Table of Contents
xorg.conf - Configuration File for Xorg
Xorg supports several
mechanisms for supplying/obtaining configuration and run-time parameters:
command line options, environment variables, the xorg.conf configuration
file, auto-detection, and fallback defaults. When the same information is
supplied in more than one way, the highest precedence mechanism is used.
The list of mechanisms is ordered from highest precedence to lowest. Note
that not all parameters can be supplied via all methods. The available
command line options and environment variables (and some defaults) are
described in the Xserver(1x)
and Xorg(1x)
manual pages. Most configuration
file parameters, with their defaults, are described below. Driver and module
specific configuration parameters are described in the relevant driver
or module manual page.
Xorg uses a configuration file called
xorg.conf for its initial setup. This configuration file is searched for
in the following places when the server is started as a normal user:
/etc/X11/<cmdline>
/usr/X11R6/etc/X11/<cmdline>
/etc/X11/$XORGCONFIG
/usr/X11R6/etc/X11/$XORGCONFIG
/etc/X11/xorg.conf-4
/etc/X11/xorg.conf
/etc/xorg.conf
/usr/X11R6/etc/X11/xorg.conf.<hostname>
/usr/X11R6/etc/X11/xorg.conf-4
/usr/X11R6/etc/X11/xorg.conf
/usr/X11R6/lib/X11/xorg.conf.<hostname>
/usr/X11R6/lib/X11/xorg.conf-4
/usr/X11R6/lib/X11/xorg.conf
where <cmdline> is a relative path (with no ".." components) specified with
the -config command line option, $XORGCONFIG is the relative path (with
no ".." components) specified by that environment variable, and <hostname>
is the machine's hostname as reported by gethostname(3)
.
When the Xorg server
is started by the "root" user, the config file search locations are as
follows:
<cmdline>
/etc/X11/<cmdline>
/usr/X11R6/etc/X11/<cmdline>
$XORGCONFIG
/etc/X11/$XORGCONFIG
/usr/X11R6/etc/X11/$XORGCONFIG
$HOME/xorg.conf
/etc/X11/xorg.conf-4
/etc/X11/xorg.conf
/etc/xorg.conf
/usr/X11R6/etc/X11/xorg.conf.<hostname>
/usr/X11R6/etc/X11/xorg.conf-4
/usr/X11R6/etc/X11/xorg.conf
/usr/X11R6/lib/X11/xorg.conf.<hostname>
/usr/X11R6/lib/X11/xorg.conf-4
/usr/X11R6/lib/X11/xorg.conf
where <cmdline> is the path specified with the -config command line option
(which may be absolute or relative), $XORGCONFIG is the path specified
by that environment variable (absolute or relative), $HOME is the path
specified by that environment variable (usually the home directory), and
<hostname> is the machine's hostname as reported by gethostname(3)
.
The xorg.conf
file is composed of a number of sections which may be present in any order.
Each section has the form:
Section "SectionName"
SectionEntry
...
EndSection
The section names are:
Files File pathnames
ServerFlags Server flags
Module Dynamic module loading
InputDevice Input device description
Device Graphics device description
VideoAdaptor Xv video adaptor description
Monitor Monitor description
Modes Video modes descriptions
Screen Screen configuration
ServerLayout Overall layout
DRI DRI-specific configuration
Vendor Vendor-specific configuration
The following obsolete section names are still recognised for compatibility
purposes. In new config files, the InputDevice section should be used instead.
Keyboard Keyboard configuration
Pointer Pointer/mouse configuration
The old XInput section is no longer recognised.
The ServerLayout sections
are at the highest level. They bind together the input and output devices
that will be used in a session. The input devices are described in the
InputDevice sections. Output devices usually consist of multiple independent
components (e.g., a graphics board and a monitor). These multiple components
are bound together in the Screen sections, and it is these that are referenced
by the ServerLayout section. Each Screen section binds together a graphics
board and a monitor. The graphics boards are described in the Device sections,
and the monitors are described in the Monitor sections.
Config file keywords
are case-insensitive, and "_" characters are ignored. Most strings (including
Option names) are also case-insensitive, and insensitive to white space
and "_" characters.
Each config file entry usually takes up a single line
in the file. They consist of a keyword, which is possibly followed by one
or more arguments, with the number and types of the arguments depending
on the keyword. The argument types are:
Integer an integer number in decimal, hex or octal
Real a floating point number
String a string enclosed in double quote marks (")
Note: hex integer values must be prefixed with "0x", and octal values with
"0".
A special keyword called Option may be used to provide free-form data
to various components of the server. The Option keyword takes either one
or two string arguments. The first is the option name, and the optional
second argument is the option value. Some commonly used option value types
include:
Integer an integer number in decimal, hex or octal
Real a floating point number
String a sequence of characters
Boolean a boolean value (see below)
Frequency a frequency value (see below)
Note that all Option values, not just strings, must be enclosed in quotes.
Boolean options may optionally have a value specified. When no value is
specified, the option's value is TRUE. The following boolean option values
are recognised as TRUE:
1, on, true, yes
and the following boolean option
values are recognised as FALSE:
0, off, false, no
If an option name is
prefixed with "No", then the option value is negated.
Example: the following
option entries are equivalent:
Option "Accel" "Off"
Option "NoAccel"
Option "NoAccel" "On"
Option "Accel" "false"
Option "Accel" "no"
Frequency option values consist of a real number that is optionally followed
by one of the following frequency units:
Hz, k, kHz, M, MHz
When the unit
name is omitted, the correct units will be determined from the value and
the expectations of the appropriate range of the value. It is recommended
that the units always be specified when using frequency option values to
avoid any errors in determining the value.
