<html> <body> <h1>Network XML format</h1> <ul id="toc"> </ul> <p> This page provides an introduction to the network XML format. For background information on the concepts referred to here, consult the <a href="archnetwork.html">network driver architecture</a> page. </p> <h2><a name="elements">Element and attribute overview</a></h2> <p> The root element required for all virtual networks is named <code>network</code> and has no configurable attributes (although <span class="since">since 0.10.0</span> there is one optional read-only attribute - when examining the live configuration of a network, the attribute <code>connections</code>, if present, specifies the number of guest interfaces currently connected via this network). The network XML format is available <span class="since">since 0.3.0</span> </p> <h3><a name="elementsMetadata">General metadata</a></h3> <p> The first elements provide basic metadata about the virtual network. </p> <pre> <network> <name>default</name> <uuid>3e3fce45-4f53-4fa7-bb32-11f34168b82b</uuid> ...</pre> <dl> <dt><code>name</code></dt> <dd>The content of the <code>name</code> element provides a short name for the virtual network. This name should consist only of alpha-numeric characters and is required to be unique within the scope of a single host. It is used to form the filename for storing the persistent configuration file. <span class="since">Since 0.3.0</span></dd> <dt><code>uuid</code></dt> <dd>The content of the <code>uuid</code> element provides a globally unique identifier for the virtual network. The format must be RFC 4122 compliant, eg <code>3e3fce45-4f53-4fa7-bb32-11f34168b82b</code>. If omitted when defining/creating a new network, a random UUID is generated. <span class="since">Since 0.3.0</span></dd> </dl> <h3><a name="elementsConnect">Connectivity</a></h3> <p> The next set of elements control how a virtual network is provided connectivity to the physical LAN (if at all). </p> <pre> ... <bridge name="virbr0" stp="on" delay="5"/> <domain name="example.com"/> <forward mode="nat" dev="eth0"/> ...</pre> <dl> <dt><code>bridge</code></dt> <dd>The <code>name</code> attribute on the <code>bridge</code> element defines the name of a bridge device which will be used to construct the virtual network. The virtual machines will be connected to this bridge device allowing them to talk to each other. The bridge device may also be connected to the LAN. It is recommended that bridge device names started with the prefix <code>vir</code>, but the name <code>virbr0</code> is reserved for the "default" virtual network. This element should always be provided when defining a new network with a <code><forward></code> mode of "nat" or "route" (or an isolated network with no <code><forward></code> element). Attribute <code>stp</code> specifies if Spanning Tree Protocol is 'on' or 'off' (default is 'on'). Attribute <code>delay</code> sets the bridge's forward delay value in seconds (default is 0). <span class="since">Since 0.3.0</span> </dd> <dt><code>domain</code></dt> <dd> The <code>name</code> attribute on the <code>domain</code> element defines the DNS domain of the DHCP server. This element is optional, and is only used for those networks with a <code><forward></code> mode of "nat" or "route" (or an isolated network with no <code><forward></code> element). <span class="since">Since 0.4.5</span> </dd> <dt><code>forward</code></dt> <dd>Inclusion of the <code>forward</code> element indicates that the virtual network is to be connected to the physical LAN.<span class="since">Since 0.3.0.</span> The <code>mode</code> attribute determines the method of forwarding. If there is no <code>forward</code> element, the network will be isolated from any other network (unless a guest connected to that network is acting as a router, of course). The following are valid settings for <code>mode</code> (if there is a <code>forward</code> element but mode is not specified, <code>mode='nat'</code> is assumed): <dl> <dt><code>nat</code></dt> <dd> All traffic between guests connected to this network and the physical network will be forwarded to the physical network via the host's IP routing stack, after the guest's IP address is translated to appear as the host machine's public IP address (a.k.a. Network Address Translation, or "NAT"). This allows multiple guests, all having access to the physical network, on a host that is only allowed a single public IP address. If a network has any IPv6 addresses defined, the IPv6 traffic will be forwarded using plain routing, since IPv6 has no concept of NAT. Firewall rules will allow outbound connections to any other network device whether ethernet, wireless, dialup, or VPN. If the <code>dev</code> attribute is set, the firewall rules will restrict forwarding to the named device only. Inbound connections from other networks are all prohibited; all connections between guests on the same network, and to/from the host to the guests, are unrestricted and not NATed.