From 1a038249967b51878bc492df42e24b2af797bb85 Mon Sep 17 00:00:00 2001
From: marha <marha@users.sourceforge.net>
Date: Fri, 21 May 2010 06:36:23 +0000
Subject: xserver git update 21/5/2010

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-<!DOCTYPE linuxdoc PUBLIC "-//Xorg//DTD linuxdoc//EN" [
- <!ENTITY % defs SYSTEM "X11/defs.ent"> %defs;
- <!-- config file keyword markup -->
- <!ENTITY s.key STARTTAG "bf">
- <!ENTITY e.key ENDTAG "bf">
- <!-- specific config file keywords -->
- <!ENTITY k.device "&s.key;Device&e.key;">
- <!ENTITY k.monitor "&s.key;Monitor&e.key;">
- <!ENTITY k.display "&s.key;Display&e.key;">
- <!ENTITY k.inputdevice "&s.key;InputDevice&e.key;">
- <!ENTITY k.screen "&s.key;Screen&e.key;">
- <!ENTITY k.serverlayout "&s.key;ServerLayout&e.key;">
- <!ENTITY k.driver "&s.key;Driver&e.key;">
- <!ENTITY k.module "&s.key;Module&e.key;">
- <!ENTITY k.identifier "&s.key;Identifier&e.key;">
- <!ENTITY k.serverflags "&s.key;ServerFlags&e.key;">
- <!-- command line markup -->
- <!ENTITY s.cmd STARTTAG "tt">
- <!ENTITY e.cmd ENDTAG "tt">
- <!-- inline code markup -->
- <!ENTITY s.code STARTTAG "tt">
- <!ENTITY e.code ENDTAG "tt">
- <!-- function indent -->
- <!ENTITY f.indent "&nl&nbsp&nbsp&nbsp&nbsp&nbsp&nbsp&nbsp&nbsp&nbsp&nbsp">
-] >
-
-<article>
-
-<title>XFree86 server 4.x Design (DRAFT)
-<author>The XFree86 Project, Inc
-<and>Updates for X11R&relvers; by Jim Gettys
-<date>19 December 2003
-
-
-
-
-
-
-
-<ident>
-$XFree86: xc/programs/Xserver/hw/xfree86/doc/sgml/DESIGN.sgml,v 1.53 2003/08/23 14:10:14 dawes Exp $
-</ident>
-
-
-<p>
-<bf>NOTE</bf>: This is a DRAFT document, and the interfaces described here
-are subject to change without notice.
-
-
-<sect>Preface
-<p>
-
-The broad design principles are:
-<itemize>
-  <item>keep it reasonable
-	<itemize>
-	  <item>We cannot rewrite the complete server
-	  <item>We don't want to re-invent the wheel
-	</itemize>
-  <item>keep it modular
-	<itemize>
-	  <item>As many things as possible should go into modules
-	  <item>The basic loader binary should be minimal
-	  <item>A clean design with well defined layering is important
-	  <item>DDX specific global variables are a nono
-	  <item>The structure should be flexible enough to allow
-		future extensions
-	  <item> The structure should minimize duplication of common code
-	</itemize>
-  <item>keep important features in mind
-	<itemize>
-	  <item>multiple screens, including multiple instances of drivers
-	  <item>mixing different color depths and visuals on different
-		and ideally even on the same screen
-	  <item>better control of the PCI device used
-	  <item>better config file parser
-	  <item>get rid of all VGA compatibility assumptions
-	</itemize>
-</itemize>
-
-Unless we find major deficiencies in the DIX layer, we should avoid
-making changes there.
-
-<sect>The xorg.conf File
-<p>
-
-The xorg.conf file format is similar to the old format, with the following
-changes:
-
-<sect1>&k.device; section
-<p>
-
-    The &k.device; sections are similar to what they used to be, and
-    describe hardware-specific information for a single video card.
-    &k.device;
-    Some new keywords are added:
-
-
-    <descrip>
-      <tag>Driver "drivername"</tag>
-        Specifies the name of the driver to be used for the card.  This
-        is mandatory.
-      <tag>BusID "busslot"</tag>
-        Specifies uniquely the location of the card on the bus.  The
-        purpose is to identify particular cards in a multi-headed
-        configuration.  The format of the argument is intentionally
-        vague, and may be architecture dependent.  For a PCI bus, it
-        is something like "bus:slot:func".
-    </descrip>
-
-    A &k.device; section is considered ``active'' if there is a reference
-    to it in an active &k.screen; section.
-
-<sect1>&k.screen; section
-<p>
-
-    The &k.screen; sections are similar to what they used to be.  They
-    no longer have a &k.driver; keyword, but an &k.identifier; keyword
-    is added.  (The &k.driver; keyword may be accepted in place of the
-    &k.identifier; keyword for compatibility purposes.)  The identifier
-    can be used to identify which screen is to be active when multiple
-    &k.screen sections are present.  It is possible to specify the active
-    screen from the command line.  A default is chosen in the absence
-    of one being specified.  A &k.screen; section is considered ``active''
-    if there is a reference to it either from the command line, or from
-    an active &k.serverlayout; section.
-
-<sect1>&k.inputdevice; section
-<p>
-
-    The &k.inputdevice; section is a new section that describes
-    configuration information for input devices.  It replaces the old
-    &s.key;Keyboard&e.key;, &s.key;Pointer&e.key; and &s.key;XInput&e.key;
-    sections.  Like the &k.device; section, it has two mandatory keywords:
-    &k.identifier; and &k.driver;.  For compatibility purposes the old
-    &s.key;Keyboard&e.key; and &s.key;Pointer&e.key; sections are
-    converted by the parser into &k.inputdevice; sections as follows:
-
-    <descrip>
-      <tag>&s.key;Keyboard&e.key;</tag>
-             &k.identifier; "Implicit Core Keyboard"<newline>
-             &k.driver; "keyboard"
-      <tag>&s.key;Pointer&e.key;</tag>
-             &k.identifier; "Implicit Core Pointer"<newline>
-             &k.driver; "mouse"
-    </descrip>
-
-    An &k.inputdevice; section is considered active if there is a
-    reference to it in an active &k.serverlayout; section.  An
-    &k.inputdevice; section may also be referenced implicitly if there
-    is no &k.serverlayout; section, if the &s.cmd;-screen&e.cmd; command
-    line options is used, or if the &k.serverlayout; section doesn't
-    reference any &k.inputdevice; sections.  In this case, the first
-    sections with drivers "keyboard" and "mouse" are used as the core
-    keyboard and pointer respectively.
-
-<sect1>&k.serverlayout; section
-<p>
-
-    The &k.serverlayout; section is a new section that is used to identify
-    which &k.screen; sections are to be used in a multi-headed configuration,
-    and the relative layout of those screens.  It also identifies which
-    &k.inputdevice; sections are to be used.  Each &k.serverlayout section
-    has an identifier, a list of &k.screen; section identifiers, and a list of
-    &k.inputdevice; section identifiers.  &k.serverflags; options may also be
-    included in a &k.serverlayout; section, making it possible to override
-    the global values in the &k.serverflags; section.
-
-    A &k.serverlayout; section can be made active by being referenced on
-    the command line.  In the absence of this, a default will be chosen
-    (the first one found).  The screen names may optionally be followed
-    by a number specifying the preferred screen number, and optionally
-    by information specifying the physical positioning of the screen,
-    either in absolute terms or relative to another screen (or screens).
-    When no screen number is specified, they are numbered according to
-    the order in which they are listed.  The old (now obsolete) method
-    of providing the positioning information is to give the names of
-    the four adjacent screens.  The order of these is top, bottom, left,
-    right.  Here is an example of a &k.serverlayout; section for two
-    screens using the old method, with the second located to the right
-    of the first:
-
-    <code>
-      Section "ServerLayout"
-        Identifier "Main Layout"
-        Screen     0 "Screen 1" ""  ""  ""  "Screen 2"
-        Screen     1 "Screen 2"
-        Screen     "Screen 3"
-      EndSection
-    </code>
-
-    The preferred way of specifying the layout is to explicitly specify
-    the screen's location in absolute terms or relative to another
-    screen.
-
-    In the absolute case, the upper left corner's coordinates are given
-    after the &s.key;Absolute&e.key; keyword.  If the coordinates are
-    omitted, a value of &s.code;(0,0)&e.code; is assumed.  An example
-    of absolute positioning follows:
-
-    <code>
-      Section "ServerLayout"
-        Identifier "Main Layout"
-        Screen     0 "Screen 1" Absolute 0 0
-        Screen     1 "Screen 2" Absolute 1024 0
-        Screen     "Screen 3" Absolute 2048 0
-      EndSection
-    </code>
-
-    In the relative case, the position is specified by either using one of
-    the following keywords followed by the name of the reference screen:
-
-    <quote>
-      &s.key;RightOf&nl;
-      LeftOf&nl;
-      Above&nl;
-      Below&nl;
-      Relative&e.key;
-    </quote>
-
-    When the &s.key;Relative&e.key; keyword is used, the reference screen
-    name is followed by the coordinates of the new screen's origin
-    relative to reference screen.  The following example shows how to use
-    some of the relative positioning options.
-
-    <code>
-      Section "ServerLayout"
-        Identifier "Main Layout"
-        Screen     0 "Screen 1"
-        Screen     1 "Screen 2" RightOf "Screen 1"
-        Screen     "Screen 3" Relative "Screen 1" 2048 0
-      EndSection
-    </code>
-
-<sect1>Options
-<p>
-
-    Options are used more extensively.  They may appear in most sections
-    now.  Options related to drivers can be present in the &k.screen;,
-    &k.device; and &k.monitor; sections and the &k.display; subsections.
-    The order of precedence is &k.display;, &k.screen;, &k.monitor;,
-    &k.device;.  Options have been extended to allow an optional value
-    to be specified in addition to the option name.  For more details
-    about options, see the <ref id="options" name="Options"> section
-    for details.
-
-<sect>Driver Interface
-<p>
-
-The driver interface consists of a minimal set of entry points that are
-required based on the external events that the driver must react to.
-No non-essential structure is imposed on the way they are used beyond
-that.  This is a significant difference compared with the old design.
-
-The entry points for drawing operations are already taken care of by
-the framebuffer code (including, XAA).  Extensions and enhancements to
-framebuffer code are outside the scope of this document.
-
-This approach to the driver interface provides good flexibility, but does
-increase the complexity of drivers.  To help address this, the XFree86
-common layer provides a set of ``helper'' functions to take care of things
-that most drivers need.  These helpers help minimise the amount of code
-duplication between drivers.  The use of helper functions by drivers is
-however optional, though encouraged.  The basic philosophy behind the
-helper functions is that they should be useful to many drivers, that
-they should balance this against the complexity of their interface.  It
-is inevitable that some drivers may find some helpers unsuitable and
-need to provide their own code.
-
-Events that a driver needs to react to are:
-
-   <descrip>
-   <tag>ScreenInit</tag>
-
-     An initialisation function is called from the DIX layer for each
-     screen at the start of each server generation.
-
-   <tag>Enter VT</tag>
-
-     The server takes control of the console.
-
-   <tag>Leave VT</tag>
-
-     The server releases control of the console.
-
-   <tag>Mode Switch</tag>
-
-     Change video mode.
-
-   <tag>ViewPort change</tag>
-
-     Change the origin of the physical view port.
-
-   <tag>ScreenSaver state change</tag>
-
-     Screen saver activation/deactivation.
-
-   <tag>CloseScreen</tag>
-
-     A close screen function is called from the DIX layer for each screen
-     at the end of each server generation.
-   </descrip>
-
-
-In addition to these events, the following functions are required by
-the XFree86 common layer:
-
-   <descrip>
-   <tag>Identify</tag>
-
-     Print a driver identifying message.
