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How the virtual networks used by guests work
Networking using libvirt is generally fairly simple, and in this section you‘ll learn the concepts you need to be effective with it.
Also please bear in mind that advanced users can change important parts of how the network layer operates, far past the concepts outlined here. This section will be enough to get you up and running though. :)
Firstly, libvirt uses the concept of a virtual network switch.
This is a simple software construction on a host server, that your virtual machines "plug in" to, and direct their traffic through.
On a Linux host server, the virtual network switch shows up as a network interface.
The default one, created when the libvirt daemon is first installed and started, shows up as virbr0.
If you‘re familiar with the ifconfig command, you can use that to show it:
$ ifconfig virbr0 virbr0 Link encap:Ethernet HWaddr 1A:D4:92:CF:FD:17 inet addr:192.168.122.1 Bcast:192.168.122.255 Mask:255.255.255.0 UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:0 errors:0 dropped:0 overruns:0 frame:0 TX packets:11 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:0 RX bytes:0 (0.0 b) TX bytes:3097 (3.0 KiB)
If you‘re more familiar with the ip command instead, this is how it looks:
$ ip addr show virbr0 3: virbr0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UNKNOWN link/ether 1a:d4:92:cf:fd:17 brd ff:ff:ff:ff:ff:ff inet 192.168.122.1/24 brd 192.168.122.255 scope global virbr0
Showing it in context, with the other network interfaces on the host:
$ ifconfig -a lo Link encap:Local Loopback inet addr:127.0.0.1 Mask:255.0.0.0 inet6 addr: ::1/128 Scope:Host UP LOOPBACK RUNNING MTU:16436 Metric:1 RX packets:13 errors:0 dropped:0 overruns:0 frame:0 TX packets:13 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:0 RX bytes:892 (892.0 b) TX bytes:892 (892.0 b) eth0 Link encap:Ethernet HWaddr 00:1B:21:43:33:30 inet addr:10.10.10.190 Bcast:10.10.255.255 Mask:255.255.0.0 inet6 addr: fe80::21b:21ff:fe43:3330/64 Scope:Link UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:1942 errors:0 dropped:0 overruns:0 frame:0 TX packets:829 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:1000 RX bytes:985906 (962.7 KiB) TX bytes:142753 (139.4 KiB) Memory:fbea0000-fbec0000 virbr0 Link encap:Ethernet HWaddr 1A:D4:92:CF:FD:17 inet addr:192.168.122.1 Bcast:192.168.122.255 Mask:255.255.255.0 UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:0 errors:0 dropped:0 overruns:0 frame:0 TX packets:11 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:0 RX bytes:0 (0.0 b) TX bytes:3097 (3.0 KiB)
$ ip addr show 1: lo: <LOOPBACK,UP,LOWER_UP> mtu 16436 qdisc noqueue state UNKNOWN link/loopback 00:00:00:00:00:00 brd 00:00:00:00:00:00 inet 127.0.0.1/8 scope host lo inet6 ::1/128 scope host valid_lft forever preferred_lft forever 2: eth0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc mq state UP qlen 1000 link/ether 00:1b:21:43:33:30 brd ff:ff:ff:ff:ff:ff inet 10.10.10.190/16 brd 10.10.255.255 scope global eth0 inet6 fe80::21b:21ff:fe43:3330/64 scope link valid_lft forever preferred_lft forever 3: virbr0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc noqueue state UNKNOWN link/ether 1a:d4:92:cf:fd:17 brd ff:ff:ff:ff:ff:ff inet 192.168.122.1/24 brd 192.168.122.255 scope global virbr0
By default, a virtual network switch operates in NAT mode (using IP masquerading rather than SNAT or DNAT).
This means any guests connected through it, use the host IP address for communication to the outside world. Computers external to the host can‘t initiate communications to the guests inside, when the virtual network switch is operating in NAT mode.
