Cisco Systems 12.4 manual Specifying the LDP Router ID

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Specifying the LDP Router ID

How to Configure MPLS LDP

ip unnumbered Loopback0 mpls ip

mpls label protocol ldp

Specifying the LDP Router ID

The mpls ldp router-idcommand allows you to establish the IP address of an interface as the LDP router ID.

The following steps describe the normal process for determining the LDP router ID:

1The router considers all the IP addresses of all operational interfaces.

2If these addresses include loopback interface addresses, the router selects the largest loopback address. Configuring a loopback address helps ensure a stable LDP ID for the router, because the state of loopback addresses does not change. However, configuring a loopback interface and IP address on each router is not required.

The loopback IP address does not become the router ID of the local LDP ID under the following circumstances:

If the loopback interface has been explicitly shut down.

If the mpls ldp router-idcommand specifies that a different interface should be used as the LDP router ID.

If you use a loopback interface, make sure that the IP address for the loopback interface is configured with a /32 network mask. In addition, make sure that the routing protocol in use is configured to advertise the corresponding /32 network.

1Otherwise, the router selects the largest interface address.

The router might select a router ID that is not usable in certain situations. For example, the router might select an IP address that the routing protocol cannot advertise to a neighboring router.

The router implements the router ID the next time it is necessary to select an LDP router ID. The effect of the command is delayed until the next time it is necessary to select an LDP router ID, which is typically the next time the interface is shut down or the address is deconfigured.

If you use the force keyword with the mpls ldp router-idcommand, the router ID takes effect more quickly. However, implementing the router ID depends on the current state of the specified interface:

If the interface is up (operational) and its IP address is not currently the LDP router ID, the LDP router ID is forcibly changed to the IP address of the interface. This forced change in the LDP router ID tears down any existing LDP sessions, releases label bindings learned via the LDP sessions, and interrupts MPLS forwarding activity associated with the bindings.

If the interface is down, the LDP router ID is forcibly changed to the IP address of the interface when the interface transitions to up. This forced change in the LDP router ID tears down any existing LDP sessions, releases label bindings learned via the LDP sessions, and interrupts MPLS forwarding activity associated with the bindings.

Make sure the specified interface is operational before assigning it as the LDP router ID.

