WSL2-Linux-Kernel/Documentation/gpu/vkms.rst

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.. _vkms:
==========================================
drm/vkms Virtual Kernel Modesetting
==========================================
.. kernel-doc:: drivers/gpu/drm/vkms/vkms_drv.c
:doc: vkms (Virtual Kernel Modesetting)
Setup
=====
The VKMS driver can be setup with the following steps:
To check if VKMS is loaded, run::
lsmod | grep vkms
This should list the VKMS driver. If no output is obtained, then
you need to enable and/or load the VKMS driver.
Ensure that the VKMS driver has been set as a loadable module in your
kernel config file. Do::
make nconfig
Go to `Device Drivers> Graphics support`
Enable `Virtual KMS (EXPERIMENTAL)`
Compile and build the kernel for the changes to get reflected.
Now, to load the driver, use::
sudo modprobe vkms
On running the lsmod command now, the VKMS driver will appear listed.
You can also observe the driver being loaded in the dmesg logs.
The VKMS driver has optional features to simulate different kinds of hardware,
which are exposed as module options. You can use the `modinfo` command
to see the module options for vkms::
modinfo vkms
Module options are helpful when testing, and enabling modules
can be done while loading vkms. For example, to load vkms with cursor enabled,
use::
sudo modprobe vkms enable_cursor=1
To disable the driver, use ::
sudo modprobe -r vkms
Testing With IGT
================
The IGT GPU Tools is a test suite used specifically for debugging and
development of the DRM drivers.
The IGT Tools can be installed from
`here <https://gitlab.freedesktop.org/drm/igt-gpu-tools>`_ .
The tests need to be run without a compositor, so you need to switch to text
only mode. You can do this by::
sudo systemctl isolate multi-user.target
To return to graphical mode, do::
sudo systemctl isolate graphical.target
Once you are in text only mode, you can run tests using the --device switch
or IGT_DEVICE variable to specify the device filter for the driver we want
to test. IGT_DEVICE can also be used with the run-test.sh script to run the
tests for a specific driver::
sudo ./build/tests/<name of test> --device "sys:/sys/devices/platform/vkms"
sudo IGT_DEVICE="sys:/sys/devices/platform/vkms" ./build/tests/<name of test>
sudo IGT_DEVICE="sys:/sys/devices/platform/vkms" ./scripts/run-tests.sh -t <name of test>
For example, to test the functionality of the writeback library,
we can run the kms_writeback test::
sudo ./build/tests/kms_writeback --device "sys:/sys/devices/platform/vkms"
sudo IGT_DEVICE="sys:/sys/devices/platform/vkms" ./build/tests/kms_writeback
sudo IGT_DEVICE="sys:/sys/devices/platform/vkms" ./scripts/run-tests.sh -t kms_writeback
You can also run subtests if you do not want to run the entire test::
sudo ./build/tests/kms_flip --run-subtest basic-plain-flip --device "sys:/sys/devices/platform/vkms"
sudo IGT_DEVICE="sys:/sys/devices/platform/vkms" ./build/tests/kms_flip --run-subtest basic-plain-flip
TODO
====
If you want to do any of the items listed below, please share your interest
with VKMS maintainers.
IGT better support
------------------
Debugging:
- kms_plane: some test cases are failing due to timeout on capturing CRC;
Virtual hardware (vblank-less) mode:
- VKMS already has support for vblanks simulated via hrtimers, which can be
tested with kms_flip test; in some way, we can say that VKMS already mimics
the real hardware vblank. However, we also have virtual hardware that does
not support vblank interrupt and completes page_flip events right away; in
this case, compositor developers may end up creating a busy loop on virtual
hardware. It would be useful to support Virtual Hardware behavior in VKMS
because this can help compositor developers to test their features in
multiple scenarios.
Add Plane Features
------------------
There's lots of plane features we could add support for:
- ARGB format on primary plane: blend the primary plane into background with
translucent alpha.
- Add background color KMS property[Good to get started].
- Full alpha blending on all planes.
- Rotation, scaling.
- Additional buffer formats, especially YUV formats for video like NV12.
Low/high bpp RGB formats would also be interesting.
- Async updates (currently only possible on cursor plane using the legacy
cursor api).
For all of these, we also want to review the igt test coverage and make sure
all relevant igt testcases work on vkms. They are good options for internship
project.
Runtime Configuration
---------------------
We want to be able to reconfigure vkms instance without having to reload the
module. Use/Test-cases:
- Hotplug/hotremove connectors on the fly (to be able to test DP MST handling
of compositors).
- Configure planes/crtcs/connectors (we'd need some code to have more than 1 of
them first).
- Change output configuration: Plug/unplug screens, change EDID, allow changing
the refresh rate.
The currently proposed solution is to expose vkms configuration through
configfs. All existing module options should be supported through configfs
too.
Writeback support
-----------------
- The writeback and CRC capture operations share the use of composer_enabled
boolean to ensure vblanks. Probably, when these operations work together,
composer_enabled needs to refcounting the composer state to proper work.
[Good to get started]
- Add support for cloned writeback outputs and related test cases using a
cloned output in the IGT kms_writeback.
- As a v4l device. This is useful for debugging compositors on special vkms
configurations, so that developers see what's really going on.
Output Features
---------------
- Variable refresh rate/freesync support. This probably needs prime buffer
sharing support, so that we can use vgem fences to simulate rendering in
testing. Also needs support to specify the EDID.
- Add support for link status, so that compositors can validate their runtime
fallbacks when e.g. a Display Port link goes bad.
CRC API Improvements
--------------------
- Optimize CRC computation ``compute_crc()`` and plane blending ``blend()``
Atomic Check using eBPF
-----------------------
Atomic drivers have lots of restrictions which are not exposed to userspace in
any explicit form through e.g. possible property values. Userspace can only
inquiry about these limits through the atomic IOCTL, possibly using the
TEST_ONLY flag. Trying to add configurable code for all these limits, to allow
compositors to be tested against them, would be rather futile exercise. Instead
we could add support for eBPF to validate any kind of atomic state, and
implement a library of different restrictions.
This needs a bunch of features (plane compositing, multiple outputs, ...)
enabled already to make sense.