Provided by: systemd_249.11-0ubuntu3.12_amd64 
NAME
systemd.netdev - Virtual Network Device configuration
SYNOPSIS
netdev.netdev
DESCRIPTION
A plain ini-style text file that encodes configuration about a virtual network device, used by systemd-
networkd(8). See systemd.syntax(7) for a general description of the syntax.
The main Virtual Network Device file must have the extension .netdev; other extensions are ignored.
Virtual network devices are created as soon as networkd is started. If a netdev with the specified name
already exists, networkd will use that as-is rather than create its own. Note that the settings of the
pre-existing netdev will not be changed by networkd.
The .netdev files are read from the files located in the system network directory /lib/systemd/network,
the volatile runtime network directory /run/systemd/network and the local administration network
directory /etc/systemd/network. All configuration files are collectively sorted and processed in lexical
order, regardless of the directories in which they live. However, files with identical filenames replace
each other. Files in /etc/ have the highest priority, files in /run/ take precedence over files with the
same name in /lib/. This can be used to override a system-supplied configuration file with a local file
if needed. As a special case, an empty file (file size 0) or symlink with the same name pointing to
/dev/null disables the configuration file entirely (it is "masked").
Along with the netdev file foo.netdev, a "drop-in" directory foo.netdev.d/ may exist. All files with the
suffix ".conf" from this directory will be merged in the alphanumeric order and parsed after the main
file itself has been parsed. This is useful to alter or add configuration settings, without having to
modify the main configuration file. Each drop-in file must have appropriate section headers.
In addition to /etc/systemd/network, drop-in ".d" directories can be placed in /lib/systemd/network or
/run/systemd/network directories. Drop-in files in /etc/ take precedence over those in /run/ which in
turn take precedence over those in /lib/. Drop-in files under any of these directories take precedence
over the main netdev file wherever located. (Of course, since /run/ is temporary and /usr/lib/ is for
vendors, it is unlikely drop-ins should be used in either of those places.)
SUPPORTED NETDEV KINDS
The following kinds of virtual network devices may be configured in .netdev files:
Table 1. Supported kinds of virtual network devices
┌──────────┬───────────────────────────────────────┐
│Kind │ Description │
├──────────┼───────────────────────────────────────┤
│bond │ A bond device is an aggregation of │
│ │ all its slave devices. See Linux │
│ │ Ethernet Bonding Driver HOWTO[1] for │
│ │ details. │
├──────────┼───────────────────────────────────────┤
│bridge │ A bridge device is a software switch, │
│ │ and each of its slave devices and the │
│ │ bridge itself are ports of the │
│ │ switch. │
├──────────┼───────────────────────────────────────┤
│dummy │ A dummy device drops all packets sent │
│ │ to it. │
├──────────┼───────────────────────────────────────┤
│gre │ A Level 3 GRE tunnel over IPv4. See │
│ │ RFC 2784[2] for details. │
├──────────┼───────────────────────────────────────┤
│gretap │ A Level 2 GRE tunnel over IPv4. │
├──────────┼───────────────────────────────────────┤
│erspan │ ERSPAN mirrors traffic on one or more │
│ │ source ports and delivers the │
│ │ mirrored traffic to one or more │
│ │ destination ports on another switch. │
│ │ The traffic is encapsulated in │
│ │ generic routing encapsulation (GRE) │
│ │ and is therefore routable across a │
│ │ layer 3 network between the source │
│ │ switch and the destination switch. │
├──────────┼───────────────────────────────────────┤
│ip6gre │ A Level 3 GRE tunnel over IPv6. │
├──────────┼───────────────────────────────────────┤
│ip6tnl │ An IPv4 or IPv6 tunnel over IPv6 │
├──────────┼───────────────────────────────────────┤
│ip6gretap │ A Level 2 GRE tunnel over IPv6. │
├──────────┼───────────────────────────────────────┤
│ipip │ An IPv4 over IPv4 tunnel. │
├──────────┼───────────────────────────────────────┤
│ipvlan │ An IPVLAN device is a stacked device │
│ │ which receives packets from its │
│ │ underlying device based on IP address │
│ │ filtering. │
├──────────┼───────────────────────────────────────┤
│ipvtap │ An IPVTAP device is a stacked device │
│ │ which receives packets from its │
│ │ underlying device based on IP address │
│ │ filtering and can be accessed using │
│ │ the tap user space interface. │
├──────────┼───────────────────────────────────────┤
│macvlan │ A macvlan device is a stacked device │
│ │ which receives packets from its │
│ │ underlying device based on MAC │
│ │ address filtering. │
├──────────┼───────────────────────────────────────┤
│macvtap │ A macvtap device is a stacked device │
│ │ which receives packets from its │
│ │ underlying device based on MAC │
│ │ address filtering. │
├──────────┼───────────────────────────────────────┤
│sit │ An IPv6 over IPv4 tunnel. │
├──────────┼───────────────────────────────────────┤
│tap │ A persistent Level 2 tunnel between a │
│ │ network device and a device node. │
├──────────┼───────────────────────────────────────┤
│tun │ A persistent Level 3 tunnel between a │
│ │ network device and a device node. │
├──────────┼───────────────────────────────────────┤
│veth │ An Ethernet tunnel between a pair of │
│ │ network devices. │
├──────────┼───────────────────────────────────────┤
│vlan │ A VLAN is a stacked device which │
│ │ receives packets from its underlying │
│ │ device based on VLAN tagging. See │
│ │ IEEE 802.1Q[3] for details. │
├──────────┼───────────────────────────────────────┤
│vti │ An IPv4 over IPSec tunnel. │
├──────────┼───────────────────────────────────────┤
│vti6 │ An IPv6 over IPSec tunnel. │
├──────────┼───────────────────────────────────────┤
│vxlan │ A virtual extensible LAN (vxlan), for │
│ │ connecting Cloud computing │
│ │ deployments. │
├──────────┼───────────────────────────────────────┤
│geneve │ A GEneric NEtwork Virtualization │
│ │ Encapsulation (GENEVE) netdev driver. │
├──────────┼───────────────────────────────────────┤
│l2tp │ A Layer 2 Tunneling Protocol (L2TP) │
│ │ is a tunneling protocol used to │
│ │ support virtual private networks │
│ │ (VPNs) or as part of the delivery of │
│ │ services by ISPs. It does not provide │
│ │ any encryption or confidentiality by │
│ │ itself │
├──────────┼───────────────────────────────────────┤
│macsec │ Media Access Control Security │
│ │ (MACsec) is an 802.1AE IEEE │
│ │ industry-standard security technology │
│ │ that provides secure communication │
│ │ for all traffic on Ethernet links. │
│ │ MACsec provides point-to-point │
│ │ security on Ethernet links between │
│ │ directly connected nodes and is │