The Files section
is used to specify some path names required by the server. Some of these
paths can also be set from the command line (see Xserver(1x)
and Xorg(1x)
).
The command line settings override the values specified in the config
file. The Files section is optional, as are all of the entries that may
appear in it.
The entries that can appear in this section are:
- FontPath
"path"
- sets the search path for fonts. This path is a comma separated list
of font path elements which the Xorg server searches for font databases.
Multiple FontPath entries may be specified, and they will be concatenated
to build up the fontpath used by the server. Font path elements may be
either absolute directory paths, or a font server identifier. Font server
identifiers have the form:
<trans>/<hostname>:<port-number>
where <trans> is the
transport type to use to connect to the font server (e.g., unix for UNIX-domain
sockets or tcp for a TCP/IP connection), <hostname> is the hostname of the
machine running the font server, and <port-number> is the port number that
the font server is listening on (usually 7100).
When this entry is not specified
in the config file, the server falls back to the compiled-in default font
path, which contains the following font path elements:
/usr/X11R6/lib/X11/fonts/misc/
/usr/X11R6/lib/X11/fonts/TTF/
/usr/X11R6/lib/X11/fonts/Type1/
/usr/X11R6/lib/X11/fonts/CID/
/usr/X11R6/lib/X11/fonts/75dpi/
/usr/X11R6/lib/X11/fonts/100dpi/
The recommended font path contains the following font path elements:
/usr/X11R6/lib/X11/fonts/local/
/usr/X11R6/lib/X11/fonts/misc/
/usr/X11R6/lib/X11/fonts/75dpi/:unscaled
/usr/X11R6/lib/X11/fonts/100dpi/:unscaled
/usr/X11R6/lib/X11/fonts/Type1/
/usr/X11R6/lib/X11/fonts/CID/
/usr/X11R6/lib/X11/fonts/Speedo/
/usr/X11R6/lib/X11/fonts/75dpi/
/usr/X11R6/lib/X11/fonts/100dpi/
Font path elements that are found to be invalid are removed from the font
path when the server starts up.
- RGBPath "path"
- sets the path name for the
RGB color database. When this entry is not specified in the config file,
the server falls back to the compiled-in default RGB path, which is:
/usr/X11R6/lib/X11/rgb
Note that an implicit .txt is added to this path if the server was compiled
to use text rather than binary format RGB color databases.
- ModulePath "path"
- sets the search path for loadable Xorg server modules. This path is a comma
separated list of directories which the Xorg server searches for loadable
modules loading in the order specified. Multiple ModulePath entries may
be specified, and they will be concatenated to build the module search
path used by the server.
In addition to options specific
to this section (described below), the ServerFlags section is used to specify
some global Xorg server options. All of the entries in this section are
Options, although for compatibility purposes some of the old style entries
are still recognised. Those old style entries are not documented here,
and using them is discouraged. The ServerFlags section is optional, as
are the entries that may be specified in it.
Options specified in this section
(with the exception of the "DefaultServerLayout" Option) may be overridden
by Options specified in the active ServerLayout section. Options with command
line equivalents are overridden when their command line equivalent is used.
The options recognised by this section are:
- Option "DefaultServerLayout"
"layout-id"
- This specifies the default ServerLayout section to use in the
absence of the -layout command line option.
- Option "NoTrapSignals" "boolean"
- This prevents the Xorg server from trapping a range of unexpected fatal
signals and exiting cleanly. Instead, the Xorg server will die and drop
core where the fault occurred. The default behaviour is for the Xorg server
to exit cleanly, but still drop a core file. In general you never want
to use this option unless you are debugging an Xorg server problem and
know how to deal with the consequences.
- Option "DontVTSwitch" "boolean"
- This disallows the use of the Ctrl+Alt+Fn sequence (where Fn refers to
one of the numbered function keys). That sequence is normally used to switch
to another "virtual terminal" on operating systems that have this feature.
When this option is enabled, that key sequence has no special meaning
and is passed to clients. Default: off.
- Option "DontZap" "boolean"
- This
disallows the use of the Ctrl+Alt+Backspace sequence. That sequence is
normally used to terminate the Xorg server. When this option is enabled,
that key sequence has no special meaning and is passed to clients. Default:
off.
- Option "DontZoom" "boolean"
- This disallows the use of the Ctrl+Alt+Keypad-Plus
and Ctrl+Alt+Keypad-Minus sequences. These sequences allows you to switch
between video modes. When this option is enabled, those key sequences have
no special meaning and are passed to clients. Default: off.
- Option "DisableVidModeExtension"
"boolean"
- This disables the parts of the VidMode extension used by the
xvidtune client that can be used to change the video modes. Default: the
VidMode extension is enabled.
- Option "AllowNonLocalXvidtune" "boolean"
- This allows the xvidtune client (and other clients that use the VidMode
extension) to connect from another host. Default: off.
- Option "DisableModInDev"
"boolean"
- This disables the parts of the Xorg-Misc extension that can be
used to modify the input device settings dynamically. Default: that functionality
is enabled.
- Option "AllowNonLocalModInDev" "boolean"
- This allows a client
to connect from another host and change keyboard and mouse settings in
the running server. Default: off.
- Option "AllowMouseOpenFail" "boolean"
- This allows the server to start up even if the mouse device can't be opened/initialised.
Default: false.
- Option "VTInit" "command"
- Runs command after the VT used
by the server has been opened. The command string is passed to "/bin/sh
-c", and is run with the real user's id with stdin and stdout set to the
VT. The purpose of this option is to allow system dependent VT initialisation
commands to be run. This option should rarely be needed. Default: not set.
