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nixos/doc/manual/configuration/configuration.xml
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@ -19,7 +19,7 @@
<xi:include href="file-systems.xml" />
<xi:include href="../from_md/configuration/x-windows.chapter.xml" />
<xi:include href="../from_md/configuration/wayland.chapter.xml" />
<xi:include href="gpu-accel.xml" />
<xi:include href="../from_md/configuration/gpu-accel.chapter.xml" />
<xi:include href="xfce.xml" />
<xi:include href="networking.xml" />
<xi:include href="linux-kernel.xml" />

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

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<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
version="5.0"
xml:id="sec-gpu-accel">
<title>GPU acceleration</title>
<para>
NixOS provides various APIs that benefit from GPU hardware
acceleration, such as VA-API and VDPAU for video playback; OpenGL and
Vulkan for 3D graphics; and OpenCL for general-purpose computing.
This chapter describes how to set up GPU hardware acceleration (as far
as this is not done automatically) and how to verify that hardware
acceleration is indeed used.
</para>
<para>
Most of the aforementioned APIs are agnostic with regards to which
display server is used. Consequently, these instructions should apply
both to the X Window System and Wayland compositors.
</para>
<section xml:id="sec-gpu-accel-opencl">
<title>OpenCL</title>
<para>
<link xlink:href="https://en.wikipedia.org/wiki/OpenCL">OpenCL</link> is a
general compute API. It is used by various applications such as
Blender and Darktable to accelerate certain operations.
</para>
<para>
OpenCL applications load drivers through the <emphasis>Installable Client
Driver</emphasis> (ICD) mechanism. In this mechanism, an ICD file
specifies the path to the OpenCL driver for a particular GPU family.
In NixOS, there are two ways to make ICD files visible to the ICD
loader. The first is through the <varname>OCL_ICD_VENDORS</varname>
environment variable. This variable can contain a directory which
is scanned by the ICL loader for ICD files. For example:
<screen><prompt>$</prompt> export \
OCL_ICD_VENDORS=`nix-build '&lt;nixpkgs&gt;' --no-out-link -A rocm-opencl-icd`/etc/OpenCL/vendors/</screen>
</para>
<para>
The second mechanism is to add the OpenCL driver package to
<xref linkend="opt-hardware.opengl.extraPackages"/>. This links the
ICD file under <filename>/run/opengl-driver</filename>, where it will
be visible to the ICD loader.
</para>
<para>
The proper installation of OpenCL drivers can be verified through
the <command>clinfo</command> command of the <package>clinfo</package>
package. This command will report the number of hardware devices
that is found and give detailed information for each device:
</para>
<screen><prompt>$</prompt> clinfo | head -n3
Number of platforms 1
Platform Name AMD Accelerated Parallel Processing
Platform Vendor Advanced Micro Devices, Inc.</screen>
<section xml:id="sec-gpu-accel-opencl-amd">
<title>AMD</title>
<para>
Modern AMD <link
xlink:href="https://en.wikipedia.org/wiki/Graphics_Core_Next">Graphics
Core Next</link> (GCN) GPUs are supported through the
<package>rocm-opencl-icd</package> package. Adding this package to
<xref linkend="opt-hardware.opengl.extraPackages"/> enables OpenCL
support:
<programlisting><xref linkend="opt-hardware.opengl.extraPackages"/> = [
rocm-opencl-icd
];</programlisting>
</para>
</section>
<section xml:id="sec-gpu-accel-opencl-intel">
<title>Intel</title>
<para>
<link
xlink:href="https://en.wikipedia.org/wiki/List_of_Intel_graphics_processing_units#Gen8">Intel
Gen8 and later GPUs</link> are supported by the Intel NEO OpenCL
runtime that is provided by the
<package>intel-compute-runtime</package> package. For Gen7 GPUs,
the deprecated Beignet runtime can be used, which is provided
by the <package>beignet</package> package. The proprietary Intel
OpenCL runtime, in the <package>intel-ocl</package> package, is
an alternative for Gen7 GPUs.
