VxLAN Support

This module contains information about VxLAN (Virtual eXtensible Local Area Network) Layer 2 gateway feature support on the Cisco ASR 1000 Series Routers. VxLAN is a technology that provides a Layer 2 overlay network, allowing for network isolation. The standard 802.1q VLAN implementation limits the number of tags to 4096. However, cloud service providers may want to operate more than 4096 virtual networks. VxLAN uses a 24-bit network ID, which allows for a much larger number of individual i networks to be operated.

Finding Feature Information

Your software release may not support all the features documented in this module. For the latest caveats and feature information, 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 at the end of this module.

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.

Prerequisites for VxLAN Support

The following are the prerequisites to configuring the Cisco ASR 1000 Routers as a VxLAN Layer 2 gateway:

  1. Configure the loopback interface.
  2. Configure the IP unicast reachability to remote VTEP's.
  3. Configure Bidirectional Protocol Independent Multicast (PIM) or Protocol Independent Multicast-Sparse Mode (PIM-SM).

For more information, see the IP Multicast: PIM Configuration Guide, Cisco IOS XE Release 3S .

Information About VxLAN Support

This feature enables the Cisco ASR 1000 Series Routers to act as a Layer 2 VxLAN gateway to provide support to bridge traffic across VxLAN segments in a hypervisor and on VLANs on physical servers. The operation of a VxLAN Layer 2 gateway is based on the data plane MAC address learning and flooding of multidestination traffic (such as unknown unicast, multicast, or broadcast frames) using IP multicast.

Acting as a VxLAN Layer 2 gateway, the Cisco ASR 1000 Routers can send and receive packets on multiple VxLAN networks, and provide connectivity between the hosts in a VLAN network and the virtual machines operating on a VxLAN network.

A VXLAN supports different modes for flood traffic:

  • Multicast Mode—A VXLAN uses an IP multicast network to send broadcast, multicast, and unknown unicast flood frames. Each multicast mode VXLAN has an assigned multicast group IP address. When a new VM joins a host in a multicast mode VXLAN, the Virtual Tunnel Endpoint (VTEP) joins the assigned multicast group IP address by sending IGMP join messages. Flood traffic, broadcast, multicast and unknown unicast from the VM is encapsulated and is sent using the assigned multicast group IP address as the destination IP address. Packets sent to known unicast MAC addresses are encapsulated and sent directly to the destination server Virtual Tunnel Endpoint (VTEP) IP addresses.
  • Unicast-Only Mode—A VXLAN uses each VEM's single unicast IP address as the destination IP address to send broadcast, multicast, and unknown unicast flood frames of the designated VTEP on each VEM that has at least one VM in the corresponding VXLAN. When a new VM joins the host in a unicast-mode VXLAN, a designated VTEP is selected for receiving flood traffic on that host. This designated VTEP is communicated to all other hosts through the Virtual Supervisor Module (VSM). Flood traffic (broadcast, multicast, and unknown unicast) is replicated on each VEM's designated VTEP in that VXLAN by encapsulating it with a VXLAN header. Packets are sent only to VEMs with a VM in that VXLAN. Packets that have a unicast MAC address are encapsulated and sent directly to the destination server's VTEP IP address.
  • MAC Distribution Mode (supported only in unicast mode)—In this mode, unknown unicast flooding in the network is eliminated. The VSM learns all the MAC addresses from the VEMs in all the VXLANs and distributes those MAC addresses with VTEP IP mappings to other VEMs. Therefore, no unknown unicast MAC address exists in the network when the VMs on the VEMs are communicating and controlled by the same VSM.

The VxLAN Layer 2 gateway performs the following functions:

  • Provides support to bridge traffic between a host in a VLAN domain and VMs behind a virtual switch (vSwitch) in a VxLAN domain. The VLAN and the virtual network identifier (VNI) on the VxLAN should be configured as member ports in the same bridge domain.
  • Implements the Virtual Tunnel Endpoint (VTEP) function, which encapsulates the Layer 2 packet on the IP/UDP tunnel with the VxLAN header (VNI) information before sending it to a multicast group or particular virtual switch on the VxLAN domain.
  • The VTEP function removes the VxLAN header, identifies the bridge domain under which the VNI is configured and then bridges the inner L2 packet to the VLAN side. The bridge function also learns the remote MAC address (the VM's MAC address behind the virtual switch).
  • The Layer 2 gateway carries the inner payload of non-IP (Layer 2 traffic), IPv4, and IPv6 traffic over the VxLAN VNI member.
  • Multiple ingress replication peers can be configured for every VNI up to 32 nodes.

