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This documentation has been moved
- Part 1 : Basic MPLS
- Part 2 : MPLS label Distribution Protocol
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Part 3: MPLS Traffic Engineering: Path Calculation and Setup
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MPLS Traffic Engineering (TE) - Scalability Enhancements
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MPLS Traffic Engineering - AutoTunnel Mesh Groups
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MPLS Traffic Engineering - Verbatim Path Support
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MPLS Traffic Engineering - RSVP Hello State Timer
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MPLS Traffic Engineering Forwarding Adjacency
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MPLS Traffic Engineering (TE) - Class-based Tunnel Selection
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MPLS Traffic Engineering - Interarea Tunnels
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MPLS Traffic Engineering—Configurable Path Calculation Metric for Tunnels
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MPLS Traffic Engineering and Enhancements
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MPLS Traffic Engineering (TE) - IP Explicit Address Exclusion
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MPLS Traffic Engineering - LSP Attributes
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MPLS Traffic Engineering—Automatic Bandwidth Adjustment for TE Tunnels
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MPLS Traffic Engineering—Tunnel Source
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- Part 4: MPLS Traffic Engineering: DiffServ
- Part 5: MPLS Traffic Engineering: Path, Link, and Node Protection
- Part 6: MPLS Layer 2 VPNs
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Part 7: MPLS Layer 3 VPNs
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Configuring MPLS Layer 3 VPNs
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Assigning an ID Number to a VPN
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Multi-VRF Selection Using Policy Based Routing (PBR)
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VRF Aware System Message Logging (Syslog)
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MPLS VPN—Route Target Rewrite
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MPLS VPN—Show Running VRF
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MPLS VPN—VRF CLI for IPv4 and IPv6 VPNs
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MPLS VPN: VRF Selection Using Policy Based Routing
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- Part 8: MPLS Layer 3 VPNs: InterAutonomous Systems and Carrier Supporting Carrier
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Part 9: MPLS Embedded Management and MIBs
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MPLS LSP Ping/Traceroute for LDP/TE, and LSP Ping for VCCV
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MPLS Embedded Management—LSP Ping/Traceroute and AToM VCCV
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MPLS Enhancements to Interfaces MIB
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MPLS Label Switching Router MIB
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MPLS Label Distribution Protocol MIB
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MPLS Label Distribution Protocol MIB Version 8 Upgrade
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MPLS Traffic Engineering MIB
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MPLS Traffic Engineering - Fast Reroute MIB
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MPLS VPN—MIB Support
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MPLS VPN—SNMP Notifications
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- Part 10: MPLS High Availability
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Table Of Contents
MPLS Traffic Engineering-Autotunnel Primary and Backup
Prerequisites for MPLS Traffic Engineering-Autotunnel Primary and Backup
Restrictions for MPLS Traffic Engineering-Autotunnel Primary and Backup
Information About MPLS Traffic Engineering-Autotunnel Primary and Backup
Overview of MPLS Traffic Engineering-Autotunnel Primary and Backup
Benefits of MPLS Traffic Engineering-Autotunnel Primary and Backup Feature
MPLS Traffic Engineering Backup Autotunnels
MPLS Traffic Engineering Primary Autotunnels
MPLS Traffic Engineering Label-Based Forwarding
Benefits of MPLS Traffic Engineering Protection
Delivery of Packets During a Failure
Multiple Backup Tunnels Protecting the Same Interface
Affinity and Link Attributes with Autotunnel Backup
How to Configure MPLS Traffic Engineering Autotunnel Primary and Backup
Establishing MPLS Backup Autotunnels to Protect Fast Reroutable TE LSPs
Establishing MPLS One-Hop Tunnels to All Neighbors
Configuration Examples for MPLS Traffic Engineering-Autotunnel Primary and Backup
Establishing MPLS Backup Autotunnels to Protect Fast Reroutable TE LSPs: Example
Establishing MPLS One-Hop Tunnels to Neighbors: Example
Feature Information for MPLS Traffic Engineering-Autotunnel Primary and Backup
MPLS Traffic Engineering-Autotunnel Primary and Backup
First Published: January 26, 2004Last Updated: November 24, 2010The MPLS Traffic Engineering-Autotunnel Primary and Backup feature enables a router to dynamically build backup tunnels and to dynamically create one-hop primary tunnels on all interfaces that have been configured with Multiprotocol Label Switching (MPLS) traffic engineering (TE) tunnels.
