NAME

xl.cfg - xl domain configuration file syntax

SYNOPSIS

 /etc/xen/xldomain

DESCRIPTION

Creating a VM (a domain in Xen terminology, sometimes called a guest) with xl requires the provision of a domain configuration file. Typically, these live in /etc/xen/DOMAIN.cfg, where DOMAIN is the name of the domain.

SYNTAX

A domain configuration file consists of a series of options, specified by using KEY=VALUE pairs.

Some KEYs are mandatory, some are general options which apply to any guest type, while others relate only to specific guest types (e.g. PV or HVM guests).

A VALUE can be one of:

"STRING"

A string, surrounded by either single or double quotes. But if the STRING is part of a SPEC_STRING, the quotes should be omitted.

NUMBER

A number, in either decimal, octal (using a 0 prefix) or hexadecimal (using a 0x prefix) format.

BOOLEAN

A NUMBER interpreted as False (0) or True (any other value).

[ VALUE, VALUE, ... ]

A list of VALUEs of the above types. Lists can be heterogeneous and nested.

The semantics of each KEY defines which type of VALUE is required.

Pairs may be separated either by a newline or a semicolon. Both of the following are valid:

  name="h0"
  type="hvm"

  name="h0"; type="hvm"

OPTIONS

Mandatory Configuration Items

The following key is mandatory for any guest type.

name="NAME"

Specifies the name of the domain. Names of domains existing on a single host must be unique.

Selecting Guest Type

type="pv"

Specifies that this is to be a PV domain, suitable for hosting Xen-aware guest operating systems. This is the default on x86.

type="pvh"

Specifies that this is to be an PVH domain. That is a lightweight HVM-like guest without a device model and without many of the emulated devices available to HVM guests. Note that this mode requires a PVH aware kernel on x86. This is the default on Arm.

type="hvm"

Specifies that this is to be an HVM domain. That is, a fully virtualised computer with emulated BIOS, disk and network peripherals, etc.

Deprecated guest type selection

Note that the builder option is being deprecated in favor of the type option.

builder="generic"

Specifies that this is to be a PV domain, suitable for hosting Xen-aware guest operating systems. This is the default.

builder="hvm"

Specifies that this is to be an HVM domain. That is, a fully virtualised computer with emulated BIOS, disk and network peripherals, etc.

General Options

The following options apply to guests of any type.

CPU Allocation

pool="CPUPOOLNAME"

Put the guest's vCPUs into the named CPU pool.

vcpus=N

Start the guest with N vCPUs initially online.

maxvcpus=M

Allow the guest to bring up a maximum of M vCPUs. When starting the guest, if vcpus=N is less than maxvcpus=M then the first N vCPUs will be created online and the remainder will be created offline.

cpus="CPULIST"

List of host CPUs the guest is allowed to use. Default is no pinning at all (more on this below). A CPULIST may be specified as follows:

"all"

To allow all the vCPUs of the guest to run on all the CPUs on the host.

"0-3,5,^1"

To allow all the vCPUs of the guest to run on CPUs 0,2,3,5. It is possible to combine this with "all", meaning "all,^7" results in all the vCPUs of the guest being allowed to run on all the CPUs of the host except CPU 7.

"nodes:0-3,^node:2"

To allow all the vCPUs of the guest to run on the CPUs from NUMA nodes 0,1,3 of the host. So, if CPUs 0-3 belong to node 0, CPUs 4-7 belong to node 1, CPUs 8-11 to node 2 and CPUs 12-15 to node 3, the above would mean all the vCPUs of the guest would be allowed to run on CPUs 0-7,12-15.

Combining this notation with the one above is possible. For instance, "1,node:1,^6", means all the vCPUs of the guest will run on CPU 1 and on all the CPUs of NUMA node 1, but not on CPU 6. Following the same example as above, that would be CPUs 1,4,5,7.

Combining this with "all" is also possible, meaning "all,^node:1" results in all the vCPUs of the guest running on all the CPUs on the host, except for the CPUs belonging to the host NUMA node 1.

["2", "3-8,^5"]

To ask for specific vCPU mapping. That means (in this example), vCPU 0 of the guest will run on CPU 2 of the host and vCPU 1 of the guest will run on CPUs 3,4,6,7,8 of the host (excluding CPU 5).

More complex notation can be also used, exactly as described above. So "all,^5-8", or just "all", or "node:0,node:2,^9-11,18-20" are all legal, for each element of the list.

If this option is not specified, no vCPU to CPU pinning is established, and the vCPUs of the guest can run on all the CPUs of the host. If this option is specified, the intersection of the vCPU pinning mask, provided here, and the soft affinity mask, if provided via cpus_soft=, is utilized to compute the domain node-affinity for driving memory allocations.

cpus_soft="CPULIST"

Exactly as cpus=, but specifies soft affinity, rather than pinning (hard affinity). When using the credit scheduler, this means what CPUs the vCPUs of the domain prefer.

A CPULIST is specified exactly as for cpus=, detailed earlier in the manual.

If this option is not specified, the vCPUs of the guest will not have any preference regarding host CPUs. If this option is specified, the intersection of the soft affinity mask, provided here, and the vCPU pinning, if provided via cpus=, is utilized to compute the domain node-affinity for driving memory allocations.

If this option is not specified (and cpus= is not specified either), libxl automatically tries to place the guest on the least possible number of nodes. A heuristic approach is used for choosing the best node (or set of nodes), with the goal of maximizing performance for the guest and, at the same time, achieving efficient utilization of host CPUs and memory. In that case, the soft affinity of all the vCPUs of the domain will be set to host CPUs belonging to NUMA nodes chosen during placement.

For more details, see xl-numa-placement(7).

CPU Scheduling

cpu_weight=WEIGHT

A domain with a weight of 512 will get twice as much CPU as a domain with a weight of 256 on a contended host. Legal weights range from 1 to 65535 and the default is 256. Honoured by the credit and credit2 schedulers.

cap=N

The cap optionally fixes the maximum amount of CPU a domain will be able to consume, even if the host system has idle CPU cycles. The cap is expressed as a percentage of one physical CPU: 100 is 1 physical CPU, 50 is half a CPU, 400 is 4 CPUs, etc. The default, 0, means there is no cap. Honoured by the credit and credit2 schedulers.

NOTE: Many systems have features that will scale down the computing power of a CPU that is not 100% utilized. This can be done in the operating system, but can also sometimes be done below the operating system, in the BIOS. If you set a cap such that individual cores are running at less than 100%, this may have an impact on the performance of your workload over and above the impact of the cap. For example, if your processor runs at 2GHz, and you cap a VM at 50%, the power management system may also reduce the clock speed to 1GHz; the effect will be that your VM gets 25% of the available power (50% of 1GHz) rather than 50% (50% of 2GHz). If you are not getting the performance you expect, look at performance and CPU frequency options in your operating system and your BIOS.

Memory Allocation

memory=MBYTES

Start the guest with MBYTES megabytes of RAM.

maxmem=MBYTES

Specifies the maximum amount of memory a guest can ever see. The value of maxmem= must be equal to or greater than that of memory=.

In combination with memory= it will start the guest "pre-ballooned", if the values of memory= and maxmem= differ. A "pre-ballooned" HVM guest needs a balloon driver, without a balloon driver it will crash.

NOTE: Because of the way ballooning works, the guest has to allocate memory to keep track of maxmem pages, regardless of how much memory it actually has available to it. A guest with maxmem=262144 and memory=8096 will report significantly less memory available for use than a system with maxmem=8096 memory=8096 due to the memory overhead of having to track the unused pages.

Guest Virtual NUMA Configuration

vnuma=[ VNODE_SPEC, VNODE_SPEC, ... ]

Specify virtual NUMA configuration with positional arguments. The nth VNODE_SPEC in the list specifies the configuration of the nth virtual node.

Note that virtual NUMA is not supported for PV guests yet, because there is an issue with the CPUID instruction handling that affects PV virtual NUMA. Furthermore, guests with virtual NUMA cannot be saved or migrated because the migration stream does not preserve node information.

Each VNODE_SPEC is a list, which has a form of "[VNODE_CONFIG_OPTION, VNODE_CONFIG_OPTION, ... ]" (without the quotes).

For example, vnuma = [ ["pnode=0","size=512","vcpus=0-4","vdistances=10,20"] ] means vnode 0 is mapped to pnode 0, has 512MB ram, has vcpus 0 to 4, the distance to itself is 10 and the distance to vnode 1 is 20.

Each VNODE_CONFIG_OPTION is a quoted KEY=VALUE pair. Supported VNODE_CONFIG_OPTIONs are (they are all mandatory at the moment):

pnode=NUMBER

Specifies which physical node this virtual node maps to.

size=MBYTES

Specifies the size of this virtual node. The sum of memory sizes of all vnodes will become maxmem=. If maxmem= is specified separately, a check is performed to make sure the sum of all vnode memory matches maxmem=.

vcpus="CPUSTRING"

Specifies which vCPUs belong to this node. "CPUSTRING" is a string of numerical values separated by a comma. You can specify a range and/or a single CPU. An example would be "vcpus=0-5,8", which means you specified vCPU 0 to vCPU 5, and vCPU 8.

vdistances=NUMBER, NUMBER, ...

Specifies the virtual distance from this node to all nodes (including itself) with positional arguments. For example, "vdistance=10,20" for vnode 0 means the distance from vnode 0 to vnode 0 is 10, from vnode 0 to vnode 1 is 20. The number of arguments supplied must match the total number of vnodes.

Normally you can use the values from xl info -n or numactl --hardware to fill the vdistances list.