-
-   <tag>Probe</tag>
-
-     This is how a driver identifies if there is any hardware present that
-     it knows how to drive.
-
-   <tag>PreInit</tag>
-
-     Process information from the xorg.conf file, determine the
-     full characteristics of the hardware, and determine if a valid
-     configuration is present.
-   </descrip>
-
-The VidMode extension also requires:
-
-   <descrip>
-   <tag>ValidMode</tag>
-
-     Identify if a new mode is usable with the current configuration.
-     The PreInit function (and/or helpers it calls) may also make use
-     of the ValidMode function or something similar.
-   </descrip>
-
-
-Other extensions may require other entry points.  The drivers will
-inform the common layer of these in such cases.
-
-<sect>Resource Access Control Introduction
-<p>
-
-Graphics devices are accessed through ranges in I/O or memory space.
-While most modern graphics devices allow relocation of such ranges many
-of them still require the use of well established interfaces such as
-VGA memory and IO ranges or 8514/A IO ranges.  With modern buses (like
-PCI) it is possible for multiple video devices to share access to these
-resources.  The RAC (Resource Access Control) subsystem provides a
-mechanism for this.
-
-<sect1>Terms and Definitions
-<p>
-
-<sect2>Bus
-<p>
-
-    ``Bus'' is ambiguous as it is used for different things: it may refer
-    to physical incompatible extension connectors in a computer system.
-    The RAC system knows two such systems: The ISA bus and the PCI bus.
-    (On the software level EISA, MCA and VL buses are currently treated
-    like ISA buses).  ``Bus'' may also refer to logically different
-    entities on a single bus system which are connected via bridges.  A
-    PCI system may have several distinct PCI buses connecting each other
-    by PCI-PCI bridges or to the host CPU by HOST-PCI bridges.
-
-    Systems that host more than one bus system link these together using
-    bridges.  Bridges are a concern to RAC as they might block or pass
-    specific resources.  PCI-PCI bridges may be set up to pass VGA
-    resources to the secondary bus.  PCI-ISA buses pass any resources not
-    decoded on the primary PCI bus to the ISA bus.  This way VGA resources
-    (although exclusive on the ISA bus) can be shared by ISA and PCI
-    cards.  Currently HOST-PCI bridges are not yet handled by RAC as they
-    require specific drivers.
-
-<sect2>Entity
-<p>
-
-    The smallest independently addressable unit on a system bus is
-    referred to as an entity.  So far we know ISA and PCI entities.  PCI
-    entities can be located on the PCI bus by an unique ID consisting of
-    the bus, card and function number.
-
-<sect2>Resource
-<p>
-
-    ``Resource'' refers to a range of memory or I/O addresses an entity
-    can decode.
-
-    If a device is capable of disabling this decoding the resource is
-    called sharable.  For PCI devices a generic method is provided to
-    control resource decoding.  Other devices will have to provide a
-    device specific function to control decoding.
-
-    If the entity is capable of decoding this range at a different
-    location this resource is considered relocatable.
-
-    Resources which start at a specific address and occupy a single
-    continuous range are called block resources.
-
-    Alternatively resource addresses can be decoded in a way that they
-    satisfy the conditions:
-    <quote><verb>
-                    address & mask == base
-    </verb></quote>
-    and
-    <quote><verb>
-                       base & mask == base
-    </verb></quote>
-    Resources addressed in such a way are called sparse resources.
-
-<sect2>Server States
-<p>
-
-    The resource access control system knows two server states: the
-    SETUP and the OPERATING state.  The SETUP state is entered whenever
-    a mode change takes place or the server exits or does VT switching.
-    During this state all entity resources are under resource access
-    control.  During OPERATING state only those entities are controlled
-    which actually have shared resources that conflict with others.
-
-<sect>Control Flow in the Server and Mandatory Driver Functions
-<p>
-
-At the start of each server generation, &s.code;main()&e.code;
-(&s.code;dix/main.c&e.code;) calls the DDX function
-&s.code;InitOutput()&e.code;.  This is the first place that the DDX gets
-control.  &s.code;InitOutput()&e.code; is expected to fill in the global
-&s.code;screenInfo&e.code; struct, and one
-&s.code;screenInfo.screen[]&e.code; entry for each screen present.  Here
-is what &s.code;InitOutput()&e.code; does:
-
-<sect1>Parse the xorg.conf file
-<p>
-
-    This is done at the start of the first server generation only.
-
-    The xorg.conf file is read in full, and the resulting information
-    stored in data structures.  None of the parsed information is
-    processed at this point.  The parser data structures are opaque to
-    the video drivers and to most of the common layer code.
-
-    The entire file is parsed first to remove any section ordering
-    requirements.
-
-
-<sect1>Initial processing of parsed information and command line options
-<p>
-
-    This is done at the start of the first server generation only.
-
-    The initial processing is to determine paths like the
-    &s.key;ModulePath&e.key;, etc, and to determine which &k.serverlayout;,
-    &k.screen; and &k.device; sections are active.
-
-
-<sect1>Enable port I/O access
-<p>
-
-    Port I/O access is controlled from the XFree86 common layer, and is
-    ``all or nothing''.  It is enabled prior to calling driver probes, at
-    the start of subsequent server generations, and when VT switching
-    back to the Xserver.  It is disabled at the end of server generations,
-    and when VT switching away from the Xserver.
-
-    The implementation details of this may vary on different platforms.
-
-
-<sect1>General bus probe
-<p>
-
-    This is done at the start of the first server generation only.
-
-    In the case of ix86 machines, this will be a general PCI probe.
-    The full information obtained here will be available to the drivers.
-    This information persists for the life of the Xserver.  In the PCI
-    case, the PCI information for all video cards found is available by
-    calling &s.code;xf86GetPciVideoInfo()&e.code;.
-
-    <quote>
-    &s.code;pciVideoPtr *xf86GetPciVideoInfo(void)&e.code;
-    <quote><p>
-	returns a pointer to a list of pointers to
-	&s.code;pciVideoRec&e.code; entries, of which there is one for
-	each detected PCI video card.  The list is terminated with a
-	&s.code;NULL&e.code; pointer.  If no PCI video cards were
-	detected, the return value is &s.code;NULL&e.code;.
-
-    </quote>
-    </quote>
-
-    After the bus probe, the resource broker is initialised.
-
-
-<sect1>Load initial set of modules
-<p>
-
-    This is done at the start of the first server generation only.
-
-    The core server contains a list of mandatory modules.  These are loaded
-    first.  Currently the only module on this list is the bitmap font module.
-
-    The next set of modules loaded are those specified explicitly in the
-    &k.module; section of the config file.
-
-    The final set of initial modules are the driver modules referenced
-    by the active &k.device; and &k.inputdevice; sections in the config
-    file.  Each of these modules is loaded exactly once.
-
-
-<sect1>Register Video and Input Drivers
-<p>
-
-    This is done at the start of the first server generation only.
-
-    When a driver module is loaded, the loader calls its
-    &s.code;Setup&e.code; function.  For video drivers, this function
-    calls &s.code;xf86AddDriver()&e.code; to register the driver's
-    &s.code;DriverRec&e.code;, which contains a small set of essential
-    details and driver entry points required during the early phase of
-    &s.code;InitOutput()&e.code;.  &s.code;xf86AddDriver()&e.code; adds
-    it to the global &s.code;xf86DriverList[]&e.code; array.
-
-    The &s.code;DriverRec&e.code; contains the driver canonical name,
-    the &s.code;Identify()&e.code;,
-    &s.code;Probe()&e.code; and &s.code;AvailableOptions()&e.code;
-    function entry points as well as a pointer
-    to the driver's module (as returned from the loader when the driver
-    was loaded) and a reference count which keeps track of how many
-    screens are using the driver.  The entry driver entry points are
-    those required prior to the driver allocating and filling in its
-    &s.code;ScrnInfoRec&e.code;.
-
-    For a static server, the &s.code;xf86DriverList[]&e.code; array is
-    initialised at build time, and the loading of modules is not done.
-
-    A similar procedure is used for input drivers.  The input driver's
-    &s.code;Setup&e.code; function calls
-    &s.code;xf86AddInputDriver()&e.code; to register the driver's
-    &s.code;InputDriverRec&e.code;, which contains a small set of
-    essential details and driver entry points required during the early
-    phase of &s.code;InitInput()&e.code;.
-    &s.code;xf86AddInputDriver()&e.code; adds it to the global
-    &s.code;xf86InputDriverList[]&e.code; array.  For a static server,
-    the &s.code;xf86InputDriverList[]&e.code; array is initialised at
-    build time.
-
-    Both the &s.code;xf86DriverList[]&e.code; and
-    &s.code;xf86InputDriverList[]&e.code; arrays have been initialised
-    by the end of this stage.
-
-    Once all the drivers are registered, their
-    &s.code;ChipIdentify()&e.code; functions are called.
-
-    <quote>
-    &s.code;void ChipIdentify(int flags)&e.code;
-    <quote>
-      This is expected to print a message indicating the driver name,
-      a short summary of what it supports, and a list of the chipset
-      names that it supports.  It may use the xf86PrintChipsets() helper
-      to do this.
-    </quote>
-    </quote>
-
-    <quote>
-    &s.code;void xf86PrintChipsets(const char *drvname, const char *drvmsg,
-                     &f.indent;SymTabPtr chips)&e.code;
-    <quote>
-      This function provides an easy way for a driver's ChipIdentify
-      function to format the identification message.
-    </quote>
-    </quote>
-
-<sect1>Initialise Access Control
-<p>
-
-    This is done at the start of the first server generation only.
-
-    The Resource Access Control (RAC) subsystem is initialised before
-    calling any driver functions that may access hardware.  All generic
-    bus information is probed and saved (for restoration later).  All
-    (shared resource) video devices are disabled at the generic bus
-    level, and a probe is done to find the ``primary'' video device.  These
-    devices remain disabled for the next step.
-
-
-<sect1>Video Driver Probe<label id="probe">
-<p>
-    This is done at the start of the first server generation only.  The
-    &s.code;ChipProbe()&e.code; function of each registered video driver
-    is called.
-
-    <quote><p>
-    &s.code;Bool ChipProbe(DriverPtr drv, int flags)&e.code;
-    <quote><p>
-      The purpose of this is to identify all instances of hardware
-      supported by the driver.  The flags value is currently either 0,
-      &s.code;PROBE_DEFAULT&e.code; or &s.code;PROBE_DETECT&e.code;.
-      &s.code;PROBE_DETECT&e.code; is used if "-configure" or "-probe"
-      command line arguments are given and indicates to the
-      &s.code;Probe()&e.code; function that it should not configure the
-      bus entities and that no xorg.conf information is available.
-
-      The probe must find the active device sections that match the
-      driver by calling &s.code;xf86MatchDevice()&e.code;.  The number
-      of matches found limits the maximum number of instances for this
-      driver.  If no matches are found, the function should return
-      &s.code;FALSE&e.code; immediately.
-
-      Devices that cannot be identified by using device-independent
-      methods should be probed at this stage (keeping in mind that access
-      to all resources that can be disabled in a device-independent way
-      are disabled during this phase).  The probe must be a minimal
-      probe.  It should just determine if there is a card present that
-      the driver can drive.  It should use the least intrusive probe
-      methods possible.  It must not do anything that is not essential,
-      like probing for other details such as the amount of memory
-      installed, etc.  It is recommended that the
-      &s.code;xf86MatchPciInstances()&e.code; helper function be used
-      for identifying matching PCI devices, and similarly the
-      &s.code;xf86MatchIsaInstances()&e.code; for ISA (non-PCI) devices
-      (see the <ref id="rac" name="RAC"> section).  These helpers also
-      checks and claims the appropriate entity.  When not using the
-      helper, that should be done with &s.code;xf86CheckPciSlot()&e.code;
-      and &s.code;xf86ClaimPciSlot()&e.code; for PCI devices and
-      &s.code;xf86ClaimIsaSlot()&e.code; for ISA devices (see the
-      <ref id="rac" name="RAC"> section).