MPLS LDP Configuration Guide, Cisco IOS Release 12.4

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Contents Mpls LDP Configuration Guide, Cisco IOS Release Page N T E N T S Mpls LDP Inbound Label Binding Filtering Mpls LDP Graceful Restart Contents Mpls LDP Configuration Guide, Cisco IOS Release Finding Feature Information Prerequisites for Mpls LDPInformation About Mpls LDP LDP and TDP Support Introduction to Mpls LDPMpls LDP Functional Overview Train and ReleaseIntroduction to LDP Sessions Train and Release LDP/TDP SupportNondirectly Connected Mpls LDP Sessions How to Configure Mpls LDP Enabling Directly Connected LDP Sessions,Step Command or Action Purpose Enabling Directly Connected LDP SessionsExample Command or Action Purpose StepStep Command or Action Establishing Nondirectly Connected Mpls LDP SessionsExamples Mpls label protocol ldp tdp both Interface tunnelnumber Tunnel destination ip-address Saving Configurations Mpls Tag Switching Commands Specifying the LDP Router ID Routerconfig# mpls ldp Router-id pos2/0/0 Preserving QoS Settings with Mpls LDP Explicit Null Following example displays the LDP router IDInterface type number Command or Action Purpose Local Outgoing Prefix Protecting Data Between LDP Peers with MD5 Authentication Summary Steps Mpls ldp neighbor vrf vpn-nameip Mpls LDP Configuration Examples Configuring Directly Connected Mpls LDP Sessions ExampleRouter 1 Configuration Router 2 ConfigurationRouter 3 Configuration Establishing Nondirectly Connected Mpls LDP Sessions Example Router 4 Configuration Router 5 ConfigurationRouter 6 Configuration Additional References Feature Information for Mpls Label Distribution Protocol Technical Assistance Description LinkReleases Feature Information Router-idFeature Name Releases Feature Name Releases Feature Information Page Restrictions for Mpls LDP Session Protection Information About Mpls LDP Session ProtectionMpls LDP Session Protection Customizations How to Configure Mpls LDP Session Protection Enabling Mpls LDP Session ProtectionRouterconfig-if#mpls label protocol ldp Verifying Mpls LDP Session Protection Troubleshooting Tips Router# show mpls ldp neighbor detailIp classless Redundancy Full-duplex Interface Ethernet5/0/2 MIBs MIBs Link RFCs TitleCommand Reference Mpls LDP Inbound Label Binding Filtering RestrictionsHow to Configure Mpls LDP Inbound Label Binding Filtering Configuring Mpls LDP Inbound Label Binding FilteringIp access-list standard access-list-number Verifying that Mpls LDP Inbound Label Bindings are Filtered Router# show mpls ldp neighbor 10.12.12.12 detailAccess-list-number Access-list-name LDP Specification, draft-ietf-mpls-ldp-08.txt Technical Assistance Description Link Releases Feature Information GlossaryMpls LDP Inbound Label Binding Filtering Page Mpls LDP Autoconfiguration Restrictions for Mpls LDP AutoconfigurationMpls LDP Autoconfiguration on Ospf and IS-IS Interfaces Information About Mpls LDP AutoconfigurationHow to Configure Mpls LDP Autoconfiguration Configuring Mpls LDP Autoconfiguration with Ospf InterfacesGlobally enables hop-by-hop forwarding Router ospf process-id Verifying Mpls LDP Autoconfiguration with Ospf Router# show mpls interfaces Serial 2/0 detail Configuring Mpls LDP Autoconfiguration with IS-IS Interfaces Command or Action Purpose StepEnables IS-IS for IP on the interface Enables the LDP for interfaces that belong to an IS-IS Verifying Mpls LDP Autoconfiguration with IS-IS Router# show isis mpls ldpMpls LDP Autoconfiguration with Ospf Example Troubleshooting TipsMpls LDP Autoconfiguration with IS-IS Examples Command ReferenceFeature Information for Mpls LDP Autoconfiguration Feature Information for Mpls LDP Autoconfiguration Mpls LDP Graceful Restart Information About Mpls LDP Graceful Restart How Mpls LDP Graceful Restart WorksHow to Configure Mpls LDP Graceful Restart Configuring Mpls LDP Graceful RestartMpls ip Mpls label protocol ldptdpboth Configuration Example for Mpls LDP Graceful Restart Verifying the ConfigurationRouter 1 configured with LDP GR Router 2 configured with LDP SSO/NSFRouter 3 configured with LDP SSO/NSF Mpls label protocol ldp mpls traffic-eng tunnels mpls ipMpls Label Distribution Protocol Feature Information for Mpls LDP Graceful Restart Feature Information for Mpls LDP Graceful Restart

12.4 specifications

Cisco Systems has consistently been at the forefront of networking technology, and one of its notable software releases is IOS version 12.4. This version introduced significant enhancements and features that continue to influence networking practices. IOS 12.4 was specifically designed to accommodate the growing demands of network reliability, scalability, and advanced functionalities.

One of the primary characteristics of IOS 12.4 is its enhanced security features. The version integrates advanced security protocols, including improvements in IPsec, which allows for secure communication across potentially insecure networks. Additionally, it supports firewall technologies and access control lists (ACLs), ensuring that organizations can implement stringent security measures tailored to their traffic requirements.

Another defining feature of IOS 12.4 is its support for IPv6. As the internet continued to grow, the need for expanded address space became critical. With IOS 12.4, Cisco provided robust capabilities for transitioning from IPv4 to IPv6, ensuring that network managers could adopt the newer standard without sacrificing performance or reliability. This included support for routing protocols and other networking functions that were essential in an IPv6 environment.

Performance improvements were also a key aspect of IOS 12.4. The release optimized routing protocols, including Enhanced Interior Gateway Routing Protocol (EIGRP) and Open Shortest Path First (OSPF), to enhance convergence times and reduce latency. This effectively contributed to improved network efficiency and uptime.

Cisco also included advanced Quality of Service (QoS) capabilities in IOS 12.4, allowing organizations to prioritize critical traffic. Features such as class-based weighted fair queuing and low-latency queuing became invaluable for organizations requiring seamless voice and video communications over IP networks. This focus on QoS demonstrated Cisco's understanding of the growing importance of multimedia applications in modern business environments.

With a set of stable and scalable routing features, IOS 12.4 supports a variety of platforms, enabling businesses to deploy it across different networking hardware to suit their needs. The modularity of this IOS version makes it flexible for various applications, from small business networks to large enterprise systems.

In summary, Cisco Systems' IOS 12.4 brought forth a wealth of features aimed at enhancing security, performance, and flexibility. Through improved routing capabilities, strong IPv6 support, and advanced QoS features, this version laid the foundation for many of the networking principles that organizations still utilize today.