This Vulkan layer can be used to do GPU offloading. Typically you want to display an image rendered on a more powerful GPU on a display managed by an internal GPU.
It is basically the same as Primus for OpenGL (https://github.com/amonakov/primus). However it does not wrap the Vulkan API from the application but is directly integrated into Vulkan as a layer (which seems to be the intendend way to implement such logic).
First you need to install primus_vk
:
- On Archlinux there are official packages (for 64-bit games, for 32-bit games).
- On Debian (from bullseye on) you should use
primus-vk-nvidia
(which recommends also the 32-bit variants of those packages for 32-bit games), which already is preconfigured for the Nvidia dedicated + Intel integrated graphics setup. When you have a different setup, you should install justprimus-vk
(which installs only the bareprimus_vk
-library and no graphics drivers), and install the Vulkan drivers, you need manually. - For Gentoo Linux and affiliates distributions, an unoffical overlay branch is developed here. This overlay branch supports multilib abi_x86_32 and abi_x86_64 for Vulkan applications on Intel/Nvidia Optimus configuration.
- For Fedora there are unofficial packages.
- For other distributions you will likely need to manually install
primus_vk
.
To run an application with primus_vk
prefix the command with pvkrun
(which in the easiest case is just ENABLE_PRIMUS_LAYER=1 optirun
). So instead of running path/to/application
, invoke pvkrun path/to/application
instead. You should be able to use pvkrun
for all applications, independently of them using Vulkan, OpenGL or both.
By default primus_vk
chooses a graphics card marked as dedicated
and one not marked as dedicated
.
If that does not fit on your scenario, you need to specify the devices used for rendering and displaying manually.
You can use PRIMUS_VK_DISPLAYID
and PRIMUS_VK_RENDERID
and give them the deviceID
s from optirun env DISPLAY=:8 vulkaninfo
.
That way you can force primus_vk
to work in a variety of different scenarios (e.g. having two dedicated graphics cards and rendering on one, while displaying on the other).
Just as the OpenGL-Primus: Let the application talk to the primary display and transparently map API calls so that the application thinks, it renders using the primary display, however the VkDevice
(and VkImage
s) comes from the rendering GPU.
When the application wants to swap frames, copy the image over to the integrated GPU and display it there.
As far as I can tell VkImage
(and VkMemory
) objects may not be shared beween different physical devices. So there is not really another way than using memcpy
on the images when memmapped into main memory.
Additionally, only images with VK_IMAGE_TILING_OPTIMAL
can be rendered to and presentend and only images with VK_IMAGE_TILING_LINEAR
can be mapped to main memory to be copied. So I see no better way than copying the image 3 times from render target to display. On my machine the memcpy
from an external device was pretty clearly the bottleneck. So it is not really the copying of the image, but the transfer from rendering GPU into main memory.
An idea might be to use VK_EXTERNAL_MEMORY_HANDLE_TYPE_HOST_ALLOCATION_BIT_EXT
to map one device's memory and use that directly on the other device (or import host-allocated memory on both devices). However that is not implemented yet.
This layer requires two working vulkan drivers. The only hardware that I have experience with are Intel Integrated Graphics + Nvidia. However it should theoretically work with any other graphics setup of two vulkan-compatible graphics devices. For the Nvidia graphics card, both the "nonglvd" and the "glvnd" proprietary driver seem to work, however the "nonglvnd"-driver seems to be broken around 430.64
and is removed in newer versions.
To use this layer you will require something similar to bumblebee to poweron/off the dedicated graphics card.
Due to a bug/missing feature in the Vulkan Loader you will need Vulkan/libvulkan >= 1.1.108
. If you have an older system you can try primus_vk version 1.1 which contains an ugly workaround for that issue and is therefore compatible with older Vulkan versions.
This layer works for all the applications I tested it with, but uses a fair share of CPU resorces for copying.
-
The NVIDIA driver always connect to the "default" X-Display to verify that it has the NV-GLX extensions availible. Otherwise the NVIDIA-vulkan-icd driver disables itself. For testing an intermediate solution is to modify the demo application to always use ":0" and set DISPLAY to ":8" to make the NV-Driver happy. However this approach does work on general applications that cannot be modified. So this issue has to be solved in the graphics driver.
-
Currently under Debian unstable the nvidia-icd is registered with a non-absolute library path in
/usr/share/vulkan/icd.d/nvidia_icd.json
. ReplacelibGL.so.1
with/usr/lib/x86_64-linux-gnu/nvidia/libGL.so.1
there to always load the intended Vulkan driver. -
When running an applications with DXVK and wine, wine loads both Vulkan and OpenGL. This creates a problem as:
- Wine loads Vulkan, which loades the integrated GPU's ICD, the Nvidia ICD (contained in Nvidia's libGL.so on my system), Primus-VK and potentially more.
- Wine loads OpenGL, which should be satisfied by OpenGL-Primus. However for whatever reason wine directly gets Nvidia's libGL which fails to provide an OpenGL context for the primary X screen. This needs to be prevented by forcing wine to load Primus' libGL.
Issues 1.,2. and 3. can be worked around by compiling libnv_vulkan_wrapper.so
and registering it instead of nvidia's libGL.so.1
in /usr/share/vulkan/icd.d/nvidia_icd.json
.
Create the folder ~/.local/share/vulkan/implicit_layer.d
and copy primus_vk.json
there with the path adjusted to the location of the shared object.
Copy primus_vk.json
to /usr/share/vulkan/implicit_layer.d
and adjust the path.
- Install the correct vulkan icds (i.e. intel/mesa, nvidia, amd, depending on your hardware).
- Use
make libprimus_vk.so libnv_vulkan_wrapper.so
to compile Primus-vk andlibnv_vulkan_wrapper.so
(check that the path to the nvidia-driver innv_vulkan_wrapper.so
is correct). - Ensure that the (unwrapped) nvidia driver is not registered (e.g. in
/usr/share/vulkan/icd.d/nvidia_icd.json
) and create a similar filenv_vulkan_wrapper.json
where the path to the driver points to the compiledlibnv_vulkan_wrapper.so
. - (Optional) Run
optirun primus_vk_diag
. It has to display entries for both graphics cards, otherwise the driver setup is broken. You can also test withoptirun vulkaninfo
that your Vulkan drivers are at least detecting your graphics cards. - Install
primus_vk.json
and adjust path. - Run
ENABLE_PRIMUS_LAYER=1 optirun vulkan-smoketest
.
Notes for running on Arch Linux:
- nv_vulkan_wrapper.cpp: Change nvDriver path to
/usr/lib/libGLX_nvidia.so.0
- primus_vk.cpp: add:
#include "vk_layer_utils.h"
(on Debian the contents are included in some other header and there is no "vk_layer_utils.h")
Leonid Maksymchuk built RPM packaging scripts for primus-vk which can be found in his repository. RPMs for Fedora >= 30 are available here
This layer is based on the sample layer available under https://github.com/baldurk/sample_layer. The guide that goes along with it is https://renderdoc.org/vulkan-layer-guide.html.