Virtual networking
As briefly mentioned in ,
VirtualBox provides up to eight virtual PCI Ethernet cards for each virtual
machine. For each such card, you can individually select
the hardware that will be virtualized as well as
the virtualization mode that the virtual card will be operating
in with respect to your physical networking hardware on the
host.
Four of the network cards can be configured in the "Network" section
of the settings dialog in the graphical user interface of VirtualBox. You
can configure all eight network cards on the command line via VBoxManage
modifyvm; see .
This chapter explains the various networking settings in more
detail.
Virtual networking hardware
For each card, you can individually select what kind of
hardware will be presented to the virtual machine.
VirtualBox can virtualize the following six types of networking
hardware:
AMD PCNet PCI II (Am79C970A);
AMD PCNet FAST III (Am79C973, the default);
Intel PRO/1000 MT Desktop (82540EM);
Intel PRO/1000 T Server (82543GC);
Intel PRO/1000 MT Server (82545EM);
Paravirtualized network adapter (virtio-net).
The PCNet FAST III is the default because it is supported by nearly
all operating systems out of the box, as well as the GNU GRUB boot
manager. As an exception, the Intel PRO/1000 family adapters are chosen
for some guest operating system types that no longer ship with drivers for
the PCNet card, such as Windows Vista.
The Intel PRO/1000 MT Desktop type works with Windows Vista and
later versions. The T Server variant of the Intel PRO/1000 card is
recognized by Windows XP guests without additional driver installation.
The MT Server variant facilitates OVF imports from other platforms.
The "Paravirtualized network adapter
(virtio-net)" is special. If you select this, then VirtualBox
does not virtualize common networking hardware (that
is supported by common guest operating systems out of the box). Instead,
VirtualBox then expects a special software interface for virtualized
environments to be provided by the guest, thus avoiding the complexity of
emulating networking hardware and improving network performance. Starting
with version 3.1, VirtualBox provides support for the industry-standard
"virtio" networking drivers, which are part of the open-source KVM
project.
The "virtio" networking drivers are available for the following
guest operating systems:
Linux kernels version 2.6.25 or later can be configured to
provide virtio support; some distributions also back-ported virtio
to older kernels.
For Windows 2000, XP and Vista, virtio drivers can be
downloaded and installed from the KVM project web page.
http://www.linux-kvm.org/page/WindowsGuestDrivers.
VirtualBox also has limited support for so-called jumbo frames, i.e. networking packets with more
than 1500 bytes of data, provided that you use the Intel card
virtualization and bridged networking. In other words, jumbo frames are
not supported with the AMD networking devices; in those cases, jumbo
packets will silently be dropped for both the transmit and the receive
direction. Guest operating systems trying to use this feature will observe
this as a packet loss, which may lead to unexpected application behavior
in the guest. This does not cause problems with guest operating systems in
their default configuration, as jumbo frames need to be explicitly
enabled.
Introduction to networking modes
Each of the eight networking adapters can be separately configured
to operate in one of the following modes:
Not attached
In this mode, VirtualBox reports to the guest that a network
card is present, but that there is no connection -- as if no
Ethernet cable was plugged into the card. This way it is possible
to "pull" the virtual Ethernet cable and disrupt the connection,
which can be useful to inform a guest operating system that no
network connection is available and enforce a
reconfiguration.
Network Address Translation (NAT)
If all you want is to browse the Web, download files and
view e-mail inside the guest, then this default mode should be
sufficient for you, and you can safely skip the rest of this
section. Please note that there are certain limitations when using
Windows file sharing (see for
details).
NAT Network
The NAT network is a new NAT flavour introduced in
VirtualBox 4.3. See
for details.
Bridged networking
This is for more advanced networking needs such as network
simulations and running servers in a guest. When enabled,
VirtualBox connects to one of your installed network cards and
exchanges network packets directly, circumventing your host
operating system's network stack.
Internal networking
This can be used to create a different kind of
software-based network which is visible to selected virtual
machines, but not to applications running on the host or to the
outside world.
Host-only networking
This can be used to create a network containing the host and
a set of virtual machines, without the need for the host's
physical network interface. Instead, a virtual network interface
(similar to a loopback interface) is created on the host,
providing connectivity among virtual machines and the host.