</para>
<para>
The <package>intel-compute-runtime</package>, <package>beignet</package>,
or <package>intel-ocl</package> package can be added to
<xref linkend="opt-hardware.opengl.extraPackages"/> to enable OpenCL
support. For example, for Gen8 and later GPUs, the following
configuration can be used:
<programlisting><xref linkend="opt-hardware.opengl.extraPackages"/> = [
intel-compute-runtime
];</programlisting>
</para>
</section>
</section>
<section xml:id="sec-gpu-accel-vulkan">
<title>Vulkan</title>
<para>
<link xlink:href="https://en.wikipedia.org/wiki/Vulkan_(API)">Vulkan</link> is a
graphics and compute API for GPUs. It is used directly by games or indirectly though
compatibility layers like <link xlink:href="https://github.com/doitsujin/dxvk/wiki">DXVK</link>.
</para>
<para>
By default, if <xref linkend="opt-hardware.opengl.driSupport"/> is enabled,
<package>mesa</package> is installed and provides Vulkan for supported hardware.
</para>
<para>
Similar to OpenCL, Vulkan drivers are loaded through the <emphasis>Installable Client
Driver</emphasis> (ICD) mechanism. ICD files for Vulkan are JSON files that specify
the path to the driver library and the supported Vulkan version. All successfully
loaded drivers are exposed to the application as different GPUs.
In NixOS, there are two ways to make ICD files visible to Vulkan applications: an
environment variable and a module option.
</para>
<para>
The first option is through the <varname>VK_ICD_FILENAMES</varname>
environment variable. This variable can contain multiple JSON files, separated by
<literal>:</literal>. For example:
<screen><prompt>$</prompt> export \
VK_ICD_FILENAMES=`nix-build '&lt;nixpkgs&gt;' --no-out-link -A amdvlk`/share/vulkan/icd.d/amd_icd64.json</screen>
</para>
<para>
The second mechanism is to add the Vulkan driver package to
<xref linkend="opt-hardware.opengl.extraPackages"/>. This links the
ICD file under <filename>/run/opengl-driver</filename>, where it will
be visible to the ICD loader.
</para>
<para>
The proper installation of Vulkan drivers can be verified through
the <command>vulkaninfo</command> command of the <package>vulkan-tools</package>
package. This command will report the hardware devices and drivers found,
in this example output amdvlk and radv:
</para>
<screen><prompt>$</prompt> vulkaninfo | grep GPU
GPU id : 0 (Unknown AMD GPU)
GPU id : 1 (AMD RADV NAVI10 (LLVM 9.0.1))
...
GPU0:
deviceType = PHYSICAL_DEVICE_TYPE_DISCRETE_GPU
deviceName = Unknown AMD GPU
GPU1:
deviceType = PHYSICAL_DEVICE_TYPE_DISCRETE_GPU</screen>
<para>
A simple graphical application that uses Vulkan is <command>vkcube</command>
from the <package>vulkan-tools</package> package.
</para>
<section xml:id="sec-gpu-accel-vulkan-amd">
<title>AMD</title>
<para>
Modern AMD <link
xlink:href="https://en.wikipedia.org/wiki/Graphics_Core_Next">Graphics
Core Next</link> (GCN) GPUs are supported through either radv, which is
part of <package>mesa</package>, or the <package>amdvlk</package> package.