-
-      The probe must register all non-relocatable resources at this
-      stage.  If a resource conflict is found between exclusive resources
-      the driver will fail immediately.  This is usually best done with
-      the &s.code;xf86ConfigPciEntity()&e.code; helper function
-      for PCI and &s.code;xf86ConfigIsaEntity()&e.code; for ISA
-      (see the <ref id="rac" name="RAC"> section).  It is possible to
-      register some entity specific functions with those helpers.  When
-      not using the helpers, the &s.code;xf86AddEntityToScreen()&e.code;
-      &s.code;xf86ClaimFixedResources()&e.code; and
-      &s.code;xf86SetEntityFuncs()&e.code; should be used instead (see
-      the <ref id="rac" name="RAC"> section).
-
-      If a chipset is specified in an active device section which the
-      driver considers relevant (ie it has no driver specified, or the
-      driver specified matches the driver doing the probe), the Probe
-      must return &s.code;FALSE&e.code; if the chipset doesn't match
-      one supported by the driver.
-
-      If there are no active device sections that the driver considers
-      relevant, it must return &s.code;FALSE&e.code;.
-
-      Allocate a &s.code;ScrnInfoRec&e.code; for each active instance of the
-      hardware found, and fill in the basic information, including the
-      other driver entry points.   This is best done with the
-      &s.code;xf86ConfigIsaEntity()&e.code; helper function for ISA
-      instances or &s.code;xf86ConfigPciEntity()&e.code; for PCI instances.
-      These functions allocate a &s.code;ScrnInfoRec&e.code; for active
-      entities. Optionally &s.code;xf86AllocateScreen()&e.code;
-      function may also be used to allocate the &s.code;ScrnInfoRec&e.code;.
-      Any of these functions take care of initialising fields to defined
-      ``unused'' values.
-
-      Claim the entities for each instance of the hardware found.  This
-      prevents other drivers from claiming the same hardware.
-
-      Must leave hardware in the same state it found it in, and must not
-      do any hardware initialisation.
-
-      All detection can be overridden via the config file, and that
-      parsed information is available to the driver at this stage.
-
-      Returns &s.code;TRUE&e.code; if one or more instances are found,
-      and &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;int xf86MatchDevice(const char *drivername,
-		&f.indent;GDevPtr **driversectlist)&e.code;
-    <quote><p>
-
-      This function takes the name of the driver and returns via
-      &s.code;driversectlist&e.code; a list of device sections that
-      match the driver name.  The function return value is the number
-      of matches found.  If a fatal error is encountered the return
-      value is &s.code;-1&e.code;.
-
-      The caller should use &s.code;xfree()&e.code; to free
-      &s.code;*driversectlist&e.code; when it is no longer needed.
-
-    </quote>
-
-    &s.code;ScrnInfoPtr xf86AllocateScreen(DriverPtr drv, int flags)&e.code;
-    <quote><p>
-      This function allocates a new &s.code;ScrnInfoRec&e.code; in the
-      &s.code;xf86Screens[]&e.code; array.  This function is normally
-      called by the video driver &s.code;ChipProbe()&e.code; functions.
-      The return value is a pointer to the newly allocated
-      &s.code;ScrnInfoRec&e.code;.  The &s.code;scrnIndex&e.code;,
-      &s.code;origIndex&e.code;, &s.code;module&e.code; and
-      &s.code;drv&e.code; fields are initialised.  The reference count
-      in &s.code;drv&e.code; is incremented.  The storage for any
-      currently allocated ``privates'' pointers is also allocated and
-      the &s.code;privates&e.code; field initialised (the privates data
-      is of course not allocated or initialised).  This function never
-      returns on failure.  If the allocation fails, the server exits
-      with a fatal error.  The flags value is not currently used, and
-      should be set to zero.
-    </quote>
-    </quote>
-
-    At the completion of this, a list of &s.code;ScrnInfoRecs&e.code;
-    have been allocated in the &s.code;xf86Screens[]&e.code; array, and
-    the associated entities and fixed resources have been claimed.  The
-    following &s.code;ScrnInfoRec&e.code; fields must be initialised at
-    this point:
-
-    <quote><verb>
-          driverVersion
-          driverName
-          scrnIndex(*)
-          origIndex(*)
-          drv(*)
-          module(*)
-          name
-          Probe
-          PreInit
-          ScreenInit
-          EnterVT
-          LeaveVT
-          numEntities
-          entityList
-          access
-    </verb></quote>
-
-    <tt>(*)</tt> These are initialised when the &s.code;ScrnInfoRec&e.code;
-    is allocated, and not explicitly by the driver.
-
-    The following &s.code;ScrnInfoRec&e.code; fields must be initialised
-    if the driver is going to use them:
-
-    <quote><verb>
-          SwitchMode
-          AdjustFrame
-          FreeScreen
-          ValidMode
-    </verb></quote>
-
-<sect1>Matching Screens
-<p>
-
-    This is done at the start of the first server generation only.
-
-    After the Probe phase is finished, there will be some number of
-    &s.code;ScrnInfoRecs&e.code;.  These are then matched with the active
-    &k.screen; sections in the xorg.conf, and those not having an active
-    &k.screen; section are deleted.  If the number of remaining screens
-    is 0, &s.code;InitOutput()&e.code; sets
-    &s.code;screenInfo.numScreens&e.code; to &s.code;0&e.code; and
-    returns.
-
-    At this point the following fields of the &s.code;ScrnInfoRecs&e.code;
-    must be initialised:
-
-    <quote><verb>
-          confScreen
-    </verb></quote>
-
-
-<sect1>Allocate non-conflicting resources
-<p>
-
-    This is done at the start of the first server generation only.
-
-    Before calling the drivers again, the resource information collected
-    from the Probe phase is processed.  This includes checking the extent
-    of PCI resources for the probed devices, and resolving any conflicts
-    in the relocatable PCI resources.  It also reports conflicts, checks
-    bus routing issues, and anything else that is needed to enable the
-    entities for the next phase.
-
-    If any drivers registered an &s.code;EntityInit()&e.code; function
-    during the Probe phase, then they are called here.
-
-
-<sect1>Sort the Screens and pre-check Monitor Information
-<p>
-
-    This is done at the start of the first server generation only.
-
-    The list of screens is sorted to match the ordering requested in the
-    config file.
-
-    The list of modes for each active monitor is checked against the
-    monitor's parameters.  Invalid modes are pruned.
-
-
-<sect1>PreInit
-<p>
-
-    This is done at the start of the first server generation only.
-
-    For each &s.code;ScrnInfoRec&e.code;, enable access to the screens entities and call
-    the &s.code;ChipPreInit()&e.code; function.
-
-    <quote><p>
-    &s.code;Bool ChipPreInit(ScrnInfoRec screen, int flags)&e.code;
-    <quote><p>
-      The purpose of this function is to find out all the information
-      required to determine if the configuration is usable, and to
-      initialise those parts of the &s.code;ScrnInfoRec&e.code; that
-      can be set once at the beginning of the first server generation.
-
-      The number of entities registered for the screen should be checked
-      against the expected number (most drivers expect only one).  The
-      entity information for each of them should be retrieved (with
-      &s.code;xf86GetEntityInfo()&e.code;) and checked for the correct
-      bus type and that none of the sharable resources registered during
-      the Probe phase was rejected.
-
-      Access to resources for the entities that can be controlled in a
-      device-independent way are enabled before this function is called.
-      If the driver needs to access any resources that it has disabled
-      in an &s.code;EntityInit()&e.code; function that it registered,
-      then it may enable them here providing that it disables them before
-      this function returns.
-
-      This includes probing for video memory, clocks, ramdac, and all
-      other HW info that is needed.  It includes determining the
-      depth/bpp/visual and related info.  It includes validating and
-      determining the set of video modes that will be used (and anything
-      that is required to determine that).
-
-      This information should be determined in the least intrusive way
-      possible.  The state of the HW must remain unchanged by this
-      function.  Although video memory (including MMIO) may be mapped
-      within this function, it must be unmapped before returning.  Driver
-      specific information should be stored in a structure hooked into
-      the &s.code;ScrnInfoRec&e.code;'s &s.code;driverPrivate&e.code;
-      field.  Any other modules which require persistent data (ie data
-      that persists across server generations) should be initialised in
-      this function, and they should allocate a ``privates'' index to
-      hook their data into by calling
-      &s.code;xf86AllocateScrnInfoPrivateIndex().&e.code;  The ``privates''
-      data is persistent.
-
-      Helper functions for some of these things are provided at the
-      XFree86 common level, and the driver can choose to make use of
-      them.
-
-      All additional resources that the screen needs must be registered
-      here.  This should be done with
-      &s.code;xf86RegisterResources()&e.code;.  If some of the fixed
-      resources registered in the Probe phase are not needed or not
-      decoded by the hardware when in the OPERATING server state, their
-      status should be updated with
-      &s.code;xf86SetOperatingState()&e.code;.
-
-      Modules may be loaded at any point in this function, and all
-      modules that the driver will need must be loaded before the end
-      of this function.  Either the  &s.code;xf86LoadSubModule()&e.code;
-      or the &s.code;xf86LoadDrvSubModule()&e.code; function should be
-      used to load modules depending on whether a
-      &s.code;ScrnInfoRec&e.code; has been set up. A driver may unload
-      a module within this function if it was only needed temporarily,
-      and the &s.code;xf86UnloadSubModule()&e.code; function should be used
-      to do that.  Otherwise there is no need to explicitly unload modules
-      because the loader takes care of module dependencies and will
-      unload submodules automatically if/when the driver module is
-      unloaded.
-
-      The bulk of the &s.code;ScrnInfoRec&e.code; fields should be filled
-      out in this function.
-
-      &s.code;ChipPreInit()&e.code; returns &s.code;FALSE&e.code; when
-      the configuration is unusable in some way (unsupported depth, no
-      valid modes, not enough video memory, etc), and &s.code;TRUE&e.code;
-      if it is usable.
-
-      It is expected that if the &s.code;ChipPreInit()&e.code; function
-      returns &s.code;TRUE&e.code;, then the only reasons that subsequent
-      stages in the driver might fail are lack or resources (like xalloc
-      failures).  All other possible reasons for failure should be
-      determined by the &s.code;ChipPreInit()&e.code; function.
-
-    </quote>
-    </quote>
-
-    The &s.code;ScrnInfoRecs&e.code; for screens where the &s.code;ChipPreInit()&e.code; fails are removed.
-    If none remain, &s.code;InitOutput()&e.code; sets &s.code;screenInfo.numScreens&e.code; to &s.code;0&e.code; and returns.
-
-    At this point, further fields of the &s.code;ScrnInfoRecs&e.code; would normally be
-    filled in.  Most are not strictly mandatory, but many are required
-    by other layers and/or helper functions that the driver may choose
-    to use.  The documentation for those layers and helper functions
-    indicates which they require.
