Contents
- Implementing BGP on Cisco IOS XR Software
- Prerequisites for Implementing BGP
- Information About Implementing BGP
- BGP Functional Overview
- BGP Router Identifier
- BGP Default Limits
- BGP Next Hop Tracking
- Next Hop as the IPv6 Address of Peering Interface
- Scoped IPv4/VPNv4 Table Walk
- Reordered Address Family Processing
- New Thread for Next-Hop Processing
- show, clear, and debug Commands
- Autonomous System Number Formats in BGP
- 2-byte Autonomous System Number Format
- 4-byte Autonomous System Number Format
- as-format Command
- BGP Configuration
- Configuration Modes
- Router Configuration Mode
- Router Address Family Configuration Mode
- Neighbor Configuration Mode
- Neighbor Address Family Configuration Mode
- VRF Configuration Mode
- VRF Address Family Configuration Mode
- VRF Neighbor Configuration Mode
- VRF Neighbor Address Family Configuration Mode
- VPNv4 Address Family Configuration Mode
- VPNv6 Address Family Configuration Mode
- L2VPN Address Family Configuration Mode
- Neighbor Submode
- Configuration Templates
- Template Inheritance Rules
- Viewing Inherited Configurations
- show bgp neighbors
- show bgp af-group
- show bgp session-group
- show bgp neighbor-group
- No Default Address Family
- Routing Policy Enforcement
- Table Policy
- Update Groups
- BGP Update Generation and Update Groups
- BGP Update Group
- BGP Cost Community
- How BGP Cost Community Influences the Best Path Selection Process
- Cost Community Support for Aggregate Routes and Multipaths
- Influencing Route Preference in a Multiexit IGP Network
- BGP Cost Community Support for EIGRP MPLS VPN PE-CE with Back-door Links
- Adding Routes to the Routing Information Base
- BGP Best Path Algorithm
- Comparing Pairs of Paths
- Order of Comparisons
- Best Path Change Suppression
- Administrative Distance
- Multiprotocol BGP
- Route Dampening
- Minimizing Flapping
- BGP Routing Domain Confederation
- BGP Route Reflectors
- Default Address Family for show Commands
- Distributed BGP
- MPLS VPN Carrier Supporting Carrier
- BGP Keychains
- IPv6/IPv6 VPN Provider Edge Transport over MPLS
- IPv6 Provider Edge Multipath
- VPNv4/VPNv6 over the IP Core Using L2TPv3 Tunnels
- BGP Multicast VPN
- BGP Nonstop Routing
- BGP Best-External Path
- BGP Prefix Independent Convergence Unipath Primary/Backup
- BGP Local Label Retention
- Command Line Interface (CLI) Consistency for BGP Commands
- BGP Add Path
- iBGP Multipath Load Sharing
- Selective VRF Download
- How to Implement BGP on Cisco IOS XR Software
- Enabling BGP Routing
- Configuring a Routing Domain Confederation for BGP
- Resetting an eBGP Session Immediately Upon Link Failure
- Logging Neighbor Changes
- Adjusting BGP Timers
- Changing the BGP Default Local Preference Value
- Configuring the MED Metric for BGP
- Configuring BGP Weights
- Tuning the BGP Best-Path Calculation
- Indicating BGP Back-door Routes
- Configuring Aggregate Addresses
- Redistributing iBGP Routes into IGP
- Redistributing Prefixes into Multiprotocol BGP
- Configuring BGP Route Dampening
- Applying Policy When Updating the Routing Table
- Setting BGP Administrative Distance
- Configuring a BGP Neighbor Group and Neighbors
- Configuring a Route Reflector for BGP
- Configuring BGP Route Filtering by Route Policy
- Configuring BGP Next-Hop Trigger Delay
- Disabling Next-Hop Processing on BGP Updates
- Configuring BGP Community and Extended-Community Advertisements
- Configuring the BGP Cost Community
- Configuring Software to Store Updates from a Neighbor
- Configuring Distributed BGP
- Configuring a VPN Routing and Forwarding Instance in BGP
- Defining the Virtual Routing and Forwarding Tables in Provider Edge Routers
- Configuring the Route Distinguisher
- Configuring BGP to Advertise VRF Routes for Multicast VPN from PE to PE
- Advertising VRF Routes for MVPNv4 from PE to PE
- Advertising VRF Routes for MVPNv6 from PE to PE
- Configuring PE-PE or PE-RR Interior BGP Sessions
- Configuring Route Reflector to Hold Routes That Have a Defined Set of RT Communities
- Configuring BGP as a PE-CE Protocol
- Redistribution of IGPs to BGP
- Configuring Keychains for BGP
- Configuring an MDT Address Family Session in BGP
- Disabling a BGP Neighbor
- Resetting Neighbors Using BGP Inbound Soft Reset
- Resetting Neighbors Using BGP Outbound Soft Reset
- Resetting Neighbors Using BGP Hard Reset
- Clearing Caches, Tables, and Databases
- Displaying System and Network Statistics
- Displaying BGP Process Information
- Monitoring BGP Update Groups
- Configuring BGP Nonstop Routing
- Configuring Best-External Path Advertisement
- Installing Primary Backup Path
- Retaining Allocated Local Label for Primary Path
- Configuring BGP Additional Paths
- Configuring iBGP Multipath Load Sharing
- Configuration Examples for Implementing BGP
- Enabling BGP: Example
- Displaying BGP Update Groups: Example
- BGP Neighbor Configuration: Example
- BGP Confederation: Example
- BGP Route Reflector: Example
- BGP MDT Address Family Configuration: Example
- BGP Nonstop Routing Configuration: Example
- Best-External Path Advertisement Configuration: Example
- Primary Backup Path Installation: Example
- Allocated Local Label Retention: Example
- iBGP Multipath Loadsharing Configuration: Example
- Configuring BGP Additional Paths: Example
- Where to Go Next
- Additional References
Implementing BGP on Cisco IOS XR Software
Border Gateway Protocol (BGP) is an Exterior Gateway Protocol (EGP) that allows you to create loop-free interdomain routing between autonomous systems. An autonomous system is a set of routers under a single technical administration. Routers in an autonomous system can use multiple Interior Gateway Protocols (IGPs) to exchange routing information inside the autonomous system and an EGP to route packets outside the autonomous system.
This module provides the conceptual and configuration information for BGP on Cisco IOS XR software.
Note
For more information about BGP on the Cisco IOS XR software and complete descriptions of the BGP commands listed in this module, see Related Documents section of this module. To locate documentation for other commands that might appear while performing a configuration task, search online in the Cisco IOS XR software master command index.
Release
Modification
Release 3.2
This feature was introduced.
Release 3.3.0
VPN routing and forwarding (VRF) support was added, including information on VRF command modes and command syntax.
BGP cost community information was added.
Release 3.4.0
The following features were supported:
Release 3.5.0
The following features were supported:
IPv6 Provider Edge and IPv6 VPN Provider Edge over Multiprotocol Label Switching
Neighbor-specific VRF IPv6 address family configurations
Address family group-specific VPNv6 configurations
VPN4/VPNv6 over IP core using L2TPv3 tunnels
Multicast Distribution Tree (MDT) Subaddress Family Identifier Information (SAFI) support for multicast VPN (MVPN)
Release 3.6.0
No modification.
Release 3.7.0
The following features were supported:
Advertisement of VRF routes for multicast VPNs (MVPN) for both IPv4 and IPv6 address families from PE to PE
Edits were made to existing MVPN procedures based on new support for IPv6 multicast VPNs
Procedure Configuring an MDT Address Family Session in BGP was updated to reflect MVPN configuration of MDT SAFI from PE to PE
Release 3.8.0
The following features were supported:
Border Gateway Protocol (BGP) nonstop routing (NSR) with stateful switchover (SSO)
Next hop as the IPv6 address of peering interface
Reset weight on import of VPN routes
New commands enforce-first-as and enforce-first-as-disable were introduced to provide enable and disable configuration options for enforce-first-as feature in Neighbor, Neighbor group, and Session group configuration modes.
Release 3.9.0
The following features were supported:
Release 4.0.0
The following features were supported:
Release 4.1.0
The following features were supported:
- Prerequisites for Implementing BGP
- Information About Implementing BGP
- How to Implement BGP on Cisco IOS XR Software
- Configuration Examples for Implementing BGP
- Where to Go Next
- Additional References
Prerequisites for Implementing BGP
You must be in a user group associated with a task group that includes the proper task IDs. The command reference guides include the task IDs required for each command. If you suspect user group assignment is preventing you from using a command, contact your AAA administrator for assistance.
Information About Implementing BGP
To implement BGP, you need to understand the following concepts:
- BGP Functional Overview
- BGP Router Identifier
- BGP Default Limits
- BGP Next Hop Tracking
- Autonomous System Number Formats in BGP
- BGP Configuration
- No Default Address Family
- Routing Policy Enforcement
- Table Policy
- Update Groups
- BGP Cost Community
- BGP Best Path Algorithm
- Administrative Distance
- Multiprotocol BGP
- Route Dampening
- BGP Routing Domain Confederation
- BGP Route Reflectors
- Default Address Family for show Commands
- Distributed BGP
- MPLS VPN Carrier Supporting Carrier
- BGP Keychains
- IPv6/IPv6 VPN Provider Edge Transport over MPLS
- VPNv4/VPNv6 over the IP Core Using L2TPv3 Tunnels
- BGP Multicast VPN
- BGP Nonstop Routing
- BGP Best-External Path
- BGP Prefix Independent Convergence Unipath Primary/Backup
- BGP Local Label Retention
- Command Line Interface (CLI) Consistency for BGP Commands
- BGP Add Path
- iBGP Multipath Load Sharing
- Selective VRF Download
BGP Functional Overview
BGP uses TCP as its transport protocol. Two BGP routers form a TCP connection between one another (peer routers) and exchange messages to open and confirm the connection parameters.
BGP routers exchange network reachability information. This information is mainly an indication of the full paths (BGP autonomous system numbers) that a route should take to reach the destination network. This information helps construct a graph that shows which autonomous systems are loop free and where routing policies can be applied to enforce restrictions on routing behavior.
Any two routers forming a TCP connection to exchange BGP routing information are called peers or neighbors. BGP peers initially exchange their full BGP routing tables. After this exchange, incremental updates are sent as the routing table changes. BGP keeps a version number of the BGP table, which is the same for all of its BGP peers. The version number changes whenever BGP updates the table due to routing information changes. Keepalive packets are sent to ensure that the connection is alive between the BGP peers and notification packets are sent in response to error or special conditions.
Note
For information on configuring BGP to distribute Multiprotocol Label Switching (MPLS) Layer 3 virtual private network (VPN) information, see the Cisco IOS XR Multiprotocol Label Switching Configuration Guide for the Cisco XR 12000 Series Router
For information on BGP support for Bidirectional Forwarding Detection (BFD), see the Cisco IOS XR Interface and Hardware Configuration Guide for the Cisco XR 12000 Series Router and the Cisco IOS XR Interface and Hardware Command Reference for the Cisco XR 12000 Series Router.
BGP Router Identifier
For BGP sessions between neighbors to be established, BGP must be assigned a router ID. The router ID is sent to BGP peers in the OPEN message when a BGP session is established.
BGP attempts to obtain a router ID in the following ways (in order of preference):
By means of the address configured using the bgp router-id command in router configuration mode.
By using the highest IPv4 address on a loopback interface in the system if the router is booted with saved loopback address configuration.
By using the primary IPv4 address of the first loopback address that gets configured if there are not any in the saved configuration.
If none of these methods for obtaining a router ID succeeds, BGP does not have a router ID and cannot establish any peering sessions with BGP neighbors. In such an instance, an error message is entered in the system log, and the show bgp summary command displays a router ID of 0.0.0.0.
After BGP has obtained a router ID, it continues to use it even if a better router ID becomes available. This usage avoids unnecessary flapping for all BGP sessions. However, if the router ID currently in use becomes invalid (because the interface goes down or its configuration is changed), BGP selects a new router ID (using the rules described) and all established peering sessions are reset.
Note
We strongly recommend that the bgp router-id command is configured to prevent unnecessary changes to the router ID (and consequent flapping of BGP sessions).
BGP Default Limits
Cisco IOS XR BGP imposes maximum limits on the number of neighbors that can be configured on the router and on the maximum number of prefixes that are accepted from a peer for a given address family. This limitation safeguards the router from resource depletion caused by misconfiguration, either locally or on the remote neighbor. The following limits apply to BGP configurations:
The default maximum number of peers that can be configured is 4000. The default can be changed using the bgp maximum neighbor command. The limit range is 1 to 15000. Any attempt to configure additional peers beyond the maximum limit or set the maximum limit to a number that is less than the number of peers currently configured will fail.
- To prevent a peer from flooding BGP with advertisements, a limit is placed on the number of prefixes that are accepted from a peer for each supported address family. The default limits can be overridden through configuration of the maximum-prefix limit command for the peer for the appropriate address family. The following default limits are used if the user does not configure the maximum number of prefixes for the address family:
512K (524,288) prefixes for IPv4 unicast.
128K (131,072) prefixes for IPv4 multicast.
128K (131,072) prefixes for IPv6 unicast.
128K (131,072) prefixes for IPv6 multicast
512K (524,288) prefixes for VPNv4 unicast
512K (524,288) prefixes for VPNv6 unicast
A cease notification message is sent to the neighbor and the peering with the neighbor is terminated when the number of prefixes received from the peer for a given address family exceeds the maximum limit (either set by default or configured by the user) for that address family.
It is possible that the maximum number of prefixes for a neighbor for a given address family has been configured after the peering with the neighbor has been established and a certain number of prefixes have already been received from the neighbor for that address family. A cease notification message is sent to the neighbor and peering with the neighbor is terminated immediately after the configuration if the configured maximum number of prefixes is fewer than the number of prefixes that have already been received from the neighbor for the address family.
BGP Next Hop Tracking
BGP receives notifications from the Routing Information Base (RIB) when next-hop information changes (event-driven notifications). BGP obtains next-hop information from the RIB to:
Determine whether a next hop is reachable.
Find the fully recursed IGP metric to the next hop (used in the best-path calculation).
Validate the received next hops.
Calculate the outgoing next hops.
Verify the reachability and connectedness of neighbors.
BGP is notified when any of the following events occurs:
Next hop becomes unreachable
Next hop becomes reachable
Fully recursed IGP metric to the next hop changes
First hop IP address or first hop interface change
Next hop becomes connected
Next hop becomes unconnected
Next hop becomes a local address
Next hop becomes a nonlocal address
Note
Reachability and recursed metric events trigger a best-path recalculation.
Event notifications from the RIB are classified as critical and noncritical. Notifications for critical and noncritical events are sent in separate batches. However, a noncritical event is sent along with the critical events if the noncritical event is pending and there is a request to read the critical events.
Critical events are related to the reachability (reachable and unreachable), connectivity (connected and unconnected), and locality (local and nonlocal) of the next hops. Notifications for these events are not delayed.
Noncritical events include only the IGP metric changes. These events are sent at an interval of 3 seconds. A metric change event is batched and sent 3 seconds after the last one was sent.
The next-hop trigger delay for critical and noncritical events can be configured to specify a minimum batching interval for critical and noncritical events using the nexthop trigger-delay command. The trigger delay is address family dependent.
The BGP next-hop tracking feature allows you to specify that BGP routes are resolved using only next hops whose routes have the following characteristics:
To avoid the aggregate routes, the prefix length must be greater than a specified value.
The source protocol must be from a selected list, ensuring that BGP routes are not used to resolve next hops that could lead to oscillation.
This route policy filtering is possible because RIB identifies the source protocol of route that resolved a next hop as well as the mask length associated with the route. The nexthop route-policy command is used to specify the route-policy.
For information on route policy filtering for next hops using the next-hop attach point, see the Implementing Routing Policy Language on Cisco IOS XR Software module of Cisco IOS XR Routing Configuration Guide (this publication).
- Next Hop as the IPv6 Address of Peering Interface
- Scoped IPv4/VPNv4 Table Walk
- Reordered Address Family Processing
- New Thread for Next-Hop Processing
- show, clear, and debug Commands
Next Hop as the IPv6 Address of Peering Interface
BGP can carry IPv6 prefixes over an IPv4 session. The next hop for the IPv6 prefixes can be set through a nexthop policy. In the event that the policy is not configured, the nexthops are set as the IPv6 address of the peering interface (IPv6 neighbor interface or IPv6 update source interface, if any one of the interfaces is configured).
If the nexthop policy is not configured and neither the IPv6 neighbor interface nor the IPv6 update source interface is configured, the next hop is the IPv4 mapped IPv6 address.
Scoped IPv4/VPNv4 Table Walk
To determine which address family to process, a next-hop notification is received by first dereferencing the gateway context associated with the next hop, then looking into the gateway context to determine which address families are using the gateway context. The IPv4 unicast and VPNv4 unicast address families share the same gateway context, because they are registered with the IPv4 unicast table in the RIB. As a result, both the global IPv4 unicast table and the VPNv4 table are processed when an IPv4 unicast next-hop notification is received from the RIB. A mask is maintained in the next hop, indicating whether the next hop belongs to IPv4 unicast or VPNv4 unicast, or both. This scoped table walk localizes the processing in the appropriate address family table.
Reordered Address Family Processing
The Cisco IOS XR software walks address family tables based on the numeric value of the address family. When a next-hop notification batch is received, the order of address family processing is reordered to the following order:
New Thread for Next-Hop Processing
The critical-event thread in the spkr process handles only next-hop, Bidirectional Forwarding Detection (BFD), and fast-external-failover (FEF) notifications. This critical-event thread ensures that BGP convergence is not adversely impacted by other events that may take a significant amount of time.
show, clear, and debug Commands
The show bgp nexthops command provides statistical information about next-hop notifications, the amount of time spent in processing those notifications, and details about each next hop registered with the RIB. The clear bgp nexthop performance-statistics command ensures that the cumulative statistics associated with the processing part of the next-hop show command can be cleared to help in monitoring. The clear bgp nexthop registration command performs an asynchronous registration of the next hop with the RIB. See the BGP Commands on Cisco IOS XR Softwaremodule of Cisco IOS XR Routing Command Reference for the Cisco XR 12000 Series Routerfor information on the next-hop show and clear commands.
The debug bgp nexthop command displays information on next-hop processing. The out keyword provides debug information only about BGP registration of next hops with RIB. The in keyword displays debug information about next-hop notifications received from RIB. The out keyword displays debug information about next-hop notifications sent to the RIB. See the BGP Debug Commands on Cisco IOS XR Software module of Cisco IOS XR Routing Debug Command Reference for the Cisco XR 12000 Series Router .
Autonomous System Number Formats in BGP
Autonomous system numbers (ASNs) are globally unique identifiers used to identify autonomous systems (ASs) and enable ASs to exchange exterior routing information between neighboring ASs. A unique ASN is allocated to each AS for use in BGP routing. ASNs are encoded as 2-byte numbers and 4-byte numbers in BGP.
2-byte Autonomous System Number Format
The 2-byte ASNs are represented in asplain notation. The 2-byte range is 1 to 65535.
4-byte Autonomous System Number Format
To prepare for the eventual exhaustion of 2-byte Autonomous System Numbers (ASNs), BGP has the capability to support 4-byte ASNs. The 4-byte ASNs are represented both in asplain and asdot notations.
The byte range for 4-byte ASNs in asplain notation is 1-4294967295. The AS is represented as a 4-byte decimal number. The 4-byte ASN asplain representation is defined in draft-ietf-idr-as-representation-01.txt.
For 4-byte ASNs in asdot format, the 4-byte range is 1.0 to 65535.65535 and the format is:
high-order-16-bit-value-in-decimal . low-order-16-bit-value-in-decimal
The BGP 4-byte ASN capability is used to propagate 4-byte-based AS path information across BGP speakers that do not support 4-byte AS numbers. See draft-ietf-idr-as4bytes-12.txt for information on increasing the size of an ASN from 2 bytes to 4 bytes. AS is represented as a 4-byte decimal number
BGP Configuration
BGP in Cisco IOS XR software follows a neighbor-based configuration model that requires that all configurations for a particular neighbor be grouped in one place under the neighbor configuration. Peer groups are not supported for either sharing configuration between neighbors or for sharing update messages. The concept of peer group has been replaced by a set of configuration groups to be used as templates in BGP configuration and automatically generated update groups to share update messages between neighbors.
- Configuration Modes
- Neighbor Submode
- Configuration Templates
- Template Inheritance Rules
- Viewing Inherited Configurations
Configuration Modes
BGP configurations are grouped into modes. The following sections show how to enter some of the BGP configuration modes. From a mode, you can enter the ? command to display the commands available in that mode.