│ │ capable of identifying and preventing │
│ │ most security threats. │
├──────────┼───────────────────────────────────────┤
│vrf │ A Virtual Routing and Forwarding │
│ │ (VRF[4]) interface to create separate │
│ │ routing and forwarding domains. │
├──────────┼───────────────────────────────────────┤
│vcan │ The virtual CAN driver (vcan). │
│ │ Similar to the network loopback │
│ │ devices, vcan offers a virtual local │
│ │ CAN interface. │
├──────────┼───────────────────────────────────────┤
│vxcan │ The virtual CAN tunnel driver │
│ │ (vxcan). Similar to the virtual │
│ │ ethernet driver veth, vxcan │
│ │ implements a local CAN traffic tunnel │
│ │ between two virtual CAN network │
│ │ devices. When creating a vxcan, two │
│ │ vxcan devices are created as pair. │
│ │ When one end receives the packet it │
│ │ appears on its pair and vice versa. │
│ │ The vxcan can be used for cross │
│ │ namespace communication. │
├──────────┼───────────────────────────────────────┤
│wireguard │ WireGuard Secure Network Tunnel. │
├──────────┼───────────────────────────────────────┤
│nlmon │ A Netlink monitor device. Use an │
│ │ nlmon device when you want to monitor │
│ │ system Netlink messages. │
├──────────┼───────────────────────────────────────┤
│fou │ Foo-over-UDP tunneling. │
├──────────┼───────────────────────────────────────┤
│xfrm │ A virtual tunnel interface like │
│ │ vti/vti6 but with several advantages. │
├──────────┼───────────────────────────────────────┤
│ifb │ The Intermediate Functional Block │
│ │ (ifb) pseudo network interface acts │
│ │ as a QoS concentrator for multiple │
│ │ different sources of traffic. │
├──────────┼───────────────────────────────────────┤
│bareudp │ Bare UDP tunnels provide a generic L3 │
│ │ encapsulation support for tunnelling │
│ │ different L3 protocols like MPLS, IP │
│ │ etc. inside of an UDP tunnel. │
├──────────┼───────────────────────────────────────┤
│batadv │ B.A.T.M.A.N. Advanced[5] is a routing │
│ │ protocol for multi-hop mobile ad-hoc │
│ │ networks which operates on layer 2. │
└──────────┴───────────────────────────────────────┘
[MATCH] SECTION OPTIONS
A virtual network device is only created if the [Match] section matches the current environment, or if
the section is empty. The following keys are accepted:
Host=
Matches against the hostname or machine ID of the host. See "ConditionHost=" in systemd.unit(5) for
details. When prefixed with an exclamation mark ("!"), the result is negated. If an empty string is
assigned, then previously assigned value is cleared.
Virtualization=
Checks whether the system is executed in a virtualized environment and optionally test whether it is
a specific implementation. See "ConditionVirtualization=" in systemd.unit(5) for details. When
prefixed with an exclamation mark ("!"), the result is negated. If an empty string is assigned, then
previously assigned value is cleared.
KernelCommandLine=
Checks whether a specific kernel command line option is set. See "ConditionKernelCommandLine=" in
systemd.unit(5) for details. When prefixed with an exclamation mark ("!"), the result is negated. If
an empty string is assigned, then previously assigned value is cleared.
KernelVersion=
Checks whether the kernel version (as reported by uname -r) matches a certain expression. See
"ConditionKernelVersion=" in systemd.unit(5) for details. When prefixed with an exclamation mark
("!"), the result is negated. If an empty string is assigned, then previously assigned value is
cleared.
Architecture=
Checks whether the system is running on a specific architecture. See "ConditionArchitecture=" in
systemd.unit(5) for details. When prefixed with an exclamation mark ("!"), the result is negated. If
an empty string is assigned, then previously assigned value is cleared.
Firmware=
Checks whether the system is running on a machine with the specified firmware. See
"ConditionFirmware=" in systemd.unit(5) for details. When prefixed with an exclamation mark ("!"),
the result is negated. If an empty string is assigned, then previously assigned value is cleared.
[NETDEV] SECTION OPTIONS
The [NetDev] section accepts the following keys:
Description=
A free-form description of the netdev.
Name=
The interface name used when creating the netdev. This setting is compulsory.
Kind=
The netdev kind. This setting is compulsory. See the "Supported netdev kinds" section for the valid
keys.
MTUBytes=
The maximum transmission unit in bytes to set for the device. The usual suffixes K, M, G are
supported and are understood to the base of 1024. For "tun" or "tap" devices, MTUBytes= setting is
not currently supported in [NetDev] section. Please specify it in [Link] section of corresponding
systemd.network(5) files.
MACAddress=
The MAC address to use for the device. For "tun" or "tap" devices, setting MACAddress= in the
[NetDev] section is not supported. Please specify it in [Link] section of the corresponding
systemd.network(5) file. If this option is not set, "vlan" devices inherit the MAC address of the
physical interface. For other kind of netdevs, if this option is not set, then MAC address is
generated based on the interface name and the machine-id(5).
[BRIDGE] SECTION OPTIONS
The [Bridge] section only applies for netdevs of kind "bridge", and accepts the following keys:
HelloTimeSec=
HelloTimeSec specifies the number of seconds between two hello packets sent out by the root bridge
and the designated bridges. Hello packets are used to communicate information about the topology
throughout the entire bridged local area network.
MaxAgeSec=
MaxAgeSec specifies the number of seconds of maximum message age. If the last seen (received) hello
packet is more than this number of seconds old, the bridge in question will start the takeover
procedure in attempt to become the Root Bridge itself.
ForwardDelaySec=
ForwardDelaySec specifies the number of seconds spent in each of the Listening and Learning states
before the Forwarding state is entered.
AgeingTimeSec=
This specifies the number of seconds a MAC Address will be kept in the forwarding database after
having a packet received from this MAC Address.
Priority=
The priority of the bridge. An integer between 0 and 65535. A lower value means higher priority. The
bridge having the lowest priority will be elected as root bridge.
GroupForwardMask=
A 16-bit bitmask represented as an integer which allows forwarding of link local frames with 802.1D
reserved addresses (01:80:C2:00:00:0X). A logical AND is performed between the specified bitmask and
the exponentiation of 2^X, the lower nibble of the last octet of the MAC address. For example, a
value of 8 would allow forwarding of frames addressed to 01:80:C2:00:00:03 (802.1X PAE).
DefaultPVID=
This specifies the default port VLAN ID of a newly attached bridge port. Set this to an integer in
the range 1...4094 or "none" to disable the PVID.
