mirror of https://gitee.com/openkylin/libvirt.git
507 lines
22 KiB
ReStructuredText
507 lines
22 KiB
ReStructuredText
=========================================
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Firewall and network filtering in libvirt
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=========================================
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.. contents::
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There are three pieces of libvirt functionality which do network filtering of
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some type. At a high level they are:
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- The virtual network driver
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This provides an isolated bridge device (ie no physical NICs attached).
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Guest TAP devices are attached to this bridge. Guests can talk to each
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other and the host, and optionally the wider world.
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- The QEMU driver MAC filtering
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This provides a generic filtering of MAC addresses to prevent the guest
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spoofing its MAC address. This is mostly obsoleted by the next item, so
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won't be discussed further.
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- The network filter driver
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This provides fully configurable, arbitrary network filtering of traffic on
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guest NICs. Generic rulesets are defined at the host level to control
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traffic in some manner. Rules sets are then associated with individual NICs
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of a guest. While not as expressive as directly using iptables/ebtables,
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this can still do nearly everything you would want to on a guest NIC
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filter.
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The virtual network driver
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--------------------------
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The typical configuration for guests is to use bridging of the physical NIC on
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the host to connect the guest directly to the LAN. In RHEL6 there is also the
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possibility of using macvtap/sr-iov and VEPA connectivity. None of this stuff
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plays nicely with wireless NICs, since they will typically silently drop any
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traffic with a MAC address that doesn't match that of the physical NIC.
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Thus the virtual network driver in libvirt was invented. This takes the form of
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an isolated bridge device (ie one with no physical NICs attached). The TAP
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devices associated with the guest NICs are attached to the bridge device. This
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immediately allows guests on a single host to talk to each other and to the host
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OS (modulo host IPtables rules).
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libvirt then uses iptables to control what further connectivity is available.
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There are three configurations possible for a virtual network at time of
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writing:
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- isolated: all off-node traffic is completely blocked
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- nat: outbound traffic to the LAN is allowed, but MASQUERADED
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- forward: outbound traffic to the LAN is allowed
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The latter 'forward' case requires the virtual network be on a separate sub-net
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from the main LAN, and that the LAN admin has configured routing for this
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subnet. In the future we intend to add support for IP subnetting and/or
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proxy-arp. This allows for the virtual network to use the same subnet as the
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main LAN and should avoid need for the LAN admin to configure special routing.
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Libvirt will optionally also provide DHCP services to the virtual network using
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DNSMASQ. In all cases, we need to allow DNS/DHCP queries to the host OS. Since
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we can't predict whether the host firewall setup is already allowing this, we
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insert 4 rules into the head of the INPUT chain
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::
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target prot opt in out source destination
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ACCEPT udp -- virbr0 * 0.0.0.0/0 0.0.0.0/0 udp dpt:53
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ACCEPT tcp -- virbr0 * 0.0.0.0/0 0.0.0.0/0 tcp dpt:53
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ACCEPT udp -- virbr0 * 0.0.0.0/0 0.0.0.0/0 udp dpt:67
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ACCEPT tcp -- virbr0 * 0.0.0.0/0 0.0.0.0/0 tcp dpt:67
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Note we have restricted our rules to just the bridge associated with the virtual
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network, to avoid opening undesirable holes in the host firewall wrt the
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LAN/WAN.
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The next rules depend on the type of connectivity allowed, and go in the main
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FORWARD chain:
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- | type=isolated
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| Allow traffic between guests. Deny inbound. Deny outbound.
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::
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target prot opt in out source destination
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ACCEPT all -- virbr1 virbr1 0.0.0.0/0 0.0.0.0/0
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REJECT all -- * virbr1 0.0.0.0/0 0.0.0.0/0 reject-with icmp-port-unreachable
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REJECT all -- virbr1 * 0.0.0.0/0 0.0.0.0/0 reject-with icmp-port-unreachable
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- | type=nat
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| Allow inbound related to an established connection. Allow outbound, but
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only from our expected subnet. Allow traffic between guests. Deny all other
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inbound. Deny all other outbound.
