Difference between revisions of "Bumblebee"
(→Output wired to the NVIDIA chip)
(Adds related articles)
|Line 7:||Line 7:|
From Bumblebee's [https://github.com/Bumblebee-Project/Bumblebee/wiki/FAQ FAQ]:
From Bumblebee's [https://github.com/Bumblebee-Project/Bumblebee/wiki/FAQ FAQ]:
Revision as of 15:34, 1 December 2013
From Bumblebee's FAQ:
"Bumblebee is an effort to make NVIDIA Optimus enabled laptops work in GNU/Linux systems. Such feature involves two graphics cards with two different power consumption profiles plugged in a layered way sharing a single framebuffer."
- 1 Bumblebee: Optimus for Linux
- 2 Installation
- 3 Start Bumblebee
- 4 Usage
- 5 Configuration
- 5.1 Optimizing speed when using VirtualGL as bridge
- 5.2 Power management
- 5.3 Multiple monitors
- 6 Switch between discrete and integrated like Windows
- 7 CUDA without Bumblebee
- 8 Troubleshooting
- 8.1 [VGL] ERROR: Could not open display :8
- 8.2 [ERROR]Cannot access secondary GPU
- 8.3 ERROR: ld.so: object 'libdlfaker.so' from LD_PRELOAD cannot be preloaded: ignored
- 8.4 Fatal IO error 11 (Resource temporarily unavailable) on X server
- 8.5 Video tearing
- 8.6 Bumblebee cannot connect to socket
- 9 See also
Bumblebee: Optimus for Linux
Optimus Technology is an hybrid graphics implementation without a hardware multiplexer. The integrated GPU manages the display while the dedicated GPU manages the most demanding rendering and ships the work to the integrated GPU to be displayed. When the laptop is running on battery supply, the dedicated GPU is turned off to save power and prolong the battery life. It has also been tested successfully with desktop machines with Intel integrated graphics and an nVidia dedicated graphics card.
Bumblebee is a software implementation comprising of two parts:
- Render programs off-screen on the dedicated video card and display it on the screen using the integrated video card. This bridge is provided by VirtualGL or primus (read further) and connects to a X server started for the discrete video card.
- Disable the dedicated video card when it is not in use (see the Power management section)
It tries to mimic the Optimus technology behavior; using the dedicated GPU for rendering when needed and power it down when not in use. The present releases only support rendering on-demand, automatically starting a program with the discrete video card based on workload is not implemented.
Before installing Bumblebee check your BIOS and activate Optimus (older laptops call it "switchable graphics") if possible (BIOS doesn't have to provide this option), and install the Intel driver for the secondary on board graphics card.
Several packages are available for a complete setup:
- - The main package providing the daemon and client programs.
- (optional) (or AUR) - Recommended for saving power by disable the NVIDIA card.
- (optional) If you want more than just saving power, that is rendering programs on the discrete NVDIA card you also need:
Installing Bumblebee with Intel/NVIDIA
Install, , and . If you have and installed, you will have to reinstall them together with the rest to avoid a dependency conflict between and .
If you want to run 32-bit applications (like games with wine) on a 64-bit system you need thepackage too.
Installing Bumblebee with Intel/Nouveau
- - experimental 3D acceleration driver.
- - Mesa classic DRI + Gallium3D drivers.
- - Mesa 3D graphics libraries.
In order to use Bumblebee it is necessary add yourself (and other users) to the bumblebee group:
# gpasswd -a $USER bumblebee
$USER is the login name of the user to be added. Then log off and on again to apply the group changes.
Finished. Reboot system and use the shell program
optirun for Optimus NVIDIA rendering!
If you simply wish to disable your NVIDIA card, this should be all that is needed, apart from having
bbswitch installed. The bumblebeed daemon will, by default, instruct bbswitch to turn off the card when it starts. See also the power management section below.
The command line programm
optirun shipped with Bumblebee is your best friend
for running applications on your Optimus NVIDIA card.
