systemd.networksystemdDeveloperTomGundersenteg@jklm.nosystemd.network5systemd.networkNetwork configurationnetwork.networkDescriptionNetwork setup is performed by
systemd-networkd8.
The main network file must have the extension .network; other
extensions are ignored. Networks are applied to links whenever the links appear.The .network files are read from the files located in the system
network directory /usr/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 /usr/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 network file foo.network, a "drop-in" directory
foo.network.d/ may exist. All files with the suffix
.conf from this directory will be parsed after the file itself is
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 /usr/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 /usr/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.)Note that an interface without any static IPv6 addresses configured, and neither DHCPv6
nor IPv6LL enabled, shall be considered to have no IPv6 support. IPv6 will be automatically
disabled for that interface by writing "1" to
/proc/sys/net/ipv6/conf/ifname/disable_ipv6.
[Match] Section OptionsThe network file contains a [Match]
section, which determines if a given network file may be applied
to a given device; and a [Network] section
specifying how the device should be configured. The first (in
lexical order) of the network files that matches a given device
is applied, all later files are ignored, even if they match as
well.A network file is said to match a device if each of the
entries in the [Match] section matches, or if
the section is empty. The following keys are accepted:MACAddress=The hardware address of the interface (use full colon-delimited hexadecimal, e.g.,
01:23:45:67:89:ab).Path=A whitespace-separated list of shell-style globs
matching the persistent path, as exposed by the udev
property ID_PATH.Driver=A whitespace-separated list of shell-style globs
matching the driver currently bound to the device, as
exposed by the udev property DRIVER
of its parent device, or if that is not set the driver
as exposed by ethtool -i of the
device itself.Type=A whitespace-separated list of shell-style globs
matching the device type, as exposed by the udev property
DEVTYPE.Name=A whitespace-separated list of shell-style globs
matching the device name, as exposed by the udev property
INTERFACE.Host=Matches against the hostname or machine ID of the
host. See ConditionHost= in
systemd.unit5
for details.
Virtualization=Checks whether the system is executed in a virtualized
environment and optionally test whether it is a specific
implementation. See ConditionVirtualization= in
systemd.unit5
for details.
KernelCommandLine=Checks whether a specific kernel command line option is
set (or if prefixed with the exclamation mark unset). See
ConditionKernelCommandLine= in
systemd.unit5
for details.
Architecture=Checks whether the system is running on a specific
architecture. See ConditionArchitecture= in
systemd.unit5
for details.
[Link] Section Options The [Link] section accepts the following keys:MACAddress=The hardware address to set for the device.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.Note that if IPv6 is enabled on the interface, and the MTU is chosen
below 1280 (the minimum MTU for IPv6) it will automatically be increased to this value.ARP= A boolean. Enables or disables the ARP (low-level Address Resolution Protocol)
for this interface. Defaults to unset, which means that the kernel default will be used. For example, disabling ARP is useful when creating multiple MACVLAN or VLAN virtual
interfaces atop a single lower-level physical interface, which will then only serve as a
link/"bridge" device aggregating traffic to the same physical link and not participate in
the network otherwise.Unmanaged=A boolean. When yes, no attempts are
made to bring up or configure matching links, equivalent to
when there are no matching network files. Defaults to
no.This is useful for preventing later matching network
files from interfering with certain interfaces that are fully
controlled by other applications.[Network] Section OptionsThe [Network] section accepts the following keys:Description=A description of the device. This is only used for
presentation purposes.DHCP=Enables DHCPv4 and/or DHCPv6 client support. Accepts
yes, no,
ipv4, or ipv6.Note that DHCPv6 will by default be triggered by Router
Advertisement, if that is enabled, regardless of this parameter.
By enabling DHCPv6 support explicitly, the DHCPv6 client will
be started regardless of the presence of routers on the link,
or what flags the routers pass. See
IPv6AcceptRA=.Furthermore, note that by default the domain name
specified through DHCP is not used for name resolution.
See option below.See the [DHCP] section below for further configuration options for the DHCP client
support.DHCPServer=A boolean. Enables DHCPv4 server support. Defaults
to no. Further settings for the DHCP
server may be set in the [DHCPServer]
section described below.LinkLocalAddressing=Enables link-local address autoconfiguration. Accepts
yes, no,
ipv4, or ipv6. Defaults to
ipv6.IPv4LLRoute=A boolean. When true, sets up the route needed for
non-IPv4LL hosts to communicate with IPv4LL-only hosts. Defaults
to false.