MulticastQuerier=
Takes a boolean. This setting controls the IFLA_BR_MCAST_QUERIER option in the kernel. If enabled,
the kernel will send general ICMP queries from a zero source address. This feature should allow
faster convergence on startup, but it causes some multicast-aware switches to misbehave and disrupt
forwarding of multicast packets. When unset, the kernel's default will be used.
MulticastSnooping=
Takes a boolean. This setting controls the IFLA_BR_MCAST_SNOOPING option in the kernel. If enabled,
IGMP snooping monitors the Internet Group Management Protocol (IGMP) traffic between hosts and
multicast routers. When unset, the kernel's default will be used.
VLANFiltering=
Takes a boolean. This setting controls the IFLA_BR_VLAN_FILTERING option in the kernel. If enabled,
the bridge will be started in VLAN-filtering mode. When unset, the kernel's default will be used.
VLANProtocol=
Allows setting the protocol used for VLAN filtering. Takes 802.1q or, 802.1ad, and defaults to unset
and kernel's default is used.
STP=
Takes a boolean. This enables the bridge's Spanning Tree Protocol (STP). When unset, the kernel's
default will be used.
MulticastIGMPVersion=
Allows changing bridge's multicast Internet Group Management Protocol (IGMP) version. Takes an
integer 2 or 3. When unset, the kernel's default will be used.
[VLAN] SECTION OPTIONS
The [VLAN] section only applies for netdevs of kind "vlan", and accepts the following key:
Id=
The VLAN ID to use. An integer in the range 0...4094. This setting is compulsory.
Protocol=
Allows setting the protocol used for the VLAN interface. Takes "802.1q" or, "802.1ad", and defaults
to unset and kernel's default is used.
GVRP=
Takes a boolean. The Generic VLAN Registration Protocol (GVRP) is a protocol that allows automatic
learning of VLANs on a network. When unset, the kernel's default will be used.
MVRP=
Takes a boolean. Multiple VLAN Registration Protocol (MVRP) formerly known as GARP VLAN Registration
Protocol (GVRP) is a standards-based Layer 2 network protocol, for automatic configuration of VLAN
information on switches. It was defined in the 802.1ak amendment to 802.1Q-2005. When unset, the
kernel's default will be used.
LooseBinding=
Takes a boolean. The VLAN loose binding mode, in which only the operational state is passed from the
parent to the associated VLANs, but the VLAN device state is not changed. When unset, the kernel's
default will be used.
ReorderHeader=
Takes a boolean. When enabled, the VLAN reorder header is used and VLAN interfaces behave like
physical interfaces. When unset, the kernel's default will be used.
EgressQOSMaps=
Defines a mapping of Linux internal packet priority (SO_PRIORITY) to VLAN header PCP field for
outgoing frames. Takes a whitespace-separated list of unsigned integer pairs in the format
"from"-"to", e.g., "21-7 45-5" ranges 1–4294967294. Note that "from" must be greater than or equal to
"to". When unset, the kernel's default will be used.
IngressQOSMaps=
Defines a mapping of Linux internal packet priority (SO_PRIORITY) to VLAN header PCP field for
incoming frames. Takes a whitespace-separated list of unsigned integer pairs in the format
"from"-"to", e.g., "21-7 45-5" ranges 1–4294967294. Note that "from" must be greater than or equal to
"to". When unset, the kernel's default will be used.
[MACVLAN] SECTION OPTIONS
The [MACVLAN] section only applies for netdevs of kind "macvlan", and accepts the following key:
Mode=
The MACVLAN mode to use. The supported options are "private", "vepa", "bridge", "passthru", and
"source".
SourceMACAddress=
A whitespace-separated list of remote hardware addresses allowed on the MACVLAN. This option only has
an effect in source mode. Use full colon-, hyphen- or dot-delimited hexadecimal. This option may
appear more than once, in which case the lists are merged. If the empty string is assigned to this
option, the list of hardware addresses defined prior to this is reset. Defaults to unset.
BroadcastMulticastQueueLength=
Specifies the length of the receive queue for broadcast/multicast packets. An unsigned integer in the
range 0...4294967294. Defaults to unset.
[MACVTAP] SECTION OPTIONS
The [MACVTAP] section applies for netdevs of kind "macvtap" and accepts the same keys as [MACVLAN].
[IPVLAN] SECTION OPTIONS
The [IPVLAN] section only applies for netdevs of kind "ipvlan", and accepts the following key:
Mode=
The IPVLAN mode to use. The supported options are "L2","L3" and "L3S".
Flags=
The IPVLAN flags to use. The supported options are "bridge","private" and "vepa".
[IPVTAP] SECTION OPTIONS
The [IPVTAP] section only applies for netdevs of kind "ipvtap" and accepts the same keys as [IPVLAN].
[VXLAN] SECTION OPTIONS
The [VXLAN] section only applies for netdevs of kind "vxlan", and accepts the following keys:
VNI=
The VXLAN Network Identifier (or VXLAN Segment ID). Takes a number in the range 1...16777215.
Remote=
Configures destination IP address.
Local=
Configures local IP address.
Group=
Configures VXLAN multicast group IP address. All members of a VXLAN must use the same multicast group
address.
TOS=
The Type Of Service byte value for a vxlan interface.
TTL=
A fixed Time To Live N on Virtual eXtensible Local Area Network packets. Takes "inherit" or a number
in the range 0...255. 0 is a special value meaning inherit the inner protocol's TTL value. "inherit"
means that it will inherit the outer protocol's TTL value.
MacLearning=
Takes a boolean. When true, enables dynamic MAC learning to discover remote MAC addresses.
FDBAgeingSec=
The lifetime of Forwarding Database entry learnt by the kernel, in seconds.
MaximumFDBEntries=
Configures maximum number of FDB entries.
ReduceARPProxy=
Takes a boolean. When true, bridge-connected VXLAN tunnel endpoint answers ARP requests from the
local bridge on behalf of remote Distributed Overlay Virtual Ethernet (DVOE)[6] clients. Defaults to
false.
L2MissNotification=
Takes a boolean. When true, enables netlink LLADDR miss notifications.
L3MissNotification=
Takes a boolean. When true, enables netlink IP address miss notifications.
RouteShortCircuit=
Takes a boolean. When true, route short circuiting is turned on.
UDPChecksum=
Takes a boolean. When true, transmitting UDP checksums when doing VXLAN/IPv4 is turned on.
UDP6ZeroChecksumTx=
Takes a boolean. When true, sending zero checksums in VXLAN/IPv6 is turned on.
UDP6ZeroChecksumRx=
Takes a boolean. When true, receiving zero checksums in VXLAN/IPv6 is turned on.
RemoteChecksumTx=
Takes a boolean. When true, remote transmit checksum offload of VXLAN is turned on.
RemoteChecksumRx=
Takes a boolean. When true, remote receive checksum offload in VXLAN is turned on.