Adding the <package>amdvlk</package> package to
<xref linkend="opt-hardware.opengl.extraPackages"/> makes amdvlk the
default driver and hides radv and lavapipe from the device list. A
specific driver can be forced as follows:
<programlisting><xref linkend="opt-hardware.opengl.extraPackages"/> = [
pkgs.<package>amdvlk</package>
];
# To enable Vulkan support for 32-bit applications, also add:
<xref linkend="opt-hardware.opengl.extraPackages32"/> = [
pkgs.driversi686Linux.<package>amdvlk</package>
];
# Force radv
<xref linkend="opt-environment.variables"/>.AMD_VULKAN_ICD = "RADV";
# Or
<xref linkend="opt-environment.variables"/>.VK_ICD_FILENAMES =
"/run/opengl-driver/share/vulkan/icd.d/radeon_icd.x86_64.json";
</programlisting>
</para>
</section>
</section>
<section xml:id="sec-gpu-accel-common-issues">
<title>Common issues</title>
<section xml:id="sec-gpu-accel-common-issues-permissions">
<title>User permissions</title>
<para>
Except where noted explicitly, it should not be necessary to
adjust user permissions to use these acceleration APIs. In the default
configuration, GPU devices have world-read/write permissions
(<filename>/dev/dri/renderD*</filename>) or are tagged as
<code>uaccess</code> (<filename>/dev/dri/card*</filename>). The
access control lists of devices with the <varname>uaccess</varname>
tag will be updated automatically when a user logs in through
<command>systemd-logind</command>. For example, if the user
<emphasis>jane</emphasis> is logged in, the access control list
should look as follows:
<screen><prompt>$</prompt> getfacl /dev/dri/card0
# file: dev/dri/card0
# owner: root
# group: video
user::rw-
user:jane:rw-
group::rw-
mask::rw-
other::---</screen>
If you disabled (this functionality of) <command>systemd-logind</command>,
you may need to add the user to the <code>video</code> group and
log in again.
</para>
</section>
<section xml:id="sec-gpu-accel-common-issues-mixing-nixpkgs">
<title>Mixing different versions of nixpkgs</title>
<para>
The <emphasis>Installable Client Driver</emphasis> (ICD)
mechanism used by OpenCL and Vulkan loads runtimes into its address
space using <code>dlopen</code>. Mixing an ICD loader mechanism and
runtimes from different version of nixpkgs may not work. For example,
if the ICD loader uses an older version of <package>glibc</package>
than the runtime, the runtime may not be loadable due to
missing symbols. Unfortunately, the loader will generally be quiet
about such issues.
</para>
<para>
If you suspect that you are running into library version mismatches
between an ICL loader and a runtime, you could run an application with
the <code>LD_DEBUG</code> variable set to get more diagnostic
information. For example, OpenCL can be tested with
<code>LD_DEBUG=files clinfo</code>, which should report missing
symbols.
</para>
</section>
</section>
</chapter>

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<chapter xmlns="http://docbook.org/ns/docbook" xmlns:xlink="http://www.w3.org/1999/xlink" xml:id="sec-gpu-accel">
<title>GPU acceleration</title>
<para>
NixOS provides various APIs that benefit from GPU hardware
acceleration, such as VA-API and VDPAU for video playback; OpenGL
and Vulkan for 3D graphics; and OpenCL for general-purpose
computing. This chapter describes how to set up GPU hardware
acceleration (as far as this is not done automatically) and how to
verify that hardware acceleration is indeed used.
</para>
<para>
Most of the aforementioned APIs are agnostic with regards to which
display server is used. Consequently, these instructions should
apply both to the X Window System and Wayland compositors.
</para>
<section xml:id="sec-gpu-accel-opencl">
<title>OpenCL</title>
<para>
<link xlink:href="https://en.wikipedia.org/wiki/OpenCL">OpenCL</link>
is a general compute API. It is used by various applications such
as Blender and Darktable to accelerate certain operations.
</para>
<para>
OpenCL applications load drivers through the <emphasis>Installable
Client Driver</emphasis> (ICD) mechanism. In this mechanism, an
ICD file specifies the path to the OpenCL driver for a particular
GPU family. In NixOS, there are two ways to make ICD files visible
to the ICD loader. The first is through the
<literal>OCL_ICD_VENDORS</literal> environment variable. This
variable can contain a directory which is scanned by the ICL
loader for ICD files. For example:
</para>
<programlisting>
$ export \
OCL_ICD_VENDORS=`nix-build '&lt;nixpkgs&gt;' --no-out-link -A rocm-opencl-icd`/etc/OpenCL/vendors/
</programlisting>
<para>
The second mechanism is to add the OpenCL driver package to
<link xlink:href="options.html#opt-hardware.opengl.extraPackages"><literal>hardware.opengl.extraPackages</literal></link>.
