ATI

This article covers the radeon open source driver which supports the majority of AMD (previously ATI) GPUs.

Selecting the right driver

Depending on the card you have, find the right driver in Xorg#AMD. This page has instructions for ATI.

If unsure, try this open source driver first, it will suit most needs and is generally less problematic. See the feature matrix to know what is supported and the decoder ring to translate marketing names (e.g. Radeon HD4330) to chip names (e.g. R700).

Installation

Install the mesa package, which provides the DRI driver for 3D acceleration.

  • For 32-bit application support, also install the lib32-mesa package from the multilib repostory.
  • For the DDX driver (which provides 2D acceleration in Xorg), install the xf86-video-ati package.

Support for accelerated video decoding is provided by libva-mesa-driver and lib32-libva-mesa-driver for VA-API and mesa-vdpau and packages for VDPAU.

Loading

The radeon kernel module should load fine automatically on system boot.

If it does not happen, then:

Enable early KMS

See Kernel mode setting#Early KMS start.

Xorg configuration

Xorg will automatically load the driver and it will use your monitor's EDID to set the native resolution. Configuration is only required for tuning the driver.

If you want manual configuration, create , and add the following:

Section "Device"
    Identifier "Radeon"
    Driver "radeon"
EndSection

Using this section, you can enable features and tweak the driver settings.

Performance tuning

Enabling video acceleration

See Hardware video acceleration#ATI/AMD.

Graphical tools

  • WattmanGTK A GTK3 user-interface written in Python 3, which allows you to view, monitor Radeon performance, fan speeds and power states and the ability to overclock the graphics processor. It uses the AMDGPU kernel driver.
https://github.com/BoukeHaarsma23/WattmanGTK || wattman-gtk-gitAUR
Note: It is required to set a kernel parameter (amdgpu.ppfeaturemask) in order to enable the AMD Overdrive technology within GNU/Linux. Which is necessary to use WattmanGTK.

      Driver options

      The following options apply to .

      Please read and RadeonFeature first before applying driver options.

      Acceleration architecture; Glamor is available as a 2D acceleration method implemented through OpenGL, and it is the default for R600 (Radeon HD2000 series) and newer graphic cards. Older cards use EXA.

      Option "AccelMethod" "glamor"

      DRI3 is enabled by default since xf86-video-ati 7.8.0. For older drivers, which use DRI2 by default, switch to DRI3 with the following option:

      Option "DRI" "3"

      TearFree is a tearing prevention option which prevents tearing by using the hardware page flipping mechanism:

      Option "TearFree" "on"

      ColorTiling and ColorTiling2D are supposed to be enabled by default. Tiled mode can provide significant performance benefits with 3D applications. It is disabled if the DRM module is too old or if the current display configuration does not support it. KMS ColorTiling2D is only supported on R600 (Radeon HD2000 series) and newer chips:

      Option "ColorTiling" "on"
      Option "ColorTiling2D" "on"

      When using Glamor as acceleration architecture, it is possible to enable the ShadowPrimary option, which enables a so-called "shadow primary" buffer for fast CPU access to pixel data, and separate scanout buffers for each display controller (CRTC). This may improve performance for some 2D workloads, potentially at the expense of other (e.g. 3D, video) workloads. Note that enabling this option currently disables Option "EnablePageFlip":

      Option "ShadowPrimary" "on"

      EXAVSync is only available when using EXA and can be enabled to avoid tearing by stalling the engine until the display controller has passed the destination region. It reduces tearing at the cost of performance and has been known to cause instability on some chips:

      Option "EXAVSync" "yes"

      Below is a sample configuration file of :

      Kernel parameters

      Defining the gartsize, if not autodetected, can be done by adding as a kernel parameter.

      The changes take effect at the next reboot.

      Deactivating PCIe 2.0

      Since kernel 3.6, PCI Express 2.0 in radeon is turned on by default.

      It may be unstable with some motherboards. It can be deactivated by adding radeon.pcie_gen2=0 as a kernel parameter.