<span class="since">Since 0.4.2</span> </dd> <dt><code>route</code></dt> <dd> Guest network traffic will be forwarded to the physical network via the host's IP routing stack, but without having NAT applied. Again, if the <code>dev</code> attribute is set, firewall rules will restrict forwarding to the named device only. This presumes that the local LAN router has suitable routing table entries to return traffic to this host. All incoming and outgoing sessions to guest on these networks are unrestricted. (To restrict incoming traffic to a guest on a routed network, you can configure <a href="formatnwfilter.html">nwfilter rules</a> on the guest's interfaces.) <span class="since">Since 0.4.2</span> </dd> <dt><code>bridge</code></dt> <dd> This network describes either 1) an existing host bridge that was configured outside of libvirt (if a <code><bridge name='xyz'/></code> element has been specified, <span class="since">Since 0.9.4</span>), 2) an existing Open vSwitch bridge that was configured outside of libvirt (if both a <code><bridge name='xyz'/></code> element <b>and</b> a <code><virtualport type='openvswitch'/></code> have been specified <span class="since">Since 0.10.0</span>) 3) an interface or group of interfaces to be used for a "direct" connection via macvtap using macvtap's "bridge" mode (if the forward element has one or more <code><interface></code> subelements, <span class="since">Since 0.9.4</span>) (see <a href="formatdomain.html#elementsNICSDirect">Direct attachment to physical interface</a> for descriptions of the various macvtap modes). libvirt doesn't attempt to manage the bridge interface at all, thus the <code><bridge></code> element's <code>stp</code> and <code>delay</code> attributes are not allowed; no iptables rules, IP addresses, or DHCP/DNS services are added; at the IP level, the guest interface appears to be directly connected to the physical interface.<span class="since">Since 0.9.4</span> </dd> <dt><code>private</code></dt> <dd> This network uses a macvtap "direct" connection in "private" mode to connect each guest to the network. The physical interface to be used will be picked from among those listed in <code><interface></code> subelements of the <code><forward></code> element; when using 802.1Qbh mode (as indicated by the <code><virtualport></code> type attribute - note that this requires an 802.1Qbh-capable hardware switch), each physical interface can only be in use by a single guest interface at a time; in modes other than 802.1Qbh, multiple guest interfaces can share each physical interface (libvirt will attempt to balance usage between all available interfaces).<span class="since">Since 0.9.4</span> </dd> <dt><code>vepa</code></dt> <dd> This network uses a macvtap "direct" connection in "vepa" mode to connect each guest to the network (this requires that the physical interfaces used be connected to a vepa-capable hardware switch. The physical interface to be used will be picked from among those listed in <code><interface></code> subelements of the <code><forward></code> element; multiple guest interfaces can share each physical interface (libvirt will attempt to balance usage between all available interfaces).<span class="since">Since 0.9.4</span> </dd> <dt><code>passthrough</code></dt> <dd> This network uses a macvtap "direct" connection in "passthrough" mode to connect each guest to the network (note that this is <i>not</i> the same thing as "PCI passthrough"). The physical interface to be used will be picked from among those listed in <code><interface></code> subelements of the <code><forward></code> element. Each physical interface can only be in use by a single guest interface at a time, so libvirt will keep track of which interfaces are currently in use, and only assign unused interfaces (if there are no available physical interfaces when a domain interface is being attached, an error will be logged, and the operation causing the attach will fail (usually either a domain start, or a hotplug interface attach to a domain).<span class="since">Since 0.9.4</span> </dd> <dt><code>hostdev</code></dt> <dd> This network facilitates PCI Passthrough of a network device. A network device is chosen from the interface pool and directly assigned to the guest using generic device passthrough, after first optionally setting the device's MAC address and vlan tag to the configured value, and optionally associating the device with an 802.1Qbh capable switch using a <code><virtualport></code> element. Note that - due to limitations in standard single-port PCI ethernet card driver design - only SR-IOV (Single Root I/O Virtualization) virtual function (VF) devices can be assigned in this manner; to assign a standard single-port PCI or PCIe ethernet card to a guest, use the traditional <code>< hostdev></code> device definition. <span class="since"> Since 0.10.0</span> <p>Note that this "intelligent passthrough" of network devices is very similar to the functionality of a standard <code>< hostdev></code> device, the difference being that this method allows