Cisco Systems A9014CFD manual Introduction, Performance Features

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Chapter 1 Cisco ASR 901 Router Overview

Introduction

Introduction

A RAN is typically composed of thousands of BTSs or Node Bs, hundreds of base station controllers or radio network controllers (BSCs or RNCs), and several mobile switching centers (MSCs). The BTS or Node Bs and BSC or RNC are often separated by large geographic distances, with the BTSs or Node Bs located in cell sites uniformly distributed throughout a region, and the BSCs, RNCs, and MSCs located at suitably chosen Central Offices (CO) or mobile telephone switching offices (MTSO).

The traffic generated by a BTS or Node B is transported to the corresponding BSC or RNC across a network, referred to as the backhaul network, which is often a hub-and-spoke topology with hundreds of BTS or Node Bs connected to a BSC or RNC by point-to-point time division multiplexing (TDM) trunks. These TDM trunks may be leased-line T1/E1s or their logical equivalents, such as microwave links or satellite channels.

The Cisco ASR 901 has two different types of interfaces by default: network node interfaces (NNIs) to connect to the service provider network and user network interfaces (UNIs) to connect to customer networks. Some features are supported only on one of these port types. You can also configure enhanced network interfaces (ENIs). An ENI is typically a user-network facing interface and has the same default configuration and functionality as UNIs, but can be configured to support protocol control packets for Cisco Discovery Protocol (CDP), Spanning-Tree Protocol (STP), EtherChannel Link Aggregation Control Protocol (LACP).

Features

This section contains the following topics:

Performance Features, page 1-2

Management Options, page 1-3

Manageability Features, page 1-3

Security Features, page 1-4

Quality of Service and Class of Service Features, page 1-4

Layer 3 Features, page 1-5

Layer 3 VPN Services, page 1-5

Monitoring Features, page 1-5

Performance Features

Autosensing of port speed and autonegotiation of duplex mode on all ports for optimizing bandwidth.

Automatic-medium-dependent interface crossover (auto-MDIX) capability on 100 and 100/1000 Mbps interfaces and on 100/1000 BASE-T/TX small form-factor pluggable (SFP) module interfaces that enables the interface to automatically detect the required cable connection type (straight-through or crossover) and to configure the connection appropriately.

EtherChannel for enhanced fault tolerance and for providing up to 8 Gbps (Gigabit EtherChannel) or 800 Mbps (Fast EtherChannel) full duplex of bandwidth between switches, routers, and servers.

Link Aggregation Control Protocol (LACP) for automatic creation of EtherChannel links (supported only on NNIs or ENIs).

Cisco ASR 901 Series Aggregation Services Router Software Configuration Guide

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OL-23826-09

 

 