GroupPolicyExtension=
Takes a boolean. When true, it enables Group Policy VXLAN extension security label mechanism across
network peers based on VXLAN. For details about the Group Policy VXLAN, see the VXLAN Group Policy[7]
document. Defaults to false.
GenericProtocolExtension=
Takes a boolean. When true, Generic Protocol Extension extends the existing VXLAN protocol to provide
protocol typing, OAM, and versioning capabilities. For details about the VXLAN GPE Header, see the
Generic Protocol Extension for VXLAN[8] document. If destination port is not specified and Generic
Protocol Extension is set then default port of 4790 is used. Defaults to false.
DestinationPort=
Configures the default destination UDP port. If the destination port is not specified then Linux
kernel default will be used. Set to 4789 to get the IANA assigned value.
PortRange=
Configures the source port range for the VXLAN. The kernel assigns the source UDP port based on the
flow to help the receiver to do load balancing. When this option is not set, the normal range of
local UDP ports is used.
FlowLabel=
Specifies the flow label to use in outgoing packets. The valid range is 0-1048575.
IPDoNotFragment=
Allows setting the IPv4 Do not Fragment (DF) bit in outgoing packets, or to inherit its value from
the IPv4 inner header. Takes a boolean value, or "inherit". Set to "inherit" if the encapsulated
protocol is IPv6. When unset, the kernel's default will be used.
[GENEVE] SECTION OPTIONS
The [GENEVE] section only applies for netdevs of kind "geneve", and accepts the following keys:
Id=
Specifies the Virtual Network Identifier (VNI) to use, a number between 0 and 16777215. This field is
mandatory.
Remote=
Specifies the unicast destination IP address to use in outgoing packets.
TOS=
Specifies the TOS value to use in outgoing packets. Takes a number between 1 and 255.
TTL=
Accepts the same values as in the [VXLAN] section, except that when unset or set to 0, the kernel's
default will be used, meaning that packet TTL will be set from /proc/sys/net/ipv4/ip_default_ttl.
UDPChecksum=
Takes a boolean. When true, specifies that UDP checksum is calculated for transmitted packets over
IPv4.
UDP6ZeroChecksumTx=
Takes a boolean. When true, skip UDP checksum calculation for transmitted packets over IPv6.
UDP6ZeroChecksumRx=
Takes a boolean. When true, allows incoming UDP packets over IPv6 with zero checksum field.
DestinationPort=
Specifies destination port. Defaults to 6081. If not set or assigned the empty string, the default
port of 6081 is used.
FlowLabel=
Specifies the flow label to use in outgoing packets.
IPDoNotFragment=
Accepts the same key as in [VXLAN] section.
Independent=
Takes a boolean. When true, the vxlan interface is created without any underlying network interface.
Defaults to false, which means that a .network file that requests this tunnel using Tunnel= is
required for the tunnel to be created.
[BAREUDP] SECTION OPTIONS
The [BareUDP] section only applies for netdevs of kind "bareudp", and accepts the following keys:
DestinationPort=
Specifies the destination UDP port (in range 1...65535). This is mandatory.
EtherType=
Specifies the L3 protocol. Takes one of "ipv4", "ipv6", "mpls-uc" or "mpls-mc". This is mandatory.
[L2TP] SECTION OPTIONS
The [L2TP] section only applies for netdevs of kind "l2tp", and accepts the following keys:
TunnelId=
Specifies the tunnel identifier. Takes an number in the range 1...4294967295. The value used must
match the "PeerTunnelId=" value being used at the peer. This setting is compulsory.
PeerTunnelId=
Specifies the peer tunnel id. Takes a number in the range 1...4294967295. The value used must match
the "TunnelId=" value being used at the peer. This setting is compulsory.
Remote=
Specifies the IP address of the remote peer. This setting is compulsory.
Local=
Specifies the IP address of the local interface. Takes an IP address, or the special values "auto",
"static", or "dynamic". When an address is set, then the local interface must have the address. If
"auto", then one of the addresses on the local interface is used. Similarly, if "static" or "dynamic"
is set, then one of the static or dynamic addresses on the local interface is used. Defaults to
"auto".
EncapsulationType=
Specifies the encapsulation type of the tunnel. Takes one of "udp" or "ip".
UDPSourcePort=
Specifies the UDP source port to be used for the tunnel. When UDP encapsulation is selected it's
mandatory. Ignored when IP encapsulation is selected.
UDPDestinationPort=
Specifies destination port. When UDP encapsulation is selected it's mandatory. Ignored when IP
encapsulation is selected.
UDPChecksum=
Takes a boolean. When true, specifies that UDP checksum is calculated for transmitted packets over
IPv4.
UDP6ZeroChecksumTx=
Takes a boolean. When true, skip UDP checksum calculation for transmitted packets over IPv6.
UDP6ZeroChecksumRx=
Takes a boolean. When true, allows incoming UDP packets over IPv6 with zero checksum field.
[L2TPSESSION] SECTION OPTIONS
The [L2TPSession] section only applies for netdevs of kind "l2tp", and accepts the following keys:
Name=
Specifies the name of the session. This setting is compulsory.
SessionId=
Specifies the session identifier. Takes an number in the range 1...4294967295. The value used must
match the "SessionId=" value being used at the peer. This setting is compulsory.
PeerSessionId=
Specifies the peer session identifier. Takes an number in the range 1...4294967295. The value used
must match the "PeerSessionId=" value being used at the peer. This setting is compulsory.
Layer2SpecificHeader=
Specifies layer2specific header type of the session. One of "none" or "default". Defaults to
"default".
[MACSEC] SECTION OPTIONS
The [MACsec] section only applies for network devices of kind "macsec", and accepts the following keys:
Port=
Specifies the port to be used for the MACsec transmit channel. The port is used to make secure
channel identifier (SCI). Takes a value between 1 and 65535. Defaults to unset.
Encrypt=
Takes a boolean. When true, enable encryption. Defaults to unset.
[MACSECRECEIVECHANNEL] SECTION OPTIONS
The [MACsecReceiveChannel] section only applies for network devices of kind "macsec", and accepts the
following keys:
Port=
Specifies the port to be used for the MACsec receive channel. The port is used to make secure channel
identifier (SCI). Takes a value between 1 and 65535. This option is compulsory, and is not set by
default.
MACAddress=
Specifies the MAC address to be used for the MACsec receive channel. The MAC address used to make
secure channel identifier (SCI). This setting is compulsory, and is not set by default.
[MACSECTRANSMITASSOCIATION] SECTION OPTIONS
The [MACsecTransmitAssociation] section only applies for network devices of kind "macsec", and accepts
the following keys:
PacketNumber=
Specifies the packet number to be used for replay protection and the construction of the
initialization vector (along with the secure channel identifier [SCI]). Takes a value between
1-4,294,967,295. Defaults to unset.