- Option "VTSysReq" "boolean"
- enables the SYSV-style VT switch sequence for
non-SYSV systems which support VT switching. This sequence is Alt-SysRq followed
by a function key (Fn). This prevents the Xorg server trapping the keys
used for the default VT switch sequence, which means that clients can access
them. Default: off.
- Option "XkbDisable" "boolean"
- disable/enable the XKEYBOARD
extension. The -kb command line option overrides this config file option.
Default: XKB is enabled.
- Option "BlankTime" "time"
- sets the inactivity
timeout for the blanking phase of the screensaver. time is in minutes. This
is equivalent to the Xorg server's `-s' flag, and the value can be changed
at run-time with xset(1x)
. Default: 10 minutes.
- Option "StandbyTime" "time"
- sets the inactivity timeout for the "standby" phase of DPMS mode. time is
in minutes, and the value can be changed at run-time with xset(1x)
. Default:
20 minutes. This is only suitable for VESA DPMS compatible monitors, and
may not be supported by all video drivers. It is only enabled for screens
that have the "DPMS" option set (see the MONITOR section below).
- Option
"SuspendTime" "time"
- sets the inactivity timeout for the "suspend" phase
of DPMS mode. time is in minutes, and the value can be changed at run-time
with xset(1x)
. Default: 30 minutes. This is only suitable for VESA DPMS
compatible monitors, and may not be supported by all video drivers. It
is only enabled for screens that have the "DPMS" option set (see the MONITOR
section below).
- Option "OffTime" "time"
- sets the inactivity timeout for
the "off" phase of DPMS mode. time is in minutes, and the value can be changed
at run-time with xset(1x)
. Default: 40 minutes. This is only suitable for
VESA DPMS compatible monitors, and may not be supported by all video drivers.
It is only enabled for screens that have the "DPMS" option set (see the
MONITOR section below).
- Option "Pixmap" "bpp"
- This sets the pixmap format
to use for depth 24. Allowed values for bpp are 24 and 32. Default: 32
unless driver constraints don't allow this (which is rare). Note: some clients
don't behave well when this value is set to 24.
- Option "PC98" "boolean"
- Specify that the machine is a Japanese PC-98 machine. This should not be
enabled for anything other than the Japanese-specific PC-98 architecture.
Default: auto-detected.
- Option "NoPM" "boolean"
- Disables something to
do with power management events. Default: PM enabled on platforms that
support it.
- Option "Xinerama" "boolean"
- enable or disable XINERAMA extension.
Default is disabled.
- Option "AllowDeactivateGrabs" "boolean"
- This option
enables the use of the Ctrl+Alt+Keypad-Divide key sequence to deactivate
any active keyboard and mouse grabs. Default: off.
- Option "AllowClosedownGrabs"
"boolean"
- This option enables the use of the Ctrl+Alt+Keypad-Multiply key
sequence to kill clients with an active keyboard or mouse grab as well
as killing any application that may have locked the server, normally using
the XGrabServer(3x)
Xlib function. Default: off.
Note that the options AllowDeactivateGrabs and AllowClosedownGrabs will
allow users to remove the grab used by screen saver/locker programs. An
API was written to such cases. If you enable this option, make sure your
screen saver/locker is updated.
- Option "HandleSpecialKeys" "when"
- This option
controls when the server uses the builtin handler to process special key
combinations (such as Ctrl+Alt+Backspace). Normally the XKEYBOARD extension
keymaps will provide mappings for each of the special key combinations,
so the builtin handler is not needed unless the XKEYBOARD extension is
disabled. The value of when can be Always, Never, or WhenNeeded. Default:
Use the builtin handler only if needed. The server will scan the keymap
for a mapping to the Terminate action and, if found, use XKEYBOARD for
processing actions, otherwise the builtin handler will be used.
The
Module section is used to specify which Xorg server modules should be loaded.
This section is ignored when the Xorg server is built in static form. The
types of modules normally loaded in this section are Xorg server extension
modules, and font rasteriser modules. Most other module types are loaded
automatically when they are needed via other mechanisms. The Module section
is optional, as are all of the entries that may be specified in it.
Entries
in this section may be in two forms. The first and most commonly used
form is an entry that uses the Load keyword, as described here:
- Load "modulename"
- This instructs the server to load the module called modulename. The module
name given should be the module's standard name, not the module file name.
The standard name is case-sensitive, and does not include the "lib" prefix,
or the ".a", ".o", or ".so" suffixes.
Example: the Type 1 font rasteriser can
be loaded with the following entry:
Load "type1"
The second form of entry
is a SubSection, with the subsection name being the module name, and the
contents of the SubSection being Options that are passed to the module
when it is loaded.
Example: the extmod module (which contains a miscellaneous
group of server extensions) can be loaded, with the Xorg-DGA extension disabled
by using the following entry:
SubSection "extmod"
Option "omit XFree86-DGA"
EndSubSection
Modules are searched for in each directory specified in the ModulePath
search path, and in the drivers, input, extensions, fonts, and internal
subdirectories of each of those directories. In addition to this, operating
system specific subdirectories of all the above are searched first if they
exist.
To see what font and extension modules are available, check the contents
of the following directories:
/usr/X11R6/lib/modules/fonts
/usr/X11R6/lib/modules/extensions
The "bitmap" font modules is loaded automatically. It is recommended that
at very least the "extmod" extension module be loaded. If it isn't some
commonly used server extensions (like the SHAPE extension) will not be
available.
The config file may have multiple InputDevice
sections. There will normally be at least two: one for the core (primary)
keyboard, and one of the core pointer. If either of these two is missing,
a default configuration for the missing ones will be used. Currently the
default configuration may not work as expected on all platforms.
