IP Routing: OSPF Configuration Guide, Cisco IOS XE Everest 16.6
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This document describes how to configure and use a sham-link to connect Virtual Private Network (VPN) client sites that run
the Open Shortest Path First (OSPF) protocol and share backdoor OSPF links in a Multiprotocol Label Switching (MPLS) VPN configuration.
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see Bug Search Tool and 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 table.
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Prerequisites for OSPF Sham-Link Support for MPLS VPN
Before you can configure a sham-link in an MPLS VPN, you must first enable OSPF as follows:
Create an OSPF routing process.
Specify the range of IP addresses to be associated with the routing process.
Assign area IDs to be associated with the range of IP addresses.
Restrictions on OSPF Sham-Link Support for MPLS VPN
When OSPF is used as a protocol between PE and CE routers, the OSPF metric is preserved when routes are advertised over the
VPN backbone. The metric is used on the remote PE routers to select the correct route. For this reason, you should not modify
the metric value when OSPF is redistributed to BGP, and when BGP is redistributed to OSPF. If you modify the metric value,
routing loops may occur.
Information About OSPF Sham-Link Support for MPLS VPN
Benefits of OSPF Sham-Link Support for MPLS VPN
Client Site Connection Across the MPLS VPN Backbone
A sham-link overcomes the OSPF default behavior for selecting an intra-area backdoor route between VPN sites instead of an
interarea (PE-to-PE) route. A sham-link ensures that OSPF client sites that share a backdoor link can communicate over the
MPLS VPN backbone and participate in VPN services.
Flexible Routing in an MPLS VPN Configuration
In an MPLS VPN configuration, the OSPF cost configured with a sham-link allows you to decide if OSPF client site traffic will
be routed over a backdoor link or through the VPN backbone.
Using OSPF in PE-CE Router Connections
In an MPLS VPN configuration, the OSPF protocol is one way you can connect customer edge (CE) routers to service provider
edge (PE) routers in the VPN backbone. OSPF is often used by customers who run OSPF as their intrasite routing protocol, subscribe
to a VPN service, and want to exchange routing information between their sites using OSPF (during migration or on a permanent
basis) over an MPLS VPN backbone.
The figure below shows an example of how VPN client sites that run OSPF can connect over an MPLS VPN backbone.
When OSPF is used to connect PE and CE routers, all routing information learned from a VPN site is placed in the VPN routing
and forwarding (VRF) instance associated with the incoming interface. The PE routers that attach to the VPN use the Border
Gateway Protocol (BGP) to distribute VPN routes to each other. A CE router can then learn the routes to other sites in the
VPN by peering with its attached PE router. The MPLS VPN superbackbone provides an additional level of routing hierarchy to
interconnect the VPN sites running OSPF.
When OSPF routes are propagated over the MPLS VPN backbone, additional information about the prefix in the form of BGP extended
communities (route type, domain ID extended communities) is appended to the BGP update. This community information is used
by the receiving PE router to decide the type of link-state advertisement (LSA) to be generated when the BGP route is redistributed
to the OSPF PE-CE process. In this way, internal OSPF routes that belong to the same VPN and are advertised over the VPN backbone
are seen as interarea routes on the remote sites.
For basic information about how to configure an MPLS VPN, refer to the
Cisco IOS XE MPLS Configuration Guide, Release 2.
Using a Sham-Link to Correct OSPF Backdoor Routing
Although OSPF PE-CE connections assume that the only path between two client sites is across the MPLS VPN backbone, backdoor
paths between VPN sites (shown in grey in the figure below) may exist. If these sites belong to the same OSPF area, the path
over a backdoor link will always be selected because OSPF prefers intraarea paths to interarea paths. (PE routers advertise
OSPF routes learned over the VPN backbone as interarea paths.) For this reason, OSPF backdoor links between VPN sites must
be taken into account so that routing is performed based on policy.
For example, the figure above shows three client sites, each with backdoor links. Because each site runs OSPF within the
same Area 1 configuration, all routing between the three sites follows the intraarea path across the backdoor links, rather
than over the MPLS VPN backbone.
The following example shows BGP routing table entries for the prefix 10.3.1.7/32 in the PE-1 router in the figure above.
This prefix is the loopback interface of the Winchester CE router. As shown in bold in this example, the loopback interface
is learned via BGP from PE-2 and PE-3. It is also generated through redistribution into BGP on PE-1.