specifying a MAC address, vlan tag, and <code><virtualport ></code> for the passed-through device. If these capabilities are not required, if you have a standard single-port PCI, PCIe, or USB network card that doesn't support SR-IOV (and hence would anyway lose the configured MAC address during reset after being assigned to the guest domain), or if you are using a version of libvirt older than 0.10.0, you should use a standard <code><hostdev></code> device definition in the domain's configuration to assign the device to the guest instead of defining an <code><interface type='network'></code> pointing to a network with <code><forward mode='hostdev'/></code>. </p> </dd> </dl> As mentioned above, a <code><forward></code> element can have multiple <code><interface></code> subelements, each one giving the name of a physical interface that can be used for this network <span class="since">Since 0.9.4</span>: <pre> ... <forward mode='passthrough'> <interface dev='eth10'/> <interface dev='eth11'/> <interface dev='eth12'/> <interface dev='eth13'/> <interface dev='eth14'/> </forward> ... </pre> <p> <span class="since">since 0.10.0</span>, <code><interface></code> also has an optional read-only attribute - when examining the live configuration of a network, the attribute <code>connections</code>, if present, specifies the number of guest interfaces currently connected via this physical interface. </p> <p> Additionally, <span class="since">since 0.9.10</span>, libvirt allows a shorthand for specifying all virtual interfaces associated with a single physical function, by using the <code><pf></code> subelement to call out the corresponding physical interface associated with multiple virtual interfaces: </p> <pre> ... <forward mode='passthrough'> <pf dev='eth0'/> </forward> ... </pre> <p>When a guest interface is being constructed, libvirt will pick an interface from this list to use for the connection. In modes where physical interfaces can be shared by multiple guest interfaces, libvirt will choose the interface that currently has the least number of connections. For those modes that do not allow sharing of the physical device (in particular, 'passthrough' mode, and 'private' mode when using 802.1Qbh), libvirt will choose an unused physical interface or, if it can't find an unused interface, fail the operation.</p> <p> <span class="since">since 0.10.0</span> When using forward mode 'hostdev', the interface pool is specified with a list of <code><address></code> elements, each of which has <code>< type></code> (must always be <code>'pci'</code>, <code><domain></code>, <code><bus></code>, <code><slot></code>, and <code><function></code> attributes. </p> <pre> ... <forward mode='hostdev' managed='yes'> <address type='pci' domain='0' bus='4' slot='0' function='1'/> <address type='pci' domain='0' bus='4' slot='0' function='2'/> <address type='pci' domain='0' bus='4' slot='0' function='3'/> </forward> ... </pre> Alternatively the interface pool can also be defined using a single physical function <code><pf></code> subelement to call out the corresponding physical interface associated with multiple virtual interfaces (similar to passthrough mode): <pre> ... <forward mode='hostdev' managed='yes'> <pf dev='eth0'/> </forward> ... </pre> </dd> </dl> <h5><a name="elementQoS">Quality of service</a></h5> <pre> ... <forward mode='nat' dev='eth0'/> <b><bandwidth> <inbound average='1000' peak='5000' burst='5120'/> <outbound average='128' peak='256' burst='256'/> </bandwidth></b> ...</pre> <p> This part of network XML provides setting quality of service. Incoming and outgoing traffic can be shaped independently. The <code>bandwidth</code> element can have at most one <code>inbound</code> and at most one <code>outbound</code> child elements. Leaving any of these children element out result in no QoS applied on that traffic direction. So, when you want to shape only network's incoming traffic, use <code>inbound</code> only, and vice versa. Each of these elements have one mandatory attribute <code>average</code>. It specifies average bit rate on interface being shaped. Then there are two optional attributes: <code>peak</code>, which specifies maximum rate at which bridge can send data, and <code>burst</code>, amount of bytes that can be burst at <code>peak</code> speed. Accepted values for attributes are integer numbers, The units for <code>average</code> and <code>peak</code> attributes are kilobytes per second, and for the <code>burst</code> just kilobytes. The rate is shared equally within domains connected to the network. Moreover, <code>bandwidth</code> element can be included in <code>portgroup</code> element. <span class="since">Since 0.9.4</span> </p> <h5><a name="elementVlanTag">Setting VLAN tag (on supported network types only)</a></h5> <pre> ... <devices> <interface type='bridge'> <b><vlan trunk='yes'></b> <b><tag id='42'/></b> <b><tag id='47'/></b> <b></vlan></b> <source bridge='ovsbr0'/> <virtualport type='openvswitch'> <parameters interfaceid='09b11c53-8b5c-4eeb-8f00-d84eaa0aaa4f'/> </virtualport> </interface> <devices> ...