.. role:: since
==============================
Driver capabilities XML format
==============================
.. contents::
Element and attribute overview
------------------------------
As new virtualization engine support gets added to libvirt, and to handle cases
like QEMU supporting a variety of emulations, a query interface has been added
in 0.2.1 allowing to list the set of supported virtualization capabilities on
the host:
::
char * virConnectGetCapabilities (virConnectPtr conn);
The value returned is an XML document listing the virtualization capabilities of
the host and virtualization engine to which ```conn`` is connected. One can test
it using ``virsh`` command line tool command '``capabilities``', it dumps the
XML associated to the current connection.
As can be seen in the `Examples`_, the capabilities XML
consists of the ``capabilities`` element which have exactly one ``host`` child
element to report information on host capabilities, and zero or more ``guest``
element to express the set of architectures the host can run at the moment.
Host capabilities
~~~~~~~~~~~~~~~~~
The ```` element consists of the following child elements:
``uuid``
The host UUID.
``cpu``
The host CPU architecture and features.
Note that, while this element contains a ``topology`` sub-element,
the information contained therein is farily high-level and likely
not very useful when it comes to optimizing guest vCPU placement.
Look into the ``topology`` *element*, described below, for more
detailed information.
``power_management``
whether host is capable of memory suspend, disk hibernation, or hybrid
suspend.
``migration_features``
This element exposes information on the hypervisor's migration capabilities,
like live migration, supported URI transports, and so on.
``topology``
This element describes the host CPU topology in detail.
Management applications may want to use this information when defining new
guests: for example, in order to ensure that all vCPUs are scheduled on
CPUs that are in the same NUMA node or even CPU core.
The ``cells`` sub-element contains a list of NUMA nodes, each one
represented by a single ``cell`` element. Within each ``cell``, a ``cpus``
sub-element contains a list of logical CPUs, each one represented by a
single ``cpu`` element. In both cases, the ``num`` attribute of the
top-level element contains the number of children.
Each ``cpu`` element contains the following attributes:
``id``
CPU identifier. Can be used to refer to it in the context of
`CPU tuning `__.
``socket_id``
Identifier for the physical package the CPU is in.
``die_id``
Identifier for the die the CPU is in.
Note that, even if this attribute is present, you might not be able to
define guests with multiple CPU dies.
``cluster_id``
Identifier for the cluster the CPU is in.
Note that, even if this attribute is present, you might not be able to
define guests with multiple CPU clusters.
``core_id``
Identifier for the core the CPU is in.
``siblings``
List of CPUs that are in the same core.
The list will include the current CPU, plus all other CPUs that have the
same values for ``socket_id``, ``die_id``, ``cluster_id`` and ``core_id``.
``secmodel``
To find out default security labels for different security models you need to
parse this element. In contrast with the former elements, this is repeated
for each security model the libvirt daemon currently supports.
Guest capabilities
~~~~~~~~~~~~~~~~~~
While the previous section (`Host capabilities`_) aims at host capabilities,
this one focuses on capabilities available to a guest using a given hypervisor.
The ```` element will typically wrap up the following elements:
``os_type``
This expresses what kind of operating system the hypervisor is able to run.
Possible values are:
``xen``
for XEN PV
``linux``
legacy alias for ``xen``
``xenpvh``
for XEN PVH
``hvm``
Unmodified operating system
``exe``
Container based virtualization
``arch``
This element brings some information on supported guest architecture.
Possible subelements are:
``wordsize``
Size of CPU word in bits, for example 64.
``emulator``
Emulator (device model) path, for use in
`emulator `__ element of domain XML.
``loader``
Loader path, for use in `loader `__
element of domain XML.
``machine``
Machine type, for use in
`machine `__ attribute of
os/type element in domain XML. For example Xen supports ``xenfv`` for HVM,
``xenpv`` for PV, or ``xenpvh`` for PVH.
``domain``
The ``type`` attribute of this element specifies the type of hypervisor
required to run the domain. Use in
`type `__ attribute of
the domain root element.
``features``
This optional element encases possible features that can be used with a guest
of described type. Possible subelements are:
``pae``
If present, 32-bit guests can use PAE address space extensions,
:since:`since 0.4.1`
``nonpae``
If present, 32-bit guests can be run without requiring PAE,
:since:`since 0.4.1`
``ia64_be``
If present, IA64 guests can be run in big-endian mode,
:since:`since 0.4.1`
``acpi``
If this element is present, the ``default`` attribute describes whether
the hypervisor exposes ACPI to the guest by default, and the ``toggle``
attribute describes whether the user can override this default.
:since:`Since 0.4.1`
``apic``
If this element is present, the ``default`` attribute describes whether
the hypervisor exposes APIC to the guest by default, and the ``toggle``
attribute describes whether the user can override this default.
:since:`Since 0.4.1`
``cpuselection``
If this element is present, the hypervisor supports the ```` element
within a domain definition for fine-grained control over the CPU presented
to the guest. :since:`Since 0.7.5`
``deviceboot``
If this element is present, the ```` element can be
used inside devices, rather than the older boot specification by category.
:since:`Since 0.8.8`
``disksnapshot``
If this element is present, the ``default`` attribute describes whether
creating external disk snapshots is supported. If absent, creating external
snapshots may still be supported, but it requires attempting the API and
checking for an error to find out for sure. :since:`Since 1.2.3`
``externalSnapshot``
If this element is present, the hypervisor supports deleting and
reverting external snapshots including memory state. Support for creation
of external snapshots is reported via the ``disksnapshot`` feature flag.
Management applications can now switch from internal snapshots to external
snapshots. :since:`Since 9.9.0`
Examples
~~~~~~~~
For example, in the case of a 64-bit machine with hardware virtualization
capabilities enabled in the chip and BIOS you will see:
::
7b55704c-29f4-11b2-a85c-9dc6ff50623f
x86_64
Skylake-Client-noTSX-IBRS
Intel
tcp
rdma
|
32498112
6813808
2048
1
|
none
0
dac
0
+77:+77
+77:+77
hvm
64
/usr/bin/qemu-system-x86_64
pc-i440fx-7.1
pc
pc-q35-5.2
pc-i440fx-2.12
pc-i440fx-2.0
pc-i440fx-6.2
pc-q35-4.2
pc-i440fx-2.5
pc-i440fx-4.2
pc-i440fx-5.2
pc-i440fx-1.5
pc-q35-2.7
pc-q35-7.1
q35
pc-i440fx-2.2
pc-i440fx-2.7
pc-q35-6.1
pc-q35-2.4
pc-q35-2.10
x-remote
pc-q35-5.1
pc-i440fx-1.7
pc-q35-2.9
pc-i440fx-2.11
pc-q35-3.1
pc-i440fx-6.1
pc-q35-4.1
pc-i440fx-2.4
pc-i440fx-4.1
pc-i440fx-5.1
pc-i440fx-2.9
isapc
pc-i440fx-1.4
pc-q35-2.6
pc-i440fx-3.1
pc-q35-2.12
pc-q35-7.0
pc-i440fx-2.1
pc-q35-6.0
pc-i440fx-2.6
pc-q35-4.0.1
pc-i440fx-7.0
pc-i440fx-1.6
pc-q35-5.0
pc-q35-2.8
pc-i440fx-2.10
pc-q35-3.0
pc-i440fx-6.0
pc-q35-4.0
microvm
pc-i440fx-2.3
pc-i440fx-4.0
pc-i440fx-5.0
pc-i440fx-2.8
pc-q35-6.2
pc-q35-2.5
pc-i440fx-3.0
pc-q35-2.11