Documentation/Networking: Difference between revisions
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= Network Basics = | |||
There are two parts to networking within QEMU: | There are two parts to networking within QEMU: | ||
* the virtual network device that is provided to the | * the virtual network device that is provided to the guest (e.g. a PCI network card). | ||
* the network backend that | * the network backend that interacts with the emulated NIC (e.g. puts packets onto the host's network). | ||
There are a range of options for each part. By default QEMU will create a SLiRP user network backend and an appropriate virtual network device for the guest (eg an E1000 PCI card for most x86 PC guests), as if you had typed <tt>-net nic -net user</tt> on your command line. | |||
'''Note''' - if you specify any networking options on the command line (via <tt>-net</tt> or <tt>-netdev</tt>) then QEMU will require you to provide options sufficient to define and connect up both parts. (Forgetting to specify the backend or the network device will give a warning message such as "Warning: netdev mynet0 has no peer", "Warning: hub 0 is not connected to host network" or "Warning: hub 0 with no nics"; the VM will then boot but will not have functioning networking.) | |||
'''Note''' - if you are using the (default) SLiRP user networking, then ping (ICMP) will not work, though TCP and UDP will. Don't try to use ping to test your QEMU network configuration! | |||
'''Note''' - As this page is probably very brief or even incomplete you might find these pages rather useful: | '''Note''' - As this page is probably very brief or even incomplete you might find these pages rather useful: | ||
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* [http://bsdwiki.reedmedia.net/wiki/networking_qemu_virtual_bsd_systems.html QEMU Networking] on bsdwiki, showing used networking principles and dealing with BSD hosts | * [http://bsdwiki.reedmedia.net/wiki/networking_qemu_virtual_bsd_systems.html QEMU Networking] on bsdwiki, showing used networking principles and dealing with BSD hosts | ||
= | = Network Backends = | ||
== How to create a network backend? == | |||
There are a number of network backends to choose from depending on your environment. Create a network backend like this: | |||
-netdev TYPE,id=NAME,... | |||
The <tt>id</tt> option gives the name by which the virtual network device and the network backend are associated with each other. If you want multiple virtual network devices inside the guest they each need their own network backend. The name is used to distinguish backends from each other and must be used even when only one backend is specified. | |||
== Network backend types == | |||
In most cases, if you don't have any specific networking requirements other than to be able to access to a web page from your guest, user networking (slirp) is a good choice. However, if you are looking to run any kind of network service or have your guest participate in a network in any meaningful way, tap is usually the best choice. | In most cases, if you don't have any specific networking requirements other than to be able to access to a web page from your guest, user networking (slirp) is a good choice. However, if you are looking to run any kind of network service or have your guest participate in a network in any meaningful way, tap is usually the best choice. | ||
=== User Networking (SLIRP) === | === User Networking (SLIRP) === | ||
Line 42: | Line 35: | ||
* there is a lot of overhead so the performance is poor | * there is a lot of overhead so the performance is poor | ||
* ICMP traffic does not work (so you cannot use ping within a guest) | * in general, ICMP traffic does not work (so you cannot use ping within a guest) | ||
* on Linux hosts, ping does work from within the guest, but it needs initial setup by root (once per host) -- see the steps below | |||
* the guest is not directly accessible from the host or the external network | * the guest is not directly accessible from the host or the external network | ||
Line 48: | Line 42: | ||
A typical (default) network is shown below. | A typical (default) network is shown below. | ||
[[File:Slirp_concept.png]] | [[File:Slirp_concept.png]] | ||
You can change the network configuration | Note that from inside the guest, connecting to a port on the "gateway" IP address will connect to that port on the host; so for instance "ssh 10.0.2.2" will ssh from the guest to the host. | ||
- <tt>id= | |||
You can configure User Networking using the <tt>-netdev user</tt> command line option. | |||
