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Table Of Contents
Dynamic Multipoint VPN (DMVPN)
Prerequisites for Dynamic Multipoint VPN (DMVPN)
Restrictions for Dynamic Multipoint VPN (DMVPN)
DMVPN Support on the Cisco 6500 and Cisco 7600
Information About Dynamic Multipoint VPN (DMVPN)
Benefits of Dynamic Multipoint VPN (DMVPN)
Feature Design of Dynamic Multipoint VPN (DMVPN)
DMVPN—Enabling Traffic Segmentation Within DMVPN
Call Admission Control with DMVPN
How to Configure Dynamic Multipoint VPN (DMVPN)
Configuring the Spoke for DMVPN
Configuring the Forwarding of Clear-Text Data IP Packets into a VRF
Configuring the Forwarding of Encrypted Tunnel Packets into a VRF
Configuring DMVPN—Traffic Segmentation Within DMVPN
Enabling MPLS on the VPN Tunnel
Configuring Multiprotocol BGP on the Hub Router
Configuring Multiprotocol BGP on the Spoke Routers
Troubleshooting Dynamic Multipoint VPN (DMVPN)
Configuration Examples for Dynamic Multipoint VPN (DMVPN) Feature
Example: Hub Configuration for DMVPN
Example: Spoke Configuration for DMVPN
Example: 2547oDMVPN with Traffic Segmentation (with BGP only)
Example: 2547oDMVPN with Traffic Segmentation (Enterprise Branch)
Feature Information for Dynamic Multipoint VPN (DMVPN)
Dynamic Multipoint VPN (DMVPN)
First Published: November 25, 2002Last Updated: February 3, 2009The Dynamic Multipoint VPN (DMVPN) feature allows users to better scale large and small IP Security (IPsec) Virtual Private Networks (VPNs) by combining generic routing encapsulation (GRE) tunnels, IPsec encryption, and Next Hop Resolution Protocol (NHRP).
Finding Feature Information
Your software release may not support all the features documented in this module. For the latest feature information and caveats, see the release notes for your platform and software release. To find information about the features documented in this module, and to see a list of the releases in which each feature is supported, see the "Feature Information for Dynamic Multipoint VPN (DMVPN)" section.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to http://www.cisco.com/go/cfn. An account on Cisco.com is not required.
Contents
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Prerequisites for Dynamic Multipoint VPN (DMVPN)
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Prerequisites for Dynamic Multipoint VPN (DMVPN)
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Restrictions for Dynamic Multipoint VPN (DMVPN)
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Note
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One example of a PAT configuration on a NAT interface is:
ip nat inside source list nat_acl interface FastEthernet0/1 overloadDMVPN Support on the Cisco 6500 and Cisco 7600
Blade-to-Blade Switchover on the Cisco 6500 and Cisco 7600
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Cisco 6500 or Cisco 7600 As a DMVPN Hub
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Cisco 6500 or Cisco 7600 As a DMVPN Spoke
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DMVPN Hub or Spoke Supervisor Engine
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Encrypted Multicast with GRE
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mGRE Interfaces
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Quality of Service (QoS)
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Tunnel Key
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VRF-Aware DMVPN Scenarios
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Information About Dynamic Multipoint VPN (DMVPN)
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Benefits of Dynamic Multipoint VPN (DMVPN)
Hub Router Configuration Reduction
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Automatic IPsec Encryption Initiation
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Support for Dynamically Addressed Spoke Routers
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Dynamic Creation for Spoke-to-Spoke Tunnels
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VRF Integrated DMVPN
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Feature Design of Dynamic Multipoint VPN (DMVPN)
The Dynamic Multipoint VPN (DMVPN) feature combines GRE tunnels, IPsec encryption, and NHRP routing to provide users an ease of configuration via crypto profiles—which override the requirement for defining static crypto maps—and dynamic discovery of tunnel endpoints.
This feature relies on the following two Cisco enhanced standard technologies:
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The topology shown in Figure 1 and the corresponding bullets explain how this feature works.
Figure 1
Sample mGRE and IPsec Integration Topology
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IPsec Profiles
IPsec profiles abstract IPsec policy information into a single configuration entity, which can be referenced by name from other parts of the configuration. Therefore, users can configure functionality such as GRE tunnel protection with a single line of configuration. By referencing an IPsec profile, the user does not have to configure an entire crypto map configuration. An IPsec profile contains only IPsec information; that is, it does not contain any access list information or peering information.
VRF Integrated DMVPN
VPN Routing and Forwarding (VRF) Integrated DMVPN enables users to map DMVPN multipoint interfaces into MPLS VPNs. This mapping allows Internet service providers (ISPs) to extend their existing MPLS VPN services by mapping off-network sites (typically a branch office) to their respective MPLS VPNs. Customer equipment (CE) routers are terminated on the DMVPN PE router, and traffic is placed in the VRF instance of an MPLS VPN.
DMVPN can interact with MPLS VPNs in two ways:
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The ip vrf forwarding and tunnel vrf commands may be used at the same time. If they are used at the same time, the VRF name of each command may be the same or different.
For information about configuring the forwarding of clear-text data IP packets into a VRF, see the section "Configuring the Forwarding of Clear-Text Data IP Packets into a VRF." For information about configuring the forwarding of encrypted tunnel packets into a VRF, see the section "Configuring the Forwarding of Encrypted Tunnel Packets into a VRF."
For more information about configuring VRF, see reference in the "Related Documents" section.
Figure 2 illustrates a typical VRF Integrated DMVPN scenario.
Figure 2 VRF Integrated DMVPN
DMVPN—Enabling Traffic Segmentation Within DMVPN
Cisco IOS Release 12.4(11)T provides an enhancement that allows you to segment VPN traffic within a DMVPN tunnel. VRF instances are labeled, using MPLS, to indicate their source and destination.
The diagram in Figure 3 and the corresponding bullets explain how traffic segmentation within DMVPN works.
Figure 3 Traffic Segmentation with DMVPN
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An example illustrates the process:
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NAT-Transparency Aware DMVPN
DMVPN spokes are often situated behind a NAT router (which is often controlled by the ISP for the spoke site) with the outside interface address of the spoke router being dynamically assigned by the ISP using a private IP address (per Internet Engineering Task Force [IETF] RFC 1918).
Prior to Cisco IOS Release 12.3(6) and 12.3(7)T, these spoke routers had to use IPsec tunnel mode to participate in a DMVPN network. In addition, their assigned outside interface private IP address had to be unique across the DMVPN network. Even though ISAKMP and IPsec would negotiate NAT-T and "learn" the correct NAT public address for the private IP address of this spoke, NHRP could only "see" and use the private IP address of the spoke for its mapping entries. Effective with the NAT-Transparency Aware DMVPN enhancement, NHRP can now learn and use the NAT public address for its mappings as long as IPsec transport mode is used (which is the recommend IPsec mode for DMVPN networks). The restriction that the private interface IP address of the spoke must be unique across the DMVPN network has been removed. It is recommended that all DMVPN routers be upgraded to the new code before you try to use the new functionality even though spoke routers that are not behind NAT do not need to be upgraded. In addition, you cannot convert upgraded spoke routers that are behind NAT to the new configuration (IPsec transport mode) until the hub routers have been upgraded.