InputDevice
sections have the following format:
Section "InputDevice"
Identifier "name"
Driver "inputdriver"
options
...
EndSection
The Identifier and Driver entries are required in all InputDevice sections.
All other entries are optional.
The Identifier entry specifies the unique
name for this input device. The Driver entry specifies the name of the
driver to use for this input device. When using the loadable server, the
input driver module "inputdriver" will be loaded for each active InputDevice
section. An InputDevice section is considered active if it is referenced
by an active ServerLayout section, if it is referenced by the -keyboard
or -pointer command line options, or if it is selected implicitly as the
core pointer or keyboard device in the absence of such explicit references.
The most commonly used input drivers are "keyboard" and "mouse".
In the
absence of an explicitly specified core input device, the first InputDevice
marked as CorePointer (or CoreKeyboard) is used. If there is no match there,
the first InputDevice that uses the "mouse" (or "keyboard" or "kbd") driver
is used. The final fallback is to use built-in default configurations.
InputDevice
sections recognise some driver-independent Options, which are described
here. See the individual input driver manual pages for a description of
the device-specific options.
- Option "CorePointer"
- When this is set, the input
device is installed as the core (primary) pointer device. There must be
exactly one core pointer. If this option is not set here, or in the ServerLayout
section, or from the -pointer command line option, then the first input
device that is capable of being used as a core pointer will be selected
as the core pointer. This option is implicitly set when the obsolete Pointer
section is used.
- Option "CoreKeyboard"
- When this is set, the input device
is to be installed as the core (primary) keyboard device. There must be
exactly one core keyboard. If this option is not set here, in the ServerLayout
section, or from the -keyboard command line option, then the first input
device that is capable of being used as a core keyboard will be selected
as the core keyboard. This option is implicitly set when the obsolete Keyboard
section is used.
- Option "AlwaysCore" "boolean"
- Option "SendCoreEvents"
"boolean"
- Both of these options are equivalent, and when enabled cause
the input device to always report core events. This can be used, for example,
to allow an additional pointer device to generate core pointer events (like
moving the cursor, etc).
- Option "HistorySize" "number"
- Sets the motion
history size. Default: 0.
- Option "SendDragEvents" "boolean"
- ???
The config file may have multiple Device sections. There must be
at least one, for the video card being used.
Device sections have the following
format:
Section "Device"
Identifier "name"
Driver "driver"
entries
...
EndSection
The Identifier and Driver entries are required in all Device sections.
All other entries are optional.
The Identifier entry specifies the unique
name for this graphics device. The Driver entry specifies the name of the
driver to use for this graphics device. When using the loadable server,
the driver module "driver" will be loaded for each active Device section.
A Device section is considered active if it is referenced by an active
Screen section.
Device sections recognise some driver-independent entries
and Options, which are described here. Not all drivers make use of these
driver-independent entries, and many of those that do don't require them
to be specified because the information is auto-detected. See the individual
graphics driver manual pages for further information about this, and for
a description of the device-specific options. Note that most of the Options
listed here (but not the other entries) may be specified in the Screen
section instead of here in the Device section.
- BusID "bus-id"
- This specifies
the bus location of the graphics card. For PCI/AGP cards, the bus-id string
has the form PCI:bus:device:function (e.g., "PCI:1:0:0" might be appropriate
for an AGP card). This field is usually optional in single-head configurations
when using the primary graphics card. In multi-head configurations, or when
using a secondary graphics card in a single-head configuration, this entry
is mandatory. Its main purpose is to make an unambiguous connection between
the device section and the hardware it is representing. This information
can usually be found by running the Xorg server with the -scanpci command
line option.
- Screen number
- This option is mandatory for cards where a single
PCI entity can drive more than one display (i.e., multiple CRTCs sharing
a single graphics accelerator and video memory). One Device section is
required for each head, and this parameter determines which head each of
the Device sections applies to. The legal values of number range from 0
to one less than the total number of heads per entity. Most drivers require
that the primary screen (0) be present.
- Chipset "chipset"
- This usually
optional entry specifies the chipset used on the graphics board. In most
cases this entry is not required because the drivers will probe the hardware
to determine the chipset type. Don't specify it unless the driver-specific
documentation recommends that you do.
- Ramdac "ramdac-type"
- This optional
entry specifies the type of RAMDAC used on the graphics board. This is
only used by a few of the drivers, and in most cases it is not required
because the drivers will probe the hardware to determine the RAMDAC type
where possible. Don't specify it unless the driver-specific documentation
recommends that you do.
- DacSpeed speed
- DacSpeed speed-8 speed-16 speed-24
speed-32
- This optional entry specifies the RAMDAC speed rating (which is
usually printed on the RAMDAC chip). The speed is in MHz. When one value
is given, it applies to all framebuffer pixel sizes. When multiple values
are give, they apply to the framebuffer pixel sizes 8, 16, 24 and 32 respectively.
This is not used by many drivers, and only needs to be specified when
the speed rating of the RAMDAC is different from the defaults built in
to driver, or when the driver can't auto-detect the correct defaults. Don't
specify it unless the driver-specific documentation recommends that you
do.
- Clocks clock ...
- specifies the pixel that are on your graphics board.
The clocks are in MHz, and may be specified as a floating point number.
The value is stored internally to the nearest kHz. The ordering of the
clocks is important. It must match the order in which they are selected
on the graphics board. Multiple Clocks lines may be specified, and each
is concatenated to form the list. Most drivers do not use this entry, and
it is only required for some older boards with non-programmable clocks.
Don't specify this entry unless the driver-specific documentation explicitly
recommends that you do.
