2021-09-18 10:52:07 +00:00
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# GPU acceleration {#sec-gpu-accel}
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NixOS provides various APIs that benefit from GPU hardware acceleration,
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such as VA-API and VDPAU for video playback; OpenGL and Vulkan for 3D
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graphics; and OpenCL for general-purpose computing. This chapter
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describes how to set up GPU hardware acceleration (as far as this is not
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done automatically) and how to verify that hardware acceleration is
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indeed used.
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Most of the aforementioned APIs are agnostic with regards to which
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display server is used. Consequently, these instructions should apply
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both to the X Window System and Wayland compositors.
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## OpenCL {#sec-gpu-accel-opencl}
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[OpenCL](https://en.wikipedia.org/wiki/OpenCL) is a general compute API.
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It is used by various applications such as Blender and Darktable to
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accelerate certain operations.
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OpenCL applications load drivers through the *Installable Client Driver*
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(ICD) mechanism. In this mechanism, an ICD file specifies the path to
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the OpenCL driver for a particular GPU family. In NixOS, there are two
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ways to make ICD files visible to the ICD loader. The first is through
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the `OCL_ICD_VENDORS` environment variable. This variable can contain a
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directory which is scanned by the ICL loader for ICD files. For example:
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```ShellSession
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$ export \
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OCL_ICD_VENDORS=`nix-build '<nixpkgs>' --no-out-link -A rocm-opencl-icd`/etc/OpenCL/vendors/
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```
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The second mechanism is to add the OpenCL driver package to
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[](#opt-hardware.opengl.extraPackages).
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This links the ICD file under `/run/opengl-driver`, where it will be visible
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to the ICD loader.
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The proper installation of OpenCL drivers can be verified through the
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`clinfo` command of the clinfo package. This command will report the
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number of hardware devices that is found and give detailed information
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for each device:
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```ShellSession
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$ clinfo | head -n3
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Number of platforms 1
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Platform Name AMD Accelerated Parallel Processing
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Platform Vendor Advanced Micro Devices, Inc.
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```
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### AMD {#sec-gpu-accel-opencl-amd}
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Modern AMD [Graphics Core
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Next](https://en.wikipedia.org/wiki/Graphics_Core_Next) (GCN) GPUs are
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supported through the rocm-opencl-icd package. Adding this package to
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[](#opt-hardware.opengl.extraPackages)
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enables OpenCL support:
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```nix
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hardware.opengl.extraPackages = [
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rocm-opencl-icd
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];
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```
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### Intel {#sec-gpu-accel-opencl-intel}
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[Intel Gen8 and later
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GPUs](https://en.wikipedia.org/wiki/List_of_Intel_graphics_processing_units#Gen8)
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are supported by the Intel NEO OpenCL runtime that is provided by the
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intel-compute-runtime package. For Gen7 GPUs, the deprecated Beignet
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runtime can be used, which is provided by the beignet package. The
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proprietary Intel OpenCL runtime, in the intel-ocl package, is an
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alternative for Gen7 GPUs.
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The intel-compute-runtime, beignet, or intel-ocl package can be added to
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[](#opt-hardware.opengl.extraPackages)
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to enable OpenCL support. For example, for Gen8 and later GPUs, the following
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configuration can be used:
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```nix
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hardware.opengl.extraPackages = [
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intel-compute-runtime
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];
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```
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## Vulkan {#sec-gpu-accel-vulkan}
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[Vulkan](https://en.wikipedia.org/wiki/Vulkan_(API)) is a graphics and
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compute API for GPUs. It is used directly by games or indirectly though
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compatibility layers like
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[DXVK](https://github.com/doitsujin/dxvk/wiki).
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By default, if [](#opt-hardware.opengl.driSupport)
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is enabled, mesa is installed and provides Vulkan for supported hardware.
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Similar to OpenCL, Vulkan drivers are loaded through the *Installable
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Client Driver* (ICD) mechanism. ICD files for Vulkan are JSON files that
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specify the path to the driver library and the supported Vulkan version.
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All successfully loaded drivers are exposed to the application as
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different GPUs. In NixOS, there are two ways to make ICD files visible
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to Vulkan applications: an environment variable and a module option.
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The first option is through the `VK_ICD_FILENAMES` environment variable.
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This variable can contain multiple JSON files, separated by `:`. For
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example:
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```ShellSession
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$ export \
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VK_ICD_FILENAMES=`nix-build '<nixpkgs>' --no-out-link -A amdvlk`/share/vulkan/icd.d/amd_icd64.json
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```
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The second mechanism is to add the Vulkan driver package to
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[](#opt-hardware.opengl.extraPackages).
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This links the ICD file under `/run/opengl-driver`, where it will be
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visible to the ICD loader.