Also added in Cisco IOS Releases 12.3(9a) and 12.3(11)T is the capability to have the hub DMVPN router behind static NAT. This was a change in the ISAKMP NAT-T support. For this functionality to be used, all the DMVPN spoke routers and hub routers must be upgraded, and IPsec must use transport mode.
For these NAT-Transparency Aware enhancements to work, you must use IPsec transport mode on the transform set. Also, even though NAT-Transparency (IKE and IPsec) can support two peers (IKE and IPsec) being translated to the same IP address (using the UDP ports to differentiate them), this functionality is not supported for DMVPN. All DMVPN spokes must have a unique IP address after they have been NAT translated. They can have the same IP address before they are NAT translated.
Figure 4 illustrates a NAT-Transparency Aware DMVPN scenario.
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In Cisco IOS Release 12.4(6)T or later releases, DMVPN spokes behind NAT will participate in dynamic direct spoke-to-spoke tunnels. The spokes must be behind NAT boxes that are preforming NAT, not PAT. The NAT box must translate the spoke to the same outside NAT IP address for the spoke-spoke connections as the NAT box does for the spoke-hub connection. If there is more than one DMVPN spoke behind the same NAT box, then the NAT box must translate the DMVPN spokes to different outside NAT IP addresses. It is also likely that you may not be able to build a direct spoke-spoke tunnel between these spokes. If a spoke-spoke tunnel fails to form, then the spoke-spoke packets will continue to be forwarded via the spoke-hub-spoke path.Figure 4 NAT-Transparency Aware DMVPN
Call Admission Control with DMVPN
In a DMVPN network, it is easy for a DMVPN router to become "overwhelmed" with the number of tunnels it is trying to build. Call Admission Control can be used to limit the number of tunnels that can be built at any one time, thus protecting the memory of the router and CPU resources.
It is most likely that Call Admission Control will be used on a DMVPN spoke to limit the total number of ISAKMP sessions (DMVPN tunnels) that a spoke router will attempt to initiate or accept. This limiting is accomplished by configuring an IKE SA limit under Call Admission Control, which configures the router to drop new ISAKMP session requests (inbound and outbound) if the current number of ISAKMP SAs exceeds the limit.
It is most likely that Call Admission Control will be used on a DMVPN hub to rate limit the number of DMVPN tunnels that are attempting to be built at the same time. The rate limiting is accomplished by configuring a system resource limit under Call Admission Control, which configures the router to drop new ISAKMP session requests (new DMVPN tunnels) when the system utilization is above a specified percentage. The dropped session requests allow the DMVPN hub router to complete the current ISAKMP session requests, and when the system utilization drops, it can process the previously dropped sessions when they are reattempted.
No special configuration is required to use Call Admission Control with DMVPN. For information about configuring Call Admission Control, see the reference in the section "Related Documents."
NHRP Rate-Limiting Mechanism
NHRP has a rate-limiting mechanism that restricts the total number of NHRP packets from any given interface. The default values, which are set using the ip nhrp max-send command, are 100 packets every 10 seconds per interface. If the limit is exceeded, you will get the following system message:
%NHRP-4-QUOTA: Max-send quota of [int]pkts/[int]Sec. exceeded on [chars]For more information about this system message, see the document 12.4T System Message Guide.
How to Configure Dynamic Multipoint VPN (DMVPN)
To enable mGRE and IPsec tunneling for hub and spoke routers, you must configure an IPsec profile that uses a global IPsec policy template and configure your mGRE tunnel for IPsec encryption. This section contains the following procedures:
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Configuring an IPsec Profile
The IPsec profile shares most of the same commands with the crypto map configuration, but only a subset of the commands are valid in an IPsec profile. Only commands that pertain to an IPsec policy can be issued under an IPsec profile; you cannot specify the IPsec peer address or the access control list (ACL) to match the packets that are to be encrypted.
Prerequisites
Before configuring an IPsec profile, you must define a transform set by using the crypto ipsec transform-set command.
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DETAILED STEPS
What to Do Next
Proceed to the following sections "Configuring the Hub for DMVPN" and "Configuring the Spoke for DMVPN."
Configuring the Hub for DMVPN
To configure the hub router for mGRE and IPsec integration (that is, associate the tunnel with the IPsec profile configured in the previous procedure), use the following commands:
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DETAILED STEPS
Configuring the Spoke for DMVPN
To configure spoke routers for mGRE and IPsec integration, use the following commands.
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tunnel destination hub-physical-ip-address
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DETAILED STEPS
Configuring the Forwarding of Clear-Text Data IP Packets into a VRF
To configure the forwarding of clear-text date IP packets into a VRF, perform the following steps. This configuration assumes that the VRF BLUE has already been configured.
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DETAILED STEPS
Configuring the Forwarding of Encrypted Tunnel Packets into a VRF
To configure the forwarding of encrypted tunnel packets into a VRF, perform the following steps. This configuration assumes that the VRF RED has already been configured.
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DETAILED STEPS
Configuring DMVPN—Traffic Segmentation Within DMVPN
There are no new commands to use for configuring traffic segmentation, but there are tasks you must complete in order to segment traffic within a DMVPN tunnel:
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Prerequisites
The tasks that follow assume that the DMVPN tunnel and the VRFs "red" and "blue" have already been configured.
For information on configuring a DMVPN tunnel, see the "Configuring the Hub for DMVPN" section and the "Configuring the Spoke for DMVPN" section. For details about VRF configuration, see the "Configuring the Forwarding of Clear-Text Data IP Packets into a VRF" section and the "Configuring the Forwarding of Encrypted Tunnel Packets into a VRF" section.
Enabling MPLS on the VPN Tunnel
Because traffic segmentation within a DMVPN tunnel depends upon MPLS, you must configure MPLS for each VRF instance in which traffic will be segmented. For detailed information about configuring MPLS, see Cisco IOS Multiprotocol Label Switching Configuration Guide, Release 12.4.
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DETAILED STEPS
Configuring Multiprotocol BGP on the Hub Router
You must configure multiprotocol iBGP (MP-iBGP) to enable advertisement of VPNv4 prefixes and labels to be applied to the VPN traffic. Use BGP to configure the hub as a route reflector. To force all traffic to be routed via the hub, configure the BGP route reflector to change the next hop to itself when it advertises VPNv4 prefixes to the route reflector clients (spokes).
For more information about the BGP routing protocol, see the "BGP Features Roadmap" chapter in the Cisco IOS IP Routing: BGP Configuration Guide.
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DETAILED STEPS
Configuring Multiprotocol BGP on the Spoke Routers
Multiprotocol-iBGP (MP-iBGP) must be configured on the spoke routers and the hub. Follow the steps below for each spoke router in the DMVPN.