Generic networking
Rarely used modes share the same generic network interface,
by allowing the user to select a driver which can be included with
VirtualBox or be distributed in an extension pack.
At the moment there are potentially two available
sub-modes:
UDP Tunnel
This can be used to interconnect virtual machines
running on different hosts directly, easily and
transparently, over existing network
infrastructure.
VDE (Virtual Distributed Ethernet)
networking
This option can be used to connect to a Virtual
Distributed Ethernet switch on a Linux or a FreeBSD host.
At the moment this needs compiling VirtualBox from
sources, as the Oracle packages do not include it.
The following sections describe the available network modes in more
detail.
Network Address Translation (NAT)
Network Address Translation (NAT) is the simplest way of accessing
an external network from a virtual machine. Usually, it does not require
any configuration on the host network and guest system. For this reason,
it is the default networking mode in VirtualBox.
A virtual machine with NAT enabled acts much like a real computer
that connects to the Internet through a router. The "router", in this
case, is the VirtualBox networking engine, which maps traffic from and to
the virtual machine transparently. In VirtualBox this router is placed
between each virtual machine and the host. This separation maximizes
security since by default virtual machines cannot talk to each
other.
The disadvantage of NAT mode is that, much like a private network
behind a router, the virtual machine is invisible and unreachable from the
outside internet; you cannot run a server this way unless you set up port
forwarding (described below).
The network frames sent out by the guest operating system are
received by VirtualBox's NAT engine, which extracts the TCP/IP data and
resends it using the host operating system. To an application on the host,
or to another computer on the same network as the host, it looks like the
data was sent by the VirtualBox application on the host, using an IP
address belonging to the host. VirtualBox listens for replies to the
packages sent, and repacks and resends them to the guest machine on its
private network.
The virtual machine receives its network address and configuration
on the private network from a DHCP server integrated into VirtualBox. The
IP address thus assigned to the virtual machine is usually on a completely
different network than the host. As more than one card of a virtual
machine can be set up to use NAT, the first card is connected to the
private network 10.0.2.0, the second card to the network 10.0.3.0 and so
on. If you need to change the guest-assigned IP range for some reason,
please refer to .
Configuring port forwarding with NAT
As the virtual machine is connected to a private network internal
to VirtualBox and invisible to the host, network services on the guest
are not accessible to the host machine or to other computers on the same
network. However, like a physical router, VirtualBox can make selected
services available to the world outside the guest through port forwarding. This means that VirtualBox
listens to certain ports on the host and resends all packets which
arrive there to the guest, on the same or a different port.
To an application on the host or other physical (or virtual)
machines on the network, it looks as though the service being proxied is
actually running on the host. This also means that you cannot run the
same service on the same ports on the host. However, you still gain the
advantages of running the service in a virtual machine -- for example,
services on the host machine or on other virtual machines cannot be
compromised or crashed by a vulnerability or a bug in the service, and
the service can run in a different operating system than the host
system.
To configure Port Forwarding you can use the graphical Port
Forwarding editor which can be found in the Network Settings dialog
for Network Adaptors configured to use NAT. Here you can map host
ports to guest ports to allow network traffic to be routed to a
specific port in the guest.
Alternatively command line tool VBoxManage could be used;
for details, please refer to .
You will need to know which ports on the guest the service uses
and to decide which ports to use on the host (often but not always you
will want to use the same ports on the guest and on the host). You can
use any ports on the host which are not already in use by a service. For
example, to set up incoming NAT connections to an
ssh server in the guest, use the
following command: VBoxManage modifyvm "VM name" --natpf1 "guestssh,tcp,,2222,,22"With
the above example, all TCP traffic arriving on port 2222 on any host
interface will be forwarded to port 22 in the guest. The protocol name
tcp is a mandatory attribute defining
which protocol should be used for forwarding
(udp could also be used). The name
guestssh is purely descriptive and will
be auto-generated if omitted. The number after
--natpf denotes the network card, like
in other parts of VBoxManage.