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::
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target prot opt in out source destination
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ACCEPT all -- * virbr0 0.0.0.0/0 192.168.122.0/24 state RELATED,ESTABLISHED
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ACCEPT all -- virbr0 * 192.168.122.0/24 0.0.0.0/0
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ACCEPT all -- virbr0 virbr0 0.0.0.0/0 0.0.0.0/0
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REJECT all -- * virbr0 0.0.0.0/0 0.0.0.0/0 reject-with icmp-port-unreachable
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REJECT all -- virbr0 * 0.0.0.0/0 0.0.0.0/0 reject-with icmp-port-unreachable
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- | type=routed
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| Allow inbound, but only to our expected subnet. Allow outbound, but only
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from our expected subnet. Allow traffic between guests. Deny all other
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inbound. Deny all other outbound.
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::
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target prot opt in out source destination
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ACCEPT all -- * virbr2 0.0.0.0/0 192.168.124.0/24
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ACCEPT all -- virbr2 * 192.168.124.0/24 0.0.0.0/0
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ACCEPT all -- virbr2 virbr2 0.0.0.0/0 0.0.0.0/0
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REJECT all -- * virbr2 0.0.0.0/0 0.0.0.0/0 reject-with icmp-port-unreachable
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REJECT all -- virbr2 * 0.0.0.0/0 0.0.0.0/0 reject-with icmp-port-unreachable
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- Finally, with type=nat, there is also an entry in the POSTROUTING chain to
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apply masquerading:
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::
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target prot opt in out source destination
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MASQUERADE all -- * * 192.168.122.0/24 !192.168.122.0/24
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firewalld and the virtual network driver
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----------------------------------------
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If `firewalld <https://firewalld.org>`__ is active on the host, libvirt will
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attempt to place the bridge interface of a libvirt virtual network into the
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firewalld zone named "libvirt" (thus making all guest->host traffic on that
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network subject to the rules of the "libvirt" zone). This is done because, if
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firewalld is using its nftables backend (available since firewalld 0.6.0) the
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default firewalld zone (which would be used if libvirt didn't explicitly set the
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zone) prevents forwarding traffic from guests through the bridge, as well as
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preventing DHCP, DNS, and most other traffic from guests to host. The zone named
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"libvirt" is installed into the firewalld configuration by libvirt (not by
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firewalld), and allows forwarded traffic through the bridge as well as DHCP,
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DNS, TFTP, and SSH traffic to the host - depending on firewalld's backend this
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will be implemented via either iptables or nftables rules. libvirt's own rules
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outlined above will \*always\* be iptables rules regardless of which backend is
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in use by firewalld.
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NB: It is possible to manually set the firewalld zone for a network's interface
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with the "zone" attribute of the network's "bridge" element.
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NB: Prior to libvirt 5.1.0, the firewalld "libvirt" zone did not exist, and
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prior to firewalld 0.7.0 a feature crucial to making the "libvirt" zone operate
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properly (rich rule priority settings) was not implemented in firewalld. In
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cases where one or the other of the two packages is missing the necessary
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functionality, it's still possible to have functional guest networking by
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setting the firewalld backend to "iptables" (in firewalld prior to 0.6.0, this
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was the only backend available).
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The network filter driver
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-------------------------
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This driver provides a fully configurable network filtering capability that
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leverages ebtables, iptables and ip6tables. This was written by the libvirt guys
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at IBM and although its XML schema is defined by libvirt, the conceptual model
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is closely aligned with the DMTF CIM schema for network filtering:
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https://www.dmtf.org/standards/cim/cim_schema_v2230/CIM_Network.pdf
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The filters are managed in libvirt as a top level, standalone object. This
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allows the filters to then be referenced by any libvirt object that requires
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their functionality, instead tying them only to use by guest NICs. In the
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current implementation, filters can be associated with individual guest NICs via
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the libvirt domain XML format. In the future we might allow filters to be
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associated with the virtual network objects. Further we're expecting to define a
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new 'virtual switch' object to remove the complexity of configuring
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bridge/sriov/vepa networking modes. This make also end up making use of network
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filters.