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Contents Americas Headquarters Text Part Number OL-23826-09Copyright 2011-2013, Cisco Systems, Inc N T E N T S IiiRelated Documents Standards MIBs Standards MIBs Searching and Filtering Output of show and more Commands Split-Horizon8-6 ViiRestrictions ViiiManually Configuring an IP SLA CFM Probe or Jitter Operation Restrictions Overview Setting up Manual Preemption for Vlan Load Balancing XiiConfiguring Mpls VPNs XiiiXiv 19-6Verifying Local Switching Verifying the Synchronous Ethernet configuration XviCisco IOS IP SLA XviiMarking XviiiXix Technical Assistance Configuring Hsrp XxiConfiguring Link Layer Discovery Protocol XxiiHow to Configure Bert XxiiiXxiv 32-2Configuring IPv6 Duplicate Address Detection XxvTroubleshooting Tips BFD XxviiVerifying Layer 2 Tunneling XxviiiConfiguring Unspecified Bit Rate XxixCreating IPv6 VRFs on PE Routers XxxTechnical Assistance XxxiFinding Feature Information XxxiiIgmp XxxiiiIPv6 Multicast Groups XxxivSpan Traffic XxxvXxxvi About This Guide Document Revision HistoryDocument Number Date Change Summary Xxxviii Xxxix OL-23826-09 Xli Xlii Xliii Xliv Xlv Xlvi Organization ObjectivesAudience XlviiMpls OAM XlviiiSLA XlixConvention Description ConventionsChapter Description Boldface fontTo access the related documentation on Cisco.com, go to Related DocumentationRelease Notes Lii Cisco ASR 901 Router Overview Introduction FeaturesPerformance Features This section contains the following topicsManageability Features Management OptionsSecurity Features Quality of Service and Class of Service FeaturesLayer 3 Features Layer 3 VPN ServicesMonitoring Features OL-23826-09 Finding Feature Information ContentsLicensing Following licenses are supported Feature OverviewLicenses Supported on Cisco ASR 901 Router License Sl.No Chassis PID License PID DescriptionLicensing Licenses Supported on Cisco ASR 901 Router License Features Feature Based LicenseFeatures Supported License Types1588BC License Port or Interface BehaviorPort Based/Mode License Port Number Port Type Chassis PID License RequiredPort Based License Example When Port Based License is not InstalledExample When Port Based License is Installed Router# show ip interface briefRouterconfig# interface gig 0/0 10gigUpgrade LicenseExample When 10gigUpgrade License is not Installed Router# show interface Ten0/1Following is a sample output from the show license command Example When 10gigUpgrade License is InstalledExample When Flexi License is not Installed Flexi LicenseExample When 1588BC License is Installed Example When Flexi License is InstalledExample When 1588BC License is not Installed Following example shows how to install the 1588BC licenseRemoving the 1588BC License Use the license clear command to remove the 1588BC licenseRouterconfig-ptp-clk#no ptp clock boundary domain Router# license clear 1588BCLicense install license-file-name Installing the LicenseEnable License install Copy tftp flash Show flash Generating the LicenseCommand Purpose Changing the LicenseExample Example RMA Process Return Materials Authorization License ProcessRouter# license install ? Router# copy tftp flashWhere to Go Next To verify the new license, use the show license commandRFCs StandardsMIBs StandardTechnical Assistance Description LinkFeature Information for Licensing Feature Name Releases Feature InformationOL-23826-09 First-Time Configuration Setup ModeBefore Starting Your Router Using Setup Mode Configuring Global ParametersEnter a hostname for the router this example uses Completing the Configuration Configuring the Hostname and Password Password prompt appears. Enter your passwordVerifying the Cisco IOS Software Version Router# configure terminal Verifying the Hostname and PasswordExit back to global configuration mode Router# show configManaging and Monitoring Network Management Features Network Management Features for the ASR This section contains the following proceduresEnter your password if prompted Configuring Snmp SupportEnables privileged Exec mode Enters global configuration modeProtocol Form of this command removes the specified community stringString-Community string is the password to access the Snmp View view-name-Optional Previously defined view. The viewEnvmon voltage shutdown supply fan temperature -When CommandNotification-type -snmp authentication -Enables RFC TemperatureSnmp-server host command Command Purpose Enable Configure terminal Configuring Remote Network ManagementExits global configuration mode Interface loopback numberCommand or Action Purpose Zero-Touch Deployment Image Download Zero-touch DeploymentSpecifies to exclude IP address of the Dhcp server Configuring a Dhcp ServerNetwork ip-address subnet-mask Ip dhcpConfiguring a Tftp Server Creating a Bootstrap ConfigurationConfiguring the Cisco Configuration Engine Enabling a Tftp Server on the Edge RouterExample Configuring Remote Network Management Configuration ExamplesExample Configuring Snmp Support Example Configuring a Dhcp ServerRelated Documents Additional ReferencesExample Zero-touch Deployment Related Topic Document TitleMIBs Network Management Features for the ASR Using the Command-Line Interface Understanding Command ModesExit, or logout Entered. Use a passwordUser Exec Log Use the interfaceCtrl-Z or enter end Understanding the Help SystemLine console HelpUnderstanding CLI Error Messages Understanding Abbreviated CommandsUnderstanding no and default Forms of Commands Router# show confError Message Meaning How to Get Help Using Command HistoryChanging the Command History Buffer Size Range is from 0 toDisabling the Command History Feature Using Editing FeaturesRecalling Commands Enabling and Disabling Editing FeaturesPress Ctrl-Y Editing Commands through KeystrokesCapability Keystroke1 Purpose Backspace keyReturn and Space bar Editing Command Lines that WrapPress Ctrl-V or Esc Q Press Ctrl-L or Ctrl-RAccessing the CLI Command begin include exclude regular-expressionRouter# show interfaces include protocol Saving Configuration Changes Software Upgrade Selecting a Cisco IOS ImageUpgrading the Cisco IOS image Copy the IOS Image from the Tftp server If the right steps are not followed properlyRouter# show file system Verify the Cisco IOS image in the file system Save the configuration and reload the routerVerify the Cisco IOS upgrade Router# verify flashasr901-universalk9-mz.151-2.SNGAuto Upgrading the MCU Router# show versionManually Upgrading the Rommon Auto Upgrade of Rommon Rommon AUTOUPGRADEROMMON=TRUE FalseRouter# upgrade rom-monitor internal To configure the GE interface, complete the following steps Configuring Gigabit Ethernet InterfacesConfiguring the Interface Enters enable modeSetting the Speed and Duplex Mode Cdp enableGigabitethernet 0/1 Enabling the Interface Modifying MTU Size on the InterfaceMtu bytes No mtu or default mtu command Verifying the MTU SizeMAC Flap Control Configuring MAC FLap ControlComplete the following steps to configure MAC Flap control Restrictions and LimitationsMac-flap-ctrl on per-mac mac-movement Configuring a Combo PortRestrictions Time-intervalAuto-select-Specifies dynamic selection Configures the media typeExits interface configuration mode and enters Physical connectionVerifying the Media Type Router# show interface gigabitethernet 0/1Router# show interface gigabitethernet 0/7 Configuring Ethernet Virtual Connections Supported EVC Features Understanding EVC Features Service Instances and EFPsEthernet Virtual Connections Encapsulation Configures default encapsulation Bridge DomainsTo the appropriate EFP Dhcp Client on Switch Virtual Interface Split-HorizonRewrite Operations Configuring EFPs Default EVC ConfigurationConfiguration Guidelines Creating Service Instances Show ethernet service instance Service instance number ethernet nameDefault Copy running-config startup-configExample Encapsulation Using a Vlan Range Configuration Examples of Supported FeaturesExample Configuring a Service Instance Example Bridge Domains and Vlan EncapsulationExample Rewrite Router config-if-srv#rewrite ingress