- ClockChip "clockchip-type"
- This optional entry is
used to specify the clock chip type on graphics boards which have a programmable
clock generator. Only a few Xorg drivers support programmable clock chips.
For details, see the appropriate driver manual page.
- VideoRam mem
- This
optional entry specifies the amount of video ram that is installed on the
graphics board. This is measured in kBytes. In most cases this is not required
because the Xorg server probes the graphics board to determine this quantity.
The driver-specific documentation should indicate when it might be needed.
- BiosBase baseaddress
- This optional entry specifies the base address of
the video BIOS for the VGA board. This address is normally auto-detected,
and should only be specified if the driver-specific documentation recommends
it.
- MemBase baseaddress
- This optional entry specifies the memory base address
of a graphics board's linear frame buffer. This entry is not used by many
drivers, and it should only be specified if the driver-specific documentation
recommends it.
- IOBase baseaddress
- This optional entry specifies the IO
base address. This entry is not used by many drivers, and it should only
be specified if the driver-specific documentation recommends it.
- ChipID
id
- This optional entry specifies a numerical ID representing the chip type.
For PCI cards, it is usually the device ID. This can be used to override
the auto-detection, but that should only be done when the driver-specific
documentation recommends it.
- ChipRev rev
- This optional entry specifies
the chip revision number. This can be used to override the auto-detection,
but that should only be done when the driver-specific documentation recommends
it.
- TextClockFreq freq
- This optional entry specifies the pixel clock frequency
that is used for the regular text mode. The frequency is specified in MHz.
This is rarely used.
- Options
- Option flags may be specified in the Device
sections. These include driver-specific options and driver-independent options.
The former are described in the driver-specific documentation. Some of the
latter are described below in the section about the Screen section, and
they may also be included here.
Nobody wants to say
how this works. Maybe nobody knows ...
The config file may
have multiple Monitor sections. There should normally be at least one,
for the monitor being used, but a default configuration will be created
when one isn't specified.
Monitor sections have the following format:
Section "Monitor"
Identifier "name"
entries
...
EndSection
The only mandatory entry in a Monitor section is the Identifier entry.
The
Identifier entry specifies the unique name for this monitor. The Monitor
section provides information about the specifications of the monitor, monitor-specific
Options, and information about the video modes to use with the monitor.
Specifying video modes is optional because the server now has a built-in
list of VESA standard modes. When modes are specified explicitly in the
Monitor section (with the Modes, ModeLine, or UseModes keywords), built-in
modes with the same names are not included. Built-in modes with different
names are, however, still implicitly included.
The entries that may be used
in Monitor sections are described below.
- VendorName "vendor"
- This optional
entry specifies the monitor's manufacturer.
- ModelName "model"
- This optional
entry specifies the monitor's model.
- HorizSync horizsync-range
- gives the
range(s) of horizontal sync frequencies supported by the monitor. horizsync-range
may be a comma separated list of either discrete values or ranges of values.
A range of values is two values separated by a dash. By default the values
are in units of kHz. They may be specified in MHz or Hz if MHz or Hz is
added to the end of the line. The data given here is used by the Xorg server
to determine if video modes are within the specifications of the monitor.
This information should be available in the monitor's handbook. If this
entry is omitted, a default range of 28-33kHz is used.
- VertRefresh vertrefresh-range
- gives the range(s) of vertical refresh frequencies supported by the monitor.
vertrefresh-range may be a comma separated list of either discrete values
or ranges of values. A range of values is two values separated by a dash.
By default the values are in units of Hz. They may be specified in MHz
or kHz if MHz or kHz is added to the end of the line. The data given here
is used by the Xorg server to determine if video modes are within the specifications
of the monitor. This information should be available in the monitor's handbook.
If this entry is omitted, a default range of 43-72Hz is used.
- DisplaySize
width height
- This optional entry gives the width and height, in millimetres,
of the picture area of the monitor. If given this is used to calculate the
horizontal and vertical pitch (DPI) of the screen.
- Gamma gamma-value
- Gamma
red-gamma green-gamma blue-gamma
- This is an optional entry that can be used
to specify the gamma correction for the monitor. It may be specified as
either a single value or as three separate RGB values. The values should
be in the range 0.1 to 10.0, and the default is 1.0. Not all drivers are capable
of using this information.
- UseModes "modesection-id"
- Include the set of
modes listed in the Modes section called modesection-id. This make all of
the modes defined in that section available for use by this monitor.
- Mode
"name"
- This is an optional multi-line entry that can be used to provide
definitions for video modes for the monitor. In most cases this isn't necessary
because the built-in set of VESA standard modes will be sufficient. The
Mode keyword indicates the start of a multi-line video mode description.
The mode description is terminated with the EndMode keyword. The mode description
consists of the following entries:
- DotClock clock
- is the dot (pixel) clock
rate to be used for the mode.
- HTimings hdisp hsyncstart hsyncend htotal
- specifies the horizontal timings for the mode.
- VTimings vdisp vsyncstart
vsyncend vtotal
- specifies the vertical timings for the mode.
- Flags "flag"
...
- specifies an optional set of mode flags, each of which is a separate string
in double quotes. "Interlace" indicates that the mode is interlaced. "DoubleScan"
indicates a mode where each scanline is doubled. "+HSync" and "-HSync" can
be used to select the polarity of the HSync signal. "+VSync" and "-VSync"
can be used to select the polarity of the VSync signal. "Composite" can
be used to specify composite sync on hardware where this is supported. Additionally,
on some hardware, "+CSync" and "-CSync" may be used to select the composite
sync polarity.
- HSkew hskew
- specifies the number of pixels (towards the
right edge of the screen) by which the display enable signal is to be skewed.