A router with primary one-hop autotunnels and backup autotunnels can be configured with stateful switchover (SSO) redundancy.
Finding Feature Information
Your software release may not support all the features documented in this module. For the latest feature information and caveats, see the release notes for your platform and software release. To find information about the features documented in this module, and to see a list of the releases in which each feature is supported, see the "Feature Information for MPLS Traffic Engineering-Autotunnel Primary and Backup" section.
Use Cisco Feature Navigator to find information about platform support and Cisco IOS and Catalyst OS software image support. To access Cisco Feature Navigator, go to http://www.cisco.com/go/cfn. An account on Cisco.com is not required.
Contents
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Prerequisites for MPLS Traffic Engineering-Autotunnel Primary and Backup
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Prerequisites for MPLS Traffic Engineering-Autotunnel Primary and Backup
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Restrictions for MPLS Traffic Engineering-Autotunnel Primary and Backup
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Information About MPLS Traffic Engineering-Autotunnel Primary and Backup
To configure autotunnels, you need to understand the following concepts:
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Overview of MPLS Traffic Engineering-Autotunnel Primary and Backup
The MPLS Traffic Engineering-Autotunnel Primary and Backup feature has the following features:
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If no backup tunnels exist, the following types of backup tunnels are created:
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Benefits of MPLS Traffic Engineering-Autotunnel Primary and Backup Feature
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MPLS Traffic Engineering
MPLS is an Internet Engineering Task Force (IETF)-specified framework that provides for the efficient designation, routing, forwarding, and switching of traffic flows through the network.
TE is the process of adjusting bandwidth allocations to ensure that enough bandwidth is left for high-priority traffic.
In MPLS TE, the upstream router creates a network tunnel for a particular traffic stream, then sets the bandwidth available for that tunnel.
MPLS Traffic Engineering Backup Autotunnels
MPLS backup autotunnels protect fast reroutable TE label switched paths (LSPs). Without MPLS backup autotunnels to protect a LSP you had to do the following:
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An LSP requests backup protection from Resource Reservation Protocol (RSVP) FRR in the following situations:
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If there was no backup tunnel protecting the interface used by the LSP, the LSP remained unprotected.
Backup autotunnels enable a router to dynamically build backup tunnels when they are needed. This prevents you from having to build MPLS TE tunnels statically.
Backup tunnels may not be available for the following reasons:
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If a backup tunnel is not available, the following two backup tunnels are created dynamically:
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Link Protection
Backup tunnels that bypass only a single link of the LSP's path provide link protection. They protect LSPs if a link along their path fails by rerouting the LSP's traffic to the next hop (bypassing the failed link). These are referred to as NHOP backup tunnels because they terminate at the LSP's next hop beyond the point of failure. Figure 1 illustrates an NHOP backup tunnel.
Figure 1 Next-Hop Backup Tunnel
Node Protection
Backup tunnels that bypass next-hop nodes along LSP paths are called NNHOP backup tunnels because they terminate at the node following the next-hop node of the LSPs, thereby bypassing the next-hop node. They protect LSPs by enabling the node upstream of a link or node failure to reroute the LSPs and their traffic around the failure to the next-hop node. NNHOP backup tunnels also provide protection from link failures because they bypass the failed link and the node.
Figure 2 illustrates an NNHOP backup tunnel.