Adding the following to the qemu command line will change the network configuration to use 192.168.76.0/24 instead of the default (10.0.2.0/24) and will start guest DHCP allocation from 9 (instead of 15): | |||
-netdev user,id=mynet0,net=192.168.76.0/24,dhcpstart=192.168.76.9 | |||
You can isolate the guest from the host (and broader network) using the <tt>restrict</tt> option. For example <tt>-netdev user,id=mynet0,restrict=y</tt> or <tt>-netdev type=user,id=mynet0,restrict=yes</tt> will restrict networking to just the guest and any virtual devices. This can be used to prevent software running inside the guest from phoning home while still providing a network inside the guest. You can selectively override this using <tt>hostfwd</tt> and <tt>guestfwd</tt> options. | |||
==== Enabling ping in the guest, on Linux hosts ==== | |||
* Determine the main group ID (or one supplementary group ID) of the user that will run QEMU with slirp. | |||
* In <tt>/etc/sysctl.conf</tt> (or whatever is appropriate for your host distro), make sure that the whitespace-separated, inclusive group ID range in the <tt>net.ipv4.ping_group_range</tt> sysctl includes the above group ID. | |||
For example, as root, | |||
* add a new group called <tt>unpriv_ping</tt>: | |||
groupadd unpriv_ping | |||
* set this group for a number of users as another supplementary group (note, they will have to re-login): | |||
for U in user1 user2 ... user_n; do | |||
usermod --append --groups unpriv_ping $U | |||
done | |||
* then set both sides of the inclusive range in the above sysctl to the numeric ID of the new group: | |||
( | |||
GROUP_ID=$(getent group unpriv_ping | cut -f 3 -d :) | |||
printf 'net.ipv4.ping_group_range = %u %u\n' $GROUP_ID $GROUP_ID \ | |||
>> /etc/sysctl.conf | |||
) | |||
sysctl -p | |||
==== Advanced user networking options ==== | |||
The | The <tt>-netdev user</tt> parameter has some more useful options: | ||
* The DHCP address and name for the guest can be set with <tt>-netdev user,id=n0,host=addr,hostname=name</tt> | |||
* You can specify the guest-visible virtual DNS server address with <tt>-netdev user,id=n0,dns=addr</tt> | |||
* QEMU can simulate a TFTP server with <tt>-netdev user,id=n0,tftp=xxx,bootfile=yyy</tt> | |||
* To share files between your guest and host, you can use <tt>-netdev user,id=n0,smb=dir,smbserver=addr</tt> | |||
* To forward host ports to your guest, use <tt>-netdev user,id=n0,hostfwd=hostip:hostport-guestip:guestport</tt> | |||
For | For details, please see the [https://www.qemu.org/docs/master/system/invocation.html#hxtool-5 QEMU documentation]. | ||
=== Tap === | === Tap === | ||
The | The tap networking backend makes use of a tap networking device in the host. It offers very good performance and can be configured to create virtually any type of network topology. Unfortunately, it requires configuration of that network topology in the host which tends to be different depending on the operating system you are using. Generally speaking, it also requires that you have root privileges. | ||
-netdev tap,id=mynet0 | |||
=== VDE === | === VDE === | ||
The | The VDE networking backend uses the [https://github.com/virtualsquare/vde-2 Virtual Distributed Ethernet] infrastructure to network guests. Unless you specifically know that you want to use VDE, it is probably not the right backend to use. | ||
=== Socket === | === Socket === | ||
The | The socket networking backend allows you to create a network of guests that can see each other. It's primarily useful in extending the network created by the SLIRP backend to multiple virtual machines. In general, if you want to have multiple guests communicate, the tap backend is a better choice unless you do not have root access to the host environment. | ||
-netdev socket,id=mynet0,listen=:1234 | |||
-netdev socket,id=mynet0,connect=:1234 | |||
= Virtual Network Devices = | |||
== How to create a virtual network device? == | |||
The virtual network device that you choose depends on your needs and the guest environment (i.e. the hardware that you are emulating). For example, if you are emulating a particular embedded board, then you should use the virtual network device that comes with embedded board's configuration. Such on-board NICs can be configured with the <tt>-nic</tt> option of QEMU. See the corresponding section below for details. | |||
