CCIE SPv5.1 Labs
  • Intro
    • Setup
  • Purpose
  • Video Demonstration
  • Containerlab Tips
  • Labs
    • ISIS
      • Start
      • Topology
      • Prefix Suppression
      • Hello padding
      • Overload Bit
      • LSP size
      • Default metric
      • Hello/Hold Timer
      • Mesh groups
      • Prefix Summarization
      • Default Route Preference
      • ISIS Timers
      • Log Neighbor Changes
      • Troubleshooting 1 - No routes
      • Troubleshooting 2 - Adjacency
      • IPv6 Single Topology
      • IPv6 Single Topology Challenge
      • IPv6 Multi Topology
      • IPv6 Single to Multi Topology
      • Wide Metrics Explained
      • Route Filtering
      • Backdoor Link
      • Non-Optimal Intra-Area routing
      • Multi Area
      • Authentication
      • Conditional ATT Bit
      • Troubleshooting iBGP
      • Troubleshooting TE Tunnel
    • LDP
      • Start
      • Topology
      • LDP and ECMP
      • LDP and Static Routes
      • LDP Timers
      • LDP Authentication
      • LDP Session Protection
      • LDP/IGP Sync (OSPF)
      • LDP/IGP Sync (ISIS)
      • LDP Local Allocation Filtering
      • LDP Conditional Label Advertisement
      • LDP Inbound Label Advertisement Filtering
      • LDP Label Advertisement Filtering Challenge
      • LDP Implicit Withdraw
      • LDP Transport Address Troubleshooting
      • LDP Static Labels
    • MPLS-TE
      • Start
      • Topology
      • Basic TE Tunnel w/ OSPF
      • Basic TE Tunnel w/ ISIS
      • TE Tunnel using Admin Weight
      • TE Tunnel using Link Affinity
      • TE Tunnel with Explicit-Null
      • TE Tunnel with Conditional Attributes
      • RSVP message pacing
      • Reoptimization timer
      • IGP TE Flooding Thresholds
      • CSPF Tiebreakers
      • TE Tunnel Preemption
      • TE Tunnel Soft Preemption
      • Tunneling LDP inside RSVP
      • PE to P TE Tunnel
      • Autoroute Announce Metric (XE)
      • Autoroute Announce Metric (XR)
      • Autoroute Announce Absolute Metric
      • Autoroute Announce Backup Path
      • Forwarding Adjacency
      • Forwarding Adjacency with OSPF
      • TE Tunnels with UCMP
      • Auto-Bandwidth
      • FRR Link Protection (XE, BFD)
      • FRR Link Protection (XE, RSVP Hellos)
      • FRR Node Protection (XR)
      • FRR Path Protection
      • FRR Multiple Backup Tunnels (Node Protection)
      • FRR Multiple Backup Tunnels (Link Protection)
      • FRR Multiple Backup Tunnels (Backwidth/Link Protection)
      • FRR Backup Auto-Tunnels
      • FRR Backup Auto-Tunnels with SRLG
      • Full Mesh Auto-Tunnels
      • Full Mesh Dynamic Auto-Tunnels
      • One-Hop Auto-Tunnels
      • CBTS/PBTS
      • Traditional DS-TE
      • IETF DS-TE with MAM
      • IETF DS-TE with RDM
      • RDM w/ FRR Troubleshooting
      • Per-VRF TE Tunnels
      • Tactical TE Issues
      • Multicast and MPLS-TE
    • SR
      • Start
      • Topology
      • Basic SR with ISIS
      • Basic SR with OSPF
      • SRGB Modifcation
      • SR with ExpNull
      • SR Anycast SID
      • SR Adjacency SID
      • SR LAN Adjacency SID (Walkthrough)
      • SR and RSVP-TE interaction
      • SR Basic Inter-area with ISIS
      • SR Basic Inter-area with OSPF
      • SR Basic Inter-IGP (redistribution)
      • SR Basic Inter-AS using BGP
      • SR BGP Data Center (eBGP)
      • SR BGP Data Center (iBGP)
      • LFA
      • LFA Tiebreakers (ISIS)
      • LFA Tiebreakers (OSPF)
      • Remote LFA
      • RLFA Tiebreakers?
      • TI-LFA
      • Remote LFA or TILFA?
      • TI-LFA Node Protection
      • TI-LFA SRLG Protection
      • TI-LFA Protection Priorities (ISIS)
      • TI-LFA Protection Priorities (OSPF)