Figure 2 Next-Next Hop Backup Tunnel
Explicit Paths
Explicit paths are used to create backup autotunnels as follows:
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Range for Backup Autotunnels
The tunnel range for backup autotunnels is configurable. By default, the last 100 TE tunnel IDs are used; that is 65,436 to 65,535. Autotunnels detect tunnel IDs that are being used. IDs are allocated starting with the lowest number.
For example, if you configure a tunnel range 1000 to 1100 and statically configured TE tunnels are in that range, routers do not use those IDs. If those static tunnels are removed, the MPLS TE dynamic tunnel software can use those IDs.
MPLS Traffic Engineering Primary Autotunnels
The MPLS Traffic Engineering-Autotunnel Primary and Backup feature enables a router to dynamically create one-hop primary tunnels on all interfaces that have been configured with MPLS traffic. The tunnels are created with zero bandwidth. The constraint-based shortest path first (CSPF) is the same as the shortest path first (SPF) when there is zero bandwidth, so the router's choice of the autorouted one-hop primary tunnel is the same as if there were no tunnel. Because it is a one-hop tunnel, the encapsulation is tag-implicit (that is, there is no tag header).
Explicit Paths
Explicit paths are used to create autotunnels as follows:
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Range for Autotunnels
The tunnel range is configurable. By default, the last 100 TE tunnel IDs are used; that is 65,436 to 65,535. Autotunnels detect tunnel IDs that are being used. IDs are allocated starting with the lowest number.
For example, if you configure a tunnel range 100 to 200 and statically configured TE tunnels are in that range, routers do not use those IDs. If those static tunnels are removed, the IDs become available for use by the MPLS TE dynamic tunnel software.
MPLS Traffic Engineering Label-Based Forwarding
Routers receive a packet, determine where it needs to go by examining some fields in the packet, and send it to the appropriate output device. A label is a short, fixed-length identifier that is used to forward packets. A label switching device normally replaces the label in a packet with a new value before forwarding the packet to the next hop. For this reason, the forwarding algorithm is called label swapping. A label switching device, referred to as an LSR, runs standard IP control protocols (that is, routing protocols, RSVP, and so forth) to determine where to forward packets.
Benefits of MPLS Traffic Engineering Protection
The following sections describe the benefits of MPLS traffic engineering protection:
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Delivery of Packets During a Failure
Backup tunnels that terminate at the NNHOP protect both the downstream link and node. This provides protection for link and node failures.
Multiple Backup Tunnels Protecting the Same Interface
In addition to being required for node protection, the autotunnel primary and backup feature provides the following benefits:
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Scalability
A backup tunnel can protect multiple LSPs. Furthermore, a backup tunnel can protect multiple interfaces. This is called many-to-one (N:1) protection. N:1 protection has significant scalability advantages over one-to-one (1:1) protection, where a separate backup tunnel must be used for each LSP needing protection.
An example of N:1 protection is that when one backup tunnel protects 5000 LSPs, each router along the backup path maintains one additional tunnel.
An example of 1:1 protection is that when 5000 backup tunnels protect 5000 LSPs, each router along the backup path must maintain state for an additional 5000 tunnels.
RSVP Hello
RSVP Hello allows a router to detect when its neighbor has gone down but its interface to that neighbor is still operational. When Layer 2 link protocols are unable to detect that the neighbor is unreachable, Hellos provide the detection mechanism; this allows the router to switch LSPs onto its backup tunnels and avoid packet loss.
SSO Redundancy Overview
The SSO feature is an incremental step within an overall program to improve the availability of networks constructed with Cisco IOS routers.
SSO is particularly useful at the network edge. It provides protection for network edge devices with dual route processors (RPs) that represent a single point of failure in the network design, and where an outage might result in loss of service for customers.
In specific Cisco networking devices that support dual RPs, SSO takes advantage of RP redundancy to increase network availability. The feature establishes one of the RPs as the active processor while the other RP is designated as the standby processor, and then synchronizes critical state information between them. Following an initial synchronization between the two processors, SSO dynamically maintains RP state information between them.