On machines that have a PCI bus (or any other pluggable bus system), there are a wider range of options. For example, the e1000 is the default network adapter on some machines in QEMU. Other older guests might require the rtl8139 network adapter. For modern guests, the virtio-net (para-virtualised) network adapter should be used instead since it has the best performance, but it requires special guest driver support which might not be available on very old operating systems. | |||
Use the <tt>-device</tt> option to add a particular virtual network device to your virtual machine: | |||
-device TYPE,netdev=NAME | |||
The <tt>netdev</tt> is the name of a previously defined <tt>-netdev</tt>. The virtual network device will be associated with this network backend. | |||
Note that there are other device options to select alternative devices, or to change some aspect of the device. For example, you want something like: | |||
<tt>-device DEVNAME,netdev=NET-ID,mac=MACADDR,DEV-OPTS</tt>, where <tt>DEVNAME</tt> is the device (e.g. <tt>i82559c</tt> for an Intel i82559C Ethernet device), <tt>NET_ID</tt> is the network identifier to attach the device to (see discussion of <tt>-netdev</tt> below), <tt>MACADDR</tt> is the MAC address for the device, and <tt>DEV-OPTS</tt> are any additional device options that you may wish to pass (e.g. <tt>bus=PCI-BUS,addr=DEVFN</tt> to control the PCI device address), if supported by the device. | |||
Use <tt>-device help</tt> to get a list of the devices (including network devices) you can add using the <tt>-device</tt> option for a particular guest. | |||
== The -nic option == | |||
In case you don't care about configuring every detail of a NIC, you can also create a NIC together with a host backend by using the <tt>-nic</tt> parameter. For example, you can replace | |||
-netdev user,id=n1 -device virtio-net-pci,netdev=n1 | |||
with: | |||
-nic user,model=virtio-net-pci | |||
Use <tt>-nic model=help</tt> to get a list of the supported NIC models. | |||
If you don't care about the NIC model, you can also omit that option. So the shortest way to get a tap device is for example simply: | |||
-nic tap | |||
The NIC option should also be use to configure NICs on embedded systems (which can not be used via <tt>-device</tt>). For example, to connect such an on-board NIC to the tap backend and change its MAC-address, you can use the <tt>-nic</tt> option like this: | |||
-nic tap,mac=02:ca:fe:f0:0d:01 | |||
= | = Network Monitoring = | ||
You can monitor the network configuration using <tt>info network</tt> and <tt>info usernet</tt> commands. | You can monitor the network configuration using <tt>info network</tt> and <tt>info usernet</tt> commands. | ||
You can capture network traffic from within | You can capture network traffic from within QEMU using the <tt>filter-dump</tt> object, like this: | ||
-netdev user,id=u1 -device e1000,netdev=u1 \ | |||
-object filter-dump,id=f1,netdev=u1,file=dump.dat | |||
Once you've shut down QEMU, you can examine the <tt>dump.dat</tt> file with tools like Wireshark. Please note that network traffic dumping can only work if QEMU has a chance to see the network packets, i.e. this does not work if you use virtio-net with vhost acceleration in the kernel. | |||
= Network HOWTOs = | |||
== How to get SSH access to a guest == | |||
A simplest way is to forward a specific host port to guest port 22. It can be done via: | |||
-device e1000,netdev=net0 | |||
-netdev user,id=net0,hostfwd=tcp::5555-:22 | |||
The first line creates a virtual e1000 network device, while the second line created one user typed backend, forwarding local port 5555 to guest port 22. Then we can do: | |||
ssh localhost -p 5555 | |||
to have SSH access to guest after its network setup (don't forget to turn off firewalls if there is any in the guest or host). | |||
== How to use tap with a wireless adapter on the host == | |||
See this: | |||
* [[Documentation/Networking/NAT|Use tap with a wireless adapter on the host]] | * [[Documentation/Networking/NAT|Use tap with a wireless adapter on the host]] | ||
* | |||
== How to disable network completely == | |||
If you don't specify any network configuration options, then QEMU will create a SLiRP user network backend and an appropriate virtual network device for the guest (eg an E1000 PCI card for most x86 PC guests). If you don't want any networking at all you can suppress this default with: | |||
-nic none | |||
The more general option <tt>-nodefaults</tt> also suppresses the default networking configuration, as well as the creation of several other default devices. | |||
== Setting up taps on Linux == | |||