      • Microloop Avoidance
      • SR/LDP Interworking
      • SR/LDP SRMS OSPF Inter-Area
      • SR/LDP Design Challenge #1
      • SR/LDP Design Challenge #2
      • Migrate LDP to SR (ISIS)
      • OAM with SR
      • SR-MPLS using IPv6
      • Basic SR-TE with AS
      • Basic SR-TE with AS and ODN
      • SR-TE with AS Primary/Secondary Paths
      • SR-TE Dynamic Policies
      • SR-TE Dynamic Policy with Margin
      • SR-TE Explicit Paths
      • SR-TE Disjoint Planes using Anycast SIDs
      • SR-TE Flex-Algo w/ Latency
      • SR-TE Flex-Algo w/ Affinity
      • SR-TE Disjoint Planes using Flex-Algo
      • SR-TE BSIDs
      • SR-TE RSVP-TE Stitching
      • SR-TE Autoroute Include
      • SR Inter-IGP using PCE
      • SR-TE PCC Features
      • SR-TE PCE Instantiated Policy
      • SR-TE PCE Redundancy
      • SR-TE PCE Redundancy w/ Sync
      • SR-TE Basic BGP EPE
      • SR-TE BGP EPE for Unified MPLS
      • SR-TE Disjoint Paths
      • SR Converged SDN Transport Challenge
      • SR OAM DPM
      • SR OAM Tools
      • Performance-Measurement (Interface Delay)
    • SRv6
      • Start
      • Topology
      • Basic SRv6
      • SRv6 uSID
      • SRv6 uSID w/ EVPN-VPWS and BGP IPv4/IPv6
      • SRv6 uSID w/ SR-TE
      • SRv6 uSID w/ SR-TE Explicit Paths
      • SRv6 uSID w/ L3 IGW
      • SRv6 uSID w/ Dual-Connected PE
      • SRv6 uSID w/ Flex Algo
      • SRv6 uSID - Scale (Pt. 1)
      • SRv6 uSID - Scale (Pt. 2)
      • SRv6 uSID - Scale (Pt. 3) (UPA Walkthrough)
      • SRv6 uSID - Scale (Pt. 4) (Flex Algo)
      • SRv6 uSID w/ TI-LFA
    • Multicast
      • Start
      • Topology
      • Basic PIM-SSM
      • PIM-SSM Static Mapping
      • Basic PIM-SM
      • PIM-SM with Anycast RP
      • PIM-SM with Auto-RP
      • PIM-SM with BSR
      • PIM-SM with BSR for IPv6
      • PIM-BiDir
      • PIM-BiDir for IPv6
      • PIM-BiDir with Phantom RP
      • PIM Security
      • PIM Boundaries with AutoRP
      • PIM Boundaries with BSR
      • PIM-SM IPv6 using Embedded RP
      • PIM SSM Range Note
      • PIM RPF Troubleshooting #1
      • PIM RPF Troubleshooting #2
      • PIM RP Troubleshooting
      • PIM Duplicate Traffic Troubleshooting
      • Using IOS-XR as a Sender/Receiver
      • PIM-SM without Receiver IGMP Joins
      • RP Discovery Methods
      • Basic Interdomain Multicast w/o MSDP
      • Basic Interdomain Multicast w/ MSDP
      • MSDP Filtering
      • MSDP Flood Reduction
      • MSDP Default Peer
      • MSDP RPF Check (IOS-XR)
      • MSDP RPF Check (IOS-XE)
      • Interdomain MBGP Policies
      • PIM Boundaries using MSDP
    • MVPN
      • Start
      • Topology
      • Profile 0
      • Profile 0 with data MDTs
      • Profile 1
      • Profile 1 w/ Redundant Roots
      • Profile 1 with data MDTs
      • Profile 6
      • Profile 7
      • Profile 3
      • Profile 3 with S-PMSI
      • Profile 11
      • Profile 11 with S-PMSI
      • Profile 11 w/ Receiver-only Sites
      • Profile 9 with S-PMSI
      • Profile 12
      • Profile 13
      • UMH (Upstream Multicast Hop) Challenge
      • Profile 13 w/ Configuration Knobs
      • Profile 13 w/ PE RP
      • Profile 12 w/ PE Anycast RP
      • Profile 14 (Partitioned MDT)
      • Profile 14 with Extranet option #1
      • Profile 14 with Extranet option #2
      • Profile 14 w/ IPv6
      • Profile 17
      • Profile 19
      • Profile 21
    • MVPN SR
      • Start
      • Topology
      • Profile 27
      • Profile 27 w/ Constraints
      • Profile 27 w/ FRR
      • Profile 28
      • Profile 28 w/ Constraints and FRR
      • Profile 28 w/ Data MDTs
      • Profile 29
    • VPWS