IPv6Token=An IPv6 address with the top 64 bits unset. When set, indicates the
64-bit interface part of SLAAC IPv6 addresses for this link. Note that
the token is only ever used for SLAAC, and not for DHCPv6 addresses, even
in the case DHCP is requested by router advertisement. By default, the
token is autogenerated.LLMNR=A boolean or resolve. When true,
enables Link-Local
Multicast Name Resolution on the link. When set to
resolve, only resolution is enabled,
but not host registration and announcement. Defaults to
true. This setting is read by
systemd-resolved.service8.MulticastDNS=A boolean or resolve. When true,
enables Multicast
DNS support on the link. When set to
resolve, only resolution is enabled,
but not host or service registration and
announcement. Defaults to false. This setting is read by
systemd-resolved.service8.DNSSEC=A boolean or
allow-downgrade. When true, enables
DNSSEC
DNS validation support on the link. When set to
allow-downgrade, compatibility with
non-DNSSEC capable networks is increased, by automatically
turning off DNSEC in this case. This option defines a
per-interface setting for
resolved.conf5's
global DNSSEC= option. Defaults to
false. This setting is read by
systemd-resolved.service8.DNSSECNegativeTrustAnchors=A space-separated list of DNSSEC negative
trust anchor domains. If specified and DNSSEC is enabled,
look-ups done via the interface's DNS server will be subject
to the list of negative trust anchors, and not require
authentication for the specified domains, or anything below
it. Use this to disable DNSSEC authentication for specific
private domains, that cannot be proven valid using the
Internet DNS hierarchy. Defaults to the empty list. This
setting is read by
systemd-resolved.service8.LLDP=Controls support for Ethernet LLDP packet reception. LLDP is a link-layer protocol commonly
implemented on professional routers and bridges which announces which physical port a system is connected
to, as well as other related data. Accepts a boolean or the special value
routers-only. When true, incoming LLDP packets are accepted and a database of all LLDP
neighbors maintained. If routers-only is set only LLDP data of various types of routers
is collected and LLDP data about other types of devices ignored (such as stations, telephones and
others). If false, LLDP reception is disabled. Defaults to routers-only. Use
networkctl1 to query the
collected neighbor data. LLDP is only available on Ethernet links. See EmitLLDP= below
for enabling LLDP packet emission from the local system.
EmitLLDP=Controls support for Ethernet LLDP packet emission. Accepts a boolean parameter or the special values
nearest-bridge, non-tpmr-bridge and
customer-bridge. Defaults to false, which turns off LLDP packet emission. If not false,
a short LLDP packet with information about the local system is sent out in regular intervals on the
link. The LLDP packet will contain information about the local host name, the local machine ID (as stored
in machine-id5) and the
local interface name, as well as the pretty hostname of the system (as set in
machine-info5). LLDP
emission is only available on Ethernet links. Note that this setting passes data suitable for
identification of host to the network and should thus not be enabled on untrusted networks, where such
identification data should not be made available. Use this option to permit other systems to identify on
which interfaces they are connected to this system. The three special values control propagation of the
LLDP packets. The nearest-bridge setting permits propagation only to the nearest
connected bridge, non-tpmr-bridge permits propagation across Two-Port MAC Relays, but
not any other bridges, and customer-bridge permits propagation until a customer bridge
is reached. For details about these concepts, see IEEE 802.1AB-2009. Note that
configuring this setting to true is equivalent to nearest-bridge, the recommended and
most restricted level of propagation. See LLDP= above for an option to enable LLDP
reception.BindCarrier=A link name or a list of link names. When set, controls the behavior of the current
link. When all links in the list are in an operational down state, the current link is brought
down. When at least one link has carrier, the current interface is brought up.
Address=A static IPv4 or IPv6 address and its prefix length,
separated by a / character. Specify
this key more than once to configure several addresses.
The format of the address must be as described in
inet_pton3.
This is a short-hand for an [Address] section only
containing an Address key (see below). This option may be
specified more than once.
If the specified address is 0.0.0.0 (for IPv4) or
[::] (for IPv6), a new address range of the requested size
is automatically allocated from a system-wide pool of
unused ranges. The allocated range is checked against all
current network interfaces and all known network
configuration files to avoid address range conflicts. The
default system-wide pool consists of 192.168.0.0/16,
172.16.0.0/12 and 10.0.0.0/8 for IPv4, and fc00::/7 for
IPv6. This functionality is useful to manage a large
number of dynamically created network interfaces with the
same network configuration and automatic address range
assignment.Gateway=The gateway address, which must be in the format
described in
inet_pton3.