WARNING - The NAT is set up using iptables rules. Be careful if you change these while the virtual switch is running. If something goes wrong with the iptables rules, your virtual machines may stop communicating properly.
Each virtual network switch can be given a range of IP addresses, to be provided to guests through DHCP.
Libvirt uses a program, dnsmasq, for this. An instance of dnsmasq is automatically configured and started by libvirt for each virtual network switch needing it.
Virtual network switches can operate in two other modes, instead of NAT:
With routed mode, the virtual switch is connected to the physical host LAN, passing guest network traffic back and forth without using NAT.
The virtual switch sees the IP addresses in each packet, using that information when deciding what to do.
In this mode all virtual machines are in a subnet routed through the virtual switch. This on its own is not sufficient. because no other hosts on the physical network know this subnet exists or how to reach it. It is thus necessary to configure routers in the physical network (e.g. using a static route).
If you are familiar with the ISO 7 layer network model, this mode operates on layer 3, the Network layer.
In this mode, guests connected to the virtual switch can communicate with each other, and with the host. However, their traffic will not pass outside of the host, nor can they receive traffic from outside the host.
The use of dnsmasq in this mode is possible and in fact needed since it is used to answer DHCP requests. However, even if this network is isolated from any physical network, DNS names are still resolved. Therefore one can get into the situation where DNS is resolved but guests are unable to ping.
When the libvirt daemon is first installed on a server, it comes with an initial virtual network switch configuration. This virtual switch is in NAT mode, and is used by installed guests for communication. (ie to the outside network)
The libvirt daemon puts this configuration into effect when it starts up, so if you have the libvirt daemon set to start automatically on each boot it should always be present.
If the libvirt daemon is only started manually instead, this is when the default virtual network switch will become available on the host.
As stated above, a virtual network can be connected to a physical netwok. Its traffic might be restricted to use a specific interface, e.g. on a system with eth0/1/2 one can limit the virtual network to use eth0 only. However, this only makes sense in routed and nat modes. The restriction can be defined in XML (dev="" attribute) or in virt-manager when creating a new virtual network.
Suppose, there is a network where a node or bunch of nodes need to be in special subnetwork for let‘s say security reasons. This is called DMZ - Demilitarized Zone. How this networks look like is shown in the picture:
Hosts in DMZ provide services both to LAN hosts and WAN. Therefore, they need to be accessible by other computers on the intranet and also by computers in the internet. Since it wouldn‘t be secure to have them on LAN (attacker could access LAN after successful attack), they are in special subnet. In addition, it is obvious they can‘t be in NAT or isolated mode.
Other scenario where routed mode is suitable is this. Consider virtual server hosting company. Each host have two physical network connections. One is for general management, accounting etc. The other is for the virtual machines to use. Each virtual machine has its own public IP address. Hosts however use private IPs, because virtual machine management is allowed to company administrators only. Whole scenario is shown in the picture:
Again, it is obvious virtual network switch can‘t operate neither NAT nor isolated mode. Special case of this is another example. Host has public IP and virtual machines have static public IPs. But one can‘t use bridged networking, since provider accept only packets from the MAC address of the host. Whole situation is shown in the picture:
This is the default mode and requires no additional configuration at all. It can be used anywhere where there is no need for ‘being seen on the network‘. For instance, a web developer who optimizes web pages for different operating systems and web browsers. Or any other developer, who need to try things out in different configurations, environments, or operating systems.
An example where this mode would be useful is running simulations in the security field, where the spread of malware is being watched. Virtual machines can communicate with each other, but since they are cut off from the physical network, no real damage can be done.
In virt-manager is possibility to view and manage virtual networks. Information available through virt-manager can be seen in this image:
NOTE
Creating virtual networks is easy when using the Virtual Machine Manager GUIT.
The following pages take you through the steps for each of the main network types:
In virt-manager by clicking Start Network, or in virsh net-start. This command takes one mandatory argument, the network name. When starting a virtual network, libvirt will automatically set iptables and dnsmasq. However, transient networks are created and started at once.