To remove this forwarding rule again, use the following command:
VBoxManage modifyvm "VM name" --natpf1 delete "guestssh"
If for some reason the guest uses a static assigned IP address not
leased from the built-in DHCP server, it is required to specify the
guest IP when registering the forwarding rule: VBoxManage modifyvm "VM name" --natpf1 "guestssh,tcp,,2222,10.0.2.19,22"This
example is identical to the previous one, except that the NAT engine is
being told that the guest can be found at the 10.0.2.19 address.
To forward all incoming traffic from a
specific host interface to the guest, specify the IP of that host
interface like this:VBoxManage modifyvm "VM name" --natpf1 "guestssh,tcp,127.0.0.1,2222,,22"This
forwards all TCP traffic arriving on the localhost interface (127.0.0.1)
via port 2222 to port 22 in the guest.
It is possible to configure incoming NAT connections while the
VM is running, see .
PXE booting with NAT
PXE booting is now supported in NAT mode. The NAT DHCP server
provides a boot file name of the form
vmname.pxe if the directory
TFTP exists in the directory where the
user's VirtualBox.xml file is kept. It
is the responsibility of the user to provide
vmname.pxe.
NAT limitations
There are four limitations of NAT
mode which users should be aware of:
ICMP protocol limitations:
Some frequently used network debugging tools (e.g.
ping or tracerouting) rely on the
ICMP protocol for sending/receiving messages. While ICMP support
has been improved with VirtualBox 2.1
(ping should now work), some
other tools may not work reliably.
Receiving of UDP broadcasts is not reliable:
The guest does not reliably receive broadcasts, since, in
order to save resources, it only listens for a certain amount of
time after the guest has sent UDP data on a particular port. As a
consequence, NetBios name resolution based on broadcasts does not
always work (but WINS always works). As a workaround, you can use
the numeric IP of the desired server in the
\\server\share notation.
Protocols such as GRE are unsupported:
Protocols other than TCP and UDP are not supported. This
means some VPN products (e.g. PPTP from Microsoft) cannot be used.
There are other VPN products which use simply TCP and UDP.
Forwarding host ports < 1024 impossible:
On Unix-based hosts (e.g. Linux, Solaris, Mac OS X) it is
not possible to bind to ports below 1024 from applications that
are not run by root. As a result,
if you try to configure such a port forwarding, the VM will refuse
to start.
These limitations normally don't affect standard network use. But
the presence of NAT has also subtle effects that may interfere with
protocols that are normally working. One example is NFS, where the
server is often configured to refuse connections from non-privileged
ports (i.e. ports not below 1024).
Network Address Translation Service (experimental)
The Network Address Translation (NAT) service works in a similar way
to a home router, grouping the systems using it into a network and
preventing systems outside of this network from directly accessing systems
inside it, but letting systems inside communicate with each other and with
systems outside using TCP and UDP over IPv4 and IPv6.
A NAT service is attached to an internal network. Virtual machines
which are to make use of it should be attached to that internal network.
The name of internal network is chosen when the NAT service is created and
the internal network will be created if it does not already exist. An
example command to create a NAT network is:
VBoxManage natnetwork add -t nat-int-network -n "192.168.15.0/24" -e
Here, "nat-int-network" is the name of the internal network to be used and
"192.168.15.0/24" is the network address and mask of the NAT service
interface. By default in this static configuration the gateway will be
assigned the address 192.168.15.1 (the address following the interface
address), though this is subject to change. To attach a DHCP server to the
internal network, we modify the example as follows:
VBoxManage natnetwork add -t nat-int-network -n "192.168.15.0/24" -e -h on
or to add a DHCP server to the network after creation:
VBoxManage natnetwork modify -t nat-int-network -h on
To disable it again, use:
VBoxManage natnetwork modify -t nat-int-network -h off
DHCP server provides list of registered nameservers, but doesn't map
servers from 127/8 network.
To start the NAT service, use the following command:
VBoxManage natnetwork start -t nat-int-network
If the network has a DHCP server attached then it will start together
with the NAT network service.
VBoxManage natnetwork stop -t nat-int-network stops
the NAT network service, together with DHCP server if any.