- Router Configuration Mode
- Router Address Family Configuration Mode
- Neighbor Configuration Mode
- Neighbor Address Family Configuration Mode
- VRF Configuration Mode
- VRF Address Family Configuration Mode
- VRF Neighbor Configuration Mode
- VRF Neighbor Address Family Configuration Mode
- VPNv4 Address Family Configuration Mode
- VPNv6 Address Family Configuration Mode
- L2VPN Address Family Configuration Mode
Router Configuration Mode
The following example shows how to enter router configuration mode:
RP/0/0/CPU0:router# configuration RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)#Router Address Family Configuration Mode
The following example shows how to enter router address family configuration mode:
RP/0/0/CPU0:router(config)# router bgp 112 RP/0/0/CPU0:router(config-bgp)# address-family ipv4 multicast RP/0/0/CPU0:router(config-bgp-af)#Neighbor Configuration Mode
The following example shows how to enter neighbor configuration mode:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# neighbor 10.0.0.1 RP/0/0/CPU0:router(config-bgp-nbr)#Neighbor Address Family Configuration Mode
The following example shows how to enter neighbor address family configuration mode:
RP/0/0/CPU0:router(config)# router bgp 112 RP/0/0/CPU0:router(config-bgp)# neighbor 10.0.0.1 RP/0/0/CPU0:router(config-bgp-nbr)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbr-af)#VRF Configuration Mode
The following example shows how to enter VPN routing and forwarding (VRF) configuration mode:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# vrf vrf_A RP/0/0/CPU0:router(config-bgp-vrf)#VRF Address Family Configuration Mode
The following example shows how to enter VRF address family configuration mode:
RP/0/0/CPU0:router(config)# router bgp 112 RP/0/0/CPU0:router(config-bgp)# vrf vrf_A RP/0/0/CPU0:router(config-bgp-vrf)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-vrf-af)#VRF Neighbor Configuration Mode
The following example shows how to enter VRF neighbor configuration mode:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# vrf vrf_A RP/0/0/CPU0:router(config-bgp-vrf)# neighbor 11.0.1.2 RP/0/0/CPU0:router(config-bgp-vrf-nbr)#VRF Neighbor Address Family Configuration Mode
The following example shows how to enter VRF neighbor address family configuration mode:
RP/0/0/CPU0:router(config)# router bgp 112 RP/0/0/CPU0:router(config-bgp)# vrf vrf_A RP/0/0/CPU0:router(config-bgp-vrf)# neighbor 11.0.1.2 RP/0/0/CPU0:router(config-bgp-vrf-nbr)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)#VPNv4 Address Family Configuration Mode
The following example shows how to enter VPNv4 address family configuration mode:
RP/0/0/CPU0:router(config)# router bgp 152 RP/0/0/CPU0:router(config-bgp)# address-family vpnv4 unicast RP/0/0/CPU0:router(config-bgp-af)#Neighbor Submode
Cisco IOS XR BGP uses a neighbor submode to make it possible to enter configurations without having to prefix every configuration with the neighbor keyword and the neighbor address:
Cisco IOS XR software has a submode available for neighbors in which it is not necessary for every command to have a “neighbor x.x.x.x” prefix:
In Cisco IOS XR software, the configuration is as follows:
RP/0/ RP0/CPU0:router(config-bgp)# neighbor 192.23.1.2 RP/0/ RP0/CPU0:router(config-bgp-nbr)# remote-as 2002 RP/0/ RP0/CPU0:router(config-bgp-nbr)# address-family ipv4 multicastAn address family configuration submode inside the neighbor configuration submode is available for entering address family-specific neighbor configurations. In Cisco IOS XR software, the configuration is as follows:
RP/0/ RP0/CPU0:router(config-bgp)# neighbor 2002::2 RP/0/ RP0/CPU0:router(config-bgp-nbr)# remote-as 2023 RP/0/ RP0/CPU0:router(config-bgp-nbr)# address-family ipv6 unicast RP/0/ RP0/CPU0:router(config-bgp-nbr-af)# next-hop-self RP/0/ RP0/CPU0:router(config-bgp-nbr-af)# route-policy one inYou must enter neighbor-specific IPv4, IPv6, VPNv4, or VPNv6 commands in neighbor address-family configuration submode. In Cisco IOS XR software, the configuration is as follows:
RP/0/ RP0/CPU0:router(config)# router bgp 109 RP/0/ RP0/CPU0:router(config-bgp)# neighbor 192.168.40.24 RP/0/ RP0/CPU0:router(config-bgp-nbr)# remote-as 1 RP/0/ RP0/CPU0:router(config-bgp-nbr)# address-family ipv4 unicast RP/0/ RP0/CPU0:router(config-bgp-nbr-af)# maximum-prefix 1000You must enter neighbor-specific IPv4 and IPv6 commands in VRF neighbor address-family configuration submode. In Cisco IOS XR software, the configuration is as follows:
RP/0/ RP0/CPU0:router(config)# router bgp 110 RP/0/ RP0/CPU0:router(config-bgp)# vrf vrf_A RP/0/ RP0/CPU0:router(config-bgp-vrf)# neighbor 11.0.1.2 RP/0/ RP0/CPU0:router(config-bgp-vrf-nbr)# address-family ipv4 unicast RP/0/ RP0/CPU0:router(config-bgp-vrf-nbr-af)# route-policy pass all inConfiguration Templates
The af-group, session-group, and neighbor-group configuration commands provide template support for the neighbor configuration in Cisco IOS XR software.
The af-group command is used to group address family-specific neighbor commands within an IPv4, IPv6, VPNv4, or VPNv6 address family. Neighbors that have the same address family configuration are able to use the address family group (af-group) name for their address family-specific configuration. A neighbor inherits the configuration from an address family group by way of the use command. If a neighbor is configured to use an address family group, the neighbor (by default) inherits the entire configuration from the address family group. However, a neighbor does not inherit all of the configuration from the address family group if items are explicitly configured for the neighbor. The address family group configuration is entered under the BGP router configuration mode. The following example shows how to enter address family group configuration mode :
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# af-group afmcast1 address-family ipv4 multicast RP/0/0/CPU0:router(config-bgp-afgrp)#The session-group command allows you to create a session group from which neighbors can inherit address family-independent configuration. A neighbor inherits the configuration from a session group by way of the use command. If a neighbor is configured to use a session group, the neighbor (by default) inherits the entire configuration of the session group. A neighbor does not inherit all of the configuration from a session group if a configuration is done directly on that neighbor. The following example shows how to enter session group configuration mode:
RP/0/0/CPU0:router# router bgp 140 RP/0/0/CPU0:router(config-bgp)# session-group session1 RP/0/0/CPU0:router(config-bgp-sngrp)#The neighbor-group command helps you apply the same configuration to one or more neighbors. Neighbor groups can include session groups and address family groups and can comprise the complete configuration for a neighbor. After a neighbor group is configured, a neighbor can inherit the configuration of the group using the use command. If a neighbor is configured to use a neighbor group, the neighbor inherits the entire BGP configuration of the neighbor group.
The following example shows how to enter neighbor group configuration mode:
RP/0/0/CPU0:router(config)# router bgp 123 RP/0/0/CPU0:router(config-bgp)# neighbor-group nbrgroup1 RP/0/0/CPU0:router(config-bgp-nbrgrp)#The following example shows how to enter neighbor group address family configuration mode:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# neighbor-group nbrgroup1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbrgrp-af)#
However, a neighbor does not inherit all of the configuration from the neighbor group if items are explicitly configured for the neighbor. In addition, some part of the configuration of the neighbor group could be hidden if a session group or address family group was also being used.
Configuration grouping has the following effects in Cisco IOS XR software:
Commands entered at the session group level define address family-independent commands (the same commands as in the neighbor submode).
Commands entered at the address family group level define address family-dependent commands for a specified address family (the same commands as in the neighbor-address family configuration submode).
Commands entered at the neighbor group level define address family-independent commands and address family-dependent commands for each address family (the same as all available neighbor commands), and define the use command for the address family group and session group commands.
Template Inheritance Rules
In Cisco IOS XR software, BGP neighbors or groups inherit configuration from other configuration groups.
For address family-independent configurations:
Neighbors can inherit from session groups and neighbor groups.
Neighbor groups can inherit from session groups and other neighbor groups.
Session groups can inherit from other session groups.
If a neighbor uses a session group and a neighbor group, the configurations in the session group are preferred over the global address family configurations in the neighbor group.
For address family-dependent configurations:
Address family groups can inherit from other address family groups.
Neighbor groups can inherit from address family groups and other neighbor groups.
Neighbors can inherit from address family groups and neighbor groups.
Configuration group inheritance rules are numbered in order of precedence as follows:
If the item is configured directly on the neighbor, that value is used. In the example that follows, the advertisement interval is configured both on the neighbor group and neighbor configuration and the advertisement interval being used is from the neighbor configuration:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# neighbor-group AS_1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# advertisement-interval 15 RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 10.1.1.1 RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 1 RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group AS_1 RP/0/0/CPU0:router(config-bgp-nbr)# advertisement-interval 20The following output from the show bgp neighbors command shows that the advertisement interval used is 20 seconds:
RP/0/0/CPU0:router# show bgp neighbors 10.1.1.1 BGP neighbor is 10.1.1.1, remote AS 1, local AS 140, external link Remote router ID 0.0.0.0 BGP state = Idle Last read 00:00:00, 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 Minimum time between advertisement runs is 20 seconds For Address Family: IPv4 Unicast BGP neighbor version 0 Update group: 0.1 eBGP neighbor with no inbound or outbound policy; defaults to 'drop' Route refresh request: received 0, sent 0 0 accepted prefixes Prefix advertised 0, suppressed 0, withdrawn 0, maximum limit 524288 Threshold for warning message 75% Connections established 0; dropped 0 Last reset 00:00:14, due to BGP neighbor initialized External BGP neighbor not directly connected.
Otherwise, if an item is configured to be inherited from a session-group or neighbor-group and on the neighbor directly, then the configuration on the neighbor is used. If a neighbor is configured to be inherited from session-group or af-group, but no directly configured value, then the value in the session-group or af-group is used. In the example that follows, the advertisement interval is configured on a neighbor group and a session group and the advertisement interval value being used is from the session group:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# session-group AS_2 RP/0/0/CPU0:router(config-bgp-sngrp)# advertisement-interval 15 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group AS_1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# advertisement-interval 20 RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 192.168.0.1 RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 1 RP/0/0/CPU0:router(config-bgp-nbr)# use session-group AS_2 RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group AS_1The following output from the show bgp neighbors command shows that the advertisement interval used is 15 seconds:RP/0/0/CPU0:router# show bgp neighbors 192.168.0.1 BGP neighbor is 192.168.0.1, remote AS 1, local AS 140, external link Remote router ID 0.0.0.0 BGP state = Idle Last read 00:00:00, 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 Minimum time between advertisement runs is 15 seconds For Address Family: IPv4 Unicast BGP neighbor version 0 Update group: 0.1 eBGP neighbor with no inbound or outbound policy; defaults to 'drop' Route refresh request: received 0, sent 0 0 accepted prefixes Prefix advertised 0, suppressed 0, withdrawn 0, maximum limit 524288 Threshold for warning message 75% Connections established 0; dropped 0 Last reset 00:03:23, due to BGP neighbor initialized External BGP neighbor not directly connected.
Otherwise, if the neighbor uses a neighbor group and does not use a session group or address family group, the configuration value can be obtained from the neighbor group either directly or through inheritance. In the example that follows, the advertisement interval from the neighbor group is used because it is not configured directly on the neighbor and no session group is used:
RP/0/0/CPU0:router(config)# router bgp 150 RP/0/0/CPU0:router(config-bgp)# session-group AS_2 RP/0/0/CPU0:router(config-bgp-sngrp)# advertisement-interval 20 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group AS_1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# advertisement-interval 15 RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 192.168.1.1 RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 1 RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group AS_1The following output from the show bgp neighbors command shows that the advertisement interval used is 15 seconds:RP/0/0/CPU0:router# show bgp neighbors 192.168.1.1 BGP neighbor is 192.168.2.2, remote AS 1, local AS 140, external link Remote router ID 0.0.0.0 BGP state = Idle Last read 00:00:00, 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 Minimum time between advertisement runs is 15 seconds For Address Family: IPv4 Unicast BGP neighbor version 0 Update group: 0.1 eBGP neighbor with no outbound policy; defaults to 'drop' Route refresh request: received 0, sent 0 Inbound path policy configured Policy for incoming advertisements is POLICY_1 0 accepted prefixes Prefix advertised 0, suppressed 0, withdrawn 0, maximum limit 524288 Threshold for warning message 75% Connections established 0; dropped 0 Last reset 00:01:14, due to BGP neighbor initialized External BGP neighbor not directly connected.
To illustrate the same rule, the following example shows how to set the advertisement interval to 15 (from the session group) and 25 (from the neighbor group). The advertisement interval set in the session group overrides the one set in the neighbor group. The inbound policy is set to POLICY_1 from the neighbor group.RP/0/0/CPU0:routerconfig)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# session-group ADV RP/0/0/CPU0:router(config-bgp-sngrp)# advertisement-interval 15 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group ADV_2 RP/0/0/CPU0:router(config-bgp-nbrgrp)# advertisement-interval 25 RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# route-policy POLICY_1 in RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# exit RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 192.168.2.2 RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 1 RP/0/0/CPU0:router(config-bgp-nbr)# use session-group ADV RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group ADV_2The following output from the show bgp neighbors command shows that the advertisement interval used is 15 seconds:RP/0/0/CPU0:router# show bgp neighbors 192.168.2.2 BGP neighbor is 192.168.2.2, remote AS 1, local AS 140, external link Remote router ID 0.0.0.0 BGP state = Idle Last read 00:00:00, 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 Minimum time between advertisement runs is 15 seconds For Address Family: IPv4 Unicast BGP neighbor version 0 Update group: 0.1 eBGP neighbor with no inbound or outbound policy; defaults to 'drop' Route refresh request: received 0, sent 0 0 accepted prefixes Prefix advertised 0, suppressed 0, withdrawn 0, maximum limit 524288 Threshold for warning message 75% Connections established 0; dropped 0 Last reset 00:02:03, due to BGP neighbor initialized External BGP neighbor not directly connected.
Otherwise, the default value is used. In the example that follows, neighbor 10.0.101.5 has the minimum time between advertisement runs set to 30 seconds (default) because the neighbor is not configured to use the neighbor configuration or the neighbor group configuration:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# neighbor-group AS_1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# remote-as 1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group adv_15 RP/0/0/CPU0:router(config-bgp-nbrgrp)# remote-as 10 RP/0/0/CPU0:router(config-bgp-nbrgrp)# advertisement-interval 15 RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 10.0.101.5 RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group AS_1 RP/0/0/CPU0:router(config-bgp-nbr)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 10.0.101.10 RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group adv_15The following output from the show bgp neighbors command shows that the advertisement interval used is 30 seconds:RP/0/0/CPU0:router# show bgp neighbors 10.0.101.5 BGP neighbor is 10.0.101.5, remote AS 1, local AS 140, external link Remote router ID 0.0.0.0 BGP state = Idle Last read 00:00:00, 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 Minimum time between advertisement runs is 30 seconds For Address Family: IPv4 Unicast BGP neighbor version 0 Update group: 0.2 eBGP neighbor with no inbound or outbound policy; defaults to 'drop' Route refresh request: received 0, sent 0 0 accepted prefixes Prefix advertised 0, suppressed 0, withdrawn 0, maximum limit 524288 Threshold for warning message 75% Connections established 0; dropped 0 Last reset 00:00:25, due to BGP neighbor initialized External BGP neighbor not directly connected.
The inheritance rules used when groups are inheriting configuration from other groups are the same as the rules given for neighbors inheriting from groups.
Viewing Inherited Configurations
You can use the following show commands to view BGP inherited configurations:
show bgp neighbors
Use the show bgp neighbors command to display information about the BGP configuration for neighbors.
Use the configuration keyword to display the effective configuration for the neighbor, including any settings that have been inherited from session groups, neighbor groups, or address family groups used by this neighbor.
Use the inheritance keyword to display the session groups, neighbor groups, and address family groups from which this neighbor is capable of inheriting configuration.
The show bgp neighbors command examples that follow are based on this sample configuration:
RP/0/0/CPU0:router(config)# router bgp 142 RP/0/0/CPU0:router(config-bgp)# af-group GROUP_3 address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-afgrp)# next-hop-self RP/0/0/CPU0:router(config-bgp-afgrp)# route-policy POLICY_1 in RP/0/0/CPU0:router(config-bgp-afgrp)# exit RP/0/0/CPU0:router(config-bgp)# session-group GROUP_2 RP/0/0/CPU0:router(config-bgp-sngrp)# advertisement-interval 15 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group GROUP_1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# use session-group GROUP_2 RP/0/0/CPU0:router(config-bgp-nbrgrp)# ebgp-multihop 3 RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# weight 100 RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# send-community-ebgp RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# exit RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family ipv4 multicast RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# default-originate RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# exit RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor 192.168.0.1 RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2 RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group GROUP_1 RP/0/0/CPU0:router(config-bgp-nbr)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbr-af)# use af-group GROUP_3 RP/0/0/CPU0:router(config-bgp-nbr-af)# weight 200The following example displays sample output from the show bgp neighbors command using the inheritance keyword. The example shows that the neighbor inherits session parameters from neighbor group GROUP_1, which in turn inherits from session group GROUP_2. The neighbor inherits IPv4 unicast parameters from address family group GROUP_3 and IPv4 multicast parameters from neighbor group GROUP_1:
RP/0/0/CPU0:router# show bgp neighbors 192.168.0.1 inheritance Session: n:GROUP_1 s:GROUP_2 IPv4 Unicast: a:GROUP_3 IPv4 Multicast: n:GROUP_1
The following example displays sample output from the show bgp neighbors command using the configuration keyword. The example shows from where each item of configuration was inherited, or if it was configured directly on the neighbor (indicated by [ ]). For example, the ebgp-multihop 3 command was inherited from neighbor group GROUP_1 and the next-hop-self command was inherited from the address family group GROUP_3:
RP/0/0/CPU0:router# show bgp neighbors 192.168.0.1 configuration neighbor 192.168.0.1 remote-as 2 [] advertisement-interval 15 [n:GROUP_1 s:GROUP_2] ebgp-multihop 3 [n:GROUP_1] address-family ipv4 unicast [] next-hop-self [a:GROUP_3] route-policy POLICY_1 in [a:GROUP_3] weight 200 [] address-family ipv4 multicast [n:GROUP_1] default-originate [n:GROUP_1]
show bgp af-group
Use the show bgp af-group command to display address family groups:
Use the configuration keyword to display the effective configuration for the address family group, including any settings that have been inherited from address family groups used by this address family group.
Use the inheritance keyword to display the address family groups from which this address family group is capable of inheriting configuration.
Use the users keyword to display the neighbors, neighbor groups, and address family groups that inherit configuration from this address family group.
The show bgp af-group sample commands that follow are based on this sample configuration:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# af-group GROUP_3 address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-afgrp)# remove-private-as RP/0/0/CPU0:router(config-bgp-afgrp)# route-policy POLICY_1 in RP/0/0/CPU0:router(config-bgp-afgrp)# exit RP/0/0/CPU0:router(config-bgp)# af-group GROUP_1 address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-afgrp)# use af-group GROUP_2 RP/0/0/CPU0:router(config-bgp-afgrp)# maximum-prefix 2500 75 warning-only RP/0/0/CPU0:router(config-bgp-afgrp)# default-originate RP/0/0/CPU0:router(config-bgp-afgrp)# exit RP/0/0/CPU0:router(config-bgp)# af-group GROUP_2 address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-afgrp)# use af-group GROUP_3 RP/0/0/CPU0:router(config-bgp-afgrp)# send-community-ebgp RP/0/0/CPU0:router(config-bgp-afgrp)# send-extended-community-ebgp RP/0/0/CPU0:router(config-bgp-afgrp)# capability orf prefix bothThe following example displays sample output from the show bgp af-group command using the configuration keyword. This example shows from where each configuration item was inherited. The default-originate command was configured directly on this address family group (indicated by [ ]). The remove-private-as command was inherited from address family group GROUP_2, which in turn inherited from address family group GROUP_3:
RP/0/0/CPU0:router# show bgp af-group GROUP_1 configuration af-group GROUP_1 address-family ipv4 unicast capability orf prefix-list both [a:GROUP_2] default-originate [] maximum-prefix 2500 75 warning-only [] route-policy POLICY_1 in [a:GROUP_2 a:GROUP_3] remove-private-AS [a:GROUP_2 a:GROUP_3] send-community-ebgp [a:GROUP_2] send-extended-community-ebgp [a:GROUP_2]
The following example displays sample output from the show bgp af-group command using the users keyword:
RP/0/0/CPU0:router# show bgp af-group GROUP_2 users IPv4 Unicast: a:GROUP_1
The following example displays sample output from the show bgp af-group command using the inheritance keyword. This shows that the specified address family group GROUP_1 directly uses the GROUP_2 address family group, which in turn uses the GROUP_3 address family group:
RP/0/0/CPU0:router# show bgp af-group GROUP_1 inheritance IPv4 Unicast: a:GROUP_2 a:GROUP_3
show bgp session-group
Use the show bgp session-group command to display session groups:
Use the configuration keyword to display the effective configuration for the session group, including any settings that have been inherited from session groups used by this session group.
Use the inheritance keyword to display the session groups from which this session group is capable of inheriting configuration.
Use the users keyword to display the session groups, neighbor groups, and neighbors that inherit configuration from this session group.
The output from the show bgp session-group command is based on the following session group configuration:
RP/0/0/CPU0:router(config)# router bgp 113 RP/0/0/CPU0:router(config-bgp)# session-group GROUP_1 RP/0/0/CPU0:router(config-bgp-sngrp)# use session-group GROUP_2 RP/0/0/CPU0:router(config-bgp-sngrp)# update-source Loopback 0 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# session-group GROUP_2 RP/0/0/CPU0:router(config-bgp-sngrp)# use session-group GROUP_3 RP/0/0/CPU0:router(config-bgp-sngrp)# ebgp-multihop 2 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# session-group GROUP_3 RP/0/0/CPU0:router(config-bgp-sngrp)# dmz-link-bandwidthThe following is sample output from the show bgp session-group command with the configuration keyword in EXEC mode:
RP/0/0/CPU0:router# show bgp session-group GROUP_1 configuration session-group GROUP_1 ebgp-multihop 2 [s:GROUP_2] update-source Loopback0 [] dmz-link-bandwidth [s:GROUP_2 s:GROUP_3]
The following is sample output from the show bgp session-group command with the inheritance keyword showing that the GROUP_1 session group inherits session parameters from the GROUP_3 and GROUP_2 session groups:
RP/0/0/CPU0:router# show bgp session-group GROUP_1 inheritance Session: s:GROUP_2 s:GROUP_3
The following is sample output from the show bgp session-group command with the users keyword showing that both the GROUP_1 and GROUP_2 session groups inherit session parameters from the GROUP_3 session group:
RP/0/0/CPU0:router# show bgp session-group GROUP_3 users Session: s:GROUP_1 s:GROUP_2
show bgp neighbor-group
Use the show bgp neighbor-group command to display neighbor groups:
Use the configuration keyword to display the effective configuration for the neighbor group, including any settings that have been inherited from neighbor groups used by this neighbor group.
Use the inheritance keyword to display the address family groups, session groups, and neighbor groups from which this neighbor group is capable of inheriting configuration.
Use the users keyword to display the neighbors and neighbor groups that inherit configuration from this neighbor group.