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Troubleshooting Dynamic Multipoint VPN (DMVPN)
After configuring DMVPN, to verify that DMVPN is operating correctly, to clear DMVPN statistics or sessions, or to debug DMVPN, you may perform the following optional steps:
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Step 1
The following example clears only dynamic DMVPN sessions:
Router# clear dmvpn session peer nbma
The following example clears all DMVPN sessions, both static and dynamic, for the specified tunnel:
Router# clear dmvpn session interface tunnel 100 static
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Router# clear dmvpn statistics peer tunnel 192.0.2.3
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The following example shows how to enable conditional DMVPN debugging that displays all error debugs for next hop routing protocol (NHRP), sockets, tunnel protection and crypto information:
Router# debug dmvpn error all
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Router# debug nhrp condition
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Router# debug nhrp error
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Router(config)# logging dmvpn rate-limit 20
The following example shows a sample system log with DMVPN messages:
%DMVPN-7-CRYPTO_SS: Tunnel101-192.0.2.1 socket is UP%DMVPN-5-NHRP_NHS: Tunnel101 192.0.2.251 is UP%DMVPN-5-NHRP_CACHE: Client 192.0.2.2 on Tunnel1 Registered.%DMVPN-5-NHRP_CACHE: Client 192.0.2.2 on Tunnel101 came UP.%DMVPN-3-NHRP_ERROR: Registration Request failed for 192.0.2.251 on Tunnel101Step 7
interface: Ethernet0/0Crypto map tag: to-peer-outside, local addr 209.165.201.3protected vrf: (nonelocal ident (addr/mask/prot/port): (192.168.0.1/255.255.255.255/0/0)remote ident (addr/mask/prot/port): (172.16.0.1/255.255.255.255/0/0)current_peer 209.165.200.225 port 500PERMIT, flags={origin_is_acl,}#pkts encaps: 3, #pkts encrypt: 3, #pkts digest: 3#pkts decaps: 4, #pkts decrypt: 4, #pkts verify: 4#pkts compressed: 0, #pkts decompressed: 0#pkts not compressed: 0, #pkts compr. failed: 0#pkts not decompressed: 0, #pkts decompress failed: 0#send errors 0, #recv errors 0local crypto endpt.: 209.165.201.3, remote crypto endpt.: 209.165.200.225path mtu 1500, media mtu 1500current outbound spi: 0xD42904F0(3559458032)inbound esp sas:spi: 0xD3E9ABD0(3555306448)transform: esp-3des ,in use settings ={Tunnel, }conn id: 2006, flow_id: 6, crypto map: to-peer-outsidesa timing: remaining key lifetime (k/sec): (4586265/3542)HA last key lifetime sent(k): (4586267)ike_cookies: 9263635C CA4B4E99 C14E908E 8EE2D79CIV size: 8 bytesreplay detection support: YStatus: ACTIVEStep 8
Router# show crypto isakmp sadst src state conn-id slot172.17.63.19 172.16.175.76 QM_IDLE 2 0172.17.63.19 172.17.63.20 QM_IDLE 1 0172.16.175.75 172.17.63.19 QM_IDLE 3 0Step 9
The following sample output is displayed after a crypto map has been configured:
Router# show crypto mapCrypto Map "Tunnel5-head-0" 10 ipsec-isakmpProfile name: vpnprofSecurity association lifetime: 4608000 kilobytes/3600 secondsPFS (Y/N): NTransform sets={trans2, }Crypto Map "Tunnel5-head-0" 20 ipsec-isakmpMap is a PROFILE INSTANCE.Peer = 172.16.175.75Extended IP access listaccess-list permit gre host 172.17.63.19 host 172.16.175.75Current peer: 172.16.175.75Security association lifetime: 4608000 kilobytes/3600 secondsPFS (Y/N): NTransform sets={trans2, }Crypto Map "Tunnel5-head-0" 30 ipsec-isakmpMap is a PROFILE INSTANCE.Peer = 172.17.63.20Extended IP access listaccess-list permit gre host 172.17.63.19 host 172.17.63.20Current peer: 172.17.63.20Security association lifetime: 4608000 kilobytes/3600 secondsPFS (Y/N): NTransform sets={trans2, }Crypto Map "Tunnel5-head-0" 40 ipsec-isakmpMap is a PROFILE INSTANCE.Peer = 172.16.175.76Extended IP access listaccess-list permit gre host 172.17.63.19 host 172.16.175.76Current peer: 172.16.175.76Security association lifetime: 4608000 kilobytes/3600 secondsPFS (Y/N): NTransform sets={trans2, }Interfaces using crypto map Tunnel5-head-0:Tunnel5Step 10
Router# show dmvpnLegend: Attrb --> S - Static, D - Dynamic, I - IncompleteN - NATed, L - Local, X - No Socket# Ent --> Number of NHRP entries with same NBMA peer! The line below indicates that the sessions are being displayed for Tunnel1.! Tunnel1 is acting as a spoke and is a peer with three other NBMA peers.Tunnel1, Type: Spoke, NBMA Peers: 3,# Ent Peer NBMA Addr Peer Tunnel Add State UpDn Tm Attrb----- --------------- --------------- ----- -------- -----2 192.0.2.21 192.0.2.116 IKE 3w0d D1 192.0.2.102 192.0.2.11 NHRP 02:40:51 S1 192.0.2.225 192.0.2.10 UP 3w0d STunnel2, Type: Spoke, NBMA Peers: 1,# Ent Peer NBMA Addr Peer Tunnel Add State UpDn Tm Attrb----- --------------- --------------- ----- -------- -----1 192.0.2.25 192.0.2.171 IKE never SStep 11
Router# show ip nhrp traffic interface tunnel7
Tunnel7: Max-send limit:100Pkts/10Sec, Usage:0%Sent: Total 7918 Resolution Request 10 Resolution Reply 42 Registration Request0 Registration Reply 3 Purge Request 6 Purge Reply0 Error Indication 0 Traffic IndicationRcvd: Total 6910 Resolution Request 15 Resolution Reply 0 Registration Request36 Registration Reply 6 Purge Request 2 Purge Reply0 Error Indication 0 Traffic Indication
What to Do Next
If you have troubleshooted your DMVPN configuration and proceed to contact technical support, the show tech-support command includes information for DMVPN sessions. For more information, see the show tech-support command in the Cisco IOS Configuration Fundamentals Command Reference.
