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.. _bond-interface:
#######################
Bond / Link Aggregation
#######################
The bonding interface provides a method for aggregating multiple network
interfaces into a single logical "bonded" interface, or LAG, or ether-channel,
or port-channel. The behavior of the bonded interfaces depends upon the mode;
generally speaking, modes provide either hot standby or load balancing services.
Additionally, link integrity monitoring may be performed.
Configuration
#############
Address
-------
.. cfgcmd:: set interfaces bonding <interface> address <address | dhcp | dhcpv6>
Configure interface `<interface>` with one or more interface addresses.
* **address** can be specified multiple times as IPv4 and/or IPv6 address,
e.g. 192.0.2.1/24 and/or 2001:db8::1/64
* **dhcp** interface address is received by DHCP from a DHCP server on this
segment.
* **dhcpv6** interface address is received by DHCPv6 from a DHCPv6 server on
this segment.
Example:
.. code-block:: none
set interfaces bonding bond0 address 192.0.2.1/24
set interfaces bonding bond0 address 192.0.2.2/24
set interfaces bonding bond0 address 2001:db8::ffff/64
set interfaces bonding bond0 address 2001:db8:100::ffff/64
.. cfgcmd:: set interfaces bonding <interface> ipv6 address autoconf
.. include:: common-ipv6-addr-autoconf.txt
.. cfgcmd:: set interfaces bonding <interface> ipv6 address eui64 <prefix>
:abbr:`EUI-64 (64-Bit Extended Unique Identifier)` as specified in
:rfc:`4291` allows a host to assign iteslf a unique 64-Bit IPv6 address.
.. code-block:: none
set interfaces bonding bond0 ipv6 address eui64 2001:db8:beef::/64
Link Administration
-------------------
.. cfgcmd:: set interfaces bonding <interface> description <description>
Assign given `<description>` to interface. Description will also be passed
to SNMP monitoring systems.
.. cfgcmd:: set interfaces bonding <interface> disable
Disable given `<interface>`. It will be placed in administratively down
(``A/D``) state.
.. cfgcmd:: set interfaces bonding <interface> mac <mac-address>
Configure user defined :abbr:`MAC (Media Access Control)` address on given
`<interface>`.
.. cfgcmd:: set interfaces bonding <interface> mode <mode>
Specifies one of the bonding policies. The default is 802.3ad. Possible
values are:
* **802.3ad** - IEEE 802.3ad Dynamic link aggregation. Creates aggregation
groups that share the same speed and duplex settings. Utilizes all slaves
in the active aggregator according to the 802.3ad specification.
Slave selection for outgoing traffic is done according to the transmit
hash policy, which may be changed from the default simple XOR policy via
the :cfgcmd:`hash-policy` option, documented below.
.. note:: Not all transmit policies may be 802.3ad compliant, particularly
in regards to the packet mis-ordering requirements of section 43.2.4
of the 802.3ad standard.
* **active-backup** - Active-backup policy: Only one slave in the bond is
active. A different slave becomes active if, and only if, the active slave
fails. The bond's MAC address is externally visible on only one port
(network adapter) to avoid confusing the switch.
When a failover occurs in active-backup mode, bonding will issue one or
more gratuitous ARPs on the newly active slave. One gratuitous ARP is
issued for the bonding master interface and each VLAN interfaces
configured above it, provided that the interface has at least one IP
address configured. Gratuitous ARPs issued for VLAN interfaces are tagged
with the appropriate VLAN id.
This mode provides fault tolerance. The :cfgcmd:`primary` option,
documented below, affects the behavior of this mode.
* **broadcast** - Broadcast policy: transmits everything on all slave
interfaces.
This mode provides fault tolerance.
* **round-robin** - Round-robin policy: Transmit packets in sequential
order from the first available slave through the last.
This mode provides load balancing and fault tolerance.
* **transmit-load-balance** - Adaptive transmit load balancing: channel
bonding that does not require any special switch support.
Incoming traffic is received by the current slave. If the receiving slave
fails, another slave takes over the MAC address of the failed receiving
slave.
* **adaptive-load-balance** - Adaptive load balancing: includes
transmit-load-balance plus receive load balancing for IPV4 traffic, and
does not require any special switch support. The receive load balancing
is achieved by ARP negotiation. The bonding driver intercepts the ARP
Replies sent by the local system on their way out and overwrites the
source hardware address with the unique hardware address of one of the
slaves in the bond such that different peers use different hardware
addresses for the server.
Receive traffic from connections created by the server is also balanced.