Event Actions

on_poweroff="ACTION"

Specifies what should be done with the domain if it shuts itself down. The ACTIONs are:

destroy

destroy the domain

restart

destroy the domain and immediately create a new domain with the same configuration

rename-restart

rename the domain which terminated, and then immediately create a new domain with the same configuration as the original

preserve

keep the domain. It can be examined, and later destroyed with xl destroy.

coredump-destroy

write a "coredump" of the domain to /var/lib/xen/dump/NAME and then destroy the domain.

coredump-restart

write a "coredump" of the domain to /var/lib/xen/dump/NAME and then restart the domain.

soft-reset

Reset all Xen specific interfaces for the Xen-aware HVM domain allowing it to reestablish these interfaces and continue executing the domain. PV and non-Xen-aware HVM guests are not supported.

The default for on_poweroff is destroy.

on_reboot="ACTION"

Action to take if the domain shuts down with a reason code requesting a reboot. Default is restart.

on_watchdog="ACTION"

Action to take if the domain shuts down due to a Xen watchdog timeout. Default is destroy.

on_crash="ACTION"

Action to take if the domain crashes. Default is destroy.

on_soft_reset="ACTION"

Action to take if the domain performs a 'soft reset' (e.g. does kexec). Default is soft-reset.

Direct Kernel Boot

Direct kernel boot allows booting guests with a kernel and an initrd stored on a filesystem available to the host physical machine, allowing command line arguments to be passed directly. PV guest direct kernel boot is supported. HVM guest direct kernel boot is supported with some limitations (it's supported when using qemu-xen and the default BIOS 'seabios', but not supported in case of using stubdom-dm and the old 'rombios'.)

kernel="PATHNAME"

Load the specified file as the kernel image.

ramdisk="PATHNAME"

Load the specified file as the ramdisk.

cmdline="STRING"

Append STRING to the kernel command line. (Note: the meaning of this is guest specific). It can replace root="STRING" along with extra="STRING" and is preferred. When cmdline="STRING" is set, root="STRING" and extra="STRING" will be ignored.

root="STRING"

Append root=STRING to the kernel command line (Note: the meaning of this is guest specific).

extra="STRING"

Append STRING to the kernel command line. (Note: the meaning of this is guest specific).

Non direct Kernel Boot

Non direct kernel boot allows booting guests with a firmware. This can be used by all types of guests, although the selection of options is different depending on the guest type.

This option provides the flexibly of letting the guest decide which kernel they want to boot, while preventing having to poke at the guest file system form the toolstack domain.

PV guest options

firmware="pvgrub32|pvgrub64"

Boots a guest using a para-virtualized version of grub that runs inside of the guest. The bitness of the guest needs to be know, so that the right version of pvgrub can be selected.

Note that xl expects to find the pvgrub32.bin and pvgrub64.bin binaries in /usr/local/lib/xen/boot.

HVM guest options

firmware="bios"

Boot the guest using the default BIOS firmware, which depends on the chosen device model.

firmware="uefi"

Boot the guest using the default UEFI firmware, currently OVMF.

firmware="seabios"

Boot the guest using the SeaBIOS BIOS firmware.

firmware="rombios"

Boot the guest using the ROMBIOS BIOS firmware.

firmware="ovmf"

Boot the guest using the OVMF UEFI firmware.

firmware="PATH"

Load the specified file as firmware for the guest.

PVH guest options

Currently there's no firmware available for PVH guests, they should be booted using the Direct Kernel Boot method or the bootloader option.

pvshim=BOOLEAN

Whether to boot this guest as a PV guest within a PVH container. Ie, the guest will experience a PV environment, but processor hardware extensions are used to separate its address space to mitigate the Meltdown attack (CVE-2017-5754).

Default is false.

pvshim_path="PATH"

The PV shim is a specially-built firmware-like executable constructed from the hypervisor source tree. This option specifies to use a non-default shim. Ignored if pvhsim is false.

pvshim_cmdline="STRING"

Command line for the shim. Default is "pv-shim console=xen,pv". Ignored if pvhsim is false.

pvshim_extra="STRING"

Extra command line arguments for the shim. If supplied, appended to the value for pvshim_cmdline. Default is empty. Ignored if pvhsim is false.

Other Options

uuid="UUID"

Specifies the UUID of the domain. If not specified, a fresh unique UUID will be generated.

seclabel="LABEL"

Assign an XSM security label to this domain.

init_seclabel="LABEL"

Specify an XSM security label used for this domain temporarily during its build. The domain's XSM label will be changed to the execution seclabel (specified by seclabel) once the build is complete, prior to unpausing the domain. With a properly constructed security policy (such as nomigrate_t in the example policy), this can be used to build a domain whose memory is not accessible to the toolstack domain.

max_grant_frames=NUMBER

Specify the maximum number of grant frames the domain is allowed to have. This value controls how many pages the domain is able to grant access to for other domains, needed e.g. for the operation of paravirtualized devices. The default is settable via xl.conf(5).

max_maptrack_frames=NUMBER

Specify the maximum number of grant maptrack frames the domain is allowed to have. This value controls how many pages of foreign domains can be accessed via the grant mechanism by this domain. The default value is settable via xl.conf(5).

max_grant_version=NUMBER

Specify the maximum grant table version the domain is allowed to use. The default value is settable via xl.conf(5).

nomigrate=BOOLEAN

Disable migration of this domain. This enables certain other features which are incompatible with migration. Currently this is limited to enabling the invariant TSC feature flag in CPUID results when TSC is not emulated.

driver_domain=BOOLEAN

Specify that this domain is a driver domain. This enables certain features needed in order to run a driver domain.

device_tree=PATH

Specify a partial device tree (compiled via the Device Tree Compiler). Everything under the node "/passthrough" will be copied into the guest device tree. For convenience, the node "/aliases" is also copied to allow the user to define aliases which can be used by the guest kernel.

Given the complexity of verifying the validity of a device tree, this option should only be used with a trusted device tree.

Note that the partial device tree should avoid using the phandle 65000 which is reserved by the toolstack.

passthrough="STRING"

Specify whether IOMMU mappings are enabled for the domain and hence whether it will be enabled for passthrough hardware. Valid values for this option are:

disabled

IOMMU mappings are disabled for the domain and so hardware may not be passed through.

This option is the default if no passthrough hardware is specified in the domain's configuration.

enabled

This option enables IOMMU mappings and selects an appropriate default operating mode (see below for details of the operating modes). For HVM/PVH domains running on platforms where the option is available, this is equivalent to share_pt. Otherwise, and also for PV domains, this option is equivalent to sync_pt.

This option is the default if passthrough hardware is specified in the domain's configuration.

sync_pt

This option means that IOMMU mappings will be synchronized with the domain's P2M table as follows:

For a PV domain, all writable pages assigned to the domain are identity mapped by MFN in the IOMMU page table. Thus a device driver running in the domain may program passthrough hardware for DMA using MFN values (i.e. host/machine frame numbers) looked up in its P2M.

For an HVM/PVH domain, all non-foreign RAM pages present in its P2M will be mapped by GFN in the IOMMU page table. Thus a device driver running in the domain may program passthrough hardware using GFN values (i.e. guest physical frame numbers) without any further translation.

This option is not currently available on Arm.

share_pt

This option is unavailable for a PV domain. For an HVM/PVH domain, this option means that the IOMMU will be programmed to directly reference the domain's P2M table as its page table. From the point of view of a device driver running in the domain this is functionally equivalent to sync_pt but places less load on the hypervisor and so should generally be selected in preference. However, the availability of this option is hardware specific. If xl info reports virt_caps containing iommu_hap_pt_share then this option may be used.

default

The default, which chooses between disabled and enabled according to whether passthrough devices are enabled in the config file.

xend_suspend_evtchn_compat=BOOLEAN

If this option is true the xenstore path for the domain's suspend event channel will not be created. Instead the old xend behaviour of making the whole xenstore device sub-tree writable by the domain will be re-instated.

The existence of the suspend event channel path can cause problems with certain PV drivers running in the guest (e.g. old Red Hat PV drivers for Windows).

If this option is not specified then it will default to false.

vmtrace_buf_kb=KBYTES

Specifies the size of vmtrace buffer that would be allocated for each vCPU belonging to this domain. Disabled (i.e. vmtrace_buf_kb=0) by default.

NOTE: Acceptable values are platform specific. For Intel Processor Trace, this value must be a power of 2 between 4k and 16M.

vpmu=BOOLEAN

Currently ARM only.

Specifies whether to enable the access to PMU registers by disabling the PMU traps.

The PMU registers are not virtualized and the physical registers are directly accessible when this parameter is enabled. There is no interrupt support and Xen will not save/restore the register values on context switches.

vPMU, by design and purpose, exposes system level performance information to the guest. Only to be used by sufficiently privileged domains. This feature is currently in experimental state.

If this option is not specified then it will default to false.

Devices

The following options define the paravirtual, emulated and physical devices which the guest will contain.

disk=[ "DISK_SPEC_STRING", "DISK_SPEC_STRING", ...]

Specifies the disks (both emulated disks and Xen virtual block devices) which are to be provided to the guest, and what objects on the host they should map to. See xl-disk-configuration(5) for more details.

vif=[ "NET_SPEC_STRING", "NET_SPEC_STRING", ...]

Specifies the network interfaces (both emulated network adapters, and Xen virtual interfaces) which are to be provided to the guest. See xl-network-configuration(5) for more details.

vtpm=[ "VTPM_SPEC_STRING", "VTPM_SPEC_STRING", ...]

Specifies the Virtual Trusted Platform module to be provided to the guest. See xen-vtpm(7) for more details.

Each VTPM_SPEC_STRING is a comma-separated list of KEY=VALUE settings from the following list:

backend=domain-id

Specifies the backend domain name or id. This value is required! If this domain is a guest, the backend should be set to the vTPM domain name. If this domain is a vTPM, the backend should be set to the vTPM manager domain name.

uuid=UUID

Specifies the UUID of this vTPM device. The UUID is used to uniquely identify the vTPM device. You can create one using the uuidgen(1) program on unix systems. If left unspecified, a new UUID will be randomly generated every time the domain boots. If this is a vTPM domain, you should specify a value. The value is optional if this is a guest domain.

p9=[ "9PFS_SPEC_STRING", "9PFS_SPEC_STRING", ...]

