Now that we have qemuMonitorGetCPUModelExpansion() aware of Hyper-V Enlightenments, we can start querying it. Two conditions need to be met: 1) KVM is in use, 2) Arch is either x86 or arm. It may look like modifying the first call to qemuMonitorGetCPUModelExpansion() inside of virQEMUCapsProbeQMPHostCPU() would be sufficient but it is not. We really need to ask QEMU for full expansion and the first call does not guarantee that. For the test data, I've just copied whatever 'query-cpu-model-expansion' returned earlier, therefore there are no hv-* props. But that's okay - the full expansion is not stored in cache (and thus not formatted in tests/qemucapabilitiesdata/caps_*.replies files either). This is purely runtime thing. Signed-off-by: Michal Privoznik <mprivozn@redhat.com> Reviewed-by: Peter Krempa <pkrempa@redhat.com>
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Domain capabilities XML format
Overview
Sometimes, when a new domain is to be created it may come handy to know the capabilities of the hypervisor so the correct combination of devices and drivers is used. For example, when management application is considering the mode for a host device's passthrough there are several options depending not only on host, but on hypervisor in question too. If the hypervisor is qemu then it needs to be more recent to support VFIO, while legacy KVM is achievable just fine with older qemus.
The main difference between virConnectGetCapabilities and the emulator capabilities API is, the former one aims more on the host capabilities (e.g. NUMA topology, security models in effect, etc.) while the latter one specializes on the hypervisor capabilities.
While the Driver Capabilities provides the host capabilities (e.g NUMA topology, security models in effect, etc.), the Domain Capabilities provides the hypervisor specific capabilities for Management Applications to query and make decisions regarding what to utilize.
The Domain Capabilities can provide information such as the correct combination of devices and drivers that are supported. Knowing which host and hypervisor specific options are available or supported would allow the management application to choose an appropriate mode for a pass-through host device as well as which adapter to utilize.
Some XML elements may be entirely omitted from the domaincapabilities XML, depending on what the libvirt driver has filled in. Applications should only act on what is explicitly reported in the domaincapabilities XML. For example, if <disk supported='yes'/> is present, you can safely assume the driver supports <disk> devices. If <disk supported='no'/> is present, you can safely assume the driver does NOT support <disk> devices. If the <disk> block is omitted entirely, the driver is not indicating one way or the other whether it supports <disk> devices, and applications should not interpret the missing block to mean any thing in particular.
Element and attribute overview
A new query interface was added to the virConnect API's to retrieve the XML listing of the set of domain capabilities ( Since 1.2.7 ):
virConnectGetDomainCapabilities
(API docs)
The root element that emulator capability XML document starts with has name domainCapabilities
. It contains at least four direct child elements:
<domainCapabilities>
<path>/usr/bin/qemu-system-x86_64</path>
<domain>kvm</domain>
<machine>pc-i440fx-2.1</machine>
<arch>x86_64</arch>
...
</domainCapabilities>
path
The full path to the emulator binary.
domain
Describes the virtualization type (or so called domain type).
machine
The domain's machine type. Since not every hypervisor has a sense of machine types this element might be omitted in such drivers.
arch
The domain's architecture.
CPU Allocation
Before any devices capability occurs, there might be info on domain wide capabilities, e.g. virtual CPUs:
<domainCapabilities>
...
<vcpu max='255'/>
...
</domainCapabilities>
vcpu
The maximum number of supported virtual CPUs
BIOS bootloader
Sometimes users might want to tweak some BIOS knobs or use UEFI. For cases like that, os element exposes what values can be passed to its children.
<domainCapabilities>
...
<os supported='yes'>
<enum name='firmware'>
<value>bios</value>
<value>efi</value>
</enum>
<loader supported='yes'>
<value>/usr/share/OVMF/OVMF_CODE.fd</value>
<enum name='type'>
<value>rom</value>
<value>pflash</value>
</enum>
<enum name='readonly'>
<value>yes</value>
<value>no</value>
</enum>
<enum name='secure'>
<value>yes</value>
<value>no</value>
</enum>
</loader>
</os>
...
<domainCapabilities>
The firmware
enum corresponds to the firmware
attribute of the os
element in the domain XML. The presence of this enum means libvirt is capable of the so-called firmware auto-selection feature. And the listed firmware values represent the accepted input in the domain XML. Note that the firmware
enum reports only those values for which a firmware "descriptor file" exists on the host. Firmware descriptor file is a small JSON document that describes details about a given BIOS or UEFI binary on the host, e.g. the firmware binary path, its architecture, supported machine types, NVRAM template, etc. This ensures that the reported values won't cause a failure on guest boot.