This is a short-hand for a [Route] section only containing
a Gateway key. This option may be specified more than
once.DNS=A DNS server address, which must be in the format
described in
inet_pton3.
This option may be specified more than once. This setting is read by
systemd-resolved.service8.Domains=A list of domains which should be resolved using the DNS servers on this link. Each item in the list
should be a domain name, optionally prefixed with a tilde (~). The domains with the
prefix are called "routing-only domains". The domains without the prefix are called "search domains" and
are first used as search suffixes for extending single-label host names (host names containing no dots) to
become fully qualified domain names (FQDNs). If a single-label host name is resolved on this interface,
each of the specified search domains are appended to it in turn, converting it into a fully qualified
domain name, until one of them may be successfully resolved.Both "search" and "routing-only" domains are used for routing of DNS queries: look-ups for host names
ending in those domains (hence also single label names, if any "search domains" are listed), are routed to
the DNS servers configured for this interface. The domain routing logic is particularly useful on
multi-homed hosts with DNS servers serving particular private DNS zones on each interface.The "routing-only" domain ~. (the tilde indicating definition of a routing domain,
the dot referring to the DNS root domain which is the implied suffix of all valid DNS names) has special
effect. It causes all DNS traffic which does not match another configured domain routing entry to be routed
to DNS servers specified for this interface. This setting is useful to prefer a certain set of DNS servers
if a link on which they are connected is available.This setting is read by
systemd-resolved.service8.
"Search domains" correspond to the domain and search entries in
resolv.conf5.
Domain name routing has no equivalent in the traditional glibc API, which has no concept of domain
name servers limited to a specific link.NTP=An NTP server address. This option may be specified more than once. This setting is read by
systemd-timesyncd.service8.IPForward=Configures IP packet forwarding for the
system. If enabled, incoming packets on any network
interface will be forwarded to any other interfaces
according to the routing table. Takes either a boolean
argument, or the values ipv4 or
ipv6, which only enable IP packet
forwarding for the specified address family. This controls
the net.ipv4.ip_forward and
net.ipv6.conf.all.forwarding sysctl
options of the network interface (see ip-sysctl.txt
for details about sysctl options). Defaults to
no.Note: this setting controls a global kernel option,
and does so one way only: if a network that has this setting
enabled is set up the global setting is turned on. However,
it is never turned off again, even after all networks with
this setting enabled are shut down again.To allow IP packet forwarding only between specific
network interfaces use a firewall.IPMasquerade=Configures IP masquerading for the network
interface. If enabled, packets forwarded from the network
interface will be appear as coming from the local host.
Takes a boolean argument. Implies
IPForward=ipv4. Defaults to
no.IPv6PrivacyExtensions=Configures use of stateless temporary
addresses that change over time (see RFC 4941,
Privacy Extensions for Stateless Address Autoconfiguration
in IPv6). Takes a boolean or the special values
prefer-public and
kernel. When true, enables the privacy
extensions and prefers temporary addresses over public
addresses. When prefer-public, enables the
privacy extensions, but prefers public addresses over
temporary addresses. When false, the privacy extensions
remain disabled. When kernel, the kernel's
default setting will be left in place. Defaults to
no.IPv6AcceptRA=Enable or disable IPv6 Router Advertisement (RA) reception support for the interface. Takes
a boolean parameter. If true, RAs are accepted; if false, RAs are ignored, independently of the local
forwarding state. When not set, the kernel default is used, and RAs are accepted only when local forwarding
is disabled for that interface. When RAs are accepted, they may trigger the start of the DHCPv6 client if
the relevant flags are set in the RA data, or if no routers are found on the link.Further settings for the IPv6 RA support may be configured in the
[IPv6AcceptRA] section, see below.Also see ip-sysctl.txt in the kernel
documentation regarding accept_ra, but note that systemd's setting of
1 (i.e. true) corresponds to kernel's setting of 2.IPv6DuplicateAddressDetection=Configures the amount of IPv6 Duplicate
Address Detection (DAD) probes to send. Defaults to unset.
IPv6HopLimit=Configures IPv6 Hop Limit. For each router that
forwards the packet, the hop limit is decremented by 1. When the
hop limit field reaches zero, the packet is discarded.