</pre> <p> If (and only if) the network type supports vlan tagging transparent to the guest, an optional <code><vlan></code> element can specify one or more vlan tags to apply to the traffic of all guests using this network <span class="since">Since 0.10.0</span>. (openvswitch and type='hostdev' SR-IOV networks do support transparent vlan tagging of guest traffic; everything else, including standard linux bridges and libvirt's own virtual networks, <b>do not</b> support it. 802.1Qbh (vn-link) and 802.1Qbg (VEPA) switches provide their own way (outside of libvirt) to tag guest traffic onto specific vlans.) As expected, the <code>tag</code> attribute specifies which vlan tag to use. If a network has more than one <code><vlan></code> element defined, it is assumed that the user wants to do VLAN trunking using all the specified tags. In the case that vlan trunking with a single tag is desired, the optional attribute <code>trunk='yes'</code> can be added to the vlan element. </p> <p> <code><vlan></code> elements can also be specified in a <code><portgroup></code> element, as well as directly in a domain's <code><interface></code> element. In the case that a vlan tag is specified in multiple locations, the setting in <code><interface></code> takes precedence, followed by the setting in the <code><portgroup></code> selected by the interface config. The <code><vlan></code> in <code><network></code> will be selected only if none is given in <code><portgroup></code> or <code><interface></code>. </p> <h5><a name="elementsPortgroup">Portgroups</a></h5> <pre> ... <forward mode='private'/> <interface dev="eth20"/> <interface dev="eth21"/> <interface dev="eth22"/> <interface dev="eth23"/> <interface dev="eth24"/> </forward> <b><portgroup name='engineering' default='yes'> <virtualport type='802.1Qbh'> <parameters profileid='test'/> </virtualport> <bandwidth> <inbound average='1000' peak='5000' burst='5120'/> <outbound average='1000' peak='5000' burst='5120'/> </bandwidth> </portgroup></b> <b><portgroup name='sales'> <virtualport type='802.1Qbh'> <parameters profileid='salestest'/> </virtualport> <bandwidth> <inbound average='500' peak='2000' burst='2560'/> <outbound average='128' peak='256' burst='256'/> </bandwidth> </portgroup></b> ...</pre> <p> <span class="since">Since 0.9.4</span> A portgroup provides a method of easily putting guest connections to the network into different classes, with each class potentially having a different level/type of service. <span class="since">Since 0.9.4</span> Each network can have multiple portgroup elements (and one of those can optionally be designated as the 'default' portgroup for the network), and each portgroup has a name, as well as various subelements associated with it. The currently supported subelements are <code><bandwidth></code> (documented <a href="formatdomain.html#elementQoS">here</a>) and <code><virtualport></code> (documented <a href="formatdomain.html#elementsNICSDirect">here</a>). If a domain interface definition specifies a portgroup (by adding a <code>portgroup</code> attribute to the <code><source></code> subelement), that portgroup's info will be merged into the interface's configuration. If no portgroup is given in the interface definition, and one of the network's portgroups has <code>default='yes'</code>, that default portgroup will be used. If no portgroup is given in the interface definition, and there is no default portgroup, then none will be used. Any <code><bandwidth></code> specified directly in the domain XML will take precedence over any setting in the chosen portgroup. if a <code><virtualport></code> is specified in the portgroup (and/or directly in the network definition), the multiple virtualports will be merged, and any parameter that is specified in more than one virtualport, and is not identical, will be considered an error, and will prevent the interface from starting. </p> <h3><a name="elementsAddress">Addressing</a></h3> <p> The final set of elements define the addresses (IPv4 and/or IPv6, as well as MAC) to be assigned to the bridge device associated with the virtual network, and optionally enable DHCP services. These elements are only valid for isolated networks (no <code>forward</code> element specified), and for those with a forward mode of 'route' or 'nat'. </p> <pre> ... <mac address='00:16:3E:5D:C7:9E'/> <domain name="example.com"/> <dns> <txt name="example" value="example value" /> <srv service='name' protocol='tcp' domain='test-domain-name' target='.' port='1024' priority='10' weight='10'/> <host ip='192.168.122.2'> <hostname>myhost</hostname> <hostname>myhostalias</hostname> </host> </dns> <ip address="192.168.122.1" netmask="255.255.255.0"> <dhcp> <range start="192.168.122.100" end="192.168.122.254" /> <host mac="00:16:3e:77:e2:ed" name="foo.example.com" ip="192.168.122.10" /> <host mac="00:16:3e:3e:a9:1a" name="bar.example.com" ip="192.168.122.11" /> </dhcp> </ip> <ip