      See Phoronix article for more information.

      Gallium Heads-Up Display

      The radeon driver supports the activation of a heads-up display (HUD) which can draw transparent graphs and text on top of applications that are rendering, such as games. These can show values such as the current frame rate or the CPU load for each CPU core or an average of all of them. The HUD is controlled by the GALLIUM_HUD environment variable, and can be passed the following list of parameters among others:

      • "fps" - displays current frames per second
      • "cpu" - displays the average CPU load
      • "cpu0" - displays the CPU load for the first CPU core
      • "cpu0+cpu1" - displays the CPU load for the first two CPU cores
      • "draw-calls" - displays how many times each material in an object is drawn to the screen
      • "requested-VRAM" - displays how much VRAM is being used on the GPU
      • "pixels-rendered" - displays how many pixels are being displayed

      To see a full list of parameters, as well as some notes on operating GALLIUM_HUD, you can also pass the "help" parameter to a simple application such as glxgears and see the corresponding terminal output:

      # GALLIUM_HUD="help" glxgears

      More information can be found from this mailing list post or this blog post.

      Hybrid graphics/AMD Dynamic Switchable Graphics

      It is the technology used on recent laptops equiped with two GPUs, one power-efficent (generally Intel integrated card) and one more powerful and more power-hungry (generally Radeon or Nvidia). There are two ways to get it work:

      • If it is not required to run 'GPU-hungry' applications, it is possible to disable the discrete card (see Ubuntu wiki):
      • PRIME: Is a proper way to use hybrid graphics on Linux, but still requires a bit of manual intervention from the user.

      Powersaving

      With the radeon driver, power saving is disabled by default and has to be enabled manually if desired.

      You can choose between three different methods:

      1. dpm (enabled by default since kernel 3.13)
      2. dynpm
      3. profile

      See https://www.x.org/wiki/RadeonFeature/#index3h2 for more details.

      Dynamic power management

      Since kernel 3.13, DPM is enabled by default for lots of AMD Radeon hardware. If you want to disable it, add the parameter radeon.dpm=0 to the kernel parameters.

      Unlike dynpm, the "dpm" method uses hardware on the GPU to dynamically change the clocks and voltage based on GPU load. It also enables clock and power gating.

      There are 3 operation modes to choose from:

      • lowest power consumption
      • sane default
      • highest performance

      They can be changed via sysfs:

      # echo battery > /sys/class/drm/card0/device/power_dpm_state

      For testing or debugging purposes, you can force the card to run in a set performance mode:

      • default; uses all levels in the power state
      • enforces the lowest performance level
      • enforces the highest performance level
      # echo low > /sys/class/drm/card0/device/power_dpm_force_performance_level

      Commandline Tools

      • radcard - A script to get and set DPM power states and levels

      Dynamic frequency switching

      This method dynamically changes the frequency depending on GPU load, so performance is ramped up when running GPU intensive applications, and ramped down when the GPU is idle. The re-clocking is attempted during vertical blanking periods, but due to the timing of the re-clocking functions, does not always complete in the blanking period, which can lead to flicker in the display. Due to this, dynamic power management only works when a single head is active.

      It can be activated by simply running the following command:

      # echo dynpm > /sys/class/drm/card0/device/power_method

      Profile-based frequency switching

      This method will allow you to select one of the five profiles (described below). Different profiles, for the most part, end up changing the frequency/voltage of the GPU. This method is not as aggressive, but is more stable and flicker free and works with multiple heads active.

      To activate the method, run the following command:

      # echo profile > /sys/class/drm/card0/device/power_method

      Select one of the available profiles:

      • default uses the default clocks and does not change the power state. This is the default behaviour.
      • selects between and power states based on the whether the system is on battery power or not.
      • forces the gpu to be in the power state all the time. Note that can cause display problems on some laptops, which is why only uses when monitors are off. Selected on other profiles when the monitors are in the DPMS-off state.
      • forces the gpu to be in the power state all the time.
      • forces the gpu to be in the power state all the time.