-
-    The following fields of the &s.code;ScrnInfoRecs&e.code; should be filled in if the
-    driver is going to use them:
-
-    <quote><verb>
-          monitor
-          display
-          depth
-          pixmapBPP
-          bitsPerPixel
-          weight                (>8bpp only)
-          mask                  (>8bpp only)
-          offset                (>8bpp only)
-          rgbBits               (8bpp only)
-          gamma
-          defaultVisual
-          maxHValue
-          maxVValue
-          virtualX
-          virtualY
-          displayWidth
-          frameX0
-          frameY0
-          frameX1
-          frameY1
-          zoomLocked
-          modePool
-          modes
-          currentMode
-          progClock             (TRUE if clock is programmable)
-          chipset
-          ramdac
-          clockchip
-          numClocks             (if not programmable)
-          clock[]               (if not programmable)
-          videoRam
-          biosBase
-          memBase
-          memClk
-          driverPrivate
-          chipID
-          chipRev
-    </verb></quote>
-
-    <quote><p>
-    &s.code;pointer xf86LoadSubModule(ScrnInfoPtr pScrn, const char *name)&e.code:
-      and
-    &s.code;pointer xf86LoadDrvSubModule(DriverPtr drv, const char *name)&e.code:
-    <quote><p>
-      Load a module that a driver depends on.  This function loads the
-      module &s.code;name&e.code; as a sub module of the driver.  The
-      return value is a handle identifying the new module.  If the load
-      fails, the return value will be &s.code;NULL&e.code;.  If a driver
-      needs to explicitly unload a module it has loaded in this way,
-      the return value must be saved and passed to
-      &s.code;xf86UnloadSubModule()&e.code; when unloading.
-
-    </quote>
-
-    &s.code;void xf86UnloadSubModule(pointer module)&e.code;
-    <quote><p>
-      Unloads the module referenced by &s.code;module&e.code;.
-      &s.code;module&e.code; should be a pointer returned previously
-      by &s.code;xf86LoadSubModule()&e.code; or
-      &s.code;xf86LoadDrvSubModule()&e.code; .
-
-    </quote>
-    </quote>
-
-<sect1>Cleaning up Unused Drivers
-<p>
-
-    At this point it is known which screens will be in use, and which
-    drivers are being used.  Unreferenced drivers (and modules they
-    may have loaded) are unloaded here.
-
-
-<sect1>Consistency Checks
-<p>
-
-    The parameters that must be global to the server, like pixmap formats,
-    bitmap bit order, bitmap scanline unit and image byte order are
-    compared for each of the screens.  If a mismatch is found, the server
-    exits with an appropriate message.
-
-
-<sect1>Check if Resource Control is Needed
-<p>
-
-    Determine if resource access control is needed.  This is the case
-    if more than one screen is used.  If necessary the RAC wrapper module
-    is loaded.
-
-<sect1>AddScreen (ScreenInit)
-<p>
-
-    At this point, the valid screens are known.
-    &s.code;AddScreen()&e.code; is called for each of them, passing
-    &s.code;ChipScreenInit()&e.code; as the argument.
-    &s.code;AddScreen()&e.code; is a DIX function that allocates a new
-    &s.code;screenInfo.screen[]&e.code; entry (aka
-    &s.code;pScreen&e.code;), and does some basic initialisation of it.
-    It then calls the &s.code;ChipScreenInit()&e.code; function, with
-    &s.code;pScreen&e.code; as one of its arguments.  If
-    &s.code;ChipScreenInit()&e.code; returns &s.code;FALSE&e.code;,
-    &s.code;AddScreen()&e.code; returns &s.code;-1&e.code;.  Otherwise
-    it returns the index of the screen.  &s.code;AddScreen()&e.code;
-    should only fail because of programming errors or failure to allocate
-    resources (like memory).  All configuration problems should be
-    detected BEFORE this point.
-
-    <quote><p>
-    &s.code;Bool ChipScreenInit(int index, ScreenPtr pScreen,
-	&f.indent;int argc, char **argv)&e.code;
-    <quote><p>
-      This is called at the start of each server generation.
-
-      Fill in all of &s.code;pScreen&e.code;, possibly doing some of
-      this by calling ScreenInit functions from other layers like mi,
-      framebuffers (cfb, etc), and extensions.
-
-      Decide which operations need to be placed under resource access
-      control.  The classes of operations are the frame buffer operations
-      (&s.code;RAC_FB&e.code;), the pointer operations
-      (&s.code;RAC_CURSOR&e.code;), the viewport change operations
-      (&s.code;RAC_VIEWPORT&e.code;) and the colormap operations
-      (&s.code;RAC_COLORMAP&e.code;).  Any operation that requires
-      resources which might be disabled during OPERATING state should
-      be set to use RAC.  This can be specified separately for memory
-      and IO resources (the &s.code;racMemFlags&e.code; and
-      &s.code;racIoFlags&e.code; fields of the &s.code;ScrnInfoRec&e.code;
-      respectively).
-
-      Map any video memory or other memory regions.
-
-      Save the video card state.  Enough state must be saved so that
-      the original state can later be restored.
-
-      Initialise the initial video mode.  The &s.code;ScrnInfoRec&e.code;'s
-      &s.code;vtSema&e.code; field should be set to &s.code;TRUE&e.code;
-      just prior to changing the video hardware's state.
-
-    </quote>
-    </quote>
-
-
-    The &s.code;ChipScreenInit()&e.code; function (or functions from other
-    layers that it calls) should allocate entries in the
-    &s.code;ScreenRec&e.code;'s &s.code;devPrivates&e.code; area by
-    calling &s.code;AllocateScreenPrivateIndex()&e.code; if it needs
-    per-generation storage.  Since the &s.code;ScreenRec&e.code;'s
-    &s.code;devPrivates&e.code; information is cleared for each server
-    generation, this is the correct place to initialise it.
-
-    After &s.code;AddScreen()&e.code; has successfully returned, the
-    following &s.code;ScrnInfoRec&e.code; fields are initialised:
-
-    <quote><verb>
-          pScreen
-          racMemFlags
-          racIoFlags
-    </verb></quote>
-
-    The &s.code;ChipScreenInit()&e.code; function should initialise the
-    &s.code;CloseScreen&e.code; and &s.code;SaveScreen&e.code; fields
-    of &s.code;pScreen&e.code;.  The old value of
-    &s.code;pScreen-&gt;CloseScreen&e.code; should be saved as part of
-    the driver's per-screen private data, allowing it to be called from
-    &s.code;ChipCloseScreen()&e.code;.  This means that the existing
-    &s.code;CloseScreen()&e.code; function is wrapped.
-
-<sect1>Finalising RAC Initialisation
-<p>
-
-    After all the &s.code;ChipScreenInit()&e.code; functions have been
-    called, each screen has registered its RAC requirements.  This
-    information is used to determine which shared resources are requested
-    by more than one driver and set the access functions accordingly.
-    This is done following these rules:
-
-    <enum>
-     <item>The sharable resources registered by each entity are compared.
-	If a resource is registered by more than one entity the entity
-	will be marked to indicate that it needs to share this resources
-	type (IO or MEM).
-
-     <item>A resource marked ``disabled'' during OPERATING state will be
-        ignored entirely.
-
-     <item>A resource marked ``unused'' will only conflict with an overlapping
-	resource of an other entity if the second is actually in use
-	during OPERATING state.
-
-     <item>If an ``unused'' resource was found to conflict but the entity
-	does not use any other resource of this type the entire resource
-	type will be disabled for that entity.
-    </enum>
-
-
-<sect1>Finishing InitOutput()
-<p>
-
-    At this point &s.code;InitOutput()&e.code; is finished, and all the
-    screens have been setup in their initial video mode.
-
-
-<sect1>Mode Switching
-<p>
-
-    When a SwitchMode event is received, &s.code;ChipSwitchMode()&e.code;
-    is called (when it exists):
-
-    <quote><p>
-    &s.code;Bool ChipSwitchMode(int index, DisplayModePtr mode, int flags)&e.code;
-    <quote><p>
-      Initialises the new mode for the screen identified by
-      &s.code;index;&e.code;.  The viewport may need to be adjusted
-      also.
-
-    </quote>
-    </quote>
-
-
-<sect1>Changing Viewport
-<p>
-
-    When a Change Viewport event is received,
-    &s.code;ChipAdjustFrame()&e.code; is called (when it exists):
-
-    <quote><p>
-    &s.code;void ChipAdjustFrame(int index, int x, int y, int flags)&e.code;
-    <quote><p>
-      Changes the viewport for the screen identified by
-      &s.code;index;&e.code;.
-
-      It should be noted that many chipsets impose restrictions on where the
-      viewport may be placed in the virtual resolution, either for alignment
-      reasons, or to prevent the start of the viewport from being positioned
-      within a pixel (as can happen in a 24bpp mode).  After calculating the
-      value the chipset's panning registers need to be set to for non-DGA
-      modes, this function should recalculate the ScrnInfoRec's
-      &s.code;frameX0&e.code;, &s.code;frameY0&e.code, &s.code;frameX1&e.code;
-      and &s.code;frameY1&e.code; fields to correspond to that value.  If
-      this is not done, switching to another mode might cause the position
-      of a hardware cursor to change.
-
-    </quote>
-    </quote>
-
-
-<sect1>VT Switching
-<p>
-
-    When a VT switch event is received, &s.code;xf86VTSwitch()&e.code;
-    is called.  &s.code;xf86VTSwitch()&e.code; does the following:
-
-    <descrip>
-    <tag>On ENTER:</tag>
-    <itemize>
-      <item>enable port I/O access
-
-      <item>save and initialise the bus/resource state
-
-      <item>enter the SETUP server state
-
-      <item>calls &s.code;ChipEnterVT()&e.code; for each screen
-
-      <item>enter the OPERATING server state
-
-      <item>validate GCs
-
-      <item>Restore fb from saved pixmap for each screen
-
-      <item>Enable all input devices
-    </itemize>
-    <tag>On LEAVE:</tag>
-    <itemize>
-      <item>Save fb to pixmap for each screen
-
-      <item>validate GCs
-
-      <item>enter the SETUP server state
-
-      <item>calls &s.code;ChipLeaveVT()&e.code; for each screen
-
-      <item>disable all input devices
-
-      <item>restore bus/resource state
-
-      <item>disables port I/O access
-    </itemize>
-    </descrip>
-
-    <quote><p>
-    &s.code;Bool ChipEnterVT(int index, int flags)&e.code;
-    <quote><p>
-      This function should initialise the current video mode and
-      initialise the viewport, turn on the HW cursor if appropriate,
-      etc.
-
-      Should it re-save the video state before initialising the video
-      mode?
-
-    </quote>
-
-    &s.code;void ChipLeaveVT(int index, int flags)&e.code;
-    <quote><p>
-      This function should restore the saved video state.  If
-      appropriate it should also turn off the HW cursor, and invalidate
-      any pixmap/font caches.
-
-    </quote>
-
-    Optionally, &s.code;ChipLeaveVT()&e.code; may also unmap memory
-    regions.  If so, &s.code;ChipEnterVT()&e.code; will need to remap
-    them.  Additionally, if an aperture used to access video memory is
-    unmapped and remapped in this fashion, &s.code;ChipEnterVT()&e.code;
-    will also need to notify the framebuffer layers of the aperture's new
-    location in virtual memory.  This is done with a call to the screen's
-    &s.code;ModifyPixmapHeader()&e.code; function, as follows
-
-    <quote><p>
-    &s.code;(*pScreen->ModifyPixmapHeader)(pScrn->ppix,
-        &f.indent;-1, -1, -1, -1, -1, <it>NewApertureAddress</it>);&e.code;
-    <quote><p>
-        where the &s.code``ppix''&e.code; field in a ScrnInfoRec
-        points to the pixmap used by the screen's
-        &s.code;SaveRestoreImage()&e.code; function to hold the screen's
-        contents while switched out.
-
-    </quote>
-    </quote>
-
-    Currently, aperture remapping, as described here, should not be
-    attempted if the driver uses the &s.code;xf8_16bpp&e.code; or
-    &s.code;xf8_32bpp&e.code; framebuffer layers.  A pending
-    restructuring of VT switching will address this restriction in
-    the near future.
-
-    </quote>
-
-    Other layers may wrap the &s.code;ChipEnterVT()&e.code; and
-    &s.code;ChipLeaveVT()&e.code; functions if they need to take some
-    action when these events are received.
