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diff --git a/docs/network-interfaces.rst b/docs/network-interfaces.rst
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@@ -471,6 +471,285 @@ Results in:
description "Description"
}
+VXLAN
+-----
+
+VXLAN is an overlaying Ethernet over IP protocol. It is described in RFC7348_.
+
+If configuring VXLAN in a VyOS virtual machine, ensure that MAC spoofing
+(Hyper-V) or Forged Transmits (ESX) are permitted, otherwise forwarded frames
+may be blocked by the hypervisor.
+
+Multicast VXLAN
+^^^^^^^^^^^^^^^^
+
+Example Topology:
+
+PC4 - Leaf2 - Spine1 - Leaf3 - PC5
+
+PC4 has IP 10.0.0.4/24 and PC5 has IP 10.0.0.5/24, so they believe they are in
+the same broadcast domain.
+
+Let's assume PC4 on Leaf2 wants to ping PC5 on Leaf3. Instead of setting Leaf3
+as our remote end manually, Leaf2 encapsulates the packet into a UDP-packet and
+sends it to its designated multicast-address via Spine1. When Spine1 receives
+this packet it forwards it to all other Leafs who has joined the same
+multicast-group, in this case Leaf3. When Leaf3 receives the packet it forwards
+it, while at the same time learning that PC4 is reachable behind Leaf2, because
+the encapsulated packet had Leaf2's IP-address set as source IP.
+
+PC5 receives the ping echo, responds with an echo reply that Leaf3 receives and
+this time forwards to Leaf2's unicast address directly because it learned the
+location of PC4 above. When Leaf2 receives the echo reply from PC5 it sees that
+it came from Leaf3 and so remembers that PC5 is reachable via Leaf3.
+
+Thanks to this discovery, any subsequent traffic between PC4 and PC5 will not
+be using the multicast-address between the Leafs as they both know behind which
+Leaf the PCs are connected. This saves traffic as less multicast packets sent
+reduces the load on the network, which improves scalability when more Leafs are
+added.
+
+For optimal scalability Multicast shouldn't be used at all, but instead use BGP
+to signal all connected devices between leafs. Unfortunately, VyOS does not yet
+support this.
+
+Configuration commands
+^^^^^^^^^^^^^^^^^^^^^^
+
+.. code-block:: sh
+
+ interfaces
+ vxlan <vxlan[0-16777215]>
+ address # IP address of the VXLAN interface
+ bridge-group # Configure a L2 bridge-group
+ description # Description
+ group <ipv4> # IPv4 Multicast group address (required)
+ ip # IPv4 routing options
+ ipv6 # IPv6 routing options
+ link <dev> # IP interface for underlay of this vxlan overlay (optional)
+ mtu # MTU
+ policy # Policy routing options
+ remote # Remote address of the VXLAN tunnel, used for PTP instead of multicast
+ vni <1-16777215> # Virtual Network Identifier (required)
+
+Configuration Example
+^^^^^^^^^^^^^^^^^^^^^
+
+The setup is this:
+
+Leaf2 - Spine1 - Leaf3
+
+Spine1 is a Cisco IOS router running version 15.4, Leaf2 and Leaf3 is each a
+VyOS router running 1.2.
+
+This topology was built using GNS3.
+
+Topology:
+
+.. code-block:: sh
+
+ Spine1:
+ fa0/2 towards Leaf2, IP-address: 10.1.2.1/24
+ fa0/3 towards Leaf3, IP-address: 10.1.3.1/24
+
+ Leaf2:
+ Eth0 towards Spine1, IP-address: 10.1.2.2/24
+ Eth1 towards a vlan-aware switch
+
+ Leaf3:
+ Eth0 towards Spine1, IP-address 10.1.3.3/24
+ Eth1 towards a vlan-aware switch
+
+Spine1 Configuration:
+
+.. code-block:: sh
+
+ conf t
+ ip multicast-routing
+ !
+ interface fastethernet0/2
+ ip address 10.1.2.1 255.255.255.0
+ ip pim sparse-dense-mode
+ !
+ interface fastethernet0/3
+ ip address 10.1.3.1 255.255.255.0
+ ip pim sparse-dense-mode
+ !
+ router ospf 1
+ network 10.0.0.0 0.255.255.255 area 0
+
+Multicast-routing is required for the leafs to forward traffic between each
+other in a more scalable way. This also requires PIM to be enabled towards the
+Leafs so that the Spine can learn what multicast groups each Leaf expect traffic
+from.