tag pop 1 symmetricRouter config-if-srv#rewrite ingress pop 1 symmetric Example Split HorizonConfiguration Examples of Unsupported Features Example FilteringExample Overlapping Encapsulation How to Configure EVC Default Encapsulation Configuring EVC Default Encapsulation with Bridge-DomainInterface type number Configuring EVC Default Encapsulation with Xconnect Configures the default service instanceAn identifier Verifying EVC Default Encapsulation with Bridge-Domain Configuration Examples for EVC Default Encapsulation Configuring Other Features on EFPsVerifying EVC Default Encapsulation with Xconnect Example Configuring EVC Default Encapsulation with XconnectEFPs and EtherChannels MAC Address Forwarding, Learning and Aging on EFPsNo mac-address-table learning vlan vlan-id Interface type slot/portAddresses learned on a particular VLAN/BD End Return to privileged Exec modeRouterconfig# no mac-address-table learning vlan Router# show mac-address-tableRouter# show mac-address-table interface 0/9 Configuring Ieee 802.1Q Tunneling using EFPs802.1Q Tunneling QinQ Router# show mac-address-table interface port-channel1shows the tag structures of the double-tagged packets Configuration Examples You can use EFPs to configure 802.1Q tunneling in two waysConfiguration Example Cisco ASR 901 router supports pop 2 configurationRouted QinQ Example Configuring Bridge-Domain Routing Bridge Domain RoutingConfigures the Vlan interface and enters interface How to Configure Dhcp Client on SVIConfiguring Dhcp Client on SVI Interface type-numberConfiguration Example for Dhcp Client on SVI Verifying Dhcp Client on SVIEFPs and Switchport MAC Addresses EFPs and MstpCommand Description Monitoring EVCSample Configuration with Switchport to EVC Mapping Configuration Example Line vty 0 4 login Additional References Supported EVC Features OL-23826-09 Configuring EtherChannels EtherChannel Feature OverviewUnderstanding How EtherChannels Work Understanding Manual EtherChannel Configuration Understanding How EtherChannels Are ConfiguredEtherChannel Configuration Overview Understanding Ieee 802.3ad Lacp EtherChannel ConfigurationActive mode Passive mode Passive modePassive mode Active mode Router a Router B ResultEtherChannel Configuration Guidelines and Restrictions Understanding Port-Channel InterfacesUnderstanding Load Balancing Configuring Etherchannels Configuring Channel GroupsConfiguring the Lacp System Priority and System ID Configuration examples for Lacp system priorityConfiguring the Lacp Transmit Rate Lacp rate fast normal EndConfiguring EtherChannel Load Balancing Configuration ExamplesVerifying the Lacp Transmit Rate Enable Configure terminal Interface port-channel number Modifying MTU Size on Port-ChannelVerifying the MTU Size on Port-Channel EVC On Port-Channel Restrictions for EVC EtherChannelRouter# show ethernet service evc id evc-idinterface Configuring EVC on Port-ChannelVerifying the Configuration Router# show ethernet service instance interfaceTroubleshooting Problem SolutionConfiguring Ethernet OAM ContentsIP SLA Support for CFM Configuring Ethernet CFMUnderstanding Ethernet CFM 10-2Configuring the CFM Domain Default Ethernet CFM ConfigurationEthernet CFM Configuration Restrictions and Guidelines Configure terminal Enter global configuration mode10-4 Is 2 to 255 the default is Second, 10 seconds, 1 minute and 10 minutes. The defaultWe do not recommend configuring a large number Optional Configure the maximum number of MEPsExample for Basic CFM configuration 10-6Exit Configuring Multi-UNI CFM MEPs in the Same VPNRestrictions 10-7Cfm mep domain domain-name mpid identifier 10-8Alias alias-short-ma-name icc icc-code meg-id Number ma-number vlan-id vlan-id vpn-id vpn-id10-9 10-10 10-11 Configuring Ethernet CFM Crosscheck 10-12Static Configuring Static Remote MEPContinuity-check static rmep 10-13Configuring a Port MEP Service ma-name ma-number vpn-id port10-14 Configuring Snmp Traps 10-15Ethernet jitter mpid identifier domain domain-name Configuring IP SLA CFM OperationEthernet echo mpid identifier domain domain-name 10-16Seconds to keep the operation in memory when it is not Repeats. The range is from 1 to 604800 seconds the defaultAllowed by the protocol being used the default is 66 bytes Seconds. The default is 0 seconds10-18 Configuring CFM over EFP with Cross Connect Show the configured IP SLA operation10-19 Configuring CFM over EFP Interface with Cross Connect 10-20Example for untagged Encapsulation 10-21Example for single tag Encapsulation 10-2210-23 Configuring CFM with EVC Default Encapsulation Cfm mep domain domain-name mpid mpid-value10-24 Verifying CFM with EVC Default Encapsulation 10-25Default Y.1731 Configuration Configuring Y.1731 Fault ManagementExample Configuring CFM with EVC Default Encapsulation 10-26Configuring ETH-AIS 10-27Show ethernet cfm smep interface interface-id Configuring ETH-LCKShow ethernet cfm error Ethernet cfm lck link-status global10-29 Managing and Displaying Ethernet CFM Information 10-31 Understanding the Ethernet OAM Protocol 10-32Benefits of Ethernet OAM OAM FeaturesFollowing OAM features are defined by Ieee 802.3ah 10-33Link Monitoring 10-34Setting Up and Configuring Ethernet OAM This section includes the following topics10-35 Enabling Ethernet OAM on an Interface Default Ethernet OAM ConfigurationRestrictions and Guidelines Ethernet oamShow ethernet oam status interface interface-id Ms mode active passive timeout secondsEthernet oam max-rate oampdus min-rate seconds 10-37Configuring Ethernet OAM Link Monitoring Enabling Ethernet OAM Remote Loopback10-38 10-39 Ethernet oam link-monitor frame-seconds Ethernet oam link-monitor frame-periodThreshold high high-frames none low 10-40No ethernet link-monitor on Configuring Ethernet OAM Remote Failure IndicationsEthernet oam link-monitor receive-crc threshold 10-41Error-disable-interface Configuring Ethernet OAM TemplatesDying-gasp link-fault action Ethernet oam remote-failure critical-event10-43 Ethernet oam link-monitor high threshold action Threshold high high-seconds none lowLow-seconds window milliseconds Source-template template-nameShow ethernet oam statistics interface interface-id Displaying Ethernet OAM Protocol InformationShow ethernet oam discovery interface interface-id Show ethernet oam summaryVerifying an OAM Session Verifying Ethernet OAM ConfigurationVerifying Information Oampdu and Fault Statistics Verifying OAM Discovery StatusVerifying Link Monitoring Configuration and Status 10-4710-48 Understanding E-LMIVerifying Status of the Remote OAM Client ActiveRestrictions Configuring E-LMIDefault E-LMI Configuration 10-49Enabling E-LMI 10-50Displaying E-LMI Information Configuring Ethernet LoopbackUnderstanding Ethernet Loopback 10-51Enabling Ethernet Loopback 10-5210-53 10-54 10-55 Configuring Y.1564 to Generate Ethernet Traffic 10-56Internal Mode 10-57Specify the SLA ID to start the IP SLA session Configuring IP SLA for Traffic GenerationRouterconfig# ip sla 10-58Measurement-type direction -Specifies the statistics 10-5910-60 Example Two-Way Measurement 10-6110-62 ITU-T Y.1731 Performance Monitoring Prerequisites for ITU-T Y.1731 Performance Monitoring11-1 Restrictions for ITU-T Y.1731 Performance Monitoring Information About ITU-T Y.1731 Performance Monitoring11-2 Frame Delay and Frame-Delay Variation Two-way Delay Measurement11-3 Single-ended ETH-SLM Frame Loss RatioOn-Demand and Concurrent Operations 11-4Supported interfaces How to Configure ITU-T Y.1731 Performance MonitoringBenefits of ITU-T Y.1731 Performance Monitoring 11-5Configuring Two-Way Delay Measurement Max-delaymilliseconds Owner owner-id11-6 Mac-address target-address -Specifies Mac-address source-address -Specifies11-7 Boundary ,...,boundary -Lists upper 11-8Configuring Single-Ended Synthetic Loss Measurement Enable Configure terminal Asr901-platf-multi-nni-cfm11-9 11-10 Mac-addresstarget-address-Specifies Mac-addresssource-address-Specifies11-11 Exits IP SLA configuration mode and enters global Exits IP SLA Y.1731 loss configuration modeEnters IP SLA configuration mode