Not all drivers use this information. This option might become necessary
to override the default value supplied by the server (if any). "Roving"
horizontal lines indicate this value needs to be increased. If the last
few pixels on a scan line appear on the left of the screen, this value
should be decreased.
- VScan vscan
- specifies the number of times each scanline
is painted on the screen. Not all drivers use this information. Values less
than 1 are treated as 1, which is the default. Generally, the "DoubleScan"
Flag mentioned above doubles this value.
- ModeLine "name" mode-description
- This entry is a more compact version of the Mode entry, and it also can
be used to specify video modes for the monitor. is a single line format
for specifying video modes. In most cases this isn't necessary because the
built-in set of VESA standard modes will be sufficient.
The mode-description
is in four sections, the first three of which are mandatory. The first
is the dot (pixel) clock. This is a single number specifying the pixel
clock rate for the mode in MHz. The second section is a list of four numbers
specifying the horizontal timings. These numbers are the hdisp, hsyncstart,
hsyncend, and htotal values. The third section is a list of four numbers
specifying the vertical timings. These numbers are the vdisp, vsyncstart,
vsyncend, and vtotal values. The final section is a list of flags specifying
other characteristics of the mode. Interlace indicates that the mode is
interlaced. DoubleScan indicates a mode where each scanline is doubled. +HSync
and -HSync can be used to select the polarity of the HSync signal. +VSync
and -VSync can be used to select the polarity of the VSync signal. Composite
can be used to specify composite sync on hardware where this is supported.
Additionally, on some hardware, +CSync and -CSync may be used to select
the composite sync polarity. The HSkew and VScan options mentioned above
in the Modes entry description can also be used here.
- Options
- Some Option
flags that may be useful to include in Monitor sections (when needed) include
"DPMS", and "SyncOnGreen".
The config file may have multiple
Modes sections, or none. These sections provide a way of defining sets
of video modes independently of the Monitor sections. Monitor sections may
include the definitions provided in these sections by using the UseModes
keyword. In most cases the Modes sections are not necessary because the
built-in set of VESA standard modes will be sufficient.
Modes sections have
the following format:
Section "Modes"
Identifier "name"
entries
...
EndSection
The Identifier entry specifies the unique name for this set of mode descriptions.
The other entries permitted in Modes sections are the Mode and ModeLine
entries that are described above in the Monitor section.
The
config file may have multiple Screen sections. There must be at least one,
for the "screen" being used. A "screen" represents the binding of a graphics
device (Device section) and a monitor (Monitor section). A Screen section
is considered "active" if it is referenced by an active ServerLayout section
or by the -screen command line option. If neither of those is present, the
first Screen section found in the config file is considered the active
one.
Screen sections have the following format:
Section "Screen"
Identifier "name"
Device "devid"
Monitor "monid"
entries
...
SubSection "Display"
entries
...
EndSubSection
...
EndSection
The Identifier and Device entries are mandatory. All others are optional.
The Identifier entry specifies the unique name for this screen. The Screen
section provides information specific to the whole screen, including screen-specific
Options. In multi-head configurations, there will be multiple active Screen
sections, one for each head. The entries available for this section are:
- Device "device-id"
- This mandatory entry specifies the Device section to
be used for this screen. This is what ties a specific graphics card to
a screen. The device-id must match the Identifier of a Device section in
the config file.
- Monitor "monitor-id"
- specifies which monitor description
is to be used for this screen. If a Monitor name is not specified, a default
configuration is used. Currently the default configuration may not function
as expected on all platforms.
- VideoAdaptor "xv-id"
- specifies an optional
Xv video adaptor description to be used with this screen.
- DefaultDepth
depth
- specifies which color depth the server should use by default. The
-depth command line option can be used to override this. If neither is specified,
the default depth is driver-specific, but in most cases is 8.
- DefaultFbBpp
bpp
- specifies which framebuffer layout to use by default. The -fbbpp command
line option can be used to override this. In most cases the driver will
chose the best default value for this. The only case where there is even
a choice in this value is for depth 24, where some hardware supports both
a packed 24 bit framebuffer layout and a sparse 32 bit framebuffer layout.
- Options
- Various Option flags may be specified in the Screen section. Some
are driver-specific and are described in the driver documentation. Others
are driver-independent, and will eventually be described here.
- Option "Accel"
- Enables XAA (X Acceleration Architecture), a mechanism that makes video
cards' 2D hardware acceleration available to the Xorg server. This option
is on by default, but it may be necessary to turn it off if there are bugs
in the driver. There are many options to disable specific accelerated operations,
listed below. Note that disabling an operation will have no effect if the
operation is not accelerated (whether due to lack of support in the hardware
or in the driver).
- Option "BiosLocation" "address"
- Set the location of the
BIOS for the Int10 module. One may select a BIOS of another card for posting
or the legacy V_BIOS range located at 0xc0000 or an alternative address
(BUS_ISA). This is only useful under very special circumstances and should
be used with extreme care.
- Option "InitPrimary" "boolean"
- Use the Int10
module to initialize the primary graphics card. Normally, only secondary
cards are soft-booted using the Int10 module, as the primary card has already
been initialized by the BIOS at boot time. Default: false.
- Option "NoInt10"
"boolean"
- Disables the Int10 module, a module that uses the int10 call
to the BIOS of the graphics card to initialize it. Default: false.
- Option
"NoMTRR"
- Disables MTRR (Memory Type Range Register) support, a feature
of modern processors which can improve video performance by a factor of
up to 2.5. Some hardware has buggy MTRR support, and some video drivers have
been known to exhibit problems when MTRR's are used.
