BGP MPLS VPNs

This chapter describes services that are supported for Border Gateway Protocol (BGP) Multi-Protocol Label Switching (MPLS) Virtual Private Networks (VPNs).


Important

MPLS is a licensed Cisco feature that requires a separate license. Contact your Cisco account representative for detailed information on specific licensing requirements. For information on installing and verifying licenses, refer to the Managing License Keys section of Software Management Operations.


It includes the following topics:

Introduction

Service providers require the ability to support a large number of corporate Access Point Names (APNs) which have a number of different addressing models and requirements. ASR 5500 uses BGP MPLS Layer 3 VPNs to segregate corporate customer APNs in a highly scalable manner. This solution conforms to RFC 4364 – BGP/MPLS IP Virtual Private Networks (VPNs).


Note

Option b is supported for connectivity between multi-AS backbones.

The BGP/MPLS solution supports the following scenarios:

ASR 5500 also supports VPNv6 as described in RFC 4659 – BGP-MPLS IP Virtual Private Network (VPN) Extension for IPv6 VPN. See IPv6 Support for BGP MPLS VPNs for details.

MPLS-CE Connected to PE

In this scenario the ASR 5500 functions as an MPLS-CE (Customer Edge) network element connected to a Provider Edge (PE) Label Edge Router (LER), which in turn connects to the MPLS core (RFC 4364). See the figure below.

Figure 1. ASR 5500 MPLS-CE to PE

The MPLS-CE functions like a PE router within its own Autonomous System (AS). It maintains Virtual Routing and Forwarding (VRF) routes and exchanges VPN route information with the PE via an MP-eBGP (Multi-Protocol-external BGP) session.

The PE is also configured with VRFs and exchanges VPN routes with other PEs in its AS via MP-iBGP (Multi-Protocol-internal BGP) connections and the MPLS-CE via an MP-eBGP connection.

The EBGP connection allows the PE to change next-hop IP addresses and labels in the routes learned from IBGP peers before advertising them to the MPLS-CE. The MPLS-CE in this case uses only MP-eBGP to advertise and learn routes. Label Distribution Protocol (LDP) and Resource Reservation Protocol (RSVP) are not required because of direct-connect EBGP peering. The MPLS-CE in this scenario pushes/pops a single label (learned over the MP-eBGP connection) to/from the PE.

ASR 5500 as a PE

Overview

In this scenario, the ASR 5500 functions as a PE router sitting at the edge of the MPLS core. See the figure below.

Figure 2. ASR 5500 as a PE

The ASR 5500 eliminates the need for an ASBR or PE as shown in the first two scenarios. In this scenario, two main requirements are introduced: IBGP functionality and MPLS label distribution protocols.

The ASR 5500 can be configured to add two labels:
  • an outer label learned from LDP or RSVP-TE (RSVP-Traffic Engineering)

  • an inner label learned from MP-iBGP

This solution supports traffic engineering and QoS initiated via the ASR 5500.

Sample Configuration

In this example, VRFs are configured on the ASR 5500 PE and pools are associated with VRFs. The ASR 5500 exchanges VPN routes with its IBGP peers (PE routers) and learns the MPLS paths to reach PEs via LDP. The ASR 5500 forwards the packets to the next-hop with two labels – an inner label learned from PE and an outer label learned from the next hop IBGP neighbor.

Figure 3. Sample Configuration
mpls ip 
  protocol ldp 
    enable 
  exit 
exit 
   
ip vrf vrf1 
  mpls traffic-class copy 
exit 
ip vrf vrf2 
  mpls traffic-class value 5 
exit 
   
router bgp 300 
  ip vrf vrf1 
    route-target export 300 1 
      route-target import 300 1 
      route-distinguisher 300 1 
  exit 
    ip vrf vrf2 
      route-target export 300 2 
        route-target import 300 2 
        route-distinguisher 300 2 
  exit 
   
  router-id 2.2.2.2 
  neighbor 192.168.107.20 remote-as 300 
  neighbor 192.168.107.20 update-source node1_loopback 
   
  address-family vpnv4 
    neighbor 192.168.107.20 activate 
      neighbor 192.168.107.20 send-community both 
      neighbor 192.168.107.20 next-hop-self 
  exit 
   
  address-family ipv4 vrf vrf1 
    redistribute connected 
  exit 
   
  address-family ipv4 vrf vrf2 
    redistribute connected 
exit 
   
interface interface_to_internet 
  ip address 192.168.109.65/24  
  mpls ip 
exit 
router ospf  
  network 192.168.109.0/24 area 0.0.0.0 
exit 

IPv6 Support for BGP MPLS VPNs

Overview

The ASR 5500 supports VPNv6 as described in RFC 4659 – BGP-MPLS IP Virtual Private Network (VPN) Extension for IPv6 VPN.