      As an example, we will activate the profile (replace with any of the aforementioned profiles as necessary):

      # echo low > /sys/class/drm/card0/device/power_profile

      Persistent configuration

      The methods described above are not persistent. To make them persistent, you may create a udev rule (example for #Profile-based frequency switching):

      As another example, dynamic power management can be permanently forced to a certain performance level:

      To determine the name, execute:

      $ udevadm info --attribute-walk /sys/class/drm/card0 | grep "KERNEL="

      Other notes

      To view the speed that the GPU is running at, perform the following command and you will get something like this output:

      It depends on which GPU line yours is, however. Along with the radeon driver versions, kernel versions, etc. So it may not have much/any voltage regulation at all.

      Thermal sensors are implemented via external i2c chips or via the internal thermal sensor (rv6xx-evergreen only). To get the temperature on asics that use i2c chips, you need to load the appropriate hwmon driver for the sensor used on your board (lm63, lm64, etc.). The drm will attempt to load the appropriate hwmon driver. On boards that use the internal thermal sensor, the drm will set up the hwmon interface automatically. When the appropriate driver is loaded, the temperatures can be accessed via lm_sensors tools or via sysfs in .

      Fan Speed

      While the power saving features above should handle fan speeds quite well, some cards may still be too noisy in their idle state. In this case, and when your card supports it, you can change the fan speed manually.

      Warning:
      • Keep in mind that the following method sets the fan speed to a fixed value, hence it will not adjust with the stress of the GPU, which can lead to overheating under heavy load.
      • Check GPU temperature when applying lower than standard values.

      To control the GPU fan, see Fan speed control#AMDGPU sysfs fan control (amdgpu and radeon share the same controls for this).

      For persistence, see the example in #Persistent configuration.

      If a fixed value is not desired, there are possibilities to define a custom fan curve manually by, for example, writing a script in which fan speeds are set depending on the current temperature (current value in ).

      A GUI solution is available by installing .

      TV out

      First, check that you have an S-video output: should give you something like

      Screen 0: minimum 320x200, current 1024x768, maximum 1280x1200
      ...
      S-video disconnected (normal left inverted right x axis y axis)

      Now we should tell Xorg that it is actually connected (it is, right?)

      xrandr --output S-video --set "load detection" 1

      Setting TV standard to use:

      xrandr --output S-video --set "tv standard" ntsc

      Adding a mode for it (currently supports only 800x600):

      xrandr --addmode S-video 800x600

      Clone mode:

      xrandr --output S-video --same-as VGA-0

      Now let us try to see what we have:

      xrandr --output S-video --mode 800x600

      At this point, you should see a 800x600 version of your desktop on your TV.

      To disable the output, do

      xrandr --output S-video --off

      Force TV-out in KMS

      The kernel can recognize video= parameter in following form (see KMS for more details):

      video=<conn>:<xres>x<yres>[M][R][-<bpp>][@<refresh>][i][m][eDd]

      For example:

      video=DVI-I-1:1280x1024-24@60e

      Parameters with whitespaces must be quoted:

      "video=9-pin DIN-1:1024x768-24@60e"

      Current mkinitcpio implementation also requires in front. For example:

      root=/dev/disk/by-uuid/d950a14f-fc0c-451d-b0d4-f95c2adefee3 ro quiet radeon.modeset=1 security=none # video=DVI-I-1:1280x1024-24@60e "video=9-pin DIN-1:1024x768-24@60e"
      • GRUB Legacy can pass such command line as is.
      • LILO needs backslashes for doublequotes (append )

      You can get list of your video outputs with following command:

      HDMI audio

      HDMI audio is supported in the xf86-video-ati video driver. To disable HDMI audio add to your kernel parameters.

      If there is no video after boot up, the driver option has to be disabled.

      Multihead setup

      Using the RandR extension

      See Multihead#RandR how to setup multiple monitors by using RandR.