- Option "XaaNoCPUToScreenColorExpandFill"
- Disables accelerated rectangular expansion blits from source patterns stored
in system memory (using a memory-mapped aperture).
- Option "XaaNoColor8x8PatternFillRect"
- Disables accelerated fills of a rectangular region with a full-color pattern.
- Option "XaaNoColor8x8PatternFillTrap"
- Disables accelerated fills of a trapezoidal
region with a full-color pattern.
- Option "XaaNoDashedBresenhamLine"
- Disables
accelerated dashed Bresenham line draws.
- Option "XaaNoDashedTwoPointLine"
- Disables accelerated dashed line draws between two arbitrary points.
- Option
"XaaNoImageWriteRect"
- Disables accelerated transfers of full-color rectangular
patterns from system memory to video memory (using a memory-mapped aperture).
- Option "XaaNoMono8x8PatternFillRect"
- Disables accelerated fills of a rectangular
region with a monochrome pattern.
- Option "XaaNoMono8x8PatternFillTrap"
- Disables
accelerated fills of a trapezoidal region with a monochrome pattern.
- Option
"XaaNoOffscreenPixmaps"
- Disables accelerated draws into pixmaps stored
in offscreen video memory.
- Option "XaaNoPixmapCache"
- Disables caching of
patterns in offscreen video memory.
- Option "XaaNoScanlineCPUToScreenColorExpandFill"
- Disables accelerated rectangular expansion blits from source patterns stored
in system memory (one scan line at a time).
- Option "XaaNoScanlineImageWriteRect"
- Disables accelerated transfers of full-color rectangular patterns from system
memory to video memory (one scan line at a time).
- Option "XaaNoScreenToScreenColorExpandFill"
- Disables accelerated rectangular expansion blits from source patterns stored
in offscreen video memory.
- Option "XaaNoScreenToScreenCopy"
- Disables accelerated
copies of rectangular regions from one part of video memory to another
part of video memory.
- Option "XaaNoSolidBresenhamLine"
- Disables accelerated
solid Bresenham line draws.
- Option "XaaNoSolidFillRect"
- Disables accelerated
solid-color fills of rectangles.
- Option "XaaNoSolidFillTrap"
- Disables accelerated
solid-color fills of Bresenham trapezoids.
- Option "XaaNoSolidHorVertLine"
- Disables accelerated solid horizontal and vertical line draws.
- Option "XaaNoSolidTwoPointLine"
- Disables accelerated solid line draws between two arbitrary points.
Each
Screen section may optionally contain one or more Display subsections.
Those subsections provide depth/fbbpp specific configuration information,
and the one chosen depends on the depth and/or fbbpp that is being used
for the screen. The Display subsection format is described in the section
below.
Each Screen section may have multiple Display
subsections. The "active" Display subsection is the first that matches
the depth and/or fbbpp values being used, or failing that, the first that
has neither a depth or fbbpp value specified. The Display subsections are
optional. When there isn't one that matches the depth and/or fbbpp values
being used, all the parameters that can be specified here fall back to
their defaults.
Display subsections have the following format:
SubSection "Display"
Depth depth
entries
...
EndSubSection
- Depth depth
- This entry specifies what colour depth the Display subsection
is to be used for. This entry is usually specified, but it may be omitted
to create a match-all Display subsection or when wishing to match only against
the FbBpp parameter. The range of depth values that are allowed depends
on the driver. Most driver support 8, 15, 16 and 24. Some also support
1 and/or 4, and some may support other values (like 30). Note: depth means
the number of bits in a pixel that are actually used to determine the pixel
colour. 32 is not a valid depth value. Most hardware that uses 32 bits
per pixel only uses 24 of them to hold the colour information, which means
that the colour depth is 24, not 32.
- FbBpp bpp
- This entry specifies the
framebuffer format this Display subsection is to be used for. This entry
is only needed when providing depth 24 configurations that allow a choice
between a 24 bpp packed framebuffer format and a 32bpp sparse framebuffer
format. In most cases this entry should not be used.
- Weight red-weight green-weight
blue-weight
- This optional entry specifies the relative RGB weighting to
be used for a screen is being used at depth 16 for drivers that allow multiple
formats. This may also be specified from the command line with the -weight
option (see Xorg(1x)
).
- Virtual xdim ydim
- This optional entry specifies
the virtual screen resolution to be used. xdim must be a multiple of either
8 or 16 for most drivers, and a multiple of 32 when running in monochrome
mode. The given value will be rounded down if this is not the case. Video
modes which are too large for the specified virtual size will be rejected.
If this entry is not present, the virtual screen resolution will be set
to accommodate all the valid video modes given in the Modes entry. Some
drivers/hardware combinations do not support virtual screens. Refer to the
appropriate driver-specific documentation for details.
- ViewPort x0 y0
- This
optional entry sets the upper left corner of the initial display. This is
only relevant when the virtual screen resolution is different from the
resolution of the initial video mode. If this entry is not given, then
the initial display will be centered in the virtual display area.
- Modes
"mode-name" ...
- This optional entry specifies the list of video modes to use.
Each mode-name specified must be in double quotes. They must correspond
to those specified or referenced in the appropriate Monitor section (including
implicitly referenced built-in VESA standard modes). The server will delete
modes from this list which don't satisfy various requirements. The first
valid mode in this list will be the default display mode for startup. The
list of valid modes is converted internally into a circular list. It is
possible to switch to the next mode with Ctrl+Alt+Keypad-Plus and to the
previous mode with Ctrl+Alt+Keypad-Minus. When this entry is omitted, the
valid modes referenced by the appropriate Monitor section will be used.
If the Monitor section contains no modes, then the selection will be taken
from the built-in VESA standard modes.