      • Start
      • Topology
      • Basic VPWS
      • VPWS with Tag Manipulation
      • Redundant VPWS
      • Redundant VPWS (IOS-XR)
      • VPWS with PW interfaces
      • Manual VPWS
      • VPWS with Sequencing
      • Pseudowire Logging
      • VPWS with FAT-PW
      • MS-PS (Pseudowire stitching)
      • VPWS with BGP AD
    • VPLS
      • Start
      • Topology
      • Basic VPLS with LDP
      • VPLS with LDP and BGP
      • VPLS with BGP only
      • Hub and Spoke VPLS
      • Tunnel L2 Protocols over VPLS
      • Basic H-VPLS
      • H-VPLS with BGP
      • H-VPLS with QinQ
      • H-VPLS with Redundancy
      • VPLS with Routing
      • VPLS MAC Protection
      • Basic E-TREE
      • VPLS with LDP/BGP-AD and XRv RR
      • VPLS with BGP and XRv RR
      • VPLS with Storm Control
    • EVPN
      • Start
      • Topology
      • EVPN VPWS
      • EVPN VPWS Multihomed
      • EVPN VPWS Multihomed Single-Active
      • Basic Single-homed EVPN E-LAN
      • EVPN E-LAN Service Label Allocation
      • EVPN E-LAN Ethernet Tag
      • EVPN E-LAN Multihomed
      • EVPN E-LAN on XRv
      • EVPN IRB
      • EVPN-VPWS Multihomed IOS-XR (All-Active)
      • EVPN-VPWS Multihomed IOS-XR (Port-Active)
      • EVPN-VPWS Multihomed IOS-XR (Single-Active)
      • EVPN-VPWS Multihomed IOS-XR (Non-Bundle)
      • PBB-EVPN (Informational)
    • BGP Multi-Homing (XE)
      • Start
      • Topology
      • Lab1 ECMP
      • Lab2 UCMP
      • Lab3 Backup Path
      • Lab4 Shadow Session
      • Lab5 Shadow RR
      • Lab6 RR with Add-Path
      • Lab7 MPLS + Add Path ECMP
      • Lab8 MPLS + Shadow RR
      • Lab9 MPLS + RDs + UCMP
    • BGP Multi-Homing (XR)
      • Start
      • Topology
      • Lab1 ECMP
      • Lab2 UCMP
      • Lab3 Backup Path
      • Lab4 “Shadow Session”
      • Lab5 “Shadow RR”
      • Lab6 RR with Add-Path
      • Lab7 MPLS + Add Path ECMP
      • Lab8 MPLS + “Shadow RR”
      • Lab9 MPLS + RDs + UCMP
      • Lab10 MPLS + Same RD + Add-Path + UCMP
      • Lab11 MPLS + Same RD + Add-Path + Repair Path
    • BGP
      • Start
      • Conditional Advertisement
      • Aggregation and Deaggregation
      • Local AS
      • BGP QoS Policy Propagation
      • Non-Optimal eBGP Routing
      • Multihomed Enterprise Challenge
      • Provider Communities
      • Destination-Based RTBH
      • Destination-Based RTBH (Community-Based)
      • Source-Based RTBH
      • Source-Based RTBH (Community-Based)
      • Multihomed Enterprise Challenge (XRv)
      • Provider Communities (XRv)
      • DMZ Link BW Lab1
      • DMZ Link BW Lab2
      • PIC Edge in the Global Table
      • PIC Edge Troubleshooting
      • PIC Edge for VPNv4
      • AIGP
      • AIGP Translation
      • Cost-Community (iBGP)
      • Cost-Community (confed eBGP)
      • Destination-Based RTBH (VRF Provider-triggered)
      • Destination-Based RTBH (VRF CE-triggered)
      • Source-Based RTBH (VRF Provider-triggered)
      • Flowspec (Global IPv4/6PE)
      • Flowspec (VRF)
      • Flowspec (Global IPv4/6PE w/ Redirect)
      • Flowspec (Global IPv4/6PE w/ Redirect) T-Shoot
      • Flowspec (VRF w/ Redirect)
      • Flowspec (Global IPv4/6PE w/ CE Advertisement)
    • Intra-AS L3VPN
      • Start
      • Partitioned RRs
      • Partitioned RRs with IOS-XR
      • RT Filter
      • Non-Optimal Multi-Homed Routing
      • Troubleshoot #1 (BGP)
      • Troubleshoot #2 (OSPF)
      • Troubleshoot #3 (OSPF)
      • Troubleshoot #4 (OSPF Inter-AS)
      • VRF to Global Internet Access (IOS-XE)
      • VRF to Global Internet Access (IOS-XR)
    • Inter-AS L3VPN
      • Start
      • Inter-AS Option A
      • Inter-AS Option B