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There are a new set of virsh commands for managing network filters:
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- ``virsh nwfilter-define``
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define or update a network filter from an XML file
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- ``virsh nwfilter-undefine``
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undefine a network filter
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- ``virsh nwfilter-dumpxml``
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network filter information in XML
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- ``virsh nwfilter-list``
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list network filters
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- ``virsh nwfilter-edit``
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edit XML configuration for a network filter
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There are equivalently named C APIs for each of these commands.
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As with all objects libvirt manages, network filters are configured using an XML
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format. At a high level the format looks like this:
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::
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<filter name='no-spamming' chain='XXXX'>
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<uuid>d217f2d7-5a04-0e01-8b98-ec2743436b74</uuid>
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<rule ...>
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....
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</rule>
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<filterref filter='XXXX'/>
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</filter>
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Every filter has a name and UUID which serve as unique identifiers. A filter can
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have zero-or-more ``<rule>`` elements which are used to actually define network
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controls. Filters can be arranged into a DAG, so zero-or-more ``<filterref/>``
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elements are also allowed. Cycles in the graph are not allowed.
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The ``<rule>`` element is where all the interesting stuff happens. It has three
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attributes, an action, a traffic direction and an optional priority. E.g.:
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::
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<rule action='drop' direction='out' priority='500'>
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Within the rule there are a wide variety of elements allowed, which do protocol
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specific matching. Supported protocols currently include ``mac``, ``arp``,
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``rarp``, ``ip``, ``ipv6``, ``tcp/ip``, ``icmp/ip``, ``igmp/ip``, ``udp/ip``,
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``udplite/ip``, ``esp/ip``, ``ah/ip``, ``sctp/ip``, ``tcp/ipv6``, ``icmp/ipv6``,
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``igmp/ipv6``, ``udp/ipv6``, ``udplite/ipv6``, ``esp/ipv6``, ``ah/ipv6``,
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``sctp/ipv6``. Each protocol defines what is valid inside the <rule> element.
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The general pattern though is:
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::
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<protocol match='yes|no' attribute1='value1' attribute2='value2'/>
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So, eg a TCP protocol, matching ports 0-1023 would be expressed as:
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::
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<tcp match='yes' srcportstart='0' srcportend='1023'/>
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Attributes can included references to variables defined by the object using the
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rule. So the guest XML format allows each NIC to have a MAC address and IP
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address defined. These are made available to filters via the variables ``$IP``
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and ``$MAC``.
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So to define a filter that prevents IP address spoofing we can simply match on
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source IP address ``!= $IP`` like this:
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::
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<filter name='no-ip-spoofing' chain='ipv4'>
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<rule action='drop' direction='out'>
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<ip match='no' srcipaddr='$IP' />
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</rule>
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</filter>
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I'm not going to go into details on all the other protocol matches you can do,
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because it'll take far too much space. You can read about the options
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`here <formatnwfilter.html#supported-protocols>`__.