The examples are based on the following group configuration:
RP/0/0/CPU0:router(config)# router bgp 140 RP/0/0/CPU0:router(config-bgp)# af-group GROUP_3 address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-afgrp)# remove-private-as RP/0/0/CPU0:router(config-bgp-afgrp)# soft-reconfiguration inbound RP/0/0/CPU0:router(config-bgp-afgrp)# exit RP/0/0/CPU0:router(config-bgp)# af-group GROUP_2 address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-afgrp)# use af-group GROUP_3 RP/0/0/CPU0:router(config-bgp-afgrp)# send-community-ebgp RP/0/0/CPU0:router(config-bgp-afgrp)# send-extended-community-ebgp RP/0/0/CPU0:router(config-bgp-afgrp)# capability orf prefix both RP/0/0/CPU0:router(config-bgp-afgrp)# exit RP/0/0/CPU0:router(config-bgp)# session-group GROUP_3 RP/0/0/CPU0:router(config-bgp-sngrp)# timers 30 90 RP/0/0/CPU0:router(config-bgp-sngrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group GROUP_1 RP/0/0/CPU0:router(config-bgp-nbrgrp)# remote-as 1982 RP/0/0/CPU0:router(config-bgp-nbrgrp)# use neighbor-group GROUP_2 RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# exit RP/0/0/CPU0:router(config-nbrgrp)# exit RP/0/0/CPU0:router(config-bgp)# neighbor-group GROUP_2 RP/0/0/CPU0:router(config-bgp-nbrgrp)# use session-group GROUP_3 RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family ipv4 unicast RP/0/0/CPU0:routerconfig-bgp-nbrgrp-af)# use af-group GROUP_2 RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# weight 100The following is sample output from the show bgp neighbor-group command with the configuration keyword. The configuration setting source is shown to the right of each command. In the output shown previously, the remote autonomous system is configured directly on neighbor group GROUP_1, and the send community setting is inherited from neighbor group GROUP_2, which in turn inherits the setting from address family group GROUP_3:
RP/0/0/CPU0:router# show bgp neighbor-group GROUP_1 configuration neighbor-group GROUP_1 remote-as 1982 [] timers 30 90 [n:GROUP_2 s:GROUP_3] address-family ipv4 unicast [] capability orf prefix-list both [n:GROUP_2 a:GROUP_2] remove-private-AS [n:GROUP_2 a:GROUP_2 a:GROUP_3] send-community-ebgp [n:GROUP_2 a:GROUP_2] send-extended-community-ebgp [n:GROUP_2 a:GROUP_2] soft-reconfiguration inbound [n:GROUP_2 a:GROUP_2 a:GROUP_3] weight 100 [n:GROUP_2]
The following is sample output from the show bgp neighbor-group command with the inheritance keyword. This output shows that the specified neighbor group GROUP_1 inherits session (address family-independent) configuration parameters from neighbor group GROUP_2. Neighbor group GROUP_2 inherits its session parameters from session group GROUP_3. It also shows that the GROUP_1 neighbor group inherits IPv4 unicast configuration parameters from the GROUP_2 neighbor group, which in turn inherits them from the GROUP_2 address family group, which itself inherits them from the GROUP_3 address family group:
RP/0/0/CPU0:router# show bgp neighbor-group GROUP_1 inheritance Session: n:GROUP-2 s:GROUP_3 IPv4 Unicast: n:GROUP_2 a:GROUP_2 a:GROUP_3
The following is sample output from the show bgp neighbor-group command with the users keyword. This output shows that the GROUP_1 neighbor group inherits session (address family-independent) configuration parameters from the GROUP_2 neighbor group. The GROUP_1 neighbor group also inherits IPv4 unicast configuration parameters from the GROUP_2 neighbor group:
RP/0/0/CPU0:router# show bgp neighbor-group GROUP_2 users Session: n:GROUP_1 IPv4 Unicast: n:GROUP_1
No Default Address Family
BGP does not support the concept of a default address family. An address family must be explicitly configured under the BGP router configuration for the address family to be activated in BGP. Similarly, an address family must be explicitly configured under a neighbor for the BGP session to be activated under that address family. It is not required to have any address family configured under the BGP router configuration level for a neighbor to be configured. However, it is a requirement to have an address family configured at the BGP router configuration level for the address family to be configured under a neighbor.
Routing Policy Enforcement
External BGP (eBGP) neighbors must have an inbound and outbound policy configured. If no policy is configured, no routes are accepted from the neighbor, nor are any routes advertised to it. This added security measure ensures that routes cannot accidentally be accepted or advertised in the case of a configuration omission error.
Note
This enforcement affects only eBGP neighbors (neighbors in a different autonomous system than this router). For internal BGP (iBGP) neighbors (neighbors in the same autonomous system), all routes are accepted or advertised if there is no policy.
In the following example, for an eBGP neighbor, if all routes should be accepted and advertised with no modifications, a simple pass-all policy is configured:
RP/0/0/CPU0:router(config)# route-policy pass-all RP/0/0/CPU0:router(config-rpl)# pass RP/0/0/CPU0:router(config-rpl)# end-policy RP/0/0/CPU0:router(config)# commitUse the route-policy (BGP) command in the neighbor address-family configuration mode to apply the pass-all policy to a neighbor. The following example shows how to allow all IPv4 unicast routes to be received from neighbor 192.168.40.42 and advertise all IPv4 unicast routes back to it:
RP/0/0/CPU0:router(config)# router bgp 1 RP/0/0/CPU0:router(config-bgp)# neighbor 192.168.40.24 RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 21 RP/0/0/CPU0:router(config-bgp-nbr)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-nbr-af)# route-policy pass-all in RP/0/0/CPU0:router(config-bgp-nbr-af)# route-policy pass-all out RP/0/0/CPU0:router(config-bgp-nbr-af)# commitUse the show bgp summary command to display eBGP neighbors that do not have both an inbound and outbound policy for every active address family. In the following example, such eBGP neighbors are indicated in the output with an exclamation (!) mark:
RP/0/0/CPU0:router# show bgp all all summary Address Family: IPv4 Unicast ============================ BGP router identifier 10.0.0.1, local AS number 1 BGP generic scan interval 60 secs BGP main routing table version 41 BGP scan interval 60 secs BGP is operating in STANDALONE mode. Process RecvTblVer bRIB/RIB SendTblVer Speaker 41 41 41 Neighbor Spk AS MsgRcvd MsgSent TblVer InQ OutQ Up/Down St/PfxRcd 10.0.101.1 0 1 919 925 41 0 0 15:15:08 10 10.0.101.2 0 2 0 0 0 0 0 00:00:00 Idle Address Family: IPv4 Multicast ============================== BGP router identifier 10.0.0.1, local AS number 1 BGP generic scan interval 60 secs BGP main routing table version 1 BGP scan interval 60 secs BGP is operating in STANDALONE mode. Process RecvTblVer bRIB/RIB SendTblVer Speaker 1 1 1 Some configured eBGP neighbors do not have both inbound and outbound policies configured for IPv4 Multicast address family. These neighbors will default to sending and/or receiving no routes and are marked with ’!’ in the output below. Use the ’show bgp neighbor <nbr_address>’ command for details. Neighbor Spk AS MsgRcvd MsgSent TblVer InQ OutQ Up/Down St/PfxRcd 10.0.101.2 0 2 0 0 0 0 0 00:00:00 Idle! Address Family: IPv6 Unicast ============================ BGP router identifier 10.0.0.1, local AS number 1 BGP generic scan interval 60 secs BGP main routing table version 2 BGP scan interval 60 secs BGP is operating in STANDALONE mode. Process RecvTblVer bRIB/RIB SendTblVer Speaker 2 2 2 Neighbor Spk AS MsgRcvd MsgSent TblVer InQ OutQ Up/Down St/PfxRcd 2222::2 0 2 920 918 2 0 0 15:15:11 1 2222::4 0 3 0 0 0 0 0 00:00:00 Idle Address Family: IPv6 Multicast ============================== BGP router identifier 10.0.0.1, local AS number 1 BGP generic scan interval 60 secs BGP main routing table version 1 BGP scan interval 60 secs BGP is operating in STANDALONE mode. Process RecvTblVer bRIB/RIB SendTblVer Speaker 1 1 1 Some configured eBGP neighbors do not have both inbound and outbound policies configured for IPv6 Multicast address family. These neighbors will default to sending and/or receiving no routes and are marked with ’!’ in the output below. Use the ’show bgp neighbor <nbr_address>’ command for details. Neighbor Spk AS MsgRcvd MsgSent TblVer InQ OutQ Up/Down St/PfxRcd 2222::2 0 2 920 918 0 0 0 15:15:11 0 2222::4 0 3 0 0 0 0 0 00:00:00 Idle!
Table Policy
The table policy feature in BGP allows you to configure traffic index values on routes as they are installed in the global routing table. This feature is enabled using the table-policy command and supports the BGP policy accounting feature.
BGP policy accounting uses traffic indices that are set on BGP routes to track various counters. See the Implementing Routing Policy on Cisco IOS XR Software module in the Cisco IOS XR Routing Configuration Guide for the Cisco XR 12000 Series Router for details on table policy use. See the Cisco Express Forwarding Commands on Cisco IOS XR Software module in the Cisco IOS XR IP Addresses and Services Command Reference for the Cisco XR 12000 Series Router for details on BGP policy accounting.
Table policy also provides the ability to drop routes from the RIB based on match criteria. This feature can be useful in certain applications and should be used with caution as it can easily create a routing ‘black hole’ where BGP advertises routes to neighbors that BGP does not install in its global routing table and forwarding table.
Update Groups
The BGP Update Groups feature contains an algorithm that dynamically calculates and optimizes update groups of neighbors that share outbound policies and can share the update messages. The BGP Update Groups feature separates update group replication from peer group configuration, improving convergence time and flexibility of neighbor configuration.
To use this feature, you must understand the following concepts:
BGP Update Generation and Update Groups
The BGP Update Groups feature separates BGP update generation from neighbor configuration. The BGP Update Groups feature introduces an algorithm that dynamically calculates BGP update group membership based on outbound routing policies. This feature does not require any configuration by the network operator. Update group-based message generation occurs automatically and independently.
BGP Update Group
When a change to the configuration occurs, the router automatically recalculates update group memberships and applies the changes.
For the best optimization of BGP update group generation, we recommend that the network operator keeps outbound routing policy the same for neighbors that have similar outbound policies. This feature contains commands for monitoring BGP update groups. For more information about the commands, see Monitoring BGP Update Groups.
BGP Cost Community
The BGP cost community is a nontransitive extended community attribute that is passed to internal BGP (iBGP) and confederation peers but not to external BGP (eBGP) peers. The cost community feature allows you to customize the local route preference and influence the best-path selection process by assigning cost values to specific routes. The extended community format defines generic points of insertion (POI) that influence the best-path decision at different points in the best-path algorithm.
The cost community attribute is applied to internal routes by configuring the set extcommunity cost command in a route policy. See the Routing Policy Language Commands on Cisco IOS XR Software module of Cisco IOS XR Routing Command Reference for information on the set extcommunity cost command. The cost community set clause is configured with a cost community ID number (0–255) and cost community number (0–4294967295). The cost community number determines the preference for the path. The path with the lowest cost community number is preferred. Paths that are not specifically configured with the cost community number are assigned a default cost community number of 2147483647 (the midpoint between 0 and 4294967295) and evaluated by the best-path selection process accordingly. When two paths have been configured with the same cost community number, the path selection process prefers the path with the lowest cost community ID. The cost-extended community attribute is propagated to iBGP peers when extended community exchange is enabled.
The following commands include the route-policy keyword, which you can use to apply a route policy that is configured with the cost community set clause:
- How BGP Cost Community Influences the Best Path Selection Process
- Cost Community Support for Aggregate Routes and Multipaths
- Influencing Route Preference in a Multiexit IGP Network
- BGP Cost Community Support for EIGRP MPLS VPN PE-CE with Back-door Links
- Adding Routes to the Routing Information Base
How BGP Cost Community Influences the Best Path Selection Process
The cost community attribute influences the BGP best-path selection process at the point of insertion (POI). By default, the POI follows the Interior Gateway Protocol (IGP) metric comparison. When BGP receives multiple paths to the same destination, it uses the best-path selection process to determine which path is the best path. BGP automatically makes the decision and installs the best path in the routing table. The POI allows you to assign a preference to a specific path when multiple equal cost paths are available. If the POI is not valid for local best-path selection, the cost community attribute is silently ignored.
Cost communities are sorted first by POI then by community ID. Multiple paths can be configured with the cost community attribute for the same POI. The path with the lowest cost community ID is considered first. In other words, all cost community paths for a specific POI are considered, starting with the one with the lowest cost community. Paths that do not contain the cost community cost (for the POI and community ID being evaluated) are assigned the default community cost value (2147483647). If the cost community values are equal, then cost community comparison proceeds to the next lowest community ID for this POI.
To select the path with the lower cost community, simultaneously walk through the cost communities of both paths. This is done by maintaining two pointers to the cost community chain, one for each path, and advancing both pointers to the next applicable cost community at each step of the walk for the given POI, in order of community ID, and stop when a best path is chosen or the comparison is a tie. At each step of the walk, the following checks are done:
If neither pointer refers to a cost community, Declare a tie; Elseif a cost community is found for one path but not for the other, Choose the path with cost community as best path; Elseif the Community ID from one path is less than the other, Choose the path with the lesser Community ID as best path; Elseif the Cost from one path is less than the other, Choose the path with the lesser Cost as best path; Else Continue.
Note
Paths that are not configured with the cost community attribute are considered by the best-path selection process to have the default cost value (half of the maximum value [4294967295] or 2147483647).
Applying the cost community attribute at the POI allows you to assign a value to a path originated or learned by a peer in any part of the local autonomous system or confederation. The cost community can be used as a “tie breaker” during the best-path selection process. Multiple instances of the cost community can be configured for separate equal cost paths within the same autonomous system or confederation. For example, a lower cost community value can be applied to a specific exit path in a network with multiple equal cost exit points, and the specific exit path is preferred by the BGP best-path selection process. See the scenario described inInfluencing Route Preference in a Multiexit IGP Network.
Note
The cost community comparison in BGP is enabled by default. Use the bgp bestpath cost-community ignore command to disable the comparison.
SeeBGP Best Path Algorithm for information on the BGP best-path selection process.
Cost Community Support for Aggregate Routes and Multipaths
The BGP cost community feature supports aggregate routes and multipaths. The cost community attribute can be applied to either type of route. The cost community attribute is passed to the aggregate or multipath route from component routes that carry the cost community attribute. Only unique IDs are passed, and only the highest cost of any individual component route is applied to the aggregate for each ID. If multiple component routes contain the same ID, the highest configured cost is applied to the route. For example, the following two component routes are configured with the cost community attribute using an inbound route policy:
- 10.0.0.1
POI=IGP
cost community ID=1
cost number=100
- 192.168.0.1
POI=IGP
cost community ID=1
cost number=200
If these component routes are aggregated or configured as a multipath, the cost value 200 is advertised, because it has the highest cost.
If one or more component routes do not carry the cost community attribute or the component routes are configured with different IDs, then the default value (2147483647) is advertised for the aggregate or multipath route. For example, the following three component routes are configured with the cost community attribute using an inbound route policy. However, the component routes are configured with two different IDs.
- 10.0.0.1
POI=IGP
cost community ID=1
cost number=100
- 172.16.0.1
POI=IGP
cost community ID=2
cost number=100
- 192.168.0.1
POI=IGP
cost community ID=1
cost number=200
The single advertised path includes the aggregate cost communities as follows:
{POI=IGP, ID=1, Cost=2147483647} {POI-IGP, ID=2, Cost=2147483647}
Influencing Route Preference in a Multiexit IGP Network
This figure shows an IGP network with two autonomous system boundary routers (ASBRs) on the edge. Each ASBR has an equal cost path to network 10.8/16.
Both paths are considered to be equal by BGP. If multipath loadsharing is configured, both paths to the routing table are installed and are used to balance the load of traffic. If multipath load balancing is not configured, the BGP selects the path that was learned first as the best path and installs this path to the routing table. This behavior may not be desirable under some conditions. For example, the path is learned from ISP1 PE2 first, but the link between ISP1 PE2 and ASBR1 is a low-speed link.
The configuration of the cost community attribute can be used to influence the BGP best-path selection process by applying a lower-cost community value to the path learned by ASBR2. For example, the following configuration is applied to ASBR2:
RP/0/0/CPU0:router(config)# route-policy ISP2_PE1 RP/0/0/CPU0:router(config-rpl)# set extcommunity cost (1:1)The preceding route policy applies a cost community number of 1 to the 10.8.0.0 route. By default, the path learned from ASBR1 is assigned a cost community number of 2147483647. Because the path learned from ASBR2 has a lower-cost community number, the path is preferred.
BGP Cost Community Support for EIGRP MPLS VPN PE-CE with Back-door Links
Back-door links in an EIGRP MPLS VPN topology is preferred by BGP if the back-door link is learned first. (A back-door link, or route, is a connection that is configured outside of the VPN between a remote and main site; for example, a WAN leased line that connects a remote site to the corporate network.)
The “prebest path” point of insertion (POI) in the BGP cost community feature supports mixed EIGRP VPN network topologies that contain VPN and back-door links. This POI is applied automatically to EIGRP routes that are redistributed into BGP. The “prebest path” POI carries the EIGRP route type and metric. This POI influences the best-path calculation process by influencing BGP to consider the POI before any other comparison step. No configuration is required. This feature is enabled automatically for EIGRP VPN sites when Cisco IOS XR software is installed on a PE, CE, or back-door router.
For information about configuring EIGRP MPLS VPNs, see the Cisco IOS XR MPLS Configuration Guide for the Cisco XR 12000 Series Router.
This figure shows how cost community can be used to support backdoor links in a network.
Figure 2. Network Showing How Cost Community Can be Used to Support Backdoor Links
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The following sequence of events happens in PE1:
PE1 learns IPv4 prefix 10.1.1.0/24 from CE1 through EIGRP running a virtual routing and forwarding (VRF) instance. EIGRP selects and installs the best path in the RIB. It also encodes the cost-extended community and adds the information to the RIB.
The route is redistributed into BGP (assuming that IGP-to-BGP redistribution is configured). BGP also receives the cost-extended community from the route through the redistribution process.
After BGP has determined the best path for the newly redistributed prefix, the path is advertised to PE peers (PE2).
PE2 receives the BGP VPNv4 prefix route_distinguisher:10.1.1.0/24 along with the cost community. It is likely that CE2 advertises the same prefix (because of the back-door link between CE1 and CE2) to PE2 through EIGRP. PE2 BGP would have already learned the CE route through the redistribution process along with the cost community value
PE2 has two paths within BGP: one with cost community cost1 through multipath BGP (PE1) and another with cost community cost2 through the EIGRP neighbor (CE2).
PE2 runs the enhanced BGP best-path calculation.
PE2 installs the best path in the RIB passing the appropriate cost community value.
PE2 RIB has two paths for 10.1.1.0/24: one with cost community cost2 added by EIGRP and another with the cost community cost1 added by BGP. Because both the route paths have cost community, RIB compares the costs first. The BGP path has the lower cost community, so it is selected and downloaded to the RIB.
PE2 RIB redistributes the BGP path into EIGRP with VRF. EIGRP runs a diffusing update algorithm (DUAL) because there are two paths, and selects the BGP-redistributed path.
PE2 EIGRP advertises the path to CE2 making the path the next hop for the prefix to send the traffic over the MPLS network.
Adding Routes to the Routing Information Base
If a nonsourced path becomes the best path after the best-path calculation, BGP adds the route to the Routing Information Base (RIB) and passes the cost communities along with the other IGP extended communities.
When a route with paths is added to the RIB by a protocol, RIB checks the current best paths for the route and the added paths for cost extended communities. If cost-extended communities are found, the RIB compares the set of cost communities. If the comparison does not result in a tie, the appropriate best path is chosen. If the comparison results in a tie, the RIB proceeds with the remaining steps of the best-path algorithm. If a cost community is not present in either the current best paths or added paths, then the RIB continues with the remaining steps of the best-path algorithm. See BGP Best Path Algorithm for information on the BGP best-path algorithm.
BGP Best Path Algorithm
BGP routers typically receive multiple paths to the same destination. The BGP best-path algorithm determines the best path to install in the IP routing table and to use for forwarding traffic. This section describes the Cisco IOS XR software implementation of BGP best-path algorithm, as specified in Section 9.1 of the Internet Engineering Task Force (IETF) Network Working Group draft-ietf-idr-bgp4-24.txt document.
The BGP best-path algorithm implementation is in three parts:
Part 1—Compares two paths to determine which is better.
Part 2—Iterates over all paths and determines which order to compare the paths to select the overall best path.
Part 3—Determines whether the old and new best paths differ enough so that the new best path should be used.
Note
The order of comparison determined by Part 2 is important because the comparison operation is not transitive; that is, if three paths, A, B, and C exist, such that when A and B are compared, A is better, and when B and C are compared, B is better, it is not necessarily the case that when A and C are compared, A is better. This nontransitivity arises because the multi exit discriminator (MED) is compared only among paths from the same neighboring autonomous system (AS) and not among all paths.
Comparing Pairs of Paths
Perform the following steps to compare two paths and determine the better path:
If either path is invalid (for example, a path has the maximum possible MED value or it has an unreachable next hop), then the other path is chosen (provided that the path is valid).
If the paths have unequal pre-bestpath cost communities, the path with the lower pre-bestpath cost community is selected as the best path.
Note
See BGP Cost Community for details on how cost communities are compared.
If the paths have unequal weights, the path with the highest weight is chosen.
Note
The weight is entirely local to the router, and can be set with the weight command or using a routing policy.
If the paths have unequal local preferences, the path with the higher local preference is chosen.
Note
If a local preference attribute was received with the path or was set by a routing policy, then that value is used in this comparison. Otherwise, the default local preference value of 100 is used. The default value can be changed using the bgp default local-preference command.
If one of the paths is a redistributed path, which results from a redistribute or network command, then it is chosen. Otherwise, if one of the paths is a locally generated aggregate, which results from an aggregate-address command, it is chosen.
Note
Step 1 through Step 4 implement the “Path Selection with BGP”of RFC 1268.
If the paths have unequal AS path lengths, the path with the shorter AS path is chosen. This step is skipped if bgp bestpath as-path ignore command is configured.
Note
When calculating the length of the AS path, confederation segments are ignored, and AS sets count as 1.
Note
eiBGP specifies internal and external BGP multipath peers. eiBGP allows simultaneous use of internal and external paths.
If the paths have different origins, the path with the lower origin is selected. Interior Gateway Protocol (IGP) is considered lower than EGP, which is considered lower than INCOMPLETE.
If appropriate, the MED of the paths is compared. If they are unequal, the path with the lower MED is chosen.
A number of configuration options exist that affect whether or not this step is performed. In general, the MED is compared if both paths were received from neighbors in the same AS; otherwise the MED comparison is skipped. However, this behavior is modified by certain configuration options, and there are also some corner cases to consider.
If the bgp bestpath med always command is configured, then the MED comparison is always performed, regardless of neighbor AS in the paths. Otherwise, MED comparison depends on the AS paths of the two paths being compared, as follows:
If a path has no AS path or the AS path starts with an AS_SET, then the path is considered to be internal, and the MED is compared with other internal paths.
If the AS path starts with an AS_SEQUENCE, then the neighbor AS is the first AS number in the sequence, and the MED is compared with other paths that have the same neighbor AS.
If the AS path contains only confederation segments or starts with confederation segments followed by an AS_SET, then the MED is not compared with any other path unless the bgp bestpath med confed command is configured. In that case, the path is considered internal and the MED is compared with other internal paths.
If the AS path starts with confederation segments followed by an AS_SEQUENCE, then the neighbor AS is the first AS number in the AS_SEQUENCE, and the MED is compared with other paths that have the same neighbor AS.
Note
If no MED attribute was received with the path, then the MED is considered to be 0 unless the bgp bestpath med missing-as-worst command is configured. In that case, if no MED attribute was received, the MED is considered to be the highest possible value.
If one path is received from an external peer and the other is received from an internal (or confederation) peer, the path from the external peer is chosen.
If the paths have different IGP metrics to their next hops, the path with the lower IGP metric is chosen.
If the paths have unequal IP cost communities, the path with the lower IP cost community is selected as the best path.
Note
See the BGP Cost Community for details on how cost communities are compared.
If all path parameters in Step 1 through Step 10 are the same, then the router IDs are compared. If the path was received with an originator attribute, then that is used as the router ID to compare; otherwise, the router ID of the neighbor from which the path was received is used. If the paths have different router IDs, the path with the lower router ID is chosen.
Note
Where the originator is used as the router ID, it is possible to have two paths with the same router ID. It is also possible to have two BGP sessions with the same peer router, and therefore receive two paths with the same router ID.
If the paths have different cluster lengths, the path with the shorter cluster length is selected. If a path was not received with a cluster list attribute, it is considered to have a cluster length of 0.