For the loader
element, the following can occur:
value
List of known firmware binary paths. Currently this is used only to advertise the known location of OVMF binaries for QEMU. OVMF binaries will only be listed if they actually exist on host.
type
Whether the boot loader is a typical BIOS (
rom
) or a UEFI firmware (pflash
). Eachvalue
sub-element under thetype
enum represents a possible value for thetype
attribute for the <loader/> element in the domain XML. E.g. the presence ofpfalsh
under thetype
enum means that a domain XML can use UEFI firmware via: <loader/> type="pflash" ...>/path/to/the/firmware/binary/</loader>.readonly
Options for the
readonly
attribute of the <loader/> element in the domain XML.secure
Options for the
secure
attribute of the <loader/> element in the domain XML. Note that the valueyes
is listed only if libvirt detects a firmware descriptor file that has path to an OVMF binary that supports Secure boot, and lists its architecture and supported machine type.
CPU configuration
The cpu
element exposes options usable for configuring guest CPUs.
<domainCapabilities>
...
<cpu>
<mode name='host-passthrough' supported='yes'>
<enum name='hostPassthroughMigratable'>
<value>on</value>
<value>off</value>
</enum>
</mode>
<mode name='maximum' supported='yes'>
<enum name='maximumMigratable'>
<value>on</value>
<value>off</value>
</enum>
</mode>
<mode name='host-model' supported='yes'>
<model fallback='allow'>Broadwell</model>
<vendor>Intel</vendor>
<feature policy='disable' name='aes'/>
<feature policy='require' name='vmx'/>
</mode>
<mode name='custom' supported='yes'>
<model usable='no' deprecated='no' vendor='Intel'>Broadwell</model>
<model usable='yes' deprecated='no' vendor='Intel'>Broadwell-noTSX</model>
<model usable='no' deprecated='yes' vendor='Intel'>Haswell</model>
<model usable='no' deprecated='no' vendor='AMD'>EPYC-Milan</model>
...
</mode>
</cpu>
...
<domainCapabilities>
Each CPU mode understood by libvirt is described with a mode
element which tells whether the particular mode is supported and provides (when applicable) more details about it:
host-passthrough
The
hostPassthroughMigratable
enum shows possible values of themigratable
attribute for the <cpu> element withmode='host-passthrough'
in the domain XML.host-model
If
host-model
is supported by the hypervisor, themode
describes the guest CPU which will be used when starting a domain withhost-model
CPU. The hypervisor specifics (such as unsupported CPU models or features, machine type, etc.) may be accounted for in this guest CPU specification and thus the CPU can be different from the one shown in host capabilities XML. This is indicated by thefallback
attribute of themodel
sub element:allow
means not all specifics were accounted for and thus the CPU a guest will see may be different;forbid
indicates that the CPU a guest will see should match this CPU definition.custom
The
mode
element contains a list of supported CPU models, each described by a dedicatedmodel
element. Theusable
attribute specifies whether the model can be used directly on the host. A special valueunknown
indicates libvirt does not have enough information to provide the usability data. Whenusable='no'
the corresponding model cannot be used without disabling some features that the CPU of such model is expected to have. The list of features blocking usability of a particular CPU model is returned as disabled features in the result ofvirConnectBaselineHypervisorCPU
API (orvirsh hypervisor-cpu-baseline
) when called on a CPU definition using the CPU model and no additional feature elements. Models marked as usable (usable='yes'
) can be safely used in domain XMLs withcheck='none'
as the hypervisor guarantees the model can be used on the current host and additional checks done by libvirt are redundant. In fact, disabling libvirt checks viacheck='none'
for such models is recommended to avoid needless issues with starting domains when libvirt's definition of a particular model differs from hypervisor's definition. Thedeprecated
attribute reflects the hypervisor's policy on usage of this model (since 7.1.0). Thevendor
attribute (since 8.9.0) contains the vendor of the CPU model for users who want to use CPU models with specific vendors only. CPU models with undefined vendor will be listed withvendor='unkwnown'
.
I/O Threads
The iothread
elements indicates whether or not I/O threads are supported.
<domainCapabilities>
...
<iothread supported='yes'/>
...
<domainCapabilities>
Memory Backing
The memory backing
element indicates whether or not memory backing is supported.
<domainCapabilities>
...
<memoryBacking supported='yes'>
<enum name='sourceType'>
<value>anonymous</value>
<value>file</value>
<value>memfd</value>
</enum>
</memoryBacking>
...
<domainCapabilities>
sourceType
Options for the
type
attribute of the <memoryBacking><source> element.
Devices
Another set of XML elements describe the supported devices and their capabilities. All devices occur as children of the main devices
element.
<domainCapabilities>
...
<devices>
<disk supported='yes'>
<enum name='diskDevice'>
<value>disk</value>
<value>cdrom</value>
<value>floppy</value>
<value>lun</value>
</enum>
...
