Ethernet Bridging - VLANs
Ethernet bridges enable hosts to communicate through layer 2 by connecting the physical and logical interfaces in the system into a single layer 2 domain. The bridge is a logical interface with a MAC address and an MTU. The bridge MTU is the minimum MTU among all its members.
When you configure a bridge with NVUE, Cumulus Linux automatically assigns a hardware address to the bridge. When you configure a bridge by editing the /etc/network/interfaces
file, the bridge MAC address is the MAC address of the first port in the bridge-ports
list in the /etc/network/interfaces
file.
- Bridge members can be individual physical interfaces, bonds, or logical interfaces that traverse an 802.1Q VLAN trunk.
- Cumulus Linux does not put all ports into a bridge by default.
Ethernet Bridge Types
The Cumulus Linux bridge driver supports two configuration modes; one that is VLAN-aware and one that follows a more traditional Linux bridge model.
NVIDIA recommends that you use VLAN-aware mode bridges instead of traditional mode bridges. The Cumulus Linux bridge driver is capable of VLAN filtering, which allows for configurations that are similar to incumbent network devices. For a comparison of traditional and VLAN-aware modes, see this knowledge base article.
You can configure both VLAN-aware and traditional mode bridges on the same network in Cumulus Linux.
- To create a VLAN-aware bridge, see VLAN-aware Bridge Mode.
- To create a traditional mode bridge, see Traditional Bridge Mode.
Bridge MAC Addresses
The switch learns the MAC address for a frame when the frame enters the bridge through an interface and records the MAC address in the bridge table. The bridge forwards the frame to its intended destination by looking up the destination MAC address. Cumulus Linux maintains the MAC entry for 1800 seconds (30 minutes). If the switch sees the frame with the same source MAC address before the MAC entry age expires, it refreshes the MAC entry age; if the MAC entry age expires, the switch deletes the MAC address from the bridge table.
The following example NVUE command output shows a MAC address table for the bridge.
cumulus@switch:~$ nv show bridge domain br_default mac-table
age bridge-domain entry-type interface last-update mac src-vni vlan vni Summary
--- ----- ------------- ---------- ---------- ----------- ----------------- ------- ---- --- ----------------------
+ 0 87699 br_default permanent bond3 87699 44:38:39:00:00:35
+ 1 87699 br_default permanent bond1 87699 44:38:39:00:00:31
+ 2 87699 br_default permanent bond2 87699 44:38:39:00:00:33
+ 3 permanent br_default 00:00:00:00:00:10
+ 4 permanent br_default 00:00:00:00:00:20
+ 5 permanent br_default 00:00:00:00:00:30
+ 6 84130 br_default permanent br_default 84130 44:38:39:22:01:b1 30
+ 7 87570 br_default permanent vxlan48 87570 42:ff:4d:82:c9:99
+ 8 84130 permanent vxlan48 84130 00:00:00:00:00:00 10 remote-dst: 224.0.0.10
bridge fdb Command Output
The Linux bridge fdb
command interacts with the FDB, which the bridge uses to store the MAC addresses it learns and the ports on which it learns those MAC addresses. The bridge fdb show
command output contains some specific keywords:
Keyword | Description |
---|---|
self | The FDB entry belongs to the FDB on the device referenced by the device. For example, this FDB entry belongs to the VXLAN device: vx-1000 : 00:02:00:00:00:08 dev vx-1000 dst 27.0.0.10 self |
master | The FDB entry belongs to the FDB on the device’s master and the FDB entry is pointing to a master’s port. For example, this FDB entry is from the master device named bridge and is pointing to the VXLAN bridge port: vx-1001 : 02:02:00:00:00:08 dev vx-1001 vlan 1001 master bridge |
extern_learn | An external control plane, such as the BGP control plane for EVPN, manages (offloads) the FDB entry. |
The following example shows the bridge fdb show
command output:
cumulus@switch:~$ bridge fdb show | grep 02:02:00:00:00:08
02:02:00:00:00:08 dev vx-1001 vlan 1001 extern_learn master bridge
02:02:00:00:00:08 dev vx-1001 dst 27.0.0.10 self extern_learn
- 02:02:00:00:00:08 is the MAC address learned with BGP EVPN.
- The first FDB entry points to a Linux bridge entry that points to the VXLAN device vx-1001.
- The second FDB entry points to the same entry on the VXLAN device and includes additional remote destination information.
- The VXLAN FDB augments the bridge FDB with additional remote destination information.
- All FDB entries that point to a VXLAN port appear as two entries. The second entry augments the remote destination information.
Considerations
- A bridge cannot contain multiple subinterfaces of the same port. Attempting this configuration results in an error.
- If you use both VLAN-aware and traditional bridges, if a traditional bridge includes a bond subinterface that is a normal interface in a VLAN-aware bridge, the bridge flaps when you bring down the bond subinterface in the traditional bridge.
- You cannot enslave a VLAN raw device to a different master interface (you cannot edit the
vlan-raw-device
setting in the/etc/network/interfaces
file). You need to delete the VLAN and recreate it. - Cumulus Linux enables MAC learning by default on traditional and VLAN-aware bridge interfaces. Do not disable MAC learning unless you are using EVPN. See Ethernet Virtual Private Network - EVPN.
- The VLAN IDs in your configuration must not overlap with the internal reserved VLAN ranges. See Reserved VLAN Range and Limitations.