Finally, the path received from the neighbor with the lower IP address is chosen. Locally generated paths (for example, redistributed paths) are considered to have a neighbor IP address of 0.
Order of Comparisons
The second part of the BGP best-path algorithm implementation determines the order in which the paths should be compared. The order of comparison is determined as follows:
The paths are partitioned into groups such that within each group the MED can be compared among all paths. The same rules as in Comparing Pairs of Paths are used to determine whether MED can be compared between any two paths. Normally, this comparison results in one group for each neighbor AS. If the bgp bestpath med always command is configured, then there is just one group containing all the paths.
The best path in each group is determined. Determining the best path is achieved by iterating through all paths in the group and keeping track of the best one seen so far. Each path is compared with the best-so-far, and if it is better, it becomes the new best-so-far and is compared with the next path in the group.
A set of paths is formed containing the best path selected from each group in Step 2. The overall best path is selected from this set of paths, by iterating through them as in Step 2.
Best Path Change Suppression
The third part of the implementation is to determine whether the best-path change can be suppressed or not—whether the new best path should be used, or continue using the existing best path. The existing best path can continue to be used if the new one is identical to the point at which the best-path selection algorithm becomes arbitrary (if the router-id is the same). Continuing to use the existing best path can avoid churn in the network.
Note
This suppression behavior does not comply with the IETF Networking Working Group draft-ietf-idr-bgp4-24.txt document, but is specified in the IETF Networking Working Group draft-ietf-idr-avoid-transition-00.txt document.
The suppression behavior can be turned off by configuring the bgp bestpath compare-routerid command. If this command is configured, the new best path is always preferred to the existing one.
Otherwise, the following steps are used to determine whether the best-path change can be suppressed:
If the existing best path is no longer valid, the change cannot be suppressed.
If either the existing or new best paths were received from internal (or confederation) peers or were locally generated (for example, by redistribution), then the change cannot be suppressed. That is, suppression is possible only if both paths were received from external peers.
If the paths were received from the same peer (the paths would have the same router-id), the change cannot be suppressed. The router ID is calculated using rules in Comparing Pairs of Paths.
If the paths have different weights, local preferences, origins, or IGP metrics to their next hops, then the change cannot be suppressed. Note that all these values are calculated using the rules in Comparing Pairs of Paths.
If the paths have different-length AS paths and the bgp bestpath as-path ignore command is not configured, then the change cannot be suppressed. Again, the AS path length is calculated using the rules in Comparing Pairs of Paths.
If the MED of the paths can be compared and the MEDs are different, then the change cannot be suppressed. The decision as to whether the MEDs can be compared is exactly the same as the rules in Comparing Pairs of Paths, as is the calculation of the MED value.
If all path parameters in Step 1 through Step 6 do not apply, the change can be suppressed.
Administrative Distance
An administrative distance is a rating of the trustworthiness of a routing information source. In general, the higher the value, the lower the trust rating. For information on specifying the administrative distance for BGP, see the BGP Commands module of the Cisco IOS XR Routing Command Reference for the Cisco XR 12000 Series Router
Normally, a route can be learned through more than one protocol. Administrative distance is used to discriminate between routes learned from more than one protocol. The route with the lowest administrative distance is installed in the IP routing table. By default, BGP uses the administrative distances shown in Table 1.
Table 1 BGP Default Administrative Distances Distance
Default Value
Function
External
20
Applied to routes learned from eBGP.
Internal
200
Applied to routes learned from iBGP.
Local
200
Applied to routes originated by the router.
Note
Distance does not influence the BGP path selection algorithm, but it does influence whether BGP-learned routes are installed in the IP routing table.
In most cases, when a route is learned through eBGP, it is installed in the IP routing table because of its distance (20). Sometimes, however, two ASs have an IGP-learned back-door route and an eBGP-learned route. Their policy might be to use the IGP-learned path as the preferred path and to use the eBGP-learned path when the IGP path is down. See Figure 1.
In Figure 1, Routers A and C and Routers B and C are running eBGP. Routers A and B are running an IGP (such as Routing Information Protocol [RIP], Interior Gateway Routing Protocol [IGRP], Enhanced IGRP, or Open Shortest Path First [OSPF]). The default distances for RIP, IGRP, Enhanced IGRP, and OSPF are 120, 100, 90, and 110, respectively. All these distances are higher than the default distance of eBGP, which is 20. Usually, the route with the lowest distance is preferred.
Router A receives updates about 160.10.0.0 from two routing protocols: eBGP and IGP. Because the default distance for eBGP is lower than the default distance of the IGP, Router A chooses the eBGP-learned route from Router C. If you want Router A to learn about 160.10.0.0 from Router B (IGP), establish a BGP back door. See .
In the following example, a network back-door is configured:
RP/0/0/CPU0:router(config)# router bgp 100 RP/0/0/CPU0:router(config-bgp)# address-family ipv4 unicast RP/0/0/CPU0:router(config-bgp-af)# network 160.10.0.0/16 backdoorRouter A treats the eBGP-learned route as local and installs it in the IP routing table with a distance of 200. The network is also learned through Enhanced IGRP (with a distance of 90), so the Enhanced IGRP route is successfully installed in the IP routing table and is used to forward traffic. If the Enhanced IGRP-learned route goes down, the eBGP-learned route is installed in the IP routing table and is used to forward traffic.
Although BGP treats network 160.10.0.0 as a local entry, it does not advertise network 160.10.0.0 as it normally would advertise a local entry.
Multiprotocol BGP
Multiprotocol BGP is an enhanced BGP that carries routing information for multiple network layer protocols and IP multicast routes. BGP carries two sets of routes, one set for unicast routing and one set for multicast routing. The routes associated with multicast routing are used by the Protocol Independent Multicast (PIM) feature to build data distribution trees.
Multiprotocol BGP is useful when you want a link dedicated to multicast traffic, perhaps to limit which resources are used for which traffic. Multiprotocol BGP allows you to have a unicast routing topology different from a multicast routing topology providing more control over your network and resources.
In BGP, the only way to perform interdomain multicast routing was to use the BGP infrastructure that was in place for unicast routing. Perhaps you want all multicast traffic exchanged at one network access point (NAP). If those routers were not multicast capable, or there were differing policies for which you wanted multicast traffic to flow, multicast routing could not be supported without multiprotocol BGP.
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 clouds with a BGP cloud. That is, you cannot redistribute multiprotocol BGP routes into BGP.
Figure 1 illustrates simple unicast and multicast topologies that are incongruent, and therefore are not possible without multiprotocol BGP.
Autonomous systems 100, 200, and 300 are each connected to two NAPs that are FDDI rings. One is used for unicast peering (and therefore the exchange of unicast traffic). The Multicast Friendly Interconnect (MFI) ring is used for multicast peering (and therefore the exchange of multicast traffic). Each router is unicast and multicast capable.
Figure 2 is a topology of unicast-only routers and multicast-only routers. The two routers on the left are unicast-only routers (that is, they do not support or are not configured to perform multicast routing). The two routers on the right are multicast-only routers. Routers A and B support both unicast and multicast routing. The unicast-only and multicast-only routers are connected to a single NAP.
In Figure 2, only unicast traffic can travel from Router A to the unicast routers to Router B and back. Multicast traffic could not flow on that path, so another routing table is required. Multicast traffic uses the path from Router A to the multicast routers to Router B and back.
Figure 2 illustrates a multiprotocol BGP environment with a separate unicast route and multicast route from Router A to Router B. Multiprotocol BGP allows these routes to be incongruent. Both of the autonomous systems must be configured for internal multiprotocol BGP (IMBGP) in the figure.
A multicast routing protocol, such as PIM, uses the multicast BGP database to perform Reverse Path Forwarding (RPF) lookups for multicast-capable sources. Thus, packets can be sent and accepted on the multicast topology but not on the unicast topology.
Route Dampening
Route dampening is a BGP feature that minimizes the propagation of flapping routes across an internetwork. A route is considered to be flapping when it is repeatedly available, then unavailable, then available, then unavailable, and so on.
For example, consider a network with three BGP autonomous systems: autonomous system 1, autonomous system 2, and autonomous system 3. Suppose the route to network A in autonomous system 1 flaps (it becomes unavailable). Under circumstances without route dampening, the eBGP neighbor of autonomous system 1 to autonomous system 2 sends a withdraw message to autonomous system 2. The border router in autonomous system 2, in turn, propagates the withdrawal message to autonomous system 3. When the route to network A reappears, autonomous system 1 sends an advertisement message to autonomous system 2, which sends it to autonomous system 3. If the route to network A repeatedly becomes unavailable, then available, many withdrawal and advertisement messages are sent. Route flapping is a problem in an internetwork connected to the Internet, because a route flap in the Internet backbone usually involves many routes.
Minimizing Flapping
The route dampening feature minimizes the flapping problem as follows. Suppose again that the route to network A flaps. The router in autonomous system 2 (in which route dampening is enabled) assigns network A a penalty of 1000 and moves it to history state. The router in autonomous system 2 continues to advertise the status of the route to neighbors. The penalties are cumulative. When the route flaps so often that the penalty exceeds a configurable suppression limit, the router stops advertising the route to network A, regardless of how many times it flaps. Thus, the route is dampened.
The penalty placed on network A is decayed until the reuse limit is reached, upon which the route is once again advertised. At half of the reuse limit, the dampening information for the route to network A is removed.
Note
No penalty is applied to a BGP peer reset when route dampening is enabled, even though the reset withdraws the route.
BGP Routing Domain Confederation
One way to reduce the iBGP mesh is to divide an autonomous system into multiple subautonomous systems and group them into a single confederation. To the outside world, the confederation looks like a single autonomous system. Each autonomous system is fully meshed within itself and has a few connections to other autonomous systems in the same confederation. Although the peers in different autonomous systems have eBGP sessions, they exchange routing information as if they were iBGP peers. Specifically, the next hop, MED, and local preference information is preserved. This feature allows you to retain a single IGP for all of the autonomous systems.
BGP Route Reflectors
BGP requires that all iBGP speakers be fully meshed. However, this requirement does not scale well when there are many iBGP speakers. Instead of configuring a confederation, you can reduce the iBGP mesh by using a route reflector configuration.
Figure 1 illustrates a simple iBGP configuration with three iBGP speakers (routers A, B, and C). Without route reflectors, when Router A receives a route from an external neighbor, it must advertise it to both routers B and C. Routers B and C do not readvertise the iBGP learned route to other iBGP speakers because the routers do not pass on routes learned from internal neighbors to other internal neighbors, thus preventing a routing information loop.
With route reflectors, all iBGP speakers need not be fully meshed because there is a method to pass learned routes to neighbors. In this model, an iBGP peer is configured to be a route reflector responsible for passing iBGP learned routes to a set of iBGP neighbors. In Figure 2 , Router B is configured as a route reflector. When the route reflector receives routes advertised from Router A, it advertises them to Router C, and vice versa. This scheme eliminates the need for the iBGP session between routers A and C.
The internal peers of the route reflector are divided into two groups: client peers and all other routers in the autonomous system (nonclient peers). A route reflector reflects routes between these two groups. The route reflector and its client peers form a cluster. The nonclient peers must be fully meshed with each other, but the client peers need not be fully meshed. The clients in the cluster do not communicate with iBGP speakers outside their cluster.
Figure 3 illustrates a more complex route reflector scheme. Router A is the route reflector in a cluster with routers B, C, and D. Routers E, F, and G are fully meshed, nonclient routers.
When the route reflector receives an advertised route, depending on the neighbor, it takes the following actions:
A route from an external BGP speaker is advertised to all clients and nonclient peers.
A route from a nonclient peer is advertised to all clients.
A route from a client is advertised to all clients and nonclient peers. Hence, the clients need not be fully meshed.
Along with route reflector-aware BGP speakers, it is possible to have BGP speakers that do not understand the concept of route reflectors. They can be members of either client or nonclient groups, allowing an easy and gradual migration from the old BGP model to the route reflector model. Initially, you could create a single cluster with a route reflector and a few clients. All other iBGP speakers could be nonclient peers to the route reflector and then more clusters could be created gradually.
An autonomous system can have multiple route reflectors. A route reflector treats other route reflectors just like other iBGP speakers. A route reflector can be configured to have other route reflectors in a client group or nonclient group. In a simple configuration, the backbone could be divided into many clusters. Each route reflector would be configured with other route reflectors as nonclient peers (thus, all route reflectors are fully meshed). The clients are configured to maintain iBGP sessions with only the route reflector in their cluster.
Usually, a cluster of clients has a single route reflector. In that case, the cluster is identified by the router ID of the route reflector. To increase redundancy and avoid a single point of failure, a cluster might have more than one route reflector. In this case, all route reflectors in the cluster must be configured with the cluster ID so that a route reflector can recognize updates from route reflectors in the same cluster. All route reflectors serving a cluster should be fully meshed and all of them should have identical sets of client and nonclient peers.
By default, the clients of a route reflector are not required to be fully meshed and the routes from a client are reflected to other clients. However, if the clients are fully meshed, the route reflector need not reflect routes to clients.
As the iBGP learned routes are reflected, routing information may loop. The route reflector model has the following mechanisms to avoid routing loops:
Originator ID is an optional, nontransitive BGP attribute. It is a 4-byte attributed created by a route reflector. The attribute carries the router ID of the originator of the route in the local autonomous system. Therefore, if a misconfiguration causes routing information to come back to the originator, the information is ignored.
Cluster-list is an optional, nontransitive BGP attribute. It is a sequence of cluster IDs that the route has passed. When a route reflector reflects a route from its clients to nonclient peers, and vice versa, it appends the local cluster ID to the cluster-list. If the cluster-list is empty, a new cluster-list is created. Using this attribute, a route reflector can identify if routing information is looped back to the same cluster due to misconfiguration. If the local cluster ID is found in the cluster-list, the advertisement is ignored.
Default Address Family for show Commands
Most of the show commands provide address family (AFI) and subaddress family (SAFI) arguments (see RFC 1700 and RFC 2858 for information on AFI and SAFI). The Cisco IOS XR software parser provides the ability to set the afi and safi so that it is not necessary to specify them while running a show command. The parser commands are:
set default-afi { ipv4 | ipv6 | all }
set default-safi { unicast | multicast | all }
The parser automatically sets the default afi value to ipv4 and default safi value to unicast . It is necessary to use only the parser commands to change the default afi value from ipv4 or default safi value from unicast . Any afi or safi keyword specified in a show command overrides the values set using the parser commands. Use the following show default-afi-safi-vrf command to check the currently set value of the afi and safi.
Distributed BGP
Distributed BGP splits BGP functionality into three process types:
BGP process manager—Responsible for verifying configuration changes and for calculating and publishing the distribution of neighbors among BGP speaker processes.
There is a single instance of this process.
bRIB process—Responsible for performing the best-path calculation of routes (receives partial best paths from the speaker). The best route is installed into the bRIB and is advertised back to all speakers. See the BGP Best Path Algorithm for information on best-path calculation. The bRIB process is also responsible for installing routes in the RIB, and for handling routes redistributed from the RIB. To accommodate route leaking from one RIB to another, bRIB may register for redistribution from multiple RIB routes into a single route in the bRIB process.
There is a single instance of this process for each address family.
BGP speaker process—Responsible for handling all BGP connections to peers. The speaker stores received paths in the RIB and performs a partial best-path calculation, advertising the partial best paths to the bRIB (limited best-path calculation). Speakers perform a limited best-path calculation because to compare Multi Exit Discriminators (MEDs), paths need to be compared from the same AS but may not be received on the same speaker. Because BGP speakers do not have access to the entire BGP local RIB, BGP speakers can perform only a limited best-path calculation. (These are Step 1 through Step 7 in the BGP Best Path Algorithm.) Only the best paths are advertised to the bRIB to reduce speaker/bRIB interprocess communications (IPC) and to reduce the number of paths to be processed in the bRIB. BGP speakers can only mark a path as active only after learning the result of the full best-path calculation from the bRIB. Neighbor import and export policies are imposed by the speaker.
If the bgp bestpath med always command is enabled, complete best-path calculation happens inside speaker process. When the bgp bestpath med always command is not enabled, speakers calculate partial best paths only (performs the best-path steps up to the MED comparison) and send them to bRIB. bRIB calculates the final best path (performs all the steps in the best-path calculation). When the bgp bestpath med always command is enabled, speakers can compare the MED across all ASs, allowing the speaker to calculate a single best path to send it to bRIB. bRIB is the ultimate process that calculates the final best path, but when the bgp bestpath med always command is enabled, the speakers send a single best path instead of potentially sending multiple partial best paths.
There are multiple instances of this process in which each instance is responsible for a subset of BGP peer connections.
Up to a total 15 speakers for all address families and one bRIB for each address family (IPv4, IPv6, and VPNv4) are supported.
Distributed BGP is used to reduce the impact that a fault in one address family has on another address family. For example, you can have one speaker with only IPv6 neighbors (peering to IPv6 addresses) and a separate speaker with only IPv4 neighbors (peering to IPv4 addresses), and yet another speaker with only VPNv4 provider edge (PE) or customer edge (CE) neighbors (peering to IPv4 addresses distinct from the non-VPN neighbors). In this scenario, there is no overlap in processes (bgp, brib, and rib) between IPv4, IPv6, and VPNv4. Therefore, a bgp, brib, or rib process crash affects only one address family. Distributed BGP also allows more CPU capacity for receiving, computing, and sending BGP routing updates. When in distributed BGP mode, you can control the number of distributed speakers that are enabled, as well as which neighbors are assigned to each speaker. If no distributed speakers are enabled, BGP operates in standalone mode. If at least one distributed speaker is enabled, BGP operates in distributed mode.
MPLS VPN Carrier Supporting Carrier
Carrier supporting carrier (CSC) is a term used to describe a situation in which one service provider allows another service provider to use a segment of its backbone network. The service provider that provides the segment of the backbone network to the other provider is called the backbone carrier. The service provider that uses the segment of the backbone network is called the customer carrier.
A backbone carrier offers Border Gateway Protocol and Multiprotocol Label Switching (BGP/MPLS) VPN services. The customer carrier can be either:
An Internet service provider (ISP) (By definition, an ISP does not provide VPN service.)
A BGP/MPLS VPN service provider
You can configure a CSC network to enable BGP to transport routes and MPLS labels between the backbone carrier provider edge (PE) routers and the customer carrier customer edge (CE) routers using multiple paths. The benefits of using BGP to distribute IPv4 routes and MPLS label routes are:
BGP takes the place of an Interior Gateway Protocol (IGP) and Label Distribution Protocol (LDP) in a VPN routing and forwarding (VRF) table. You can use BGP to distribute routes and MPLS labels. Using a single protocol instead of two simplifies the configuration and troubleshooting.
BGP is the preferred routing protocol for connecting two ISPs, mainly because of its routing policies and ability to scale. ISPs commonly use BGP between two providers. This feature enables those ISPs to use BGP.
For detailed information on configuring MPLS VPN CSC with BGP, see the Implementing MPLS Layer 3 VPNs on Cisco IOS XR Software module of the Cisco IOS XR MPLS Configuration Guide for the Cisco XR 12000 Series Router.
BGP Keychains
BGP keychains enable keychain authentication between two BGP peers. The BGP endpoints must both comply with draft-bonica-tcp-auth-05.txt and a keychain on one endpoint and a password on the other endpoint does not work.
See the Cisco IOS XR System Security Configuration Guide for the Cisco XR 12000 Series Router for information on keychain management.
BGP is able to use the keychain to implement hitless key rollover for authentication. Key rollover specification is time based, and in the event of clock skew between the peers, the rollover process is impacted. The configurable tolerance specification allows for the accept window to be extended (before and after) by that margin. This accept window facilitates a hitless key rollover for applications (for example, routing and management protocols).
The key rollover does not impact the BGP session, unless there is a keychain configuration mismatch at the endpoints resulting in no common keys for the session traffic (send or accept).
IPv6/IPv6 VPN Provider Edge Transport over MPLS
IPv6 Provider Edge (6PE) and IPv6 VPN Provider Edge (6VPE) leverages the existing Multiprotocol Label Switching (MPLS) IPv4 core infrastructure for IPv6 transport. 6PE and 6VPE enables IPv6 sites to communicate with each other over an MPLS IPv4 core network using MPLS label switched paths (LSPs). This feature relies on multiprotocol Border Gateway Protocol (BGP) extensions in the IPv4 network configuration on the provider edge (PE) router, to exchange IPv6 reachability information in addition to an MPLS label for each IPv6 address prefix to be advertised. Edge routers are configured to be dual stack running both IPv4 and IPv6, and use the IPv4-mapped IPv6 address for IPv6 prefix reachability exchange.
For detailed information on configuring 6PE and 6VPE over MPLS, see Cisco IOS XR MPLS Configuration Guide for the Cisco XR 12000 Series Router .
IPv6 Provider Edge Multipath
Internal and external BGP multipath for IPv6 allows the IPv6 router to load balance between several paths (for example, same neighboring autonomous system [AS] or sub-AS, or the same metric) to reach its destination. The 6PE multipath feature uses multiprotocol internal BGP (MP-iBGP) to distribute IPv6 routes over the MPLS IPv4 core network and to attach an MPLS label to each route.
When MP-iBGP multipath is enabled on the 6PE router, all labeled paths are installed in the forwarding table with MPLS information (label stack) when MPLS information is available. This functionality enables 6PE to perform load balancing.
VPNv4/VPNv6 over the IP Core Using L2TPv3 Tunnels
The Layer 2 Tunnel Protocol version 3 (L2TPv3) feature defines the L2TP protocol for tunneling Layer 2 traffic over an IP core network using Layer 2 VPNs. Benefits of this feature include:
Simplifies deployment of VPNs
Does not require Multiprotocol Label Switching (MPLS)
Supports Layer 2 tunneling over IP for any traffic
Supports data encapsulation directly over IP (IP protocol number 115), not using User Datagram Protocol (UDP)
Supports point-to-point sessions, not point-to-multipoint or multipoint-to-point sessions
Supports sessions between the same Layer 2 protocols, for example Frame Relay to Frame Relay or ATM to ATM
When an RFC 4364-based IP VPN service is deployed (see RFC 4364), VPN traffic is typically transported across the core network between service provider edge (PE) routers using MPLS label switched paths (LSPs). Native IP L3VPNs eliminate the need for MPLS between the participating core routers by relying on scalable tunnel encapsulation over IP. These tunnels can be used instead of, or with, MPLS to transport VPN traffic between participating edge routers.
A native IP L3VPN allows service providers to use an IP backbone to provide VPN services. BGP is used to distribute VPN routing information across the provider backbone.
BGP Multicast VPN
The BGP Multicast VPN feature uses the IPv4 multicast distribution tree (MDT) subaddress family identifier (SAFI) in Border Gateway Protocol (BGP).
Multicast VPN (MVPN) extends the VPN architecture to provide multicast services over a shared service provider backbone using native multicast technology. This is achieved using virtual connections between provider edge (PE) routers in each VPN and using native multicast forwarding inside the provider network. An MDT may span across multiple customer sites and the provider network, allowing traffic to flow freely from one source to multiple receivers.
MVPN is supported on VPN networks based on MPLS and on networks based on IP Layer 2 Tunnel Protocol version 3 (L2TPv3).