For Linux with iproute2 and tap/tun support, this can be configured as below, and assumes the reader has experience using iproute2 (at least ip-addr and ip-link). Take note of the host's physical devices' configuration, as the bridge created will become the new endpoint for the physical device. Note that this '''WILL''' cause the host's networking on that physical device to go out, possibly requiring a reboot for remote systems! | |||
# ip link add br0 type bridge | |||
# ip tuntap add dev tap0 mode tap | |||
# ip link set dev tap0 master br0 # set br0 as the target bridge for tap0 | |||
# ip link set dev eth0 master br0 # set br0 as the target bridge for eth0 | |||
# ip link set dev br0 up | |||
At this point, the bridge works, but is not usable as it does not have an IP address. For reassigning the physical device's addresses for the bridge to be usable: | |||
# ip address delete $PREFIX dev eth0 | |||
# ip address add $PREFIX dev br0 | |||
# ip route add default via $ROUTE dev br0 | |||
This can be automated with a shell script to setup tap networking on remote hosts; as mentioned above, connection will be lost upon setting the physical device's master to a bridge. | |||
Please note that the newly-created tap device's link may need to be set to UP via <tt>ip-link</tt> after a virtual machine has been started. Furthermore, as a bridge device basically acts as the new endpoint for a physical device, most normal networking commands, such as a DHCP client or packet sniffer, must be ran on the bridge instead of the physical device. Creating multiple bridges per interface is known (anecdotally) to be problematic; instead, create a tap for each virtual machine using a single bridge for each physical device to be used. | |||
== TODO LIST == | |||
* Use tap to let guests be visible on the host network for non-Linux. | |||
* Pass QEMU a physical card rather than emulation/simulation. | * Pass QEMU a physical card rather than emulation/simulation. | ||
= Misc = | |||
== The legacy -net option == | |||
QEMU previously used the <tt>-net nic</tt> option instead of <tt>-device DEVNAME</tt> and <tt>-net TYPE</tt> instead of <tt>-netdev TYPE</tt>. This is considered obsolete since QEMU 0.12, although it continues to work. | |||
The legacy syntax to create virtual network devices is: | |||
-net nic,model=MODEL | |||
You can use <tt>-net nic,model=?</tt> to get a list of valid network devices that you can pass to the <tt>-net nic</tt> option. Note that these model names might be different from the <tt>-device ?</tt> names and are therefore only useful if you are using the <tt>-net nic,model=MODEL</tt> syntax. | |||
The obsolete <tt>-net</tt> syntax automatically created an emulated hub with ID 0 (used to be called a "VLAN" in older versions of QEMU, for virtual LAN) that forwards traffic from any device connected to it to every other device on the "VLAN". If you need more than one hub in recent versions of QEMU, you can do this with the "hubport" backend, e.g. by using <tt>-nic hubport,hubid=1</tt>. | |||
== Guest Hints == | |||
=== Linux === | |||
Should work using default network settings. | |||
=== Mac OS 9 === | |||
If having problems, open the TCP/IP control panel. Under "Connect via:" select Ethernet. Under "Configure" select "Using DHCP Server". Close the control panel. Wait a few seconds then try opening it again. The fields in the window should have been auto-populated. | |||
-netdev user,id=mynet0 -device sungem,netdev=mynet0 | |||
=== Mac OS 10.2 === | |||
Starting with QEMU 2.11, the SunGEM NIC can be used. Open the System Preferences, go to the Network pane. You should see a dialog box telling you it has found a new network interface card. Click the Ok button. Click the 'Apply Now' Button at the bottom of the window. The fields in the TCP/IP tab should populate. | |||
-netdev user,id=mynet0 -device sungem,netdev=mynet0 | |||
=== Mac OS 10.4 === | |||
-usb -netdev user,id=mynet0 -device usb-net,netdev=mynet0 | |||
or | |||
-netdev user,id=mynet0 -device rtl8139,netdev=mynet0 | |||
Open System Preferences and go to the Network pane. Select the Ethernet Adapter from the "Show" drop down menu. From the TCP/IP tab, push the Apply Now button at the bottom. This will make the nic work. | |||
=== Windows NT 4.0 === | |||
-netdev user,id=mynet0 -device pcnet,netdev=mynet0 | |||
=== Windows 2000, Windows XP, Windows 7 === | |||
-netdev user,id=n0 -device rtl8139,netdev=n0 | |||
Windows will automatically detect and use the NIC. | |||
=== React OS === | |||
-netdev user,id=n0 -device rtl8139,netdev=n0 | |||
[[Category:User documentation]] |
Latest revision as of 07:33, 18 December 2023
Network Basics
There are two parts to networking within QEMU:
- the virtual network device that is provided to the guest (e.g. a PCI network card).