To delete the NAT network service use:
VBoxManage natnetwork remove -t nat-int-network
This command does not remove the DHCP server if one is enabled on the
internal network.
Port-forwarding is supported (using the "-p" switch for IPv4 and "-P"
for IPv6):
VBoxManage natnetwork modify -t nat-int-network -p "ssh:tcp:[]:10022:[192.168.15.15]:22"
This adds a port-forwarding rule from the host's TCP 10022 port to
the port 22 on the guest with IP address 192.168.15.15. To delete the rule,
use:
VBoxManage natnetwork modify -t nat-int-network -p delete ssh
It's possible to bind NAT service to specified interface:
VBoxManage setextradata global "NAT/win-nat-test-0/SourceIp4" 192.168.1.185
To see the list of registered NAT networks, use:
VBoxManage list natnetworks
Bridged networking
With bridged networking, VirtualBox uses a device driver on your
host system that filters data from your physical
network adapter. This driver is therefore called a "net filter" driver.
This allows VirtualBox to intercept data from the physical network and
inject data into it, effectively creating a new network interface in
software. When a guest is using such a new software interface, it looks to
the host system as though the guest were physically connected to the
interface using a network cable: the host can send data to the guest
through that interface and receive data from it. This means that you can
set up routing or bridging between the guest and the rest of your
network.
For this to work, VirtualBox needs a device driver on your host
system. The way bridged networking works has been completely rewritten
with VirtualBox 2.0 and 2.1, depending on the host operating system. From
the user perspective, the main difference is that complex configuration is
no longer necessary on any of the supported host operating
systems.
For Mac OS X and Solaris hosts, net filter drivers were already
added in VirtualBox 2.0 (as initial support for Host Interface
Networking on these platforms). With VirtualBox 2.1, net filter
drivers were also added for the Windows and Linux hosts, replacing the
mechanisms previously present in VirtualBox for those platforms;
especially on Linux, the earlier method required creating TAP
interfaces and bridges, which was complex and varied from one
distribution to the next. None of this is necessary anymore. Bridged
network was formerly called "Host Interface Networking" and has been
renamed with version 2.2 without any change in functionality.
Even though TAP is no longer necessary on Linux with bridged
networking, you can still use TAP interfaces for
certain advanced setups, since you can connect a VM to any host
interface -- which could also be a TAP interface.
To enable bridged networking, all you need to do is to open the
Settings dialog of a virtual machine, go to the "Network" page and select
"Bridged network" in the drop down list for the "Attached to" field.
Finally, select desired host interface from the list at the bottom of the
page, which contains the physical network interfaces of your systems. On a
typical MacBook, for example, this will allow you to select between "en1:
AirPort" (which is the wireless interface) and "en0: Ethernet", which
represents the interface with a network cable.
Bridging to a wireless interface is done differently from
bridging to a wired interface, because most wireless adapters do not
support promiscuous mode. All traffic has to use the MAC address of the
host's wireless adapter, and therefore VirtualBox needs to replace the
source MAC address in the Ethernet header of an outgoing packet to make
sure the reply will be sent to the host interface. When VirtualBox sees
an incoming packet with a destination IP address that belongs to one of
the virtual machine adapters it replaces the destination MAC address in
the Ethernet header with the VM adapter's MAC address and passes it on.
VirtualBox examines ARP and DHCP packets in order to learn the IP
addresses of virtual machines.
Depending on your host operating system, the following limitations
should be kept in mind:
On Macintosh hosts,
functionality is limited when using AirPort (the Mac's wireless
networking) for bridged networking. Currently, VirtualBox supports
only IPv4 over AirPort. For other protocols such as IPv6 and IPX,
you must choose a wired interface.
On Linux hosts, functionality
is limited when using wireless interfaces for bridged networking.
Currently, VirtualBox supports only IPv4 over wireless. For other
protocols such as IPv6 and IPX, you must choose a wired
interface.
Also, setting the MTU to less than 1500 bytes on wired
interfaces provided by the sky2 driver on the Marvell Yukon II EC
Ultra Ethernet NIC is known to cause packet losses under certain
conditions.
Some adapters strip VLAN tags in hardware. This does not allow
to use VLAN trunking between VM and the external network with
pre-2.6.27 Linux kernels nor with host operating systems other than
Linux.