family="ipv6" address="2001:db8:ca2:2::1" prefix="64" /> </network></pre> <dl> <dt><code>mac</code></dt> <dd>The <code>address</code> attribute defines a MAC (hardware) address formatted as 6 groups of 2-digit hexadecimal numbers, the groups separated by colons (eg, <code>"52:54:00:1C:DA:2F"</code>). This MAC address is assigned to the bridge device when it is created. Generally it is best to not specify a MAC address when creating a network - in this case, if a defined MAC address is needed for proper operation, libvirt will automatically generate a random MAC address and save it in the config. Allowing libvirt to generate the MAC address will assure that it is compatible with the idiosyncrasies of the platform where libvirt is running. <span class="since">Since 0.8.8</span> </dd> <dt><code>dns</code></dt><dd> The dns element of a network contains configuration information for the virtual network's DNS server. <span class="since">Since 0.9.3</span> Currently supported elements are: <dl> <dt><code>txt</code></dt> <dd>A <code>dns</code> element can have 0 or more <code>txt</code> elements. Each txt element defines a DNS TXT record and has two attributes, both required: a name that can be queried via dns, and a value that will be returned when that name is queried. names cannot contain embedded spaces or commas. value is a single string that can contain multiple values separated by commas. <span class="since">Since 0.9.3</span> </dd> <dt><code>host</code></dt> <dd>The <code>host</code> element within <code>dns</code> is the definition of DNS hosts to be passed to the DNS service. The IP address is identified by the <code>ip</code> attribute and the names for that IP address are identified in the <code>hostname</code> sub-elements of the <code>host</code> element. <span class="since">Since 0.9.3</span> </dd> </dl> <dl> <dt><code>srv</code></dt> <dd>The <code>dns</code> element can have also 0 or more <code>srv</code> record elements. Each <code>srv</code> record element defines a DNS SRV record and has 2 mandatory and 5 optional attributes. The mandatory attributes are service name and protocol (tcp, udp) and the optional attributes are target, port, priority, weight and domain as defined in DNS server SRV RFC (RFC 2782). <span class="since">Since 0.9.9</span> </dd> </dl> </dd> <dt><code>ip</code></dt> <dd>The <code>address</code> attribute defines an IPv4 address in dotted-decimal format, or an IPv6 address in standard colon-separated hexadecimal format, that will be configured on the bridge device associated with the virtual network. To the guests this address will be their default route. For IPv4 addresses, the <code>netmask</code> attribute defines the significant bits of the network address, again specified in dotted-decimal format. For IPv6 addresses, and as an alternate method for IPv4 addresses, you can specify the significant bits of the network address with the <code>prefix</code> attribute, which is an integer (for example, <code>netmask='255.255.255.0'</code> could also be given as <code>prefix='24'</code>. The <code>family</code> attribute is used to specify the type of address - 'ipv4' or 'ipv6'; if no <code>family</code> is given, 'ipv4' is assumed. A network can have more than one of each family of address defined, but only a single address can have a <code>dhcp</code> or <code>tftp</code> element. <span class="since">Since 0.3.0; IPv6, multiple addresses on a single network, <code>family</code>, and <code>prefix</code> since 0.8.7</span> <dl> <dt><code>tftp</code></dt> <dd>Immediately within the <code>ip</code> element there is an optional <code>tftp</code> element. The presence of this element and of its attribute <code>root</code> enables TFTP services. The attribute specifies the path to the root directory served via TFTP. <code>tftp</code> is not supported for IPv6 addresses, and can only be specified on a single IPv4 address per network. <span class="since">Since 0.7.1</span> </dd> <dt><code>dhcp</code></dt> <dd>Also within the <code>ip</code> element there is an optional <code>dhcp</code> element. The presence of this element enables DHCP services on the virtual network. It will further contain one or more <code>range</code> elements. The <code>dhcp</code> element is not supported for IPv6, and is only supported on a single IP address per network for IPv4. <span class="since">Since 0.3.0</span> <dl> <dt><code>range</code></dt> <dd>The <code>start</code> and <code>end</code> attributes on the <code>range</code> element specify the boundaries of a pool of IPv4 addresses to be provided to DHCP clients. These two addresses must lie within the scope of the network defined on the parent <code>ip</code> element. <span class="since">Since 0.3.0</span> </dd> <dt><code>host</code></dt> <dd>Within the <code>dhcp</code> element there may be zero or more <code>host</code> elements; these specify hosts which will be given names and predefined IP addresses by the built-in DHCP server. Any such element must specify the MAC address of the host to be