- the network backend that interacts with the emulated NIC (e.g. puts packets onto the host's network).
There are a range of options for each part. By default QEMU will create a SLiRP user network backend and an appropriate virtual network device for the guest (eg an E1000 PCI card for most x86 PC guests), as if you had typed -net nic -net user on your command line.
Note - if you specify any networking options on the command line (via -net or -netdev) then QEMU will require you to provide options sufficient to define and connect up both parts. (Forgetting to specify the backend or the network device will give a warning message such as "Warning: netdev mynet0 has no peer", "Warning: hub 0 is not connected to host network" or "Warning: hub 0 with no nics"; the VM will then boot but will not have functioning networking.)
Note - if you are using the (default) SLiRP user networking, then ping (ICMP) will not work, though TCP and UDP will. Don't try to use ping to test your QEMU network configuration!
Note - As this page is probably very brief or even incomplete you might find these pages rather useful:
- QEMU Networking on wikibooks.org, mainly dealing with Linux hosts
- QEMU Networking on bsdwiki, showing used networking principles and dealing with BSD hosts
Network Backends
How to create a network backend?
There are a number of network backends to choose from depending on your environment. Create a network backend like this:
-netdev TYPE,id=NAME,...
The id option gives the name by which the virtual network device and the network backend are associated with each other. If you want multiple virtual network devices inside the guest they each need their own network backend. The name is used to distinguish backends from each other and must be used even when only one backend is specified.
Network backend types
In most cases, if you don't have any specific networking requirements other than to be able to access to a web page from your guest, user networking (slirp) is a good choice. However, if you are looking to run any kind of network service or have your guest participate in a network in any meaningful way, tap is usually the best choice.
User Networking (SLIRP)
This is the default networking backend and generally is the easiest to use. It does not require root / Administrator privileges. It has the following limitations:
- there is a lot of overhead so the performance is poor
- in general, ICMP traffic does not work (so you cannot use ping within a guest)
- on Linux hosts, ping does work from within the guest, but it needs initial setup by root (once per host) -- see the steps below
- the guest is not directly accessible from the host or the external network
User Networking is implemented using "slirp", which provides a full TCP/IP stack within QEMU and uses that stack to implement a virtual NAT'd network.
A typical (default) network is shown below.
Note that from inside the guest, connecting to a port on the "gateway" IP address will connect to that port on the host; so for instance "ssh 10.0.2.2" will ssh from the guest to the host.
You can configure User Networking using the -netdev user command line option.
Adding the following to the qemu command line will change the network configuration to use 192.168.76.0/24 instead of the default (10.0.2.0/24) and will start guest DHCP allocation from 9 (instead of 15):
-netdev user,id=mynet0,net=192.168.76.0/24,dhcpstart=192.168.76.9
You can isolate the guest from the host (and broader network) using the restrict option. For example -netdev user,id=mynet0,restrict=y or -netdev type=user,id=mynet0,restrict=yes will restrict networking to just the guest and any virtual devices. This can be used to prevent software running inside the guest from phoning home while still providing a network inside the guest. You can selectively override this using hostfwd and guestfwd options.
Enabling ping in the guest, on Linux hosts
- Determine the main group ID (or one supplementary group ID) of the user that will run QEMU with slirp.
- In /etc/sysctl.conf (or whatever is appropriate for your host distro), make sure that the whitespace-separated, inclusive group ID range in the net.ipv4.ping_group_range sysctl includes the above group ID.
For example, as root,
- add a new group called unpriv_ping:
groupadd unpriv_ping
- set this group for a number of users as another supplementary group (note, they will have to re-login):
for U in user1 user2 ... user_n; do usermod --append --groups unpriv_ping $U done
- then set both sides of the inclusive range in the above sysctl to the numeric ID of the new group:
( GROUP_ID=$(getent group unpriv_ping | cut -f 3 -d :) printf 'net.ipv4.ping_group_range = %u %u\n' $GROUP_ID $GROUP_ID \ >> /etc/sysctl.conf ) sysctl -p
Advanced user networking options
The -netdev user parameter has some more useful options:
- The DHCP address and name for the guest can be set with -netdev user,id=n0,host=addr,hostname=name
- You can specify the guest-visible virtual DNS server address with -netdev user,id=n0,dns=addr
- QEMU can simulate a TFTP server with -netdev user,id=n0,tftp=xxx,bootfile=yyy
- To share files between your guest and host, you can use -netdev user,id=n0,smb=dir,smbserver=addr
- To forward host ports to your guest, use -netdev user,id=n0,hostfwd=hostip:hostport-guestip:guestport
For details, please see the QEMU documentation.