</disk>
<hostdev supported='no'/>
</devices>
</domainCapabilities>
Reported capabilities are expressed as an enumerated list of available options for each of the element or attribute. For example, the <disk/> element has an attribute device
which can support the values disk
, cdrom
, floppy
, or lun
.
Hard drives, floppy disks, CDROMs
Disk capabilities are exposed under the disk
element. For instance:
<domainCapabilities>
...
<devices>
<disk supported='yes'>
<enum name='diskDevice'>
<value>disk</value>
<value>cdrom</value>
<value>floppy</value>
<value>lun</value>
</enum>
<enum name='bus'>
<value>ide</value>
<value>fdc</value>
<value>scsi</value>
<value>virtio</value>
<value>xen</value>
<value>usb</value>
<value>sata</value>
<value>sd</value>
</enum>
</disk>
...
</devices>
</domainCapabilities>
diskDevice
Options for the
device
attribute of the <disk/> element.bus
Options for the
bus
attribute of the <target/> element for a <disk/>.
Graphical framebuffers
Graphics device capabilities are exposed under the graphics
element. For instance:
<domainCapabilities>
...
<devices>
<graphics supported='yes'>
<enum name='type'>
<value>sdl</value>
<value>vnc</value>
<value>spice</value>
</enum>
</graphics>
...
</devices>
</domainCapabilities>
type
Options for the
type
attribute of the <graphics/> element.
Video device
Video device capabilities are exposed under the video
element. For instance:
<domainCapabilities>
...
<devices>
<video supported='yes'>
<enum name='modelType'>
<value>vga</value>
<value>cirrus</value>
<value>vmvga</value>
<value>qxl</value>
<value>virtio</value>
</enum>
</video>
...
</devices>
</domainCapabilities>
modelType
Options for the
type
attribute of the <video><model> element.
Host device assignment
Some host devices can be passed through to a guest (e.g. USB, PCI and SCSI). Well, only if the following is enabled:
<domainCapabilities>
...
<devices>
<hostdev supported='yes'>
<enum name='mode'>
<value>subsystem</value>
<value>capabilities</value>
</enum>
<enum name='startupPolicy'>
<value>default</value>
<value>mandatory</value>
<value>requisite</value>
<value>optional</value>
</enum>
<enum name='subsysType'>
<value>usb</value>
<value>pci</value>
<value>scsi</value>
</enum>
<enum name='capsType'>
<value>storage</value>
<value>misc</value>
<value>net</value>
</enum>
<enum name='pciBackend'>
<value>default</value>
<value>kvm</value>
<value>vfio</value>
<value>xen</value>
</enum>
</hostdev>
</devices>
</domainCapabilities>
mode
Options for the
mode
attribute of the <hostdev/> element.startupPolicy
Options for the
startupPolicy
attribute of the <hostdev/> element.subsysType
Options for the
type
attribute of the <hostdev/> element in case ofmode="subsystem"
.capsType
Options for the
type
attribute of the <hostdev/> element in case ofmode="capabilities"
.pciBackend
Options for the
name
attribute of the <driver/> element.
RNG device
RNG device capabilities are exposed under the rng
element. For instance:
<domainCapabilities>
...
<devices>
<rng supported='yes'>
<enum name='model'>
<value>virtio</value>
<value>virtio-transitional</value>
<value>virtio-non-transitional</value>
</enum>
<enum name='backendModel'>
<value>random</value>
<value>egd</value>
<value>builtin</value>
</enum>
</rng>
...
</devices>
</domainCapabilities>
model
Options for the
model
attribute of the <rng> element.backendModel
Options for the
model
attribute of the <rng><backend> element.
Filesystem device
Filesystem device capabilities are exposed under the filesystem
element. For instance:
<domainCapabilities>
...
<devices>
<filesystem supported='yes'>
<enum name='driverType'>
<value>default</value>
<value>path</value>
<value>handle</value>
<value>virtiofs</value>
</enum>
</filesystem>
...
</devices>
</domainCapabilities>
driverType
Options for the
type
attribute of the <filesystem><driver> element.
TPM device
TPM device capabilities are exposed under the tpm
element. For instance:
<domainCapabilities>
...
<devices>
<tpm supported='yes'>
<enum name='model'>
<value>tpm-tis</value>
<value>tpm-crb</value>
</enum>
<enum name='backendModel'>
<value>passthrough</value>
<value>emulator</value>
</enum>
<enum name='backendVersion'>
<value>1.2</value>
<value>2.0</value>
</enum>
</tpm>
...
</devices>
</domainCapabilities>
model
Options for the
model
attribute of the<tpm/>
element.backendModel
Options for the
type
attribute of the<tpm><backend/>
element.backendVersion
Options for the
version
attribute of the<tpm><backend/>
element.
USB redirect device
USB redirdev device capabilities are exposed under the redirdev
element. For instance:
<domainCapabilities>
...