Defaults to unset.
ProxyARP=A boolean. Configures proxy ARP. Proxy ARP is the technique in which one host,
usually a router, answers ARP requests intended for another machine. By "faking" its identity,
the router accepts responsibility for routing packets to the "real" destination. (see RFC 1027.
Defaults to unset.
Bridge=The name of the bridge to add the link to. See
systemd.netdev5.
Bond=The name of the bond to add the link to. See
systemd.netdev5.
VRF=The name of the VRF to add the link to. See
systemd.netdev5.
VLAN=The name of a VLAN to create on the link. See
systemd.netdev5.
This option may be specified more than once.MACVLAN=The name of a MACVLAN to create on the link. See
systemd.netdev5.
This option may be specified more than once.VXLAN=The name of a VXLAN to create on the link. See
systemd.netdev5.
This option may be specified more than once.Tunnel=The name of a Tunnel to create on the link. See
systemd.netdev5.
This option may be specified more than once.[Address] Section OptionsAn [Address] section accepts the
following keys. Specify several [Address]
sections to configure several addresses.Address=As in the [Network] section. This
key is mandatory.Peer=The peer address in a point-to-point connection.
Accepts the same format as the Address
key.Broadcast=The broadcast address, which must be in the format
described in
inet_pton3.
This key only applies to IPv4 addresses. If it is not
given, it is derived from the Address
key.Label=An address label.PreferredLifetime=Allows the default "preferred lifetime" of the address to be overridden.
Only three settings are accepted: forever or infinity
which is the default and means that the address never expires, and 0 which means
that the address is considered immediately "expired" and will not be used,
unless explicitly requested. A setting of PreferredLifetime=0 is useful for
addresses which are added to be used only by a specific application,
which is then configured to use them explicitly.HomeAddress=Takes a boolean argument. Designates this address the "home address" as defined in
RFC 6275.
Supported only on IPv6. Defaults to false.DuplicateAddressDetection=Takes a boolean argument. Do not perform Duplicate Address Detection
RFC 4862 when adding this address.
Supported only on IPv6. Defaults to false.ManageTemporaryAddress=Takes a boolean argument. If true the kernel manage temporary addresses created
from this one as template on behalf of Privacy Extensions
RFC 3041. For this to become
active, the use_tempaddr sysctl setting has to be set to a value greater than zero.
The given address needs to have a prefix length of 64. This flag allows to use privacy
extensions in a manually configured network, just like if stateless auto-configuration
was active. Defaults to false. PrefixRoute=Takes a boolean argument. When adding or modifying an IPv6 address, the userspace
application needs a way to suppress adding a prefix route. This is for example relevant
together with IFA_F_MANAGERTEMPADDR, where userspace creates autoconf generated addresses,
but depending on on-link, no route for the prefix should be added. Defaults to false.AutoJoin=Takes a boolean argument. Joining multicast group on ethernet level via
ip maddr command would not work if we have an Ethernet switch that does
IGMP snooping since the switch would not replicate multicast packets on ports that did not
have IGMP reports for the multicast addresses. Linux vxlan interfaces created via
ip link add vxlan or networkd's netdev kind vxlan have the group option
that enables then to do the required join. By extending ip address command with option
autojoin we can get similar functionality for openvswitch (OVS) vxlan
interfaces as well as other tunneling mechanisms that need to receive multicast traffic.
Defaults to no.[Route] Section OptionsThe [Route] section accepts the
following keys. Specify several [Route]
sections to configure several routes.Gateway=As in the [Network] section.Destination=The destination prefix of the route. Possibly
followed by a slash and the prefix length. If omitted, a
full-length host route is assumed.Source=The source prefix of the route. Possibly followed by
a slash and the prefix length. If omitted, a full-length
host route is assumed.Metric=The metric of the route (an unsigned integer).Scope=The scope of the route, which can be global,
link or host. Defaults to
global.PreferredSource=The preferred source address of the route. The address
must be in the format described in
inet_pton3.Table=numThe table identifier for the route (a number between 1 and 4294967295, or 0 to unset).
The table can be retrieved using ip route show table num.
[DHCP] Section OptionsThe [DHCP] section configures the
DHCPv4 and DHCP6 client, if it is enabled with the
DHCP= setting described above:UseDNS=When true (the default), the DNS servers received
from the DHCP server will be used and take precedence over
any statically configured ones.This corresponds to the
option in resolv.conf5.UseNTP=When true (the default), the NTP servers received
from the DHCP server will be used by systemd-timesyncd
and take precedence over any statically configured ones.UseMTU=When true, the interface maximum transmission unit
from the DHCP server will be used on the current link.