KeyId=
Specifies the identification for the key. Takes a number between 0-255. This option is compulsory,
and is not set by default.
Key=
Specifies the encryption key used in the transmission channel. The same key must be configured on the
peer’s matching receive channel. This setting is compulsory, and is not set by default. Takes a
128-bit key encoded in a hexadecimal string, for example "dffafc8d7b9a43d5b9a3dfbbf6a30c16".
KeyFile=
Takes an absolute path to a file which contains a 128-bit key encoded in a hexadecimal string, which
will be used in the transmission channel. When this option is specified, Key= is ignored. Note that
the file must be readable by the user "systemd-network", so it should be, e.g., owned by
"root:systemd-network" with a "0640" file mode. If the path refers to an AF_UNIX stream socket in the
file system a connection is made to it and the key read from it.
Activate=
Takes a boolean. If enabled, then the security association is activated. Defaults to unset.
UseForEncoding=
Takes a boolean. If enabled, then the security association is used for encoding. Only one
[MACsecTransmitAssociation] section can enable this option. When enabled, Activate=yes is implied.
Defaults to unset.
[MACSECRECEIVEASSOCIATION] SECTION OPTIONS
The [MACsecReceiveAssociation] section only applies for network devices of kind "macsec", and accepts the
following keys:
Port=
Accepts the same key as in [MACsecReceiveChannel] section.
MACAddress=
Accepts the same key as in [MACsecReceiveChannel] section.
PacketNumber=
Accepts the same key as in [MACsecTransmitAssociation] section.
KeyId=
Accepts the same key as in [MACsecTransmitAssociation] section.
Key=
Accepts the same key as in [MACsecTransmitAssociation] section.
KeyFile=
Accepts the same key as in [MACsecTransmitAssociation] section.
Activate=
Accepts the same key as in [MACsecTransmitAssociation] section.
[TUNNEL] SECTION OPTIONS
The [Tunnel] section only applies for netdevs of kind "ipip", "sit", "gre", "gretap", "ip6gre",
"ip6gretap", "vti", "vti6", "ip6tnl", and "erspan" and accepts the following keys:
Local=
A static local address for tunneled packets. It must be an address on another interface of this host,
or the special value "any".
Remote=
The remote endpoint of the tunnel. Takes an IP address or the special value "any".
TOS=
The Type Of Service byte value for a tunnel interface. For details about the TOS, see the Type of
Service in the Internet Protocol Suite[9] document.
TTL=
A fixed Time To Live N on tunneled packets. N is a number in the range 1...255. 0 is a special value
meaning that packets inherit the TTL value. The default value for IPv4 tunnels is 0 (inherit). The
default value for IPv6 tunnels is 64.
DiscoverPathMTU=
Takes a boolean. When true, enables Path MTU Discovery on the tunnel.
IPv6FlowLabel=
Configures the 20-bit flow label (see RFC 6437[10]) field in the IPv6 header (see RFC 2460[11]),
which is used by a node to label packets of a flow. It is only used for IPv6 tunnels. A flow label of
zero is used to indicate packets that have not been labeled. It can be configured to a value in the
range 0...0xFFFFF, or be set to "inherit", in which case the original flowlabel is used.
CopyDSCP=
Takes a boolean. When true, the Differentiated Service Code Point (DSCP) field will be copied to the
inner header from outer header during the decapsulation of an IPv6 tunnel packet. DSCP is a field in
an IP packet that enables different levels of service to be assigned to network traffic. Defaults to
"no".
EncapsulationLimit=
The Tunnel Encapsulation Limit option specifies how many additional levels of encapsulation are
permitted to be prepended to the packet. For example, a Tunnel Encapsulation Limit option containing
a limit value of zero means that a packet carrying that option may not enter another tunnel before
exiting the current tunnel. (see RFC 2473[12]). The valid range is 0–255 and "none". Defaults to 4.
Key=
The Key= parameter specifies the same key to use in both directions (InputKey= and OutputKey=). The
Key= is either a number or an IPv4 address-like dotted quad. It is used as mark-configured SAD/SPD
entry as part of the lookup key (both in data and control path) in IP XFRM (framework used to
implement IPsec protocol). See ip-xfrm — transform configuration[13] for details. It is only used for
VTI/VTI6, GRE, GRETAP, and ERSPAN tunnels.
InputKey=
The InputKey= parameter specifies the key to use for input. The format is same as Key=. It is only
used for VTI/VTI6, GRE, GRETAP, and ERSPAN tunnels.
OutputKey=
The OutputKey= parameter specifies the key to use for output. The format is same as Key=. It is only
used for VTI/VTI6, GRE, GRETAP, and ERSPAN tunnels.
Mode=
An "ip6tnl" tunnel can be in one of three modes "ip6ip6" for IPv6 over IPv6, "ipip6" for IPv4 over
IPv6 or "any" for either.
Independent=
Takes a boolean. When false (the default), the tunnel is always created over some network device, and
a .network file that requests this tunnel using Tunnel= is required for the tunnel to be created.
When true, the tunnel is created independently of any network as "tunnel@NONE".
AssignToLoopback=
Takes a boolean. If set to "yes", the loopback interface "lo" is used as the underlying device of the
tunnel interface. Defaults to "no".
AllowLocalRemote=
Takes a boolean. When true allows tunnel traffic on ip6tnl devices where the remote endpoint is a
local host address. When unset, the kernel's default will be used.
FooOverUDP=
Takes a boolean. Specifies whether FooOverUDP= tunnel is to be configured. Defaults to false. This
takes effects only for IPIP, SIT, GRE, and GRETAP tunnels. For more detail information see Foo over
UDP[14]
FOUDestinationPort=
This setting specifies the UDP destination port for encapsulation. This field is mandatory when
FooOverUDP=yes, and is not set by default.
FOUSourcePort=
This setting specifies the UDP source port for encapsulation. Defaults to 0 — that is, the source
port for packets is left to the network stack to decide.
Encapsulation=
Accepts the same key as in the [FooOverUDP] section.
IPv6RapidDeploymentPrefix=
Reconfigure the tunnel for IPv6 Rapid Deployment[15], also known as 6rd. The value is an ISP-specific
IPv6 prefix with a non-zero length. Only applicable to SIT tunnels.
ISATAP=
Takes a boolean. If set, configures the tunnel as Intra-Site Automatic Tunnel Addressing Protocol
(ISATAP) tunnel. Only applicable to SIT tunnels. When unset, the kernel's default will be used.
SerializeTunneledPackets=
Takes a boolean. If set to yes, then packets are serialized. Only applies for GRE, GRETAP, and ERSPAN
tunnels. When unset, the kernel's default will be used.