On Solaris hosts, there is no
support for using wireless interfaces. Filtering guest traffic using
IPFilter is also not completely supported due to technical
restrictions of the Solaris networking subsystem. These issues would
be addressed in a future release of Solaris 11.
Starting with VirtualBox 4.1, on Solaris 11 hosts (build 159
and above), it is possible to use Solaris' Crossbow Virtual Network
Interfaces (VNICs) directly with VirtualBox without any additional
configuration other than each VNIC must be exclusive for every guest
network interface.
Starting with VirtualBox 2.0.4 and up to VirtualBox 4.0, VNICs
can be used but with the following caveats:
A VNIC cannot be shared between multiple guest network
interfaces, i.e. each guest network interface must have its own,
exclusive VNIC.
The VNIC and the guest network interface that uses the
VNIC must be assigned identical MAC addresses.
When using VLAN interfaces with VirtualBox, they must be named
according to the PPA-hack naming scheme (e.g. "e1000g513001"), as
otherwise the guest may receive packets in an unexpected
format.
Internal networking
Internal Networking is similar to bridged networking in that the VM
can directly communicate with the outside world. However, the "outside
world" is limited to other VMs on the same host which connect to the same
internal network.
Even though technically, everything that can be done using internal
networking can also be done using bridged networking, there are security
advantages with internal networking. In bridged networking mode, all
traffic goes through a physical interface of the host system. It is
therefore possible to attach a packet sniffer (such as Wireshark) to the
host interface and log all traffic that goes over it. If, for any reason,
you prefer two or more VMs on the same machine to communicate privately,
hiding their data from both the host system and the user, bridged
networking therefore is not an option.
Internal networks are created automatically as needed, i.e. there is
no central configuration. Every internal network is identified simply by
its name. Once there is more than one active virtual network card with the
same internal network ID, the VirtualBox support driver will automatically
"wire" the cards and act as a network switch. The VirtualBox support
driver implements a complete Ethernet switch and supports both
broadcast/multicast frames and promiscuous mode.
In order to attach a VM's network card to an internal network, set
its networking mode to "internal networking". There are two ways to
accomplish this:
You can use a VM's "Settings" dialog in the VirtualBox
graphical user interface. In the "Networking" category of the
settings dialog, select "Internal Networking" from the drop-down
list of networking modes. Now select the name of an existing
internal network from the drop-down below or enter a new name into
the entry field.
You can use VBoxManage modifyvm "VM name" --nic<x> intnet
Optionally, you can specify a network name with the command VBoxManage modifyvm "VM name" --intnet<x> "network name"
If you do not specify a network name, the network card will be
attached to the network intnet by
default.
Unless you configure the (virtual) network cards in the guest
operating systems that are participating in the internal network to use
static IP addresses, you may want to use the DHCP server that is built
into VirtualBox to manage IP addresses for the internal network. Please
see for details.
As a security measure, the Linux implementation of internal
networking only allows VMs running under the same user ID to establish an
internal network.
Host-only networking
Host-only networking is another networking mode that was added with
version 2.2 of VirtualBox. It can be thought of as a hybrid between the
bridged and internal networking modes: as with bridged networking, the
virtual machines can talk to each other and the host as if they were
connected through a physical Ethernet switch. Similarly, as with internal
networking however, a physical networking interface need not be present,
and the virtual machines cannot talk to the world outside the host since
they are not connected to a physical networking interface.
Instead, when host-only networking is used, VirtualBox creates a new
software interface on the host which then appears next to your existing
network interfaces. In other words, whereas with bridged networking an
existing physical interface is used to attach virtual machines to, with
host-only networking a new "loopback" interface is created on the host.
And whereas with internal networking, the traffic between the virtual
machines cannot be seen, the traffic on the "loopback" interface on the
host can be intercepted.
Host-only networking is particularly useful for preconfigured
virtual appliances, where multiple virtual machines are shipped together
and designed to cooperate. For example, one virtual machine may contain a
web server and a second one a database, and since they are intended to
talk to each other, the appliance can instruct VirtualBox to set up a
host-only network for the two. A second (bridged) network would then
connect the web server to the outside world to serve data to, but the
outside world cannot connect to the database.