This links the ICD file under
<literal>/run/opengl-driver</literal>, where it will be visible to
the ICD loader.
</para>
<para>
The proper installation of OpenCL drivers can be verified through
the <literal>clinfo</literal> command of the clinfo package. This
command will report the number of hardware devices that is found
and give detailed information for each device:
</para>
<programlisting>
$ clinfo | head -n3
Number of platforms 1
Platform Name AMD Accelerated Parallel Processing
Platform Vendor Advanced Micro Devices, Inc.
</programlisting>
<section xml:id="sec-gpu-accel-opencl-amd">
<title>AMD</title>
<para>
Modern AMD
<link xlink:href="https://en.wikipedia.org/wiki/Graphics_Core_Next">Graphics
Core Next</link> (GCN) GPUs are supported through the
rocm-opencl-icd package. Adding this package to
<link xlink:href="options.html#opt-hardware.opengl.extraPackages"><literal>hardware.opengl.extraPackages</literal></link>
enables OpenCL support:
</para>
<programlisting language="bash">
hardware.opengl.extraPackages = [
rocm-opencl-icd
];
</programlisting>
</section>
<section xml:id="sec-gpu-accel-opencl-intel">
<title>Intel</title>
<para>
<link xlink:href="https://en.wikipedia.org/wiki/List_of_Intel_graphics_processing_units#Gen8">Intel
Gen8 and later GPUs</link> are supported by the Intel NEO OpenCL
runtime that is provided by the intel-compute-runtime package.
For Gen7 GPUs, the deprecated Beignet runtime can be used, which
is provided by the beignet package. The proprietary Intel OpenCL
runtime, in the intel-ocl package, is an alternative for Gen7
GPUs.
</para>
<para>
The intel-compute-runtime, beignet, or intel-ocl package can be
added to
<link xlink:href="options.html#opt-hardware.opengl.extraPackages"><literal>hardware.opengl.extraPackages</literal></link>
to enable OpenCL support. For example, for Gen8 and later GPUs,
the following configuration can be used:
</para>
<programlisting language="bash">
hardware.opengl.extraPackages = [
intel-compute-runtime
];
</programlisting>
</section>
</section>
<section xml:id="sec-gpu-accel-vulkan">
<title>Vulkan</title>
<para>
<link xlink:href="https://en.wikipedia.org/wiki/Vulkan_(API)">Vulkan</link>
is a graphics and compute API for GPUs. It is used directly by
games or indirectly though compatibility layers like
<link xlink:href="https://github.com/doitsujin/dxvk/wiki">DXVK</link>.
</para>
<para>
By default, if
<link xlink:href="options.html#opt-hardware.opengl.driSupport"><literal>hardware.opengl.driSupport</literal></link>
is enabled, mesa is installed and provides Vulkan for supported
hardware.
</para>
<para>
Similar to OpenCL, Vulkan drivers are loaded through the
<emphasis>Installable Client Driver</emphasis> (ICD) mechanism.
ICD files for Vulkan are JSON files that specify the path to the
driver library and the supported Vulkan version. All successfully
loaded drivers are exposed to the application as different GPUs.
In NixOS, there are two ways to make ICD files visible to Vulkan
applications: an environment variable and a module option.
</para>
<para>
The first option is through the
<literal>VK_ICD_FILENAMES</literal> environment variable. This
variable can contain multiple JSON files, separated by
<literal>:</literal>. For example:
</para>
<programlisting>
$ export \
VK_ICD_FILENAMES=`nix-build '&lt;nixpkgs&gt;' --no-out-link -A amdvlk`/share/vulkan/icd.d/amd_icd64.json
</programlisting>
<para>
The second mechanism is to add the Vulkan driver package to
<link xlink:href="options.html#opt-hardware.opengl.extraPackages"><literal>hardware.opengl.extraPackages</literal></link>.
This links the ICD file under
<literal>/run/opengl-driver</literal>, where it will be visible to
the ICD loader.