Tap
The tap networking backend makes use of a tap networking device in the host. It offers very good performance and can be configured to create virtually any type of network topology. Unfortunately, it requires configuration of that network topology in the host which tends to be different depending on the operating system you are using. Generally speaking, it also requires that you have root privileges.
-netdev tap,id=mynet0
VDE
The VDE networking backend uses the Virtual Distributed Ethernet infrastructure to network guests. Unless you specifically know that you want to use VDE, it is probably not the right backend to use.
Socket
The socket networking backend allows you to create a network of guests that can see each other. It's primarily useful in extending the network created by the SLIRP backend to multiple virtual machines. In general, if you want to have multiple guests communicate, the tap backend is a better choice unless you do not have root access to the host environment.
-netdev socket,id=mynet0,listen=:1234 -netdev socket,id=mynet0,connect=:1234
Virtual Network Devices
How to create a virtual network device?
The virtual network device that you choose depends on your needs and the guest environment (i.e. the hardware that you are emulating). For example, if you are emulating a particular embedded board, then you should use the virtual network device that comes with embedded board's configuration. Such on-board NICs can be configured with the -nic option of QEMU. See the corresponding section below for details.
On machines that have a PCI bus (or any other pluggable bus system), there are a wider range of options. For example, the e1000 is the default network adapter on some machines in QEMU. Other older guests might require the rtl8139 network adapter. For modern guests, the virtio-net (para-virtualised) network adapter should be used instead since it has the best performance, but it requires special guest driver support which might not be available on very old operating systems.
Use the -device option to add a particular virtual network device to your virtual machine:
-device TYPE,netdev=NAME
The netdev is the name of a previously defined -netdev. The virtual network device will be associated with this network backend.
Note that there are other device options to select alternative devices, or to change some aspect of the device. For example, you want something like: -device DEVNAME,netdev=NET-ID,mac=MACADDR,DEV-OPTS, where DEVNAME is the device (e.g. i82559c for an Intel i82559C Ethernet device), NET_ID is the network identifier to attach the device to (see discussion of -netdev below), MACADDR is the MAC address for the device, and DEV-OPTS are any additional device options that you may wish to pass (e.g. bus=PCI-BUS,addr=DEVFN to control the PCI device address), if supported by the device.
Use -device help to get a list of the devices (including network devices) you can add using the -device option for a particular guest.
The -nic option
In case you don't care about configuring every detail of a NIC, you can also create a NIC together with a host backend by using the -nic parameter. For example, you can replace
-netdev user,id=n1 -device virtio-net-pci,netdev=n1
with:
-nic user,model=virtio-net-pci
Use -nic model=help to get a list of the supported NIC models.
If you don't care about the NIC model, you can also omit that option. So the shortest way to get a tap device is for example simply:
-nic tap
The NIC option should also be use to configure NICs on embedded systems (which can not be used via -device). For example, to connect such an on-board NIC to the tap backend and change its MAC-address, you can use the -nic option like this:
-nic tap,mac=02:ca:fe:f0:0d:01
Network Monitoring
You can monitor the network configuration using info network and info usernet commands.
You can capture network traffic from within QEMU using the filter-dump object, like this:
-netdev user,id=u1 -device e1000,netdev=u1 \ -object filter-dump,id=f1,netdev=u1,file=dump.dat
Once you've shut down QEMU, you can examine the dump.dat file with tools like Wireshark. Please note that network traffic dumping can only work if QEMU has a chance to see the network packets, i.e. this does not work if you use virtio-net with vhost acceleration in the kernel.
Network HOWTOs
How to get SSH access to a guest
A simplest way is to forward a specific host port to guest port 22. It can be done via:
-device e1000,netdev=net0 -netdev user,id=net0,hostfwd=tcp::5555-:22
The first line creates a virtual e1000 network device, while the second line created one user typed backend, forwarding local port 5555 to guest port 22. Then we can do:
ssh localhost -p 5555
to have SSH access to guest after its network setup (don't forget to turn off firewalls if there is any in the guest or host).