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Out of the box in RHEL6/Fedora rawhide, libvirt ships with a set of default
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useful rules:
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::
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# virsh nwfilter-list
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UUID Name
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----------------------------------------------------------------
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15b1ab2b-b1ac-1be2-ed49-2042caba4abb allow-arp
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6c51a466-8d14-6d11-46b0-68b1a883d00f allow-dhcp
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7517ad6c-bd90-37c8-26c9-4eabcb69848d allow-dhcp-server
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7680776c-77aa-496f-90d6-13097664b925 allow-dhcpv6
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9cdaad60-7631-4172-8ccb-ef774be7485b allow-dhcpv6-server
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3d38b406-7cf0-8335-f5ff-4b9add35f288 allow-incoming-ipv4
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908543c1-902e-45f6-a6ca-1a0ad35e7599 allow-incoming-ipv6
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5ff06320-9228-2899-3db0-e32554933415 allow-ipv4
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ce8904cc-ad3a-4454-896c-53452882f817 allow-ipv6
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db0b1767-d62b-269b-ea96-0cc8b451144e clean-traffic
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6d6ddcc8-1242-4c43-ac63-63af80493132 clean-traffic-gateway
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4cf38077-c7d5-4e25-99bb-6c4c9efad294 no-arp-ip-spoofing
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0b11a636-ce58-497f-be90-17f63c92487a no-arp-mac-spoofing
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f88f1932-debf-4aa1-9fbe-f10d3aa4bc95 no-arp-spoofing
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772f112d-52e4-700c-0250-e178a3d91a7a no-ip-multicast
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7ee20370-8106-765d-f7ff-8a60d5aaf30b no-ip-spoofing
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f8a51c43-a08f-49b3-b9e2-393d54522dc0 no-ipv6-multicast
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a7f0afe9-a428-44b8-8566-c8ee2a669271 no-ipv6-spoofing
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d5d3c490-c2eb-68b1-24fc-3ee362fc8af3 no-mac-broadcast
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fb57c546-76dc-a372-513f-e8179011b48a no-mac-spoofing
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dba10ea7-446d-76de-346f-335bd99c1d05 no-other-l2-traffic
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f5c78134-9da4-0c60-a9f0-fb37bc21ac1f no-other-rarp-traffic
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7637e405-4ccf-42ac-5b41-14f8d03d8cf3 qemu-announce-self
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9aed52e7-f0f3-343e-fe5c-7dcb27b594e5 qemu-announce-self-rarp
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Most of these are just building blocks. The interesting one here is
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'clean-traffic'. This pulls together all the building blocks into one filter
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that you can then associate with a guest NIC. This stops the most common bad
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things a guest might try, IP spoofing, arp spoofing and MAC spoofing. To look at
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the rules for any of these just do:
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::
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virsh nwfilter-dumpxml FILTERNAME|UUID
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They are all stored in ``/etc/libvirt/nwfilter``, but don't edit the files there
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directly. Use ``virsh nwfilter-define`` to update them. This ensures the guests
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have their iptables/ebtables rules recreated.
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To associate the clean-traffic filter with a guest, edit the guest XML config
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and change the ``<interface>`` element to include a ``<filterref>`` and also
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specify the ``<ip address/>`` that the guest is allowed to use:
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::
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<interface type='bridge'>
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<mac address='52:54:00:56:44:32'/>
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<source bridge='br1'/>
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<ip address='10.33.8.131'/>
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<target dev='vnet0'/>
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<model type='virtio'/>
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<filterref filter='clean-traffic'/>
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</interface>
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If no ``<ip address>`` is included, the network filter driver will activate its
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'learning mode'. This uses libpcap to snoop on network traffic the guest sends
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and attempts to identify the first IP address it uses. It then locks traffic to
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this address. Obviously this isn't entirely secure, but it does offer some
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protection against the guest being trojaned once up and running. In the future
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we intend to enhance the learning mode so that it looks for DHCPOFFERS from a
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trusted DHCP server and only allows the offered IP address to be used.
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Now, how is all this implemented...?
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The network filter driver uses a combination of ebtables, iptables and
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ip6tables, depending on which protocols are referenced in a filter. The out of
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the box 'clean-traffic' filter rules only require use of ebtables. If you want
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to do matching at tcp/udp/etc protocols (eg to add a new filter
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'no-email-spamming' to block port 25), then iptables will also be used.