Owner-id-Specified the name of the SnmpNumber-of-measurements argument. The range is Threshold-type averageNumber-of-measurements -Optional When Threshold-type consecutivePrerequisites Threshold-type immediate -Optional When aScheduling IP SLAs Operations Threshold-value upper-thresholdRange of operation numbers to be scheduled for a Individual IP SLAs operationSpecifies an IP SLAs operation group number Multi-operation schedulerRouter# show ip sla configuration 11-16Router-1#show running interface gigabitethernet0/0 Router# show ethernet cfm pm session summary Example Verifying Ethernet CFM Performance Monitoring11-17 Router# show ethernet cfm pm session detailExample Verifying History for IP SLAs Operations 11-18Router# show ip sla history interval-statistics Configuring Direct On-Demand Operation on a Sender MEP 11-19Configuring Referenced On-Demand Operation on a Sender MEP 11-20Example On-Demand Operation in Direct Mode 11-21Example On-Demand Operation in Referenced Mode 11-22Router# ip sla on-demand ethernet slm 2002 duration Following URL Releases, and feature sets, use Cisco MIB Locator found atIeee 802.1ag ITU-T Y.1731 MEF 11-2311-24 Feature Name Releases Feature Information 11-2511-26 Overview Configuring Resilient Ethernet ProtocolUnderstanding Resilient Ethernet Protocol REP 12-112-2 REP Open Segments12-3 No-neighbor TopologyVlan Load Balancing VLB Link IntegrityFast Convergence 12-412-5 Neighbor Offset Numbers in a SegmentREP Ports 12-6REP Configuration Guidelines Configuring Resilient Ethernet Protocol REPDefault REP Configuration 12-712-8 Configuring the REP Administrative Vlan 12-9Configuring REP Interfaces 12-10Enter the physical Layer 2 interface or port channel ID. Routerconfig# interface Gigabitethernet0/1Service instance instance-id Port-channel range is 1 to12-12 12-13 Verifies the REP interface configuration File12-14 Configuring REP as Dual Edge No-Neighbor Port 12-1512-16 Rep segment segment-id edge no-neighbor Primary preferred12-17 Cisco ASR 901 Dual Rep Edge No-Neighbor Topology Example 7600112-18 76002 12-19Setting up Manual Preemption for Vlan Load Balancing 12-20Configuring Snmp Traps for REP 12-21Trap-rate command Monitoring REP12-22 12-23 Configuring a REP Interface Example Configuration Examples for REPConfiguring the REP Administrative Vlan Example This section contains the following examplesMonitoring the REP Configuration Example Setting up the Preemption for Vlan Load Balancing ExampleConfiguring Snmp Traps for REP Example 12-25Cisco ASR 901 Topology Example 12-26ASR2 12-2712-28 12-29 12-30 Configuring MST on EVC Bridge Domain Overview of MST and STP13-1 Overview of MST on EVC Bridge Domain Restrictions and Guidelines13-2 13-3 MST0Configuring MST on EVC Bridge Domain 13-4Specifies the gigabit ethernet interface to configure Slot/port-Specifies the location of the interface13-5 Configuration Example for MST on EVC Bridge Domain Verification13-6 13-7 Router# show spanning-tree vlanThis example shows MST on port channels 13-8Router# show spanning-tree mst Troubleshooting Tips 13-913-10 Configuring Multiprotocol Label Switching 14-114-2 Configuring EoMPLS Understanding EoMPLS15-1 Configuring EoMPLS 15-2EoMPLS Configuration Example 15-3Specifies an interface to configure Configuring Pseudowire RedundancyConfiguration Commands Configures encapsulation type for the service instanceShow mpls l2t vc id Configure terminal Enters global configuration mode ExamplePort Based EoMPLS 15-5Routerconfig# xconnect Encapsulation mpls 15-6Configuring Mpls VPNs Understanding Mpls VPNs16-1 PE1 Configuration Configuring Mpls VPNsConfiguration Examples for Mpls VPN 16-2Configuring Mpls VPNs Configuration Examples for Mpls VPN 16-316-4 Provider Configuration 16-5PE2 Configuration Interface details16-6 Ospf and BGP details 16-7Loop Back details 16-816-9 16-10 LSP Ping Configuring Mpls OAMUnderstanding Mpls OAM 17-1LSP Traceroute Configuring Mpls OAMLSP Ping over Pseudowire 17-2Using LSP Ping for Pseudowire Using LSP Ping for LDP IPv4 FECUsing LSP Traceroute for LDP IPv4 FEC Ping mpls ipv4Show mpls l2transport binding vcid Using LSP Traceroute over PseudowireDisplaying AToM Vccv capabilities Vc-id-valueAsr901-ecmp-hash-config global-type Configuring Routing ProtocolsChanging Default Hashing Algorithm for Ecmp 18-118-2 Configuring BFD Understanding BFD19-1 Configuring BFD for Ospf on One of More Interfaces BFD Configuration Guidelines and RestrictionsConfiguring BFD for Ospf Enables BFD for Ospf on the interfaceSpecifies the BFD session parameters Configuring BFD for Ospf on All InterfacesCreates a configuration for an Ospf process ProcessConfiguring BFD for IS-IS on a Single Interface Configuring BFD for BGPConfiguring BFD for IS-IS 19-4Configuring BFD for IS-IS for All Interfaces 19-5Configuring BFD for Static Routes 19-6BFD with Ospf on Individual Interfaces Configuration Examples for BFDBFD with Ospf on All Interfaces 19-7BFD with IS-IS on Individual Interfaces BFD with BGPBFD with IS-IS on All Interfaces 19-8BFD with Static Routes 19-919-10 Configuring T1/E1 Controllers Configuring the Card Type20-1 Configuring E1 Controllers Subslot20-2 Channel-group channel-no timeslots timeslot-list 64 command 20-3Configuring T1 Controllers 20-4Troubleshooting Controllers Troubleshooting E1 Controllers20-5 Receiver Troubleshooting T1 ControllersPayload loopback mode of the framer. The framer re-clocks Incoming trafficPath to the receiver path 20-7Local line 20-8 Configuring Pseudowire 21-1Understanding Pseudowires Structure-Agnostic TDM over Packet21-2 Limitations Hot Standby Pseudowire Support for ATM/IMATransportation of Service Using Ethernet over Mpls 21-3Xconnect ip pw-class pseudowire-class Configuring PseudowireConfiguring Pseudowire Classes Cem group-number21-5 Cem group-number Cem class cem-class-name Configuring CEM ClassesClass cem cem-class-name Xconnect ip-addressencapsulation mpls21-7 Specifies the CEM class name Configuring a Backup PeerEnable Configure terminal Interface cemslot/port Xconnect peer-loopback-ip-addressencapsulation mplsConfiguring Structure-Agnostic TDM over Packet Xconnect ip-addressencapsulation mpls Exit21-9 30.30.30.2 255.255.255.255 21-10Xconnect peer-router-id vcid pseudowire-class name Configuring a SAToP Pseudowire with UDP EncapsulationPseudowire-classpseudowire-class-name Udp port local-udp-port remote remote-udp-port21-12 Remote peer Values for SAToP pseudowires using UDP are fromExits the configuration mode Exits the CEM interfaceExit Interface CEMslot/port Enable Configure terminal Controller e1 t1 slot/portCem-groupgroup-number timeslots timeslot Xconnect ip-addressencapsulation mpls Exit EndDefines a CEM channel Configuring a CESoPSN Pseudowire with UDP EncapsulationExits configuration mode Recommend that you build a route from the xconnect addressExits pseudowire-class configuration mode Udp port local localudpport remote remoteudpport21-16 21-17 QoS for CESoPSN over UDP and SAToP over UDP 21-1821-19 Service instance instance-numberAlthough the symmetric keyword appears to be optional, you Xconnect ip-addressencapsulationCreates a CEM interface and assigns it a CEM group number Configuring L2VPN Pseudowire RedundancySelects an E1 or T1 controller 21-2021-21 Backup peer peer-router-ip-addr vcid Configuring ATM/IMA Pseudowire Redundancy in PVC ModeExample Pseudowire Redundancy Interface interface-name21-23 Vpi-ATM network virtual path identifier VPI of the VC to Configuring ATM/IMA Pseudowire Redundancy in PVP ModeOr more virtual circuits VCs Multiplex on the permanent virtual pathConfiguring ATM/IMA Pseudowire Redundancy in Port Mode Transport over Mpls AToM static pseudowire21-25 21-26 Verifying Hot Standby Pseudowire Support for ATM/IMAPeer-router-ip-addr-IP address of the remote peer router Router# show mpls l2transport vcTDM Local Switching 21-27Configuring TDM Local Switching on a T1/E1 Mode 21-28Configuration Example for Local Switching Verifying Local Switching21-29 ATM/IMA 21-30Configuration Examples for Pseudowire Example TDM over Mpls Configuration-Example21-31 21-32 Asrb 