Configuration Examples for Dynamic Multipoint VPN (DMVPN) Feature
This section provides the following comprehensive configuration examples:
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Example: Hub Configuration for DMVPN
In the following example, which configures the hub router for multipoint GRE and IPsec integration, no explicit configuration lines are needed for each spoke; that is, the hub is configured with a global IPsec policy template that all spoke routers can talk to. In this example, EIGRP is configured to run over the private physical interface and the tunnel interface.
crypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco47 address 0.0.0.0!crypto ipsec transform-set trans2 esp-des esp-md5-hmacmode transport!crypto ipsec profile vpnprofset transform-set trans2!interface Tunnel0bandwidth 1000ip address 10.0.0.1 255.255.255.0! Ensures longer packets are fragmented before they are encrypted; otherwise, the receiving router would have to do the reassembly.ip mtu 1400! The following line must match on all nodes that "want to use" this mGRE tunnel:ip nhrp authentication donttell! Note that the next line is required only on the hub.ip nhrp map multicast dynamic! The following line must match on all nodes that want to use this mGRE tunnel:ip nhrp network-id 99ip nhrp holdtime 300! Turns off split horizon on the mGRE tunnel interface; otherwise, EIGRP will not advertise routes that are learned via the mGRE interface back out that interface.no ip split-horizon eigrp 1! Enables dynamic, direct spoke-to-spoke tunnels when using EIGRP.no ip next-hop-self eigrp 1ip tcp adjust-mss 1360delay 1000! Sets IPsec peer address to Ethernet interface's public address.tunnel source Ethernet0tunnel mode gre multipoint! The following line must match on all nodes that want to use this mGRE tunnel.tunnel key 100000tunnel protection ipsec profile vpnprof!interface Ethernet0ip address 172.17.0.1 255.255.255.0!interface Ethernet1ip address 192.168.0.1 255.255.255.0!router eigrp 1network 10.0.0.0 0.0.0.255network 192.168.0.0 0.0.0.255!For information about defining and configuring ISAKMP profiles, see the references in the "Related Documents" section.
Example: Spoke Configuration for DMVPN
In the following example, all spokes are configured the same except for tunnel and local interface address, thereby, reducing necessary configurations for the user:
crypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco47 address 0.0.0.0!crypto ipsec transform-set trans2 esp-des esp-md5-hmacmode transport!crypto ipsec profile vpnprofset transform-set trans2!interface Tunnel0bandwidth 1000ip address 10.0.0.2 255.255.255.0ip mtu 1400! The following line must match on all nodes that want to use this mGRE tunnel:ip nhrp authentication donttell! Definition of NHRP server at the hub (10.0.0.1), which is permanently mapped to the static public address of the hub (172.17.0.1).ip nhrp map 10.0.0.1 172.17.0.1! Sends multicast packets to the hub router, and enables the use of a dynamic routing protocol between the spoke and the hub.ip nhrp map multicast 172.17.0.1! The following line must match on all nodes that want to use this mGRE tunnel:ip nhrp network-id 99ip nhrp holdtime 300! Configures the hub router as the NHRP next-hop server.ip nhrp nhs 10.0.0.1ip tcp adjust-mss 1360delay 1000tunnel source Ethernet0tunnel mode gre multipoint! The following line must match on all nodes that want to use this mGRE tunnel:tunnel key 100000tunnel protection ipsec profile vpnprof!! This is a spoke, so the public address might be dynamically assigned via DHCP.interface Ethernet0ip address dhcp hostname Spoke1!interface Ethernet1ip address 192.168.1.1 255.255.255.0!! EIGRP is configured to run over the inside physical interface and the tunnel.router eigrp 1network 10.0.0.0 0.0.0.255network 192.168.1.0 0.0.0.255Example: VRF Aware DMVPN
When configuring VRF Aware DMVPN, you must create a separate DMVPN network for each VRF instance. In the following example, there are two DMVPN networks: BLUE and RED. In addition, a separate source interface has been used on the hub for each DMVPN tunnel—a must for Cisco IOS Release 12.2(18)SXE. For other Cisco IOS releases, you can configure the same tunnel source for both of the tunnel interfaces, but you must configure the tunnel key and tunnel protection (tunnel protection ipsec profile {name} shared) commands.
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Hub Configuration
interface Tunnel0! Note the next line.ip vrf forwarding BLUEbandwidth 1000ip address 10.0.0.1 255.255.255.0ip mtu 1436! Note the next line.ip nhrp authentication BLUE!KEYip nhrp map multicast dynamic! Note the next lineip nhrp network-id 100000ip nhrp holdtime 600no ip split-horizon eigrp 1no ip next-hop-self eigrp 1ip tcp adjust-mss 1360delay 1000! Note the next line.tunnel source Ethernet0tunnel mode gre multipointtunnel protection ipsec profile vpnprof!interface Tunnel1! Note the next line.ip vrf forwarding REDbandwidth 1000ip address 10.0.0.1 255.255.255.0ip mtu 1436! Note the next line.ip nhrp authentication RED!KEYip nhrp map multicast dynamic! Note the next line.ip nhrp network-id 20000ip nhrp holdtime 600no ip split-horizon eigrp 1no ip next-hop-self eigrp 1ip tcp adjust-mss 1360delay 1000! Note the next line.tunnel source Ethernet1tunnel mode gre multipointtunnel protection ipsec profile vpnprof!interface Ethernet0ip address 172.17.0.1 255.255.255.0interface Ethernet1ip address 192.0.2.171 255.255.255.0
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EIGRP Configuration on the Hub
router eigrp 1auto-summary!address-family ipv4 vrf BLUEnetwork 10.0.0.0 0.0.0.255no auto-summaryautonomous-system 1exit-address-family!address-family ipv4 vrf REDnetwork 10.0.0.0 0.0.0.255no auto-summaryautonomous-system 1exit-address-familySpoke Configurations
Spoke 1:
interface Tunnel0bandwidth 1000ip address 10.0.0.2 255.255.255.0ip mtu 1436! Note the next line.ip nhrp authentication BLUE!KEYip nhrp map 10.0.0.1 172.17.0.1ip nhrp network-id 100000ip nhrp holdtime 300ip nhrp nhs 10.0.0.1ip tcp adjust-mss 1360delay 1000tunnel mode gre multipointtunnel source Ethernet0tunnel destination 172.17.0.1tunnel protection ipsec profile vpnprofSpoke 2:
interface Tunnel0bandwidth 1000ip address 10.0.0.2 255.255.255.0ip mtu 1436ip nhrp authentication RED!KEYip nhrp map 10.0.0.1 192.0.2.171ip nhrp network-id 200000ip nhrp holdtime 300ip nhrp nhs 10.0.0.1ip tcp adjust-mss 1360delay 1000tunnel source Ethernet0tunnel destination 192.0.2.171tunnel protection ipsec profile vpnprof!Example: 2547oDMVPN with Traffic Segmentation (with BGP only)
The following example show a traffic segmentation configuration in which traffic is segmented between two spokes that serve as provider edge (PE) devices.