-
-<sect1>End of server generation
-<p>
-
-    At the end of each server generation, the DIX layer calls
-    &s.code;ChipCloseScreen()&e.code; for each screen:
-
-    <quote><p>
-    &s.code;Bool ChipCloseScreen(int index, ScreenPtr pScreen)&e.code;
-    <quote><p>
-      This function should restore the saved video state and unmap the
-      memory regions.
-
-      It should also free per-screen data structures allocated by the
-      driver.  Note that the persistent data held in the
-      &s.code;ScrnInfoRec&e.code;'s &s.code;driverPrivate&e.code; field
-      should not be freed here because it is needed by subsequent server
-      generations.
-
-      The &s.code;ScrnInfoRec&e.code;'s &s.code;vtSema&e.code; field
-      should be set to &s.code;FALSE&e.code; once the video HW state
-      has been restored.
-
-      Before freeing the per-screen driver data the saved
-      &s.code;CloseScreen&e.code; value should be restored to
-      &s.code;pScreen-&gt;CloseScreen&e.code;, and that function should
-      be called after freeing the data.
-
-    </quote>
-    </quote>
-
-<sect>Optional Driver Functions
-<p>
-
-The functions outlined here can be called from the XFree86 common layer,
-but their presence is optional.
-
-<sect1>Mode Validation
-<p>
-
-    When a mode validation helper supplied by the XFree86-common layer is
-    being used, it can be useful to provide a function to check for hw
-    specific mode constraints:
-
-    <quote><p>
-    &s.code;ModeStatus ChipValidMode(int index, DisplayModePtr mode,
-                   &f.indent;Bool verbose, int flags)&e.code;
-    <quote><p>
-      Check the passed mode for hw-specific constraints, and return the
-      appropriate status value.
-
-    </quote>
-    </quote>
-
-<p>
-This function may also modify the effective timings and clock of the passed
-mode.  These have been stored in the mode's &s.code;Crtc*&e.code; and
-&s.code;SynthClock&e.code; elements, and have already been adjusted for
-interlacing, doublescanning, multiscanning and clock multipliers and dividers.
-The function should not modify any other mode field, unless it wants to modify
-the mode timings reported to the user by &s.code;xf86PrintModes()&e.code;.
-
-<p>
-The function is called once for every mode in the xorg.conf Monitor section
-assigned to the screen, with &s.code;flags&e.code; set to
-&s.code;MODECHECK_INITIAL&e.code;.  It is subsequently called for every mode
-in the xorg.conf Display subsection assigned to the screen, with
-&s.code;flags&e.code; set to &s.code;MODECHECK_FINAL&e.code;.  In the second
-case, the mode will have successfully passed all other tests.  In addition,
-the &s.code;ScrnInfoRec&e.code;'s &s.code;virtualX&e.code;,
-&s.code;virtualY&e.code; and &s.code;displayWidth&e.code; fields will have been
-set as if the mode to be validated were to be the last mode accepted.
-
-<p>
-In effect, calls with MODECHECK_INITIAL are intended for checks that do not
-depend on any mode other than the one being validated, while calls with
-MODECHECK_FINAL are intended for checks that may involve more than one mode.
-
-<sect1>Free screen data
-<p>
-
-    When a screen is deleted prior to the completion of the ScreenInit
-    phase the &s.code;ChipFreeScreen()&e.code; function is called when defined.
-
-    <quote><p>
-    &s.code;void ChipFreeScreen(int scrnindex, int flags)&e.code;
-    <quote><p>
-      Free any driver-allocated data that may have been allocated up to
-      and including an unsuccessful &s.code;ChipScreenInit()&e.code;
-      call.  This would predominantly be data allocated by
-      &s.code;ChipPreInit()&e.code; that persists across server
-      generations.  It would include the &s.code;driverPrivate&e.code;,
-      and any ``privates'' entries that modules may have allocated.
-
-    </quote>
-    </quote>
-
-
-<sect>Recommended driver functions
-<p>
-
-The functions outlined here are for internal use by the driver only.
-They are entirely optional, and are never accessed directly from higher
-layers.  The sample function declarations shown here are just examples.
-The interface (if any) used is up to the driver.
-
-<sect1>Save
-<p>
-
-    Save the video state.  This could be called from &s.code;ChipScreenInit()&e.code; and
-    (possibly) &s.code;ChipEnterVT()&e.code;.
-
-    <quote><p>
-    &s.code;void ChipSave(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      Saves the current state.  This will only be saving pre-server
-      states or states before returning to the server.  There is only
-      one current saved state per screen and it is stored in private
-      storage in the screen.
-
-    </quote>
-    </quote>
-
-<sect1>Restore
-<p>
-
-    Restore the original video state.  This could be called from the
-    &s.code;ChipLeaveVT()&e.code; and &s.code;ChipCloseScreen()&e.code;
-    functions.
-
-    <quote><p>
-    &s.code;void ChipRestore(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      Restores the saved state from the private storage.  Usually only
-      used for restoring text modes.
-
-    </quote>
-    </quote>
-
-
-<sect1>Initialise Mode
-<p>
-
-    Initialise a video mode.  This could be called from the
-    &s.code;ChipScreenInit()&e.code;, &s.code;ChipSwitchMode()&e.code;
-    and &s.code;ChipEnterVT()&e.code; functions.
-
-    <quote><p>
-    &s.code;Bool ChipModeInit(ScrnInfoPtr pScrn, DisplayModePtr mode)&e.code;
-    <quote><p>
-      Programs the hardware for the given video mode.
-
-    </quote>
-    </quote>
-
-
-<sect>Data and Data Structures
-<p>
-
-<sect1>Command line data
-<p>
-
-Command line options are typically global, and are stored in global
-variables.  These variables are read-only and are available to drivers
-via a function call interface.  Most of these command line values are
-processed via helper functions to ensure that they are treated consistently
-by all drivers.  The other means of access is provided for cases where
-the supplied helper functions might not be appropriate.
-
-Some of them are:
-
-<quote><verb>
-    xf86Verbose               verbosity level
-    xf86Bpp                   -bpp from the command line
-    xf86Depth                 -depth from the command line
-    xf86Weight                -weight from the command line
-    xf86Gamma                 -{r,g,b,}gamma from the command line
-    xf86FlipPixels            -flippixels from the command line
-    xf86ProbeOnly             -probeonly from the command line
-    defaultColorVisualClass   -cc from the command line
-</verb></quote>
-
-If we ever do allow for screen-specific command line options, we may
-need to rethink this.
-
-These can be accessed in a read-only manner by drivers with the following
-functions:
-
-    <quote><p>
-    &s.code;int xf86GetVerbosity()&e.code;
-    <quote><p>
-      Returns the value of &s.code;xf86Verbose&e.code;.
-
-    </quote>
-
-    &s.code;int xf86GetDepth()&e.code;
-    <quote><p>
-      Returns the &s.cmd;-depth&e.cmd; command line setting.  If not
-      set on the command line, &s.code;-1&e.code; is returned.
-
-    </quote>
-
-    &s.code;rgb xf86GetWeight()&e.code;
-    <quote><p>
-      Returns the &s.cmd;-weight&e.cmd; command line setting.  If not
-      set on the command line, &s.code;{0, 0, 0}&e.code; is returned.
-
-    </quote>
-
-    &s.code;Gamma xf86GetGamma()&e.code;
-    <quote><p>
-      Returns the &s.cmd;-gamma&e.cmd; or &s.cmd;-rgamma&e.cmd;,
-      &s.cmd;-ggamma&e.cmd;, &s.cmd;-bgamma&e.cmd; command line settings.
-      If not set on the command line, &s.code;{0.0, 0.0, 0.0}&e.code;
-      is returned.
-
-    </quote>
-
-    &s.code;Bool xf86GetFlipPixels()&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; if &s.cmd;-flippixels&e.cmd; is
-      present on the command line, and &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;const char *xf86GetServerName()&e.code;
-    <quote><p>
-      Returns the name of the X server from the command line.
-
-    </quote>
-    </quote>
-
-<sect1>Data handling
-<p>
-
-Config file data contains parts that are global, and parts that are
-Screen specific.  All of it is parsed into data structures that neither
-the drivers or most other parts of the server need to know about.
-
-The global data is typically not required by drivers, and as such, most
-of it is stored in the private &s.code;xf86InfoRec&e.code;.
-
-The screen-specific data collected from the config file is stored in
-screen, device, display, monitor-specific data structures that are separate
-from the &s.code;ScrnInfoRecs&e.code;, with the appropriate elements/fields
-hooked into the &s.code;ScrnInfoRecs&e.code; as required.  The screen
-config data is held in &s.code;confScreenRec&e.code;, device data in
-the &s.code;GDevRec&e.code;, monitor data in the &s.code;MonRec&e.code;,
-and display data in the &s.code;DispRec&e.code;.
-
-The XFree86 common layer's screen specific data (the actual data in use
-for each screen) is held in the &s.code;ScrnInfoRecs&e.code;.  As has
-been outlined above, the &s.code;ScrnInfoRecs&e.code; are allocated at probe
-time, and it is the responsibility of the Drivers' &s.code;Probe()&e.code;
-and &s.code;PreInit()&e.code; functions to finish filling them in based
-on both data provided on the command line and data provided from the
-Config file.  The precedence for this is:
-
-    <quote>
-    command line  -&gt;  config file  -&gt;  probed/default data
-    </quote>
-
-For most things in this category there are helper functions that the
-drivers can use to ensure that the above precedence is consistently
-used.
-
-As well as containing screen-specific data that the XFree86 common layer
-(including essential parts of the server infrastructure as well as helper
-functions) needs to access, it also contains some data that drivers use
-internally.  When considering whether to add a new field to the
-&s.code;ScrnInfoRec&e.code;, consider the balance between the convenience
-of things that lots of drivers need and the size/obscurity of the
-&s.code;ScrnInfoRec&e.code;.
-
-Per-screen driver specific data that cannot be accommodated with the
-static &s.code;ScrnInfoRec&e.code; fields is held in a driver-defined
-data structure, a pointer to which is assigned to the
-&s.code;ScrnInfoRec&e.code;'s &s.code;driverPrivate&e.code; field.  This
-is per-screen data that persists across server generations (as does the
-bulk of the static &s.code;ScrnInfoRec&e.code; data).  It would typically
-also include the video card's saved state.
-
-Per-screen data for other modules that the driver uses (for example,
-the XAA module) that is reset for each server generation is hooked into
-the &s.code;ScrnInfoRec&e.code; through it's &s.code;privates&e.code;
-field.
-
-Once it has stabilised, the data structures and variables accessible to
-video drivers will be documented here.  In the meantime, those things
-defined in the &s.code;xf86.h&e.code; and &s.code;xf86str.h&e.code;
-files are visible to video drivers.  Things defined in
-&s.code;xf86Priv.h&e.code; and &s.code;xf86Privstr.h&e.code; are NOT
-intended to be visible to video drivers, and it is an error for a driver
-to include those files.
-
-
-<sect1>Accessing global data
-<p>
-
-Some other global state information that the drivers may access via
-functions is as follows:
-
-    <quote><p>
-    &s.code;Bool xf86ServerIsExiting()&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; if the server is at the end of a
-      generation and is in the process of exiting, and
-      &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;Bool xf86ServerIsResetting()&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; if the server is at the end of a
-      generation and is in the process of resetting, and
-      &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;Bool xf86ServerIsInitialising()&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; if the server is at the beginning of
-      a generation and is in the process of initialising, and
-      &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;Bool xf86ServerIsOnlyProbing()&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; if the -probeonly command line flag
-      was specified, and &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;Bool xf86CaughtSignal()&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; if the server has caught a signal,
-      and &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-    </quote>
-
-<sect1>Allocating private data
-<p>
-
-A driver and any module it uses may allocate per-screen private storage
-in either the &s.code;ScreenRec&e.code; (DIX level) or
-&s.code;ScrnInfoRec&e.code; (XFree86 common layer level).