21-33Following configuration uses CESoSPN with UDP encapsulation Example CESoPSN with UDP21-34 Example Ethernet over Mpls 21-3521-36 Feature Information for Configuring Pseudowire 21-3721-38 Configuring Clocking Restrictions22-1 Configuring Network Clock for Cisco ASR 901 Router 22-2Configuring Network Clock in Global Configuration Mode 22-322-4 Example for GPS interface 22-5Configuring Network Clock in Interface Configuration Mode 22-6Ethernet Synchronization Messaging Channel Understanding SSM and EsmcSynchronization Status Message Clock Selection AlgorithmEsmc behavior for Port Channels Configuring Esmc in Global Configuration ModeQL-disabled mode Esmc behavior for STP Blocked PortsConfiguring Esmc in Interface Configuration Mode 22-9Verifying Esmc Configuration Show esmc22-10 22-11 Managing SynchronizationShow network-clock synchronization Router#show esmc interface gigabitEthernet 0/10Synchronization Example 22-12Configures synchronous ethernet copper port as slave Configuring Synchronous Ethernet for Copper PortsVerifying the Synchronous Ethernet configuration Configures synchronous ethernet copper port as master22-14 22-15 Shown in this example Troubleshooting TipsSynchronization detail RP command to confirm 22-16Troubleshooting Esmc Configuration 22-17Configuring PTP for the Cisco ASR 901 Router 22-18Configuring Master Ordinary Clock Setting System Time to Current TimeConfiguring PTP Ordinary Clock 22-19Priority1 priority-value Priority2 priority-value 22-20Configuring Slave Ordinary Clock 22-21Clock source source-address 22-2222-23 22-24 Port Name Configuring PTP in Unicast ModeConfiguring PTP in Unicast Negotiation Mode Port RolePTP Boundary Clock Configures Cisco ASR 901 router on unicastConfigured with this command Negotiation mode. The following options can beConfiguring PTP Boundary Clock Clock-port port-namemaster22-27 22-28 Ordinary Clock Exits clock port configuration modeVerifying PTP modes 22-2922-30 Router# show ptp clock dataset defaultBoundary Clock Router# show ptp clock dataset time-properties domainVerifying PTP Configuration on the 1588V2 Slave 22-31Router# show ptp clock runn dom 22-32 Verifying PTP Configuration on the 1588V2 MasterTypical configuration on a 1588V2 master is Router# show ptp clock running domain22-33 Configuring a Hybrid Ordinary Clock PTP Hybrid Clock22-34 That the output of the clock is transmitted to the remote Hybrid-Optional Enables the PTP boundary clockTo work in hybrid mode. Enables the hybrid clock such Slaves22-36 Configuring a Hybrid Boundary Clock 22-37Router# show running-config section ptp Verifying Hybrid modes22-38 SSM and PTP Interaction 22-39Router#show platform ptp channelstatus Telecom Profiles ClockClass MappingPTP Redundancy 22-40End Configuring Telecom Profile in Slave Ordinary ClockClock source source-address priority 22-4122-42 Configuring Telecom Profile in Master Ordinary Clock 22-4322-44 Verifying Telecom profileTiming packets with a PTP slave devices Router#show ptp port running detail22-45 Router#show ptp clock running domainASR901 Negotiation Mechanism Setting the TimePropertiesStatic Unicast Mode 22-46Configuring ToD on 1588V2 Slave 22-4722-48 Configuring Ipsla Path Discovery Cisco IOS IP SLA23-1 Configuration Parameters 23-2Example for Ipsla Path Discovery 23-3This example shows the LPD parameter values configured 23-4Router#show ip sla mpls-lsp-monitor neighbors Two-Way Active Measurement Protocol 23-5Configuring Twamp 23-6Port port-number Configuring the Twamp ServerEnable Configure terminal Ip sla server twamp 23-7Configures the switch as a Twamp responder, and enter Twamp Configuring the Twamp ReflectorConfiguration Examples for Twamp 23-8Routerconfig# ip sla server twamp Example Configuring the Router as an IP SLA Twamp serverExample Configuring the Router as an IP SLA Twamp Reflector Routerconfig# ip sla responder twamp23-10 Configuring QoS 24-1Understanding QoS 24-2Default QoS for Traffic from External Ethernet Ports Default QoS for Traffic from Internal Ports24-3 Modular QoS CLI 24-4Input and Output Policies Input Policy Maps24-5 Access Control Lists Output Policy Maps24-6 Classification 24-7Match Command Class Maps24-8 Classification Based on IP Dscp Classification Based on Layer 2 CoSClassification Based on IP Precedence 24-9Per-hop Decimal Precedence CoS Classification ComparisonsThis display shows the available classification options 24-10Classification Based on QoS Groups Traffic Type Per-hop Decimal Precedence CoS24-11 Classification Based on Vlan IDs 24-12Table Maps 24-13Policing 24-14Individual Policing Gigabitethernet port24-15 Unconditional Priority Policing 24-16Egress Policing Configuration ExampleRouterconfig# policy-map policy1 24-17Routerconfig# policy-map Example Marking24-18 Congestion Management and Scheduling Traffic Shaping24-19 Routerconfig-pmap-c#service-policy out-policy Routerconfig# policy-map out-policyRouterconfig# policy-map out-policy-parent 24-20Routerconfig# policy-map parent Class-Based Weighted Fair QueuingThis is an example of a parent-child configuration 24-21Routerconfig-pmap-c#bandwidth remaining percent 24-22Priority Queuing 24-23Ingress QoS Functions Routerconfig# policy-map pmapbckboneIngress and Egress QoS Functions 24-24Egress QoS Functions Configuring Quality of Service QoSQoS Limitations 24-25General QoS Limitations Statistics Limitations24-26 GigabitEthernet Propagation LimitationsClassification Limitations ValueMarking Limitations 24-28Queuing Limitations Congestion Management LimitationsPrecedence Prec-transmit Qos-group Rate Limiting LimitationsShaping Limitations ACL-based QoS RestrictionsPolicing with 24-30Tcam with QoS Improving Feature ScalabilityQoS for MPLS/IP over Mlppp QoS for CPU Generated TrafficQoS Configuration Guidelines 24-32Sample QoS Configuration 24-33Creating a Class Map for Classifying Network Traffic Configuring ClassificationEnter the password 24-3424-35 Attaching the Policy Map to an Interface 24-36Attaching Policy Map to Cross Connect EVC 24-37Configuring Marking 24-38Creating a Class Map for Marking Network Traffic 24-39Set dscp Traffic Attributes Network Layer ProtocolSet cos Set qos-groupSpecify an encapsulation type for the EVC Configuring Mpls Exp Bit Marking using a PseudowireSpecify an EVC 24-41Use the policy-mapcommand to define a policy map Configuring Congestion ManagementConfiguring Low Latency Queueing LLQ 24-42Configuring Multiple Priority Queueing Policy-map interface commands to verify your configuration24-43 24-44 Use the exit command to exit the policy map configuration Configuring Class-Based Weighted Fair Queuing CbfqUse the exit command to exit class map configuration 24-45This step is optional Weighted Random Early Detection WredAmount of bandwidth 24-46No random-detect discard-class value Configuring ShapingNo random-detect discard-class-based 24-47Configuring the Secondary-Level Child Policy Map 24-48Configuring Ethernet Trusted Mode Creating IP Extended ACLs24-49 Class-map-name Using Class Maps to Define a Traffic ClassClass-map match-all match-any 24-50Qos-group value vlan vlan-list Match cos cos-list ip dscp dscp-listIp precedence ip-precedence-list Show class-mapPermit source source-wildcard any log Creating a Named Access ListMatch access-group name access-group-name Class-mapclass-map-nameWhat to do Next 24-5324-54 Router# show ip access-lists tcam1Tcam with ACL Router# show run int gig 0/124-55 Verifying Named Access ListRouter# show access-lists tes456 Router# show policy-map interface gigabitethernet 0/0Configuration Example for Named Access List Router# show running-config24-56 24-57 Class-map match-any test24-58 24-59 24-60 24-61 QoS Treatment for IP-SLA Probes QoS Treatment for Performance-Monitoring ProtocolsCisco IP-SLAs QoS Marking for CPU-Generated TrafficQoS Queuing for CPU-Generated Traffic 24-63Extending QoS for Mlppp Configuring Class-map for Matching Mpls EXP BitsTo enter QoS class-map configuration mode Class in the policy mapConfiguring Class-map for Matching IP Dscp Value Match ip dscp dscp-value...dscp-value24-65 24-66 This configuration