When the local system sends an ARP Request the bonding driver copies and
saves the peer's IP information from the ARP packet. When the ARP Reply
arrives from the peer, its hardware address is retrieved and the bonding
driver initiates an ARP reply to this peer assigning it to one of the
slaves in the bond. A problematic outcome of using ARP negotiation for
balancing is that each time that an ARP request is broadcast it uses the
hardware address of the bond. Hence, peers learn the hardware address
of the bond and the balancing of receive traffic collapses to the current
slave. This is handled by sending updates (ARP Replies) to all the peers
with their individually assigned hardware address such that the traffic
is redistributed. Receive traffic is also redistributed when a new slave
is added to the bond and when an inactive slave is re-activated. The
receive load is distributed sequentially (round robin) among the group
of highest speed slaves in the bond.
When a link is reconnected or a new slave joins the bond the receive
traffic is redistributed among all active slaves in the bond by initiating
ARP Replies with the selected MAC address to each of the clients. The
updelay parameter (detailed below) must be set to a value equal or greater
than the switch's forwarding delay so that the ARP Replies sent to the
peers will not be blocked by the switch.
* **xor-hash** - XOR policy: Transmit based on the selected transmit
hash policy. The default policy is a simple [(source MAC address XOR'd
with destination MAC address XOR packet type ID) modulo slave count].
Alternate transmit policies may be selected via the :cfgcmd:`hash-policy`
option, described below.
This mode provides load balancing and fault tolerance.
.. cfgcmd:: set interfaces bonding <interface> min-links <0-16>
Specifies the minimum number of links that must be active before asserting
carrier. It is similar to the Cisco EtherChannel min-links feature. This
allows setting the minimum number of member ports that must be up (link-up
state) before marking the bond device as up (carrier on). This is useful for
situations where higher level services such as clustering want to ensure a
minimum number of low bandwidth links are active before switchover.
This option only affects 802.3ad mode.
The default value is 0. This will cause carrier to be asserted (for 802.3ad
mode) whenever there is an active aggregator, regardless of the number of
available links in that aggregator.
.. note:: Because an aggregator cannot be active without at least one
available link, setting this option to 0 or to 1 has the exact same
effect.
.. cfgcmd:: set interfaces bonding <interface> hash-policy <policy>
* **layer2** - Uses XOR of hardware MAC addresses and packet type ID field
to generate the hash. The formula is
.. code-block:: none
hash = source MAC XOR destination MAC XOR packet type ID
slave number = hash modulo slave count
This algorithm will place all traffic to a particular network peer on
the same slave.
This algorithm is 802.3ad compliant.
* **layer2+3** - This policy uses a combination of layer2 and layer3
protocol information to generate the hash. Uses XOR of hardware MAC
addresses and IP addresses to generate the hash. The formula is:
.. code-block:: none
hash = source MAC XOR destination MAC XOR packet type ID
hash = hash XOR source IP XOR destination IP
hash = hash XOR (hash RSHIFT 16)
hash = hash XOR (hash RSHIFT 8)
And then hash is reduced modulo slave count.
If the protocol is IPv6 then the source and destination addresses are
first hashed using ipv6_addr_hash.
This algorithm will place all traffic to a particular network peer on the
same slave. For non-IP traffic, the formula is the same as for the layer2
transmit hash policy.
This policy is intended to provide a more balanced distribution of traffic
than layer2 alone, especially in environments where a layer3 gateway
device is required to reach most destinations.
This algorithm is 802.3ad compliant.
* **layer3+4** - This policy uses upper layer protocol information, when
available, to generate the hash. This allows for traffic to a particular
network peer to span multiple slaves, although a single connection will
not span multiple slaves.
The formula for unfragmented TCP and UDP packets is
.. code-block:: none
hash = source port, destination port (as in the header)
hash = hash XOR source IP XOR destination IP
hash = hash XOR (hash RSHIFT 16)
hash = hash XOR (hash RSHIFT 8)
And then hash is reduced modulo slave count.
If the protocol is IPv6 then the source and destination addresses are
first hashed using ipv6_addr_hash.
For fragmented TCP or UDP packets and all other IPv4 and IPv6 protocol
traffic, the source and destination port information is omitted. For
non-IP traffic, the formula is the same as for the layer2 transmit hash
policy.
This algorithm is not fully 802.3ad compliant. A single TCP or UDP
conversation containing both fragmented and unfragmented packets will see
packets striped across two interfaces. This may result in out of order
delivery. Most traffic types will not meet this criteria, as TCP rarely
fragments traffic, and most UDP traffic is not involved in extended
conversations. Other implementations of 802.3ad may or may not tolerate
this noncompliance.
.. cfgcmd:: set interfaces bonding <interface> primary <interface>
An `<interface>` specifying which slave is the primary device. The specified
device will always be the active slave while it is available. Only when the
primary is off-line will alternate devices be used. This is useful when one
slave is preferred over another, e.g., when one slave has higher throughput
than another.
The primary option is only valid for active-backup, transmit-load-balance,
and adaptive-load-balance mode.