Limitations of VxLAN Support

  1. Platforms that support a new scale number (8192 or 16000) require an 8G RP memory. Scale number for RP memory that is less than 8G is unchanged.
  2. Scale number on platform RP+ESP5 and ASR1002F is unchanged.
  3. VxLAN is not supported on ISR4000 series platforms before Cisco IOS XE Everest 16.5.1.
  4. The maximum NVE interface number is unchanged on all platforms.
  5. The NVE source is supported for lookback interface before Cisco IOS XE Denali 16.3. After Cisco IOS XE Denali 16.3, it can support physical interfaces as well.
  6. The scale enhancement is applicable only for the VxLAN layer 2 and layer 3 gateway feature. Other bridge-domain related features are not impacted.
  7. RP switchover for VxLAN is not supported on these platforms before Cisco IOS XE Denali 16.3.
  8. Only one VNI ID on every bridge-domain is supported.

New Scale Number after Enhancements

The following table lists new VxLAN scale numbers on different platforms after enhancements. All platforms that support a new scale number (8192 or 16000) require an 8G RP memory.

Platform

MAX BD per system

MAX BDI interface per system

MAX VNI per system

RP+ESP200

16000

16000

16000

RP+ESP100

16000

16000

16000

RP+ESP40

16000

16000

16000

RP+ESP20

16000

16000

16000

RP+ESP10

16000

16000

16000

ASR1002-X

16000

16000

16000

ASR1001-X

16000

16000

16000

ASR 1001

8192

8192

8192

CSR1000v

8192

8192

8192

Configuring VxLAN Layer 2 Gateway with Multicast

Configuring the VxLAN UDP Destination Port (Optional)

The default VxLAN UDP destination is 4789. If you want to change the VxLAN UDP destination port value, you must change it before configuring the network virtualization endpoint (NVE) interface.

SUMMARY STEPS

  1. enable
  2. configure terminal
  3. vxlan udp port number

DETAILED STEPS

  Command or Action Purpose
Step 1

enable

Example:


router> enable

Enables privileged EXEC mode.

  • Enter your password if prompted.
Step 2

configure terminal

Example:


router# configure terminal

Enters global configuration mode.

Step 3

vxlan udp port number

Example:


Router(config)# vxlan udp port 1000

Configures the VxLAN UDP destination port number. The default value is 4789.

Creating the Network Virtualization Endpoint (NVE) Interface

You create the network virtualization endpoint (NVE) interface and then assign member virtual network identifiers (VNIs) to it. The mapping between the VNI range and the multicast group range is either one-to-one or many-to-one.

SUMMARY STEPS

  1. interface nve number
  2. source-interface loopback number
  3. member vni {range | startnumber-endnumber } multicast-group startip-address endip-address
  4. member vni range
  5. ingress-replication Unicast IP Addresses
  6. no shutdown

DETAILED STEPS

  Command or Action Purpose
Step 1

interface nve number

Example:


Router(config)# interface nve 1

Creates a network virtualization endpoint (NVE) interface and enters NVE interface configuration mode.

Step 2

source-interface loopback number

Example:


Router(config-if)# source-interface loopback 0

Assigns the previously-created loopback interface to the NVE interface.

Step 3

member vni {range | startnumber-endnumber } multicast-group startip-address endip-address

Example:


Router(config-if)# member  vni  7115  multicast-group  225.1.1.1  

Creates a VNI member or a range of VNI members. Repeat this step for each VNI to be added to the NVE interface. The valid values for the VNI number are from 4096 to 16777215.

Step 4

member vni range

Example:


Router(config-if)# member  vni  7115  

Creates a VNI member or a range of VNI members. Repeat this step for each VNI to be added to the NVE interface. The valid values for the VNI number are from 4096 to 16777215.

Step 5

ingress-replication Unicast IP Addresses

Example:


Router(config-if-nve-vni)# ingress-replication  225.1.1.1  
ingress-replication  225.1.1.2  

Sets up ingress-replication unicast addresses which enables the headend replication functionality.

Step 6

no shutdown

Example:


Router(config-if)# no shutdown

Enables the NVE interface.

Creating the Access Ethernet Flow Point (EFP)

After the member VNI is created, you must create the access Ethernet Flow Point (EFP) for the VLAN interface.

SUMMARY STEPS

  1. interface GigabitEthernet number
  2. service instance id ethernet
  3. encapsulation dot1q vlan-ID
  4. rewrite ingress tag pop 1 symmetric

DETAILED STEPS

  Command or Action Purpose
Step 1

interface GigabitEthernet number

Example:


Router(config)# interface GigabitEthernet1

Enters interface configuration mode.

Step 2

service instance id ethernet

Example:


Router(config-if)# service instance 20  ethernet

Configures an Ethernet service instance on the overlay interface being configured and enters service instance configuration mode.

  • The service instance identifier range is from 1 to 8000.
Step 3

encapsulation dot1q vlan-ID

Example:


Router(config-if-srv)# encapsulation dot1q 100

Defines the VLAN encapsulation format as IEEE 802.1Q and specifies the VLAN identifier.

Step 4

rewrite ingress tag pop 1 symmetric

Example:


Router(config-if-srv)# rewrite ingress tag pop 1 symmetric

Removes the VLAN tag in the Layer 2 traffic before switching to the outgoing VxLAN interface.

Note 
This command is required to remove the VLAN tag before sending the VLAN traffic to VxLAN and adding the VLAN tag in the reverse direction.