-&s.code;ScreenRec&e.code; storage persists only for a single server
-generation, and &s.code;ScrnInfoRec&e.code; storage persists across
-generations for the lifetime of the server.
-
-The &s.code;ScreenRec&e.code; &s.code;devPrivates&e.code; data must be
-reallocated/initialised at the start of each new generation.  This is
-normally done from the &s.code;ChipScreenInit()&e.code; function, and
-Init functions for other modules that it calls.  Data allocated in this
-way should be freed by the driver's &s.code;ChipCloseScreen()&e.code;
-functions, and Close functions for other modules that it calls.  A new
-&s.code;devPrivates&e.code; entry is allocated by calling the
-&s.code;AllocateScreenPrivateIndex()&e.code; function.
-
-    <quote><p>
-    &s.code;int AllocateScreenPrivateIndex()&e.code;
-    <quote><p>
-      This function allocates a new element in the
-      &s.code;devPrivates&e.code; field of all currently existing
-      &s.code;ScreenRecs&e.code;.  The return value is the index of this
-      new element in the &s.code;devPrivates&e.code; array.  The
-      &s.code;devPrivates&e.code; field is of type
-      &s.code;DevUnion&e.code;:
-
-	<verb>
-        typedef union _DevUnion {
-            pointer             ptr;
-            long                val;
-            unsigned long       uval;
-            pointer             (*fptr)(void);
-        } DevUnion;
-	</verb>
-
-      which allows the element to be used for any of the above types.
-      It is commonly used as a pointer to data that the caller allocates
-      after the new index has been allocated.
-
-      This function will return &s.code;-1&e.code; when there is an
-      error allocating the new index.
-
-    </quote>
-    </quote>
-
-The &s.code;ScrnInfoRec&e.code; &s.code;privates&e.code; data persists
-for the life of the server, so only needs to be allocated once.  This
-should be done from the &s.code;ChipPreInit()&e.code; function, and Init
-functions for other modules that it calls.  Data allocated in this way
-should be freed by the driver's &s.code;ChipFreeScreen()&e.code; functions,
-and Free functions for other modules that it calls.  A new
-&s.code;privates&e.code; entry is allocated by calling the
-&s.code;xf86AllocateScrnInfoPrivateIndex()&e.code; function.
-
-
-    <quote><p>
-    &s.code;int xf86AllocateScrnInfoPrivateIndex()&e.code;
-    <quote><p>
-      This function allocates a new element in the &s.code;privates&e.code;
-      field of all currently existing &s.code;ScrnInfoRecs&e.code;.
-      The return value is the index of this new element in the
-      &s.code;privates&e.code; array.  The &s.code;privates&e.code;
-      field is of type &s.code;DevUnion&e.code;:
-
-        <verb>
-        typedef union _DevUnion {
-            pointer             ptr;
-            long                val;
-            unsigned long       uval;
-            pointer             (*fptr)(void);
-        } DevUnion;
-        </verb>
-
-      which allows the element to be used for any of the above types.
-      It is commonly used as a pointer to data that the caller allocates
-      after the new index has been allocated.
-
-      This function will not return when there is an error allocating
-      the new index.  When there is an error it will cause the server
-      to exit with a fatal error.  The similar function for allocation
-      privates in the &s.code;ScreenRec&e.code;
-      (&s.code;AllocateScreenPrivateIndex()&e.code;) differs in this
-      respect by returning &s.code;-1&e.code; when the allocation fails.
-
-    </quote>
-    </quote>
-
-<sect>Keeping Track of Bus Resources<label id="rac">
-<p>
-
-<sect1>Theory of Operation
-<p>
-
-The XFree86 common layer has knowledge of generic access control mechanisms
-for devices on certain bus systems (currently the PCI bus) as well as
-of methods to enable or disable access to the buses itself.  Furthermore
-it can access information on resources decoded by these devices and if
-necessary modify it.
-
-When first starting the Xserver collects all this information, saves it
-for restoration, checks it for consistency, and if necessary, corrects
-it.  Finally it disables all resources on a generic level prior to
-calling any driver function.
-
-When the &s.code;Probe()&e.code; function of each driver is called the
-device sections are matched against the devices found in the system.
-The driver may probe devices at this stage that cannot be identified by
-using device independent methods.  Access to all resources that can be
-controlled in a device independent way is disabled.  The
-&s.code;Probe()&e.code; function should register all non-relocatable
-resources at this stage.  If a resource conflict is found between
-exclusive resources the driver will fail immediately.  Optionally the
-driver might specify an &s.code;EntityInit()&e.code;,
-&s.code;EntityLeave()&e.code; and &s.code;EntityEnter()&e.code; function.
-
-&s.code;EntityInit()&e.code; can be used to disable any shared resources
-that are not controlled by the generic access control functions.  It is
-called prior to the PreInit phase regardless if an entity is active or
-not.  When calling the &s.code;EntityInit()&e.code;,
-&s.code;EntityEnter()&e.code; and &s.code;EntityLeave()&e.code; functions
-the common level will disable access to all other entities on a generic
-level.  Since the common level has no knowledge of device specific
-methods to disable access to resources it cannot be guaranteed that
-certain resources are not decoded by any other entity until the
-&s.code;EntityInit()&e.code; or &s.code;EntityEnter()&e.code; phase is
-finished.  Device drivers should therefore register all those resources
-which they are going to disable.  If these resources are never to be
-used by any driver function they may be flagged &s.code;ResInit&e.code;
-so that they can be removed from the resource list after processing all
-&s.code;EntityInit()&e.code; functions.  &s.code;EntityEnter()&e.code;
-should disable decoding of all resources which are not registered as
-exclusive and which are not handled by the generic access control in
-the common level.  The difference to &s.code;EntityInit()&e.code; is
-that the latter one is only called once during lifetime of the server.
-It can therefore be used to set up variables prior to disabling resources.
-&s.code;EntityLeave()&e.code; should restore the original state when
-exiting the server or switching to a different VT.  It also needs to
-disable device specific access functions if they need to be disabled on
-server exit or VT switch.  The default state is to enable them before
-giving up the VT.
-
-In &s.code;PreInit()&e.code; phase each driver should check if any
-sharable resources it has registered during &s.code;Probe()&e.code; has
-been denied and take appropriate action which could simply be to fail.
-If it needs to access resources it has disabled during
-&s.code;EntitySetup()&e.code; it can do so provided it has registered
-these and will disable them before returning from
-&s.code;PreInit()&e.code;.  This also applies to all other driver
-functions.  Several functions are provided to request resource ranges,
-register these, correct PCI config space and add replacements for the
-generic access functions.  Resources may be marked ``disabled'' or
-``unused'' during OPERATING stage.  Although these steps could also be
-performed in &s.code;ScreenInit()&e.code;, this is not desirable.
-
-Following &s.code;PreInit()&e.code; phase the common level determines
-if resource access control is needed.  This is the case if more than
-one screen is used.  If necessary the RAC wrapper module is loaded.  In
-&s.code;ScreenInit()&e.code; the drivers can decide which operations
-need to be placed under RAC.  Available are the frame buffer operations,
-the pointer operations and the colormap operations.  Any operation that
-requires resources which might be disabled during OPERATING state should
-be set to use RAC.  This can be specified separately for memory and IO
-resources.
-
-When &s.code;ScreenInit()&e.code; phase is done the common level will
-determine which shared resources are requested by more than one driver
-and set the access functions accordingly.  This is done following these
-rules:
-
-<enum>
-<item>The sharable resources registered by each entity are compared.  If
-   a resource is registered by more than one entity the entity will be
-   marked to need to share this resources type (&s.code;IO&e.code; or
-   &s.code;MEM&e.code;).
-
-<item>A resource marked ``disabled'' during OPERATING state will be ignored
-   entirely.
-
-<item>A resource marked ``unused'' will only conflicts with an overlapping
-   resource of an other entity if the second is actually in use during
-   OPERATING state.
-
-<item>If an ``unused'' resource was found to conflict however the entity
-   does not use any other resource of this type the entire resource type
-   will be disabled for that entity.
-</enum>
-
-The driver has the choice among different ways to control access to
-certain resources:
-
-<enum>
-<item>It can rely on the generic access functions.  This is probably the
-   most common case.  Here the driver only needs to register any resource
-   it is going to use.
-
-<item>It can replace the generic access functions by driver specific
-   ones.  This will mostly be used in cases where no generic access
-   functions are available.  In this case the driver has to make sure
-   these resources are disabled when entering the &s.code;PreInit()&e.code;
-   stage.  Since the replacement functions are registered in
-   &s.code;PreInit()&e.code; the driver will have to enable these
-   resources itself if it needs to access them during this state.  The
-   driver can specify if the replacement functions can control memory
-   and/or I/O resources separately.
-
-<item>The driver can enable resources itself when it needs them.  Each
-   driver function enabling them needs to disable them before it will
-   return.  This should be used if a resource which can be controlled
-   in a device dependent way is only required during SETUP state.  This
-   way it can be marked ``unused'' during OPERATING state.
-</enum>
-
-A resource which is decoded during OPERATING state however never accessed
-by the driver should be marked unused.
-
-Since access switching latencies are an issue during Xserver operation,
-the common level attempts to minimize the number of entities that need
-to be placed under RAC control.  When a wrapped operation is called,
-the &s.code;EnableAccess()&e.code; function is called before control is
-passed on.  &s.code;EnableAccess()&e.code; checks if a screen is under
-access control.  If not it just establishes bus routing and returns.
-If the screen needs to be under access control,
-&s.code;EnableAccess()&e.code; determines which resource types
-(&s.code;MEM&e.code;, &s.code;IO&e.code;) are required.  Then it tests
-if this access is already established.  If so it simply returns.  If
-not it disables the currently established access, fixes bus routing and
-enables access to all entities registered for this screen.
-
-Whenever a mode switch or a VT-switch is performed the common level will
-return to SETUP state.
-
-<sect1>Resource Types
-<p>
-
-Resource have certain properties.  When registering resources each range
-is accompanied by a flag consisting of the ORed flags of the different
-properties the resource has.  Each resource range may be classified
-according to
-
-<itemize>
-  <item>its physical properties i.e., if it addresses
-       memory (&s.code;ResMem&e.code;)  or
-       I/O space (&s.code;ResIo&e.code;),
-  <item>if it addresses a
-       block (&s.code;ResBlock&e.code;) or
-       sparse (&s.code;ResSparse&e.code;)
-    range,
-  <item>its access properties.
-</itemize>
-
-There are two known access properties:
-
-<itemize>
-  <item>&s.code;ResExclusive&e.code;
-    for resources which may not be shared with any other device and
-  <item>&s.code;ResShared&e.code;
-    for resources which can be disabled and therefore can be shared.
-</itemize>
-
-If it is necessary to test a resource against any type a generic access
-type &s.code;ResAny&e.code; is provided.  If this is set the resource
-will conflict with any resource of a different entity intersecting its
-range.  Further it can be specified that a resource is decoded however
-never used during any stage (&s.code;ResUnused&e.code;) or during
-OPERATING state (&s.code;ResUnusedOpr&e.code;).  A resource only visible
-during the init functions (ie.  &s.code;EntityInit()&e.code;,
-&s.code;EntityEnter()&e.code; and &s.code;EntityLeave()&e.code; should
-be registered with the flag &s.code;ResInit&e.code;.  A resource that
-might conflict with background resource ranges may be flagged with
-&s.code;ResBios&e.code;.  This might be useful when registering resources
-ranges that were assigned by the system Bios.
-
-Several predefined resource lists are available for VGA and 8514/A
-resources in &s.code;common/xf86Resources.h&e.code;.