PE-1# show ip bgp vpnv4 all 10.3.1.7
BGP routing table entry for 100:251:10.3.1.7/32, version 58
Paths: (3 available, best #2)
Advertised to non peer-group peers:
10.3.1.2 10.3.1.5
Local
10.3.1.5 (metric 30) from 10.3.1.5 (10.3.1.5)
Origin incomplete, metric 22, localpref 100, valid, internal
Extended Community: RT:1:793 OSPF DOMAIN ID:0.0.0.100 OSPF
RT:1:2:0 OSPF 2
Local
10.2.1.38 from 0.0.0.0 (10.3.1.6)
Origin incomplete, metric 86, localpref 100, weight 32768,
valid, sourced, best
Extended Community: RT:1:793 OSPF DOMAIN ID:0.0.0.100 OSPF
RT:1:2:0 OSPF 2
Local
10.3.1.2 (metric 30) from 10.3.1.2 (10.3.1.2)
Origin incomplete, metric 11, localpref 100, valid, internal
Extended Community: RT:1:793 OSPF DOMAIN ID:0.0.0.100 OSPF
RT:1:2:0 OSPF 2
Within BGP, the locally generated route (10.2.1.38) is considered to be the best route. However, as shown in bold in the
next example, the VRF routing table shows that the selected path is learned via OSPF with a next hop of 10.2.1.38, which is
the Vienna CE router.
PE-1# show ip route vrf ospf 10.3.1.7
Routing entry for 10.3.1.7/32
Known via "ospf 100", distance 110, metric 86, type intra area
Redistributing via bgp 215
Advertised by bgp 215
Last update from 10.2.1.38 on Serial0/0/0, 00:00:17 ago
Routing Descriptor Blocks:
* 10.2.1.38
, from 10.3.1.7, 00:00:17 ago, via Serial0/0/0
Route metric is 86, traffic share count is 1
This path is selected because:
The OSPF intra-area path is preferred over the interarea path (over the MPLS VPN backbone) generated by the PE-1 router.
OSPF has a lower administrative distance (AD) than internal BGP (BGP running between routers in the same autonomous system).
If the backdoor links between sites are used only for backup purposes and do not participate in the VPN service, then the
default route selection shown in the preceding example is not acceptable. To reestablish the desired path selection over the
MPLS VPN backbone, you must create an additional OSPF intra-area (logical) link between ingress and egress VRFs on the relevant
PE routers. This link is called a sham-link.
A sham-link is required between any two VPN sites that belong to the same OSPF area and share an OSPF backdoor link. If no
backdoor link exists between the sites, no sham-link is required.
The figure below shows a sample sham-link between PE-1 and PE-2. A cost is configured with each sham-link and is used to
decide whether traffic will be sent over the backdoor path or the sham-link path. When a sham-link is configured between PE
routers, the PEs can populate the VRF routing table with the OSPF routes learned over the sham-link.
Because the sham-link is seen as an intra-area link between PE routers, an OSPF adjacency is created and database exchange
(for the particular OSPF process) occurs across the link. The PE router can then flood LSAs between sites from across the
MPLS VPN backbone. As a result, the desired intra-area connectivity is created.
How to Configure an OSPF Sham-Link
Creating a Sham-Link
Before you begin
Before you create a sham-link between PE routers in an MPLS VPN, you must:
Configure a separate /32 address on the remote PE so that OSPF packets can be sent over the VPN backbone to the remote end
of the sham-link. The /32 address must meet the following criteria:
Belong to a VRF.
Not be advertised by OSPF.
Be advertised by BGP.
You can use the /32 address for other sham-links.
Associate the sham-link with an existing OSPF area.
To create a sham-link, use the following commands starting in EXEC mode:
Configures the specified OSPF process with the VRF associated with the sham-link interface on PE-1 and enters interface configuration
mode.
Step 16
Router1(config-if)# area area-idsham-link source-addressdestination-addresscost number
Configures the sham-link on the PE-1 interface within a specified OSPF area and with the loopback interfaces specified by
the IP addresses as endpoints. cost number configures the OSPF cost for sending an IP packet on the PE-1 sham-link interface.
Configures the specified OSPF process with the VRF associated with the sham-link interface on PE-2 and enters interface configuration
mode.
Step 18
Router2(config-if)# area area-idsham-link source-addressdestination-addresscost number
Configures the sham-link on the PE-2 interface within a specified OSPF area and with the loopback interfaces specified by
the IP addresses as endpoints. cost number configures the OSPF cost for sending an IP packet on the PE-2 sham-link interface.