Test Bumblebee if it works with your Optimus system:
$ optirun glxgears -info
If it succeeds and the terminal you are running from mentions something about your NVIDIA - Optimus with Bumblebee is working!
$ optirun [options] application [application-parameters]
Start Windows applications with Optimus:
$ optirun wine windows application.exe
Use NVIDIA Settings with Optimus:
$ optirun -b none nvidia-settings -c :8
For a list of options for
optirun view its manual page.
A new program is soon becoming the default choice because of better performance, namely
primus. Currently you need to run this program separately (it does not accept options
optirun), but in the future it will be started by optirun. Usage:
$ primusrun glxgears
You can configure the behaviour of Bumblebee to fit your needs. Fine tuning like speed optimization, power management and other stuff can be configured in
Optimizing speed when using VirtualGL as bridge
Bumblebee renders frames for your Optimus NVIDIA card in an invisible X Server with VirtualGL and transports them back to your visible X Server.
Frames will be compressed before they are transported - this saves bandwidth and can be used for speed-up optimization of bumblebee:
To use an other compression method for a single application:
$ optirun -c compress-method application
The method of compres will affect performance in the GPU/GPU usage. Compressed methods (such as
jpeg) will load the CPU the most but will load GPU the minimum necessary; uncompressed methods loads the most on GPU and the CPU will have the minimum load possible.
Compressed methods are:
Uncompressed methods are:
To use a standard compression for all applications set the
[...] [optirun] VGLTransport=proxy [...]
You can also play with the way VirtualGL reads back the pixels from your graphic card. Setting
VGL_READBACK environment variable to
pbo should increase the performance. Compare these two:
# PBO should be faster. VGL_READBACK=pbo optirun glxspheres # The default value is sync. VGL_READBACK=sync optirun glxspheres
The goal of power management feature is to turn off the NVIDIA card when it is not used by bumblebee any more. If bbswitch is installed, it will be detected automatically when the Bumblebee daemon starts. No additional configuration is necessary.
Default power state of NVIDIA card using bbswitch
The default behavior of bbswitch is to leave the card power state unchanged.
bumblebeed does disable
the card when started, so the following is only necessary if you use bbswitch without bumblebeed.
unload_state module options according to your needs (see bbswitch documentation).
options bbswitch load_state=0 unload_state=1
Enable NVIDIA card during shutdown
The NVIDIA card may not correctly initialize during boot if the card was powered off when the system was last shutdown. One option is to set
/etc/bumblebee/bumblebee.conf, however this will enable the card everytime you stop the Bumblebee daemon, even if done manually. To ensure that the NVIDIA card is always powered on during shutdown, add the following systemd service (if using ):
[Unit] Description=Enable NVIDIA card DefaultDependencies=no [Service] Type=oneshot ExecStart=/bin/sh -c 'echo ON > /proc/acpi/bbswitch' [Install] WantedBy=shutdown.target
Then enable the service by running
systemctl enable nvidia-enable.service at the root prompt.
Outputs wired to the Intel chip
If the port (DisplayPort/HDMI/VGA) is wired to the Intel chip, you can set up multiple monitors with xorg.conf. Set them to use the Intel card, but Bumblebee can still use the NVIDIA card. One example configuration is below for two identical screens with 1080p resolution and using the HDMI out.
Section "Screen" Identifier "Screen0" Device "intelgpu0" Monitor "Monitor0" DefaultDepth 24 Option "TwinView" "0" SubSection "Display" Depth 24 Modes "1980x1080_60.00" EndSubSection EndSection Section "Screen" Identifier "Screen1" Device "intelgpu1" Monitor "Monitor1" DefaultDepth 24 Option "TwinView" "0" SubSection "Display" Depth 24 Modes "1980x1080_60.00" EndSubSection EndSection Section "Monitor" Identifier "Monitor0" Option "Enable" "true" EndSection Section "Monitor" Identifier "Monitor1" Option "Enable" "true" EndSection Section "Device" Identifier "intelgpu0" Driver "intel" Option "XvMC" "true" Option "UseEvents" "true" Option "AccelMethod" "UXA" BusID "PCI:0:2:0" EndSection Section "Device" Identifier "intelgpu1" Driver "intel" Option "XvMC" "true" Option "UseEvents" "true" Option "AccelMethod" "UXA" BusID "PCI:0:2:0" EndSection Section "Device" Identifier "nvidiagpu1" Driver "nvidia" BusID "PCI:0:1:0" EndSection
You need to probably change the BusID for both the Intel and the NVIDIA card.