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The driver attempts to keep its rules separate from those that the host admin
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might already have configured. So the first thing it does with ebtables, is to
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add two hooks in POSTROUTING and PREROUTING chains, to redirect traffic to
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custom chains. These hooks match on the TAP device name of the guest NIC, so
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they should not interact badly with any administrator defined rules:
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::
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Bridge chain: PREROUTING, entries: 1, policy: ACCEPT
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-i vnet0 -j libvirt-I-vnet0
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Bridge chain: POSTROUTING, entries: 1, policy: ACCEPT
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-o vnet0 -j libvirt-O-vnet0
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To keep things manageable and easy to follow, the driver will then create
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further sub-chains for each protocol then it needs to match against:
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::
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Bridge chain: libvirt-I-vnet0, entries: 5, policy: ACCEPT
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-p IPv4 -j I-vnet0-ipv4
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-p ARP -j I-vnet0-arp
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-p 0x8035 -j I-vnet0-rarp
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-p 0x835 -j ACCEPT
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-j DROP
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Bridge chain: libvirt-O-vnet0, entries: 4, policy: ACCEPT
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-p IPv4 -j O-vnet0-ipv4
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-p ARP -j O-vnet0-arp
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-p 0x8035 -j O-vnet0-rarp
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-j DROP
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Finally, here comes the actual implementation of the filters. This example shows
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the 'clean-traffic' filter implementation. I'm not going to explain what this is
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doing now. :-)
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::
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Bridge chain: I-vnet0-ipv4, entries: 2, policy: ACCEPT
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-s ! 52:54:0:56:44:32 -j DROP
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-p IPv4 --ip-src ! 10.33.8.131 -j DROP
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Bridge chain: O-vnet0-ipv4, entries: 1, policy: ACCEPT
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-j ACCEPT
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Bridge chain: I-vnet0-arp, entries: 6, policy: ACCEPT
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-s ! 52:54:0:56:44:32 -j DROP
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-p ARP --arp-mac-src ! 52:54:0:56:44:32 -j DROP
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-p ARP --arp-ip-src ! 10.33.8.131 -j DROP
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-p ARP --arp-op Request -j ACCEPT
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-p ARP --arp-op Reply -j ACCEPT
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-j DROP
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Bridge chain: O-vnet0-arp, entries: 5, policy: ACCEPT
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-p ARP --arp-op Reply --arp-mac-dst ! 52:54:0:56:44:32 -j DROP
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-p ARP --arp-ip-dst ! 10.33.8.131 -j DROP
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-p ARP --arp-op Request -j ACCEPT
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-p ARP --arp-op Reply -j ACCEPT
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-j DROP
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Bridge chain: I-vnet0-rarp, entries: 2, policy: ACCEPT
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-p 0x8035 -s 52:54:0:56:44:32 -d Broadcast --arp-op Request_Reverse --arp-ip-src 0.0.0.0 --arp-ip-dst 0.0.0.0 --arp-mac-src 52:54:0:56:44:32 --arp-mac-dst 52:54:0:56:44:32 -j ACCEPT
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-j DROP
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Bridge chain: O-vnet0-rarp, entries: 2, policy: ACCEPT
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-p 0x8035 -d Broadcast --arp-op Request_Reverse --arp-ip-src 0.0.0.0 --arp-ip-dst 0.0.0.0 --arp-mac-src 52:54:0:56:44:32 --arp-mac-dst 52:54:0:56:44:32 -j ACCEPT
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-j DROP
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NB, we would have liked to include the prefix 'libvirt-' in all of our chain
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names, but unfortunately the kernel limits names to a very short maximum length.
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So only the first two custom chains can include that prefix. The others just
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include the TAP device name + protocol name.
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If I define a new filter 'no-spamming' and then add this to the 'clean-traffic'
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filter, I can illustrate how iptables usage works:
|
|
|
|
::
|
|
|
|
# cat > /root/spamming.xml <<EOF
|
|
<filter name='no-spamming' chain='root'>
|
|
<uuid>d217f2d7-5a04-0e01-8b98-ec2743436b74</uuid>
|
|
<rule action='drop' direction='out' priority='500'>
|
|
<tcp dstportstart='25' dstportend='25'/>
|
|
</rule>
|
|
</filter>
|
|
EOF
|
|
# virsh nwfilter-define /root/spamming.xml
|
|
# virsh nwfilter-edit clean-traffic
|
|
|
|
...add ``<filterref filter='no-spamming'/>``
|
|
|
|
All active guests immediately have their iptables/ebtables rules rebuilt.