-
-<sect1>Available Functions<label id="avail">
-<p>
-
-The functions provided for resource management are listed in their order
-of use in the driver.
-
-
-<sect2>Probe Phase
-<p>
-
-In this phase each driver detects those resources it is able to drive,
-creates an entity record for each of them, registers non-relocatable
-resources and allocates screens and adds the resources to screens.
-
-Two helper functions are provided for matching device sections in the
-xorg.conf file to the devices:
-
-    <quote><p>
-    &s.code;int xf86MatchPciInstances(const char *driverName, int vendorID,
-		&f.indent;SymTabPtr chipsets, PciChipsets *PCIchipsets,
-                &f.indent;GDevPtr *devList, int numDevs, DriverPtr drvp,
-                &f.indent;int **foundEntities)&e.code;
-    <quote><p>
-      This function finds matches between PCI cards that a driver supports
-      and config file device sections.  It is intended for use in the
-      &s.code;ChipProbe()&e.code; function of drivers for PCI cards.
-      Only probed PCI devices with a vendor ID matching
-      &s.code;vendorID&e.code; are considered.  &s.code;devList&e.code;
-      and &s.code;numDevs&e.code; are typically those found from
-      calling &s.code;xf86MatchDevice()&e.code;, and represent the active
-      config file device sections relevant to the driver.
-      &s.code;PCIchipsets&e.code; is a table that provides a mapping
-      between the PCI device IDs, the driver's internal chipset tokens
-      and a list of fixed resources.
-
-      When a device section doesn't have a &s.key;BusID&e.key; entry it
-      can only match the primary video device.  Secondary devices are
-      only matched with device sections that have a matching
-      &s.key;BusID&e.key; entry.
-
-      Once the preliminary matches have been found, a final match is
-      confirmed by checking if the chipset override, ChipID override or
-      probed PCI chipset type match one of those given in the
-      &s.code;chipsets&e.code; and &s.code;PCIchipsets&e.code; lists.
-      The &s.code;PCIchipsets&e.code; list includes a list of the PCI
-      device IDs supported by the driver.  The list should be terminated
-      with an entry with PCI ID &s.code;-1&e.code;".  The
-      &s.code;chipsets&e.code; list is a table mapping the driver's
-      internal chipset tokens to names, and should be terminated with
-      a &s.code;NULL&e.code; entry.  Only those entries with a
-      corresponding entry in the &s.code;PCIchipsets&e.code; list are
-      considered.  The order of precedence is: config file chipset,
-      config file ChipID, probed PCI device ID.
-
-      In cases where a driver handles PCI chipsets with more than one
-      vendor ID, it may set &s.code;vendorID&e.code; to
-      &s.code;0&e.code;, and OR each devID in the list with (the
-      vendor&nbsp;ID&nbsp;&lt;&lt;&nbsp;16).
-
-      Entity index numbers for confirmed matches are returned as an
-      array via &s.code;foundEntities&e.code;.  The PCI information,
-      chipset token and device section for each match are found in the
-      &s.code;EntityInfoRec&e.code; referenced by the indices.
-
-      The function return value is the number of confirmed matches.  A
-      return value of &s.code;-1&e.code; indicates an internal error.
-      The returned &s.code;foundEntities&e.code; array should be freed
-      by the driver with &s.code;xfree()&e.code; when it is no longer
-      needed in cases where the return value is greater than zero.
-
-    </quote>
-
-    &s.code;int xf86MatchIsaInstances(const char *driverName,
-		     &f.indent;SymTabPtr chipsets, IsaChipsets *ISAchipsets,
-		     &f.indent;DriverPtr drvp, FindIsaDevProc FindIsaDevice,
-		     &f.indent;GDevPtr *devList, int numDevs,
-					int **foundEntities)&e.code;
-    <quote><p>
-      This function finds matches between ISA cards that a driver supports
-      and config file device sections.  It is intended for use in the
-      &s.code;ChipProbe()&e.code; function of drivers for ISA cards.
-      &s.code;devList&e.code; and &s.code;numDevs&e.code; are
-      typically those found from calling &s.code;xf86MatchDevice()&e.code;,
-      and represent the active config file device sections relevant to
-      the driver.  &s.code;ISAchipsets&e.code; is a table that provides
-      a mapping between the driver's internal chipset tokens and the
-      resource classes.  &s.code;FindIsaDevice&e.code; is a
-      driver-provided function that probes the hardware and returns the
-      chipset token corresponding to what was detected, and
-      &s.code;-1&e.code; if nothing was detected.
-
-      If the config file device section contains a chipset entry, then
-      it is checked against the &s.code;chipsets&e.code; list.  When
-      no chipset entry is present, the &s.code;FindIsaDevice&e.code;
-      function is called instead.
-
-      Entity index numbers for confirmed matches are returned as an
-      array via &s.code;foundEntities&e.code;.  The chipset token and
-      device section for each match are found in the
-      &s.code;EntityInfoRec&e.code; referenced by the indices.
-
-      The function return value is the number of confirmed matches.  A
-      return value of &s.code;-1&e.code; indicates an internal error.
-      The returned &s.code;foundEntities&e.code; array should be freed
-      by the driver with &s.code;xfree()&e.code; when it is no longer
-      needed in cases where the return value is greater than zero.
-
-    </quote>
-    </quote>
-
-These two helper functions make use of several core functions that are
-available at the driver level:
-
-    <quote><p>
-    &s.code;Bool xf86ParsePciBusString(const char *busID, int *bus,
-			&f.indent;int *device, int *func)&e.code;
-    <quote><p>
-      Takes a &s.code;BusID&e.code; string, and if it is in the correct
-      format, returns the PCI &s.code;bus&e.code;, &s.code;device&e.code;,
-      &s.code;func&e.code; values that it indicates.  The format of the
-      string is expected to be "PCI:bus:device:func" where each of `bus',
-      `device' and `func' are decimal integers.  The ":func" part may
-      be omitted, and the func value assumed to be zero, but this isn't
-      encouraged.  The "PCI" prefix may also be omitted.  The prefix
-      "AGP" is currently equivalent to the "PCI" prefix.  If the string
-      isn't a valid PCI BusID, the return value is &s.code;FALSE&e.code;.
-
-    </quote>
-
-
-    &s.code;Bool xf86ComparePciBusString(const char *busID, int bus,
-			&f.indent;int device, int func)&e.code;
-    <quote><p>
-      Compares a &s.code;BusID&e.code; string with PCI &s.code;bus&e.code;,
-      &s.code;device&e.code;, &s.code;func&e.code; values.  If they
-      match &s.code;TRUE&e.code; is returned, and &s.code;FALSE&e.code;
-      if they don't.
-
-    </quote>
-
-    &s.code;Bool xf86ParseIsaBusString(const char *busID)&e.code;
-    <quote><p>
-      Compares a &s.code;BusID&e.code; string with the ISA bus ID string
-      ("ISA" or "ISA:").  If they match &s.code;TRUE&e.code; is returned,
-      and &s.code;FALSE&e.code; if they don't.
-
-    </quote>
-
-    &s.code;Bool xf86CheckPciSlot(int bus, int device, int func)&e.code;
-    <quote><p>
-      Checks if the PCI slot &s.code;bus:device:func&e.code; has been
-      claimed.  If so, it returns &s.code;FALSE&e.code;, and otherwise
-      &s.code;TRUE&e.code;.
-
-    </quote>
-
-    &s.code;int xf86ClaimPciSlot(int bus, int device, int func, DriverPtr drvp,
-			&f.indent;int chipset, GDevPtr dev, Bool active)&e.code;
-    <quote><p>
-      This function is used to claim a PCI slot, allocate the associated
-      entity record and initialise their data structures.  The return
-      value is the index of the newly allocated entity record, or
-      &s.code;-1&e.code; if the claim fails.  This function should always
-      succeed if &s.code;xf86CheckPciSlot()&e.code; returned
-      &s.code;TRUE&e.code; for the same PCI slot.
-
-    </quote>
-
-    &s.code;Bool xf86IsPrimaryPci(void)&e.code;
-    <quote><p>
-      This function returns &s.code;TRUE&e.code; if the primary card is
-      a PCI device, and &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-
-    &s.code;int xf86ClaimIsaSlot(DriverPtr drvp, int chipset,
-			&f.indent;GDevPtr dev, Bool active)&e.code;
-    <quote><p>
-      This allocates an entity record entity and initialise the data
-      structures.  The return value is the index of the newly allocated
-      entity record.
-
-    </quote>
-
-    &s.code;Bool xf86IsPrimaryIsa(void)&e.code;
-    <quote><p>
-      This function returns &s.code;TRUE&e.code; if the primary card is
-      an ISA (non-PCI) device, and &s.code;FALSE&e.code; otherwise.
-
-    </quote>
-    </quote>
-
-Two helper functions are provided to aid configuring entities:
-    <quote><p>
-    &s.code;ScrnInfoPtr xf86ConfigPciEntity(ScrnInfoPtr pScrn,
-                                 &f.indent;int scrnFlag, int entityIndex,
-                                 &f.indent;PciChipsets *p_chip,
-                                 &f.indent;resList res, EntityProc init,
-                                 &f.indent;EntityProc enter, EntityProc leave,
-                                 &f.indent;pointer private)&e.code;
-    <p>
-    &s.code;ScrnInfoPtr xf86ConfigIsaEntity(ScrnInfoPtr pScrn,
-                                 &f.indent;int scrnFlag, int entityIndex,
-                                 &f.indent;IsaChipsets *i_chip,
-                                 &f.indent;resList res, EntityProc init,
-                                 &f.indent;EntityProc enter, EntityProc leave,
-                                 &f.indent;pointer private)&e.code;
-    <quote><p>
-      These functions are used to register the non-relocatable resources
-      for an entity, and the optional entity-specific &s.code;Init&e.code;, &s.code;Enter&e.code; and
-      &s.code;Leave&e.code; functions.  Usually the list of fixed resources is obtained
-      from the Isa/PciChipsets lists.  However an additional list of
-      resources may be passed.  Generally this is not required.
-      For active entities a &s.code;ScrnInfoRec&e.code; is allocated
-      if the &s.code;pScrn&e.code; argument is &s.code;NULL&e.code;.
-The
-      return value is &s.code;TRUE&e.code; when successful.  The init, enter, leave
-      functions are defined as follows:
-
-        <quote>
-        &s.code;typedef void (*EntityProc)(int entityIndex,
-			&f.indent;pointer private)&e.code;
-        </quote>
-
-      They are passed the entity index and a pointer to a private scratch
-      area.  This can be set up during &s.code;Probe()&e.code; and
-      its address can be passed to
-      &s.code;xf86ConfigIsaEntity()&e.code; and
-      &s.code;xf86ConfigPciEntity()&e.code; as the last argument.
-
-    </quote>
-    </quote>
-
-These two helper functions make use of several core functions that are
-available at the driver level:
-    <quote><p>
-    &s.code;void xf86ClaimFixedResources(resList list, int entityIndex)&e.code;
-    <quote><p>
-      This function registers the non-relocatable resources which cannot
-      be disabled and which therefore would cause the server to fail
-      immediately if they were found to conflict.  It also records
-      non-relocatable but sharable resources for processing after the
-      &s.code;Probe()&e.code; phase.
-
-    </quote>
-
-    &s.code;Bool xf86SetEntityFuncs(int entityIndex, EntityProc init,
-			&f.indent;EntityProc enter, EntityProc leave, pointer)&e.code;
-    <quote><p>
-      This function registers with an entity the &s.code;init&e.code;,
-      &s.code;enter&e.code;, &s.code;leave&e.code; functions along
-      with the pointer to their private area.