$ lspci | grep VGA
00:02.0 VGA compatible controller: Intel Corporation 2nd Generation Core Processor Family Integrated Graphics Controller (rev 09)
The BusID is 0:2:0
Output wired to the NVIDIA chip
On some notebooks, the digital Video Output (HDMI or DisplayPort) is hardwired to the NVIDIA chip. If you want to use all the displays on such a system simultaniously, you have to run 2 X Servers. The first will be using the Intel driver for the notebooks panel and a display connected on VGA. The second will be started through optirun on the NVIDIA card, and drives the digital display.
There are currently several instructions on the web how such a setup can be made to work. One can be found on the bumblebee wiki page. Another approach is described below.
xf86-video-intel-virtual-crtc and hybrid-screenclone
This method uses a patched Intel driver, which is extended to have a VIRTUAL Display, and the program hybrid-screenclone which is used to copy the display over from the virtual display to a second X Server which is running on the NVIDIA card using Optirun. Credit goes to Triple-head monitors on a Thinkpad T520 which has a detailed explanation on how this is done on a Ubuntu system.
For simplicity, DP is used below to refer to the Digital Output (DisplayPort). The instructions should be the same if the notebook has a HDMI port instead.
- Set system to use NVIDIA card exclusively, test DP/Monitor combination and generate xorg.nvidia.conf. This step is not required, but recommended if your system Bios has an option to switch the graphics into NVIDIA-only mode. To do this, first uninstall the bumblebee package and install just the NVIDIA driver. Then reboot, enter the Bios and switch the Graphics to NVIDIA-only. When back in Arch, connect you Monitor on DP and use startx to test if it is working in principle. Use Xorg -configure to generate an xorg.conf file for your NVIDIA card. This will come in handy further down below.
- Reinstall bumlbebee and bbswitch, reboot and set the system Gfx back to Hybrid in the BIOS.
- Install AUR, and replace your xf86-video-intel package with it.
- Install AUR
- Change these bumblebee.conf settings:
- Copy the xorg.conf generated in Step 1 to
/etc/X11/xorg.nvidia.conf). In the [driver-nvidia] section of
XorgConfFileto point to it.
- Test if your
/etc/X11/xorg.nvidia.confis working with
startx -- -config /etc/X11/xorg.nvidia.conf
- In order for your DP Monitor to show up with the correct resolution in your VIRTUAL Display you might have to edit the Monitor section in your
/etc/xorg.nvidia.conf. Since this is extra work, you could try to continue with your auto-generated file. Come back to this step in the instructions if you find that the resolution of the VIRTUAL Display as shown by xrandr is not correct.
- First you have to generate a Modeline. You can use the tool amlc, which will genearte a Modeline if you input a few basic parameters.