Hub Configuration
hostname hub-pe1boot-start-markerboot-end-markerno aaa new-modelresource policyclock timezone EST 0ip cefno ip domain lookup!This section refers to the forwarding table for VRF blue:ip vrf bluerd 2:2route-target export 2:2route-target import 2:2!This section refers to the forwarding table for VRF red:ip vrf redrd 1:1route-target export 1:1route-target import 1:1mpls label protocol ldpcrypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco address 0.0.0.0 0.0.0.0crypto ipsec transform-set t1 esp-desmode transportcrypto ipsec profile profset transform-set t1interface Tunnel1ip address 10.9.9.1 255.255.255.0no ip redirectsip nhrp authentication ciscoip nhrp map multicast dynamicip nhrp network-id 1!The command below enables MPLS on the DMVPN network:mpls iptunnel source Ethernet0/0tunnel mode gre multipointtunnel protection ipsec profile profinterface Loopback0ip address 10.0.0.1 255.255.255.255interface Ethernet0/0ip address 172.0.0.1 255.255.255.0!The multiprotocol BGP route reflector (the hub) configuration changes the next-hop information to set itself as the next-hop and assigns a new VPN label for the prefixes learned from the spokes and advertises the VPN prefix:router bgp 1no synchronizationbgp log-neighbor-changesneighbor 10.0.0.11 remote-as 1neighbor 10.0.0.11 update-source Tunnel1neighbor 10.0.0.12 remote-as 1neighbor 10.0.0.12 update-source Tunnel1no auto-summaryaddress-family vpnv4neighbor 10.0.0.11 activateneighbor 10.0.0.11 send-community extendedneighbor 10.0.0.11 route-reflector-clientneighbor 10.0.0.11 route-map NEXTHOP outneighbor 10.0.0.12 activateneighbor 10.0.0.12 send-community extendedneighbor 10.0.0.12 route-reflector-clientneighbor 10.0.0.12 route-map NEXTHOP outexit-address-familyaddress-family ipv4 vrf redredistribute connectedno synchronizationexit-address-familyaddress-family ipv4 vrf blueredistribute connectedno synchronizationexit-address-familyno ip http serverno ip http secure-server!In this route map information, the hub sets the next hop to itself, and the VPN prefixes are advertised:route-map NEXTHOP permit 10set ip next-hop 10.0.0.1control-planeline con 0logging synchronousline aux 0line vty 0 4no loginendSpoke Configurations
Spoke 2
hostname spoke-pe2boot-start-markerboot-end-markerno aaa new-modelresource policyclock timezone EST 0ip cefno ip domain lookup!This section refers to the forwarding table for VRF blue:ip vrf bluerd 2:2route-target export 2:2route-target import 2:2!This section refers to the forwarding table for VRF red:ip vrf redrd 1:1route-target export 1:1route-target import 1:1mpls label protocol ldpcrypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco address 0.0.0.0 0.0.0.0crypto ipsec transform-set t1 esp-desmode transportcrypto ipsec profile profset transform-set t1interface Tunnel1ip address 10.0.0.11 255.255.255.0no ip redirectsip nhrp authentication ciscoip nhrp map multicast dynamicip nhrp map 10.0.0.1 172.0.0.1ip nhrp map multicast 172.0.0.1ip nhrp network-id 1ip nhrp nhs 10.0.0.1!The command below enables MPLS on the DMVPN network:mpls iptunnel source Ethernet0/0tunnel mode gre multipointtunnel protection ipsec profile profinterface Loopback0ip address 10.9.9.11 255.255.255.255interface Ethernet0/0ip address 172.0.0.11 255.255.255.0!!interface Ethernet1/0ip vrf forwarding redip address 192.168.11.2 255.255.255.0interface Ethernet2/0ip vrf forwarding blueip address 192.168.11.2 255.255.255.0!The multiprotocol BGP route reflector (the hub) configuration changes the next-hop information to set itself as the next-hop and assigns a new VPN label for the prefixes learned from the spokes and advertises the VPN prefix:router bgp 1no synchronizationbgp log-neighbor-changesneighbor 10.0.0.1 remote-as 1neighbor 10.0.0.1 update-source Tunnel1no auto-summaryaddress-family vpnv4neighbor 10.0.0.1 activateneighbor 10.0.0.1 send-community extendedexit-address-family!address-family ipv4 vrf redredistribute connectedno synchronizationexit-address-family!address-family ipv4 vrf blueredistribute connectedno synchronizationexit-address-familyno ip http serverno ip http secure-servercontrol-planeline con 0logging synchronousline aux 0line vty 0 4no loginendSpoke 3
hostname spoke-PE3boot-start-markerboot-end-markerno aaa new-modelresource policyclock timezone EST 0ip cefno ip domain lookup!This section refers to the forwarding table for VRF blue:ip vrf bluerd 2:2route-target export 2:2route-target import 2:2!This section refers to the forwarding table for VRF red:ip vrf redrd 1:1route-target export 1:1route-target import 1:1mpls label protocol ldpcrypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco address 0.0.0.0 0.0.0.0crypto ipsec transform-set t1 esp-desmode transportcrypto ipsec profile profset transform-set t1interface Tunnel1ip address 10.0.0.12 255.255.255.0no ip redirectsip nhrp authentication ciscoip nhrp map multicast dynamicip nhrp map 10.0.0.1 172.0.0.1ip nhrp map multicast 172.0.0.1ip nhrp network-id 1ip nhrp nhs 10.0.0.1!The command below enables MPLS on the DMVPN network:mpls iptunnel source Ethernet0/0tunnel mode gre multipointtunnel protection ipsec profile prof!interface Loopback0ip address 10.9.9.12 255.255.255.255interface Ethernet0/0ip address 172.0.0.12 255.255.255.0interface Ethernet1/0ip vrf forwarding redip address 192.168.12.2 255.255.255.0interface Ethernet2/0ip vrf forwarding blueip address 192.168.12.2 255.255.255.0!The multiprotocol BGP route reflector (the hub) configuration changes the next-hop information to set itself as the next-hop and assigns a new VPN label for the prefixes learned from the spokes and advertises the VPN prefix:router bgp 1no synchronizationbgp log-neighbor-changesneighbor 10.0.0.1 remote-as 1neighbor 10.0.0.1 update-source Tunnel1no auto-summaryaddress-family vpnv4neighbor 10.0.0.1 activateneighbor 10.0.0.1 send-community extendedexit-address-familyaddress-family ipv4 vrf redredistribute connectedno synchronizationexit-address-familyaddress-family ipv4 vrf blueredistribute connectedno synchronizationexit-address-familyno ip http serverno ip http secure-servercontrol-planeline con 0logging synchronousline aux 0line vty 0 4no loginendExample: 2547oDMVPN with Traffic Segmentation (Enterprise Branch)
The following example shows a configuration for segmenting traffic between two spokes located at branch offices of an enterprise. In this example, EIGRP is configured to learn routes to reach BGP neighbors within the DMVPN.