ERSPANIndex=
Specifies the ERSPAN index field for the interface, an integer in the range 1...1048575 associated
with the ERSPAN traffic's source port and direction. This field is mandatory.
[FOOOVERUDP] SECTION OPTIONS
The [FooOverUDP] section only applies for netdevs of kind "fou" and accepts the following keys:
Encapsulation=
Specifies the encapsulation mechanism used to store networking packets of various protocols inside
the UDP packets. Supports the following values: "FooOverUDP" provides the simplest no-frills model of
UDP encapsulation, it simply encapsulates packets directly in the UDP payload.
"GenericUDPEncapsulation" is a generic and extensible encapsulation, it allows encapsulation of
packets for any IP protocol and optional data as part of the encapsulation. For more detailed
information see Generic UDP Encapsulation[16]. Defaults to "FooOverUDP".
Port=
Specifies the port number where the encapsulated packets will arrive. Those packets will be removed
and manually fed back into the network stack with the encapsulation removed to be sent to the real
destination. This option is mandatory.
PeerPort=
Specifies the peer port number. Defaults to unset. Note that when peer port is set "Peer=" address is
mandatory.
Protocol=
The Protocol= specifies the protocol number of the packets arriving at the UDP port. When
Encapsulation=FooOverUDP, this field is mandatory and is not set by default. Takes an IP protocol
name such as "gre" or "ipip", or an integer within the range 1...255. When
Encapsulation=GenericUDPEncapsulation, this must not be specified.
Peer=
Configures peer IP address. Note that when peer address is set "PeerPort=" is mandatory.
Local=
Configures local IP address.
[PEER] SECTION OPTIONS
The [Peer] section only applies for netdevs of kind "veth" and accepts the following keys:
Name=
The interface name used when creating the netdev. This setting is compulsory.
MACAddress=
The peer MACAddress, if not set, it is generated in the same way as the MAC address of the main
interface.
[VXCAN] SECTION OPTIONS
The [VXCAN] section only applies for netdevs of kind "vxcan" and accepts the following key:
Peer=
The peer interface name used when creating the netdev. This setting is compulsory.
[TUN] SECTION OPTIONS
The [Tun] section only applies for netdevs of kind "tun", and accepts the following keys:
MultiQueue=
Takes a boolean. Configures whether to use multiple file descriptors (queues) to parallelize packets
sending and receiving. Defaults to "no".
PacketInfo=
Takes a boolean. Configures whether packets should be prepended with four extra bytes (two flag bytes
and two protocol bytes). If disabled, it indicates that the packets will be pure IP packets. Defaults
to "no".
VNetHeader=
Takes a boolean. Configures IFF_VNET_HDR flag for a tun or tap device. It allows sending and
receiving larger Generic Segmentation Offload (GSO) packets. This may increase throughput
significantly. Defaults to "no".
User=
User to grant access to the /dev/net/tun device.
Group=
Group to grant access to the /dev/net/tun device.
[TAP] SECTION OPTIONS
The [Tap] section only applies for netdevs of kind "tap", and accepts the same keys as the [Tun] section.
[WIREGUARD] SECTION OPTIONS
The [WireGuard] section accepts the following keys:
PrivateKey=
The Base64 encoded private key for the interface. It can be generated using the wg genkey command
(see wg(8)). This option or PrivateKeyFile= is mandatory to use WireGuard. Note that because this
information is secret, you may want to set the permissions of the .netdev file to be owned by
"root:systemd-network" with a "0640" file mode.
PrivateKeyFile=
Takes an absolute path to a file which contains the Base64 encoded private key for the interface.
When this option is specified, then PrivateKey= is ignored. Note that the file must be readable by
the user "systemd-network", so it should be, e.g., owned by "root:systemd-network" with a "0640" file
mode. If the path refers to an AF_UNIX stream socket in the file system a connection is made to it
and the key read from it.
ListenPort=
Sets UDP port for listening. Takes either value between 1 and 65535 or "auto". If "auto" is
specified, the port is automatically generated based on interface name. Defaults to "auto".
FirewallMark=
Sets a firewall mark on outgoing WireGuard packets from this interface. Takes a number between 1 and
4294967295.
[WIREGUARDPEER] SECTION OPTIONS
The [WireGuardPeer] section accepts the following keys:
PublicKey=
Sets a Base64 encoded public key calculated by wg pubkey (see wg(8)) from a private key, and usually
transmitted out of band to the author of the configuration file. This option is mandatory for this
section.
PresharedKey=
Optional preshared key for the interface. It can be generated by the wg genpsk command. This option
adds an additional layer of symmetric-key cryptography to be mixed into the already existing
public-key cryptography, for post-quantum resistance. Note that because this information is secret,
you may want to set the permissions of the .netdev file to be owned by "root:systemd-network" with a
"0640" file mode.
PresharedKeyFile=
Takes an absolute path to a file which contains the Base64 encoded preshared key for the peer. When
this option is specified, then PresharedKey= is ignored. Note that the file must be readable by the
user "systemd-network", so it should be, e.g., owned by "root:systemd-network" with a "0640" file
mode. If the path refers to an AF_UNIX stream socket in the file system a connection is made to it
and the key read from it.
AllowedIPs=
Sets a comma-separated list of IP (v4 or v6) addresses with CIDR masks from which this peer is
allowed to send incoming traffic and to which outgoing traffic for this peer is directed.
The catch-all 0.0.0.0/0 may be specified for matching all IPv4 addresses, and ::/0 may be specified
for matching all IPv6 addresses.
Note that this only affects routing inside the network interface itself, i.e. the packets that pass
through the tunnel itself. To cause packets to be sent via the tunnel in the first place, an
appropriate route needs to be added as well — either in the "[Routes]" section on the ".network"
matching the wireguard interface, or externally to systemd-networkd.
Endpoint=
Sets an endpoint IP address or hostname, followed by a colon, and then a port number. This endpoint
will be updated automatically once to the most recent source IP address and port of correctly
authenticated packets from the peer at configuration time.
PersistentKeepalive=
Sets a seconds interval, between 1 and 65535 inclusive, of how often to send an authenticated empty
packet to the peer for the purpose of keeping a stateful firewall or NAT mapping valid persistently.
For example, if the interface very rarely sends traffic, but it might at anytime receive traffic from
a peer, and it is behind NAT, the interface might benefit from having a persistent keepalive interval
of 25 seconds. If set to 0 or "off", this option is disabled. By default or when unspecified, this
option is off. Most users will not need this.
[BOND] SECTION OPTIONS
The [Bond] section accepts the following key:
Mode=
Specifies one of the bonding policies. The default is "balance-rr" (round robin). Possible values are
"balance-rr", "active-backup", "balance-xor", "broadcast", "802.3ad", "balance-tlb", and
"balance-alb".