- Example: 24" 1920x1080 Monitor
- start the tool with
Monitor Identifier: Samsung 2494 Aspect Ratio: 2 physical size[cm]: 60 Ideal refresh rate, in Hz: 60 min HSync, kHz: 40 max HSync, kHz: 90 min VSync, Hz: 50 max VSync, Hz: 70 max pixel Clock, MHz: 400
This is the Monitor section which
amlc generated for this input:
Section "Monitor" Identifier "Samsung 2494" ModelName "Generated by Another Modeline Calculator" HorizSync 40-90 VertRefresh 50-70 DisplaySize 532 299 # Aspect ratio 1.778:1 # Custom modes Modeline "1920x1080" 174.83 1920 2056 2248 2536 1080 1081 1084 1149 # 174.83 MHz, 68.94 kHz, 60.00 Hz EndSection # Samsung 2494
xorg.nvidia.conf to include this Monitor section. You can also trim down your file so that it only contains ServerLayout, Monitor, Device and Screen sections. For reference, here is mine:
Section "ServerLayout" Identifier "X.org Nvidia DP" Screen 0 "Screen0" 0 0 InputDevice "Mouse0" "CorePointer" InputDevice "Keyboard0" "CoreKeyboard" EndSection Section "Monitor" Identifier "Samsung 2494" ModelName "Generated by Another Modeline Calculator" HorizSync 40-90 VertRefresh 50-70 DisplaySize 532 299 # Aspect ratio 1.778:1 # Custom modes Modeline "1920x1080" 174.83 1920 2056 2248 2536 1080 1081 1084 1149 # 174.83 MHz, 68.94 kHz, 60.00 Hz EndSection # Samsung 2494 Section "Device" Identifier "DiscreteNvidia" Driver "nvidia" BusID "PCI:1:0:0" EndSection Section "Screen" Identifier "Screen0" Device "DiscreteNvidia" Monitor "Samsung 2494" SubSection "Display" Viewport 0 0 Depth 24 EndSubSection EndSection
- Plug in both external monitors and startx. Look at your
/var/log/Xorg.0.log. Check that your VGA Monitor is detected with the correct Modes there. You should also see a VIRTUAL output with modes show up.
xrandrand three displays should be listed there, along with the supported modes.
- If the listed Modelines for your VIRTUAL display doesn't have your Monitors native resolution, make note of the exact output name. For me that is
VIRTUAL1. Then have a look again in the Xorg.0.log file. You should see a message: "Output VIRTUAL1 has no monitor section" there. We will change this by putting a file with the needed Monitor section into
/etc/X11/xorg.conf.d. Exit and Restart X afterward.
Section "Monitor" Identifier "VIRTUAL1" ModelName "Generated by Another Modeline Calculator" HorizSync 40-90 VertRefresh 50-70 DisplaySize 532 299 # Aspect ratio 1.778:1 # Custom modes Modeline "1920x1080" 174.83 1920 2056 2248 2536 1080 1081 1084 1149 # 174.83 MHz, 68.94 kHz, 60.00 Hz EndSection # Samsung 2494
- Turn the NVIDIA card on by running:
sudo tee /proc/acpi/bbswitch <<< ON
- Start another X server for the DisplayPort monitor:
sudo optirun true
- Check the log of the second X server in
- Run xrandr to set up the VIRTUAL display to be the right size and placement, eg.:
xrandr --output VGA1 --auto --rotate normal --pos 0x0 --output VIRTUAL1 --mode 1920x1080 --right-of VGA1 --output LVDS1 --auto --rotate normal --right-of VIRTUAL1
- Take note of the position of the VIRTUAL display in the list of Outputs as shown by xrandr. The counting starts from zero, i.e. if it is the third display shown, you would specify
-x 2as parameter to
screenclone(Note: This might not always be correct. If you see your internal laptop display cloned on the monitor, try
- Clone the contents of the VIRTUAL display onto the X server created by bumblebee, which is connected to the DisplayPort monitor via the NVIDIA chip:
screenclone -d :8 -x 2
Thats it, all three displays should be up and running now.
Switch between discrete and integrated like Windows
In Windows, the way that Optimus works is NVIDIA has a whitelist of applications that require Optimus for, and you can add applications to this whitelist as needed. When you launch the application, it automatically decides which card to use.