Mapping the VLAN to the Bridge Domain

You must map the VLAN created in the previous procedure to the bridge domain.

SUMMARY STEPS

  1. bridge-domain bridge-id
  2. member interface service-instance id
  3. member vni vni-id

DETAILED STEPS

  Command or Action Purpose
Step 1

bridge-domain bridge-id

Example:


Router(config)# bridge-domain 10

Creates a bridge domain and enters bridge domain configuration mode.

The valid range for bridge-id is 1-4096.

Step 2

member interface service-instance id

Example:


Router(config-bdomain)# member 
gigabitEthernet 1 service-instance 1

Binds the bridge domain to the service instance.

Step 3

member vni vni-id

Example:


Router(config-bdomain)# member vni 1010

Maps the VNI to the bridge domain.

What to do next

The following example displays the NVE VNIs configured on the router:


Router# show nve vni
 
Interface  VNI          mcast       VNI state
nve1       5000         230.1.1.1       UP        L2DP 2 N/A

The following example displays the NVE VNIs assigned to NVE interface 1:


Router(config)# show nve vni interface nve1
Interface  VNI          mcast       VNI state
nve1       5000         230.1.1.1       UP        L2DP 2 N/A

The following example shows the status of NVE interface 1:


Router(config)# show nve interface nve1
Interface: nve1, State: Admin Up, Oper Up Encapsulation: Vxlan
source-interface: Loopback0 (primary:11.11.11.11 vrf:0)

The following example shows a detailed display for NVE interface 1:


Router(config)# show nve interface nve1 detail
Interface: nve1, State: Admin Up, Oper Up Encapsulation: Vxlan
source-interface: Loopback0 (primary:11.11.11.11 vrf:0)
Pkts In   Bytes In   Pkts Out  Bytes Out
0          0          0          0

The following example shows the NVE peers configured on the router:


Router(config)# show nve peers
Interface Peer-IP         VNI      Up Time
nve1        230.1.1.1     5000       UP        L2DP 2 N/A
nve2       1.1.1.3        2030      20h  

The following example shows the bridge domain configuration with the entry in bold displaying the VM’s MAC address that was learned on the VxLAN VNI:


Router# show bridge-domain 1000
Bridge-domain 1000 (3 ports in all)
State: UP                    Mac learning: Enabled
Aging-Timer: 300 second(s)
    GigabitEthernet1 service instance 1000
    GigabitEthernet3 service instance 1000
    vni 7639335
   MAC address    Policy  Tag      Age  Pseudoport
   0050.56A4.ECD2 forward dynamic  297  nve1.VNI7639335 VxLAN
src:10.0.0.1  dst:10.0.0.2
   0050.56A4.257A forward dynamic  297  GigabitEthernet3.EFP1000

Configuring VxLAN Layer 2 Gateway with Unicast

The following example shows VxLAN with unicast ingress-replication which is a point-to-point (unicast) configuration.


interface Loopback0
ip address 11.11.11.11 255.255.255.255
!
interface nve1
no ip address
member vni 5001
  ingress-replication 22.22.22.22  < Remote L2 GW loopback ip>
!
source-interface Loopback0
!
bridge-domain 1
member vni 5001
member GigabitEthernet0/2/0 service-instance 1
interface GigabitEthernet0/2/0
service instance 1 ethernet
encapsulation dot1q 100
rewrite ingress tag pop 1 symmetric

The following example shows VxLAN with unicast multiple ingress-replication peers which is a point-to-point (unicast) configuration.


interface Loopback0
ip address 11.11.11.11 255.255.255.255
!
interface nve1
no ip address
member vni 5001
  ingress-replication 22.22.22.22  < Remote L2 GW loopback ip>
		ingress-replication 22.22.22.23  < Remote L2 GW loopback ip>
!
source-interface Loopback0
!
bridge-domain 1
member vni 5001
member GigabitEthernet0/2/0 service-instance 1
interface GigabitEthernet0/2/0
service instance 1 ethernet
encapsulation dot1q 100
rewrite ingress tag pop 1 symmetric

Feature Information for VxLAN Support

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 VxLAN Support

Feature Name

Releases

Feature Configuration Information

VxLAN Support

Cisco IOS XE Release 3.13.1S

Cisco IOS XE Fuji 16.9

This feature was introduced on the Cisco ASR 1000 Series Routers.

This feature was introduced on the following:

  • Cisco ISR 1000 Series Integrated Services Routers.

  • Cisco ISR 4000 Series Integrated Services Routers.

Protocol Independent Multicast-Sparse Mode (PIM-SM) Support

Cisco IOS XE Release 3.17S

This feature was introduced on the Cisco ASR 1000 Series Routers. No commands were introduced or modified for this feature.

Support for multiple ingress replication peers

Cisco IOS XE Everest 16.5.1b

The VXLAN feature was modified to support multiple ingress replication peers on the Cisco ASR 1000 Series Routers.

The ingress-replication command was modified to support multiple replication peers for every VNI up to 32 nodes.

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