To change a virtual machine's virtual network interface to "host
only" mode:
either go to the "Network" page in the virtual machine's
settings notebook in the graphical user interface and select
"Host-only networking", or
on the command line, type VBoxManage modifyvm
"VM name" --nic<x> hostonly; see for details.
For host-only networking, like with internal networking, you may
find the DHCP server useful that is built into VirtualBox. This can be
enabled to then manage the IP addresses in the host-only network since
otherwise you would need to configure all IP addresses
statically.
In the VirtualBox graphical user interface, you can configure
all these items in the global settings via "File" -> "Settings"
-> "Network", which lists all host-only networks which are
presently in use. Click on the network name and then on the "Edit"
button to the right, and you can modify the adapter and DHCP
settings.
Alternatively, you can use VBoxManage
dhcpserver on the command line; please see for details.
On Linux and Mac OS X hosts the number of host-only interfaces is
limited to 128. There is no such limit for Solaris and Windows hosts.
UDP Tunnel networking
This networking mode allows to interconnect virtual machines running
on different hosts.
Technically this is done by encapsulating Ethernet frames sent or
received by the guest network card into UDP/IP datagrams, and sending them
over any network available to the host.
UDP Tunnel mode has three parameters:
Source UDP port
The port on which the host listens. Datagrams arriving on
this port from any source address will be forwarded to the
receiving part of the guest network card.
Destination address
IP address of the target host of the transmitted
data.
Destination UDP port
Port number to which the transmitted data is sent.
When interconnecting two virtual machines on two different hosts,
their IP addresses must be swapped. On single host, source and destination
UDP ports must be swapped.
In the following example host 1 uses the IP address 10.0.0.1 and
host 2 uses IP address 10.0.0.2. Configuration via command-line: VBoxManage modifyvm "VM 01 on host 1" --nic<x> generic
VBoxManage modifyvm "VM 01 on host 1" --nicgenericdrv<x> UDPTunnel
VBoxManage modifyvm "VM 01 on host 1" --nicproperty<x> dest=10.0.0.2
VBoxManage modifyvm "VM 01 on host 1" --nicproperty<x> sport=10001
VBoxManage modifyvm "VM 01 on host 1" --nicproperty<x> dport=10002
and VBoxManage modifyvm "VM 02 on host 2" --nic<y> generic
VBoxManage modifyvm "VM 02 on host 2" --nicgenericdrv<y> UDPTunnel
VBoxManage modifyvm "VM 02 on host 2" --nicproperty<y> dest=10.0.0.1
VBoxManage modifyvm "VM 02 on host 2" --nicproperty<y> sport=10002
VBoxManage modifyvm "VM 02 on host 2" --nicproperty<y> dport=10001
Of course, you can always interconnect two virtual machines on the
same host, by setting the destination address parameter to 127.0.0.1 on
both. It will act similarly to "Internal network" in this case, however
the host can see the network traffic which it could not in the normal
Internal network case.
On Unix-based hosts (e.g. Linux, Solaris, Mac OS X) it is not possible
to bind to ports below 1024 from applications that are not run by
root. As a result, if you try to
configure such a source UDP port, the VM will refuse to start.
VDE networking
Virtual Distributed Ethernet (VDE
VDE is a project developed by Renzo Davoli, Associate Professor
at the University of Bologna, Italy.
) is a flexible, virtual network infrastructure system,
spanning across multiple hosts in a secure way. It allows for L2/L3
switching, including spanning-tree protocol, VLANs, and WAN emulation. It
is an optional part of VirtualBox which is only included in the source
code.
The basic building blocks of the infrastructure are VDE switches,
VDE plugs and VDE wires which inter-connect the switches.
The VirtualBox VDE driver has one parameter:
VDE network
The name of the VDE network switch socket to which the VM
will be connected.