+
+Leaf2 configuration:
+
+.. code-block:: sh
+
+ set interfaces ethernet eth0 address '10.1.2.2/24'
+ set protocols ospf area 0 network '10.0.0.0/8'
+
+ ! Our first vxlan interface
+ set interfaces bridge br241 address '172.16.241.1/24'
+ set interfaces ethernet eth1 vif 241 bridge-group bridge 'br241'
+ set interfaces vxlan vxlan241 bridge-group bridge 'br241'
+ set interfaces vxlan vxlan241 group '239.0.0.241'
+ set interfaces vxlan vxlan241 link 'eth0'
+ set interfaces vxlan vxlan241 vni '241'
+
+ ! Our seconds vxlan interface
+ set interfaces bridge br242 address '172.16.242.1/24'
+ set interfaces ethernet eth1 vif 242 bridge-group bridge 'br242'
+ set interfaces vxlan vxlan242 bridge-group bridge 'br242'
+ set interfaces vxlan vxlan242 group '239.0.0.242'
+ set interfaces vxlan vxlan242 link 'eth0'
+ set interfaces vxlan vxlan242 vni '242'
+
+Leaf3 configuration:
+
+.. code-block:: sh
+
+ set interfaces ethernet eth0 address '10.1.3.3/24'
+ set protocols ospf area 0 network '10.0.0.0/8'
+
+ ! Our first vxlan interface
+ set interfaces bridge br241 address '172.16.241.1/24'
+ set interfaces ethernet eth1 vif 241 bridge-group bridge 'br241'
+ set interfaces vxlan vxlan241 bridge-group bridge 'br241'
+ set interfaces vxlan vxlan241 group '239.0.0.241'
+ set interfaces vxlan vxlan241 link 'eth0'
+ set interfaces vxlan vxlan241 vni '241'
+
+ ! Our seconds vxlan interface
+ set interfaces bridge br242 address '172.16.242.1/24'
+ set interfaces ethernet eth1 vif 242 bridge-group bridge 'br242'
+ set interfaces vxlan vxlan242 bridge-group bridge 'br242'
+ set interfaces vxlan vxlan242 group '239.0.0.242'
+ set interfaces vxlan vxlan242 link 'eth0'
+ set interfaces vxlan vxlan242 vni '242'
+
+As you can see, Leaf2 and Leaf3 configuration is almost identical. There are
+lots of commands above, I'll try to into more detail below, command
+descriptions are placed under the command boxes:
+
+.. code-block:: sh
+
+ set interfaces bridge br241 address '172.16.241.1/24'
+
+This commands creates a bridge that is used to bind traffic on eth1 vlan 241
+with the vxlan241-interface. The IP-address is not required. It may however be
+used as a default gateway for each Leaf which allows devices on the vlan to
+reach other subnets. This requires that the subnets are redistributed by OSPF
+so that the Spine will learn how to reach it. To do this you need to change the
+OSPF network from '10.0.0.0/8' to '0.0.0.0/0' to allow 172.16/12-networks to be
+advertised.
+
+.. code-block:: sh
+
+ set interfaces ethernet eth1 vif 241 bridge-group bridge 'br241'
+ set interfaces vxlan vxlan241 bridge-group bridge 'br241'
+
+Binds eth1 vif 241 and vxlan241 to each other by putting them in the same
+bridge-group. Internal VyOS requirement.
+
+.. code-block:: sh
+
+ set interfaces vxlan vxlan241 group '239.0.0.241'
+
+The multicast-group used by all Leafs for this vlan extension. Has to be the
+same on all Leafs that has this interface.
+
+.. code-block:: sh
+
+ set interfaces vxlan vxlan241 link 'eth0'
+
+Sets the interface to listen for multicast packets on. Could be a loopback, not
+yet tested.
+
+.. code-block:: sh
+
+ set interfaces vxlan vxlan241 vni '241'
+
+Sets the unique id for this vxlan-interface. Not sure how it correlates with
+multicast-address.
+
+.. code-block:: sh
+
+ set interfaces vxlan vxlan241 remote-port 12345
+
+The destination port used for creating a VXLAN interface in Linux defaults to
+its pre-standard value of 8472 to preserve backwards compatibility. A
+configuration directive to support a user-specified destination port to override
+that behavior is available using the above command.
+
+Older Examples
+^^^^^^^^^^^^^^
+
+Example for bridging normal L2 segment and vxlan overlay network, and using a
+vxlan interface as routing interface.
+
+.. code-block:: sh
+
+ interfaces {
+ bridge br0 {
+ }
+ ethernet eth0 {
+ address dhcp
+ }
+ loopback lo {
+ }
+ vxlan vxlan0 {
+ bridge-group {
+ bridge br0
+ }
+ group 239.0.0.1
+ vni 0
+ }
+ vxlan vxlan1 {
+ address 192.168.0.1/24
+ link eth0
+ group 239.0.0.1
+ vni 1
+ }
+ }
+
+Here is a working configuration that creates a VXLAN between two routers. Each
+router has a VLAN interface (26) facing the client devices and a VLAN interface
+(30) that connects it to the other routers. With this configuration, traffic
+can flow between both routers' VLAN 26, but can't escape since there is no L3
+gateway. You can add an IP to a bridge-group to create a gateway.
+
+.. code-block:: sh
+
+ interfaces {
+ bridge br0 {
+ }
+ ethernet eth0 {
+ duplex auto
+ smp-affinity auto
+ speed auto
+ vif 26 {
+ bridge-group {
+ bridge br0
+ }
+ }
+ vif 30 {
+ address 10.7.50.6/24
+ }
+ }
+ loopback lo {
+ }
+ vxlan vxlan0 {
+ bridge-group {
+ bridge br0
+ }
+ group 239.0.0.241
+ vni 241
+ }
+ }
+
+
WireGuard VPN Interface
-----------------------
@@ -572,4 +851,5 @@ your peer should have knowledge if its content.
.. _RFC4862: https://tools.ietf.org/html/rfc4862
.. _RFC4291: http://tools.ietf.org/html/rfc4291#section-2.5.1
+.. _RFC7348: https://datatracker.ietf.org/doc/rfc7348/
.. _WireGuard: https://www.wireguard.com