Verifying Sham-Link Creation
To verify that the sham-link was successfully created and is operational, use the show ip ospf sham-links command in EXEC mode:
Router# show ip ospf sham-links
Sham Link OSPF_SL0 to address 10.2.1.2 is up
Area 1 source address 10.2.1.1
Run as demand circuit
DoNotAge LSA allowed. Cost of using 40 State POINT_TO_POINT,
Timer intervals configured, Hello 10, Dead 40, Wait 40,
Hello due in 00:00:04
Adjacency State FULL (Hello suppressed)
Index 2/2, retransmission queue length 4, number of
retransmission 0
First 0x63311F3C(205)/0x63311FE4(59) Next
0x63311F3C(205)/0x63311FE4(59)
Last retransmission scan length is 0, maximum is 0
Last retransmission scan time is 0 msec, maximum is 0 msec
Link State retransmission due in 360 msec
Monitoring and Maintaining a Sham-Link
Command
Purpose
Router# show ip ospf sham-links
Displays the operational status of all sham-links configured for a router.
Router# show ip ospf data router ip-address
Displays information about how the sham-link is advertised as an unnumbered point-to-point connection between two PE routers.
Configuration Examples of an OSPF Sham-Link
Example Sham-Link Configuration
This example is designed to show how a sham-link is used only to affect the OSPF intra-area path selection of the PE and
CE routers. The PE router also uses the information received from MP-BGP to set the outgoing label stack of incoming packets,
and to decide to which egress PE router to label switch the packets.
The figure below shows a sample MPLS VPN topology in which a sham-link configuration is necessary. A VPN client has three
sites, each with a backdoor link. Two sham-links have been configured, one between PE-1 and PE-2, and another between PE-2
and PE-3. A sham-link between PE-1 and PE-3 is not necessary in this configuration because the Vienna and Winchester sites
do not share a backdoor link.
The following output shows the forwarding that occurs between sites from the standpoint of how PE-1 views the 10.3.1.7/32
prefix, the loopback1 interface of the Winchester CE router in the figure.
PE-1# show ip bgp vpnv4 all 10.3.1.7
BGP routing table entry for 100:251:10.3.1.7/32, version 124
Paths: (1 available, best #1)
Local
10.3.1.2 (metric 30) from 10.3.1.2
(10.3.1.2)
Origin incomplete, metric 11, localpref 100, valid, internal,
best
Extended Community: RT:1:793 OSPF DOMAIN ID:0.0.0.100 OSPF
RT:1:2:0 OSPF 2
PE-1# show ip route vrf ospf 10.3.1.7
Routing entry for 10.3.1.7/32
Known via "ospf 100
", distance 110, metric 13, type intra area
Redistributing via bgp 215
Last update from 10.3.1.2 00:12:59 ago
Routing Descriptor Blocks:
10.3.1.2 (Default-IP-Routing-Table), from 10.3.1.7, 00:12:59 ago
The following output shows forwarding information in which the next hop for the route, 10.3.1.2, is the PE-3 router rather
than the PE-2 router (which is the best path according to OSPF). The reason the OSPF route is not redistributed to BGP on
the PE is because the other end of the sham-link already redistributed the route to BGP and there is no need for duplication.
The OSPF sham-link is used only to influence intra-area path selection. When sending traffic to a particular destination,
the PE router uses the MP-BGP forwarding information.
PE-1# show ip bgp vpnv4 all tag | begin 10.3.1.7
10.3.1.7/32 10.3.1.2
notag/38
PE-1# show tag-switching forwarding 10.3.1.2
Local Outgoing Prefix Bytes tag Outgoing Next Hop
tag tag or VC or Tunnel Id switched interface
31 42 10.3.1.2/32
0 PO3/0/0 point2point
PE-1# show ip cef vrf ospf 10.3.1.7
10.3.1.7/32, version 73, epoch 0, cached adjacency to POS3/0/0
0 packets, 0 bytes
tag information set
local tag: VPN-route-head
fast tag rewrite with PO3/0/0, point2point, tags imposed: {42 38
}
via 10.3.1.2
, 0 dependencies, recursive
next hop 10.1.1.17, POS3/0/0 via 10.3.1.2/32
valid cached adjacency
tag rewrite with PO3/0/0, point2point, tags imposed: {42 38}
If a prefix is learned across the sham-link and the path via the sham-link is selected as the best, the PE router does not
generate an MP-BGP update for the prefix. It is not possible to route traffic from one sham-link over another sham-link.
In the following output, PE-2 shows how an MP-BGP update for the prefix is not generated. Although 10.3.1.7/32 has been learned
via OSPF across the sham-link as shown in bold, no local generation of a route into BGP is performed. The only entry within
the BGP table is the MP-BGP update received from PE-3 (the egress PE router for the 10.3.1.7/32 prefix).