TransmitHashPolicy=
Selects the transmit hash policy to use for slave selection in balance-xor, 802.3ad, and tlb modes.
Possible values are "layer2", "layer3+4", "layer2+3", "encap2+3", and "encap3+4".
LACPTransmitRate=
Specifies the rate with which link partner transmits Link Aggregation Control Protocol Data Unit
packets in 802.3ad mode. Possible values are "slow", which requests partner to transmit LACPDUs every
30 seconds, and "fast", which requests partner to transmit LACPDUs every second. The default value is
"slow".
MIIMonitorSec=
Specifies the frequency that Media Independent Interface link monitoring will occur. A value of zero
disables MII link monitoring. This value is rounded down to the nearest millisecond. The default
value is 0.
UpDelaySec=
Specifies the delay before a link is enabled after a link up status has been detected. This value is
rounded down to a multiple of MIIMonitorSec. The default value is 0.
DownDelaySec=
Specifies the delay before a link is disabled after a link down status has been detected. This value
is rounded down to a multiple of MIIMonitorSec. The default value is 0.
LearnPacketIntervalSec=
Specifies the number of seconds between instances where the bonding driver sends learning packets to
each slave peer switch. The valid range is 1–0x7fffffff; the default value is 1. This option has an
effect only for the balance-tlb and balance-alb modes.
AdSelect=
Specifies the 802.3ad aggregation selection logic to use. Possible values are "stable", "bandwidth"
and "count".
AdActorSystemPriority=
Specifies the 802.3ad actor system priority. Takes a number in the range 1...65535.
AdUserPortKey=
Specifies the 802.3ad user defined portion of the port key. Takes a number in the range 0...1023.
AdActorSystem=
Specifies the 802.3ad system MAC address. This cannot be a null or multicast address.
FailOverMACPolicy=
Specifies whether the active-backup mode should set all slaves to the same MAC address at the time of
enslavement or, when enabled, to perform special handling of the bond's MAC address in accordance
with the selected policy. The default policy is none. Possible values are "none", "active" and
"follow".
ARPValidate=
Specifies whether or not ARP probes and replies should be validated in any mode that supports ARP
monitoring, or whether non-ARP traffic should be filtered (disregarded) for link monitoring purposes.
Possible values are "none", "active", "backup" and "all".
ARPIntervalSec=
Specifies the ARP link monitoring frequency. A value of 0 disables ARP monitoring. The default value
is 0, and the default unit seconds.
ARPIPTargets=
Specifies the IP addresses to use as ARP monitoring peers when ARPIntervalSec is greater than 0.
These are the targets of the ARP request sent to determine the health of the link to the targets.
Specify these values in IPv4 dotted decimal format. 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.
ARPAllTargets=
Specifies the quantity of ARPIPTargets that must be reachable in order for the ARP monitor to
consider a slave as being up. This option affects only active-backup mode for slaves with ARPValidate
enabled. Possible values are "any" and "all".
PrimaryReselectPolicy=
Specifies the reselection policy for the primary slave. This affects how the primary slave is chosen
to become the active slave when failure of the active slave or recovery of the primary slave occurs.
This option is designed to prevent flip-flopping between the primary slave and other slaves. Possible
values are "always", "better" and "failure".
ResendIGMP=
Specifies the number of IGMP membership reports to be issued after a failover event. One membership
report is issued immediately after the failover, subsequent packets are sent in each 200ms interval.
The valid range is 0–255. Defaults to 1. A value of 0 prevents the IGMP membership report from being
issued in response to the failover event.
PacketsPerSlave=
Specify the number of packets to transmit through a slave before moving to the next one. When set to
0, then a slave is chosen at random. The valid range is 0–65535. Defaults to 1. This option only has
effect when in balance-rr mode.
GratuitousARP=
Specify the number of peer notifications (gratuitous ARPs and unsolicited IPv6 Neighbor
Advertisements) to be issued after a failover event. As soon as the link is up on the new slave, a
peer notification is sent on the bonding device and each VLAN sub-device. This is repeated at each
link monitor interval (ARPIntervalSec or MIIMonitorSec, whichever is active) if the number is greater
than 1. The valid range is 0–255. The default value is 1. These options affect only the active-backup
mode.
AllSlavesActive=
Takes a boolean. Specifies that duplicate frames (received on inactive ports) should be dropped when
false, or delivered when true. Normally, bonding will drop duplicate frames (received on inactive
ports), which is desirable for most users. But there are some times it is nice to allow duplicate
frames to be delivered. The default value is false (drop duplicate frames received on inactive
ports).
DynamicTransmitLoadBalancing=
Takes a boolean. Specifies if dynamic shuffling of flows is enabled. Applies only for balance-tlb
mode. Defaults to unset.
MinLinks=
Specifies the minimum number of links that must be active before asserting carrier. The default value
is 0.
For more detail information see Linux Ethernet Bonding Driver HOWTO[1]
[XFRM] SECTION OPTIONS
The [Xfrm] section accepts the following keys:
InterfaceId=
Sets the ID/key of the xfrm interface which needs to be associated with a SA/policy. Can be decimal
or hexadecimal, valid range is 1-0xffffffff. This is mandatory.
Independent=
Takes a boolean. If false (the default), the xfrm interface must have an underlying device which can
be used for hardware offloading.
For more detail information see Virtual XFRM Interfaces[17].
[VRF] SECTION OPTIONS
The [VRF] section only applies for netdevs of kind "vrf" and accepts the following key:
Table=
The numeric routing table identifier. This setting is compulsory.
[BATMANADVANCED] SECTION OPTIONS
The [BatmanAdvanced] section only applies for netdevs of kind "batadv" and accepts the following keys:
GatewayMode=
Takes one of "off", "server", or "client". A batman-adv node can either run in server mode (sharing
its internet connection with the mesh) or in client mode (searching for the most suitable internet
connection in the mesh) or having the gateway support turned off entirely (which is the default
setting).
Aggregation=
Takes a boolean value. Enables or disables aggregation of originator messages. Defaults to true.
BridgeLoopAvoidance=
Takes a boolean value. Enables or disables avoidance of loops on bridges. Defaults to true.
DistributedArpTable=
Takes a boolean value. Enables or disables the distributed ARP table. Defaults to true.
Fragmentation=
Takes a boolean value. Enables or disables fragmentation. Defaults to true.
HopPenalty=
The hop penalty setting allows to modify batctl(8) preference for multihop routes vs. short routes.
This integer value is applied to the TQ (Transmit Quality) of each forwarded OGM (Originator
Message), thereby propagating the cost of an extra hop (the packet has to be received and
retransmitted which costs airtime). A higher hop penalty will make it more unlikely that other nodes
will choose this node as intermediate hop towards any given destination. The default hop penalty of
'15' is a reasonable value for most setups and probably does not need to be changed. However, mobile
nodes could choose a value of 255 (maximum value) to avoid being chosen as a router by other nodes.