Creates a Xen 9pfs connection to share a filesystem from the backend to the frontend.

Each 9PFS_SPEC_STRING is a comma-separated list of KEY=VALUE settings, from the following list:

type=TYPE

The backendtype for the PV device. Supported values are qemu and xen_9pfsd. The default is qemu.

tag=STRING

9pfs tag to identify the filesystem share. The tag is needed on the guest side to mount it. For the backendtype of xen_9pfsd the tag defaults to "Xen".

security_model="none"

Only "none" is supported today, which means that the files are stored using the same credentials as those they have in the guest (no user ownership squash or remap).

path=STRING

Filesystem path on the backend to export. For the backendtype of xen_9pfsd the path defaults to "/var/log/xen/guests/<guest-name>".

backend=domain-id

Specify the backend domain name or id, defaults to dom0.

max-files=NUMBER

Specify the maximum number of files below path. A value of 0 (which is the default) doesn't limit the number of files. Only valid for type=xen_9pfsd.

max-open-files=NUMBER

Specify the maximum number of concurrently opened files below path. Multiple opens of the same file are counted individually. Only valid for type=xen_9pfsd, which has a default of max-open-files=5.

max-space=NUMBER

Specify the maximum used disk space in MiB below path. A value of 0 (which is the default) doesn't limit the usable disk space. Only valid for type=xen_9pfsd.

auto-delete=BOOLEAN

When set the backend will delete the oldest file which is currently not opened by the guest in case the disk space limit set via max-space or the file limit set via max-files is being reached. Only valid for type=xen_9pfsd.

pvcalls=[ "backend=domain-id", ... ]

Creates a Xen pvcalls connection to handle pvcalls requests from frontend to backend. It can be used as an alternative networking model. For more information about the protocol, see https://xenbits.xenproject.org/docs/unstable/misc/pvcalls.html.

vfb=[ "VFB_SPEC_STRING", "VFB_SPEC_STRING", ...]

Specifies the paravirtual framebuffer devices which should be supplied to the domain.

This option does not control the emulated graphics card presented to an HVM guest. See Emulated VGA Graphics Device below for how to configure the emulated device. If Emulated VGA Graphics Device options are used in a PV guest configuration, xl will pick up vnc, vnclisten, vncpasswd, vncdisplay, vncunused, sdl, opengl and keymap to construct the paravirtual framebuffer device for the guest.

Each VFB_SPEC_STRING is a comma-separated list of KEY=VALUE settings, from the following list:

vnc=BOOLEAN

Allow access to the display via the VNC protocol. This enables the other VNC-related settings. Default is 1 (enabled).

vnclisten=ADDRESS[:DISPLAYNUM]

Specifies the IP address, and optionally the VNC display number, to use.

Note: if you specify the display number here, you should not use the vncdisplay option.

vncdisplay=DISPLAYNUM

Specifies the VNC display number to use. The actual TCP port number will be DISPLAYNUM+5900.

Note: you should not use this option if you set the DISPLAYNUM in the vnclisten option.

vncunused=BOOLEAN

Requests that the VNC display setup searches for a free TCP port to use. The actual display used can be accessed with xl vncviewer.

vncpasswd=PASSWORD

Specifies the password for the VNC server. If the password is set to an empty string, authentication on the VNC server will be disabled, allowing any user to connect.

sdl=BOOLEAN

Specifies that the display should be presented via an X window (using Simple DirectMedia Layer). The default is 0 (not enabled).

display=DISPLAY

Specifies the X Window display that should be used when the sdl option is used.

xauthority=XAUTHORITY

Specifies the path to the X authority file that should be used to connect to the X server when the sdl option is used.

opengl=BOOLEAN

Enable OpenGL acceleration of the SDL display. Only effects machines using device_model_version="qemu-xen-traditional" and only if the device-model was compiled with OpenGL support. The default is 0 (disabled).

keymap=LANG

Configure the keymap to use for the keyboard associated with this display. If the input method does not easily support raw keycodes (e.g. this is often the case when using VNC) then this allows us to correctly map the input keys into keycodes seen by the guest. The specific values which are accepted are defined by the version of the device-model which you are using. See Keymaps below or consult the qemu(1) manpage. The default is en-us.

channel=[ "CHANNEL_SPEC_STRING", "CHANNEL_SPEC_STRING", ...]

Specifies the virtual channels to be provided to the guest. A channel is a low-bandwidth, bidirectional byte stream, which resembles a serial link. Typical uses for channels include transmitting VM configuration after boot and signalling to in-guest agents. Please see xen-pv-channel(7) for more details.

Each CHANNEL_SPEC_STRING is a comma-separated list of KEY=VALUE settings. Leading and trailing whitespace is ignored in both KEY and VALUE. Neither KEY nor VALUE may contain ',', '=' or '"'. Defined values are:

backend=domain-id

Specifies the backend domain name or id. This parameter is optional. If this parameter is omitted then the toolstack domain will be assumed.

name=NAME

Specifies the name for this device. This parameter is mandatory! This should be a well-known name for a specific application (e.g. guest agent) and should be used by the frontend to connect the application to the right channel device. There is no formal registry of channel names, so application authors are encouraged to make their names unique by including the domain name and a version number in the string (e.g. org.mydomain.guestagent.1).

connection=CONNECTION

Specifies how the backend will be implemented. The following options are available:

SOCKET

The backend will bind a Unix domain socket (at the path given by path=PATH), listen for and accept connections. The backend will proxy data between the channel and the connected socket.

PTY

The backend will create a pty and proxy data between the channel and the master device. The command xl channel-list can be used to discover the assigned slave device.

rdm="RDM_RESERVATION_STRING"

HVM/x86 only! Specifies information about Reserved Device Memory (RDM), which is necessary to enable robust device passthrough. One example of RDM is reporting through the ACPI Reserved Memory Region Reporting (RMRR) structure on the x86 platform.

RDM_RESERVATION_STRING is a comma separated list of KEY=VALUE settings, from the following list:

strategy=STRING

Currently there is only one valid type, and that is "host".

host

If set to "host" it means all reserved device memory on this platform should be checked to reserve regions in this VM's address space. This global RDM parameter allows the user to specify reserved regions explicitly, and using "host" includes all reserved regions reported on this platform, which is useful when doing hotplug.

By default this isn't set so we don't check all RDMs. Instead, we just check the RDM specific to a given device if we're assigning this kind of a device.

Note: this option is not recommended unless you can make sure that no conflicts exist.

For example, you're trying to set "memory = 2800" to allocate memory to one given VM but the platform owns two RDM regions like:

Device A [sbdf_A]: RMRR region_A: base_addr ac6d3000 end_address ac6e6fff

Device B [sbdf_B]: RMRR region_B: base_addr ad800000 end_address afffffff

In this conflict case,

#1. If strategy is set to "host", for example:

rdm = "strategy=host,policy=strict" or rdm = "strategy=host,policy=relaxed"

it means all conflicts will be handled according to the policy introduced by policy as described below.

#2. If strategy is not set at all, but

pci = [ 'sbdf_A, rdm_policy=xxxxx' ]

it means only one conflict of region_A will be handled according to the policy introduced by rdm_policy=STRING as described inside pci options.

policy=STRING

Specifies how to deal with conflicts when reserving already reserved device memory in the guest address space.

strict

Specifies that in case of an unresolved conflict the VM can't be created, or the associated device can't be attached in the case of hotplug.

relaxed

Specifies that in case of an unresolved conflict the VM is allowed to be created but may cause the VM to crash if a pass-through device accesses RDM. For example, the Windows IGD GFX driver always accesses RDM regions so it leads to a VM crash.

Note: this may be overridden by the rdm_policy option in the pci device configuration.

usbctrl=[ "USBCTRL_SPEC_STRING", "USBCTRL_SPEC_STRING", ...]

Specifies the USB controllers created for this guest.

Each USBCTRL_SPEC_STRING is a comma-separated list of KEY=VALUE settings, from the following list:

type=TYPE

Specifies the usb controller type.

pv

Specifies a kernel based PVUSB backend.

qusb

Specifies a QEMU based PVUSB backend.

devicemodel

Specifies a USB controller emulated by QEMU. It will show up as a PCI-device in the guest.

auto

Determines whether a kernel based backend is installed. If this is the case, pv is used, otherwise qusb will be used. For HVM domains devicemodel will be selected.

This option is the default.

version=VERSION

Specifies the usb controller version. Possible values include 1 (USB1.1), 2 (USB2.0) and 3 (USB3.0). Default is 2 (USB2.0). Value 3 (USB3.0) is available for the devicemodel type only.

ports=PORTS

Specifies the total number of ports of the usb controller. The maximum number is 31. The default is 8. With the type devicemodel the number of ports is more limited: a USB1.1 controller always has 2 ports, a USB2.0 controller always has 6 ports and a USB3.0 controller can have up to 15 ports.

USB controller ids start from 0. In line with the USB specification, however, ports on a controller start from 1.

EXAMPLE

    usbctrl=["version=1,ports=4", "version=2,ports=8"]

    The first controller is USB1.1 and has:

    controller id = 0, and ports 1,2,3,4.

    The second controller is USB2.0 and has:

    controller id = 1, and ports 1,2,3,4,5,6,7,8.

usbdev=[ "USBDEV_SPEC_STRING", "USBDEV_SPEC_STRING", ...]

Specifies the USB devices to be attached to the guest at boot.

Each USBDEV_SPEC_STRING is a comma-separated list of KEY=VALUE settings, from the following list:

type=hostdev

Specifies USB device type. Currently only "hostdev" is supported.

hostbus=busnum

Specifies busnum of the USB device from the host perspective.

hostaddr=devnum

Specifies devnum of the USB device from the host perspective.

controller=CONTROLLER

Specifies the USB controller id, to which controller the USB device is attached.