packets with IP Dscp of value af11 areDscp-value-The Dscp value used to identify a Dscp value Match ip dscpConfiguring a Policy-map 24-67Exampleclass Class class-defaultBandwidth percent bandwidth-percent Exit 24-68Dscp-value-The Dscp value used to identify a Dscp Value in the type of service ToS byteBits defined by the policy map 24-69Ip address address subnet mask Enable Configure terminal Interface multilink group-numberAttaching the Policy-map to Mlppp Interface 24-7024-71 Re-marking IP Dscp Values of CPU Generated Traffic 24-72Are 0 to Re-marking Mpls EXP Values of CPU Generated TrafficGenerated traffic 24-73Bandwidth percent bandwidth-percent Set ip dscp dscp-value Configuring a Policy-map to Match on CS5 and EXP4Class and enters QoS class-map configuration mode Class-map-name-The name used for class mapCs-value-The Class SelectorCS value Value in the type of service ToS byteAs a match criterion Class-map-name-Name of the class for the class mapConfiguring Class-map for Matching Mpls EXP Bits Exits QoS policy-map class configuration mode24-76 Following example shows a configuration of a policy-map Configuring Class-map for Matching IP Dscp ValueConfiguring a Policy-map 24-77Configuring a Policy-map to Match on CS5 and EXP Attaching the Policy-map to Mlppp Interface24-78 Verifying Mpls over Mlppp Configuration 24-7924-80 Troubleshooting Tips 24-8124-82 Example Tcam troubleshooting related error 24-83Routerconfig-if-srv#service-policy input policy2 24-84Entries used 256/256 no free entries available Entries used 195/256 after unconfiguring policy1 We now have enough free entries to configure policy2Routerconfig-if-srv#no service-policy input policy1 24-85Entries used 220/256 after configuring policy2 24-86Related Topic Document Title 24-87Feature Information for Configuring QoS 24-88Configuring Mlppp 25-1Distributed Multilink Point-to-Point Protocol Offload Mlppp Optimization FeaturesPrerequisites Mpls label protocol ldpMulticlass Mlppp Mpls over Mlppp25-3 Mpls Label imposition LER Mpls Label switching LSR 25-4Mpls over Mlppp on Core Links Mpls over Mlppp on CE to PE Links25-5 Configuring a Multilink Backhaul Interface Configuring Mlppp BackhaulConfiguring the Card Type, E1 and T1 Controllers Creating a Multilink BundleExample creates a multilink bundle Configuring MrruExample configures an IP address and subnet mask 25-7Configuring PFC and Acfc Remote apply, pfc local request, and pfc remote apply25-8 25-9 Acfc option are not accepted Configuration requestsRequests. The syntax is as follows 25-10Enabling Multilink and Identifying the Multilink Interface Keepalive period retries25-11 Ppp multilink group group-number 25-12Mlppp Offload Ppp multilink idle-link Ppp multilink queue depth25-13 Ppp multilink Ppp multilink group group-number Exit Configuring Mpls over the Mlppp on a Serial InterfaceConfiguring Additional Mlppp Settings 25-1425-15 25-16 Configuring Mpls over Mlppp for OspfNumber, and enters the interface configuration mode Interface multilink group-number25-17 Configuration Examples for Mpls over Mlppp 25-18Router# ping mpls ipv4 6.6.6.6/32 Verifying Mpls over Mlppp Configuration25-19 Router# show mpls ldp bindings 6.6.6.625-20 25-21 Feature Information for Mlppp 25-22Retrieval of the Obfl message Onboard Failure LoggingUnderstanding Obfl Recording Obfl MessagesConfiguring Obfl Verifying Obfl Configuration26-2 26-3 Clilog summary26-4 27-1 Overview of Hsrp and Vrrp Text AuthenticationInformation About Hsrp and Vrrp PreemptionComplete the following steps to configure Hsrp How to Configure HsrpConfiguring Hsrp Standby group-numberauthentication text string27-4 Example Configuring Hsrp Backup Router Configuration Examples for HsrpExample Configuring Hsrp Active Router 27-5Configuring Vrrp How to Configure VrrpExample Hsrp Text Authentication Interface type number Ip ip-address maskVrrp group-numberauthentication text string Vrrp group-numberpriority level27-7 Example Configuring a Vrrp Backup Router Configuration Examples for VrrpExample Configuring a Vrrp Master Router 27-8Example Vrrp Text Authentication 27-927-10 Feature Information for Hsrp and Vrrp 27-1127-12 Configuring Link Layer Discovery Protocol 28-1Restrictions for Lldp How to Configure LldpConfiguring Lldp Overview of Lldp28-3 Verifying Lldp Configuration Example for LldpExample Configuring Hold Time Example Enabling Lldp GloballyExample Configuring Delay Time Example Configuring Intervals28-5 28-6 28-7 Feature Information for Lldp 28-8Configuring Multihop Bidirectional Forwarding Detection 29-1Restrictions for Multihop BFD How to Configure Multihop BFDConfiguring Multihop BFD Template Information About Multihop BFD29-3 Example Configuring Multihop BFD Configuration Examples for Multihop BFDConfiguring a Multihop BFD Map Configuration for Router aInterface Fast Ethernet 0/1 Configuration for Router B29-5 Interface Fast Ethernet 6/029-6 Feature Information for Multihop BFD 29-729-8 Bit Error Rate Testing Prerequisites30-1 How to Configure Bert Bert Pattern Description30-2 Terminating Bert on a T1/E1 Controller Enable Configure terminal Controller t1 e1 slot/portPerforming Bert on a T1/E1 Line 30-3No bert pattern pattern interval time Routerconfig-controller# no bert patternVerifying Bert on a T1/E1 Controller 30-4Following is a sample configuration of the Bert feature 30-5Feature Information for Bit Error Rate Testing 30-630-7 30-8 Microwave ACM Signaling and EEM Integration 31-131-2 Benefits QoS Policy AdjustmentIGP Metric Adjustment Link RemovalConfiguring Connectivity Fault Management Bridge-domainbridge-domain-id31-4 31-5 31-6 Configuring EEP Applet Using CLIs 31-731-8 An EEM applet is triggered Configuring Event HandlerExits applet configuration mode 31-931-10 Following is a sample configuration of CFM Example Configuring CFMExample Configuring EEP Applet 31-1131-12 Action 104 set n $ringnodes31-13 Action 442 cli command isis metric $dlc 31-14Example Configuring Event Handler Following is a sample configuration of Event Handler31-15 Bandwidth Transport Integration with Microwave ACM Cisco ASR 901 Router CommandsCFM Support for Microwave Adaptive 31-1631-17 31-18 IPv6 Support on the Cisco ASR 901 Router 32-1Prerequisites for IPv6 Support on the Cisco ASR 901 Router 32-2IPv6 Address Formats BenefitsOverview of IPv6 32-3IPv6 Address Type Preferred Format Compressed Format Static ConfigurationIPv6 Addressing and Discovery 32-4Stateless Autoconfiguration ICMPv632-5 IPv4 and IPv6 Dual-Stack on an Interface IPv6 Duplicate Address DetectionIPv6 Neighbor Discovery 32-6IS-IS Enhancements for IPv6 Routing ProtocolsBidirectional Forwarding Detection for IPv6 OSPFv3 for IPv6Configuring IPv6 Addressing and Enabling IPv6 Routing QoS for IPv632-8 32-9 Enables the forwarding of IPv6 unicast datagrams Configuring a Static IPv6 RouteGlobal configuration mode Enables Cisco Express Forwarding CEF globally onIpv6 address autoconfig Enabling Stateless Auto-ConfigurationAdministrative-multicast-distance -Optional 32-11Ipv6 enable or Implementing IPv6 on Vlan Interfaces32-12 Implementing IPv6 Addressing on Loopback Interfaces 32-13Configuring ICMPv6 Rate Limiting Enable Configure terminal Ipv6 icmp error-interval interval32-14 Configuring IPv6 Duplicate Address Detection Ipv6 nd dad attempts value32-15 Configuring IPv6 Neighbor Discovery 32-16Configuring IPv6 and IPv4 Dual-Stack on the Same Vlan 32-17Configures IPv6 address on the interface Configuring OSPFv3 for IPv6Configures an IPv4 address on the interface Enables IPv6 address on the interfaceNet network-entity-tag Configuring IS-IS for IPv6Enable Configure terminal Router isis area-tag Ipv6 router isis area-name32-20 Configuring Multiprotocol-BGP for IPv6 32-21Configuring BFD for IPv6 Specifying a Static BFDv6 Neighbor32-22 Associating an IPv6 Static Route with a BFDv6 Neighbor Interface-number -SVI name32-23 32-24 Configuring BFDv6 and OSPFv3 32-25Configuring BFDv6 for BGP 32-26Implementing QoS for IPv6 Exits global configuration mode and enters privilegedExec mode Verifying IPv6 Addressing RoutingVerifying a Static