      • Inter-AS Option C
      • Inter-AS Option AB (D)
      • CSC
      • CSC with Option AB (D)
      • Inter-AS Option C - iBGP LU
      • Inter-AS Option B w/ RT Rewrite
      • Inter-AS Option C w/ RT Rewrite
      • Inter-AS Option A Multi-Homed
      • Inter-AS Option B Multi-Homed
      • Inter-AS Option C Multi-Homed
    • Russo Inter-AS
      • Start
      • Topology
      • Option A L3NNI
      • Option A L2NNI
      • Option A mVPN
      • Option B L3NNI
      • Option B mVPN
      • Option C L3NNI
      • Option C L3NNI w/ L2VPN
      • Option C mVPN
    • BGP RPKI
      • Start
      • RPKI on IOS-XE (Enabling the feature)
      • RPKI on IOS-XE (Validation)
      • RPKI on IOS-XR (Enabling the feature)
      • Enable SSH in Routinator
      • RPKI on IOS-XR (Validation)
      • RPKI on IOS-XR (RPKI Routes)
      • RPKI on IOS-XR (VRF)
      • RPKI iBGP Mesh (No Signaling)
      • RPKI iBGP Mesh (iBGP Signaling)
    • NAT
      • Start
      • Egress PE NAT44
      • NAT44 within an INET VRF
      • Internet Reachability between VRFs
      • CGNAT
      • NAT64 Stateful
      • NAT64 Stateful w/ Static NAT
      • NAT64 Stateless
      • MAP-T BR
    • BFD
      • Start
      • Topology
      • OSPF Hellos
      • ISIS Hellos
      • BGP Keepalives
      • PIM Hellos
      • Basic BFD for all protocols
      • BFD Asymmetric Timers
      • BFD Templates
      • BFD Tshoot #1
      • BFD for Static Routes
      • BFD Multi-Hop
      • BFD for VPNv4 Static Routes
      • BFD for VPNv6 Static Routes
      • BFD for Pseudowires
    • QoS
      • Start
      • QoS on IOS-XE
      • Advanced QoS on IOS-XE Pt. 1
      • Advanced QoS on IOS-XE Pt. 2
      • MPLS QoS Design
      • Notes - QoS on IOS-XR
    • NSO
      • Start
      • Basic NSO Usage
      • Basic NSO Template Service
      • Advanced NSO Template Service
      • Advanced NSO Template Service #2
      • NSO Template vs. Template Service
      • NSO API using Python
      • NSO API using Python #2
      • NSO API using Python #3
      • Using a NETCONF NED
      • Python Service
      • Nano Services
    • MDT
      • Start
      • MDT Server Setup
      • Basic Dial-Out
      • Filtering Data using XPATH
      • Finding the correct YANG model
      • Finding the correct YANG model #2
      • Event-Driven MDT
      • Basic Dial-In using gNMI
      • Dial-Out with TLS
      • Dial-In with TLS
      • Dial-In with two-way TLS
    • App-Hosting
      • Start
      • Lab - iperf3 Docker Container
      • Notes - LXC Container
      • Notes - Native Applications
      • Notes - Process Scripts
    • ZTP
      • Notes - Classic ZTP
      • Notes - Secure ZTP
    • L2 Connectivity Notes
      • 802.1ad (Q-in-Q)
      • MST-AG
      • MC-LAG
      • G.8032
    • Ethernet OAM
      • Start
      • Topology
      • CFM
      • y1731
      • Notes - y1564
    • Security
      • Start
      • Notes - Security ACLs
      • Notes - Hybrid ACLs
      • Notes - MPP (IOS-XR)
      • Notes - MPP (IOS-XE)
      • Notes - CoPP (IOS-XE)
      • Notes - LPTS (IOS-XR)
      • Notes - WAN MACsec White Paper
      • Notes - WAN MACsec Config Guide
      • Notes - AAA
      • Notes - uRPF
      • Notes - VTY lines (IOS-XR)
      • Lab - uRPF
      • Lab - MPP
      • Lab - AAA (IOS-XE)
      • Lab - AAA (IOS-XR)
      • Lab - CoPP and LPTS
    • Assurance
      • Start
      • Notes - Syslog on IOS-XE
      • Notes - Syslog on IOS-XR
      • Notes - SNMP Traps
      • Syslog (IOS-XR)
      • RMON
      • Netflow (IOS-XE)
      • Netflow (IOS-XR)
Powered by GitBook
On this page
  • Answer
  • Explanation/Verification
  1. Labs
  2. BGP Multi-Homing (XR)