A switchover from the active to the standby processor occurs when the active RP fails, is removed from the networking device, or is manually taken down for maintenance.
Affinity and Link Attributes with Autotunnel Backup
In Cisco IOS Release 15.1(1)S and later releases, you can use affinity and link attributes with the MPLS TE Autotunnel Backup feature to include or exclude links when configuring dynamic backup paths.
For a link, you can configure up to 32 bits of attribute flags, as shown in the following example:
Router> enableRouter# configure terminalRouter(config)# interface ethernet0/0Router(config-if)# mpls traffic-eng attribute-flags 0x22The attribute flags are compared to the tunnel's affinity bits during selection of the path.
When you enable the auto-tunnel backup feature, you can optionally specify the affinity and mask, as shown in the following example. If you do not specify an affinity and mask, the default for affinity is 0 and for the mask it is 0xFFFF is used. To ignore link affinity, use affinity and mask of 0. See the mpls traffic-eng auto-tunnel backup config affinity command for more information.
Router> enableRouter# configure terminalRouter(config)# mpls traffic-eng auto-tunnel backupRouter(config)# mpls traffic-eng auto-tunnel backup config affinity 0x13 mask 0x13The affinity/mask configured by the mpls traffic-eng auto-tunnel backup config affinity command is used for all dynamically created backup tunnels. The attribute mask determines which link attributes are relevent. If a bit in the mask is 0, the attribute is irrelevant. If a bit in the mask is 1, the attribute value of a link and the configured affinity of the tunnel for that bit must match.
In Figure 3, there are two primary tunnels. One tunnel travels from router A to router B. The other primary tunnel travels from router A to router B and then router D. All the the links are configured with attribute flags 0x22. Both tunnels require fast reroute protection. To automatically create backup tunnels, enable the autotunnel backup feature with the mpls traffic-eng auto-tunnel backup command. However, the dynamically created backup tunnels do not come up, because attribute flags are configured on the links. To enable the dynamically created backup tunnels, you must also issue the following command:
Router(config)# mpls traffic-eng auto-tunnel backup config affinity 0x22 mask 0x22
Figure 3 Specifying Link Attributes and Affinity with Autotunnel Backup
How to Configure MPLS Traffic Engineering Autotunnel Primary and Backup
This sections contains the following procedures:
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Establishing MPLS Backup Autotunnels to Protect Fast Reroutable TE LSPs
To establish an MPLS backup autotunnel to protect fast reroutable TE LSPs, perform the following task.
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Establishing MPLS One-Hop Tunnels to All Neighbors
To establish MPLS one-hop tunnels to all neighbors, perform the following task.
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Configuration Examples for MPLS Traffic Engineering-Autotunnel Primary and Backup
This section contains the following configuration examples:
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Establishing MPLS Backup Autotunnels to Protect Fast Reroutable TE LSPs: Example
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To determine if there are any backup tunnels, enter the show ip rsvp fast-reroute command. This example shows that there is a static configured primary tunnel and no backup tunnels.