The minimum value is 0.
OriginatorIntervalSec=
The value specifies the interval in seconds, unless another time unit is specified in which
batman-adv floods the network with its protocol information. See systemd.time(7) for more
information.
GatewayBandwidthDown=
If the node is a server, this parameter is used to inform other nodes in the network about this
node's internet connection download bandwidth in bits per second. Just enter any number suffixed with
K, M, G or T (base 1000) and the batman-adv module will propagate the entered value in the mesh.
GatewayBandwidthUp=
If the node is a server, this parameter is used to inform other nodes in the network about this
node's internet connection upload bandwidth in bits per second. Just enter any number suffixed with
K, M, G or T (base 1000) and the batman-adv module will propagate the entered value in the mesh.
RoutingAlgorithm=
This can be either "batman-v" or "batman-iv" and describes which routing_algo of batctl(8) to use.
The algorithm cannot be changed after interface creation. Defaults to "batman-v".
EXAMPLES
Example 1. /etc/systemd/network/25-bridge.netdev
[NetDev]
Name=bridge0
Kind=bridge
Example 2. /etc/systemd/network/25-vlan1.netdev
[Match]
Virtualization=no
[NetDev]
Name=vlan1
Kind=vlan
[VLAN]
Id=1
Example 3. /etc/systemd/network/25-ipip.netdev
[NetDev]
Name=ipip-tun
Kind=ipip
MTUBytes=1480
[Tunnel]
Local=192.168.223.238
Remote=192.169.224.239
TTL=64
Example 4. /etc/systemd/network/1-fou-tunnel.netdev
[NetDev]
Name=fou-tun
Kind=fou
[FooOverUDP]
Port=5555
Protocol=4
Example 5. /etc/systemd/network/25-fou-ipip.netdev
[NetDev]
Name=ipip-tun
Kind=ipip
[Tunnel]
Independent=yes
Local=10.65.208.212
Remote=10.65.208.211
FooOverUDP=yes
FOUDestinationPort=5555
Example 6. /etc/systemd/network/25-tap.netdev
[NetDev]
Name=tap-test
Kind=tap
[Tap]
MultiQueue=yes
PacketInfo=yes
Example 7. /etc/systemd/network/25-sit.netdev
[NetDev]
Name=sit-tun
Kind=sit
MTUBytes=1480
[Tunnel]
Local=10.65.223.238
Remote=10.65.223.239
Example 8. /etc/systemd/network/25-6rd.netdev
[NetDev]
Name=6rd-tun
Kind=sit
MTUBytes=1480
[Tunnel]
Local=10.65.223.238
IPv6RapidDeploymentPrefix=2602::/24
Example 9. /etc/systemd/network/25-gre.netdev
[NetDev]
Name=gre-tun
Kind=gre
MTUBytes=1480
[Tunnel]
Local=10.65.223.238
Remote=10.65.223.239
Example 10. /etc/systemd/network/25-ip6gre.netdev
[NetDev]
Name=ip6gre-tun
Kind=ip6gre
[Tunnel]
Key=123
Example 11. /etc/systemd/network/25-vti.netdev
[NetDev]
Name=vti-tun
Kind=vti
MTUBytes=1480
[Tunnel]
Local=10.65.223.238
Remote=10.65.223.239
Example 12. /etc/systemd/network/25-veth.netdev
[NetDev]
Name=veth-test
Kind=veth
[Peer]
Name=veth-peer
Example 13. /etc/systemd/network/25-bond.netdev
[NetDev]
Name=bond1
Kind=bond
[Bond]
Mode=802.3ad
TransmitHashPolicy=layer3+4
MIIMonitorSec=1s
LACPTransmitRate=fast
Example 14. /etc/systemd/network/25-dummy.netdev
[NetDev]
Name=dummy-test
Kind=dummy
MACAddress=12:34:56:78:9a:bc
Example 15. /etc/systemd/network/25-vrf.netdev
Create a VRF interface with table 42.
[NetDev]
Name=vrf-test
Kind=vrf
[VRF]
Table=42
Example 16. /etc/systemd/network/25-macvtap.netdev
Create a MacVTap device.
[NetDev]
Name=macvtap-test
Kind=macvtap
Example 17. /etc/systemd/network/25-wireguard.netdev
[NetDev]
Name=wg0
Kind=wireguard
[WireGuard]
PrivateKey=EEGlnEPYJV//kbvvIqxKkQwOiS+UENyPncC4bF46ong=
ListenPort=51820
[WireGuardPeer]
PublicKey=RDf+LSpeEre7YEIKaxg+wbpsNV7du+ktR99uBEtIiCA=
AllowedIPs=fd31:bf08:57cb::/48,192.168.26.0/24
Endpoint=wireguard.example.com:51820
Example 18. /etc/systemd/network/27-xfrm.netdev
[NetDev]
Name=xfrm0
Kind=xfrm
[Xfrm]
Independent=yes
SEE ALSO
systemd(1), systemd-networkd(8), systemd.link(5), systemd.network(5)
NOTES
1. Linux Ethernet Bonding Driver HOWTO
https://www.kernel.org/doc/Documentation/networking/bonding.txt
2. RFC 2784
https://tools.ietf.org/html/rfc2784
3. IEEE 802.1Q
http://www.ieee802.org/1/pages/802.1Q.html
4. VRF
https://www.kernel.org/doc/Documentation/networking/vrf.txt
5. B.A.T.M.A.N. Advanced
https://www.open-mesh.org/projects/open-mesh/wiki
6. (DVOE)
https://en.wikipedia.org/wiki/Distributed_Overlay_Virtual_Ethernet
7. VXLAN Group Policy
https://tools.ietf.org/html/draft-smith-vxlan-group-policy
8. Generic Protocol Extension for VXLAN
https://tools.ietf.org/html/draft-ietf-nvo3-vxlan-gpe-07
9. Type of Service in the Internet Protocol Suite
http://tools.ietf.org/html/rfc1349
10. RFC 6437
https://tools.ietf.org/html/rfc6437
11. RFC 2460
https://tools.ietf.org/html/rfc2460
12. RFC 2473
https://tools.ietf.org/html/rfc2473#section-4.1.1
13. ip-xfrm — transform configuration
http://man7.org/linux/man-pages/man8/ip-xfrm.8.html
14. Foo over UDP
https://lwn.net/Articles/614348
15. IPv6 Rapid Deployment
https://tools.ietf.org/html/rfc5569
16. Generic UDP Encapsulation
https://lwn.net/Articles/615044
17. Virtual XFRM Interfaces
https://lwn.net/Articles/757391