      Independent X screens

      Independent dual-headed setups can be configured the usual way. However you might want to know that the radeon driver has a option which allows you to bind a specific device section to an output of your choice:

      /etc/X11/xorg.conf.d/20-radeon.conf
      Section "Device"
        Identifier "Device0"
        Driver "radeon"
        Option "ZaphodHeads" "VGA-0"
        VendorName "ATI"
        BusID "PCI:1:0:0"
        Screen 0
      EndSection
      

      This can be a life-saver, when using videocards that have more than two outputs. For instance one HDMI out, one DVI, one VGA, will only select and use HDMI+DVI outputs for the dual-head setup, unless you explicitly specify .

      Turn vsync off

      The radeon driver will probably enable vsync by default, which is perfectly fine except for benchmarking. To turn it off, try the environment variable or create ~/.drirc (edit it if it already exists) and add the following:

      If vsync is still enabled, you can disable it by editing . See #Driver options.

      Troubleshooting

      Performance and/or artifacts issues when using EXA

      If having 2D performance issues, like slow scrolling in a terminal or webbrowser, adding as device option may solve the issue.

      In addition disabling EXAPixmaps may solve artifacts issues, although this is generally not recommended and may cause other issues.

      Adding undetected/unsupported resolutions

      See Xrandr#Adding undetected resolutions.

      TV showing a black border around the screen

      When connecting a TV using the HDMI port, the TV may show a blurry picture with a 2-3cm border around it. This protects against overscanning (see Wikipedia:Overscan), but can be turned off using xrandr:

      xrandr --output HDMI-0 --set underscan off

      Black screen and no console, but X works in KMS

      This is a solution to the no-console problem that might come up, when using two or more ATI cards on the same PC. Fujitsu Siemens Amilo PA 3553 laptop for example has this problem. This is due to fbcon console driver mapping itself to the wrong framebuffer device that exists on the wrong card. This can be fixed by adding this to the kernel boot line:

      fbcon=map:1

      This will tell the fbcon to map itself to the /dev/fb1 framebuffer and not the , that in our case exists on the wrong graphics card. If that does not fix your problem, try booting with

      fbcon=map:0

      instead.

      ATI X1600 (RV530 series) 3D application show black windows

      There are three possible solutions:

      • Try adding to your boot loader Kernel parameters.
      • If this does not work, you can try adding noapic instead of .
      • If none of the above work, then you can try running or to see which one works for you, then install and set that option in ~/.drirc.

      Cursor corruption after coming out of sleep

      If the cursor becomes corrupted (e.g. repeating itself vertically after the monitor(s) comes out of sleep) set in the section of the configuration file.

      DisplayPort stays black on multimonitor mode

      Try booting with the kernel parameter .

      R9-390 Poor Performance and/or Instability

      Firmware issues with R9-390 series cards include poor performance and crashes (frequently caused by gaming or using Google Maps) possibly related DPM. Comment 115 of this bug report includes instructions for a fix.

      QHD / UHD / 4k support over HDMI for older Radeon cards

      Older cards have their pixel clock limited to 165MHz for HDMI. Hence, they do not support QHD or 4k only via dual-link DVI but not over HDMI.

      One possibility to work around this is to use custom modes with lower refresh rate, e.g. 30Hz.

      Another one is a kernel patch removing the pixel clock limit, but this may damage the card!

      Official kernel bug ticket with patch for 4.8: https://bugzilla.kernel.org/show_bug.cgi?id=172421

      The patch introduces a new kernel parameter which alters the pixel clock limit.

      Be sure to use a high speed HDMI cable for this.

      Horizontal flickering occasionally when using 4k DP output on 390X

      If you use 390X (or perhaps similar models) and the 4k output from DP, you may experiencing occasional horizontal artifacts / flickering (i.e. every half an hour or so, a horizontal strip of pixels with a height of ~100 pixels across the whole screen's width shaking up and down for a few seconds). This might be a bug of the radeon driver. Changing to AMDGPU seems to fix it.

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      See also

      Benchmark showing the open source driver is on par performance-wise with the proprietary driver for many cards.

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