Router(config)# show ip rsvp fast-reroutePrimary Protect BW BackupTunnel I/F BPS:Type Tunnel:Label State Level Type------ ------- ------- ------------ ------ ----- ----R3-PRP_t0 PO3/1 0:G None None NoneThe following command causes autotunnels to automatically configure NHOP and NNHOP backup tunnels:
Router(config)# mpls traffic-eng auto-tunnel backupAs illustrated in the show ip interface brief command output, autotunneling created two backup tunnels that have tunnel IDs 65436 and 65437:
Router# show ip interface briefInterface IP-Address OK? Method Status ProtocolPOS2/0 10.0.0.14 YES NVRAM down downPOS2/1 10.0.0.49 YES NVRAM up upPOS2/2 10.0.0.45 YES NVRAM up upPOS2/3 10.0.0.57 YES NVRAM administratively down downPOS3/0 10.0.0.18 YES NVRAM down downPOS3/1 10.0.0.33 YES NVRAM up upPOS3/2 unassigned YES NVRAM administratively down downPOS3/3 unassigned YES NVRAM administratively down downGigabitEthernet4/0 10.0.0.37 YES NVRAM up upGigabitEthernet4/1 unassigned YES NVRAM administratively down downGigabitEthernet4/2 unassigned YES NVRAM administratively down downLoopback0 10.0.3.1 YES NVRAM up upTunnel0 10.0.3.1 YES unset up upTunnel65436 10.0.3.1 YES unset up upTunnel65437 10.0.3.1 YES unset up upEthernet0 10.3.38.3 YES NVRAM up upEthernet1 unassigned YES NVRAM administratively down downR3-PRP#The following command prevents autotunneling from creating NNHOP backup tunnels:
Router# mpls traffic-eng auto-tunnel backup nhop-onlyThe "Type" field in the following show ip rsvp fast-reroute command shows that there is only an NHOP tunnel:
Router# show ip rsvp fast-reroutePrimary Protect BW BackupTunnel I/F BPS:Type Tunnel:Label State Level Type------ ------- -------- ------------- ------ ------- ----R3-PRP_t0 PO3/1 0:G Tu65436:24 Ready any-unl NhopThe following command changes the minimum and maximum tunnel interface numbers to 1000 and 1100, respectively:
Router# mpls traffic-eng auto-tunnel backup tunnel-num min 1000 max 1100You can verify the ID numbers and autotunnel backup range ID by entering the show ip rsvp fast-reroute and show ip interface brief commands. In this example, only one backup tunnel is protecting the primary tunnel:
Router# show ip rsvp fast-reroutePrimary Protect BW BackupTunnel I/F BPS:Type Tunnel:Label State Level Type------ ------- -------- ------------- ------ ----- ------R3-PRP_t0 PO3/1 0:G Tu1000:24 Ready any-unl NhopRouter# show ip interface briefInterface IP-Address OK? Method Status ProtocolPOS2/0 10.0.0.14 YES NVRAM down downPOS2/1 10.0.0.49 YES NVRAM up upPOS2/2 10.0.0.45 YES NVRAM up upPOS2/3 10.0.0.57 YES NVRAM administratively down downPOS3/0 10.0.0.18 YES NVRAM down downPOS3/1 10.0.0.33 YES NVRAM up upPOS3/2 unassigned YES NVRAM administratively down downPOS3/3 unassigned YES NVRAM administratively down downGigabitEthernet4/0 10.0.0.37 YES NVRAM up upGigabitEthernet4/1 unassigned YES NVRAM administratively down downGigabitEthernet4/2 unassigned YES NVRAM administratively down downLoopback0 10.0.3.1 YES NVRAM up upTunnel0 10.0.3.1 YES unset up upTunnel65436 10.0.3.1 YES unset up upEthernet0 10.3.38.3 YES NVRAM up upEthernet1 unassigned YES NVRAM administratively down downThe default tunnel range for autotunnel backup tunnels is 65,436 through 65,535. The following show ip rsvp fast-reroute command changes the tunnel range IDs:
Router# show ip rsvp fast-reroutePrimary Protect BW BackupTunnel I/F BPS:Type Tunnel:Label State Level Type------ ------- -------- ------------- ------ ----- ------R3-PRP_t0 PO3/1 0:G Tu1001:0 Ready any-unl N-NhopThe results are shown in the show ip interface brief command:
Router# show ip interfaceRouter# show ip interface briefInterface UP-Address OK? Method Status ProtocolPOS2/0 10.0.0.14 YES NVRAM down downPOS2/1 10.0.0.49 YES NVRAM up upPOS2/2 10.0.0.45 YES NVRAM up upPOS2/3 10.0.0.57 YES NVRAM up upPOS3/0 10.0.0.18 YES NVRAM up upPOS3/1 10.0.0.33 YES NVRAM up upPOS3/2 unassigned YES NVRAM administratively down downPOS3/3 unassigned YES NVRAM administratively down downLoopback0 10.0.3.1 YES NVRAM up upTunnel0 10.0.3.1 YES unset up upTunnel1000 10.0.3.1 YES unset up upTunnel1001 10.0.3.1 YES unset up upEthernet0 10.3.38.3 YES NVRAM up upEthernet1 unassigned YES NVRAM administratively down downThe following mpls traffic-eng auto-tunnel backup timers removal unused command specifies that a timer will scan backup autotunnels every 50 seconds and the timer will remove tunnels that are not being used:
Router(config)# mpls traffic-eng auto-tunnel backup timers removal unused 50The following mpls traffic-eng auto-tunnel backup config unnumbered-interface command enables IP processing on POS interface 3/1:
Router(config)# mpls traffic-eng auto-tunnel backup config unnumbered-interface POS3/1To verify that IP processing is enabled on POS3/1, enter the show interfaces tunnel command:
Router# show interfaces tunnel 1001Tunnel1001 is up, line protocol is upHardware is TunnelInterface is unnumbered. Using address of POS3/1 (10.0.0.33)MTU 1514 bytes, BW 9 Kbit, DLY 500000 usec, rely 255/255, load 1/255Encapsulation TUNNEL, loopback not setKeepalive not setTunnel source 10.0.0.0, destination 10.0.5.1Tunnel protocol/transport Label Switching, sequencing disabledKey disabledChecksumming of packets disabledLast input never, output never, output hang neverLast clearing of "show interface" counters neverQueueing strategy: fifoOutput queue 0/0, 0 drops; input queue 0/75, 0 drops5 minute input rate 0 bits/sec, 0 packets/sec5 minute output rate 0 bits/sec, 0 packets/sec0 packets input, 0 bytes, 0 no bufferReceived 0 broadcasts, 0 runts, 0 giants, 0 throttles0 input errors, 0 CRC, 0 frame, 0 overrun, 0 ignored, 0 abort0 packets output, 0 bytes, 0 underruns0 output errors, 0 collisions, 0 interface resets0 output buffer failures, 0 output buffers swapped outThe following mpls traffic-eng auto-tunnel backup config affinity command specifies affinity and link attributes that help in the calculation of the dynamically created backup tunnel:
Router(config)# mpls traffic-eng auto-tunnel backup config affinity 0x22 mask 0x22
To display the affinity and link attributes assigned to a dynamically created backup tunnel, enter the show mpls traffic-eng auto-tunnel backup command:
Router# show mpls traffic-eng auto-tunnel backupState: EnabledTunnel Count: 3 (up:2, down: 1)Tunnel ID Range: 65436-65535Create Nhop only: YesSRLG: Not configuredDelete unused tunnels after: 50 SecondsConfig:Unnumbered i/f: Looback0Affinity: 0x22/0x22Establishing MPLS One-Hop Tunnels to Neighbors: Example
For autotunneling to automatically create primary tunnels to all next hops, you must enter the following command:
Router(config)# mpls traffic-eng auto-tunnel primary onehopIn this example there are four primary tunnels and no backup tunnels. To verify that configuration, enter the show ip rsvp fast-reroute command and the show ip interface brief command:
Router# show ip rsvp fast-reroutePrimary Protect BW BackupTunnel I/F BPS:Type Tunnel:Label State Level Type------ ------- -------- ------------- ------ ----- ------R3-PRP_t65337 PO2/2 0:G None None NoneR3-PRP_t65338 PO3/1 0:G None None NoneR3-PRP_t65339 Gi4/0 0:G None None NoneR3-PRP_t65336 PO2/1 0:G None None NoneRouter# show ip interface briefInterface IP-Address OK? Method Status ProtocolPOS2/0 10.0.0.14 YES NVRAM down downPOS2/1 10.0.0.49 YES NVRAM up upPOS2/2 10.0.0.45 YES NVRAM up upPOS2/3 10.0.0.57 YES NVRAM administratively down downPOS3/0 10.0.0.18 YES NVRAM down downPOS3/1 10.0.0.33 YES NVRAM up upPOS3/2 unassigned YES NVRAM administratively down downPOS3/3 unassigned YES NVRAM administratively down downGigabitEthernet4/0 10.0.0.37 YES NVRAM up upGigabitEthernet4/1 unassigned YES NVRAM administratively down downGigabitEthernet4/2 unassigned YES NVRAM administratively down downLoopback0 10.0.3.1 YES NVRAM up upTunnel0 10.0.3.1 YES unset administratively down downTunnel65336 10.0.3.1 YES unset up upTunnel65337 10.0.3.1 YES unset up upTunnel65338 10.0.3.1 YES unset up upTunnel65339 10.0.3.1 YES unset up upEthernet0 10.3.38.3 YES NVRAM up upEthernet1 unassigned YES NVRAM administratively down downR3-PRP#The default tunnel range for primary autotunnels is 65,336 through 65,435. The following mpls traffic-eng auto-tunnel primary tunnel-num command changes the range to 2000 through 2100:
Router(config)# mpls traffic-eng auto-tunnel primary tunnel-num min 2000 max 2100The following sample output from the show ip rsvp fast-reroute command and the show ip interface brief command shows that the tunnel IDs are 2000, 2001, 2002, and 2003:
Router# show ip rsvp fast-reroutePrimary Protect BW BackupTunnel I/F BPS:Type Tunnel:Label State Level Type------ ------- -------- ------------- ------ ----- ------R3-PRP_t2001 PO2/2 0:G None None NoneR3-PRP_t2002 PO3/1 0:G None None NoneR3-PRP_t2003 Gi4/0 0:G None None NoneR3-PRP_t2000 PO2/1 0:G None None NoneRouter# show ip interface briefInterface IP-Address OK? Method Status ProtocolPOS2/0 10.0.0.14 YES NVRAM down downPOS2/1 10.0.0.49 YES NVRAM up upPOS2/2 10.0.0.45 YES NVRAM up upPOS2/3 10.0.0.57 YES NVRAM administratively down downPOS3/0 10.0.0.18 YES NVRAM down downPOS3/1 10.0.0.33 YES NVRAM up upPOS3/2 unassigned YES NVRAM administratively down downPOS3/3 unassigned YES NVRAM administratively down downGigabitEthernet4/0 10.0.0.37 YES NVRAM up upGigabitEthernet4/1 unassigned YES NVRAM administratively down downGigabitEthernet4/2 unassigned YES NVRAM administratively down downLoopback0 10.0.3.1 YES NVRAM up upTunnel0 10.0.3.1 YES unset administratively down downTunnel2000 10.0.3.1 YES unset up upTunnel2001 10.0.3.1 YES unset up upTunnel2002 10.0.3.1 YES unset up upTunnel2003 10.0.3.1 YES unset up upEthernet0 10.3.38.3 ' YES NVRAM up upEthernet1 unassigned YES NVRAM administratively down downThe following mpls traffic-eng auto-tunnel primary timers command specifies that a timer will scan backup autotunnels every 50 seconds and remove tunnels that are not being used:
Router(config)# mpls traffic-eng auto-tunnel primary timers removal rerouted 50The following mpls traffic-eng auto-tunnel primary config unnumbered command enables IP processing on POS interface 3/1:
Router(config)# mpls traffic-eng auto-tunnel primary config unnumbered POS3/1To specify that autotunneling remove all primary autotunnels and re-create them, enter the following command:
Router(config)# clear mpls traffic-eng auto-tunnel primaryAdditional References
The following sections provide references related to the MPLS Traffic Engineering-Autotunnel Primary and Backup feature.