Defaults to false.SendHostname=When true (the default), the machine's hostname will
be sent to the DHCP server.UseHostname=When true (the default), the hostname received from
the DHCP server will be set as the transient hostname of the system
Hostname=Use this value for the hostname which is sent to the
DHCP server, instead of machine's hostname.UseDomains=Takes a boolean argument, or the special value route. When true, the domain name
received from the DHCP server will be used as DNS search domain over this link, similar to the effect of
the setting. If set to route, the domain name received from
the DHCP server will be used for routing DNS queries only, but not for searching, similar to the effect of
the setting when the argument is prefixed with ~. Defaults to
false.It is recommended to enable this option only on trusted networks, as setting this affects resolution
of all host names, in particular of single-label names. It is generally safer to use the supplied domain
only as routing domain, rather than as search domain, in order to not have it affect local resolution of
single-label names.When set to true, this setting corresponds to the option in resolv.conf5.UseRoutes=When true (the default), the static routes will be
requested from the DHCP server and added to the routing
table with a metric of 1024.UseTimezone=When true, the timezone received from the
DHCP server will be set as timezone of the local
system. Defaults to no.CriticalConnection=When true, the connection will never be torn down
even if the DHCP lease expires. This is contrary to the
DHCP specification, but may be the best choice if, say,
the root filesystem relies on this connection. Defaults to
false.ClientIdentifier=The DHCPv4 client identifier to use. Either mac to use the MAC address of the link
or duid (the default, see below) to use an RFC4361-compliant Client ID.VendorClassIdentifier=The vendor class identifier used to identify vendor
type and configuration.DUIDType=Override the global DUIDType setting for this network. See
networkd.conf5
for a description of possible values.DUIDRawData=Override the global DUIDRawData setting for this network. See
networkd.conf5
for a description of possible values.IAID=The DHCP Identity Association Identifier (IAID) for the interface, a 32-bit unsigned integer.RequestBroadcast=Request the server to use broadcast messages before
the IP address has been configured. This is necessary for
devices that cannot receive RAW packets, or that cannot
receive packets at all before an IP address has been
configured. On the other hand, this must not be enabled on
networks where broadcasts are filtered out.RouteMetric=Set the routing metric for routes specified by the
DHCP server.RouteTable=numThe table identifier for DHCP routes (a number between 1 and 4294967295, or 0 to unset).
The table can be retrieved using ip route show table num.
ListenPort=Allow setting custom port for the DHCP client to listen on.[IPv6AcceptRA] Section OptionsThe [IPv6AcceptRA] section configures the IPv6 Router Advertisement
(RA) client, if it is enabled with the IPv6AcceptRA= setting described
above:UseDNS=When true (the default), the DNS servers received in the Router Advertisement will be used and take
precedence over any statically configured ones.This corresponds to the option in resolv.conf5.UseDomains=Takes a boolean argument, or the special value route. When true, the domain name
received via IPv6 Router Advertisement (RA) will be used as DNS search domain over this link, similar to
the effect of the setting. If set to route, the domain name
received via IPv6 RA will be used for routing DNS queries only, but not for searching, similar to the
effect of the setting when the argument is prefixed with
~. Defaults to false.It is recommended to enable this option only on trusted networks, as setting this affects resolution
of all host names, in particular of single-label names. It is generally safer to use the supplied domain
only as routing domain, rather than as search domain, in order to not have it affect local resolution of
single-label names.When set to true, this setting corresponds to the option in resolv.conf5.RouteTable=numThe table identifier for the routes received in the Router Advertisement
(a number between 1 and 4294967295, or 0 to unset).
The table can be retrieved using ip route show table num.
[DHCPServer] Section OptionsThe [DHCPServer] section contains
settings for the DHCP server, if enabled via the
DHCPServer= option described above:PoolOffset=PoolSize=Configures the pool of addresses to hand out. The pool
is a contiguous sequence of IP addresses in the subnet configured for
the server address, which does not include the subnet nor the broadcast
address. PoolOffset= takes the offset of the pool
from the start of subnet, or zero to use the default value.