.. cfgcmd:: set interfaces bonding <interface> arp-monitor interval <time>
Specifies the ARP link monitoring `<time>` in seconds.
The ARP monitor works by periodically checking the slave devices to determine
whether they have sent or received traffic recently (the precise criteria
depends upon the bonding mode, and the state of the slave). Regular traffic
is generated via ARP probes issued for the addresses specified by the
:cfgcmd:`arp-monitor target` option.
If ARP monitoring is used in an etherchannel compatible mode (modes
round-robin and xor-hash), the switch should be configured in a mode that
evenly distributes packets across all links. If the switch is configured to
distribute the packets in an XOR fashion, all replies from the ARP targets
will be received on the same link which could cause the other team members
to fail.
A value of 0 disables ARP monitoring. The default value is 0.
.. cfgcmd:: set interfaces bonding <interface> arp-monitor target <address>
Specifies the IP addresses to use as ARP monitoring peers when
:cfgcmd:`arp-monitor interval` option is > 0. These are the targets of the
ARP request sent to determine the health of the link to the targets.
Multiple target IP addresses can be specified. At least one IP address must
be given for ARP monitoring to function.
The maximum number of targets that can be specified is 16. The default value
is no IP addresses.
Member Interfaces
-----------------
.. cfgcmd:: set interfaces bonding <interface> member interface <member>
Enslave `<member>` interface to bond `<interface>`.
Example
-------
The following configuration on VyOS applies to all following 3rd party vendors.
It creates a bond with two links and VLAN 10, 100 on the bonded interfaces with
a per VIF IPv4 address.
.. code-block:: none
# Create bonding interface bond0 with 802.3ad LACP
set interfaces bonding bond0 hash-policy 'layer2'
set interfaces bonding bond0 mode '802.3ad'
# Add the required vlans and IPv4 addresses on them
set interfaces bonding bond0 vif 10 address 192.168.0.1/24
set interfaces bonding bond0 vif 100 address 10.10.10.1/24
# Add the member interfaces to the bonding interface
set interfaces bonding bond0 member interface eth1
set interfaces bonding bond0 member interface eth2
Cisco Catalyst
^^^^^^^^^^^^^^
Assign member interfaces to PortChannel
.. code-block:: none
interface GigabitEthernet1/0/23
description VyOS eth1
channel-group 1 mode active
!
interface GigabitEthernet1/0/24
description VyOS eth2
channel-group 1 mode active
!
A new interface becomes present ``Port-channel1``, all configuration like
allowed VLAN interfaces, STP will happen here.
.. code-block:: none
interface Port-channel1
description LACP Channel for VyOS
switchport trunk encapsulation dot1q
switchport trunk allowed vlan 10,100
switchport mode trunk
spanning-tree portfast trunk
!
Juniper EX Switch
^^^^^^^^^^^^^^^^^
For a headstart you can use the below example on how to build a bond with two
interfaces from VyOS to a Juniper EX Switch system.
.. code-block:: none
# Create aggregated ethernet device with 802.3ad LACP and port speeds of 10gbit/s
set interfaces ae0 aggregated-ether-options link-speed 10g
set interfaces ae0 aggregated-ether-options lacp active
# Create layer 2 on the aggregated ethernet device with trunking for our vlans
set interfaces ae0 unit 0 family ethernet-switching port-mode trunk
# Add the required vlans to the device
set interfaces ae0 unit 0 family ethernet-switching vlan members 10
set interfaces ae0 unit 0 family ethernet-switching vlan members 100
# Add the two interfaces to the aggregated ethernet device, in this setup both
# ports are on the same switch (switch 0, module 1, port 0 and 1)
set interfaces xe-0/1/0 ether-options 802.3ad ae0
set interfaces xe-0/1/1 ether-options 802.3ad ae0
# But this can also be done with multiple switches in a stack, a virtual
# chassis on Juniper (switch 0 and switch 1, module 1, port 0 on both switches)
set interfaces xe-0/1/0 ether-options 802.3ad ae0
set interfaces xe-1/1/0 ether-options 802.3ad ae0
Aruba/HP
^^^^^^^^
For a headstart you can use the below example on how to build a bond,port-channel
with two interfaces from VyOS to a Aruba/HP 2510G switch.
.. code-block:: none
# Create trunk with 2 member interfaces (interface 1 and 2) and LACP
trunk 1-2 Trk1 LACP
# Add the required vlans to the trunk
vlan 10 tagged Trk1
vlan 100 tagged Trk1
Operation
#########
.. code-block:: none
vyos@vyos:~$ show interfaces bonding
Codes: S - State, L - Link, u - Up, D - Down, A - Admin Down
Interface IP Address S/L Description
--------- ---------- --- -----------
bond0 - u/u my-sw1 int 23 and 24
bond0.10 192.168.0.1/24 u/u office-net
bond0.100 10.10.10.1/24 u/u management-net
|