If no controller is specified, an available controller:port combination will be used. If there are no available controller:port combinations, a new controller will be created.

port=PORT

Specifies the USB port to which the USB device is attached. The port option is valid only when the controller option is specified.

pci=[ "PCI_SPEC_STRING", "PCI_SPEC_STRING", ...]

Specifies the host PCI devices to passthrough to this guest. See xl-pci-configuration(5) for more details.

pci_permissive=BOOLEAN

Changes the default value of permissive for all PCI devices passed through to this VM. See permissive above.

pci_msitranslate=BOOLEAN

Changes the default value of msitranslate for all PCI devices passed through to this VM. See msitranslate above.

pci_seize=BOOLEAN

Changes the default value of seize for all PCI devices passed through to this VM. See seize above.

pci_power_mgmt=BOOLEAN

(HVM only) Changes the default value of power_mgmt for all PCI devices passed through to this VM. See power_mgmt above.

gfx_passthru=BOOLEAN|"STRING"

Enable graphics device PCI passthrough. This option makes an assigned PCI graphics card become the primary graphics card in the VM. The QEMU emulated graphics adapter is disabled and the VNC console for the VM will not have any graphics output. All graphics output, including boot time QEMU BIOS messages from the VM, will go to the physical outputs of the passed through physical graphics card.

The graphics card PCI device to pass through is chosen with the pci option, in exactly the same way a normal Xen PCI device passthrough/assignment is done. Note that gfx_passthru does not do any kind of sharing of the GPU, so you can assign the GPU to only one single VM at a time.

gfx_passthru also enables various legacy VGA memory ranges, BARs, MMIOs, and ioports to be passed through to the VM, since those are required for correct operation of things like VGA BIOS, text mode, VBE, etc.

Enabling the gfx_passthru option also copies the physical graphics card video BIOS to the guest memory, and executes the VBIOS in the guest to initialize the graphics card.

Most graphics adapters require vendor specific tweaks for properly working graphics passthrough. See the XenVGAPassthroughTestedAdapters https://wiki.xenproject.org/wiki/XenVGAPassthroughTestedAdapters wiki page for graphics cards currently supported by gfx_passthru.

gfx_passthru is currently supported both with the qemu-xen-traditional device-model and upstream qemu-xen device-model.

When given as a boolean the gfx_passthru option either disables graphics card passthrough or enables autodetection.

When given as a string the gfx_passthru option describes the type of device to enable. Note that this behavior is only supported with the upstream qemu-xen device-model. With qemu-xen-traditional IGD (Intel Graphics Device) is always assumed and options other than autodetect or explicit IGD will result in an error.

Currently, valid values for the option are:

0

Disables graphics device PCI passthrough.

1, "default"

Enables graphics device PCI passthrough and autodetects the type of device which is being used.

"igd"

Enables graphics device PCI passthrough but forcing the type of device to Intel Graphics Device.

Note that some graphics cards (AMD/ATI cards, for example) do not necessarily require the gfx_passthru option, so you can use the normal Xen PCI passthrough to assign the graphics card as a secondary graphics card to the VM. The QEMU-emulated graphics card remains the primary graphics card, and VNC output is available from the QEMU-emulated primary adapter.

More information about the Xen gfx_passthru feature is available on the XenVGAPassthrough https://wiki.xenproject.org/wiki/XenVGAPassthrough wiki page.

rdm_mem_boundary=MBYTES

Number of megabytes to set for a boundary when checking for RDM conflicts.

When RDM conflicts with RAM, RDM is probably scattered over the whole RAM space. Having multiple RDM entries would worsen this and lead to a complicated memory layout. Here we're trying to figure out a simple solution to avoid breaking the existing layout. When a conflict occurs,

    #1. Above a predefined boundary
        - move lowmem_end below the reserved region to solve the conflict;

    #2. Below a predefined boundary
        - Check if the policy is strict or relaxed.
        A "strict" policy leads to a fail in libxl.
        Note that when both policies are specified on a given region,
        "strict" is always preferred.
        The "relaxed" policy issues a warning message and also masks this
        entry INVALID to indicate we shouldn't expose this entry to
        hvmloader.

The default value is 2048.

dtdev=[ "DTDEV_PATH", "DTDEV_PATH", ...]

Specifies the host device tree nodes to passt hrough to this guest. Each DTDEV_PATH is an absolute path in the device tree.

ioports=[ "IOPORT_RANGE", "IOPORT_RANGE", ...]

Allow the guest to access specific legacy I/O ports. Each IOPORT_RANGE is given in hexadecimal format and may either be a range, e.g. 2f8-2ff (inclusive), or a single I/O port, e.g. 2f8.

It is recommended to only use this option for trusted VMs under administrator's control.

iomem=[ "IOMEM_START,NUM_PAGES[@GFN]", "IOMEM_START,NUM_PAGES[@GFN]", ...]

Allow auto-translated domains to access specific hardware I/O memory pages.

IOMEM_START is a physical page number. NUM_PAGES is the number of pages, beginning with START_PAGE, to allow access to. GFN specifies the guest frame number where the mapping will start in the guest's address space. If GFN is not specified, the mapping will be performed using IOMEM_START as a start in the guest's address space, therefore performing a 1:1 mapping by default. All of these values must be given in hexadecimal format.

Note that the IOMMU won't be updated with the mappings specified with this option. This option therefore should not be used to pass through any IOMMU-protected devices.

It is recommended to only use this option for trusted VMs under administrator's control.

irqs=[ NUMBER, NUMBER, ...]

Allow a guest to access specific physical IRQs.

It is recommended to only use this option for trusted VMs under administrator's control.

If vuart console is enabled then irq 32 is reserved for it. See "vuart="uart"" to know how to enable vuart console.

max_event_channels=N

Limit the guest to using at most N event channels (PV interrupts). Guests use hypervisor resources for each event channel they use.

The default of 1023 should be sufficient for typical guests. The maximum value depends on what the guest supports. Guests supporting the FIFO-based event channel ABI support up to 131,071 event channels. Other guests are limited to 4095 (64-bit x86 and ARM) or 1023 (32-bit x86).

vdispl=[ "VDISPL_SPEC_STRING", "VDISPL_SPEC_STRING", ...]

Specifies the virtual display devices to be provided to the guest.

Each VDISPL_SPEC_STRING is a comma-separated list of KEY=VALUE settings, from the following list:

backend=DOMAIN

Specifies the backend domain name or id. If not specified Domain-0 is used.

be-alloc=BOOLEAN

Indicates if backend can be a buffer provider/allocator for this domain. See display protocol for details.

connectors=CONNECTORS

Specifies virtual connectors for the device in following format <id>:<W>x<H>;<id>:<W>x<H>... where:

id

String connector unique id. Space, comma symbols are not allowed.

W

Connector width in pixels.

H

Connector height in pixels.

EXAMPLE

    connectors=id0:1920x1080;id1:800x600;id2:640x480

dm_restrict=BOOLEAN

Restrict the device model after startup, to limit the consequencese of security vulnerabilities in qemu.

See docs/features/qemu-depriv.pandoc for more information on Linux and QEMU version requirements, device model user setup, and current limitations.

This feature is a technology preview. See SUPPORT.md for a security support statement.

device_model_user=USERNAME

When running dm_restrict, run the device model as this user.

NOTE: Each domain MUST have a SEPARATE username.

See docs/features/qemu-depriv.pandoc for more information.

vsnd=[ VCARD_SPEC, VCARD_SPEC, ... ]

Specifies the virtual sound cards to be provided to the guest. Each VCARD_SPEC is a list, which has a form of "[VSND_ITEM_SPEC, VSND_ITEM_SPEC, ... ]" (without the quotes). The virtual sound card has hierarchical structure. Every card has a set of PCM devices and streams, each could be individually configured.

VSND_ITEM_SPEC describes individual item parameters. VSND_ITEM_SPEC is a string of comma separated item parameters headed by item identifier. Each item parameter is KEY=VALUE pair:

Identifier shall be one of following values: "CARD", "PCM", "STREAM". The child item treated as belonging to the previously defined parent item.

All parameters are optional.

There are group of parameters which are common for all items. This group can be defined at higher level of the hierarchy and be fully or partially re-used by the underlying layers. These parameters are:

E.g. one can define these values for the whole card, device or stream. Every underlying layer in turn can re-define some or all of them to better fit its needs. For example, card may define number of channels to be in [1; 8] range, and some particular stream may be limited to [1; 2] only. The rule is that the underlying layer must be a subset of the upper layer range.

COMMON parameters:

CARD specification:

PCM specification:

STREAM specification:

EXAMPLE:

    vsnd = [
        ['CARD, short-name=Main, sample-formats=s16_le;s8;u32_be',
            'PCM, name=Main',
                'STREAM, id=0, type=p',
                'STREAM, id=1, type=c, channels-max=2'
        ],
        ['CARD, short-name=Second',
            'PCM, name=Second, buffer-size=1024',
                'STREAM, id=2, type=p',
                'STREAM, id=3, type=c'
        ]
    ]
vkb=[ "VKB_SPEC_STRING", "VKB_SPEC_STRING", ...]

Specifies the virtual keyboard device to be provided to the guest.