Lab4 “Shadow Session”

PreviousLab3 Backup PathNextLab5 “Shadow RR”

Last updated 3 months ago

Load lab4.init.cfg

#R1, R6
configure replace unix:lab4.init.cfg

#R2-R5, R7
configure
load bootflash:lab4.init.cfg
commit replace
y

R7 has been introduced as the RR. This causes the path to R6’s loopbacks via R5 to be hidden again. Create a “shadow session” between R3 and R7 so that R3 learns both paths (via R4 and via R5).

For this task, you must enable multipathing on R3. Note that on IOS-XR, shadow sessions are not possible. IOS-XR appears to lack the functionality of “advertise diverse-path.” Instead, you will need to configure add path between R3 and R7. Interestingly, configuring add path on XR does not automatically reset BGP peerings.

Answer

#R3
router bgp 65000
 address-family ipv4 unicast
  additional-paths receive
  maximum-paths ibgp 2
 !
 address-family ipv6 unicast
  additional-paths receive
  maximum-paths ibgp 2
!
! Clear bgp with R7 to negotiate Add-Path
do clear bgp 10.0.0.7
do clear bgp fc00::7

#R7
route-policy SELECT_BACKUP
  set path-selection backup 1 advertise
end-policy
!
router bgp 65000
 address-family ipv4 unicast
  additional-paths send
  additional-paths selection route-policy SELECT_BACKUP
 !
 address-family ipv6 unicast
  additional-paths send
  additional-paths selection route-policy SELECT_BACKUP

Explanation/Verification

Before we make the change, notice that R7 is hiding the backup path via R5. By default, the RR only sends its bestpath to all RR clients.

Only the bestpath is sent to R3:

If R7 was an IOS-XE router, we could setup a shadow session using “advertise diverse-path backup” with a separate loopback on R3, like below:

#R7 (If it was IOS-XE)
router bgp 65000
 add ipv4
  bgp additional-paths select backup
  neighbor 10.0.0.33 advertise diverse-path backup
 !
 add ipv6
  bgp additional-paths select backup
  neighbor fc00::33 advertise diverse-path backup

However, on IOS-XR, I do not see a way to implement this feature. Instead we can run Add-Path between R7 and R3 only. The capability will only be negotiated between these two routers, so R7 won’t send additional paths to any other iBGP peers.

On IOS-XR, we enable Add-Path for the address-family. We also must use a route-policy to install/advertise routes to peers. The RPL determines which paths are selected for advertisement and installation locally. R7 does not need to install these paths locally, so it only uses the “advertise” keyword in the RPL.

#R3
router bgp 65000
 address-family ipv4 unicast
  additional-paths receive
 !
 address-family ipv6 unicast
  additional-paths receive

#R7
route-policy SELECT_BACKUP
  set path-selection backup 1 advertise
end-policy
!
router bgp 65000
 address-family ipv4 unicast
  additional-paths send
  additional-paths selection route-policy SELECT_BACKUP
 !
 address-family ipv6 unicast
  additional-paths send
  additional-paths selection route-policy SELECT_BACKUP

On R3 we also use iBGP multi-paths.

#R3
router bgp 65000
 address-family ipv4 unicast
  maximum-paths ibgp 2
 !
 address-family ipv6 unicast
  maximum-paths ibgp 2

We now must manually clear the session. IOS-XR will not automatically clear the session for us when we add Add-Path capability. This capability is negotiated in the BGP Open.

#R3
clear bgp 10.0.0.7
clear bgp fc00::7

We should now see that Add-Path is negotiated:

R3 is now receiving the additional paths via R5:

R3 installs these locally as multipath in the RIB/FIB.

https://www.youtube.com/watch?v=eF1zqUhiPbs&list=PL3Y9eZjZCcsejbVWD3wJIePqe3NiImqxB&index=6