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'virt' generic virtual platform (``virt``)
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The ``virt`` board is a platform which does not correspond to any
real hardware; it is designed for use in virtual machines.
It is the recommended board type if you simply want to run
a guest such as Linux and do not care about reproducing the
idiosyncrasies and limitations of a particular bit of real-world
hardware.
This is a "versioned" board model, so as well as the ``virt`` machine
type itself (which may have improvements, bugfixes and other minor
changes between QEMU versions) a version is provided that guarantees
to have the same behaviour as that of previous QEMU releases, so
that VM migration will work between QEMU versions. For instance the
``virt-5.0`` machine type will behave like the ``virt`` machine from
the QEMU 5.0 release, and migration should work between ``virt-5.0``
of the 5.0 release and ``virt-5.0`` of the 5.1 release. Migration
is not guaranteed to work between different QEMU releases for
the non-versioned ``virt`` machine type.
Supported devices
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The virt board supports:
- PCI/PCIe devices
- Flash memory
- Either one or two PL011 UARTs for the NonSecure World
- An RTC
- The fw_cfg device that allows a guest to obtain data from QEMU
- A PL061 GPIO controller
- An optional SMMUv3 IOMMU
- hotpluggable DIMMs
- hotpluggable NVDIMMs
- An MSI controller (GICv2M or ITS). GICv2M is selected by default along
with GICv2. ITS is selected by default with GICv3 (>= virt-2.7). Note
that ITS is not modeled in TCG mode.
- 32 virtio-mmio transport devices
- running guests using the KVM accelerator on aarch64 hardware
- large amounts of RAM (at least 255GB, and more if using highmem)
- many CPUs (up to 512 if using a GICv3 and highmem)
- Secure-World-only devices if the CPU has TrustZone:
- A second PL011 UART
- A second PL061 GPIO controller, with GPIO lines for triggering
a system reset or system poweroff
- A secure flash memory
- 16MB of secure RAM
The second NonSecure UART only exists if a backend is configured
explicitly (e.g. with a second -serial command line option) and
TrustZone emulation is not enabled.
Supported guest CPU types:
- ``cortex-a7`` (32-bit)
- ``cortex-a15`` (32-bit; the default)
- ``cortex-a35`` (64-bit)
- ``cortex-a53`` (64-bit)
- ``cortex-a55`` (64-bit)
- ``cortex-a57`` (64-bit)
- ``cortex-a72`` (64-bit)
- ``cortex-a76`` (64-bit)
- ``cortex-a710`` (64-bit)
- ``a64fx`` (64-bit)
- ``host`` (with KVM only)
- ``neoverse-n1`` (64-bit)
- ``neoverse-v1`` (64-bit)
- ``neoverse-n2`` (64-bit)
- ``max`` (same as ``host`` for KVM; best possible emulation with TCG)
Note that the default is ``cortex-a15``, so for an AArch64 guest you must
specify a CPU type.
Also, please note that passing ``max`` CPU (i.e. ``-cpu max``) won't
enable all the CPU features for a given ``virt`` machine. Where a CPU
architectural feature requires support in both the CPU itself and in the
wider system (e.g. the MTE feature), it may not be enabled by default,
but instead requires a machine option to enable it.
For example, MTE support must be enabled with ``-machine virt,mte=on``,
as well as by selecting an MTE-capable CPU (e.g., ``max``) with the
``-cpu`` option.
See the machine-specific options below, or check them for a given machine
by passing the ``help`` suboption, like: ``-machine virt-9.0,help``.
Graphics output is available, but unlike the x86 PC machine types
there is no default display device enabled: you should select one from
the Display devices section of "-device help". The recommended option
is ``virtio-gpu-pci``; this is the only one which will work correctly
with KVM. You may also need to ensure your guest kernel is configured
with support for this; see below.