An IPv6 VPN is connected over an IPv6 interface or sub-interface to the Service Provider (SP) backbone via a PE router. The site can be both IPv4 and IPv6 capable. Each VPNv6 has its own address space which means a given address denotes different systems in different VPNs. This is achieved via a VPNv6 address-family which prepends a Route Distinguisher (RD) to the IP address.

A VPNv6 address is a 24-byte quantity beginning with an 8-byte RD and ending with a 16-byte IPv6 address. When a site is IPv4 and IPv6 capable, the same RD can be used for the advertisement of both IPv4 and IPv6 addresses.

The system appends RD to IPv6 routes and exchanges the labeled IPv6-RD using the VPNv6 address-family. The Address Family Identifier (AFI) and Subsequent Address Family Identifier (SAFI) fields for VPNv6 routes will be set to 2 and 128 respectively.

The IPv6 VPN traffic will be transported to the BGP speaker via IPv4 tunneling. The BGP speaker advertises to its peer a Next Hop Network Address field containing a VPN-IPv6 address whose 8-octet RD is set to zero and whose 16-octet IPv6 address is encoded as an IPv4-mapped IPv6 address (RFC 4291) containing the IPv4 address of the advertising router. It is assumed that only EBGP peering will be used to exchange VPNv6 routes.

Support for VPN-IPv6 assumes the following:
  • Dual Stack (IPv4/IPv6) routing
  • IPv6 pools in VRFs
  • BGP peering over a directly connected IPv4 interface

See the figure below.

Figure 4. IPv6-RD Support for VPNv6

Sample Configuration

This example assumes three VRFs. VRF 1 has only IPv4 routes, VRF f2 has both IPv4 and IPv6 routes, and VRF 3 has only IPv6 routes.

Figure 5. VPNv6 Sample Configuration

Configure VRFs.

  ip vrf vrf1 
  exit 
  ip vrf vrf2 
  exit 
  ip vrf vrf3 
  exit 

Enable MPLS BGP forwarding.

  mpls bgp forwarding 

Configure pools.

  ip pool vrf1-pool 51.52.53.0 255.255.255.0 private 0 vrf vrf1 
  exit 
  ip pool vrf2-pool 51.52.53.0 255.255.255.0 private 0 vrf vrf2 
  exit 
  ipv6 pool vrf2-v6pool prefix 2005:0101::/32 private 0 vrf vrf2 
  exit  
  ipv6 pool vrf3-v6pool prefix 2005:0101::/32 private 0 vrf vrf3 
exit 

Configure interfaces.

  interface ce_interface_to_rtr 
    ip address 192.168.110.90 255.255.255.0 
  exit 
  interface ce_v6_interface 
    ip address 2009:0101:0101:0101::1/96 
  exit 
  interface ce_loopback loopback 
    ip address 52.1.2.3 255.255.255.255 
  exit 
  interface vrf1-loop loopback  
    ip vrf forwarding vrf1 
    ip address 1.52.53.54 255.255.255.255 
  exit 
  interface vrf2-loop loopback 
    ip vrf forwarding vrf2  
    ip address 2.52.53.54 255.255.255.255 
  exit 
  interface vrf2-v6loop loopback 
    ip vrf forwarding vrf2 
    ip address 2005:0202:0101::1/128 
  exit 
  interface vrf3-v6loop loopback 
    ip vrf forwarding vrf3 
    ip address 2005:0303:0101::1/128 
  exit 

Configure BGP along with address families and redistribution rules.

  router bgp 800 
    router-id 1.1.1.1 
  neighbor 192.168.110.20 remote-as 1003 
    neighbor 192.168.110.20 activate 
  address-family vpnv4 
    neighbor 192.168.110.20 activate 
    neighbor 192.168.110.20 send-community both 
  exit 
  address-family vpnv6 
    neighbor 192.168.110.20 activate  
    neighbor 192.168.110.20 send-community both 
  exit 
  ip vrf vrf1 
    route-distinguisher 800 1 
    route-target export 800 1 
    route-target import 800 1 
  exit 
  address-family ipv4 vrf vrf1 
    redistribute connected 
    redistribute static 
  exit  
  ip vrf vrf2 
    route-distinguisher 800 2 
    route-target export 800 2 
    route-target import 800 2 
  exit 
  address-family ipv4 vrf vrf2 
    redistribute connected 
    redistribute static 
  exit 
  address-family ipv6 vrf vrf2 
    redistribute connected 
    redistribute static 
  exit  
  ip vrf vrf3 
    route-distinguisher 800 3 
    route-target export 800 3 
    route-target import 800 3 
  exit  
  address-family ipv6 vrf   vrf3 
    redistribute connected 
    redistribute static  
  exit  