PoolSize= takes the number of IP addresses in the
pool or zero to use the default value. By default, the pool starts at
the first address after the subnet address and takes up the rest of
the subnet, excluding the broadcast address. If the pool includes
the server address (the default), this is reserved and not handed
out to clients.DefaultLeaseTimeSec=MaxLeaseTimeSec=Control the default and maximum DHCP lease
time to pass to clients. These settings take time values in seconds or
another common time unit, depending on the suffix. The default
lease time is used for clients that did not ask for a specific
lease time. If a client asks for a lease time longer than the
maximum lease time, it is automatically shortened to the
specified time. The default lease time defaults to 1h, the
maximum lease time to 12h. Shorter lease times are beneficial
if the configuration data in DHCP leases changes frequently
and clients shall learn the new settings with shorter
latencies. Longer lease times reduce the generated DHCP
network traffic.EmitDNS=DNS=Configures whether the DHCP leases handed out
to clients shall contain DNS server information. The
EmitDNS= setting takes a boolean argument
and defaults to yes. The DNS servers to
pass to clients may be configured with the
DNS= option, which takes a list of IPv4
addresses. If the EmitDNS= option is
enabled but no servers configured, the servers are
automatically propagated from an "uplink" interface that has
appropriate servers set. The "uplink" interface is determined
by the default route of the system with the highest
priority. Note that this information is acquired at the time
the lease is handed out, and does not take uplink interfaces
into account that acquire DNS or NTP server information at a
later point. DNS server propagation does not take
/etc/resolv.conf into account. Also, note
that the leases are not refreshed if the uplink network
configuration changes. To ensure clients regularly acquire the
most current uplink DNS server information, it is thus
advisable to shorten the DHCP lease time via
MaxLeaseTimeSec= described
above.EmitNTP=NTP=Similar to the EmitDNS= and
DNS= settings described above, these
settings configure whether and what NTP server information
shall be emitted as part of the DHCP lease. The same syntax,
propagation semantics and defaults apply as for
EmitDNS= and
DNS=.EmitRouter=Similar to the EmitDNS=
setting described above, this setting configures whether the
DHCP lease should contain the router option. The same syntax,
propagation semantics and defaults apply as for
EmitDNS=.EmitTimezone=Timezone=Configures whether the DHCP leases handed out
to clients shall contain timezone information. The
EmitTimezone= setting takes a boolean
argument and defaults to yes. The
Timezone= setting takes a timezone string
(such as Europe/Berlin or
UTC) to pass to clients. If no explicit
timezone is set, the system timezone of the local host is
propagated, as determined by the
/etc/localtime symlink.[Bridge] Section OptionsThe [Bridge] section accepts the
following keys.UnicastFlood=A boolean. Controls whether the bridge should flood
traffic for which an FDB entry is missing and the destination
is unknown through this port. Defaults to on.
HairPin=A boolean. Configures whether traffic may be sent back
out of the port on which it was received. By default, this
flag is false, and the bridge will not forward traffic back
out of the receiving port.UseBPDU=A boolean. Configures whether STP Bridge Protocol Data Units will be
processed by the bridge port. Defaults to yes.FastLeave=A boolean. This flag allows the bridge to immediately stop multicast
traffic on a port that receives an IGMP Leave message. It is only used with
IGMP snooping if enabled on the bridge. Defaults to off.AllowPortToBeRoot=A boolean. Configures whether a given port is allowed to
become a root port. Only used when STP is enabled on the bridge.
Defaults to on.Cost=Sets the "cost" of sending packets of this interface.
Each port in a bridge may have a different speed and the cost
is used to decide which link to use. Faster interfaces
should have lower costs.[BridgeFDB] Section OptionsThe [BridgeFDB] section manages the
forwarding database table of a port and accepts the following
keys. Specify several [BridgeFDB] sections to
configure several static MAC table entries.MACAddress=As in the [Network] section. This
key is mandatory.VLANId=The VLAN ID for the new static MAC table entry. If
omitted, no VLAN ID info is appended to the new static MAC
table entry.[BridgeVLAN] Section OptionsThe [BridgeVLAN] section manages the VLAN ID configuration of a bridge port and accepts
the following keys. Specify several [BridgeVLAN] sections to configure several VLAN entries.