How to use tap with a wireless adapter on the host
See this:
How to disable network completely
If you don't specify any network configuration options, then QEMU will create a SLiRP user network backend and an appropriate virtual network device for the guest (eg an E1000 PCI card for most x86 PC guests). If you don't want any networking at all you can suppress this default with:
-nic none
The more general option -nodefaults also suppresses the default networking configuration, as well as the creation of several other default devices.
Setting up taps on Linux
For Linux with iproute2 and tap/tun support, this can be configured as below, and assumes the reader has experience using iproute2 (at least ip-addr and ip-link). Take note of the host's physical devices' configuration, as the bridge created will become the new endpoint for the physical device. Note that this WILL cause the host's networking on that physical device to go out, possibly requiring a reboot for remote systems!
# ip link add br0 type bridge # ip tuntap add dev tap0 mode tap # ip link set dev tap0 master br0 # set br0 as the target bridge for tap0 # ip link set dev eth0 master br0 # set br0 as the target bridge for eth0 # ip link set dev br0 up
At this point, the bridge works, but is not usable as it does not have an IP address. For reassigning the physical device's addresses for the bridge to be usable:
# ip address delete $PREFIX dev eth0 # ip address add $PREFIX dev br0 # ip route add default via $ROUTE dev br0
This can be automated with a shell script to setup tap networking on remote hosts; as mentioned above, connection will be lost upon setting the physical device's master to a bridge.
Please note that the newly-created tap device's link may need to be set to UP via ip-link after a virtual machine has been started. Furthermore, as a bridge device basically acts as the new endpoint for a physical device, most normal networking commands, such as a DHCP client or packet sniffer, must be ran on the bridge instead of the physical device. Creating multiple bridges per interface is known (anecdotally) to be problematic; instead, create a tap for each virtual machine using a single bridge for each physical device to be used.
TODO LIST
- Use tap to let guests be visible on the host network for non-Linux.
- Pass QEMU a physical card rather than emulation/simulation.
Misc
The legacy -net option
QEMU previously used the -net nic option instead of -device DEVNAME and -net TYPE instead of -netdev TYPE. This is considered obsolete since QEMU 0.12, although it continues to work. The legacy syntax to create virtual network devices is:
-net nic,model=MODEL
You can use -net nic,model=? to get a list of valid network devices that you can pass to the -net nic option. Note that these model names might be different from the -device ? names and are therefore only useful if you are using the -net nic,model=MODEL syntax.
The obsolete -net syntax automatically created an emulated hub with ID 0 (used to be called a "VLAN" in older versions of QEMU, for virtual LAN) that forwards traffic from any device connected to it to every other device on the "VLAN". If you need more than one hub in recent versions of QEMU, you can do this with the "hubport" backend, e.g. by using -nic hubport,hubid=1.
Guest Hints
Linux
Should work using default network settings.
Mac OS 9
If having problems, open the TCP/IP control panel. Under "Connect via:" select Ethernet. Under "Configure" select "Using DHCP Server". Close the control panel. Wait a few seconds then try opening it again. The fields in the window should have been auto-populated.
-netdev user,id=mynet0 -device sungem,netdev=mynet0
Mac OS 10.2
Starting with QEMU 2.11, the SunGEM NIC can be used. Open the System Preferences, go to the Network pane. You should see a dialog box telling you it has found a new network interface card. Click the Ok button. Click the 'Apply Now' Button at the bottom of the window. The fields in the TCP/IP tab should populate.
-netdev user,id=mynet0 -device sungem,netdev=mynet0
Mac OS 10.4
-usb -netdev user,id=mynet0 -device usb-net,netdev=mynet0
or
-netdev user,id=mynet0 -device rtl8139,netdev=mynet0
Open System Preferences and go to the Network pane. Select the Ethernet Adapter from the "Show" drop down menu. From the TCP/IP tab, push the Apply Now button at the bottom. This will make the nic work.
Windows NT 4.0
-netdev user,id=mynet0 -device pcnet,netdev=mynet0
Windows 2000, Windows XP, Windows 7
-netdev user,id=n0 -device rtl8139,netdev=n0
Windows will automatically detect and use the NIC.
React OS
-netdev user,id=n0 -device rtl8139,netdev=n0