Configure APNs.

  apn walmart51.com  
    selection-mode sent-by-ms 
    accounting-mode none  
    aaa group walmart-group 
    authentication pap 1 chap 2 allow-noauth 
    ip context-name Gi_ce 
    ip address pool name vrf1-pool 
  exit 
  apn amazon51.com 
    selection-mode sent-by-ms 
    accounting-mode none 
    aaa group amazon-group 
    authentication pap 1 chap 2 allow-noauth  
    ip context-name Gi_ce 
    ip address pool name vrf2-pool  
    ipv6 address prefix-pool vrf2-v6pool  
  exit  
  apn apple51.com 
    selection-mode sent-by-ms 
    accounting-mode none  
    aaa group apple-group 
    authentication pap 1 chap 2 allow-noauthip context-name Gi_ce  
    ipv6 address prefix-pool vrf3-v6pool 
  exit  
  aaa-group amazon-group 
    radius ip vrf vrf2 
  aaa group default 
  exit  
  gtpp group default 
  exit  
  ip igmp profile default 
  exit 

Bind physical interfaces with the port.

VPN-Related CLI Commands

VPN-related features and functions are supported across several CLI command modes. The following tables identify commands associated with configuration and monitoring of VPN-related functions.

For detailed information regarding the use of the commands listed below, see the Command Line Interface Reference.

Table 1. VPN-Related Configuration Commands
CLI Mode Command Description

BGP Address-Family (IPv4/IPv6) Configuration Mode

neighbor ip_address activate

Enables the exchange of routing information with a peer router.

BGP Address-Family (IPv4/IPv6) Configuration Mode

neighbor ip_address send community { both | extended | standard }

Sends the community attributes to a peer router (neighbor).

BGP Address-Family (IPv4/IPv6) Configuration Mode

redistribute connected

Redistributes routes into BGP from another protocol as BGP neighbors.

BGP Address-Family (VPNv4) Configuration Mode

neighbor ip_address activate

Enables the exchange of routing information with a peer router.

BGP Address-Family (VPNv4) Configuration Mode

neighbor ip_address send community { both | extended | standard }

Sends the extended-community attribute to a peer router. In VPN, route-distinguisher and route-target are encoded in the BGP extended-community. This command enables sending of BGP routes with extended community to a neighbor.

BGP Address-Family (VRF) Configuration Mode

neighbor ip_address activate

Enables the exchange of routing information with a peer router.

BGP Address-Family (VRF) Configuration Mode

neighbor ip_address send community { both | extended | standard }

Sends the extended-community attribute to a peer router. In VPN, route-distinguisher and route-target are encoded in the BGP extended-community. This command enables sending of BGP routes with extended community to a neighbor.

BGP Address-Family (VRF) Configuration Mode

redistribute connected

Redistributes routes into BGP from another protocol as BGP neighbors.

BGP Configuration Mode

address-family { ipv4 vrf vrf_name | vpnv4 }

Enables the exchange of IPv4 VRF routing information. There is a different mode for each address-family.

BGP Configuration Mode

address-family { ipv6 vrf vrf_name | vpnv6 }

Configures a VPNv6 address family and IPv6 VRF routing in BGP.

BGP Configuration Mode

ip vrf vrf_name

Adds a VRF to BGP and switches to the VRF Configuration mode to allow configuration of BGP attributes for the VRF.

BGP IP VRF Configuration Mode

route-distinguisher { as_value | ip_address } rd_value

Assigns a Route Distinguisher (RD) for the VRF. The RD value must be a unique value on the router for each VRF.

BGP IP VRF Configuration Mode

route-target { both | import | export } { as_value | ip_address } rt_value

Adds a list of import and export route-target extended communities to the VRF.

Context Configuration Mode

ip pool pool_name addr_range vrf vrf_name [ mpls-label input inlabel1 output outlabel1 outlabel2 ]

Configures a pool into the specified VRF. This parameter must be specified with the Next-Hop parameter. inlabel1 is the MPLS label that identifies inbound traffic destined for this pool. outlabel1 and outlabel2 specify the MPLS labels to be added to packets sent for subscribers from this pool.

Context Configuration Mode

ip vrf vrf_name

Creates a VRF and assigns a VRF-ID. A VRF is created in the router.

Context Configuration Mode

ipv6 pool pool_name vrf vrf_name

Associates the pool with that VRF.

Note: By default the configured ipv6 pool will be associated with the global routing domain.

Context Configuration Mode

mpls bgp forwarding

Globally enables MPLS Border Gateway Protocol (BGP) forwarding.