Each VKB_SPEC_STRING is a comma-separated list of KEY=VALUE settings from the following list:

unique-id=STRING

Specifies the unique input device id.

backend=domain-id

Specifies the backend domain name or id.

backend-type=type

Specifies the backend type: qemu - for QEMU backend or linux - for Linux PV domain.

feature-disable-keyboard=BOOLEAN

Indicates if keyboard device is disabled.

feature-disable-pointer=BOOLEAN

Indicates if pointer device is disabled.

feature-abs-pointer=BOOLEAN

Indicates if pointer device can return absolute coordinates.

feature-raw-pointer=BOOLEAN

Indicates if pointer device can return raw (unscaled) absolute coordinates.

feature-multi-touch=BOOLEAN

Indicates if input device supports multi touch.

multi-touch-width=MULTI_TOUCH_WIDTH

Set maximum width for multi touch device.

multi-touch-height=MULTI_TOUCH_HEIGHT

Set maximum height for multi touch device.

multi-touch-num-contacts=MULTI_TOUCH_NUM_CONTACTS

Set maximum contacts number for multi touch device.

width=WIDTH

Set maximum width for pointer device.

height=HEIGHT

Set maximum height for pointer device.

virtio=[ "VIRTIO_DEVICE_STRING", "VIRTIO_DEVICE_STRING", ...]

Specifies the Virtio devices to be provided to the guest.

Each VIRTIO_DEVICE_STRING is a comma-separated list of KEY=VALUE settings from the following list. As a special case, a single comma is allowed in the VALUE of the "type" KEY, where the VALUE is set with "virtio,device<N>".

backend=domain-id

Specifies the backend domain name or id, defaults to dom0.

type=STRING

Specifies the compatible string for the specific Virtio device. The same will be written in the Device Tree compatible property of the Virtio device. For example, "type=virtio,device22" for the I2C device, whose device-tree binding is present here:

https://www.kernel.org/doc/Documentation/devicetree/bindings/i2c/i2c-virtio.yaml

For other generic virtio devices, where we don't need to set special or compatible properties in the Device Tree, the type field must be set to "virtio,device" or "virtio,device<N>", where "N" is the virtio device id in hexadecimal format, without the "0x" prefix and all in lower case, like "virtio,device1a" for the file system device.

transport=STRING

Specifies the transport mechanism for the Virtio device, only "mmio" is supported for now.

grant_usage=BOOLEAN

If this option is true, the Xen grants are always enabled. If this option is false, the Xen grants are always disabled.

If this option is missing, then the default grant setting will be used, i.e. enable grants if backend-domid != 0.

tee="STRING"

Arm only. Set TEE type for the guest. TEE is a Trusted Execution Environment -- separate secure OS found on some platforms. STRING can be one of the:

none

"Don't allow the guest to use TEE if present on the platform. This is the default value.

optee

Allow a guest to access the host OP-TEE OS. Xen will mediate the access to OP-TEE and the resource isolation will be provided directly by OP-TEE. OP-TEE itself may limit the number of guests that can concurrently use it. This requires a virtualization-aware OP-TEE for this to work.

You can refer to OP-TEE documentation for more information about how to enable and configure virtualization support in OP-TEE.

This feature is a technology preview.

ffa

Arm only. Allow a guest to communicate via FF-A with Secure Partitions (SP), default false.

Currently only a small subset of the FF-A specification is supported. Just enough to communicate with OP-TEE. In general only direct messaging and sharing memory with one SP. More advanced use cases where memory might be shared or donated to multiple SPs are not supported.

See https://developer.arm.com/documentation/den0077/latest for more information about FF-A.

This feature is a technology preview.

Paravirtualised (PV) Guest Specific Options

The following options apply only to Paravirtual (PV) guests.

bootloader="PROGRAM"

Run PROGRAM to find the kernel image and ramdisk to use. Normally PROGRAM would be pygrub, which is an emulation of grub/grub2/syslinux. Either kernel or bootloader must be specified for PV guests.

bootloader_args=[ "ARG", "ARG", ...]

Append ARGs to the arguments to the bootloader program. Alternatively if the argument is a simple string then it will be split into words at whitespace (this second option is deprecated).

bootloader_restrict=BOOLEAN

Attempt to restrict the bootloader after startup, to limit the consequences of security vulnerabilities due to parsing guest owned image files.

See docs/features/qemu-deprivilege.pandoc for more information on how to setup the unprivileged users.

Note that running the bootloader in restricted mode also implies using non-interactive mode, and the disk image must be readable by the restricted user.

bootloader_user=USERNAME

When using bootloader_restrict, run the bootloader as this user. If not set the default QEMU restrict users will be used.

NOTE: Each domain MUST have a SEPARATE username.

See docs/features/qemu-deprivilege.pandoc for more information.

e820_host=BOOLEAN

Selects whether to expose the host e820 (memory map) to the guest via the virtual e820. When this option is false (0) the guest pseudo-physical address space consists of a single contiguous RAM region. When this option is specified the virtual e820 instead reflects the host e820 and contains the same PCI holes. The total amount of RAM represented by the memory map is always the same, this option configures only how it is laid out.

Exposing the host e820 to the guest gives the guest kernel the opportunity to set aside the required part of its pseudo-physical address space in order to provide address space to map passedthrough PCI devices. It is guest Operating System dependent whether this option is required, specifically it is required when using a mainline Linux ("pvops") kernel. This option defaults to true (1) if any PCI passthrough devices are configured and false (0) otherwise. If you do not configure any passthrough devices at domain creation time but expect to hotplug devices later then you should set this option. Conversely if your particular guest kernel does not require this behaviour then it is safe to allow this to be enabled but you may wish to disable it anyway.

Fully-virtualised (HVM) Guest Specific Options

The following options apply only to Fully-virtualised (HVM) guests.

Boot Device

boot="STRING"

Specifies the emulated virtual device to boot from.

Possible values are:

c

Hard disk.

d

CD-ROM.

n

Network / PXE.

Note: multiple options can be given and will be attempted in the order they are given, e.g. to boot from CD-ROM but fall back to the hard disk you can specify it as dc.

The default is cd, meaning try booting from the hard disk first, but fall back to the CD-ROM.

Emulated disk controller type

hdtype=STRING

Specifies the hard disk type.

Possible values are:

ide

If thise mode is specified xl adds an emulated IDE controller, which is suitable even for older operation systems.

ahci

If this mode is specified, xl adds an ich9 disk controller in AHCI mode and uses it with upstream QEMU to emulate disks instead of IDE. It decreases boot time but may not be supported by default in older operating systems, e.g. Windows XP.

The default is ide.

Paging

The following options control the mechanisms used to virtualise guest memory. The defaults are selected to give the best results for the common cases so you should normally leave these options unspecified.

hap=BOOLEAN

Turns "hardware assisted paging" (the use of the hardware nested page table feature) on or off. This feature is called EPT (Extended Page Tables) by Intel and NPT (Nested Page Tables) or RVI (Rapid Virtualisation Indexing) by AMD. If turned off, Xen will run the guest in "shadow page table" mode where the guest's page table updates and/or TLB flushes etc. will be emulated. Use of HAP is the default when available.

oos=BOOLEAN

Turns "out of sync pagetables" on or off. When running in shadow page table mode, the guest's page table updates may be deferred as specified in the Intel/AMD architecture manuals. However, this may expose unexpected bugs in the guest, or find bugs in Xen, so it is possible to disable this feature. Use of out of sync page tables, when Xen thinks it appropriate, is the default.

shadow_memory=MBYTES

Number of megabytes to set aside for shadowing guest pagetable pages (effectively acting as a cache of translated pages) or to use for HAP state. By default this is 1MB per guest vCPU plus 8KB per MB of guest RAM. You should not normally need to adjust this value. However, if you are not using hardware assisted paging (i.e. you are using shadow mode) and your guest workload consists of a very large number of similar processes then increasing this value may improve performance.

Processor and Platform Features

The following options allow various processor and platform level features to be hidden or exposed from the guest's point of view. This can be useful when running older guest Operating Systems which may misbehave when faced with more modern features. In general, you should accept the defaults for these options wherever possible.

bios="STRING"

Select the virtual firmware that is exposed to the guest. By default, a guess is made based on the device model, but sometimes it may be useful to request a different one, like UEFI.

rombios

Loads ROMBIOS, a 16-bit x86 compatible BIOS. This is used by default when device_model_version=qemu-xen-traditional. This is the only BIOS option supported when device_model_version=qemu-xen-traditional. This is the BIOS used by all previous Xen versions.

seabios

Loads SeaBIOS, a 16-bit x86 compatible BIOS. This is used by default with device_model_version=qemu-xen.

ovmf

Loads OVMF, a standard UEFI firmware by Tianocore project. Requires device_model_version=qemu-xen.

bios_path_override="PATH"

Override the path to the blob to be used as BIOS. The blob provided here MUST be consistent with the bios= which you have specified. You should not normally need to specify this option.

This option does not have any effect if using bios="rombios" or device_model_version="qemu-xen-traditional".

pae=BOOLEAN

Hide or expose the IA32 Physical Address Extensions. These extensions make it possible for a 32 bit guest Operating System to access more than 4GB of RAM. Enabling PAE also enabled other features such as NX. PAE is required if you wish to run a 64-bit guest Operating System. In general, you should leave this enabled and allow the guest Operating System to choose whether or not to use PAE. (X86 only)

acpi=BOOLEAN

Expose ACPI (Advanced Configuration and Power Interface) tables from the virtual firmware to the guest Operating System. ACPI is required by most modern guest Operating Systems. This option is enabled by default and usually you should omit it. However, it may be necessary to disable ACPI for compatibility with some guest Operating Systems. This option is true for x86 while it's false for ARM by default.

acpi_s3=BOOLEAN

Include the S3 (suspend-to-ram) power state in the virtual firmware ACPI table. True (1) by default.

acpi_s4=BOOLEAN

Include S4 (suspend-to-disk) power state in the virtual firmware ACPI table. True (1) by default.

acpi_laptop_slate=BOOLEAN

Include the Windows laptop/slate mode switch device in the virtual firmware ACPI table. False (0) by default.

apic=BOOLEAN

(x86 only) Include information regarding APIC (Advanced Programmable Interrupt Controller) in the firmware/BIOS tables on a single processor guest. This causes the MP (multiprocessor) and PIR (PCI Interrupt Routing) tables to be exported by the virtual firmware. This option has no effect on a guest with multiple virtual CPUs as they must always include these tables. This option is enabled by default and you should usually omit it but it may be necessary to disable these firmware tables when using certain older guest Operating Systems. These tables have been superseded by newer constructs within the ACPI tables.

nx=BOOLEAN

(x86 only) Hides or exposes the No-eXecute capability. This allows a guest Operating System to map pages in such a way that they cannot be executed which can enhance security. This options requires that PAE also be enabled.

hpet=BOOLEAN

(x86 only) Enables or disables HPET (High Precision Event Timer). This option is enabled by default and you should usually omit it. It may be necessary to disable the HPET in order to improve compatibility with guest Operating Systems.

altp2m="MODE"

(x86 only) Specifies the access mode to the alternate-p2m capability. Alternate-p2m allows a guest to manage multiple p2m guest physical "memory views" (as opposed to a single p2m). You may want this option if you want to access-control/isolate access to specific guest physical memory pages accessed by the guest, e.g. for domain memory introspection or for isolation/access-control of memory between components within a single guest domain. This option is disabled by default.