Hub Configuration
hostname HUBboot-start-markerboot-end-markerno aaa new-modelresource policyclock timezone EST 0ip cefno ip domain lookup!This section refers to the forwarding table for VRF blue:ip vrf bluerd 2:2route-target export 2:2route-target import 2:2!This refers to the forwarding table for VRF red:ip vrf redrd 1:1route-target export 1:1route-target import 1:1mpls label protocol ldpcrypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco address 0.0.0.0 0.0.0.0crypto ipsec transform-set t1 esp-desmode transportcrypto ipsec profile profset transform-set t1interface Tunnel1ip address 10.0.0.1 255.255.255.0no ip redirectsip nhrp authentication ciscoip nhrp map multicast dynamicip nhrp network-id 1!EIGRP is enabled on the DMVPN network to learn the IGP prefixes:no ip split-horizon eigrp 1!The command below enables MPLS on the DMVPN network:mpls iptunnel source Ethernet0/0tunnel mode gre multipointtunnel protection ipsec profile prof!This address is advertised by EIGRP and used as the BGP endpoint:interface Loopback0ip address 10.9.9.1 255.255.255.255interface Ethernet0/0ip address 172.0.0.1 255.255.255.0!EIGRP is configured to learn the BGP peer addresses (10.9.9.x networks)router eigrp 1network 10.9.9.1 0.0.0.0network 10.0.0.0 0.0.0.255no auto-summary!The multiprotocol BGP route reflector (the hub) configuration changes the next-hop information to set itself as the next-hop and assigns a new VPN label for the prefixes learned from the spokes and advertises the VPN prefix:router bgp 1no synchronizationbgp router-id 10.9.9.1bgp log-neighbor-changesneighbor 10.9.9.11 remote-as 1neighbor 10.9.9.11 update-source Loopback0neighbor 10.9.9.12 remote-as 1neighbor 10.9.9.12 update-source Loopback0no auto-summaryaddress-family vpnv4neighbor 10.9.9.11 activateneighbor 10.9.9.11 send-community extendedneighbor 10.9.9.11 route-reflector-clientneighbor 10.9.9.12 activateneighbor 10.9.9.12 send-community extendedneighbor 10.9.9.12 route-reflector-clientexit-address-familyaddress-family ipv4 vrf redredistribute connectedno synchronizationexit-address-familyaddress-family ipv4 vrf blueredistribute connectedno synchronizationexit-address-familyno ip http serverno ip http secure-servercontrol-planeline con 0logging synchronousline aux 0line vty 0 4no loginendSpoke Configurations
Spoke 2
hostname Spoke2boot-start-markerboot-end-markerno aaa new-modelresource policyclock timezone EST 0ip cefno ip domain lookup!This section refers to the forwarding table for VRF blue:ip vrf bluerd 2:2route-target export 2:2route-target import 2:2!This section refers to the forwarding table for VRF red:ip vrf redrd 1:1route-target export 1:1route-target import 1:1mpls label protocol ldpcrypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco address 0.0.0.0 0.0.0.0crypto ipsec transform-set t1 esp-desmode transportcrypto ipsec profile profset transform-set t1interface Tunnel1ip address 10.0.0.11 255.255.255.0no ip redirectsip nhrp authentication ciscoip nhrp map multicast dynamicip nhrp map 10.0.0.1 172.0.0.1ip nhrp map multicast 172.0.0.1ip nhrp network-id 1ip nhrp nhs 10.0.0.1!The command below enables MPLS on the DMVPN network:mpls iptunnel source Ethernet0/0tunnel mode gre multipointtunnel protection ipsec profile prof!This address is advertised by EIGRP and used as the BGP endpoint:interface Loopback0ip address 10.9.9.11 255.255.255.255interface Ethernet0/0ip address 172.0.0.11 255.255.255.0interface Ethernet1/0ip vrf forwarding redip address 192.168.11.2 255.255.255.0interface Ethernet2/0ip vrf forwarding blueip address 192.168.11.2 255.255.255.0!EIGRP is enabled on the DMVPN network to learn the IGP prefixes:router eigrp 1network 10.9.9.11 0.0.0.0network 10.0.0.0 0.0.0.255no auto-summary!The multiprotocol BGP route reflector (the hub) configuration changes the next-hop information to set itself as the next-hop and assigns a new VPN label for the prefixes learned from the spokes and advertises the VPN prefix:router bgp 1no synchronizationbgp router-id 10.9.9.11bgp log-neighbor-changesneighbor 10.9.9.1 remote-as 1neighbor 10.9.9.1 update-source Loopback0no auto-summaryaddress-family vpnv4neighbor 10.9.9.1 activateneighbor 10.9.9.1 send-community extendedexit-address-familyaddress-family ipv4 vrf redredistribute connectedno synchronizationexit-address-familyaddress-family ipv4 vrf blueredistribute connectedno synchronizationexit-address-familyno ip http serverno ip http secure-servercontrol-planeline con 0logging synchronousline aux 0line vty 0 4no loginendSpoke 3
hostname Spoke3boot-start-markerboot-end-markerno aaa new-modelresource policyclock timezone EST 0ip cefno ip domain lookup!This section refers to the forwarding table for VRF blue:ip vrf bluerd 2:2route-target export 2:2route-target import 2:2!This section refers to the forwarding table for VRF red:ip vrf redrd 1:1route-target export 1:1route-target import 1:1mpls label protocol ldpcrypto isakmp policy 1authentication pre-sharecrypto isakmp key cisco address 0.0.0.0 0.0.0.0crypto ipsec transform-set t1 esp-desmode transportcrypto ipsec profile profset transform-set t1interface Tunnel1ip address 10.0.0.12 255.255.255.0no ip redirectsip nhrp authentication ciscoip nhrp map multicast dynamicip nhrp map 10.0.0.1 172.0.0.1ip nhrp map multicast 172.0.0.1ip nhrp network-id 1ip nhrp nhs 10.0.0.1!The command below enables MPLS on the DMVPN network:mpls iptunnel source Ethernet0/0tunnel mode gre multipointtunnel protection ipsec profile prof!This address is advertised by EIGRP and used as the BGP endpoint:interface Loopback0ip address 10.9.9.12 255.255.255.255interface Ethernet0/0ip address 172.0.0.12 255.255.255.0interface Ethernet1/0ip vrf forwarding redip address 192.168.12.2 255.255.255.0interface Ethernet2/0ip vrf forwarding blueip address 192.168.12.2 255.255.255.0!EIGRP is enabled on the DMVPN network to learn the IGP prefixes:router eigrp 1network 10.9.9.12 0.0.0.0network 10.0.0.0 0.0.0.255no auto-summary!The multiprotocol BGP route reflector (the hub) configuration changes the next-hop information to set itself as the next-hop and assigns a new VPN label for the prefixes learned from the spokes and advertises the VPN prefix:router bgp 1no synchronizationbgp router-id 10.9.9.12bgp log-neighbor-changesneighbor 10.9.9.1 remote-as 1neighbor 10.9.9.1 update-source Loopback0no auto-summaryaddress-family vpnv4neighbor 10.9.9.1 activateneighbor 10.9.9.1 send-community extendedexit-address-familyaddress-family ipv4 vrf redredistribute connectedno synchronizationexit-address-familyaddress-family ipv4 vrf blueredistribute connectedno synchronizationexit-address-familyno ip http serverno ip http secure-servercontrol-planeline con 0logging synchronousline aux 0line vty 0 4no loginendSample Command Output: show mpls ldp bindings
