIB 7.6.1 Extensions for High Capacity Alarms, High-Capacity Alarm Table (64 bits) 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 3580 IEEE 802.
RFC# Full Name S4810 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 9.2(0.0) 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) isisISAdjIPAddrTable isisISAdjProtSuppTable draftietfnetmod interfac escfg-03 Defines a YANG data model for the configuration of network interfaces. Used in the Programmatic Interface RESTAPI feature. IEEE 802.1A B Management Information Base 7.7.1 module for LLDP configuration, statistics, local system data and remote systems data components. 9.8(0.0P2) 9.8(0.
RFC# Full Name S4810 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) FORCE Force10 E-Series Enterprise 10Chassis MIB CHASS IS-MIB 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) FORCE Force10 File Copy MIB (supporting 7.7.1 10SNMP SET operation) COPYCONFI G-MIB 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.
RFC# Full Name S4810 S3048–ON S4048–ON Z9100–ON S4048T-ON S6010–ON FORCE Force10 Textual Convention 10-TCMIB 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) FORCE Force10 Trap Alarm MIB 10TRAPALARM -MIB 7.6.1 9.8(0.0P2) 9.8(0.0P5) 9.8(1.0) 9.8(1.0) 9.8(1.0) ONENT -MIB 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.
65 X.509v3 supports X.509v3 standards. Topics: • • • • • • • • • Introduction to X.509v3 certification X.509v3 support in Information about installing CA certificates Information about Creating Certificate Signing Requests (CSR) Information about installing trusted certificates Transport layer security (TLS) Online Certificate Status Protocol (OSCP) Verifying certificates Event logging Introduction to X.509v3 certification X.
1 An entity or organization that wants a digital certificate requests one through a CSR. 2 To request a digital certificate through a CSR, a key pair is generated and the CSR is signed using the secret private key. The CSR contains information identifying the applicant and the applicant's public key. This public key is used to verify the signature of the CSR and the Distinguished Name (DN). 3 This CSR is sent to a Certificate Authority (CA).
The Root CA generates a private key and a self-signed CA certificate. The Intermediate CA generates a private key and a Certificate Signing Request (CSR). Using its private key, the root CA signs the intermediate CA’s CSR generating a CA certificate for the Intermediate CA. This intermediate CA can then sign certificates for hosts in the network and also for further intermediate CAs.
During the initial TLS protocol negotiation, both participating parties also check to see if the other’s certificate is revoked by the CA. To do this check, the devices query the CA’s designated OCSP responder on the network. The OCSP responder information is included in the presented certificate, the Intermediate CA inserts the info upon signing it, or it may be statically configured on the host. Information about installing CA certificates Dell EMC Networking OS enables you to download and install X.
If you do not specify the cert-file option, the system prompts you to enter metadata information related to the CSR as follows: You are about to be asked to enter information that will be incorporated into your certificate request. What you are about to enter is what is called a Distinguished Name or a DN. There are quite a few fields but you can leave some blank. For some fields there will be a default value; if you enter '.', the field will be left blank.
NOTE: The command contains multiple options with the Common Name being a required field and blanks being filled in for unspecified fields. Information about installing trusted certificates Dell EMC Networking OS also enables you to install a trusted certificate. The system can then present this certificate for authentication to clients such as SSH and HTTPS. This trusted certificate is also presented to the TLS server implementations that require client authentication such as Syslog.
TLS_ECDH_RSA_WITH_AES_256_CBC_SHA TLS_ECDH_RSA_WITH_AES_128_CBC_SHA TLS_DH_RSA_WITH_AES_256_CBC_SHA TLS_DH_RSA_WITH_AES_128_CBC_SHA TLS compression is disabled by default. TLS session resumption is also supported to reduce processor and traffic overhead due to public key cryptographic operations and handshake traffic. However, the maximum time allowed for a TLS session to resume without repeating the TLS authentication or handshake process is configurable with a default of 1 hour.
NOTE: If you have an IPv6 address in the URL, then enclose this address in square brackets. For example, http:// [1100::203]:6514. Configuring OCSP behavior You can configure how the OCSP requests and responses are signed when the CA or the device contacts the OCSP responders. To configure this behavior, follow this step: In CONFIGURATION mode, enter the following command: crypto x509 ocsp {[nonce] [sign-request]} Both the none and sign-request parameters are optional.
Verifying Server certificates Verifying server certificates is mandatory in the TLS protocol. As a result, all TLS-enabled applications require certificate verification, including Syslog servers. The system checks the Server certificates against installed CA certificates. NOTE: As part of the certificate verification, the hostname or IP address of the server is verified against the hostname or IP address specified in the application.