Stopping virtual network can be done by clicking the appropriate button in Virtual Manager or by net-destroy. If it is a transient network being stopped, it is also removed.
Again, removing a virtual network is possible in Virtual Manager or in virsh by net-undefine. Please keep in mind, only inactive networks can be removed.
Making changes is only available via the virsh console tool. ‘The ‘net-edit command allows the user to edit the XML configuration of a virtual network.
Introduces the basic virsh net-* commands for virtual network management. Here, the <network-identifier> stands for either network name or network UUID.
net-list - List the virtual networks libvirt is aware of, along with some basic status and autostart flag information. Used without parameters it shows active virtual networks only.
Usage: net-list [--all] [--inactive].
net-start - Starts an inactive, previously defined virtual network.
Usage: net-start [--network] <network-identifier>
net-destroy - Stops an active network and deallocates all resources used by it, e.g. stopping appropiate dnsmasq process, releasing the bridge. The virtual network being stopped can be persistent or transient.
Usage: net-destroy [--network] <network-identifier>
net-undefine - Removes an inactive presistent virtual network from the libvirt configuration.
Usage: net-undefine [--network] <network-identifier>
net-autostart - Marks or unmarks automatic startup of a persistent virtual network. Networks with the autostart flag enabled are started whenever libvirt daemon starts. To disable autostart use the --disable switch.
Usage: net-autostart [--network] <network-identifier> [--disable]
net-name - Returns the network name corresponding to the given UUID.
Usage: net-name [--network] <network-uuid>
net-uuid - Returns the UUID corresponding to the given network-name.
Usage: net-uuid [--network] <network-name>
net-dumpxml - Outputs the XML configuration for a virtual network.
Usage: net-dumpxml [--network] <network-identifier>
Libvirt allows a virtual network to be persistent or transient. A transient network, once created (using net-create) lasts until destroyed or the libvirt daemon restarts.
The alternative is a persistent network (net-define) which lasts until explicitly destroyed. Persistent networks, in addition, can be autostarted. This means when the libvirt daemon is starting up it will also run the virtual network.
The root element required for all virtual networks is named ‘network‘ and has no attributes. The first elements provide basic metadata about the virtual network.
<network> <name>default</name> <uuid>f01bd721-af12-4d20-9cf2-390c7375b17c</uuid> ...
The next two elements defines the virtual network‘s connectivity to the physical network (if any).
... <forward dev=‘eth0‘ mode=‘nat‘/> <bridge name=‘virbr0‘ stp=‘on‘ delay=‘0‘ /> ...
The final set of elements define the IPv4 address range available and optionally enable DHCP.
... <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:e2:ed" name="foo.example.com" ip="192.168.122.10" /> </dhcp> </ip> ...
XML definition files of presistent virtual networks are stored in the /etc/libvirt/<hypervisor>/networks/ directory. In addition, if the network is marked as autostart, the symbolic link to its XML file is created under the autostart/ subdirectory.
net-edit - Edits the XML configuration of a virtual network. net-edit launches the editor defined in $EDITOR environment variable passing it a temporary copy of the XML configuration file for the virtual network. When the user finishes editing, net-edit checks the temporary file for changes and errors and redefines the virtual network.
Usage: net-edit [--network] <network-identifier>
net-create - Creates a running transient virtual network. Command takes one argument, the full path to an XML file containing network settings.
Usage: net-create [--file] <file-name>
net-define - Creates a persistent virtual network, without starting it, from the given XML file. To start the network use net-autostart and/or net-start.
Usage: net-define [--file] <file-name>
The bridge control commands (brctl) should definitely be covered, as they‘re used to understand how the network topology is put together.
Also, some people will want to know how to set up their own bridges manually, rather than have libvirt do it.
This should probably go into its own sub-section, as there‘s a decent amount of topic in it to cover properly.