PE routers are the only routers that must be MVPN-aware and that must be able to signal to remote PEs information regarding the MVPN. Therefore, all PE routers must have a BGP relationship with each other—either directly or using a route reflector (RR).
Generally the source address of the default MDT is the same address used to source the internal BGP (iBGP) sessions with the remote PE routers that belong to the same VPN and multicast VPN routing and forwarding (MVRF) instance. When Protocol Independent Multicast–Source Specific Multicast (PIM–SSM) is used for transport inside the provider core, it is through the BGP relationship that the PEs indicate that they are MVPN-capable and provide for source discovery. This capability is indicated using the updated BGP message.
Note
The source address can also be configured uniquely per VRF instance under multicast-routing configuration. See Cisco IOS XR Multicast Configuration Guide for the Cisco XR 12000 Series Router.
When a PE receives a BGP update, which includes the rendezvous point (RP) and the group information, it joins the root of that tree, thereby joining the MDT.
Figure 1 shows Multiprotocol iBGP updates for MVPN. On PE1, PE2 is configured as its iBGP peer. This BGP peer configuration within a VRF triggers the MP-iBGP updates that send PE1 local VPN routes to PE2. BGP process on PE2 receives the VPN updates and installs VPN routes in the Routing Information Base (RIB) VRF table. When PIM looks up a VRF source or rendezvous point address that is reachable through the provider core, it receives an MP-iBGP route from the RIB.
When an MVPN-specific default MDT group is configured on PE1, PIM creates a virtual MDT tunnel interface with the tunnel source address the same as the BGP local peering address. This MDT interface is used by PIM to send VPN packets to the provider network and to receive VPN packets from the provider network. PIM also exchanges control messages over this MDT interface.
Each time a default MDT group is configured for a specific VRF, BGP builds an MDT SAFI update, with network layer reachability information (NLRI) containing the local PE BGP peering address and the newly configured MDT group address (The NLRI format is 8-byte-RD:IPv4-address followed by the MDT group address). This update is sent to all the BGP peers including PE2. The BGP process on PE2 receives this MDT update and notifies PIM. If the group is a PIM–SSM group, PIM on PE2 begins sending SSM joins to the BGP peering address on PE1 to establish an SSM tree in the core. This SSM tree is used to carry PIM control traffic and multicast data traffic in the corresponding VRF.
In summary, PIM requires the following from BGP:
A new BGP MDT SAFI, which carries the VRF RD and BGP local peering address and default MDT group in its NLRI.
A notification mechanism from BGP to PIM about the availability of the MDT SAFI update.
A notification mechanism from PIM to BGP about the default MDT group address and source address.
See Internet Engineering Task Force (IETF) draft-nalawade-idr-mdt-safi-03 for detailed information on MDT SAFI.
BGP Nonstop Routing
The Border Gateway Protocol (BGP) Nonstop Routing (NSR) with Stateful Switchover (SSO) feature enables all bgp peerings to maintain the BGP state and ensure continuous packet forwarding during events that could interrupt service. Under NSR, events that might potentially interrupt service are not visible to peer routers. Protocol sessions are not interrupted and routing states are maintained across process restarts and switchovers.
BGP NSR provides nonstop routing during the following events:
Route processor switchover
Process restart of BGP or TCP
In-Service System Upgrade (ISSU)
Minimum Disruption Restart (MDR)
During route processor switchover and In-Service System Upgrade (ISSU), NSR is achieved by stateful switchover (SSO) of both TCP and BGP.
NSR does not force any software upgrades on other routers in the network, and peer routers are not required to support NSR.
When a route processor switchover occurs due to a fault, the TCP connections and the BGP sessions are migrated transparently to the standby route processor, and the standby route processor becomes active. The existing protocol state is maintained on the standby route processor when it becomes active, and the protocol state does not need to be refreshed by peers.
Events such as soft reconfiguration and policy modifications can trigger the BGP internal state to change. To ensure state consistency between active and standby BGP processes during such events, the concept of post-it is introduced that act as synchronization points.
BGP NSR provides the following features:
NSR-related alarms and notifications
Configured and operational NSR states are tracked separately
NSR statistics collection
NSR statistics display using show commands
XML schemas support
Auditing mechanisms to verify state synchronization between active and standby instances
CLI commands to enable and disable NSR
NSR can be provisioned on a multishelf router, especially if distributed BGP is configured. The following guidelines should be observed when provisioning NSR on a multishelf router:
When provisioning NSR for line cards installed on a single rack, provision the active and standby applications on the distributed route processor (DRP) of that rack. If a rack failure occurs, sessions are dropped, because all line cards go down.
- When provisioning NSR for line cards installed on different racks, use one of the following three options:
Provision the active and standby applications on a distributed route processor (DRP) redundant pair, where there is a separate route processor in each rack. This configuration uses up two revenue-producing line-card slots on each rack, but is the most secure configuration.
Provision the active and standby application instances using distributed BGP so that the routing sessions on one rack are serviced by a speaker on that rack. The speaker’s standby instance is on a distributed route processor (DRP) on the same rack. If a rack failure occurs, it affects only the sessions on that rack and does not result in NSR loss.
Provision the active and standby applications on a distributed route processor (DRP) pair that spans two racks. In this configuration, the active/standby role of the line cards is not dependent on the active/standby role of the DRPs. This is called flexible process redundancy and provides for rack loss and efficient use of LC slots. Use of distributed BGP is not required with this solution.
Note
Sessions on line cards in a lost rack are not protected with any of the above options, because there is no line-card redundancy. These options ensure only that sessions on other racks are not affected by a lost rack. However, lost sessions from a lost rack may cause some traffic loss on other racks, because destinations learned through those lost sessions may no longer have alternate routes. Also, rack loss may cause the CPUs on route processors of active racks to slow as they attempt to define new paths for some routes.
BGP Best-External Path
The Border Gateway Protocol (BGP) best–external path functionality supports advertisement of the best–external path to the iBGP and Route Reflector peers when a locally selected bestpath is from an internal peer.
BGP selects one best path and one backup path to every destination. By default, selects one best path . Additionally, BGP selects another bestpath from among the remaining external paths for a prefix. Only a single path is chosen as the best–external path and is sent to other PEs as the backup path.
BGP calculates the best–external path only when the best path is an iBGP path. If the best path is an eBGP path, then best–external path calculation is not required.
The procedure to determine the best–external path is as follows:
Determine the best path from the entire set of paths available for a prefix.
Eliminate the current best path.
Eliminate all the internal paths for the prefix.
From the remaining paths, eliminate all the paths that have the same next hop as that of the current best path.
Rerun the best path algorithm on the remaining set of paths to determine the best–external path.
BGP considers the external and confederations BGP paths for a prefix to calculate the best–external path.
BGP advertises the best path and the best–external path as follows:
On the primary PE—advertises the best path for a prefix to both its internal and external peers
On the backup PE—advertises the best path selected for a prefix to the external peers and advertises the best–external path selected for that prefix to the internal peers
The advertise best-external command enables the advertisement of the best–external path in global address family and VRF address family configuration modes.
BGP Prefix Independent Convergence Unipath Primary/Backup
The Border Gateway Protocol Prefix Independent Convergence Unipath (BGP PIC Unipath) primary/backup feature provides the capability to install a backup path into the forwarding table. Installing the backup path provides prefix independent convergence in the event of a primary PE–CE link failure.
The primary/backup path provides a mechanism for BGP to determine a backup best path. The backup best path acts as a backup to the overall best path, which is the primary best path. BGP programs both the paths into the Forwarding Information Base (FIB).
The procedure to determine the backup best path is as follows:
Determine the best path from the entire set of paths available for a prefix.
Eliminate the current best path.
Eliminate all the paths that have the same next hop as that of the current best path.
Rerun the best path algorithm on the remaining set of paths to determine the backup best path.
The PE-CE local convergence is in the order of four to five seconds for 10000 prefixes. Installing a backup path on the linecards, so that the Forwarding Information Base (FIB) can immediately switch to an alternate path, in the event of a primary PE-CE link failure reduces the convergence time.
In the case of primary PE-CE link failure, the FIB starts forwarding the received traffic towards the backup PE. FIB will continue forwarding the received traffic towards the backup PE for the duration of the network convergence. Since the approach of using a backup path is independent to the prefixes, Prefix Independent Convergence Unipath functionality provides a prefix independent sub second convergence.
The additional-paths install backup command installs the backup path in the Forwarding Information Base (FIB) to enable primary backup path.
BGP Local Label Retention
When a primary PE-CE link fails, BGP withdraws the route corresponding to the primary path along with its local label and programs the backup path in the Routing Information Base (RIB) and the Forwarding Information Base (FIB), by default.
However, until all the internal peers of the primary PE reconverge to use the backup path as the new bestpath, the traffic continues to be forwarded to the primary PE with the local label that was allocated for the primary path. Hence the previously allocated local label for the primary path must be retained on the primary PE for some configurable time after the reconvergence. BGP Local Label Retention feature enables the retention of the local label for a specified period. If no time is specified, the local lable is retained for a default value of five minutes.
The retain local-label command enables the retention of the local label until the network is converged.
Command Line Interface (CLI) Consistency for BGP Commands
From Cisco IOS XR Release 3.9.0 onwards, the Border Gateway Protocol (BGP) commands use disable keyword to disable a feature. The keyword inheritance-disable disables the inheritance of the feature properties from the parent level.
BGP Add Path
The Border Gateway Protocol (BGP) Add Path feature modifies the BGP protocol machinery for a BGP speaker to be able to send multiple paths for a prefix. This gives 'path diversity' in the network. The add path enables BGP prefix independent convergence (PIC)at the edge routers.
BGP add path enables add path advertisement in an iBGP network and advertises the following types of paths for a prefix:
iBGP Multipath Load Sharing
When a Border Gateway Protocol (BGP) speaking router that has no local policy configured, receives multiple network layer reachability information (NLRI) from the internal BGP (iBGP) for the same destination, the router will choose one iBGP path as the best path. The best path is then installed in the IP routing table of the router.
The iBGP Multipath Load Sharing feature enables the BGP speaking router to select multiple iBGP paths as the best paths to a destination. The best paths or multipaths are then installed in the IP routing table of the router.
When there are multiple border BGP routers having reachability information heard over eBGP, if no local policy is applied, the border routers will choose their eBGP paths as best. They advertise that bestpath inside the ISP network. For a core router, there can be multiple paths to the same destination, but it will select only one path as best and use that path for forwarding. iBGP multipath load sharing adds the ability to enable load sharing among multiple equi-distant paths.
Configuring multiple iBGP best paths enables a router to evenly share the traffic destined for a particular site.
The iBGP Multipath Load Sharing feature functions similarly in a Multiprotocol Label Switching (MPLS) Virtual Private Network (VPN) with a service provider backbone.
For multiple paths to the same destination to be considered as multipaths, the following criteria must be met:
All attributes must be the same. The attributes include weight, local preference, autonomous system path (entire attribute and not just length), origin code, Multi Exit Discriminator (MED), and Interior Gateway Protocol (iGP) distance.
The next hop router for each multipath must be different.
Even if the criteria are met and multiple paths are considered multipaths, the BGP speaking router will still designate one of the multipaths as the best path and advertise this best path to its neighbors.
Selective VRF Download
Selective VRF Download (SVD) feature is a solution to download only those prefixes and labels to a line card that are actively required to forward traffic through that line card.
To meet the demand for a consolidated edge MSE platform, the number of VRFs, VRF interfaces, and prefix capacity increases. Convergence timings are different in different line card engines. One of the major factors that determine convergence timing is the time taken to process and program a prefix and its associated data structures. Hence, less number of prefixes and labels ensures better convergence timing. SVD reduces scalability and convergence problems in L3VPNs by enabling selective download of VRF routes to both Engine-3 (E3) and Engine-5 (E5) Linecards on Cisco XR 12000.
SVD is enabled by default on the line cards. Use selective-vrf-download disable command to disable SVD. Use show svd role and show svd state commands to display the role and state information of SVD on the line cards.
How to Implement BGP on Cisco IOS XR Software
Enabling BGP Routing
Perform this task to enable BGP routing and establish a BGP routing process. Configuring BGP neighbors is included as part of enabling BGP routing.
Note
At least one neighbor and at least one address family must be configured to enable BGP routing. At least one neighbor with both a remote AS and an address family must be configured globally using the address family and remote as commands.
Before You BeginSUMMARY STEPSBGP must be able to obtain a router identifier (for example, a configured loopback address). At least, one address family must be configured in the BGP router configuration and the same address family must also be configured under the neighbor.
Note
If the neighbor is configured as an external BGP (eBGP) peer, you must configure an inbound and outbound route policy on the neighbor using the route-policy command.
2. route-policy route-policy-name
8. address-family { ipv4 | ipv6 } unicast
12. address-family { ipv4 | ipv6 } unicast
13. route-policy route-policy-name { in | out }
DETAILED STEPSConfiguring a Routing Domain Confederation for BGP
SUMMARY STEPSPerform this task to configure the routing domain confederation for BGP. This includes specifying a confederation identifier and autonomous systems that belong to the confederation.
Configuring a routing domain confederation reduces the internal BGP (iBGP) mesh by dividing an autonomous system into multiple autonomous systems and grouping them into a single confederation. Each autonomous system is fully meshed within itself and has a few connections to another autonomous system in the same confederation. The confederation maintains the next hop and local preference information, and that allows you to retain a single Interior Gateway Protocol (IGP) for all autonomous systems. To the outside world, the confederation looks like a single autonomous system.
3. bgp confederation identifier as-number
4. bgp confederation peers as-number
DETAILED STEPSResetting an eBGP Session Immediately Upon Link Failure
By default, if a link goes down, all BGP sessions of any directly adjacent external peers are immediately reset. Use the bgp fast-external-fallover disable command to disable automatic resetting. Turn the automatic reset back on using the no bgp fast-external-fallover disable command.
eBGP sessions flap when the node reaches 3500 eBGP sessions with BGP timer values set as 10 and 30. To support more than 3500 eBGP sessions, increase the packet rate by using the lpts pifib hardware police location location-id command. Following is a sample configuration to increase the eBGP sessions:RP/0/0/CPU0:router#configure RP/0/0/CPU0:router(config)#lpts pifib hardware police location 0/2/CPU0 RP/0/0/CPU0:router(config-pifib-policer-per-node)#flow bgp configured rate 4000 RP/0/0/CPU0:router(config-pifib-policer-per-node)#flow bgp known rate 4000 RP/0/0/CPU0:router(config-pifib-policer-per-node)#flow bgp default rate 4000 RP/0/0/CPU0:router(config-pifib-policer-per-node)#commitLogging Neighbor Changes
Logging neighbor changes is enabled by default. Use the log neighbor changes disable command to turn off logging. The no log neighbor changes disable command can also be used to turn logging back on if it has been disabled.
Adjusting BGP Timers
SUMMARY STEPSPerform this task to set the timers for BGP neighbors.
BGP uses certain timers to control periodic activities, such as the sending of keepalive messages and the interval after which a neighbor is assumed to be down if no messages are received from the neighbor during the interval. The values set using the timers bgp command in router configuration mode can be overridden on particular neighbors using the timers command in the neighbor configuration mode.
3. timers bgp keepalive hold-time
DETAILED STEPSChanging the BGP Default Local Preference Value
SUMMARY STEPS3. bgp default local-preference value
DETAILED STEPSConfiguring the MED Metric for BGP
SUMMARY STEPSPerform this task to set the multi exit discriminator (MED) to advertise to peers for routes that do not already have a metric set (routes that were received with no MED attribute).
DETAILED STEPSConfiguring BGP Weights
Perform this task to assign a weight to routes received from a neighbor. A weight is a number that you can assign to a path so that you can control the best-path selection process. If you have particular neighbors that you want to prefer for most of your traffic, you can use the weight command to assign a higher weight to all routes learned from that neighbor.
Before You BeginSUMMARY STEPS
Note
The clear bgp command must be used for the newly configured weight to take effect.
5. address-family { ipv4 | ipv6 } unicast
DETAILED STEPSTuning the BGP Best-Path Calculation
SUMMARY STEPS3. bgp bestpath med missing-as-worst
6. bgp bestpath as-path ignore
7. bgp bestpath compare-routerid
DETAILED STEPSIndicating BGP Back-door Routes
SUMMARY STEPSPerform this task to set the administrative distance on an external Border Gateway Protocol (eBGP) route to that of a locally sourced BGP route, causing it to be less preferred than an Interior Gateway Protocol (IGP) route.
3. address-family { ipv4 | ipv6 } unicast
4. network { ip-address / prefix-length | ip-address mask } backdoor
DETAILED STEPSConfiguring Aggregate Addresses
SUMMARY STEPS3. address-family { ipv4 | ipv6 } unicast
4. aggregate-address address/mask-length [ as-set ] [ as-confed-set ] [ summary-only ] [ route-policy route-policy-name ]
DETAILED STEPSRedistributing iBGP Routes into IGP
SUMMARY STEPSPerform this task to redistribute iBGP routes into an Interior Gateway Protocol (IGP), such as Intermediate System-to-Intermediate System (IS-IS) or Open Shortest Path First (OSPF).
Note
Use of the bgp redistribute-internal command requires the clear route * command to be issued to reinstall all BGP routes into the IP routing table.
Caution
Redistributing iBGP routes into IGPs may cause routing loops to form within an autonomous system. Use this command with caution.
DETAILED STEPSRedistributing Prefixes into Multiprotocol BGP
SUMMARY STEPSPerform this task to redistribute prefixes from another protocol into multiprotocol BGP.
Redistribution is the process of injecting prefixes from one routing protocol into another routing protocol. This task shows how to inject prefixes from another routing protocol into multiprotocol BGP. Specifically, prefixes that are redistributed into multiprotocol BGP using the redistribute command are injected into the unicast database, the multicast database, or both.
3. address-family { ipv4 | ipv6 } unicast
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]]} [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]]} [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
DETAILED STEPSConfiguring BGP Route Dampening
SUMMARY STEPS3. address-family { ipv4 | ipv6 } unicast
4. bgp dampening [ half-life [ reuse suppress max-suppress-time ] | route-policy route-policy-name ]
6. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | tunnel } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast [ rd rd-address ] | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpnv6 unicast [ rd rd-address ]] flap-statistics
7. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast [ rd rd-address ] | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpnv6 unicast [ rd rd-address ]] flap-statistics regexp regular-expression
8. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled -unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast [ rd rd-address ] | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpnv6 unicast [ rd rd-address ]] flap-statistics route-policy route-policy-name
9. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled -unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast [ rd rd-address ] | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpnv6 unicast [ rd rd-address ]] flap-statistics { ip-address { mask | /prefix-length }}
10. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast [ rd rd-address ] | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast ] | ipv6 unicast ] | vpnv6 unicast [ rd rd-address ]] flap-statistics { ip-address [{ mask | /prefix-length } [ longer-prefixes ]]}
11. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } flap-statistics
12. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } flap-statistics regexp regular-expression
13. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } flap-statistics route-policy route-policy-name
14. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } flap-statistics network / mask-length
15. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } flap-statistics ip-address / mask-length
16. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled -unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast [ rd rd-address ] | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpnv6 unicast [ rd rd-address ]] dampened-paths
17. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } dampening [ ip-address / mask-length ]
DETAILED STEPSApplying Policy When Updating the Routing Table
Before You BeginSUMMARY STEPSSee the Implementing Routing Policy on Cisco IOS XR Software module of Cisco IOS XR Routing Configuration Guide for the Cisco XR 12000 Series Router (this publication) for a list of the supported attributes and operations that are valid for table policy filtering.
3. address-family { ipv4 | ipv6 } unicast
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120.6
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either the IPv4 or IPv6 address family and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 4 table-policy policy-name
Example:RP/0/0/CPU0:router(config-bgp-af)# table-policy tbl-plcy-A
Applies the specified policy to routes being installed into the routing table.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-af)# end
or
RP/0/0/CPU0:router(config-bgp-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Setting BGP Administrative Distance
SUMMARY STEPSPerform this task to specify the use of administrative distances that can be used to prefer one class of route over another.
3. address-family { ipv4 | ipv6 } unicast
4. distance bgp external-distance internal-distance local-distance
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 4 distance bgp external-distance internal-distance local-distance
Example:RP/0/0/CPU0:router(config-bgp-af)# distance bgp 20 20 200
Sets the external, internal, and local administrative distances to prefer one class of routes over another. The higher the value, the lower the trust rating.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-af)# end
or
RP/0/0/CPU0:router(config-bgp-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring a BGP Neighbor Group and Neighbors
SUMMARY STEPSPerform this task to configure BGP neighbor groups and apply the neighbor group configuration to a neighbor. A neighbor group is a template that holds address family-independent and address family-dependent configurations associated with the neighbor.
After a neighbor group is configured, each neighbor can inherit the configuration through the use command. If a neighbor is configured to use a neighbor group, the neighbor (by default) inherits the entire configuration of the neighbor group, which includes the address family-independent and address family-dependent configurations. The inherited configuration can be overridden if you directly configure commands for the neighbor or configure session groups or address family groups through the use command.
You can configure an address family-independent configuration under the neighbor group. An address family-dependent configuration requires you to configure the address family under the neighbor group to enter address family submode.
From neighbor group configuration mode, you can configure address family-independent parameters for the neighbor group. Use the address-family command when in the neighbor group configuration mode.
After specifying the neighbor group name using the neighbor group command, you can assign options to the neighbor group.
Note
All commands that can be configured under a specified neighbor group can be configured under a neighbor.
3. address-family { ipv4 | ipv6 } unicast
7. address-family { ipv4 | ipv6 } unicast
8. route-policy route-policy-name { in | out }
12. use neighbor-group group-name
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 4 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 5 neighbor-group name
Example:RP/0/0/CPU0:router(config-bgp)# neighbor-group nbr-grp-A
Places the router in neighbor group configuration mode.
Step 6 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp)# remote-as 2002
Creates a neighbor and assigns a remote autonomous system number to it.
Step 7 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 8 route-policy route-policy-name { in | out }
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# route-policy drop-as-1234 in
(Optional) Applies the specified policy to inbound IPv4 unicast routes.
Step 9 exit
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# exit
Exits the current configuration mode.
Step 10 exit
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit
Exits the current configuration mode.
Step 11 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 12 use neighbor-group group-name
Example:RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group nbr-grp-A
(Optional) Specifies that the BGP neighbor inherit configuration from the specified neighbor group.
Step 13 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2002
Creates a neighbor and assigns a remote autonomous system number to it.
Step 14 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr)# end
or
RP/0/0/CPU0:router(config-bgp-nbr)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring a Route Reflector for BGP
SUMMARY STEPSPerform this task to configure a route reflector for BGP.
All the neighbors configured with the route-reflector-clientcommand are members of the client group, and the remaining iBGP peers are members of the nonclient group for the local route reflector.
Together, a route reflector and its clients form a cluster. A cluster of clients usually has a single route reflector. In such instances, the cluster is identified by the software as the router ID of the route reflector. To increase redundancy and avoid a single point of failure in the network, a cluster can have more than one route reflector. If it does, all route reflectors in the cluster must be configured with the same 4-byte cluster ID so that a route reflector can recognize updates from route reflectors in the same cluster. The bgp cluster-id command is used to configure the cluster ID when the cluster has more than one route reflector.