</para>
<para>
The proper installation of Vulkan drivers can be verified through
the <literal>vulkaninfo</literal> command of the vulkan-tools
package. This command will report the hardware devices and drivers
found, in this example output amdvlk and radv:
</para>
<programlisting>
$ vulkaninfo | grep GPU
GPU id : 0 (Unknown AMD GPU)
GPU id : 1 (AMD RADV NAVI10 (LLVM 9.0.1))
...
GPU0:
deviceType = PHYSICAL_DEVICE_TYPE_DISCRETE_GPU
deviceName = Unknown AMD GPU
GPU1:
deviceType = PHYSICAL_DEVICE_TYPE_DISCRETE_GPU
</programlisting>
<para>
A simple graphical application that uses Vulkan is
<literal>vkcube</literal> from the vulkan-tools package.
</para>
<section xml:id="sec-gpu-accel-vulkan-amd">
<title>AMD</title>
<para>
Modern AMD
<link xlink:href="https://en.wikipedia.org/wiki/Graphics_Core_Next">Graphics
Core Next</link> (GCN) GPUs are supported through either radv,
which is part of mesa, or the amdvlk package. Adding the amdvlk
package to
<link xlink:href="options.html#opt-hardware.opengl.extraPackages"><literal>hardware.opengl.extraPackages</literal></link>
makes amdvlk the default driver and hides radv and lavapipe from
the device list. A specific driver can be forced as follows:
</para>
<programlisting language="bash">
hardware.opengl.extraPackages = [
pkgs.amdvlk
];
# To enable Vulkan support for 32-bit applications, also add:
hardware.opengl.extraPackages32 = [
pkgs.driversi686Linux.amdvlk
];
# Force radv
environment.variables.AMD_VULKAN_ICD = &quot;RADV&quot;;
# Or
environment.variables.VK_ICD_FILENAMES =
&quot;/run/opengl-driver/share/vulkan/icd.d/radeon_icd.x86_64.json&quot;;
</programlisting>
</section>
</section>
<section xml:id="sec-gpu-accel-common-issues">
<title>Common issues</title>
<section xml:id="sec-gpu-accel-common-issues-permissions">
<title>User permissions</title>
<para>
Except where noted explicitly, it should not be necessary to
adjust user permissions to use these acceleration APIs. In the
default configuration, GPU devices have world-read/write
permissions (<literal>/dev/dri/renderD*</literal>) or are tagged
as <literal>uaccess</literal>
(<literal>/dev/dri/card*</literal>). The access control lists of
devices with the <literal>uaccess</literal> tag will be updated
automatically when a user logs in through
<literal>systemd-logind</literal>. For example, if the user
<emphasis>jane</emphasis> is logged in, the access control list
should look as follows:
</para>
<programlisting>
$ getfacl /dev/dri/card0
# file: dev/dri/card0
# owner: root
# group: video
user::rw-
user:jane:rw-
group::rw-
mask::rw-
other::---
</programlisting>
<para>
If you disabled (this functionality of)
<literal>systemd-logind</literal>, you may need to add the user
to the <literal>video</literal> group and log in again.
</para>
</section>
<section xml:id="sec-gpu-accel-common-issues-mixing-nixpkgs">
<title>Mixing different versions of nixpkgs</title>
<para>
The <emphasis>Installable Client Driver</emphasis> (ICD)
mechanism used by OpenCL and Vulkan loads runtimes into its
address space using <literal>dlopen</literal>. Mixing an ICD
loader mechanism and runtimes from different version of nixpkgs
may not work. For example, if the ICD loader uses an older
version of glibc than the runtime, the runtime may not be
loadable due to missing symbols. Unfortunately, the loader will
generally be quiet about such issues.
</para>
<para>
If you suspect that you are running into library version
mismatches between an ICL loader and a runtime, you could run an
application with the <literal>LD_DEBUG</literal> variable set to
get more diagnostic information. For example, OpenCL can be
tested with <literal>LD_DEBUG=files clinfo</literal>, which
should report missing symbols.
</para>
</section>
</section>
</chapter>