Spoke2# show mpls ldp bindingstib entry: 10.9.9.1/32, rev 8local binding: tag: 16remote binding: tsr: 10.9.9.1:0, tag: imp-nulltib entry: 10.9.9.11/32, rev 4local binding: tag: imp-nullremote binding: tsr: 10.9.9.1:0, tag: 16tib entry: 10.9.9.12/32, rev 10local binding: tag: 17remote binding: tsr: 10.9.9.1:0, tag: 17tib entry: 10.0.0.0/24, rev 6local binding: tag: imp-nullremote binding: tsr: 10.9.9.1:0, tag: imp-nulltib entry: 172.0.0.0/24, rev 3local binding: tag: imp-nullremote binding: tsr: 10.9.9.1:0, tag: imp-nullSpoke2#Sample Command Output: show mpls forwarding-table
Spoke2# show mpls forwarding-tableLocal Outgoing Prefix Bytes tag Outgoing Next Hoptag tag or VC or Tunnel Id switched interface16 Pop tag 10.9.9.1/32 0 Tu1 10.0.0.117 17 10.9.9.12/32 0 Tu1 10.0.0.118 Aggregate 192.168.11.0/24[V] \019 Aggregate 192.168.11.0/24[V] \0Spoke2#Sample Command Output: show ip route vrf red
Spoke2# show ip route vrf redRouting Table: redCodes: C - connected, S - static, R - RIP, M - mobile, B - BGPD - EIGRP, EX - EIGRP external, O - OSPF, IA - OSPF inter areaN1 - OSPF NSSA external type 1, N2 - OSPF NSSA external type 2E1 - OSPF external type 1, E2 - OSPF external type 2i - IS-IS, su - IS-IS summary, L1 - IS-IS level-1, L2 - IS-IS level-2ia - IS-IS inter area, * - candidate default, U - per-user static routeo - ODR, P - periodic downloaded static routeGateway of last resort is not setB 192.168.12.0/24 [200/0] via 10.9.9.12, 00:00:02C 192.168.11.0/24 is directly connected, Ethernet1/0Spoke2#Sample Command Output: show ip route vrf blue
Spoke2# show ip route vrf blueRouting Table: blueCodes: C - connected, S - static, R - RIP, M - mobile, B - BGPD - EIGRP, EX - EIGRP external, O - OSPF, IA - OSPF inter areaN1 - OSPF NSSA external type 1, N2 - OSPF NSSA external type 2E1 - OSPF external type 1, E2 - OSPF external type 2i - IS-IS, su - IS-IS summary, L1 - IS-IS level-1, L2 - IS-IS level-2ia - IS-IS inter area, * - candidate default, U - per-user static routeo - ODR, P - periodic downloaded static routeGateway of last resort is not setB 192.168.12.0/24 [200/0] via 10.9.9.12, 00:00:08C 192.168.11.0/24 is directly connected, Ethernet2/0Spoke2#Spoke2# show ip cef vrf red 192.168.12.0192.168.12.0/24, version 5, epoch 00 packets, 0 bytestag information setlocal tag: VPN-route-headfast tag rewrite with Tu1, 10.0.0.1, tags imposed: {17 18}via 10.9.9.12, 0 dependencies, recursivenext hop 10.0.0.1, Tunnel1 via 10.9.9.12/32valid adjacencytag rewrite with Tu1, 10.0.0.1, tags imposed: {17 18}Spoke2#Sample Command Output: show ip bgp neighbors
Spoke2# show ip bgp neighborsBGP neighbor is 10.9.9.1, remote AS 1, internal linkBGP version 4, remote router ID 10.9.9.1BGP state = Established, up for 00:02:09Last read 00:00:08, last write 00:00:08, hold time is 180, keepalive interval is 60 secondsNeighbor capabilities:Route refresh: advertised and received(old & new)Address family IPv4 Unicast: advertised and receivedAddress family VPNv4 Unicast: advertised and receivedMessage statistics:InQ depth is 0OutQ depth is 0Sent RcvdOpens: 1 1Notifications: 0 0Updates: 4 4Keepalives: 4 4Route Refresh: 0 0Total: 9 9Default minimum time between advertisement runs is 0 secondsFor address family: IPv4 UnicastBGP table version 1, neighbor version 1/0Output queue size : 0Index 1, Offset 0, Mask 0x21 update-group memberSent RcvdPrefix activity: ---- ----Prefixes Current: 0 0Prefixes Total: 0 0Implicit Withdraw: 0 0Explicit Withdraw: 0 0Used as bestpath: n/a 0Used as multipath: n/a 0Outbound InboundLocal Policy Denied Prefixes: -------- -------Total: 0 0Number of NLRIs in the update sent: max 0, min 0For address family: VPNv4 UnicastBGP table version 9, neighbor version 9/0Output queue size : 0Index 1, Offset 0, Mask 0x21 update-group memberSent RcvdPrefix activity: ---- ----Prefixes Current: 2 2 (Consumes 136 bytes)Prefixes Total: 4 2Implicit Withdraw: 2 0Explicit Withdraw: 0 0Used as bestpath: n/a 2Used as multipath: n/a 0Outbound InboundLocal Policy Denied Prefixes: -------- -------ORIGINATOR loop: n/a 2Bestpath from this peer: 4 n/aTotal: 4 2Number of NLRIs in the update sent: max 1, min 1Connections established 1; dropped 0Last reset neverConnection state is ESTAB, I/O status: 1, unread input bytes: 0Connection is ECN DisabledLocal host: 10.9.9.11, Local port: 179Foreign host: 10.9.9.1, Foreign port: 12365Enqueued packets for retransmit: 0, input: 0 mis-ordered: 0 (0 bytes)Event Timers (current time is 0x2D0F0):Timer Starts Wakeups NextRetrans 6 0 0x0TimeWait 0 0 0x0AckHold 7 3 0x0SendWnd 0 0 0x0KeepAlive 0 0 0x0GiveUp 0 0 0x0PmtuAger 0 0 0x0DeadWait 0 0 0x0iss: 3328307266 snduna: 3328307756 sndnxt: 3328307756 sndwnd: 15895irs: 4023050141 rcvnxt: 4023050687 rcvwnd: 16384 delrcvwnd: 0SRTT: 165 ms, RTTO: 1457 ms, RTV: 1292 ms, KRTT: 0 msminRTT: 0 ms, maxRTT: 300 ms, ACK hold: 200 msFlags: passive open, nagle, gen tcbsIP Precedence value : 6Datagrams (max data segment is 536 bytes):Rcvd: 13 (out of order: 0), with data: 7, total data bytes: 545Sent: 11 (retransmit: 0, fastretransmit: 0, partialack: 0, Second Congestion: 0), with data: 6, total data bytes: 489Spoke2#Additional References
Related Documents
Cisco IOS commands
Call Admission Control
GRE tunnel keepalive information
Generic Routing Encapsulation (GRE) Tunnel Keepalive, Cisco IOS Release 12.2(8)T
IKE configuration tasks such as defining an IKE policy
The chapter "Configuring Internet Key Exchange for IPSec VPNs" in the Cisco IOS Security Configuration Guide: Secure Connectivity
IPsec configuration tasks
The chapter "Configuring Security for VPNs with IPsec" in the Cisco IOS Security Configuration Guide: Secure Connectivity
Configuring VRF-Aware IPsec
The chapter "VRF-Aware IPsec" in the Cisco IOS Security Configuration Guide: Secure Connectivity
Configuring MPLS
The chapter "Configuring Multiprotocol Label Switching" in the Cisco IOS Multiprotocol Label Switching Configuration Guide
Configuring BGP
The chapter "Cisco BGP Overview" in the Cisco IOS IP Routing: BGP Protocols Configuration Guide
System messages
System Message Guide
Defining and configuring ISAKMP profiles
"Certificate to ISAKMP Profile Mapping" chapter in the Cisco IOS Security Configuration Guide: Secure Connectivity
Standards
MIBs
None
To locate and download MIBs for selected platforms, Cisco software releases, and feature sets, use Cisco MIB Locator found at the following URL:
RFCs
Technical Assistance
Feature Information for Dynamic Multipoint VPN (DMVPN)
Table 1 lists the features in this module and provides links to specific configuration information.