Additional References
Backup tunnels
Link protection
MPLS traffic engineering commands
SSO
Cisco IOS High Availability Configuration Guide
Standards
No new or modified standards are supported by this feature, and support for existing standards has not been modified by this feature.
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MIBs
RFCs
No new or modified RFCs are supported by this feature, and support for existing RFCs has not been modified by this feature.
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Technical Assistance
Feature Information for MPLS Traffic Engineering-Autotunnel Primary and Backup
Table 1 lists the release history for this feature.
Not all commands may be available in your Cisco IOS software release. For release information about a specific command, see the command reference documentation.
Use Cisco Feature Navigator to find information about platform support and software image support. Cisco Feature Navigator enables you to determine which Cisco IOS and Catalyst OS software images support a specific software release, feature set, or platform. To access Cisco Feature Navigator, go to http://www.cisco.com/go/cfn. An account on Cisco.com is not required.
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Glossary
backup tunnel—An MPLS traffic engineering tunnel used to protect other (primary) tunnel's traffic when a link or node failure occurs.
egress router—A router at the edge of the network where packets are leaving.
Fast Reroute—Fast Reroute (FRR) is a mechanism for protecting MPLS traffic engineering (TE) LSPs from link and node failure by locally repairing the LSPs at the point of failure, allowing data to continue to flow on them while their headend routers attempt to establish end-to-end LSPs to replace them. FRR locally repairs the protected LSPs by rerouting them over backup tunnels that bypass failed links or nodes.
hop—Passage of a data packet between two network nodes (for example, between two routers).
interface—A network connection.
IP address—A 32-bit address assigned to hosts using TCP/IP. An IP address belongs to one of five classes (A, B, C, D, or E) and is written as four octets separated by periods (dotted decimal format). Each address consists of a network number, an optional subnetwork number, and a host number. The network and subnetwork numbers together are used for routing, and the host number is used to address an individual host within the network or subnetwork. A subnet mask is used to extract network and subnetwork information from the IP address.
IP explicit path—A list of IP addresses, each representing a node or link in the explicit path.
LDP—Label Distribution Protocol. A standard protocol between MPLS-enabled routers to negotiate the labels (addresses) used to forward packets.
link—Point-to-point connection between adjacent nodes.
LSP—label switched path. A path that is followed by a labeled packet over several hops, starting at an ingress LSR and ending at an egress LSR.
LSR—label switch router. A Layer 3 router that forwards a packet based on the value of a label encapsulated in the packet.
MPLS—Multiprotocol Label Switching. A method for forwarding packets (frames) through a network. It enables routers at the edge of a network to apply labels to packets. ATM switches or existing routers in the network core can switch packets according to the labels with minimal lookup overhead.
node—Endpoint of a network connection or a junction common to two or more lines in a network. Nodes can be interconnected by links, and serve as control points in the network.
penultimate router—The second-to-last router; that is, the router that is immediately before the egress router.
primary tunnel—An MPLS tunnel whose LSP can be fast rerouted if there is a failure.
router—A network layer device that uses one or more metrics to determine the optimal path along which network traffic should be forwarded. Routers forward packets from one network to another based on network layer information.
router ID—Something by which a router originating a packet can be uniquely distinguished from all other routers. For example, an IP address from one of the router's interfaces.
scalability—An indicator showing how quickly some measure of resource usage increases as a network gets larger.
traffic engineering—The techniques and processes used to cause routed traffic to travel through the network on a path other than the one that would have been chosen if standard routing methods had been used.
tunnel—A secure communication path between two peers, such as two routers. A traffic engineering tunnel is a label-switched tunnel that is used for traffic engineering. Such a tunnel is set up through means other than normal Layer 3 routing; it is used to direct traffic over a path different from the one that Layer 3 routing could cause the tunnel to take.
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Any Internet Protocol (IP) addresses used in this document are not intended to be actual addresses. Any examples, command display output, and figures included in the document are shown for illustrative purposes only. Any use of actual IP addresses in illustrative content is unintentional and coincidental.
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