The VLANFiltering= option has to be enabled, see [Bridge] section in
systemd.netdev5.VLAN=The VLAN ID allowed on the port. This can be either a single ID or a range M-N. VLAN IDs are valid
from 1 to 4094.EgressUntagged=The VLAN ID specified here will be used to untag frames on egress. Configuring
EgressUntagged= implicates the use of VLAN= above and will enable the
VLAN ID for ingress as well. This can be either a single ID or a range M-N.PVID=The Port VLAN ID specified here is assigned to all untagged frames at ingress.
PVID= can be used only once. Configuring PVID= implicates the use of
VLAN= above and will enable the VLAN ID for ingress as well.ExamplesStatic network configuration# /etc/systemd/network/50-static.network
[Match]
Name=enp2s0
[Network]
Address=192.168.0.15/24
Gateway=192.168.0.1This brings interface enp2s0 up with a static address. The
specified gateway will be used for a default route.DHCP on ethernet links# /etc/systemd/network/80-dhcp.network
[Match]
Name=en*
[Network]
DHCP=yesThis will enable DHCPv4 and DHCPv6 on all interfaces with names starting with
en (i.e. ethernet interfaces).A bridge with two enslaved links# /etc/systemd/network/25-bridge-static.network
[Match]
Name=bridge0
[Network]
Address=192.168.0.15/24
Gateway=192.168.0.1
DNS=192.168.0.1# /etc/systemd/network/25-bridge-slave-interface-1.network
[Match]
Name=enp2s0
[Network]
Bridge=bridge0# /etc/systemd/network/25-bridge-slave-interface-2.network
[Match]
Name=wlp3s0
[Network]
Bridge=bridge0This creates a bridge and attaches devices enp2s0 and
wlp3s0 to it. The bridge will have the specified static address
and network assigned, and a default route via the specified gateway will be
added. The specified DNS server will be added to the global list of DNS resolvers.
# /etc/systemd/network/20-bridge-slave-interface-vlan.network
[Match]
Name=enp2s0
[Network]
Bridge=bridge0
[BridgeVLAN]
VLAN=1-32
PVID=42
EgressUntagged=42
[BridgeVLAN]
VLAN=100-200
[BridgeVLAN]
EgressUntagged=300-400This overrides the configuration specified in the previous example for the
interface enp2s0, and enables VLAN on that bridge port. VLAN IDs
1-32, 42, 100-400 will be allowed. Packets tagged with VLAN IDs 42, 300-400 will be
untagged when they leave on this interface. Untagged packets which arrive on this
interface will be assigned VLAN ID 42.Various tunnels/etc/systemd/network/25-tunnels.network
[Match]
Name=ens1
[Network]
Tunnel=ipip-tun
Tunnel=sit-tun
Tunnel=gre-tun
Tunnel=vti-tun
/etc/systemd/network/25-tunnel-ipip.netdev
[NetDev]
Name=ipip-tun
Kind=ipip
/etc/systemd/network/25-tunnel-sit.netdev
[NetDev]
Name=sit-tun
Kind=sit
/etc/systemd/network/25-tunnel-gre.netdev
[NetDev]
Name=gre-tun
Kind=gre
/etc/systemd/network/25-tunnel-vti.netdev
[NetDev]
Name=vti-tun
Kind=vti
This will bring interface ens1 up and create an IPIP tunnel,
a SIT tunnel, a GRE tunnel, and a VTI tunnel using it.A bond device# /etc/systemd/network/30-bond1.network
[Match]
Name=bond1
[Network]
DHCP=ipv6
# /etc/systemd/network/30-bond1.netdev
[NetDev]
Name=bond1
Kind=bond
# /etc/systemd/network/30-bond1-dev1.nework
[Match]
MACAddress=52:54:00:e9:64:41
[Network]
Bond=bond1
# /etc/systemd/network/30-bond1-dev2.nework
[Match]
MACAddress=52:54:00:e9:64:42
[Network]
Bond=bond1
This will create a bond device bond1 and enslave the two
devices with MAC addresses 52:54:00:e9:64:41 and 52:54:00:e9:64:42 to it. IPv6 DHCP
will be used to acquire an address.Virtual Routing and Forwarding (VRF)Add the bond1 interface to the VRF master interface
vrf1. This will redirect routes generated on this interface to be
within the routing table defined during VRF creation. Traffic won't be redirected
towards the VRFs routing table unless specific ip-rules are added.# /etc/systemd/network/25-vrf.network
[Match]
Name=bond1
[Network]
VRF=vrf1
See Alsosystemd1,
systemd-networkd.service8,
systemd.link5,
systemd.netdev5,
systemd-resolved.service8