Another idea might be to read some manual page about brctl.
NOTE - When covering the brctl addbr command, specifically point out that a random MAC address will be displayed for it if ifconfig is used, even though the bridge interface doesn‘t actually have a MAC address. It is important, as it‘s misleading and can confuse a person that is wondering "how/why is ARP propagating through this, when it has a MAC address? ARP isn‘t supposed to propagate..." (this caught me out). When the bridge has its first network interface assigned to it, it will then use that interface‘s MAC address from then on. (It only uses the MAC of the first interface, not of any further interfaces plugged in).
Retrieved from "http://wiki.libvirt.org/page/VirtualNetworking"
The guests connected through a NAT network aren‘t visible to the outside world.
This generally makes them the easiest type of virtual network for working with.
To create a virtual network with the Virtual Machine Manager tool, you need to go into the "Host properties" screen for the host it will be created on.
You can do that by selecting the host in question, right clicking on it with the mouse, then choosing the "Properties" context menu icon.
This will open a new dialog, where host level details can be managed.
When it first opens, you will be on the "Overview" tab.
Click on the "Virtual Networks" tab. This will look similar to the screenshot below:
In the bottom left corner of the dialog, there is a button with a plus sign "+" on it. Click on it to start the "New Virtual Network" assistant.
NOTE - The screenshot below needs to have some kind of highlight added pointing to the "+" button to add a new virtual network
The first page of the assistant appears, click the "Forward" button.
In this step, you choose a name for the new NAT network. Use something descriptive you won‘t forget.
If you know you‘ll be using command line tools with this virtual network, then choose a name that‘s easy to type.
We‘ve used the name NAT_Network_172 here, as it‘s fairly descriptive.
In this step, you choose a range of IP addresses to use inside this virtual network. They will be visible to all guests using this virtual network, but won‘t be seen outside of it due to the NAT.
The key concept here is choosing an address range big enough to accommodate your guests, and that won‘t interfere with routing externally. It‘s a good idea to use one of the IPv4 private addresses ranges, as mentioned in the dialog:
In this example, we‘re using the range 172.16.99.0/24 (for no particular reason).
In this step, you choose a range of IP addresses for the DHCP server to assign to guests. This DHCP server and address range are only visible inside this specific NAT network, and won‘t be seen outside of it.
In this example, we chose the range 172.16.99.128 through 172.16.99.254.
This leaves the range 172.16.99.2 through 172.16.99.127 unallocated by DHCP, so you can statically assign IP addresses in it.
DIAGRAM HERE - Show the address range breakup:
This is where you choose whether your network is to be NAT, Routed, or Isolated.
We chose NAT for this this example.
Check the settings are how you want them.
Click the "Finish" button if they are correct.
The assistant will now use the settings, and create the new virtual network.
Select your newly created virtual network in the left side of the dialog box. The settings in use for it will be shown on the right.
Verify they are how you to expect them to be.
After the virtual network has been created, any subsequent guests you create or edit can be configured to use it.
For example, below we are creating a brand new guest using the Virtual Machine Manager. In the list of virtual networks the guest can connect to, we‘ve chosen the new NAT_Network_172 virtual network.
NOTE - Would be good to adjust the screenshot, adding some sort of arrow and/or highlight to the selected virtual network field
We choose this virtual network, so when the guest is started, it will be connected to the host through it.
PIC GOES HERE SHOWING IP ADDRESS AND NAT CONNECTIVITY
Retrieved from "http://wiki.libvirt.org/page/TaskNATSetupVirtManager"
TaskRoutedNetworkSetupVirtManager
Retrieved from "http://wiki.libvirt.org/page/TaskRoutedNetworkSetupVirtManager"
TaskIsolatedNetworkSetupVirtManager
Retrieved from "http://wiki.libvirt.org/page/TaskIsolatedNetworkSetupVirtManager"
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原文地址:http://www.cnblogs.com/popsuper1982/p/3845407.html