6. address-family { ipv4 | ipv6 } unicast
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 bgp cluster-id cluster-id
Example:RP/0/0/CPU0:router(config-bgp)# bgp cluster-id 192.168.70.1
Configures the local router as one of the route reflectors serving the cluster. It is configured with a specified cluster ID to identify the cluster.
Step 4 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 5 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2003
Creates a neighbor and assigns a remote autonomous system number to it.
Step 6 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 7 route-reflector-client
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# route-reflector-client
Configures the router as a BGP route reflector and configures the neighbor as its client.
Step 8 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring BGP Route Filtering by Route Policy
Before You BeginSUMMARY STEPSSee the Implementing Routing Policy on Cisco IOS XR Softwaremodule of Cisco Cisco IOS XR Routing Configuration Guide (this publication) for a list of the supported attributes and operations that are valid for inbound and outbound neighbor policy filtering.
6. address-family { ipv4 | ipv6 } unicast
7. route-policy route-policy-name { in | out }
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 route-policy name
Example:RP/0/0/CPU0:router(config)# route-policy drop-as-1234 RP/0/0/CPU0:router(config-rpl)# if as-path passes-through '1234' then RP/0/0/CPU0:router(config-rpl)# apply check-communities RP/0/0/CPU0:router(config-rpl)# else RP/0/0/CPU0:router(config-rpl)# pass RP/0/0/CPU0:router(config-rpl)# endif(Optional) Creates a route policy and enters route policy configuration mode, where you can define the route policy.
Step 3 end-policy
Example:RP/0/0/CPU0:router(config-rpl)# end-policy
(Optional) Ends the definition of a route policy and exits route policy configuration mode.
Step 4 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 5 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 6 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 7 route-policy route-policy-name { in | out }
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# route-policy drop-as-1234 in
Applies the specified policy to inbound routes.
Step 8 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring BGP Next-Hop Trigger Delay
SUMMARY STEPSPerform this task to configure BGP next-hop trigger delay. The Routing Information Base (RIB) classifies the dampening notifications based on the severity of the changes. Event notifications are classified as critical and noncritical. This task allows you to specify the minimum batching interval for the critical and noncritical events.
3. address-family { ipv4 | ipv6 } unicast
4. nexthop trigger-delay { critical delay | non-critical delay }
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 4 nexthop trigger-delay { critical delay | non-critical delay }
Example:RP/0/0/CPU0:router(config-bgp-af)# nexthop trigger-delay critical 15000
Sets the critical next-hop trigger delay.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-af)# end
or
RP/0/0/CPU0:router(config-bgp-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Disabling Next-Hop Processing on BGP Updates
SUMMARY STEPSPerform this task to disable next-hop calculation for a neighbor and insert your own address in the next-hop field of BGP updates. Disabling the calculation of the best next hop to use when advertising a route causes all routes to be advertised with the network device as the next hop.
Note
Next-hop processing can be disabled for address family group, neighbor group, or neighbor address family.
5. address-family { ipv4 | ipv6 } unicast
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 4 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 206
Creates a neighbor and assigns a remote autonomous system number to it.
Step 5 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 6 next-hop-self
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# next-hop-self
Sets the next-hop attribute for all routes advertised to the specified neighbor to the address of the local router. Disabling the calculation of the best next hop to use when advertising a route causes all routes to be advertised with the local network device as the next hop.
Step 7 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring BGP Community and Extended-Community Advertisements
SUMMARY STEPSPerform this task to specify that community attributes should be sent to an eBGP neighbor.
Perform this task to specify that community/extended-community attributes should be sent to an eBGP neighbor. These attributes are not sent to an eBGP neighbor by default. By contrast, they are always sent to iBGP neighbors. This section provides examples on how to enable sending community attributes. The send-community-ebgp keyword can be replaced by the send-extended-community-ebgp keyword to enable sending extended-communities.
Note
If the send-community-ebgp command is configured for a neighbor group or address family group, all neighbors using the group inherit the configuration. Configuring the command specifically for a neighbor overrides inherited values.
Note
BGP community and extended-community filtering cannot be configured for iBGP neighbors. Communities and extended-communities are always sent to iBGP neighbors
5. address-family { ipv4 | ipv6} unicast
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 4 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2002
Creates a neighbor and assigns a remote autonomous system number to it.
Step 5 address-family { ipv4 | ipv6} unicast
Example:RP/0/0/CPU0:router(config-bgp-nbr)# address-family ipv4 unicast
Enters neighbor address family configuration mode for the specified address family.
Step 6 send-community-ebgp
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# send-community-ebgp
Specifies that the router send community attributes (which are disabled by default for eBGP neighbors) to a specified eBGP neighbor.
Step 7 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring the BGP Cost Community
SUMMARY STEPSPerform this task to configure the BGP cost community.
BGP receives multiple paths to the same destination and it uses the best-path algorithm to decide which is the best path to install in RIB. To enable users to determine an exit point after partial comparison, the cost community is defined to tie-break equal paths during the best-path selection process.
3. set extcommunity cost { cost-extcommunity-set-name | cost-inline-extcommunity-set } [ additive ]
- default-information originate
- aggregate-address address/mask-length [ as-set ] [ as-confed-set ] [ summary-only ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } network { ip-address/prefix-length | ip-address mask } [ route-policy route-policy-name ]
- neighbor ip-address remote-as as-number address-family { ipv4 unicast | ipv4 multicast | ipv4 labeled-unicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | ipv6 labeled-unicast | vpnv4 unicast | vpnv6 unicast }
- route-policy route-policy-name { in | out }
9. show bgp [ vrf vrf-name ] ip-address
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 route-policy name
Example:RP/0/0/CPU0:router(config)# route-policy costA
Enters route policy configuration mode and specifies the name of the route policy to be configured.
Step 3 set extcommunity cost { cost-extcommunity-set-name | cost-inline-extcommunity-set } [ additive ]
Example:RP/0/0/CPU0:router(config)# set extcommunity cost cost_A
Specifies the BGP extended community attribute for cost.
Step 4 end-policy
Example:RP/0/0/CPU0:router(config)# end-policy
Ends the definition of a route policy and exits route policy configuration mode.
Step 5 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Enters BGP configuration mode allowing you to configure the BGP routing process.
Step 6 Do one of the following:
- default-information originate
- aggregate-address address/mask-length [ as-set ] [ as-confed-set ] [ summary-only ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
Applies the cost community to the attach point (route policy).
Step 7 Do one of the following:
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
- address-family { ipv4 unicast | ipv4 multicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | vpnv4 unicast | vpnv6 unicast } network { ip-address/prefix-length | ip-address mask } [ route-policy route-policy-name ]
- neighbor ip-address remote-as as-number address-family { ipv4 unicast | ipv4 multicast | ipv4 labeled-unicast | ipv4 tunnel | ipv4 mdt | ipv6 unicast | ipv6 multicast | ipv6 labeled-unicast | vpnv4 unicast | vpnv6 unicast }
- route-policy route-policy-name { in | out }
Step 8 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-af)# end
or
RP/0/0/CPU0:router(config-bgp-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Step 9 show bgp [ vrf vrf-name ] ip-address
Example:RP/0/0/CPU0:router# show bgp 172.168.40.24
Displays the cost community in the following format:
Cost: POI : cost-community-ID : cost-number
Configuring Software to Store Updates from a Neighbor
SUMMARY STEPSPerform this task to configure the software to store updates received from a neighbor.
The soft-reconfiguration inbound command causes a route refresh request to be sent to the neighbor if the neighbor is route refresh capable. If the neighbor is not route refresh capable, the neighbor must be reset to relearn received routes using the clear bgp soft command. See the Resetting Neighbors Using BGP Inbound Soft Reset.
Note
Storing updates from a neighbor works only if either the neighbor is route refresh capable or the soft-reconfiguration inbound command is configured. Even if the neighbor is route refresh capable and the soft-reconfiguration inbound command is configured, the original routes are not stored unless the always option is used with the command. The original routes can be easily retrieved with a route refresh request. Route refresh sends a request to the peer to resend its routing information. The soft-reconfiguration inbound command stores all paths received from the peer in an unmodified form and refers to these stored paths during the clear. Soft reconfiguration is memory intensive.
4. address-family { ipv4 | ipv6 } unicast
5. soft-reconfiguration inbound [ always]
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 4 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 5 soft-reconfiguration inbound [ always]
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# soft-reconfiguration inbound always
Configures the software to store updates received from a specified neighbor. Soft reconfiguration inbound causes the software to store the original unmodified route in addition to a route that is modified or filtered. This allows a “soft clear” to be performed after the inbound policy is changed.
Soft reconfiguration enables the software to store the incoming updates before apply policy if route refresh is not supported by the peer (otherwise a copy of the update is not stored). The always keyword forces the software to store a copy even when route refresh is supported by the peer.
Step 6 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring Distributed BGP
Perform this task to configure distributed BGP. Configuring distributed BGP includes starting the speaker process and allocating the speaker process to a neighbor.
Before You BeginSUMMARY STEPS
Note
If BGP is running in standalone mode, the clear bgp current-mode or clear bgp vrf all * command must be used to switch from standalone mode to distributed mode.
5. address-family { ipv4 | ipv6 } unicast
10. address-family { ipv4 | ipv6 } unicast
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 distributed speaker id
Example:RP/0/0/CPU0:router(config-bgp)# distributed speaker 2
Specifies the speaker process to start.
Step 4 commit
Example:RP/0/0/CPU0:router(config-bgp)# commit
Saves the configuration changes to the running configuration file and remains within the configuration session.
Step 5 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 6 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits address family mode.
Step 7 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 8 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2002
Creates a neighbor and assigns a remote autonomous system number to it.
Step 9 speaker-id id
Example:RP/0/0/CPU0:router(config-bgp-nbr)# speaker-id 2
Allocates a neighbor to a specified speaker process.
Step 10 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 11 end
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Step 12 clear bgp current-mode
Example:RP/0/0/CPU0:router# clear bgp current-mode
Switches from standalone mode to distributed mode.
Configuring a VPN Routing and Forwarding Instance in BGP
Layer 2 and Layer 3 (virtual private network) VPN can be configured only if there is an available Layer 3 VPN license for the line card slot on which the feature is being configured.
If the advanced IP license is enabled, 4096 Layer 3 VPN routing and forwarding instances (VRFs) can be configured on an interface. If the infrastructure VRF license is enabled, eight Layer 3 VRFs can be configured on the line card. See the Software Entitlement on Cisco IOS XR Software module in Cisco IOS XR System Management Configuration Guide for the Cisco XR 12000 Series Router for more information on advanced IP licencing.
The following error message appears if the appropriate licence is not enabled:RP/0/0/CPU0:router#LC/0/0/CPU0:Dec 15 17:57:53.653 : rsi_agent[247]: %LICENSE-ASR9K_LICENSE-2-INFRA_VRF_NEEDED : 5 VRF(s) are configured without license A9K-iVRF-LIC in violation of the Software Right To Use Agreement. This feature may be disabled by the system without the appropriate license. Contact Cisco to purchase the license immediately to avoid potential service interruption.
The following tasks are used to configure a VPN routing and forwarding (VRF) instance in BGP:
- Defining the Virtual Routing and Forwarding Tables in Provider Edge Routers
- Configuring the Route Distinguisher
- Configuring BGP to Advertise VRF Routes for Multicast VPN from PE to PE
- Advertising VRF Routes for MVPNv4 from PE to PE
- Advertising VRF Routes for MVPNv6 from PE to PE
- Configuring PE-PE or PE-RR Interior BGP Sessions
- Configuring Route Reflector to Hold Routes That Have a Defined Set of RT Communities
- Configuring BGP as a PE-CE Protocol
- Redistribution of IGPs to BGP
Defining the Virtual Routing and Forwarding Tables in Provider Edge Routers
SUMMARY STEPSPerform this task to define the VPN routing and forwarding (VRF) tables in the provider edge (PE) routers.
3. address-family { ipv4 | ipv6 } unicast
4. maximum prefix maximum [ threshold ]
5. import route-policy policy-name
6. import route-target [ as-number : nn | ip-address : nn ]
7. export route-policy policy-name
8. export route-target [ as-number : nn | ip-address : nn ]
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 vrf vrf-name
Example:RP/0/0/CPU0:router(config)# vrf vrf_pe
Configures a VRF instance.
Step 3 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either the IPv4 or IPv6 address family and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 4 maximum prefix maximum [ threshold ]
Example:RP/0/0/CPU0:router(config-vrf-af)# maximum prefix 2300
Configures a limit to the number of prefixes allowed in a VRF table.
A maximum number of routes is applicable only to dynamic routing protocols and not to static or connected routes.
You can specify a threshold percentage of the prefix limit using the mid-threshold argument.
Step 5 import route-policy policy-name
Example:RP/0/0/CPU0:router(config-vrf-af)# import route-policy policy_a
(Optional) Provides finer control over what gets imported into a VRF. This import filter discards prefixes that do not match the specified policy-name argument.
Step 6 import route-target [ as-number : nn | ip-address : nn ]
Example:RP/0/0/CPU0:router(config-vrf-af)# import route-target 234:222
Specifies a list of route target (RT) extended communities. Only prefixes that are associated with the specified import route target extended communities are imported into the VRF.
Step 7 export route-policy policy-name
Example:RP/0/0/CPU0:router(config-vrf-af)# export route-policy policy_b
(Optional) Provides finer control over what gets exported into a VRF. This export filter discards prefixes that do not match the specified policy-name argument.
Step 8 export route-target [ as-number : nn | ip-address : nn ]
Example:RP/0/0/CPU0:routerr(config-vrf-af)# export route-target 123;234
Specifies a list of route target extended communities. Export route target communities are associated with prefixes when they are advertised to remote PEs. The remote PEs import them into VRFs which have import RTs that match these exported route target communities.
Step 9 Do one of the following:
Example:RP/0/0/CPU0:router(config-vrf-af)# end
or
RP/0/0/CPU0:router(config-vrf-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring the Route Distinguisher
SUMMARY STEPSThe route distinguisher (RD) makes prefixes unique across multiple VPN routing and forwarding (VRF) instances.
In the L3VPN multipath same route distinguisher (RD)environment, the determination of whether to install a prefix in RIB or not is based on the prefix's bestpath. In a rare misconfiguration situation, where the best pah is not a valid path to be installed in RIB, BGP drops the prefix and does not consider the other paths. The behavior is different for different RD setup, where the non-best multipath will be installed if the best multipath is invalid to be installed in RIB.
Perform this task to configure the RD.
5. rd { as-number : nn | ip-address : nn | auto }
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Enters BGP configuration mode allowing you to configure the BGP routing process.
Step 3 bgp router-id ip-address
Example:RP/0/0/CPU0:router(config-bgp)# bgp router-id 10.0.0.0
Configures a fixed router ID for the BGP-speaking router.
Step 4 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp)# vrf vrf_pe
Configures a VRF instance.
Step 5 rd { as-number : nn | ip-address : nn | auto }
Example:RP/0/0/CPU0:router(config-bgp-vrf)# rd 345:567
Configures the route distinguisher.
Use the auto keyword if you want the router to automatically assign a unique RD to the VRF.
Automatic assignment of RDs is possible only if a router ID is configured using the bgp router-id command in router configuration mode. This allows you to configure a globally unique router ID that can be used for automatic RD generation. The router ID for the VRF does not need to be globally unique, and using the VRF router ID would be incorrect for automatic RD generation. Having a single router ID also helps in checkpointing RD information for BGP graceful restart, because it is expected to be stable across reboots.
Step 6 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-vrf)# end
or
RP/0/0/CPU0:router(config-bgp-vrf)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring BGP to Advertise VRF Routes for Multicast VPN from PE to PE
Perform these tasks to enable multicast VPN routing for IPv4 and IPv6 address families from one provider edge (PE) router to another:
Advertising VRF Routes for MVPNv4 from PE to PE
SUMMARY STEPS4. address-family { ipv4 | ipv6 } unicast
6. address-family vpnv4 unicast
12. update-source type interface-path-id
13. address-family { ipv4 | ipv6 } unicast
15. address-family vpnv4 unicast
18. rd { as-number : nn | ip-address : nn | auto }
19. address-family { ipv4 | ipv6 } unicast
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 100
Enters BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 bgp router-id ip-address
Example:RP/0/0/CPU0:router(config-bgp)# bgp router-id 1.1.1.1
Configures a fixed router ID for a BGP-speaking router.
Step 4 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 5 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits IPv4 address family configuration submode and reenters BGP configuration submode.
Step 6 address-family vpnv4 unicast
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpvnv4 unicast
Enters VPNv4 address family configuration submode.
Step 7 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits IPv4 address-family configuration submode and reenters BGP configuration submode.
Step 8 address-family ipv4 mdt
Example:RP/0/0/CPU0:router(config-bgp)# address-family ipv4 mdt
Configures an IPv4 address-family multicast distribution tree (MDT).
Step 9 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 10 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.16.1.1
Places the PE router in neighbor configuration submode.
Step 11 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 100
Creates a neighbor and assigns the neighbor a remote autonomous system number, which can be from 1 to 65535.
Step 12 update-source type interface-path-id
Example:RP/0/0/CPU0:router(config-bgp-nbr)# update-source loopback 0
Allows sessions to use the primary IP address from a specific interface as the local address when forming a session with a neighbor.
The interface-type interface-id arguments specify the type and ID number of the interface, such as GigabitEthernet or Loopback. Use the CLI help (?) to see a list of all the possible interface types and their ID numbers.
Step 13 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 14 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# exit
Exits the neighbor address family configuration submode.
Step 15 address-family vpnv4 unicast
Example:RP/0/0/CPU0:router(config-bgp-nbr)# address-family vpnv4 unicast
Specifies the address family as VPNv4 and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 16 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# exit
Exits BGP neighbor address family configuration submode.
Step 17 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp-nbr)# vrf vpn1
Enables BGP routing for a particular VRF on the PE router.
Step 18 rd { as-number : nn | ip-address : nn | auto }
Example:RP/0/0/CPU0:router(config-bgp-vrf)# rd 1:1
Configures the route distinguisher.
Use the auto keyword if you want the router to automatically assign a unique RD to the VRF.
Automatic assignment of RDs is possible only if a router ID is configured using the bgp router-id command in router configuration mode. This allows you to configure a globally unique router ID that can be used for automatic RD generation.
The router ID for the VRF does not need to be globally unique, and using the VRF router ID would be incorrect for automatic RD generation. Having a single router ID also helps in checkpointing RD information for BGP graceful restart, because it is expected to be stable across reboots.
Step 19 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 20 Do one of the following:
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# redistribute ospf 1
Configures redistribution of a protocol into the VRF address family context.
Step 21 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# end
or
RP/0/0/CPU0:router(config-bgp-vrf-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Advertising VRF Routes for MVPNv6 from PE to PE
SUMMARY STEPS4. address-family ipv6 unicast
5. address-family vpnv6 unicast
9. update-source interface-type interface-id
10. address-family vpnv6 unicast
15. use neighbor-group vpn-name
16. update-source interface-type interface-id
17. address-family ipv6 unicast
19. address-family vpnv6 unicast
23. rd { as-number : nn | ip-address : nn | auto }
26. rd { as-number : nn | ip-address : nn | auto }
27. address-family ipv6 unicast
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 100
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 bgp router-id ip-address
Example:RP/0/0/CPU0:router(config-bgp)# bgp router-id 1.1.1.1
Configures a fixed router ID for a BGP-speaking router.
Step 4 address-family ipv6 unicast
Example:RP/0/0/CPU0:router(config-bgp)# address-family ipv6 unicast
Specifies the address family as IPv6 and enters IPv6 neighbor address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 5 address-family vpnv6 unicast
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpnv6 unicast
Enters VPNv6 address family configuration submode.
Step 6 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the VPNv6 address family configuration submode.
Step 7 neighbor-group vrf-name
Example:RP/0/0/CPU0:router(config-bgp)# neighbor-group vpn22
Places the router in neighbor group configuration submode.
Step 8 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp)# remote-as 100
Creates a neighbor and assigns the neighbor a remote autonomous system number, which can be from 1 to 65535.
Step 9 update-source interface-type interface-id
Example:RP/0/0/CPU0:router(config-bgp-nbr)# update-source loopback 0
Allows sessions to use the primary IP address from a specific interface as the local address when forming a session with a neighbor.
The interface-type interface-id arguments specify the type and ID number of the interface, such as ATM, POS, Loopback. Use the CLI help (?) to see a list of all the possible interface types and their ID numbers.
Step 10 address-family vpnv6 unicast
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp)# address-family vpnv6 unicast
Specifies the address family as VPNv6 and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 11 exit
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp-af)# exit
Exits the neighbor group address family configuration submode.
Step 12 exit
Example:RP/0/0/CPU0:router(config-bgp-nbrgrp)# exit
Exits BGP neighbor group configuration submode.
Step 13 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 1.1.1.2
Places a PE router in neighbor group configuration submode.
Step 14 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 100
Creates a neighbor and assigns it a remote autonomous system number, which can be from 1 to 65535.
Step 15 use neighbor-group vpn-name
Example:RP/0/0/CPU0:router(config-bgp-nbr)# use neighbor-group vpn22
(Optional) Specifies that the BGP neighbor inherits the configuration from the specified VPN neighbor group.
Step 16 update-source interface-type interface-id
Example:RP/0/0/CPU0:router(config-bgp-nbr)# update-source loopback 0
Allows sessions to use the primary IP address from a specific interface as the local address when forming a session with a neighbor.
The interface-type interface-id arguments specify the type and ID number of the interface, such as ATM, POS, Loopback. Use the CLI help (?) to see a list of all the possible interface types and their ID numbers.
Step 17 address-family ipv6 unicast
Example:RP/0/0/CPU0:router(config-bgp-nbr)# address-family ipv6 unicast
Specifies the address family as IPv6 and enters IPv6 neighbor address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 18 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# exit
Exits BGP neighbor address family configuration submode.
Step 19 address-family vpnv6 unicast
Example:RP/0/0/CPU0:router(config-bgp-nbr)# address-family vpnv6 unicast
Specifies the address family as VPNv6 and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 20 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# exit
Exits the neighbor address family configuration submode.
Step 21 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr)# exit
Exits the BGP neighbor configuration submode.
Step 22 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp)# vrf vpn1
Enters BGP VRF configuration submode.
Step 23 rd { as-number : nn | ip-address : nn | auto }
Example:RP/0/0/CPU0:router(config-bgp-vrf)# rd 111:1
Configures the route distinguisher.
Use the auto keyword if you want the router to automatically assign a unique RD to the VRF.
Automatic assignment of RDs is possible only if a router ID is configured using the bgp router-id command in router configuration mode. This allows you to configure a globally unique router ID that can be used for automatic RD generation.
The router ID for the VRF does not need to be globally unique, and using the VRF router ID would be incorrect for automatic RD generation. Having a single router ID also helps in checkpointing RD information for BGP graceful restart, because it is expected to be stable across reboots.