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The proper installation of Vulkan drivers can be verified through the
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`vulkaninfo` command of the vulkan-tools package. This command will
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report the hardware devices and drivers found, in this example output
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amdvlk and radv:
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```ShellSession
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$ vulkaninfo | grep GPU
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GPU id : 0 (Unknown AMD GPU)
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GPU id : 1 (AMD RADV NAVI10 (LLVM 9.0.1))
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...
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GPU0:
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deviceType = PHYSICAL_DEVICE_TYPE_DISCRETE_GPU
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deviceName = Unknown AMD GPU
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GPU1:
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deviceType = PHYSICAL_DEVICE_TYPE_DISCRETE_GPU
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```
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A simple graphical application that uses Vulkan is `vkcube` from the
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vulkan-tools package.
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### AMD {#sec-gpu-accel-vulkan-amd}
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Modern AMD [Graphics Core
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Next](https://en.wikipedia.org/wiki/Graphics_Core_Next) (GCN) GPUs are
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supported through either radv, which is part of mesa, or the amdvlk
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package. Adding the amdvlk package to
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[](#opt-hardware.opengl.extraPackages)
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makes amdvlk the default driver and hides radv and lavapipe from the device list.
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A specific driver can be forced as follows:
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```nix
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hardware.opengl.extraPackages = [
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pkgs.amdvlk
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];
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# To enable Vulkan support for 32-bit applications, also add:
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hardware.opengl.extraPackages32 = [
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pkgs.driversi686Linux.amdvlk
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];
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# Force radv
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environment.variables.AMD_VULKAN_ICD = "RADV";
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# Or
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environment.variables.VK_ICD_FILENAMES =
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"/run/opengl-driver/share/vulkan/icd.d/radeon_icd.x86_64.json";
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```
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2022-12-17 10:02:37 +00:00
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## VA-API {#sec-gpu-accel-va-api}
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[VA-API (Video Acceleration API)](https://www.intel.com/content/www/us/en/developer/articles/technical/linuxmedia-vaapi.html)
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is an open-source library and API specification, which provides access to
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graphics hardware acceleration capabilities for video processing.
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VA-API drivers are loaded by `libva`. The version in nixpkgs is built to search
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the opengl driver path, so drivers can be installed in
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[](#opt-hardware.opengl.extraPackages).
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VA-API can be tested using:
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```ShellSession
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$ nix-shell -p libva-utils --run vainfo
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```
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### Intel {#sec-gpu-accel-va-api-intel}
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Modern Intel GPUs use the iHD driver, which can be installed with:
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```nix
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hardware.opengl.extraPackages = [
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intel-media-driver
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];
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```
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Older Intel GPUs use the i965 driver, which can be installed with:
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```nix
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hardware.opengl.extraPackages = [
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vaapiIntel
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];
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```
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2021-09-18 10:52:07 +00:00
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## Common issues {#sec-gpu-accel-common-issues}
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### User permissions {#sec-gpu-accel-common-issues-permissions}
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Except where noted explicitly, it should not be necessary to adjust user
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permissions to use these acceleration APIs. In the default
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configuration, GPU devices have world-read/write permissions
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(`/dev/dri/renderD*`) or are tagged as `uaccess` (`/dev/dri/card*`). The
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access control lists of devices with the `uaccess` tag will be updated
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automatically when a user logs in through `systemd-logind`. For example,
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if the user *alice* is logged in, the access control list should look as
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follows:
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```ShellSession
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$ getfacl /dev/dri/card0
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# file: dev/dri/card0
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# owner: root
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# group: video
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user::rw-
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2022-08-12 12:06:08 +00:00
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user:alice:rw-
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2021-09-18 10:52:07 +00:00
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group::rw-
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mask::rw-
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other::---
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```
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If you disabled (this functionality of) `systemd-logind`, you may need
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to add the user to the `video` group and log in again.
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### Mixing different versions of nixpkgs {#sec-gpu-accel-common-issues-mixing-nixpkgs}
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The *Installable Client Driver* (ICD) mechanism used by OpenCL and
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Vulkan loads runtimes into its address space using `dlopen`. Mixing an
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ICD loader mechanism and runtimes from different version of nixpkgs may
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not work. For example, if the ICD loader uses an older version of glibc
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than the runtime, the runtime may not be loadable due to missing
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symbols. Unfortunately, the loader will generally be quiet about such
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issues.
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If you suspect that you are running into library version mismatches
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between an ICL loader and a runtime, you could run an application with
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the `LD_DEBUG` variable set to get more diagnostic information. For
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example, OpenCL can be tested with `LD_DEBUG=files clinfo`, which should
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report missing symbols.
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