IPv6 Route 32-28Router# show ipv6 route 32-29 Verifying a Stateless Auto-ConfigurationVerifying IPv6 Implementation on Vlan Interfaces Router# show ipv6 interface loopback32-30 Verifying ICMPv6 ConfigurationVerifying IPv6 Implementation on Loopback Interfaces Router# show ipv6 interface loopback032-31 Router# show ipv6 trafficVerifying IPv6 Duplicate Address Detection Configuration 32-3232-33 Verifying IPv6 Neighbor Discovery ConfigurationVerifying IPv6 and IPv4 Dual-Stack Configuration Router# show ipv6 neighbors detail32-34 Verifying OSPFv3 for IPv6 ConfigurationAs shown in the example Router# show ipv6 ospf32-35 Verifying IS-IS for IPv6 ConfigurationVerifying Multiprotocol-BGP for IPv6 Configuration Router# show isis ipv6 rib32-36 BGPVerifying BFD for IPv6 Configuration 32-37Router# show bfd neighbors Verifying BFDv6 and OSPFv3 Configuration 32-38Verifying BFDv6 for BGP Configuration 32-39Example IPv6 Addressing on Loopback Interfaces Example Configuring IPv6 Duplicate Address DetectionExample IPv6 Addressing on Vlan Interfaces Example Customizing ICMPv6Example Configuring the IPv4 and IPv6 Dual-Stack Example Configuring IPv6 Neighborhood DiscoveryExample Enabling IPv6 Stateless Address Autoconfiguration Example Configuring IPv6 Static RoutingExample Configuring BFD and OSPFv3 for IPv6 Example Configuring BFD and Static Routing for IPv6Example Configuring OSPFv3 for IPv6 Following is a sample configuration of OSPFv3 for IPv6Example Configuring IS-IS for IPv6 Following is a sample configuration of IS-IS for IPv632-43 Example Configuring Multiprotocol-BGP for IPv6 32-44Example Configuring BFD and Multiprotocol-BGP for IPv6 32-45Route advertisement messages. Also, define a No ipv6 nd suppress-ra command to enableDebug Commands Show Commands Platform Hardware Commands Valid prefix pool for IPv632-47 32-48 32-49 Chapter of the IPv6 Configuration Guide provide 32-50BGP for IPv6 chapter of the IPv6 Configuration Guide Aggregation Services Router Software Configuration Guide32-51 32-52 Labeled BGP Support 33-1VPN/VRF over RFC How to Configure Labeled BGP SupportOverview of Labeled BGP Support 33-2Configuration Example for Labeled Support Send-label option33-3 Router# show bgp ipv4 unicast labels Verifying Labeled BGP Support33-4 LabelsVpnv4 vrf LTE12 label 33-5Vpnv4 all label Router# show ip cef vrf LTE12 113.22.12.0 internal33-6 RFC-3107 Carrying Label Information in BGP-433-7 Feature Information for Labeled BGP Support 33-8Mpls Traffic Engineering Fast Reroute Link Protection 34-134-2 BFD-triggered Fast Reroute R2 R334-3 Fast Reroute Link Protection34-4 Enabling Mpls TE-FRR for EoMPLS on a Global Interface Enables Mpls TE tunnel signaling on the specified interfaceEnabling Mpls TE-FRR on an SVI Interface Mpls traffic-eng tunnelsPseudowire-class pw-class-name 34-6Enabling Mpls TE-FRR for EoMPLS on an Interface Xconnect peer-ip-address vc-id pw-classpw-class-name34-7 34-8 Enabling Mpls TE-FRR for IS-IS 34-934-10 Configuring Primary One-hop Auto-Tunnels 34-1134-12 Configuring Backup Auto-Tunnels 34-13Mpls ldp discovery targeted-hello accept command 34-14Messages from all neighbors Ip rsvp signalling hello bfdEnabling BFD Triggered FRR on an SVI Interface 34-15Enabling BFD Triggered FRR on a Router Configuration modeEnable Configure terminal Ip rsvp signalling hello bfd 34-1634-17 Verifying Mpls TE-FRR ConfigurationVerification Examples Router# show mpls traffic-eng tunnels brief34-18 Use the following command to verify the reservation detailRouter# show mpls traffic-eng tunnels backup Router# show mpls traffic-eng fast-reroute database34-19 Verifying Backup Auto-TunnelsVerifying Primary One-hop Auto-Tunnels Router# show ip rsvp fast-rerouteVerifying BFD Triggered FRR Configuration 34-2034-21 Database34-22 Router# show ip rsvp helloRouter# show ip rsvp hello bfd nbr 34-23Router# show ip rsvp interface detail Router# show ip rsvp hello bfd nbr detailExample Configuring Backup Auto-Tunnels Example Configuring Mpls TE-FRRExample Configuring Primary One-hop Auto-Tunnels Example Configuring BFD Triggered FRRMpls TE FRR 34-2534-26 34-27 34-28 Layer 2 Control Protocol Peering, Forwarding, and Tunneling 35-1Layer 2 Control Protocol Forwarding Layer 2 Control Protocol Tunneling35-2 35-3 L2protocol peer protocol Configuring Layer 2 PeeringDefault Action Configuration Option 35-4Configuring Layer 2 Forwarding 35-5Protocol-Specifies the protocol to be forwarded Routerconfig-if# l2proto-forward tagged CdpRouterconfig-if# service instance Ethernet 35-6Configuring Layer 2 Tunneling 35-7L2protocol tunnel protocol Bridge-domain bridge-id 35-8Verifying Layer 2 Tunneling Verifying Layer 2 PeeringVerifying Layer 2 Forwarding 35-9Following is a sample configuration of layer 2 peering Example Configuring Layer 2 PeeringExample Configuring Layer 2 Forwarding 35-10Example Configuring Layer 2 Tunneling 35-11Router 35-1235-13 Commands Cisco IOS LAN Switching Commands 35-14Following command was introduced l2proto-forward 35-1535-16 Configuring Inverse Muliplexing over ATM 36-1How to Configure IMA 36-2Interface ATMslot-number/IMAima-group-number Configuring ATM IMA on T1/E1 InterfaceIma-groupima-group-number No ip address Atm bandwidth dynamic No atm ilmi-keepaliveConfiguring ATM IMA over Mpls Configuring the T1/E1 Controller36-4 Ima-groupgroup-number Configuring an ATM IMA InterfaceClock source internal 36-5You can configure ATM over Mpls in the following modes Configuring ATM over Mpls Pseudowire InterfaceDisables the Ilmi keepalive parameters 36-6Configures the ATM interface Configuring a Port Mode PseudowireConfiguring an N-to-1 VCC Cell Mode 36-7Xconnect ip-addressport-numberencapsulation mpls one-to-one Configuring an N-to-1 vPC Cell ModeEnable Configure terminal Interface ATMslot/IMAgroup-number 36-8ATM AAL5 SDU VCC Transport 36-9L2transport encapsulation for the VCC mode Verifying IMA ConfigurationsSets the encapsulation type to AAL5. AAL5 is the default 36-10Enters the global configuration mode How to Configure ATM Class of ServiceConfiguring Constant Bit Rate 36-11Configuring Unspecified Bit Rate Mode36-12 IMA links and the bandwidth of each link Configuring Unspecified Bit Rate PlusATM class of service with the rate equal to the bandwidth Ubr+ pcr-rate mcr-ratePcr-rate-Peak cell rate in Kbps Configures the UBR+ QoS class for an ATM permanent virtualCircuit and specifies the bandwidth Mcr-rate-Peak cell rate in MbpsExample Creating an IMA Interface Configuration ExamplesExample Configuring a Port Mode Pseudowire 36-15Example Configuring CBR Example Configuring an N-to-1 VCC Cell ModeExample Configuring an N-to-1 VPC Cell Mode Example Configuring UBRExample Configuring VBR for Real Time Traffic Configuring Marking Mpls Experimental BitsExample Configuring UBR Plus Example Configuring VBR for Non-Real Time TrafficApplying the Policy-map Applying a Policy map on PVC and PVP36-18 Attaches a policy map to the input interface Disables the Ilmi trap parametersSets the PVC encapsulation type to AAL0 36-19Applying a Policy map on ATM IMA Interface 36-2036-21 Creating a Table-mapTable-maptable-map-name Interface ATM slot/IMA group-numberMap from from-value to to-value Default copyCreating a Policy-map for SVI Interface 36-22Applying a Service Policy on SVI Interface Mpls ip Service-policy output policy-map-name36-23 36-24 36-25 Feature Information for Inverse Multiplexing over ATM 36-26IPv6 over Mpls 6PE and 6VPE 37-137-2 Benefits of 6PE and 6VPE IPv6 on Provider Edge Routers37-3 IPv6 router on the customer IPv6 on VPN Provider Edge RoutersComponents of MPLS-based 6VPE Network PE equipment, connected to CEs and entrySupported Features 37-5Scalability Numbers How to Configure IPv6 over Mpls 6PE and 6VPEConfiguring 6PE Interface NumbersAddress-family ipv6 Exit-address-family37-7 37-8 Configuring 6VPE Setting up IPv6 Connectivity from PE to CE Routers37-9 Vrf-name-Optional a specific VRF table for an IPv6 Setting up MP-BGP Peering to the Neighboring PEVRF table for an IPv6 address 37-10Address prefixes Places the router in address family configuration mode forEnable