Step 24 exit
Example:RP/0/0/CPU0:router(config-bgp-vrf)# exit
Exits BGP VRF configuration submode.
Step 25 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp-nbr)# vrf vpn1
Enables BGP routing for a particular VRF on the PE router.
Step 26 rd { as-number : nn | ip-address : nn | auto }
Example:RP/0/0/CPU0:router(config-bgp-vrf)# rd 1:1
Configures the route distinguisher.
Use the auto keyword if you want the router to automatically assign a unique RD to the VRF.
Automatic assignment of RDs is possible only if a router ID is configured using the bgp router-id command in router configuration mode. This allows you to configure a globally unique router ID that can be used for automatic RD generation.
The router ID for the VRF does not need to be globally unique, and using the VRF router ID would be incorrect for automatic RD generation. Having a single router ID also helps in checkpointing RD information for BGP graceful restart, because it is expected to be stable across reboots.
Step 27 address-family ipv6 unicast
Example:RP/0/0/CPU0:router(config-bgp-vrf)# address-family ipv6 unicast
Specifies the address family as IPv6 and enters IPv6 VRF address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 28 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# end
or
RP/0/0/CPU0:router(config-bgp-vrf-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring PE-PE or PE-RR Interior BGP Sessions
SUMMARY STEPSTo enable BGP to carry VPN reachability information between provider edge (PE) routers you must configure the PE-PE interior BGP (iBGP) sessions. A PE uses VPN information carried from the remote PE router to determine VPN connectivity and the label value to be used so the remote (egress) router can demultiplex the packet to the correct VPN during packet forwarding.
The PE-PE, PE-route reflector (RR) iBGP sessions are defined to all PE and RR routers that participate in the VPNs configured in the PE router.
Perform this task to configure PE-PE iBGP sessions and to configure global VPN options on a PE.
3. address-family { vpnv4 unicast | vpnv6 unicast }
8. password { clear | encrypted } password
10. timers keepalive hold-time
11. update-source type interface-id
12. address-family { vpnv4 unicast | vpnv6 unicast }
13. route-policy route-policy-name in
14. route-policy route-policy-name out
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { vpnv4 unicast | vpnv6 unicast }
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpvn4 unicast
Enters VPN address family configuration mode.
Step 4 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 5 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.16.1.1
Configures a PE iBGP neighbor.
Step 6 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 1
Assigns the neighbor a remote autonomous system number.
Step 7 description text
Example:RP/0/0/CPU0:router(config-bgp-nbr)# description neighbor 172.16.1.1
(Optional) Provides a description of the neighbor. The description is used to save comments and does not affect software function.
Step 8 password { clear | encrypted } password
Example:RP/0/0/CPU0:router(config-bgp-nbr)# password encrypted 123abc
Enables Message Digest 5 (MD5) authentication on the TCP connection between the two BGP neighbors.
Step 9 shutdown
Example:RP/0/0/CPU0:router(config-bgp-nbr)# shutdown
Terminates any active sessions for the specified neighbor and removes all associated routing information.
Step 10 timers keepalive hold-time
Example:RP/0/0/CPU0:router(config-bgp-nbr)# timers 12000 200
Set the timers for the BGP neighbor.
Step 11 update-source type interface-id
Example:RP/0/0/CPU0:router(config-bgp-nbr)# update-source gigabitEthernet 0/1/5/0
Allows iBGP sessions to use the primary IP address from a specific interface as the local address when forming an iBGP session with a neighbor.
Step 12 address-family { vpnv4 unicast | vpnv6 unicast }
Example:RP/0/0/CPU0:router(config-bgp-nbr)# address-family vpvn4 unicast
Enters VPN neighbor address family configuration mode.
Step 13 route-policy route-policy-name in
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# route-policy pe-pe-vpn-in in
Specifies a routing policy for an inbound route. The policy can be used to filter routes or modify route attributes.
Step 14 route-policy route-policy-name out
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# route-policy pe-pe-vpn-out out
Specifies a routing policy for an outbound route. The policy can be used to filter routes or modify route attributes.
Step 15 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring Route Reflector to Hold Routes That Have a Defined Set of RT Communities
SUMMARY STEPSA provider edge (PE) needs to hold the routes that match the import route targets (RTs) of the VPNs configured on it. The PE router can discard all other VPNv4 (Cisco XR 12000 Series Router and Cisco CRS-1) and VPNv6 (Cisco XR 12000 Series Router only) routes. But, a route reflector (RR) must retain all VPNv4 and VPNv6 routes, because it might peer with PE routers and different PEs might require different RT-tagged VPNv4 and VPNv6 routes (making RRs non-scalable). You can configure an RR to only hold routes that have a defined set of RT communities. Also, a number of the RRs can be configured to service a different set of VPNs (thereby achieving some scalability). A PE is then made to peer with all RRs that service the VRFs configured on the PE. When a new VRF is configured with an RT for which the PE does not already hold routes, the PE issues route refreshes to the RRs and retrieves the relevant VPN routes.
Note
Note that this process can be more efficient if the PE-RR session supports extended community outbound route filter (ORF).
Perform this task to configure a reflector to retain routes tagged with specific RTs.
3. address-family { vpnv4 unicast | vpnv6 unicast }
4. retain route-target { all | route-policy route-policy-name }
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { vpnv4 unicast | vpnv6 unicast }
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpvn4 unicast
Enters VPN address family configuration mode.
Step 4 retain route-target { all | route-policy route-policy-name }
Example:RP/0/0/CPU0:router(config-bgp-af)# retain route-target route-policy rr_ext-comm
Configures a reflector to retain routes tagged with particular RTs. Use the route-policy-name argument for the policy name that lists the extended communities that a path should have in order for the RR to retain that path.
Note The all keyword is not required, because this is the default behavior of a route reflector.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring BGP as a PE-CE Protocol
SUMMARY STEPS5. label-allocation-mode { per-ce | per-vrf }
6. address-family { ipv4 | ipv6 } unicast
7. network { ip-address / prefix-length | ip-address mask }
8. aggregate-address address / mask-length
12. password { clear | encrypted } password
13. ebgp-multihop [ ttl-value ]
15. site-of-origin [ as-number : nn | ip-address : nn ]
17. allowas-in [ as-occurrence-number ]
18. route-policy route-policy-name in
19. route-policy route-policy-name out
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp)# vrf vrf_pe_2
Enables BGP routing for a particular VRF on the PE router.
Step 4 bgp router-id ip-address
Example:RP/0/0/CPU0:router(config-bgp-vrf)# bgp router-id 172.16.9.9
Configures a fixed router ID for a BGP-speaking router.
Step 5 label-allocation-mode { per-ce | per-vrf }
Example:RP/0/0/CPU0:router(config-bgp-vrf)# label-allocation-mode per-ce
Configures the MPLS/VPN label allocation mode.
The per-ce keyword configures the per-CE label allocation mode to avoid an extra lookup on the PE router and conserve label space (per-prefix is the default label allocation mode). In this mode, the PE router allocates one label for every immediate next-hop (in most cases, this would be a CE router). This label is directly mapped to the next hop, so there is no VRF route lookup performed during data forwarding. However, the number of labels allocated would be one for each CE rather than one for each VRF. Because BGP knows all the next hops, it assigns a label for each next hop (not for each PE-CE interface). When the outgoing interface is a multiaccess interface and the media access control (MAC) address of the neighbor is not known, Address Resolution Protocol (ARP) is triggered during packet forwarding.
The per-vrf keyword configures the same label to be used for all the routes advertised from a unique VRF.
Step 6 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 7 network { ip-address / prefix-length | ip-address mask }
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# network 172.16.5.5
Originates a network prefix in the address family table in the VRF context.
Step 8 aggregate-address address / mask-length
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# aggregate-address 10.0.0.0/24
Configures aggregation in the VRF address family context to summarize routing information to reduce the state maintained in the core. This summarization introduces some inefficiency in the PE edge, because an additional lookup is required to determine the ultimate next hop for a packet. When configured, a summary prefix is advertised instead of a set of component prefixes, which are more specifics of the aggregate. The PE advertises only one label for the aggregate. Because component prefixes could have different next hops to CEs, an additional lookup has to be performed during data forwarding.
Step 9 exit
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# exit
Exits the current configuration mode.
Step 10 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp-vrf)# neighbor 10.0.0.0
Configures a CE neighbor. The ip-address argument must be a private address.
Step 11 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr)# remote-as 2
Configures the remote AS for the CE neighbor.
Step 12 password { clear | encrypted } password
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr)# password encrypted 234xyz
Enable Message Digest 5 (MD5) authentication on a TCP connection between two BGP neighbors.
Step 13 ebgp-multihop [ ttl-value ]
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr)# ebgp-multihop 55
Configures the CE neighbor to accept and attempt BGP connections to external peers residing on networks that are not directly connected.
Step 14 Do one of the following:
- address-family { ipv4 | ipv6 } unicast
- address-family {ipv4 {unicast | labeled-unicast} | ipv6 unicast}
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 (unicast or labeled-unicast) or IPv6 unicast address family and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 15 site-of-origin [ as-number : nn | ip-address : nn ]
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# site-of-origin 234:111
Configures the site-of-origin (SoO) extended community. Routes that are learned from this CE neighbor are tagged with the SoO extended community before being advertised to the rest of the PEs. SoO is frequently used to detect loops when as-override is configured on the PE router. If the prefix is looped back to the same site, the PE detects this and does not send the update to the CE.
Step 16 as-override
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# as-override
Configures AS override on the PE router. This causes the PE router to replace the CE’s ASN with its own (PE) ASN.
Note This loss of information could lead to routing loops; to avoid loops caused by as-override, use it in conjunction with site-of-origin.
Step 17 allowas-in [ as-occurrence-number ]
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# allowas-in 5
Allows an AS path with the PE autonomous system number (ASN) a specified number of times.
Hub and spoke VPN networks need the looping back of routing information to the HUB PE through the HUB CE. When this happens, due to the presence of the PE ASN, the looped-back information is dropped by the HUB PE. To avoid this, use the allowas-in command to allow prefixes even if they have the PEs ASN up to the specified number of times.
Step 18 route-policy route-policy-name in
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# route-policy pe_ce_in_policy in
Specifies a routing policy for an inbound route. The policy can be used to filter routes or modify route attributes.
Step 19 route-policy route-policy-name out
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# route-policy pe_ce_out_policy out
Specifies a routing policy for an outbound route. The policy can be used to filter routes or modify route attributes.
Step 20 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# end
or
RP/0/0/CPU0:router(config-bgp-vrf-nbr-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Redistribution of IGPs to BGP
SUMMARY STEPSPerform this task to configure redistribution of a protocol into the VRF address family.
Even if Interior Gateway Protocols (IGPs) are used as the PE-CE protocol, the import logic happens through BGP. Therefore, all IGP routes have to be imported into the BGP VRF table.
4. address-family { ipv4 | ipv6 } unicast
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp)# vrf vrf_a
Enables BGP routing for a particular VRF on the PE router.
Step 4 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 5 Do one of the following:
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# redistribute eigrp 23
Configures redistribution of a protocol into the VRF address family context.
The redistribute command is used if BGP is not used between the PE-CE routers. If BGP is used between PE-CE routers, the IGP that is used has to be redistributed into BGP to establish VPN connectivity with other PE sites. Redistribution is also required for inter-table import and export.
Step 6 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# end
or
RP/0/0/CPU0:router(config-bgp-vrf-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring Keychains for BGP
SUMMARY STEPSKeychains provide secure authentication by supporting different MAC authentication algorithms and provide graceful key rollover. Perform this task to configure keychains for BGP. This task is optional.
Note
If a keychain is configured for a neighbor group or a session group, a neighbor using the group inherits the keychain. Values of commands configured specifically for a neighbor override inherited values.
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 4 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2002
Creates a neighbor and assigns a remote autonomous system number to it.
Step 5 keychain name
Example:RP/0/0/CPU0:router(config-bgp-nbr)# keychain kych_a
Configures keychain-based authentication.
Step 6 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr)# end
or
RP/0/0/CPU0:router(config-bgp-nbr)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring an MDT Address Family Session in BGP
SUMMARY STEPSPerform this task to configure an IPv4 multicast distribution tree (MDT) subaddress family identifier (SAFI) session in BGP, which can also be used for MVPNv6 network distribution.
3. address-family { ipv4 | ipv6 } unicast
5. address-family { vpnv4 | vpnv6 } unicast
11. update-source interface-type interface-id
12. address-family { ipv4 | ipv6 } unicast
14. address-family {vpnv4 | vpnv6} unicast
19. rd { as-number:nn | ip-address:nn | auto }
20. address-family { ipv4 | ipv6 } unicast
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 4 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 5 address-family { vpnv4 | vpnv6 } unicast
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpnv4 unicast
Specifies the address family and enters the address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Note Required if you are configuring multicast MVPN. If configuring MVPNv6, use the vpnv6 keyword
Step 6 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 7 address-family ipv4 mdt
Example:RP/0/0/CPU0:router(config-bgp)# address-family ipv4 mdt
Specifies the multicast distribution tree (MDT) address family.
Step 8 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 9 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 10 remote-as as-number
Example:RP/0/0/CPU0:router(config-bgp-nbr)# remote-as 2002
Creates a neighbor and assigns a remote autonomous system number to it.
Step 11 update-source interface-type interface-id
Example:RP/0/0/CPU0:router(config-bgp-nbr)# update-source loopback 0
Allows sessions to use the primary IP address from a specific interface as the local address when forming a session with a neighbor.
The interface-type interface-id arguments specify the type and ID number of the interface, such as ATM, POS, Loopback. Use the CLI help (?) to see a list of all the possible interface types and their ID numbers.
Step 12 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 13 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# exit
(Optional) Exits the current configuration mode.
Step 14 address-family {vpnv4 | vpnv6} unicast
Example:RP/0/0/CPU0:router(config-bgp-nbr)# address-family vpnv4 unicast
(Optional) Enters address family configuration submode for the specified address family.
Note Required if you are configuring multicast MVPN. If configuring MVPNv6, use the vpnv6 keyword.
Step 15 exit
Example:RP/0/0/CPU0:router(config-bgp-nbr-af)# exit
Exits the current configuration mode.
Step 16 address-family ipv4 mdt
Example:RP/0/0/CPU0:router(config-bgp)# address-family ipv4 mdt
Specifies the multicast distribution tree (MDT) address family.
Step 17 exit
Example:RP/0/0/CPU0:router(config-bgp-af)# exit
Exits the current configuration mode.
Step 18 vrf vrf-name
Example:RP/0/0/CPU0:router(config-bgp)# vrf vpn1
(Optional) Enables BGP routing for a particular VRF on the PE router.
Note Required if you are configuring multicast MVPN.
Step 19 rd { as-number:nn | ip-address:nn | auto }
Example:RP/0/0/CPU0:router(config-bgp-vrf)# rd 1:1
(Optional) Configures the route distinguisher.
Use the auto keyword if you want the router to automatically assign a unique RD to the VRF.
Automatic assignment of RDs is possible only if a router ID is configured using the bgp router-id command in router configuration mode. This allows you to configure a globally unique router ID that can be used for automatic RD generation.
The router ID for the VRF does not need to be globally unique, and using the VRF router ID would be incorrect for automatic RD generation. Having a single router ID also helps in checkpointing RD information for BGP graceful restart, because it is expected to be stable across reboots.
Note Required if you are configuring multicast MVPN.
Step 20 address-family { ipv4 | ipv6 } unicast
Example:RP/0/0/CPU0:router(config-vrf)# address-family ipv4 unicast
Specifies either an IPv4 or IPv6 address family unicast and enters address family configuration submode.
To see a list of all the possible keywords and arguments for this command, use the CLI help (?).
Step 21 Do one of the following:
- redistribute connected [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute eigrp process-id [ match { external | internal }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute isis process-id [ level { 1 | 1-inter-area | 2 }] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospf process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute ospfv3 process-id [ match { external [ 1 | 2 ] | internal | nssa-external [ 1 | 2 ]}] [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute rip [ metric metric-value ] [ route-policy route-policy-name ]
- redistribute static [ metric metric-value ] [ route-policy route-policy-name ]
Example:RP/0/0/CPU0:router(config-bgp-vrf-af)# redistribute eigrp 23
(Optional) Configures redistribution of a protocol into the VRF address family context.
Note Required if you are configuring multicast MVPN.
Step 22 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-af)# end
or
RP/0/0/CPU0:router(config-bgp-af)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Disabling a BGP Neighbor
SUMMARY STEPSPerform this task to administratively shut down a neighbor session without removing the configuration.
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 127
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 neighbor ip-address
Example:RP/0/0/CPU0:router(config-bgp)# neighbor 172.168.40.24
Places the router in neighbor configuration mode for BGP routing and configures the neighbor IP address as a BGP peer.
Step 4 shutdown
Example:RP/0/0/CPU0:router(config-bgp-nbr)# shutdown
Disables all active sessions for the specified neighbor.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp-nbr)# end
or
RP/0/0/CPU0:router(config-bgp-nbr)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Resetting Neighbors Using BGP Inbound Soft Reset
SUMMARY STEPSPerform this task to trigger an inbound soft reset of the specified address families for the specified group or neighbors. The group is specified by the * , ip-address , as-number , or external keywords and arguments.
Resetting neighbors is useful if you change the inbound policy for the neighbors or any other configuration that affects the sending or receiving of routing updates. If an inbound soft reset is triggered, BGP sends a REFRESH request to the neighbor if the neighbor has advertised the ROUTE_REFRESH capability. To determine whether the neighbor has advertised the ROUTE_REFRESH capability, use the show bgp neighbors command.
2. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | mdt } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } { * | ip-address | as as-number | external } soft [ in [ prefix-filter ] | out ]
DETAILED STEPS
Command or Action Purpose Step 1 show bgp neighbors
Example:RP/0/0/CPU0:router# show bgp neighbors
Verifies that received route refresh capability from the neighbor is enabled.
Step 2 clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | mdt } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } { * | ip-address | as as-number | external } soft [ in [ prefix-filter ] | out ]
Example:RP/0/0/CPU0:router# clear bgp ipv4 unicast 10.0.0.1 soft in
Soft resets a BGP neighbor.
Resetting Neighbors Using BGP Outbound Soft Reset
SUMMARY STEPSPerform this task to trigger an outbound soft reset of the specified address families for the specified group or neighbors. The group is specified by the * , ip-address , as-number , or external keywords and arguments.
Resetting neighbors is useful if you change the outbound policy for the neighbors or any other configuration that affects the sending or receiving of routing updates.
If an outbound soft reset is triggered, BGP resends all routes for the address family to the given neighbors.
To determine whether the neighbor has advertised the ROUTE_REFRESH capability, use the show bgp neighbors command.
2. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } { * | ip-address | as as-number | external } soft out
DETAILED STEPS
Command or Action Purpose Step 1 show bgp neighbors
Example:RP/0/0/CPU0:router# show bgp neighbors
Verifies that received route refresh capability from the neighbor is enabled.
Step 2 clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } { * | ip-address | as as-number | external } soft out
Example:RP/0/0/CPU0:router# clear bgp ipv4 unicast 10.0.0.2 soft out
Soft resets a BGP neighbor.
Resetting Neighbors Using BGP Hard Reset
SUMMARY STEPSPerform this task to reset neighbors using a hard reset. A hard reset removes the TCP connection to the neighbor, removes all routes received from the neighbor from the BGP table, and then re-establishes the session with the neighbor. If the graceful keyword is specified, the routes from the neighbor are not removed from the BGP table immediately, but are marked as stale. After the session is re-established, any stale route that has not been received again from the neighbor is removed.
1. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | mdt } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } { * | ip-address | as as-number | external } [ graceful ] soft [ in [ prefix-filter ] | out ]
DETAILED STEPS
Command or Action Purpose Step 1 clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | mdt } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } { * | ip-address | as as-number | external } [ graceful ] soft [ in [ prefix-filter ] | out ]
Example:RP/0/0/CPU0:router# clear bgp ipv4 unicast 10.0.0.3 graceful soft out
Clears a BGP neighbor.
The * keyword resets all BGP neighbors.
The ip-address argument specifies the address of the neighbor to be reset.
The as-number argument specifies that all neighbors that match the autonomous system number be reset.
The external keyword specifies that all external neighbors are reset.
The graceful keyword specifies a graceful restart.
Clearing Caches, Tables, and Databases
SUMMARY STEPSPerform this task to remove all contents of a particular cache, table, or database. The clear bgp command resets the sessions of the specified group of neighbors (hard reset); it removes the TCP connection to the neighbor, removes all routes received from the neighbor from the BGP table, and then re-establishes the session with the neighbor. Clearing a cache, table, or database can become necessary when the contents of the particular structure have become, or are suspected to be, invalid.
1. clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | mdt } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } ip-address
DETAILED STEPS
Command or Action Purpose Step 1 clear bgp { ipv4 { unicast | multicast | labeled-unicast | all | tunnel | mdt } | ipv6 { unicast | multicast | all | labeled-unicast } | all { unicast | multicast | all | labeled-unicast | mdt | tunnel } | vpnv4 unicast | vrf { vrf-name | all } { ipv4 { unicast | labeled-unicast } | ipv6 unicast } | vpnv6 unicast } ip-address
Example:RP/0/0/CPU0:router# clear bgp ipv4 172.20.1.1
Clears a specified neighbor.
Step 2 clear bgp external
Example:RP/0/0/CPU0:router# clear bgp external
Clears all external peers.
Step 3 clear bgp *
Example:RP/0/0/CPU0:router# clear bgp *
Clears all BGP neighbors.
Displaying System and Network Statistics
SUMMARY STEPSPerform this task to display specific statistics, such as the contents of BGP routing tables, caches, and databases. Information provided can be used to determine resource usage and solve network problems. You can also display information about node reachability and discover the routing path that the packets of your device are taking through the network.
2. show bgp community community-list [ exact-match ]
3. show bgp regexp regular-expression
5. show bgp neighbors ip-address [ advertised-routes | dampened-routes | flap-statistics | performance-statistics | received prefix-filter | routes ]
7. show bgp neighbor-group group-name configuration
DETAILED STEPS
Command or Action Purpose Step 1 show bgp cidr-only
Example:RP/0/0/CPU0:router# show bgp cidr-only
Displays routes with nonnatural network masks (classless interdomain routing [CIDR]) routes.
Step 2 show bgp community community-list [ exact-match ]
Example:RP/0/0/CPU0:router# show bgp community 1081:5 exact-match
Displays routes that match the specified BGP community.
Step 3 show bgp regexp regular-expression
Example:RP/0/0/CPU0:router# show bgp regexp "^3 "
Displays routes that match the specified autonomous system path regular expression.
Step 4 show bgp
Example:RP/0/0/CPU0:router# show bgp
Displays entries in the BGP routing table.
Step 5 show bgp neighbors ip-address [ advertised-routes | dampened-routes | flap-statistics | performance-statistics | received prefix-filter | routes ]
Example:RP/0/0/CPU0:router# show bgp neighbors 10.0.101.1
Displays information about the BGP connection to the specified neighbor.