The valid values are as follows:

disabled

Altp2m is disabled for the domain (default).

mixed

The mixed mode allows access to the altp2m interface for both in-guest and external tools as well.

external

Enables access to the alternate-p2m capability by external privileged tools.

limited

Enables limited access to the alternate-p2m capability, ie. giving the guest access only to enable/disable the VMFUNC and #VE features.

altp2mhvm=BOOLEAN

Enables or disables HVM guest access to alternate-p2m capability. Alternate-p2m allows a guest to manage multiple p2m guest physical "memory views" (as opposed to a single p2m). This option is disabled by default and is available only to HVM domains. You may want this option if you want to access-control/isolate access to specific guest physical memory pages accessed by the guest, e.g. for HVM domain memory introspection or for isolation/access-control of memory between components within a single guest HVM domain. This option is deprecated, use the option "altp2m" instead.

Note: While the option "altp2mhvm" is deprecated, legacy applications for x86 systems will continue to work using it.

nestedhvm=BOOLEAN

Enable or disables guest access to hardware virtualisation features, e.g. it allows a guest Operating System to also function as a hypervisor. You may want this option if you want to run another hypervisor (including another copy of Xen) within a Xen guest or to support a guest Operating System which uses hardware virtualisation extensions (e.g. Windows XP compatibility mode on more modern Windows OS). This option is disabled by default.

cpuid="LIBXL_STRING" or cpuid=[ "XEND_STRING", "XEND_STRING" ]

Configure the value returned when a guest executes the CPUID instruction. Two versions of config syntax are recognized: libxl and xend.

Both formats use a common notation for specifying a single feature bit. Possible values are: '1' -> force the corresponding bit to 1 '0' -> force to 0 'x' -> Get a safe value (pass through and mask with the default policy) 'k' -> pass through the host bit value (at boot only - value preserved on migrate) 's' -> legacy alias for 'k'

Libxl format:

Xend format:

Note: when specifying cpuid for hypervisor leaves (0x4000xxxx major group) only the lowest 8 bits of leaf's 0x4000xx00 EAX register are processed, the rest are ignored (these 8 bits signify maximum number of hypervisor leaves).

More info about the CPUID instruction can be found in the processor manuals, and on Wikipedia: https://en.wikipedia.org/wiki/CPUID

acpi_firmware="STRING"

Specifies a path to a file that contains extra ACPI firmware tables to pass into a guest. The file can contain several tables in their binary AML form concatenated together. Each table self describes its length so no additional information is needed. These tables will be added to the ACPI table set in the guest. Note that existing tables cannot be overridden by this feature. For example, this cannot be used to override tables like DSDT, FADT, etc.

smbios_firmware="STRING"

Specifies a path to a file that contains extra SMBIOS firmware structures to pass into a guest. The file can contain a set of DMTF predefined structures which will override the internal defaults. Not all predefined structures can be overridden, only the following types: 0, 1, 2, 3, 11, 22, 39. The file can also contain any number of vendor defined SMBIOS structures (type 128 - 255). Since SMBIOS structures do not present their overall size, each entry in the file must be preceded by a 32b integer indicating the size of the following structure.

smbios=[ "SMBIOS_SPEC_STRING", "SMBIOS_SPEC_STRING", ...]

Specifies the SMBIOS values to be provided to the guest. These set or override specific entries in the tables provided to the guest.

Each SMBIOS_SPEC_STRING is a KEY=VALUE string from the following list:

bios_vendor=STRING
bios_version=STRING
system_manufacturer=STRING
system_product_name=STRING
system_version=STRING
system_serial_number=STRING
baseboard_manufacturer=STRING
baseboard_product_name=STRING
baseboard_version=STRING
baseboard_serial_number=STRING
baseboard_asset_tag=STRING
baseboard_location_in_chassis=STRING
enclosure_manufacturer=STRING
enclosure_serial_number=STRING
enclosure_asset_tag=STRING
battery_manufacturer=STRING
battery_device_name=STRING
oem=STRING

oem= can be specified up to 99 times.

ms_vm_genid="OPTION"

Provide a VM generation ID to the guest.

The VM generation ID is a 128-bit random number that a guest may use to determine if the guest has been restored from an earlier snapshot or cloned.

This is required for Microsoft Windows Server 2012 (and later) domain controllers.

Valid options are:

generate

Generate a random VM generation ID every time the domain is created or restored.

none

Do not provide a VM generation ID.

See also "Virtual Machine Generation ID" by Microsoft: https://docs.microsoft.com/en-us/windows/win32/hyperv_v2/virtual-machine-generation-identifier

Guest Virtual Time Controls

tsc_mode="MODE"

(x86 only) Specifies how the TSC (Time Stamp Counter) should be provided to the guest. Specifying this option as a number is deprecated.

Options are:

default

Guest rdtsc/p is executed natively when monotonicity can be guaranteed and emulated otherwise (with frequency scaled if necessary).

If a HVM container in default TSC mode is created on a host that provides constant host TSC, its guest TSC frequency will be the same as the host. If it is later migrated to another host that provide constant host TSC and supports Intel VMX TSC scaling/AMD SVM TSC ratio, its guest TSC frequency will be the same before and after migration, and guest rdtsc/p will be executed natively after migration as well

always_emulate

Guest rdtsc/p is always emulated and the virtual TSC will appear to increment (kernel and user) at a fixed 1GHz rate, regardless of the pCPU HZ rate or power state. Although there is an overhead associated with emulation, this will NOT affect underlying CPU performance.

native

Guest rdtsc/p is always executed natively (no monotonicity/frequency guarantees). Guest rdtsc/p is emulated at native frequency if unsupported by h/w, else executed natively.

native_paravirt

This mode has been removed.

Please see xen-tscmode(7) for more information on this option.

localtime=BOOLEAN

Set the real time clock to local time or to UTC. False (0) by default, i.e. set to UTC.

rtc_timeoffset=SECONDS

Set the real time clock offset in seconds. No offset (0) by default.

vpt_align=BOOLEAN

Specifies that periodic Virtual Platform Timers should be aligned to reduce guest interrupts. Enabling this option can reduce power consumption, especially when a guest uses a high timer interrupt frequency (HZ) values. The default is true (1).

timer_mode="MODE"

Specifies the mode for Virtual Timers. The valid values are as follows:

delay_for_missed_ticks

Delay for missed ticks. Do not advance a vCPU's time beyond the correct delivery time for interrupts that have been missed due to preemption. Deliver missed interrupts when the vCPU is rescheduled and advance the vCPU's virtual time stepwise for each one.

no_delay_for_missed_ticks

No delay for missed ticks. As above, missed interrupts are delivered, but guest time always tracks wallclock (i.e., real) time while doing so. This is the default.

no_missed_ticks_pending

No missed interrupts are held pending. Instead, to ensure ticks are delivered at some non-zero rate, if we detect missed ticks then the internal tick alarm is not disabled if the vCPU is preempted during the next tick period.

one_missed_tick_pending

One missed tick pending. Missed interrupts are collapsed together and delivered as one 'late tick'. Guest time always tracks wallclock (i.e., real) time.

Memory layout

mmio_hole=MBYTES

Specifies the size the MMIO hole below 4GiB will be. Only valid for device_model_version="qemu-xen".

Cannot be smaller than 256. Cannot be larger than 3840.

Known good large value is 3072.

Support for Paravirtualisation of HVM Guests

The following options allow Paravirtualised features (such as devices) to be exposed to the guest Operating System in an HVM guest. Utilising these features requires specific guest support but when available they will result in improved performance.

xen_platform_pci=BOOLEAN

Enable or disable the Xen platform PCI device. The presence of this virtual device enables a guest Operating System (subject to the availability of suitable drivers) to make use of paravirtualisation features such as disk and network devices etc. Enabling these drivers improves performance and is strongly recommended when available. PV drivers are available for various Operating Systems including HVM Linux (out-of-the-box) and Microsoft Windows https://xenproject.org/windows-pv-drivers/.