assigned a given name (via the <code>mac</code> attribute), the IP to be assigned to that host (via the <code>ip</code> attribute), and the name to be given that host by the DHCP server (via the <code>name</code> attribute). <span class="since">Since 0.4.5</span> </dd> <dt><code>bootp</code></dt> <dd>The optional <code>bootp</code> element specifies BOOTP options to be provided by the DHCP server. Two attributes are supported: <code>file</code> is mandatory and gives the file to be used for the boot image; <code>server</code> is optional and gives the address of the TFTP server from which the boot image will be fetched. <code>server</code> defaults to the same host that runs the DHCP server, as is the case when the <code>tftp</code> element is used. The BOOTP options currently have to be the same for all address ranges and statically assigned addresses.<span class="since">Since 0.7.1 (<code>server</code> since 0.7.3).</span> </dd> </dl> </dd> </dl> </dd> </dl> <h2><a name="examples">Example configuration</a></h2> <h3><a name="examplesNAT">NAT based network</a></h3> <p> This example is the so called "default" virtual network. It is provided and enabled out-of-the-box for all libvirt installations. This is a configuration that allows guest OS to get outbound connectivity regardless of whether the host uses ethernet, wireless, dialup, or VPN networking without requiring any specific admin configuration. In the absence of host networking, it at least allows guests to talk directly to each other. </p> <pre> <network> <name>default</name> <bridge name="virbr0" /> <forward mode="nat"/> <ip address="192.168.122.1" netmask="255.255.255.0"> <dhcp> <range start="192.168.122.2" end="192.168.122.254" /> </dhcp> </ip> <ip family="ipv6" address="2001:db8:ca2:2::1" prefix="64" /> </network></pre> <h3><a name="examplesRoute">Routed network config</a></h3> <p> This is a variant on the default network which routes traffic from the virtual network to the LAN without applying any NAT. It requires that the IP address range be pre-configured in the routing tables of the router on the host network. This example further specifies that guest traffic may only go out via the <code>eth1</code> host network device. </p> <pre> <network> <name>local</name> <bridge name="virbr1" /> <forward mode="route" dev="eth1"/> <ip address="192.168.122.1" netmask="255.255.255.0"> <dhcp> <range start="192.168.122.2" end="192.168.122.254" /> </dhcp> </ip> <ip family="ipv6" address="2001:db8:ca2:2::1" prefix="64" /> </network></pre> <h3><a name="examplesPrivate">Isolated network config</a></h3> <p> This variant provides a completely isolated private network for guests. The guests can talk to each other, and the host OS, but cannot reach any other machines on the LAN, due to the omission of the <code>forward</code> element in the XML description. </p> <pre> <network> <name>private</name> <bridge name="virbr2" /> <ip address="192.168.152.1" netmask="255.255.255.0"> <dhcp> <range start="192.168.152.2" end="192.168.152.254" /> </dhcp> </ip> <ip family="ipv6" address="2001:db8:ca2:3::1" prefix="64" /> </network></pre> <h3><a name="examplesBridge">Using an existing host bridge</a></h3> <p> <span class="since">Since 0.9.4</span> This shows how to use a pre-existing host bridge "br0". The guests will effectively be directly connected to the physical network (i.e. their IP addresses will all be on the subnet of the physical network, and there will be no restrictions on inbound or outbound connections). </p> <pre> <network> <name>host-bridge</name> <forward mode="bridge"/> <bridge name="br0"/> </network></pre> <h3><a name="examplesDirect">Using a macvtap "direct" connection</a></h3> <p> <span class="since">Since 0.9.4, QEMU and KVM only, requires Linux kernel 2.6.34 or newer</span> This shows how to use macvtap to connect to the physical network directly through one of a group of physical devices (without using a host bridge device). As with the host bridge network, the guests will effectively be directly connected to the physical network so their IP addresses will all be on the subnet of the physical network, and there will be no restrictions on inbound or outbound connections. Note that, due to a limitation in the implementation of macvtap, these connections do not allow communication directly between the host and the guests - if you require this you will either need the attached physical switch to be operating in a mirroring mode (so that all traffic coming to the switch is reflected back to the host's interface), or provide alternate means for this communication (e.g. a second interface on each guest that is connected to an isolated network). The other forward modes that use macvtap (private, vepa, and passthrough) would be used in a similar fashion. </p> <pre> <network> <name>direct-macvtap</name> <forward mode="bridge"> <interface dev="eth20"/> <interface dev="eth21"/> <interface dev="eth22"/> <interface dev="eth23"/> <interface dev="eth24"/> </forward> </network></pre> </body> </html>