PE-2# show ip route vrf ospf 10.3.1.7
Routing entry for 10.3.1.7/32
Known via "ospf 100
", distance 110, metric 12, type intra area
Redistributing via bgp 215
Last update from 10.3.1.2 00:00:10 ago
Routing Descriptor Blocks:
* 10.3.1.2 (Default-IP-Routing-Table), from 10.3.1.7, 00:00:10 ago
Route metric is 12, traffic share count is 1
PE-2# show ip bgp vpnv4 all 10.3.1.7
BGP routing table entry for 100:251:10.3.1.7/32, version 166
Paths: (1 available, best #1)
Not advertised to any peer
Local
10.3.1.2 (metric 30) from 10.3.1.2 (10.3.1.2)
Origin incomplete, metric 11, localpref 100, valid, internal,
best
Extended Community: RT:1:793 OSPF DOMAIN ID:0.0.0.100 OSPF
RT:1:2:0 OSPF 2
The PE router uses the information received from MP-BGP to set the ongoing label stack of incoming packets, and to decide
to which egress PE router to label switch the packets.
Example Sham-Link Between Two PE Routers
The following example shows how to configure a sham-link between two PE routers:
Router1(config)
# interface loopback 1
Router1(config-if)# ip vrf forwarding ospf
Router1(config-if)# ip address 10.2.1.1 255.255.255.255
!
Router2(config)# interface loopback 1
Router2(config-if)# ip vrf forwarding ospf
Router2(config-if)# ip address 10.2.1.2 255.255.255.255
!
Router1(config)# router ospf 100 vrf ospf
Router1(config-if)# area 1 sham-link 10.2.1.1 10.2.1.2 cost 40
!
Router2(config)# router ospf 100 vrf ospf
Router2(config-if)# area 1 sham-link 10.2.1.2 10.2.1.1 cost 40
Additional References
The following sections provide references related to the OSPF Sham-Link Support for MPLS VPN feature.
Application of the Border Gateway Protocol in the Internet
RFC 2283
Multiprotocol Extensions for BGP-4
RFC 2328
Open Shortest Path First, Version 2
RFC 2547
BGP/MPLS VPNs
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Feature Information for OSPF Sham-Link Support for MPLS VPN
The following table provides release information about the feature or features described in this module. This table lists
only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise,
subsequent releases of that software release train also support that feature.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco
Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Table 1. Feature Information for OSPF Sham-Link Support for MPLS VPN
Feature Name
Releases
Feature Information
OSPF Sham-Link Support for MPLS VPN
Cisco IOS XE Release 2.1
This feature allows you to use a sham-link to connect Virtual Private Network (VPN) client sites that run OSPF and share
backdoor OSPF links in a Multiprotocol Label Switching (MPLS) VPN configuration.
The following commands are introduced or modified in the feature documented in this module:
area sham-link cost
show ip ospf sham-links
Glossary
BGP --Border Gateway Protocol. Interdomain routing protocol that exchanges reachability information with other BGP systems. It
is defined in RFC 1163.
CE router --customer edge router. A router that is part of a customer network and that interfaces to a provider edge (PE) router. CE
routers are not aware of associated VPNs.
CEF --
Cisco Express Forwarding. An advanced Layer 3 IP switching technology. CEF optimizes network performance and scalability for
networks with large and dynamic traffic patterns.
IGP --Interior Gateway Protocol. An Internet protocol used to exchange routing information within an autonomous system. Examples
of common IGPs include IGRP, OSPF, and RIP.
LSA --link-state advertisement. A broadcast packet used by link-state protocols. The LSA contains information about neighbors
and path costs and is used by the receiving router to maintain a routing table.
MPLS --Multiprotocol Label Switching. Emerging industry standard upon which tag switching is based.
OSPF --Open Shortest Path First protocol.
PE router --provider edge router. A router that is part of a service provider network connected to a customer edge (CE) router. All
VPN processing occurs in the PE router.
SPF --shortest path first calculation.
VPN --Virtual Private Network. A secure IP-based network that shares resources on one or more physical networks. A VPN contains
geographically dispersed sites that can communicate securely over a shared backbone.
VRF --VPN routing and forwarding instance. A VRF consists of an IP routing table, a derived forwarding table, a set of interfaces
that use the forwarding table, and a set of rules and routing protocols that determine what goes into the forwarding table.
In general, a VRF includes the routing information that defines a customer VPN site that is attached to a PE router.