Setting xen_platform_pci=0 with the default device_model "qemu-xen" requires at least QEMU 1.6.

viridian=[ "GROUP", "GROUP", ...] or viridian=BOOLEAN

The groups of Microsoft Hyper-V (AKA viridian) compatible enlightenments exposed to the guest. The following groups of enlightenments may be specified:

base

This group incorporates the Hypercall MSRs, Virtual processor index MSR, and APIC access MSRs. These enlightenments can improve performance of Windows Vista and Windows Server 2008 onwards and setting this option for such guests is strongly recommended. This group is also a pre-requisite for all others. If it is disabled then it is an error to attempt to enable any other group.

freq

This group incorporates the TSC and APIC frequency MSRs. These enlightenments can improve performance of Windows 7 and Windows Server 2008 R2 onwards.

time_ref_count

This group incorporates Partition Time Reference Counter MSR. This enlightenment can improve performance of Windows 8 and Windows Server 2012 onwards.

reference_tsc

This set incorporates the Partition Reference TSC MSR. This enlightenment can improve performance of Windows 7 and Windows Server 2008 R2 onwards.

hcall_remote_tlb_flush

This set incorporates use of hypercalls for remote TLB flushing. This enlightenment may improve performance of Windows guests running on hosts with higher levels of (physical) CPU contention.

apic_assist

This set incorporates use of the APIC assist page to avoid EOI of the local APIC. This enlightenment may improve performance of guests that make use of per-vCPU event channel upcall vectors. Note that this enlightenment will have no effect if the guest is using APICv posted interrupts.

crash_ctl

This group incorporates the crash control MSRs. These enlightenments allow Windows to write crash information such that it can be logged by Xen.

stimer

This set incorporates the SynIC and synthetic timer MSRs. Windows will use synthetic timers in preference to emulated HPET for a source of ticks and hence enabling this group will ensure that ticks will be consistent with use of an enlightened time source (time_ref_count or reference_tsc).

hcall_ipi

This set incorporates use of a hypercall for interprocessor interrupts. This enlightenment may improve performance of Windows guests with multiple virtual CPUs.

ex_processor_masks

This set enables new hypercall variants taking a variably-sized sparse Virtual Processor Set as an argument, rather than a simple 64-bit mask. Hence this enlightenment must be specified for guests with more than 64 vCPUs if hcall_remote_tlb_flush and/or hcall_ipi are also specified.

no_vp_limit

This group when set indicates to a guest that the hypervisor does not explicitly have any limits on the number of Virtual processors a guest is allowed to bring up. It is strongly recommended to keep this enabled for guests with more than 64 vCPUs.

cpu_hotplug

This set enables dynamic changes to Virtual processor states in Windows guests effectively allowing vCPU hotplug.

defaults

This is a special value that enables the default set of groups, which is currently the base, freq, time_ref_count, apic_assist, crash_ctl, stimer, no_vp_limit and cpu_hotplug groups.

all

This is a special value that enables all available groups.

Groups can be disabled by prefixing the name with '!'. So, for example, to enable all groups except freq, specify:

For details of the enlightenments see the latest version of Microsoft's Hypervisor Top-Level Functional Specification.

The enlightenments should be harmless for other versions of Windows (although they will not give any benefit) and the majority of other non-Windows OSes. However it is known that they are incompatible with some other Operating Systems and in some circumstance can prevent Xen's own paravirtualisation interfaces for HVM guests from being used.

The viridian option can be specified as a boolean. A value of true (1) is equivalent to the list [ "defaults" ], and a value of false (0) is equivalent to an empty list.

hvm_pirq=BOOLEAN

Select whether the guest is allowed to route interrupts from devices (either emulated or passed through) over event channels.

This option is disabled by default.

Emulated VGA Graphics Device

The following options control the features of the emulated graphics device. Many of these options behave similarly to the equivalent key in the VFB_SPEC_STRING for configuring virtual frame buffer devices (see above).

videoram=MBYTES

Sets the amount of RAM which the emulated video card will contain, which in turn limits the resolutions and bit depths which will be available.

When using the qemu-xen-traditional device-model, the default as well as minimum amount of video RAM for stdvga is 8 MB, which is sufficient for e.g. 1600x1200 at 32bpp. For the upstream qemu-xen device-model, the default and minimum is 16 MB.

When using the emulated Cirrus graphics card (vga="cirrus") and the qemu-xen-traditional device-model, the amount of video RAM is fixed at 4 MB, which is sufficient for 1024x768 at 32 bpp. For the upstream qemu-xen device-model, the default and minimum is 8 MB.

For QXL vga, both the default and minimal are 128MB. If videoram is set less than 128MB, an error will be triggered.

stdvga=BOOLEAN

Specifies a standard VGA card with VBE (VESA BIOS Extensions) as the emulated graphics device. If your guest supports VBE 2.0 or later (e.g. Windows XP onwards) then you should enable this. stdvga supports more video ram and bigger resolutions than Cirrus. The default is false (0) which means to emulate a Cirrus Logic GD5446 VGA card. This option is deprecated, use vga="stdvga" instead.

vga="STRING"

Selects the emulated video card. Options are: none, stdvga, cirrus and qxl. The default is cirrus.

In general, QXL should work with the Spice remote display protocol for acceleration, and a QXL driver is necessary in the guest in that case. QXL can also work with the VNC protocol, but it will be like a standard VGA card without acceleration.

vnc=BOOLEAN

Allow access to the display via the VNC protocol. This enables the other VNC-related settings. The default is (1) enabled.

vnclisten="ADDRESS[:DISPLAYNUM]"

Specifies the IP address and, optionally, the VNC display number to use.

vncdisplay=DISPLAYNUM

Specifies the VNC display number to use. The actual TCP port number will be DISPLAYNUM+5900.

vncunused=BOOLEAN

Requests that the VNC display setup searches for a free TCP port to use. The actual display used can be accessed with xl vncviewer.

vncpasswd="PASSWORD"

Specifies the password for the VNC server. If the password is set to an empty string, authentication on the VNC server will be disabled allowing any user to connect.

keymap="LANG"

Configure the keymap to use for the keyboard associated with this display. If the input method does not easily support raw keycodes (e.g. this is often the case when using VNC) then this allows us to correctly map the input keys into keycodes seen by the guest. The specific values which are accepted are defined by the version of the device-model which you are using. See Keymaps below or consult the qemu(1) manpage. The default is en-us.

sdl=BOOLEAN

Specifies that the display should be presented via an X window (using Simple DirectMedia Layer). The default is (0) not enabled.

opengl=BOOLEAN

Enable OpenGL acceleration of the SDL display. Only effects machines using device_model_version="qemu-xen-traditional" and only if the device-model was compiled with OpenGL support. Default is (0) false.

nographic=BOOLEAN

Enable or disable the virtual graphics device. The default is to provide a VGA graphics device but this option can be used to disable it.

Spice Graphics Support

The following options control the features of SPICE.

spice=BOOLEAN

Allow access to the display via the SPICE protocol. This enables the other SPICE-related settings.

spicehost="ADDRESS"

Specifies the interface address to listen on if given, otherwise any interface.

spiceport=NUMBER

Specifies the port to listen on by the SPICE server if SPICE is enabled.

spicetls_port=NUMBER

Specifies the secure port to listen on by the SPICE server if SPICE is enabled. At least one of spiceport or spicetls_port must be given if SPICE is enabled.

Note: the options depending on spicetls_port have not been supported.

spicedisable_ticketing=BOOLEAN

Enable clients to connect without specifying a password. When disabled, spicepasswd must be set. The default is (0) false.

spicepasswd="PASSWORD"

Specify the password which is used by clients for establishing a connection.

spiceagent_mouse=BOOLEAN

Whether SPICE agent is used for client mouse mode. The default is (1) true.

spicevdagent=BOOLEAN

Enables the SPICE vdagent. The SPICE vdagent is an optional component for enhancing user experience and performing guest-oriented management tasks. Its features include: client mouse mode (no need to grab the mouse by the client, no mouse lag), automatic adjustment of screen resolution, copy and paste (text and image) between the client and the guest. It also requires the vdagent service installed on the guest OS to work. The default is (0) disabled.

spice_clipboard_sharing=BOOLEAN

Enables SPICE clipboard sharing (copy/paste). It requires that spicevdagent is enabled. The default is (0) false.

spiceusbredirection=NUMBER

Enables SPICE USB redirection. Creates a NUMBER of USB redirection channels for redirecting up to 4 USB devices from the SPICE client to the guest's QEMU. It requires an USB controller and, if not defined, it will automatically add an USB2.0 controller. The default is (0) disabled.

spice_image_compression="COMPRESSION"

Specifies what image compression is to be used by SPICE (if given), otherwise the QEMU default will be used. Please see the documentation of your QEMU version for more details.

Available options are: auto_glz, auto_lz, quic, glz, lz, off.

spice_streaming_video="VIDEO"

Specifies what streaming video setting is to be used by SPICE (if given), otherwise the QEMU default will be used.

Available options are: filter, all, off.

Miscellaneous Emulated Hardware

serial=[ "DEVICE", "DEVICE", ...]

Redirect virtual serial ports to DEVICEs. Please see the -serial option in the qemu(1) manpage for details of the valid DEVICE options. Default is vc when in graphical mode and stdio if nographic=1 is used.

The form serial=DEVICE is also accepted for backwards compatibility.

soundhw="DEVICE"

Select the virtual sound card to expose to the guest. The valid devices are hda, ac97, es1370, adlib, cs4231a, gus, sb16 if there are available with the device model QEMU. The default is not to export any sound device.

vkb_device=BOOLEAN

Specifies that the HVM guest gets a vkdb. The default is true (1).

usb=BOOLEAN

Enables or disables an emulated USB bus in the guest.

usbversion=NUMBER

Specifies the type of an emulated USB bus in the guest, values 1 for USB1.1, 2 for USB2.0 and 3 for USB3.0. It is available only with an upstream QEMU. Due to implementation limitations this is not compatible with the usb and usbdevice parameters. Default is (0) no USB controller defined.

usbdevice=[ "DEVICE", "DEVICE", ...]

Adds DEVICEs to the emulated USB bus. The USB bus must also be enabled using usb=1. The most common use for this option is usbdevice=['tablet'] which adds a pointer device using absolute coordinates. Such devices function better than relative coordinate devices (such as a standard mouse) since many methods of exporting guest graphics (such as VNC) work better in this mode. Note that this is independent of the actual pointer device you are using on the host/client side.

Host devices can also be passed through in this way, by specifying host:USBID, where USBID is of the form xxxx:yyyy. The USBID can typically be found by using lsusb(1) or usb-devices(1).