To mimic this behavior in Linux, you can useAUR. After installing, you can add the below in your .xprofile.
mkdir -p /tmp/libgl-switcheroo-$USER/fs gtkglswitch & libgl-switcheroo /tmp/libgl-switcheroo-$USER/fs &
To enable this, you must add the below to the shell that you intend to launch applications from (I simply added it to the .xprofile file)
Once this has all been done, every application you launch from this shell will pop up a GTK+ window asking which card you want to run it with (you can also add an application to the whitelist in the configuration). The configuration is located in
CUDA without Bumblebee
This is not well documented, but you do not need Bumblebee to use CUDA and it may work even on machines where optirun fails. For a guide on how to get it working with the Lenovo IdeaPad Y580 (which uses the GeForce 660M), see: https://wiki.archlinux.org/index.php/Lenovo_IdeaPad_Y580#NVIDIA_Card. Those instructions are very likely to work with other machines.
[VGL] ERROR: Could not open display :8
There is a known problem with some wine applications that fork and kill the parent process without keeping track of it (for example the free to play online game "Runes of Magic")
This is a known problem with VirtualGL. As of bumblebee 3.1, so long as you have it installed, you can use Primus as your render bridge:
$ optirun -b primus wine windows program.exe
If this does not work, an alternative walkaround for this problem is:
$ optirun bash $ optirun wine windows program.exe
If using NVIDIA drivers a fix for this problem is to edit
/etc/bumblebee/xorg.conf.nvidia and change Option
[ERROR]Cannot access secondary GPU
No devices detected
In some instances, running optirun will return:
[ERROR]Cannot access secondary GPU - error: [XORG] (EE) No devices detected. [ERROR]Aborting because fallback start is disabled.
In this case, you will need to move the file
/etc/X11/xorg.conf.d/20-intel.conf to somewhere else. Restart the bumblebeed daemon, and it should work. If you do need to change some features on Intel module, a workaround is to move your
It could be also necessary to comment the driver line in
If you're using the nouveau driver you could try switching to the nVidia driver.
You might need to define the NVIDIA card somewhere (e.g. file
/etc/X11/xorg.conf.d), and remember to change the BusID using lspci.
Section "Device" Identifier "nvidiagpu1" Driver "nvidia" BusID "PCI:0:1:0" EndSection
NVIDIA(0): Failed to assign any connected display devices to X screen 0
If the console output is:
[ERROR]Cannot access secondary GPU - error: [XORG] (EE) NVIDIA(0): Failed to assign any connected display devices to X screen 0 [ERROR]Aborting because fallback start is disabled.
You can change this line in
Option "ConnectedMonitor" "DFP"
Option "ConnectedMonitor" "CRT"
Could not load GPU driver
If the console output is:
[ERROR]Cannot access secondary GPU - error: Could not load GPU driver
and if you try to load the nvidia module you get:
modprobe nvidia modprobe: ERROR: could not insert 'nvidia': Exec format error
You should try manually compiling the nvidia packages against your current kernel.
yaourt -Sb nvidia
Should do the trick
ERROR: ld.so: object 'libdlfaker.so' from LD_PRELOAD cannot be preloaded: ignored
You probably want to start a 32-bit application with bumblebee on a 64-bit system. See the "Note" box in Installation.
true. Your program forks into background and bumblebee don't know anything about it.
Video tearing is a somewhat common problem on Bumblebee. To fix it, you need to enable vsync. It should be enabled by default on the Intel card, but verify that from Xorg logs. To check whether or not it is enabled for NVIDIA, run:
$ optirun nvidia-settings -c :8
X Server XVideo Settings -> Sync to VBlank and
OpenGL Settings -> Sync to VBlank should both be enabled. The Intel card has in general less tearing, so use it for video playback. Especially use VA-API for video decoding (e.g.
mplayer-vaapi and with
Refer to the Intel article on how to fix tearing on the Intel card.
If it is still not fixed, try to disable compositing from your desktop environment. Try also disabling triple buffering.
Bumblebee cannot connect to socket
You might get something like:
$ optirun glxspheres
[ 1648.179533] [ERROR]You've no permission to communicate with the Bumblebee daemon. Try adding yourself to the 'bumblebee' group [ 1648.179628] [ERROR]Could not connect to bumblebee daemon - is it running?
If you are already in the
bumblebee group (
$ groups | grep bumblebee), you may try removing the socket
Join us at #bumblebee at freenode.net.