Use Cisco Feature Navigator to find information about platform support and software image support. Cisco Feature Navigator enables you to determine which software images support a specific software release, feature set, or platform. To access Cisco Feature Navigator, go to http://www.cisco.com/go/cfn. An account on Cisco.com is not required.
Note
Table 1 Feature Information for Dynamic Multipoint VPN (DMVPN)
DMVPN—Enabling Traffic Segmentation Within DMVPN
12.4(11)T
The 2547oDMVPN feature allows users to segment VPN traffic within a DMVPN tunnel by applying MPLS labels to VRF instances to indicate the source and destination of each VRF.
Mangeability Enhancements for DMVPN
12.4(9)T
DMVPN session manageabilty was expanded with DMVPN specific commands for debugging, show output, session and counter control, and system log information.
The following sections provide information about this feature:
•
The following commands were introduced or modified by this feature: clear dmvpn session, clear dmvpn statistics, debug dmvpn, debug nhrp condition, debug nhrp error, logging dmvpn, show dmvpn, show ip nhrp traffic.
DMVPN Phase 2
12.2(18)SXE
12.3(9)a
12.3(8)T1DMVPN Spoke-to-Spoke functionality was made more production ready. If you are using this functionality in a production network, the minimum release is Release 12.3(9a) or Release 12.3(8)T1.
In Release 12.2(18)SXE, support was added for the Cisco Catalyst 6500 series switch and the Cisco 7600 series router.
—
12.3(6)
12.3(7)TVirtual Route Forwarding Integrated DMVPN and Network Address Translation-Transparency (NAT-T) Aware DMVPN enhancements were added. In addition, DMVPN Hub-to-Spoke functionality was made more production ready. If you are using this functionality in a production network, the minimum release requirement is Cisco IOS Release12.3(6) or 12.3(7)T.
The enhancements added in Cisco IOS Release 12.3(6) were integrated into Cisco IOS Release 12.3(7)T.
Dynamic Multipoint VPN (DMVPN) Phase 1
12.2(13)T
The Dynamic Multipoint VPN (DMVPN) feature allows users to better scale large and small IPsec Virtual Private Networks (VPNs) by combining generic routing encapsulation (GRE) tunnels, IP security (IPsec) encryption, and Next Hop Resolution Protocol (NHRP).
Glossary
AM—aggressive mode. A mode during IKE negotiation. Compared to MM, AM eliminates several steps, making it faster but less secure than MM. Cisco IOS software will respond in aggressive mode to an IKE peer that initiates aggressive mode.
GRE—generic routing encapsulation. Tunnels that provide a specific pathway across the shared WAN and encapsulate traffic with new packet headers to ensure delivery to specific destinations. The network is private because traffic can enter a tunnel only at an endpoint. Tunnels do not provide true confidentiality (encryption does) but can carry encrypted traffic.
GRE tunneling can also be used to encapsulate non-IP traffic into IP and send it over the Internet or IP network. The Internet Package Exchange (IPX) and AppleTalk protocols are examples of non-IP traffic.
IKE—Internet Key Exchange. A hybrid protocol that implements Oakley key exchange and Skeme key exchange inside the ISAKMP framework. Although IKE can be used with other protocols, its initial implementation is with IPsec. IKE provides authentication of the IPsec peers, negotiates IPsec keys, and negotiates IPsec security associations.
IPsec—IP security. A framework of open standards developed by the Internet Engineering Task Force (IETF). IPsec provides security for transmission of sensitive information over unprotected networks such as the Internet. IPsec acts at the network layer, protecting and authenticating IP packets between participating IPsec devices ("peers"), such as Cisco routers.
ISAKMP—Internet Security Association Key Management Protocol. A protocol framework that defines payload formats, the mechanics of implementing a key exchange protocol, and the negotiation of a security association.
MM—main mode. Mode that is slower than aggressive mode but more secure and more flexible than aggressive mode because it can offer an IKE peer more security proposals. The default action for IKE authentication (rsa-sig, rsa-encr, or preshared) is to initiate main mode.
NHRP—Next Hop Resolution Protocol. Routers, access servers, and hosts can use NHRP to discover the addresses of other routers and hosts connected to a NBMA network.
The Cisco implementation of NHRP supports the IETF draft version 11 of NBMA Next Hop Resolution Protocol (NHRP).
The Cisco implementation of NHRP supports IP Version 4, Internet Packet Exchange (IPX) network layers, and, at the link layer, ATM, Ethernet, SMDS, and multipoint tunnel networks. Although NHRP is available on Ethernet, NHRP need not be implemented over Ethernet media because Ethernet is capable of broadcasting. Ethernet support is unnecessary (and not provided) for IPX.
PFS—Perfect Forward Secrecy. A cryptographic characteristic associated with a derived shared secret value. With PFS, if one key is compromised, previous and subsequent keys are not compromised, because subsequent keys are not derived from previous keys.
SA—security association. Describes how two or more entities will utilize security services to communicate securely. For example, an IPsec SA defines the encryption algorithm (if used), the authentication algorithm, and the shared session key to be used during the IPsec connection.
Both IPsec and IKE require and use SAs to identify the parameters of their connections. IKE can negotiate and establish its own SA. The IPsec SA is established either by IKE or by manual user configuration.
transform—The list of operations done on a dataflow to provide data authentication, data confidentiality, and data compression. For example, one transform is the ESP protocol with the HMAC-MD5 authentication algorithm; another transform is the AH protocol with the 56-bit DES encryption algorithm and the ESP protocol with the HMAC-SHA authentication algorithm.
VPN—Virtual Private Network. A framework that consists of multiple peers transmitting private data securely to one another over an otherwise public infrastructure. In this framework, inbound and outbound network traffic is protected using protocols that tunnel and encrypt all data. This framework permits networks to extend beyond their local topology, while remote users are provided with the appearance and functionality of a direct network connection.
Cisco and the Cisco Logo are trademarks of Cisco Systems, Inc. and/or its affiliates in the U.S. and other countries. A listing of Cisco's trademarks can be found at www.cisco.com/go/trademarks. Third party trademarks mentioned are the property of their respective owners. The use of the word partner does not imply a partnership relationship between Cisco and any other company. (1005R)
Any Internet Protocol (IP) addresses used in this document are not intended to be actual addresses. Any examples, command display output, and figures included in the document are shown for illustrative purposes only. Any use of actual IP addresses in illustrative content is unintentional and coincidental.
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