If you wish to use the "host:bus.addr" format, remove any leading '0' from the bus and addr. For example, for the USB device on bus 008 dev 002, you should write "host:8.2".

The form usbdevice=DEVICE is also accepted for backwards compatibility.

More valid options can be found in the "usbdevice" section of the QEMU documentation.

vendor_device="VENDOR_DEVICE"

Selects which variant of the QEMU xen-pvdevice should be used for this guest. Valid values are:

none

The xen-pvdevice should be omitted. This is the default.

xenserver

The xenserver variant of the xen-pvdevice (device-id=C000) will be specified, enabling the use of XenServer PV drivers in the guest.

This parameter only takes effect when device_model_version=qemu-xen. See xen-pci-device-reservations(7) for more information.

PVH Guest Specific Options

nestedhvm=BOOLEAN

Enable or disables guest access to hardware virtualisation features, e.g. it allows a guest Operating System to also function as a hypervisor. You may want this option if you want to run another hypervisor (including another copy of Xen) within a Xen guest or to support a guest Operating System which uses hardware virtualisation extensions (e.g. Windows XP compatibility mode on more modern Windows OS).

This option is disabled by default.

bootloader="PROGRAM"

Run PROGRAM to find the kernel image and ramdisk to use. Normally PROGRAM would be pygrub, which is an emulation of grub/grub2/syslinux. Either kernel or bootloader must be specified for PV guests.

bootloader_args=[ "ARG", "ARG", ...]

Append ARGs to the arguments to the bootloader program. Alternatively if the argument is a simple string then it will be split into words at whitespace (this second option is deprecated).

bootloader_restrict=BOOLEAN

Attempt to restrict the bootloader after startup, to limit the consequences of security vulnerabilities due to parsing guest owned image files.

See docs/features/qemu-deprivilege.pandoc for more information on how to setup the unprivileged users.

Note that running the bootloader in restricted mode also implies using non-interactive mode, and the disk image must be readable by the restricted user.

bootloader_user=USERNAME

When using bootloader_restrict, run the bootloader as this user.

NOTE: Each domain MUST have a SEPARATE username.

See docs/features/qemu-deprivilege.pandoc for more information.

timer_mode="MODE"

Specifies the mode for Virtual Timers. The valid values are as follows:

delay_for_missed_ticks

Delay for missed ticks. Do not advance a vCPU's time beyond the correct delivery time for interrupts that have been missed due to preemption. Deliver missed interrupts when the vCPU is rescheduled and advance the vCPU's virtual time stepwise for each one.

no_delay_for_missed_ticks

No delay for missed ticks. As above, missed interrupts are delivered, but guest time always tracks wallclock (i.e., real) time while doing so. This is the default.

no_missed_ticks_pending

No missed interrupts are held pending. Instead, to ensure ticks are delivered at some non-zero rate, if we detect missed ticks then the internal tick alarm is not disabled if the vCPU is preempted during the next tick period.

one_missed_tick_pending

One missed tick pending. Missed interrupts are collapsed together and delivered as one 'late tick'. Guest time always tracks wallclock (i.e., real) time.

Paging

The following options control the mechanisms used to virtualise guest memory. The defaults are selected to give the best results for the common cases so you should normally leave these options unspecified.

hap=BOOLEAN

Turns "hardware assisted paging" (the use of the hardware nested page table feature) on or off. This feature is called EPT (Extended Page Tables) by Intel and NPT (Nested Page Tables) or RVI (Rapid Virtualisation Indexing) by AMD. If turned off, Xen will run the guest in "shadow page table" mode where the guest's page table updates and/or TLB flushes etc. will be emulated. Use of HAP is the default when available.

oos=BOOLEAN

Turns "out of sync pagetables" on or off. When running in shadow page table mode, the guest's page table updates may be deferred as specified in the Intel/AMD architecture manuals. However, this may expose unexpected bugs in the guest, or find bugs in Xen, so it is possible to disable this feature. Use of out of sync page tables, when Xen thinks it appropriate, is the default.

shadow_memory=MBYTES

Number of megabytes to set aside for shadowing guest pagetable pages (effectively acting as a cache of translated pages) or to use for HAP state. By default this is 1MB per guest vCPU plus 8KB per MB of guest RAM. You should not normally need to adjust this value. However, if you are not using hardware assisted paging (i.e. you are using shadow mode) and your guest workload consists of a very large number of similar processes then increasing this value may improve performance.

On Arm, this field is used to determine the size of the guest P2M pages pool, and the default value is the same as x86 HAP mode, plus 512KB to cover the extended regions. Users should adjust this value if bigger P2M pool size is needed.

Device-Model Options

The following options control the selection of the device-model. This is the component which provides emulation of the virtual devices to an HVM guest. For a PV guest a device-model is sometimes used to provide backends for certain PV devices (most usually a virtual framebuffer device).

device_model_version="DEVICE-MODEL"

Selects which variant of the device-model should be used for this guest.

Valid values are:

qemu-xen

Use the device-model merged into the upstream QEMU project. This device-model is the default for Linux dom0.

qemu-xen-traditional

Use the device-model based upon the historical Xen fork of QEMU. This device-model is still the default for NetBSD dom0.

It is recommended to accept the default value for new guests. If you have existing guests then, depending on the nature of the guest Operating System, you may wish to force them to use the device model which they were installed with.

device_model_override="PATH"

Override the path to the binary to be used as the device-model running in toolstack domain. The binary provided here MUST be consistent with the device_model_version which you have specified. You should not normally need to specify this option.

stubdomain_kernel="PATH"

Override the path to the kernel image used as device-model stubdomain. The binary provided here MUST be consistent with the device_model_version which you have specified. In case of qemu-xen-traditional it is expected to be MiniOS-based stubdomain image, in case of qemu-xen it is expected to be Linux-based stubdomain kernel.

stubdomain_cmdline="STRING"

Set the device-model stubdomain kernel command line to STRING.

stubdomain_ramdisk="PATH"

Override the path to the ramdisk image used as device-model stubdomain. The binary provided here is to be used by a kernel pointed by stubdomain_kernel. It is known to be used only by Linux-based stubdomain kernel.

stubdomain_memory=MBYTES

Start the stubdomain with MBYTES megabytes of RAM. Default is 128.

device_model_stubdomain_override=BOOLEAN

Override the use of stubdomain based device-model. Normally this will be automatically selected based upon the other features and options you have selected.

device_model_stubdomain_seclabel="LABEL"

Assign an XSM security label to the device-model stubdomain.

device_model_args=[ "ARG", "ARG", ...]

Pass additional arbitrary options on the device-model command line. Each element in the list is passed as an option to the device-model.

device_model_args_pv=[ "ARG", "ARG", ...]

Pass additional arbitrary options on the device-model command line for a PV device model only. Each element in the list is passed as an option to the device-model.

device_model_args_hvm=[ "ARG", "ARG", ...]

Pass additional arbitrary options on the device-model command line for an HVM device model only. Each element in the list is passed as an option to the device-model.

Keymaps

The keymaps available are defined by the device-model which you are using. Commonly this includes:

        ar  de-ch  es  fo     fr-ca  hu  ja  mk     no  pt-br  sv
        da  en-gb  et  fr     fr-ch  is  lt  nl     pl  ru     th
        de  en-us  fi  fr-be  hr     it  lv  nl-be  pt  sl     tr

The default is en-us.

See qemu(1) for more information.

Architecture Specific options

ARM

gic_version="vN"

Version of the GIC emulated for the guest.

Currently, the following versions are supported:

v2

Emulate a GICv2

v3

Emulate a GICv3. Note that the emulated GIC does not support the GICv2 compatibility mode.

default

Emulate the same version as the native GIC hardware used by the host where the domain was created.

This requires hardware compatibility with the requested version, either natively or via hardware backwards compatibility support.

vuart="uart"

To enable vuart console, user must specify the following option in the VM config file:

vuart = "sbsa_uart"

Currently, only the "sbsa_uart" model is supported for ARM.

sve="vl"

The `sve` parameter enables Arm Scalable Vector Extension (SVE) usage for the guest and sets the maximum SVE vector length, the option is applicable only to AArch64 guests. A value equal to "disabled" disables the feature, this is the default value. Allowed values are "disabled", "128", "256", "384", "512", "640", "768", "896", "1024", "1152", "1280", "1408", "1536", "1664", "1792", "1920", "2048", "hw". Specifying "hw" means that the maximum vector length supported by the platform will be used. Please be aware that if a specific vector length is passed and its value is above the maximum vector length supported by the platform, an error will be raised.

x86

mca_caps=[ "CAP", "CAP", ... ]

(HVM only) Enable MCA capabilities besides default ones enabled by Xen hypervisor for the HVM domain. "CAP" can be one in the following list:

"lmce"

Intel local MCE

default

No MCA capabilities in above list are enabled.

msr_relaxed=BOOLEAN

The "msr_relaxed" boolean is an interim option, and defaults to false.

In Xen 4.15, the default behaviour for unhandled MSRs has been changed, to avoid leaking host data into guests, and to avoid breaking guest logic which uses #GP probing to identify the availability of MSRs.

However, this new stricter behaviour has the possibility to break guests, and a more 4.14-like behaviour can be selected by setting this option.

If using this option is necessary to fix an issue, please report a bug.

SEE ALSO

xl(1)
xl.conf(5)
xlcpupool.cfg(5)
xl-disk-configuration(5)
xl-network-configuration(5)
xen-tscmode(7)

FILES

/etc/xen/NAME.cfg /var/lib/xen/dump/NAME

BUGS

This document may contain items which require further documentation. Patches to improve incomplete items (or any other item) are gratefully received on the xen-devel@lists.xenproject.org mailing list. Please see https://wiki.xenproject.org/wiki/Submitting_Xen_Project_Patches for information on how to submit a patch to Xen.