- Visual "visual-name"
- This optional
entry sets the default root visual type. This may also be specified from
the command line (see the Xserver(1x)
man page). The visual types available
for depth 8 are (default is PseudoColor):
StaticGray
GrayScale
StaticColor
PseudoColor
TrueColor
DirectColor
The visual type available for the depths 15, 16 and 24 are (default is
TrueColor):
TrueColor
DirectColor
Not all drivers support DirectColor at these depths.
The visual types available
for the depth 4 are (default is StaticColor):
StaticGray
GrayScale
StaticColor
PseudoColor
The visual type available for the depth 1 (monochrome) is StaticGray.
- Black
red green blue
- This optional entry allows the "black" colour to be specified.
This is only supported at depth 1. The default is black.
- White red green
blue
- This optional entry allows the "white" colour to be specified. This
is only supported at depth 1. The default is white.
- Options
- Option flags
may be specified in the Display subsections. These may include driver-specific
options and driver-independent options. The former are described in the
driver-specific documentation. Some of the latter are described above in
the section about the Screen section, and they may also be included here.
The config file may have multiple ServerLayout sections.
A "server layout" represents the binding of one or more screens (Screen
sections) and one or more input devices (InputDevice sections) to form
a complete configuration. In multi-head configurations, it also specifies
the relative layout of the heads. A ServerLayout section is considered
"active" if it is referenced by the -layout command line option or by an
Option "DefaultServerLayout" entry in the ServerFlags section (the former
takes precedence over the latter). If those options are not used, the first
ServerLayout section found in the config file is considered the active
one. If no ServerLayout sections are present, the single active screen
and two active (core) input devices are selected as described in the relevant
sections above.
ServerLayout sections have the following format:
Section "ServerLayout"
Identifier "name"
Screen "screen-id"
...
InputDevice "idev-id"
...
options
...
EndSection
Each ServerLayout section must have an Identifier entry and at least one
Screen entry.
The Identifier entry specifies the unique name for this server
layout. The ServerLayout section provides information specific to the whole
session, including session-specific Options. The ServerFlags options (described
above) may be specified here, and ones given here override those given
in the ServerFlags section.
The entries that may be used in this section
are described here.
- Screen screen-num "screen-id" position-information
- One
of these entries must be given for each screen being used in a session.
The screen-id field is mandatory, and specifies the Screen section being
referenced. The screen-num field is optional, and may be used to specify
the screen number in multi-head configurations. When this field is omitted,
the screens will be numbered in the order that they are listed in. The numbering
starts from 0, and must be consecutive. The position-information field describes
the way multiple screens are positioned. There are a number of different
ways that this information can be provided:
- x y
- Absolute x y
- These both
specify that the upper left corner's coordinates are (x,y). The Absolute
keyword is optional. Some older versions of Xorg (4.2 and earlier) don't
recognise the Absolute keyword, so it's safest to just specify the coordinates
without it.
- RightOf "screen-id"
- LeftOf "screen-id"
- Above "screen-id"
- Below "screen-id"
- Relative "screen-id" x y
- These give the screen's location
relative to another screen. The first four position the screen immediately
to the right, left, above or below the other screen. When positioning to
the right or left, the top edges are aligned. When positioning above or
below, the left edges are aligned. The Relative form specifies the offset
of the screen's origin (upper left corner) relative to the origin of another
screen.
- InputDevice "idev-id" "option" ...
- One of these entries should be given
for each input device being used in a session. Normally at least two are
required, one each for the core pointer and keyboard devices. If either
of those is missing, suitable InputDevice entries are searched for using
the method described above in the INPUTDEVICE section. The idev-id field
is mandatory, and specifies the name of the InputDevice section being referenced.
Multiple option fields may be specified, each in double quotes. The options
permitted here are any that may also be given in the InputDevice sections.
Normally only session-specific input device options would be used here.
The most commonly used options are:
"CorePointer"
"CoreKeyboard"
"SendCoreEvents"
and the first two should normally be used to indicate the core pointer
and core keyboard devices respectively.
- Options
- In addition to the following,
any option permitted in the ServerFlags section may also be specified here.
When the same option appears in both places, the value given here overrides
the one given in the ServerFlags section.
- Option "IsolateDevice" "bus-id"
- Restrict device resets to the specified bus-id. See the BusID option (described
in DEVICE SECTION, above) for the format of the bus-id parameter. This option
overrides SingleCard, if specified. At present, only PCI devices can be
isolated in this manner.
- Option "SingleCard" "boolean"
- As IsolateDevice,
except that the bus ID of the first device in the layout is used.
Here is
an example of a ServerLayout section for a dual headed configuration with
two mice:
Section "ServerLayout"
Identifier "Layout 1"
Screen "MGA 1"
Screen "MGA 2" RightOf "MGA 1"
InputDevice "Keyboard 1" "CoreKeyboard"
InputDevice "Mouse 1" "CorePointer"
InputDevice "Mouse 2" "SendCoreEvents"
Option "BlankTime" "5"
EndSection
This optional section is used to provide some information for
the Direct Rendering Infrastructure. Details about the format of this section
can be found on-line at <http://dri.freedesktop.org/
>.
The optional
Vendor section may be used to provide vendor-specific configuration information.
Multiple Vendor sections may be present, and they may contain an Identifier
entry and multiple Option flags. The data therein is not used in this release.
For an example of an xorg.conf file, see the file installed as /usr/X11R6/lib/X11/xorg.conf.eg.
X(7)
, Xserver(1x)
, Xorg(1x)
, apm(4)
,
This manual page was largely rewritten by David Dawes <dawes@xfree86.org>.
Table of Contents