The following basic example shows how to connect a virtual machine
to a VDE switch:
Create a VDE switch: vde_switch -s /tmp/switch1
Configuration via command-line: VBoxManage modifyvm "VM name" --nic<x> generic
VBoxManage modifyvm "VM name" --nicgenericdrv<x> VDE
To connect to automatically allocated switch port, use: VBoxManage modifyvm "VM name" --nicproperty<x> network=/tmp/switch1
To connect to specific switch port <n>, use: VBoxManage modifyvm "VM name" --nicproperty<x> network=/tmp/switch1[<n>]
The latter option can be useful for VLANs.
Optionally map between VDE switch port and VLAN: (from switch
CLI) vde$ vlan/create <VLAN> vde$ port/setvlan <port> <VLAN>
VDE is available on Linux and FreeBSD hosts only. It is only
available if the VDE software and the VDE plugin library from the
VirtualSquare project are installed on the host system
For Linux hosts, the shared library libvdeplug.so must be
available in the search path for shared libraries
. For more information on setting up VDE networks, please see
the documentation accompanying the software.
http://wiki.virtualsquare.org/wiki/index.php/VDE_Basic_Networking.
Limiting bandwidth for network I/O
Starting with version 4.2, VirtualBox allows for limiting the
maximum bandwidth used for network transmission. Several network adapters
of one VM may share limits through bandwidth groups. It is possible
to have more than one such limit.
VirtualBox shapes VM traffic only in the transmit direction,
delaying the packets being sent by virtual machines. It does not limit
the traffic being received by virtual machines.
Limits are configured through
VBoxManage. The example below creates a
bandwidth group named "Limit", sets the limit to 20 Mbit/s and assigns the
group to the first and second adapters of the VM:VBoxManage bandwidthctl "VM name" add Limit --type network --limit 20m
VBoxManage modifyvm "VM name" --nicbandwidthgroup1 Limit
VBoxManage modifyvm "VM name" --nicbandwidthgroup2 Limit
All adapters in a group share the bandwidth limit, meaning that in the
example above the bandwidth of both adapters combined can never exceed 20
Mbit/s. However, if one adapter doesn't require bandwidth the other can use the
remaining bandwidth of its group.
The limits for each group can be changed while the VM is running,
with changes being picked up immediately. The example below changes the
limit for the group created in the example above to 100 Kbit/s:VBoxManage bandwidthctl "VM name" set Limit --limit 100k
To completely disable shaping for the first adapter of VM use the
following command:
VBoxManage modifyvm "VM name" --nicbandwidthgroup1 none
It is also possible to disable shaping for all adapters assigned to a
bandwidth group while VM is running, by specifying the zero limit for the
group. For example, for the bandwidth group named "Limit" use:
VBoxManage bandwidthctl "VM name" set Limit --limit 0
Improving network performance
VirtualBox provides a variety of virtual network adapters that can be
"attached" to the host's network in a number of ways. Depending on which
types of adapters and attachments are used the network performance will
be different. Performance-wise the virtio network
adapter is preferable over Intel PRO/1000 emulated
adapters, which are preferred over PCNet family of
adapters. Both virtio and Intel PRO/1000
adapters enjoy the benefit of segmentation and checksum
offloading. Segmentation offloading is essential for high performance as
it allows for less context switches, dramatically increasing the sizes
of packets that cross VM/host boundary.
Neither virtio nor Intel PRO/1000
drivers for Windows XP support segmentation
offloading. Therefore Windows XP guests never reach the same
transmission rates as other guest types. Refer to MS Knowledge base
article 842264 for additional information.
Three attachment types: internal,
bridged and host-only, have
nearly identical performance, the internal type
being a little bit faster and using less CPU cycles as the packets never
reach the host's network stack. The NAT attachment
is the slowest (and safest) of all attachment types as it provides
network address translation. The generic driver attachment is special and
cannot be considered as an alternative to other attachment types.
The number of CPUs assigned to VM does not improve network
performance and in some cases may hurt it due to increased concurrency in
the guest.
Here is the short summary of things to check in order to improve
network performance:
Whenever possible use virtio network
adapter, otherwise use one of Intel PRO/1000
adapters;
Use bridged attachment instead of
NAT;
Make sure segmentation offloading is enabled in the guest OS.
Usually it will be enabled by default. You can check and modify
offloading settings using ethtool
command in Linux guests.