|
|
|
|
The network filter driver deals with iptables in a very similar way. First it
|
|
separates out its rules from those the admin may have defined, by adding a
|
|
couple of hooks into the INPUT/FORWARD chains:
|
|
|
|
::
|
|
|
|
Chain INPUT (policy ACCEPT 13M packets, 21G bytes)
|
|
target prot opt in out source destination
|
|
libvirt-host-in all -- * * 0.0.0.0/0 0.0.0.0/0
|
|
|
|
Chain FORWARD (policy ACCEPT 5532K packets, 3010M bytes)
|
|
target prot opt in out source destination
|
|
libvirt-in all -- * * 0.0.0.0/0 0.0.0.0/0
|
|
libvirt-out all -- * * 0.0.0.0/0 0.0.0.0/0
|
|
libvirt-in-post all -- * * 0.0.0.0/0 0.0.0.0/0
|
|
|
|
These custom chains then do matching based on the TAP device name, so they won't
|
|
open holes in the admin defined matches for the LAN/WAN (if any).
|
|
|
|
::
|
|
|
|
Chain libvirt-host-in (1 references)
|
|
target prot opt in out source destination
|
|
HI-vnet0 all -- * * 0.0.0.0/0 0.0.0.0/0 [goto] PHYSDEV match --physdev-in vnet0
|
|
|
|
Chain libvirt-in (1 references)
|
|
target prot opt in out source destination
|
|
FI-vnet0 all -- * * 0.0.0.0/0 0.0.0.0/0 [goto] PHYSDEV match --physdev-in vnet0
|
|
|
|
Chain libvirt-in-post (1 references)
|
|
target prot opt in out source destination
|
|
ACCEPT all -- * * 0.0.0.0/0 0.0.0.0/0 PHYSDEV match --physdev-in vnet0
|
|
|
|
Chain libvirt-out (1 references)
|
|
target prot opt in out source destination
|
|
FO-vnet0 all -- * * 0.0.0.0/0 0.0.0.0/0 [goto] PHYSDEV match --physdev-out vnet0
|
|
|
|
Finally, we can see the interesting bit which is the actual implementation of my
|
|
filter to block port 25 access:
|
|
|
|
::
|
|
|
|
Chain FI-vnet0 (1 references)
|
|
target prot opt in out source destination
|
|
DROP tcp -- * * 0.0.0.0/0 0.0.0.0/0 tcp dpt:25
|
|
|
|
Chain FO-vnet0 (1 references)
|
|
target prot opt in out source destination
|
|
DROP tcp -- * * 0.0.0.0/0 0.0.0.0/0 tcp spt:25
|
|
|
|
Chain HI-vnet0 (1 references)
|
|
target prot opt in out source destination
|
|
DROP tcp -- * * 0.0.0.0/0 0.0.0.0/0 tcp dpt:25
|
|
|
|
One thing in looking at this you may notice is that if there are many guests all
|
|
using the same filters, we will be duplicating the iptables rules over and over
|
|
for each guest. This is merely a limitation of the current rules engine
|
|
implementation. At the libvirt object modelling level you can clearly see we've
|
|
designed the model so filter rules are defined in one place, and indirectly
|
|
referenced by guests. Thus it should be possible to change the implementation in
|
|
the future so we can share the actual iptables/ebtables rules for each guest to
|
|
create a more scalable system. The stuff in current libvirt is more or less the
|
|
very first working implementation we've had of this, so there's not been much
|
|
optimization work done yet.
|
|
|
|
Also notice that at the XML level we don't expose the fact we are using iptables
|
|
or ebtables at all. The rule definition is done in terms of network protocols.
|
|
Thus if we ever find a need, we could plug in an alternative implementation that
|
|
calls out to a different firewall implementation instead of ebtables/iptables
|
|
(providing that implementation was suitably expressive of course)
|
|
|
|
Finally, in terms of problems we have in deployment. The biggest problem is that
|
|
if the admin does ``service iptables restart`` all our work gets blown away.
|
|
We've experimented with using lokkit to record our custom rules in a persistent
|
|
config file, but that caused different problem. Admins who were not using lokkit
|
|
for their config found that all their own rules got blown away. So we threw away
|
|
our lokkit code. Instead we document that if you run
|
|
``service iptables restart``, you need to send SIGHUP to libvirt to make it
|
|
recreate its rules.
|
|
|
|
More in depth documentation on this is `here <formatnwfilter.html>`__.
|