Machine-specific options
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The following machine-specific options are supported:
secure
Set ``on``/``off`` to enable/disable emulating a guest CPU which implements the
Arm Security Extensions (TrustZone). The default is ``off``.
virtualization
Set ``on``/``off`` to enable/disable emulating a guest CPU which implements the
Arm Virtualization Extensions. The default is ``off``.
mte
Set ``on``/``off`` to enable/disable emulating a guest CPU which implements the
Arm Memory Tagging Extensions. The default is ``off``.
highmem
Set ``on``/``off`` to enable/disable placing devices and RAM in physical
address space above 32 bits. The default is ``on`` for machine types
later than ``virt-2.12`` when the CPU supports an address space
bigger than 32 bits (i.e. 64-bit CPUs, and 32-bit CPUs with the
Large Physical Address Extension (LPAE) feature). If you want to
boot a 32-bit kernel which does not have ``CONFIG_LPAE`` enabled on
a CPU type which implements LPAE, you will need to manually set
this to ``off``; otherwise some devices, such as the PCI controller,
will not be accessible.
compact-highmem
Set ``on``/``off`` to enable/disable the compact layout for high memory regions.
The default is ``on`` for machine types later than ``virt-7.2``.
highmem-redists
Set ``on``/``off`` to enable/disable the high memory region for GICv3 or
GICv4 redistributor. The default is ``on``. Setting this to ``off`` will
limit the maximum number of CPUs when GICv3 or GICv4 is used.
highmem-ecam
Set ``on``/``off`` to enable/disable the high memory region for PCI ECAM.
The default is ``on`` for machine types later than ``virt-3.0``.
highmem-mmio
Set ``on``/``off`` to enable/disable the high memory region for PCI MMIO.
The default is ``on``.
gic-version
Specify the version of the Generic Interrupt Controller (GIC) to provide.
Valid values are:
``2``
GICv2. Note that this limits the number of CPUs to 8.
``3``
GICv3. This allows up to 512 CPUs.
``4``
GICv4. Requires ``virtualization`` to be ``on``; allows up to 317 CPUs.
``host``
Use the same GIC version the host provides, when using KVM
``max``
Use the best GIC version possible (same as host when using KVM;
with TCG this is currently ``3`` if ``virtualization`` is ``off`` and
``4`` if ``virtualization`` is ``on``, but this may change in future)
its
Set ``on``/``off`` to enable/disable ITS instantiation. The default is ``on``
for machine types later than ``virt-2.7``.
iommu
Set the IOMMU type to create for the guest. Valid values are:
``none``
Don't create an IOMMU (the default)
``smmuv3``
Create an SMMUv3
ras
Set ``on``/``off`` to enable/disable reporting host memory errors to a guest
using ACPI and guest external abort exceptions. The default is off.
dtb-randomness
Set ``on``/``off`` to pass random seeds via the guest DTB
rng-seed and kaslr-seed nodes (in both "/chosen" and
"/secure-chosen") to use for features like the random number
generator and address space randomisation. The default is
``on``. You will want to disable it if your trusted boot chain
will verify the DTB it is passed, since this option causes the
DTB to be non-deterministic. It would be the responsibility of
the firmware to come up with a seed and pass it on if it wants to.
dtb-kaslr-seed
A deprecated synonym for dtb-randomness.
Linux guest kernel configuration
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The 'defconfig' for Linux arm and arm64 kernels should include the
right device drivers for virtio and the PCI controller; however some older
kernel versions, especially for 32-bit Arm, did not have everything
enabled by default. If you're not seeing PCI devices that you expect,
then check that your guest config has::
CONFIG_PCI=y
CONFIG_VIRTIO_PCI=y
CONFIG_PCI_HOST_GENERIC=y
If you want to use the ``virtio-gpu-pci`` graphics device you will also
need::
CONFIG_DRM=y
CONFIG_DRM_VIRTIO_GPU=y
Hardware configuration information for bare-metal programming
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The ``virt`` board automatically generates a device tree blob ("dtb")
which it passes to the guest. This provides information about the
addresses, interrupt lines and other configuration of the various devices
in the system. Guest code can rely on and hard-code the following
addresses:
- Flash memory starts at address 0x0000_0000
- RAM starts at 0x4000_0000
All other information about device locations may change between
QEMU versions, so guest code must look in the DTB.
QEMU supports two types of guest image boot for ``virt``, and
the way for the guest code to locate the dtb binary differs:
- For guests using the Linux kernel boot protocol (this means any
non-ELF file passed to the QEMU ``-kernel`` option) the address
of the DTB is passed in a register (``r2`` for 32-bit guests,
or ``x0`` for 64-bit guests)
- For guests booting as "bare-metal" (any other kind of boot),
the DTB is at the start of RAM (0x4000_0000)