the exchange of information with a BGP neighbor Extended-Specifies that only extended communities will beSetting up MPLS/IPv4 Connectivity with LDP 37-12Creating IPv6 VRFs on PE Routers 37-1337-14 To configure dual-stack VRF, complete the following stepsSessions that use standard IPv4 address prefixes Address-family ipv4Router# show bgp vpnv6 unicast all Verifying IPv6 over Mpls 6PE and 6VPE Configuration37-15 Router# show ipv6 protocols vrf vpe137-16 Router# show ipv6 cef vrf cisco137-17 Router# show ipv6 route vrfRouter# show mpls forwarding-table vrf vpe1 37-18 Example Configuring 6PEFollowing is a sample configuration of 6PE Router# show bgp ipv6 200133/64Example Configuring 6VPE Following is a sample configuration of 6VPE37-19 37-20 Feature Information for IPv6 over Mpls 6PE and 6VPE 37-2137-22 Storm Control 38-1Configuring Storm Control 38-238-3 Verifying Storm Control 38-438-5 Configuring Error Disable RecoveryErrdisable recovery cause Storm-controlError-disable cause Monitoring Error Disable RecoverySeconds-Specifies the time to recover from a specified CauseConfiguration Example for Storm Control 38-7Router# debug platform hardware ether SC 38-8 Feature Information for Storm Control 38-938-10 Remote Loop-Free Alternate Fast Reroute 39-139-2 39-3 Remote LFA-FRR Link ProtectionAvoiding Traffic Drops Pseudowire Redundancy over FRRBenefits of Remote LFA-FRR 39-4Conditions for Switchover CESoPSN, SAToP, and ATM/IMA39-5 Configuring Remote LFA-FRR for IS-IS 39-639-7 Switch Virtual Interface SVISpecifies an IP address for the specified interface Ip router isis39-8 Configuring Remote LFA-FRR for Ospf 39-9Enables the Ospf routing protocol and enters the router 39-10Router ospf Configuring Remote LFA-FRR for Ethernet and TDM Pseudowires Enables Mpls LDP synchronization on interfaces for an Ospf39-11 Targeted hello messages from all neighbors Configuring Remote LFA-FRR on a Global InterfaceAccept-Configures the router to respond to requests for 39-12Configuring Remote LFA-FRR on a GigabitEthernet Interface 39-13Configuring Remote LFA-FRR on an SVI Interface 39-14Configuring Remote LFA-FRR on IS-IS 39-15Passive-interfaceinterface-type interface-number 39-1639-17 39-18 Backup peer peer-ip-address vc-id Configuring LFA-FRR for EoMPLSDisables sending routing updates on an interface 39-1939-20 Removes an IP address or disables IP processingEnables automatic negotiation Negotiation autoConfiguring LFA-FRR for ATM/IMA 39-2139-22 Exit Interface CEM slot/port No ip address Configuring LFA-FRR for CESoPSNBackup peer peer-ip-address 39-2339-24 Configuring LFA-FRR for SAToP Exit Interface CEM slot/port39-25 39-26 Verification Examples for Remote LFA-FRR 39-27Router# show ip ospf fast-reroute remote-lfa tunnels Verifying Remote LFA-FRR Configuration39-28 Router# show ip cef 171.1.1.0 internal39-29 Router# show ip ospf ribRouter# show isis fast-reroute remote-lfa tunnels 39-30 Router# show isis ribRouter# show mpls l2transport vc 1 detail 39-31 39-32 Router# show mpls l2transport vc 3001 detail39-33 Verifying Remote LFA-FRR Configuration on IS-ISVerifying Remote LFA-FRR Configuration on ATM/IMA Router# show mpls l2 vc 90 detailVerifying Remote LFA-FRR Configuration on CESoPSN 39-34Router# show mpls l2 vc 111 detail Configuration Examples for Remote LFA-FRR Verifying Remote LFA-FRR Configuration on SAToP39-35 Example Configuring Remote LFA-FRR Globally Example Configuring Remote LFA-FRR for IS-ISExample Configuring Remote LFA-FRR for Ospf 39-36Example Configuring LFA-FRR on ATM/IMA Example Configuring Remote LFA-FRR on an SVI InterfaceExample Configuring EoMPLS Pseudowire Redundancy over FRR 39-37Example Configuring LFA-FRR on CESoPSN Example Configuring LFA-FRR on SAToP39-38 39-39 Reroute, 39-40Digital Optical Monitoring 40-1Routerconfig# transceiver type all How to Enable Transceiver MonitoringEnters transceiver type configuration mode 40-2Example Displaying Transceiver Information Show interfaces transceiver commandExamples 40-3Example Displaying Detailed Transceiver Information 40-4Router# show interfaces transceiver detail Example Displaying List of Supported Transceivers 40-5Example Displaying Threshold Tables 40-640-7 40-8 40-9 Example When Transceiver Monitoring is DisabledExample Displaying Threshold Violations Router# show interfaces transceiver threshold violationsExample Displaying SPF Details 40-1040-11 SCP6G44-C1-BMHSFF-8472 40-12Feature Information for Digital Optical Monitoring 40-1340-14 IPv4 Multicast 41-141-2 Source Specific Multicast Supported ProtocolsPIM SSM for IPv4 Protocol Independent MulticastIGMPv3 IGMPv1IGMPv2 41-4Reverse Path Forwarding Ip igmp static ssm-map commandPIM SSM Mapping Static SSM MappingEnabling IPv4 Multicast Routing Configuring IPv4 MulticastEnables multicast routing Ip pim sparse-mode Asr901-multicast sourceIp pim sparse-mode Ip igmp version Configuring PIM SSMEnable Configure terminal Ip pim ssm default 41-7Configuring PIM SSM Mapping Ip igmp ssm-map static access-list source-address41-8 Verifying IPv4 Multicast Routing Verifying PIM SSM41-9 Router# show ip mroute Verifying PIM SSM Mapping41-10 Router# show ip igmp ssm-mappingShow ip igmp groups interface-type interface-number Configuration Examples for IPv4 MulticastShow ip igmp groups group-address Show ip igmp groups interface-type detailExample IPv4 Multicast Routing Example Configuring PIM SSMExample Configuring PIM SSM Mapping 41-12Example Configuring Rendezvous Point 41-13Router# debug ip igmp 41-14 41-15 Feature Information for IPv4 Multicast 41-16IGMPv2, 41-1741-18 IPv6 Multicast 42-142-2 Multicast Listener Discovery Protocol for IPv6 IPv6 Multicast GroupsIPv6 Multicast Routing Implementation 42-3Protocol Independent Multicast 42-4Source Specific Multicast Mapping for IPv6 PIM-Sparse ModePIM Source Specific Multicast 42-5Rendezvous Point Configuring IPv6 MulticastEnabling IPv6 Multicast Routing 42-6Enable Configure terminal No ipv6 mfib Disabling IPv6 Multicast Forwarding42-7 No ipv6 mld router Disables IPv6 multicast forwarding on the routerDisabling MLD Device-Side Processing 42-8Configuring MLD Protocol on an Interface 42-9No ipv6 mld router Configuring a Rendezvous Point 42-10Configuring PIM SSM Options Enable Configure terminal Ipv6 pim42-11 Disabling PIM SSM Multicast on an Interface Configuring IPv6 SSM MappingDisables PIM on the specified interface No ipv6 pimNo ipv6 mld vrf vrf-namessm-map query dns Configure terminal Ipv6 mld vrf vrf-namessm-map enableVerifying IPv6 Multicast 42-13Router# show ipv6 mld traffic 42-14Router# show ipv6 mld interface gigabitethernet 0/1 Router# show ipv6 pim interface42-15 Router# show ipv6 mld groups summaryRouter# show ipv6 pim neighbor count Router# show ipv6 mroute 42-16Router# show ipv6 pim neighbor Router# show ipv6 pim topologyRouter# show ipv6 pim group-map FF0EE0111 42-17Router# show ipv6 pim topology route-count Router# show ipv6 pim range-list42-18 Router# show ipv6 pim trafficRouter# show ipv6 pim join-prune statistic Following example 42-19Router# show ipv6 mfib summary 42-20Router# show ipv6 mfib status Router# show ipv6 mfib interfaceExample Enabling IPv6 Multicast Routing Configuration Examples for IPv6 MulticastExample Configuring IPv6 SSM Mapping 42-21Command Name Description 42-2242-23 Feature Information for IPv6 Multicast Chapter of the IP Multicast PIM Configuration Guide42-24 Chapter of the IP Multicast LSM Configuration Guide 42-2542-26 Configuring Switched Port Analyzer Span Limitations and Configuration Guidelines43-1 Understanding Span Following sections describe Span43-2 Span Session Source Interface43-3 Traffic Types Configuring SpanDestination Interface Span TrafficRemoving Sources or Destination from a Span Session 43-5Clears existing Span configuration for a session Configuration Examples for SpanEnable Configure terminal No monitor session sessionnumber Verifying Local Span43-7 Rspan Vlan43-8 Feature Information for Switched Port Analyzer 43-943-10 See BSC IN-1IN-2 IN-3 IN-4 IN-5 See MSC IN-6IN-7 IN-8 IN-9 IN-10
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