The advertised-routes keyword displays all routes the router advertised to the neighbor.
The dampened-routes keyword displays the dampened routes that are learned from the neighbor.
The flap-statistics keyword displays flap statistics of the routes learned from the neighbor.
The performance-statistics keyword displays performance statistics relating to work done by the BGP process for this neighbor.
The received prefix-filter keyword and argument display the received prefix list filter.
The routes keyword displays routes learned from the neighbor.
Step 6 show bgp paths
Example:RP/0/0/CPU0:router# show bgp paths
Displays all BGP paths in the database.
Step 7 show bgp neighbor-group group-name configuration
Example:RP/0/0/CPU0:router# show bgp neighbor-group group_1 configuration
Displays the effective configuration for a specified neighbor group, including any configuration inherited by this neighbor group.
Step 8 show bgp summary
Example:RP/0/0/CPU0:router# show bgp summary
Displays the status of all BGP connections.
Displaying BGP Process Information
SUMMARY STEPS2. show bgp ipv4 unicast summary
3. show bgp vpnv4 unicast summary
4. show bgp vrf ( vrf-name | all }
8. show placement program brib
DETAILED STEPS
Command or Action Purpose Step 1 show bgp process
Example:RP/0/0/CPU0:router# show bgp process
Displays status and summary information for the BGP process. The output shows various global and address family-specific BGP configurations. A summary of the number of neighbors, update messages, and notification messages sent and received by the process is also displayed.
Step 2 show bgp ipv4 unicast summary
Example:RP/0/0/CPU0:router# show bgp ipv4 unicast summary
Displays a summary of the neighbors for the IPv4 unicast address family.
Step 3 show bgp vpnv4 unicast summary
Example:RP/0/0/CPU0:router# show bgp vpnv4 unicast summary
Displays a summary of the neighbors for the VPNv4 unicast address family.
Step 4 show bgp vrf ( vrf-name | all }
Example:RP/0/0/CPU0:router# show bgp vrf vrf_A
Displays BGP VPN virtual routing and forwarding (VRF) information.
Step 5 show bgp process detail
Example:RP/0/0/CPU0:router# show bgp processes detail
Displays detailed process information including the memory used by each of various internal structure types.
Step 6 show bgp summary
Example:RP/0/0/CPU0:router# show bgp summary
Displays the status of all BGP connections.
Step 7 show placement program bgp
Example:RP/0/0/CPU0:router# show placement program bgp
Displays BGP program information.
If a program is shown as having ‘rejected locations’ (for example, locations where program cannot be placed), the locations in question can be viewed using the show placement program bgp command.
If a program has been placed but not started, the amount of elapsed time since the program was placed is displayed in the Waiting to start column.
Step 8 show placement program brib
Example:RP/0/0/CPU0:router# show placement program brib
Displays bRIB program information.
If a program is shown as having ‘rejected locations’ (for example, locations where program cannot be placed), the locations in question can be viewed using the show placement program bgp command.
If a program has been placed but not started, the amount of elapsed time since the program was placed is displayed in the Waiting to start column.
Monitoring BGP Update Groups
SUMMARY STEPS1. show bgp [ ipv4 { unicast | multicast | labeled-unicast | all | tunnel | } | ipv6 { unicast | all | labeled-unicast } | all { unicast | multicast | all | mdt | labeled-unicast | tunnel } | vpnv4 unicast | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpvn6 unicast ] update-group [ neighbor ip-address | process-id.index [ summary | performance-statistics ]]
DETAILED STEPS
Command or Action Purpose Step 1 show bgp [ ipv4 { unicast | multicast | labeled-unicast | all | tunnel | } | ipv6 { unicast | all | labeled-unicast } | all { unicast | multicast | all | mdt | labeled-unicast | tunnel } | vpnv4 unicast | vrf { vrf-name | all } [ ipv4 { unicast | labeled-unicast } | ipv6 unicast ] | vpvn6 unicast ] update-group [ neighbor ip-address | process-id.index [ summary | performance-statistics ]]
Example:RP/0/0/CPU0:router# show bgp update-group 0.0
Displays information about BGP update groups.
The ip-address argument displays the update groups to which that neighbor belongs.
The process-id.index argument selects a particular update group to display and is specified as follows: process ID (dot) index. Process ID range is from 0 to 254. Index range is from 0 to 4294967295.
The summary keyword displays summary information for neighbors in a particular update group.
If no argument is specified, this command displays information for all update groups (for the specified address family).
The performance-statistics keyword displays performance statistics for an update group.
Configuring BGP Nonstop Routing
SUMMARY STEPS
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 120
Specifies the BGP AS number, and enters the BGP configuration mode, for configuring BGP routing processes.
Step 3 nsr
Example:RP/0/0/CPU0:router(config-bgp)# nsr
Activates BGP Nonstop routing.
Step 4 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp)# end
or
RP/0/0/CPU0:router(config-bgp)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting (yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring Best-External Path Advertisement
SUMMARY STEPSPerform the following tasks to advertise the best–external path to the iBGP and route-reflector peers:
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 100
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 Do one of the following
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpnv4 unicast
Specifies the address family or VRF address family and enters the address family or VRF address family configuration submode.
Step 4 advertise best-external
Example:RP/0/0/CPU0:router(config-bgp-af)# advertise best-external
Advertise the best–external path to the iBGP and route-reflector peers.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp)# end
or
RP/0/0/CPU0:router(config-bgp)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting (yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Installing Primary Backup Path
SUMMARY STEPSPerform the following tasks to install a backup path into the forwarding table and provide prefix independent convergence (PIC) in case of a PE-CE link failure:
4. additional-paths install backup
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 100
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 Do one of the following
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpnv4 unicast
Specifies the address family or VRF address family and enters the address family or VRF address family configuration submode.
Step 4 additional-paths install backup
Example:RP/0/0/CPU0:router(config-bgp-af)# additional-paths install backup
Installs a backup path into the forwarding table and provides prefix independent convergence (PIC) in case of a PE-CE link failure.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp)# end
or
RP/0/0/CPU0:router(config-bgp)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting (yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session
Retaining Allocated Local Label for Primary Path
SUMMARY STEPSPerform the following tasks to retain the previously allocated local label for the primary path on the primary PE for some configurable time after reconvergence:
3. address-family { vpnv4 unicast | vpnv6 unicast }
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 100
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family { vpnv4 unicast | vpnv6 unicast }
Example:RP/0/0/CPU0:router(config-bgp)# address-family vpnv4 unicast
Specifies the address family and enters the address family configuration submode.
Step 4 retain local-label minutes
Example:RP/0/0/CPU0:router(config-bgp-af)# retain local-label 10
Retains the previously allocated local label for the primary path on the primary PE for 10 minutes after reconvergence.
Step 5 Do one of the following:
Example:RP/0/0/CPU0:router(config-bgp)# end
or
RP/0/0/CPU0:router(config-bgp)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting (yes/no/cancel)?[cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session
Configuring BGP Additional Paths
SUMMARY STEPS2. route-policy route-policy-name
3. if conditional-expression then action-statement else
7. address-family {ipv4 {unicast | multicast} | ipv6 {unicast | multicast | l2vpn vpls-vpws | vpnv4 unicast | vpnv6 unicast }
10. additional-paths selection route-policy route-policy-name
11. Use one of the following commands:
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 route-policy route-policy-name
Example:RP/0/0/CPU0:router (config)#route-policy add_path_policy
Defines the route policy and enters route-policy configuration mode.
Step 3 if conditional-expression then action-statement else
Example:RP/0/0/CPU0:router (config-rpl)#if community matches-any (*) then set path-selection all advertise else
Decides the actions and dispositions for the given route.
Step 4 pass endif
Example:RP/0/0/CPU0:router(config-rpl-else)#pass RP/0/0/CPU0:router(config-rpl-else)#endifPasses the route for processing and ends the if statement.
Step 5 end-policy
Example:RP/0/0/CPU0:router(config-rpl)#end-policy
Ends the route policy definition of the route policy and exits route-policy configuration mode.
Step 6 router bgp as-number
Example:RP/0/0/CPU0:router(config)#router bgp 100
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 7 address-family {ipv4 {unicast | multicast} | ipv6 {unicast | multicast | l2vpn vpls-vpws | vpnv4 unicast | vpnv6 unicast }
Example:RP/0/0/CPU0:router(config-bgp)#address-family ipv4 unicast
Specifies the address family and enters address family configuration submode.
Step 8 additional-paths receive
Example:RP/0/0/CPU0:router(config-bgp-af)#additional-paths receive
Configures receive capability of multiple paths for a prefix to the capable peers.
Step 9 additional-paths send
Example:RP/0/0/CPU0:router(config-bgp-af)#additional-paths send
Configures send capability of multiple paths for a prefix to the capable peers .
Step 10 additional-paths selection route-policy route-policy-name
Example:RP/0/0/CPU0:router(config-bgp-af)#additional-paths selection route-policy add_path_policy
Configures additional paths selection capability for a prefix.
Step 11 Use one of the following commands:
Example:RP/0/0/CPU0:router(config)# end
or
RP/0/0/CPU0:router(config)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)? [cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuring iBGP Multipath Load Sharing
SUMMARY STEPS3. address-family {ipv4|ipv6} {unicast|multicast}
5. Use one of the following commands:
DETAILED STEPS
Command or Action Purpose Step 1 configure
Example:RP/0/0/CPU0:router# configure
Enters global configuration mode.
Step 2 router bgp as-number
Example:RP/0/0/CPU0:router(config)# router bgp 100
Specifies the autonomous system number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Step 3 address-family {ipv4|ipv6} {unicast|multicast}
Example:RP/0/0/CPU0:router(config-bgp)# address-family ipv4 multicast
Specifies either the IPv4 or IPv6 address family and enters address family configuration submode.
Step 4 maximum-paths ibgp number
Example:RP/0/0/CPU0:router(config-bgp-af)# maximum-paths ibgp 30
Configures the maximum number of iBGP paths for load sharing.
Step 5 Use one of the following commands:
Example:RP/0/0/CPU0:router(config)# end
or
RP/0/0/CPU0:router(config)# commit
Saves configuration changes.
When you issue the end command, the system prompts you to commit changes:
Uncommitted changes found, commit them before exiting(yes/no/cancel)? [cancel]:
Entering yes saves configuration changes to the running configuration file, exits the configuration session, and returns the router to EXEC mode.
Entering no exits the configuration session and returns the router to EXEC mode without committing the configuration changes.
Entering cancel leaves the router in the current configuration session without exiting or committing the configuration changes.
Use the commit command to save the configuration changes to the running configuration file and remain within the configuration session.
Configuration Examples for Implementing BGP
This section provides the following configuration examples:
- Enabling BGP: Example
- Displaying BGP Update Groups: Example
- BGP Neighbor Configuration: Example
- BGP Confederation: Example
- BGP Route Reflector: Example
- BGP MDT Address Family Configuration: Example
- BGP Nonstop Routing Configuration: Example
- Best-External Path Advertisement Configuration: Example
- Primary Backup Path Installation: Example
- Allocated Local Label Retention: Example
- iBGP Multipath Loadsharing Configuration: Example
- Configuring BGP Additional Paths: Example
Enabling BGP: Example
The following shows how to enable BGP.
prefix-set static 2020::/64, 2012::/64, 10.10.0.0/16, 10.2.0.0/24 end-set route-policy pass-all pass end-policy route-policy set_next_hop_agg_v4 set next-hop 10.0.0.1 end-policy route-policy set_next_hop_static_v4 if (destination in static) then set next-hop 10.1.0.1 else drop endif end-policy route-policy set_next_hop_agg_v6 set next-hop 2003::121 end-policy route-policy set_next_hop_static_v6 if (destination in static) then set next-hop 2011::121 else drop endif end-policy router bgp 65000 bgp fast-external-fallover disable bgp confederation peers 65001 65002 bgp confederation identifier 1 bgp router-id 1.1.1.1 address-family ipv4 unicast aggregate-address 10.2.0.0/24 route-policy set_next_hop_agg_v4 aggregate-address 10.3.0.0/24 redistribute static route-policy set_next_hop_static_v4 address-family ipv4 multicast aggregate-address 10.2.0.0/24 route-policy set_next_hop_agg_v4 aggregate-address 10.3.0.0/24 redistribute static route-policy set_next_hop_static_v4 address-family ipv6 unicast aggregate-address 2012::/64 route-policy set_next_hop_agg_v6 aggregate-address 2013::/64 redistribute static route-policy set_next_hop_static_v6 address-family ipv6 multicast aggregate-address 2012::/64 route-policy set_next_hop_agg_v6 aggregate-address 2013::/64 redistribute static route-policy set_next_hop_static_v6 neighbor 10.0.101.60 remote-as 65000 address-family ipv4 unicast address-family ipv4 multicast neighbor 10.0.101.61 remote-as 65000 address-family ipv4 unicast address-family ipv4 multicast neighbor 10.0.101.62 remote-as 3 address-family ipv4 unicast route-policy pass-all in route-policy pass-all out address-family ipv4 multicast route-policy pass-all in route-policy pass-all out neighbor 10.0.101.64 remote-as 5 update-source Loopback0 address-family ipv4 unicast route-policy pass-all in route-policy pass-all out address-family ipv4 multicast route-policy pass-all in route-policy pass-all outDisplaying BGP Update Groups: Example
The following is sample output from the show bgp update-group command run in EXEC mode:
RP/0/0/CPU0:router# show bgp update-group Update group for IPv4 Unicast, index 0.1: Attributes: Outbound Route map:rm Minimum advertisement interval:30 Messages formatted:2, replicated:2 Neighbors in this update group: 10.0.101.92 Update group for IPv4 Unicast, index 0.2: Attributes: Minimum advertisement interval:30 Messages formatted:2, replicated:2 Neighbors in this update group: 10.0.101.91
BGP Neighbor Configuration: Example
The following example shows how BGP neighbors on an autonomous system are configured to share information. In the example, a BGP router is assigned to autonomous system 109, and two networks are listed as originating in the autonomous system. Then the addresses of three remote routers (and their autonomous systems) are listed. The router being configured shares information about networks 131. 108.0.0 and 192. 31.7.0 with the neighbor routers. The first router listed is in a different autonomous system; the second neighbor and remote-as commands specify an internal neighbor (with the same autonomous system number) at address 131. 108.234.2; and the third neighbor and remote-as commands specify a neighbor on a different autonomous system.
route-policy pass-all pass end-policy router bgp 109 address-family ipv4 unicast network 131. 108.0.0 255. 0.0.0 network 192. 31.7.0 255. 0.0.0 neighbor 131. 108.200.1 remote-as 167 exit address-family ipv4 unicast route-policy pass-all in route-policy pass-out out neighbor 131. 108.234.2 remote-as 109 exit address-family ipv4 unicast neighbor 150. 136.64.19 remote-as 99 exit address-family ipv4 unicast route-policy pass-all in route-policy pass-all outBGP Confederation: Example
The following is a sample configuration that shows several peers in a confederation. The confederation consists of three internal autonomous systems with autonomous system numbers 6001, 6002, and 6003. To the BGP speakers outside the confederation, the confederation looks like a normal autonomous system with autonomous system number 666 (specified using the bgp confederation identifier command).
In a BGP speaker in autonomous system 6001, the bgp confederation peers command marks the peers from autonomous systems 6002 and 6003 as special eBGP peers. Hence, peers 171. 69.232.55 and 171. 69.232.56 get the local preference, next hop, and MED unmodified in the updates. The router at 160. 69.69.1 is a normal eBGP speaker, and the updates received by it from this peer are just like a normal eBGP update from a peer in autonomous system 666.
router bgp 6001 bgp confederation identifier 666 bgp confederation peers 6002 6003 exit address-family ipv4 unicast neighbor 171. 69.232.55 remote-as 6002 exit address-family ipv4 unicast neighbor 171. 69.232.56 remote-as 6003 exit address-family ipv4 unicast neighbor 160. 69.69.1 remote-as 777In a BGP speaker in autonomous system 6002, the peers from autonomous systems 6001 and 6003 are configured as special eBGP peers. Peer 170. 70.70.1 is a normal iBGP peer, and peer 199.99.99.2 is a normal eBGP peer from autonomous system 700.
router bgp 6002 bgp confederation identifier 666 bgp confederation peers 6001 6003 exit address-family ipv4 unicast neighbor 170. 70.70.1 remote-as 6002 exit address-family ipv4 unicast neighbor 171. 69.232.57 remote-as 6001 exit address-family ipv4 unicast neighbor 171. 69.232.56 remote-as 6003 exit address-family ipv4 unicast neighbor 199. 99.99.2 remote-as 700 exit address-family ipv4 unicast route-policy pass-all in route-policy pass-all outIn a BGP speaker in autonomous system 6003, the peers from autonomous systems 6001 and 6002 are configured as special eBGP peers. Peer 200. 200.200.200 is a normal eBGP peer from autonomous system 701.
router bgp 6003 bgp confederation identifier 666 bgp confederation peers 6001 6002 exit address-family ipv4 unicast neighbor 171. 69.232.57 remote-as 6001 exit address-family ipv4 unicast neighbor 171. 69.232.55 remote-as 6002 exit address-family ipv4 unicast neighbor 200. 200.200.200 remote-as 701 exit address-family ipv4 unicast route-policy pass-all in route-policy pass-all outThe following is a part of the configuration from the BGP speaker 200. 200.200.205 from autonomous system 701 in the same example. Neighbor 171. 69.232.56 is configured as a normal eBGP speaker from autonomous system 666. The internal division of the autonomous system into multiple autonomous systems is not known to the peers external to the confederation.
router bgp 701 address-family ipv4 unicast neighbor 171. 69.232.56 remote-as 666 exit address-family ipv4 unicast route-policy pass-all in route-policy pass-all out exit address-family ipv4 unicast neighbor 200. 200.200.205 remote-as 701BGP Route Reflector: Example
The following example shows how to use an address family to configure internal BGP peer 10.1.1.1 as a route reflector client for both unicast and multicast prefixes:
router bgp 140 address-family ipv4 unicast neighbor 10.1.1.1 remote-as 140 address-family ipv4 unicast route-reflector-client exit address-family ipv4 multicast route-reflector-clientBGP MDT Address Family Configuration: Example
The following example shows how to configure an MDT address family in BGP:
router bgp 10 bgp router-id 10.0.0.2 address-family ipv4 unicast address-family vpnv4 unicast address-family ipv4 mdt ! neighbor 1.1.1.1 remote-as 11 update-source Loopback0 address-family ipv4 unicast address-family vpnv4 unicast address-family ipv4 md !BGP Nonstop Routing Configuration: Example
The following example shows how to enable BGP NSR:
RP/0/0/CPU0:router# configure RP/0/0/CPU0:router(config)# router bgp 120 RP/0/0/CPU0:router(config-bgp)# nsr RP/0/0/CPU0:router(config-bgp)# endThe following example shows how to disable BGP NSR:
RP/0/0/CPU0:router# configure RP/0/0/CPU0:router(config)# router bgp 120 RP/0/0/CPU0:router(config-bgp)# no nsr RP/0/0/CPU0:router(config-bgp)# endBest-External Path Advertisement Configuration: Example
The following example shows how to configure Best–External Path Advertisement:
router bgp 100 address-family l2vpn vpls-vpws advertise best-external endAllocated Local Label Retention: Example
The following example shows how to retain the previously allocated local label for the primary path on the primary PE for 10 minutes after reconvergence:
router bgp 100 address-family l2vpn vpls-vpws retain local-label 10 endConfiguring BGP Additional Paths: Example
This is a sample configuration for enabling BGP Additional Paths send, receive, and selcetion capabilities:route-policy add_path_policy if community matches-any (*) then set path-selection all advertise else pass endif end-policy ! router bgp 100 address-family ipv4 unicast additional-paths receive additional-paths send additional-paths selection route-policy add_path_policy ! ! endWhere to Go Next
For detailed information about BGP commands, see Cisco IOS XR Routing Command Reference for the Cisco XR 12000 Series Router
Additional References
Related Documents
Related Topic
Document Title
BGP commands: complete command syntax, command modes, command history, defaults, usage guidelines, and examples
Cisco IOS XR Routing Command Reference for the Cisco XR 12000 Series Router Cisco Express Forwarding (CEF) commands: complete command syntax, command modes, command history, defaults, usage guidelines, and examples
Cisco IOS XR IP Addresses and Services Command Reference for the Cisco XR 12000 Series Router MPLS VPN configuration information.
Cisco IOS XR MPLS Configuration Guide for the Cisco XR 12000 Series Router Bidirectional Forwarding Detection (BFD)
Cisco IOS XR Interface and Hardware Component Configuration Guide for the Cisco XR 12000 Series Router and Cisco IOS XR Interface and Hardware Component Command Reference for the Cisco XR 12000 Series Router Task ID information.
Configuring AAA Services on Cisco IOS XR Software module of Cisco IOS XR System Security Configuration Guide for the Cisco XR 12000 Series Router Standards
Standards
Title
draft-bonica-tcp-auth-05.txt
Authentication for TCP-based Routing and Management Protocols, by R. Bonica, B. Weis, S. Viswanathan, A. Lange, O. Wheeler
draft-ietf-idr-bgp4-26.txt
A Border Gateway Protocol 4, by Y. Rekhter, T.Li, S. Hares
draft-ietf-idr-bgp4-mib-15.txt
Definitions of Managed Objects for the Fourth Version of Border Gateway Protocol (BGP-4), by J. Hass and S. Hares
draft-ietf-idr-cease-subcode-05.txt
Subcodes for BGP Cease Notification Message, by Enke Chen, V. Gillet
draft-ietf-idr-avoid-transition-00.txt
Avoid BGP Best Path Transitions from One External to Another, by Enke Chen, Srihari Sangli
draft-ietf-idr-as4bytes-12.txt
BGP Support for Four-octet AS Number Space, by Quaizar Vohra, Enke Chen
draft-nalawade-idr-mdt-safi-03.txt
MDT SAFI, by Gargi Nalawade and Arjun Sreekantiah
MIBs
MIBs
MIBs Link
— To locate and download MIBs using Cisco IOS XR software, use the Cisco MIB Locator found at the following URL and choose a platform under the Cisco Access Products menu: http://cisco.com/public/sw-center/netmgmt/cmtk/mibs.shtml
RFCs
RFCs
Title
RFC 1700
Assigned Numbers
RFC 1997
BGP Communities Attribute
RFC 2385
Protection of BGP Sessions via the TCP MD5 Signature Option
RFC 2439
BGP Route Flap Damping
RFC 2545
Use of BGP-4 Multiprotocol Extensions for IPv6 Inter-Domain Routing
RFC 2796
BGP Route Reflection - An Alternative to Full Mesh IBGP
RFC 2858
Multiprotocol Extensions for BGP-4
RFC 2918
Route Refresh Capability for BGP-4
RFC 3065
Autonomous System Confederations for BGP
RFC 3392
Capabilities Advertisement with BGP-4
RFC 4271
A Border Gateway Protocol 4 (BGP-4)
RFC 4364
BGP/MPLS IP Virtual Private Networks (VPNs)
RFC 4724
Graceful Restart Mechanism for BGP