Context Configuration Mode

mpls exp value

Sets the default behavior as Best Effort using a zero value in the 3-bit MPLS EXP header. This value applies to all the VRFs in the context. The default behavior is to copy the DSCP value of mobile subscriber traffic to the EXP header, if there is no explicit configuration for DSCP to EXP (via the mpls map-dscp-to-exp dscp n exp m command).

mpls exp disables the default behavior and sets the EXP value to the configured value.

Context Configuration Mode

mpls ip

Globally enables the MPLS forwarding of IPv4 packets along normally routed paths.

Context Configuration Mode

radius change-authorize-nas-ip ip_address ip_address { encrypted | key } value port port_num mpls input inlabel output outlabel1 outlabel2

Configures COA traffic to use the specified MPLS labels. inlabel identifies inbound COA traffic. outlabel1 and outlabel2 specify the MPLS labels to be added to the COA response. outlabel1 is the inner output label; outlabel2 is the outer output label.

Ethernet Interface Configuration Mode

mpls ip

Enables dynamic MPLS forwarding of IP packets on this interface.

Exec Mode

clear ip bgp peer

Clears BGP sessions.

Exec Mode

lsp-ping ip_prefix_FEC

Checks MPLS Label-Switched Path (LSP) connectivity for the specified forwarding equivalence class (FEC). It must be followed by an IPv4 or IPv6 FEC prefix.

Exec Mode

lsp-traceroute ip_prefix_FEC

Discovers MPLS LSP routes that packets actually take when traveling to their destinations. It must be followed by an IPv4 or IPv6 FEC prefix.

IP VRF Context Configuration Mode

mpls map-dscp-to-exp dscp dscp_bit_value exp exp_bit_value Maps the final differentiated services code point (DSCP) bit value in the IP packet header to the final Experimental (EXP) bit value in the MPLS header for incoming traffic.

IP VRF Context Configuration Mode

mpls map-exp-to-dscp exp exp_bit_value dscp dscp_bit_value

Maps the incoming EXP bit value in the MPLS header to the internal DSCP bit value in IP packet headers for outgoing traffic.

MPLS-IP Configuration Mode

protocol ldp

Creates the MPLS protocol family configuration modes, or configures an existing protocol and enters the MPLS-LDP Configuration Mode in the current context. This command configures the protocol parameters for the MPLS protocol family.

MPLS-LDP Configuration Mode

advertise-labels { explicit-null | implicit-null }

Configure advertisement of Implicit NULL or Explicit NULL label for all the prefixes advertised by the system in this context.

MPLS-LDP Configuration Mode

discovery { hello { hello-interval seconds | hold-interval seconds } | transport-address ip_address }

Configures the Label Distribution Protocol (LDP) neighbor discovery parameters.

MPLS-LDP Configuration Mode

enable

Enables Label Distribution Protocol (LDP).

MPLS-LDP Configuration Mode

router-id ip_address

Configures the LDP Router ID.

MPLS-LDP Configuration Mode

session timers { hold-interval seconds | keepalive-interval seconds }

Configures the LDP session parameters.

Table 2. VPN-Related Monitoring Commands
CLI Mode Command Description

Exec Mode show Commands

show ip bgp neighbors

Displays information regarding BGP neighbors.

Exec Mode show Commands

show ip bgp vpnv4 { all | route-distinguisher | vrf }

Displays all VPNv4 routing data, routing data for a VRF or a route-distinguisher.

Exec Mode show Commands

show ip bgp vpnv6

Displays contents of VPNv6 routing table.

Exec Mode show Commands

show ip bgp vpnv6 { all | route-distinguisher | vrf }

Displays all VPNv6 routing data, routing data for a VRF or a route-distinguisher.

Exec Mode show Commands

show ip pool

Displays pool details including the configured VRF.

Exec Mode show Commands

show mpls cross-connect

Displays MPLS cross-connect information. MPLS tunnel cross-connects between interfaces and Label-Switched Paths (LSPs) connect two distant interface circuits of the same type via MPLS tunnels that use LSPs as the conduit.

Exec Mode show Commands

show mpls ftn [ vrf vrf_name

Displays MPLS FEC-to-NHLFE (FTN) table information.

Exec Mode show Commands

show mpls ftn [ vrf vrf_name ]

Displays contents of the MPLS FTN table for a specified VRF.

Exec Mode show Commands

show mpls ilm

Displays MPLS Incoming Label Map (ILM) table information.

Exec Mode show Commands

show mpls ldp

Displays the MPLS LDP information.

Exec Mode show Commands

show mpls nexthop-label-forwarding-entry

Displays MPLS Next-Hop Label Forwarding Entry (NHLFE) table information.