<devices>
<redirdev supported='yes'>
<enum name='bus'>
<value>usb</value>
</enum>
</redirdev>
...
</devices>
</domainCapabilities>
bus
Options for the
bus
attribute of the<redirdev/>
element.
Channel device
Channel device capabilities are exposed under the channel
element. For instance:
<domainCapabilities>
...
<devices>
<channel supported='yes'>
<enum name='type'>
<value>pty</value>
<value>unix</value>
<value>spicevmc</value>
</enum>
</channel
...
</devices>
</domainCapabilities>
type
Options for the
type
attribute of the<channel/>
element.
Features
One more set of XML elements describe the supported features and their capabilities. All features occur as children of the main features
element.
<domainCapabilities>
...
<features>
<gic supported='yes'>
<enum name='version'>
<value>2</value>
<value>3</value>
</enum>
</gic>
<vmcoreinfo supported='yes'/>
<genid supported='yes'/>
<backingStoreInput supported='yes'/>
<backup supported='yes'/>
<sev>
<cbitpos>47</cbitpos>
<reduced-phys-bits>1</reduced-phys-bits>
</sev>
<sgx supported='yes'>
<flc>no</flc>
<sgx1>yes</sgx1>
<sgx2>no</sgx2>
<section_size unit='KiB'>524288</section_size>
<sections>
<section node='0' size='262144' unit='KiB'/>
<section node='1' size='262144' unit='KiB'/>
</sections>
</sgx>
<hyperv supported='yes'>
<enum name='features'>
<value>relaxed</value>
<value>vapic</value>
</enum>
</hyperv>
</features>
</domainCapabilities>
Reported capabilities are expressed as an enumerated list of possible values for each of the elements or attributes. For example, the gic
element has an attribute version
which can support the values 2
or 3
.
For information about the purpose of each feature, see the relevant section in the domain XML documentation.
GIC capabilities
GIC capabilities are exposed under the gic
element.
version
Options for the
version
attribute of thegic
element.
vmcoreinfo
Reports whether the vmcoreinfo feature can be enabled.
genid
Reports whether the genid feature can be used by the domain.
backingStoreInput
Reports whether the hypervisor will obey the <backingStore> elements configured for a <disk> when booting the guest, hotplugging the disk to a running guest, or similar. (Since 5.10)
backup
Reports whether the hypervisor supports the backup, checkpoint, and related features. (virDomainBackupBegin
, virDomainCheckpointCreateXML
etc). The presence of the backup
element even if supported='no'
implies that the VIR_DOMAIN_UNDEFINE_CHECKPOINTS_METADATA
flag for virDomainUndefine
is supported.
s390-pv capability
Reports whether the hypervisor supports the Protected Virtualization. In order to use Protected Virtualization with libvirt have a look at the launchSecurity element in the domain XML. For more details on the Protected Virtualization feature please see Protected Virtualization on s390.
SEV capabilities
AMD Secure Encrypted Virtualization (SEV) capabilities are exposed under the sev
element. SEV is an extension to the AMD-V architecture which supports running virtual machines (VMs) under the control of a hypervisor. When supported, guest owner can create a VM whose memory contents will be transparently encrypted with a key unique to that VM.
For more details on the SEV feature, please follow resources in the AMD developer's document store. In order to use SEV with libvirt have a look at SEV in domain XML
cbitpos
When memory encryption is enabled, one of the physical address bits (aka the C-bit) is utilized to mark if a memory page is protected. The C-bit position is Hypervisor dependent.
reducedPhysBits
When memory encryption is enabled, we lose certain bits in physical address space. The number of bits we lose is hypervisor dependent.
maxGuests
The maximum number of SEV guests that can be launched on the host. This value may be configurable in the firmware for some hosts.
maxESGuests
The maximum number of SEV-ES guests that can be launched on the host. This value may be configurable in the firmware for some hosts.
SGX capabilities
Intel Software Guard Extensions (Intel SGX) capabilities are exposed under the sgx
element.
Intel SGX helps protect data in use via unique application isolation technology. Protect selected code and data from modification using hardened enclaves with Intel SGX.
For more details on the SGX feature, please follow resources in the SGX developer's document store. In order to use SGX with libvirt have a look at SGX in domain XML
flc
FLC (Flexible Launch Control), not strictly part of SGX2, but was not part of original SGX hardware either.
sgx1
the sgx version 1.
sgx2
The sgx version 2.
section_size
The size of the SGX enclave page cache (called EPC).
sections
The sections of the SGX enclave page cache (called EPC).
Hyper-V Enlightenments
Report which features improving behavior of guests running Microsoft Windows are supported. The features
enum corresponds to the <hyperv/>
element (well, its children) as documented in Hypervisor features.
Please note that depending on the QEMU version some capabilities might be missing even though QEMU does support them. This is because prior to QEMU-6.1.0 not all features were reported by QEMU.