-
-    </quote>
-
-    &s.code;void xf86AddEntityToScreen(ScrnInfoPtr pScrn, int entityIndex)&e.code;
-    <quote><p>
-      This function associates the entity referenced by
-      &s.code;entityIndex&e.code; with the screen.
-
-    </quote>
-    </quote>
-
-<sect2>PreInit Phase
-<p>
-
-During this phase the remaining resources should be registered.
-&s.code;PreInit()&e.code; should call &s.code;xf86GetEntityInfo()&e.code;
-to obtain a pointer to an &s.code;EntityInfoRec&e.code; for each entity
-it is able to drive and check if any resource are listed in its
-&s.code;resources&e.code; field.  If resources registered in the Probe
-phase have been rejected in the post-Probe phase
-(&s.code;resources&e.code; is non-&s.code;NULL&e.code;), then the driver should
-decide if it can continue without using these or if it should fail.
-
-    <quote><p>
-    &s.code;EntityInfoPtr xf86GetEntityInfo(int entityIndex)&e.code;
-    <quote><p>
-      This function returns a pointer to the &s.code;EntityInfoRec&e.code;
-      referenced by &s.code;entityIndex&e.code;.  The returned
-      &s.code;EntityInfoRec&e.code; should be freed with
-      &s.code;xfree()&e.code; when no longer needed.
-
-    </quote>
-    </quote>
-Several functions are provided to simplify resource registration:
-    <quote><p>
-    &s.code;Bool xf86IsEntityPrimary(int entityIndex)&e.code;
-    <quote><p>
-      This function returns &s.code;TRUE&e.code; if the entity referenced
-      by &s.code;entityIndex&e.code; is the primary display device (i.e.,
-      the one initialised at boot time and used in text mode).
-
-    </quote>
-
-    &s.code;Bool xf86IsScreenPrimary(int scrnIndex)&e.code;
-    <quote><p>
-      This function returns &s.code;TRUE&e.code; if the primary entity
-      is registered with the screen referenced by
-      &s.code;scrnIndex&e.code;.
-
-    </quote>
-
-    &s.code;pciVideoPtr xf86GetPciInfoForEntity(int entityIndex)&e.code;
-    <quote><p>
-      This function returns a pointer to the &s.code;pciVideoRec&e.code;
-      for the specified entity.  If the entity is not a PCI device,
-      &s.code;NULL&e.code; is returned.
-
-    </quote>
-    </quote>
-
-The primary function for registration of resources is:
-    <quote><p>
-    &s.code;resPtr xf86RegisterResources(int entityIndex, resList list,
-			&f.indent;int access)&e.code;
-    <quote><p>
-      This function tries to register the resources in
-      &s.code;list&e.code;.  If list is &s.code;NULL&e.code; it tries
-      to determine the resources automatically.  This only works for
-      entities that provide a generic way to read out the resource ranges
-      they decode.  So far this is only the case for PCI devices.  By
-      default the PCI resources are registered as shared
-      (&s.code;ResShared&e.code;) if the driver wants to set a different
-      access type it can do so by specifying the access flags in the
-      third argument.  A value of &s.code;0&e.code; means to use the
-      default settings.  If for any reason the resource broker is not
-      able to register some of the requested resources the function will
-      return a pointer to a list of the failed ones.  In this case the
-      driver may be able to move the resource to different locations.
-      In case of PCI bus entities this is done by passing the list of
-      failed resources to &s.code;xf86ReallocatePciResources()&e.code;.
-      When the registration succeeds, the return value is
-      &s.code;NULL&e.code;.
-
-    </quote>
-
-    &s.code;resPtr xf86ReallocatePciResources(int entityIndex, resPtr pRes)&e.code;
-    <quote><p>
-      This function takes a list of PCI resources that need to be
-      reallocated and returns &s.code;NULL&e.code when all relocations are
-      successful.
-      &s.code;xf86RegisterResources()&e.code; should be called again to
-      register the relocated resources with the broker.
-      If the reallocation fails, a list of the resources that could not be
-      relocated is returned.
-
-    </quote>
-    </quote>
-
-Two functions are provided to obtain a resource range of a given type:
-    <quote><p>
-    &s.code;resRange xf86GetBlock(long type, memType size,
-			&f.indent;memType window_start, memType window_end,
-			&f.indent;memType align_mask, resPtr avoid)&e.code;
-    <quote><p>
-      This function tries to find a block range of size
-      &s.code;size&e.code; and type &s.code;type&e.code; in a window
-      bound by &s.code;window_start&e.code; and &s.code;window_end&e.code;
-      with the alignment specified in &s.code;align_mask&e.code;.
-      Optionally a list of resource ranges which should be avoided within
-      the window can be supplied.  On failure a zero-length range of
-      type &s.code;ResEnd&e.code; will be returned.
-
-    </quote>
-    &s.code;resRange xf86GetSparse(long type, memType fixed_bits,
-			&f.indent;memType decode_mask, memType address_mask,
-			&f.indent;resPtr avoid)&e.code;
-    <quote><p>
-      This function is like the previous one, but attempts to find a
-      sparse range instead of a block range.  Here three values have to
-      be specified: the &s.code;address_mask&e.code; which marks all
-      bits of the mask part of the address, the &s.code;decode_mask&e.code;
-      which masks out the bits which are hardcoded and are therefore
-      not available for relocation and the values of the fixed bits.
-      The function tries to find a base that satisfies the given condition.
-      If the function fails it will return a zero range of type
-      &s.code;ResEnd&e.code;.  Optionally it might be passed a list of
-      resource ranges to avoid.
-
-    </quote>
-    </quote>
-
-Some PCI devices are broken in the sense that they return invalid size
-information for a certain resource.  In this case the driver can supply
-the correct size and make sure that the resource range allocated for
-the card is large enough to hold the address range decoded by the card.
-The function &s.code;xf86FixPciResource()&e.code; can be used to do this:
-    <quote><p>
-    &s.code;Bool xf86FixPciResource(int entityIndex, unsigned int prt,
-				&f.indent;CARD32 alignment, long type)&e.code;
-    <quote><p>
-      This function fixes a PCI resource allocation.  The
-      &s.code;prt&e.code; parameter contains the number of the PCI base
-      register that needs to be fixed (&s.code;0-5&e.code;, and
-      &s.code;6&e.code; for the BIOS base register).  The size is
-      specified by the alignment.  Since PCI resources need to span an
-      integral range of size &s.code;2^n&e.code;, the alignment also
-      specifies the number of addresses that will be decoded.  If the
-      driver specifies a type mask it can override the default type for
-      PCI resources which is &s.code;ResShared&e.code;.  The resource
-      broker needs to know that to find a matching resource range.  This
-      function should be called before calling
-      &s.code;xf86RegisterResources()&e.code;.  The return value is
-      &s.code;TRUE&e.code; when the function succeeds.
-
-    </quote>
-
-    &s.code;Bool xf86CheckPciMemBase(pciVideoPtr pPci, memType base)&e.code;
-    <quote><p>
-      This function checks that the memory base address specified matches
-      one of the PCI base address register values for the given PCI
-      device.  This is mostly used to check that an externally provided
-      base address (e.g., from a config file) matches an actual value
-      allocated to a device.
-
-    </quote>
-    </quote>
-
-The driver may replace the generic access control functions for an entity.
-This is done with the &s.code;xf86SetAccessFuncs()&e.code;:
-    <quote><p>
-    &s.code;void xf86SetAccessFuncs(EntityInfoPtr pEnt,
-                        &f.indent;xf86SetAccessFuncPtr funcs,
-			&f.indent;xf86SetAccessFuncPtr oldFuncs)&e.code;
-    <quote><p>
-     with:
-    </quote>
-
-    <verb>
-      typedef struct {
-          xf86AccessPtr mem;
-          xf86AccessPtr io;
-          xf86AccessPtr io_mem;
-      } xf86SetAccessFuncRec, *xf86SetAccessFuncPtr;
-    </verb>
-
-    <quote><p>
-      The driver can pass three functions: one for I/O access, one for
-      memory access and one for combined memory and I/O access.  If the
-      memory access and combined access functions are identical the
-      common level assumes that the memory access cannot be controlled
-      independently of I/O access, if the I/O access function and the
-      combined access functions are the same it is assumed that I/O can
-      not be controlled independently.  If memory and I/O have to be
-      controlled together all three values should be the same.  If a
-      non &s.code;NULL&e.code; value is passed as third argument it is
-      interpreted as an address where to store the old access record.
-      If the third argument is &s.code;NULL&e.code; it will be assumed
-      that the generic access should be enabled before replacing the
-      access functions.  Otherwise it will be disabled.  The driver may
-      enable them itself using the returned values.  It should do this
-      from its replacement access functions as the generic access may
-      be disabled by the common level on certain occasions.  If replacement
-      functions are specified they must control all resources of the
-      specific type registered for the entity.
-
-    </quote>
-    </quote>
-
-To find out if a specific resource range conflicts with another
-resource the &s.code;xf86ChkConflict()&e.code; function may be used:
-    <quote><p>
-    &s.code;memType xf86ChkConflict(resRange *rgp, int entityIndex)&e.code;
-    <quote><p>
-      This function checks if the resource range &s.code;rgp&e.code; of
-      for the specified entity conflicts with with another resource.
-      If a conflict is found, the address of the start of the conflict
-      is returned.  The return value is zero when there is no conflict.
-
-    </quote>
-    </quote>
-
-The OPERATING state properties of previously registered fixed resources
-can be set with the &s.code;xf86SetOperatingState()&e.code; function:
-    <quote><p>
-    &s.code;resPtr xf86SetOperatingState(resList list, int entityIndex,
-			&f.indent;int mask)&e.code;
-    <quote><p>
-      This function is used to set the status of a resource during
-      OPERATING state.  &s.code;list&e.code; holds a list to which
-      &s.code;mask&e.code; is to be applied.  The parameter
-      &s.code;mask&e.code; may have the value &s.code;ResUnusedOpr&e.code;
-      and &s.code;ResDisableOpr&e.code;.  The first one should be used
-      if a resource isn't used by the driver during OPERATING state
-      although it is decoded by the device, while the latter one indicates
-      that the resource is not decoded during OPERATING state.  Note
-      that the resource ranges have to match those specified during
-      registration.  If a range has been specified starting at
-      &s.code;A&e.code; and ending at &s.code;B&e.code; and suppose
-      &s.code;C&e.code; us a value satisfying
-      &s.code;A&nbsp;&lt;&nbsp;C&nbsp;&lt;&nbsp;B&e.code; one may not
-      specify the resource range &s.code;(A,B)&e.code; by splitting it
-      into two ranges &s.code;(A,C)&e.code; and &s.code;(C,B)&e.code;.
-
-    </quote>
-    </quote>
-
-The following two functions are provided for special cases:
-    <quote><p>
-    &s.code;void xf86RemoveEntityFromScreen(ScrnInfoPtr pScrn, int entityIndex)&e.code;
-    <quote><p>
-      This function may be used to remove an entity from a screen.  This
-      only makes sense if a screen has more than one entity assigned or
-      the screen is to be deleted.  No test is made if the screen has
-      any entities left.
-
-    </quote>
-
-    &s.code;void xf86DeallocateResourcesForEntity(int entityIndex, long type)&e.code;
-    <quote><p>
-      This function deallocates all resources of a given type registered
-      for a certain entity from the resource broker list.
-
-    </quote>
-    </quote>
-
-<sect2>ScreenInit Phase
-<p>
-
-All that is required in this phase is to setup the RAC flags.  Note that
-it is also permissible to set these flags up in the PreInit phase.  The
-RAC flags are held in the &s.code;racIoFlags&e.code; and &s.code;racMemFlags&e.code; fields of the
-&s.code;ScrnInfoRec&e.code; for each screen.  They specify which graphics operations
-might require the use of shared resources.  This can be specified
-separately for memory and I/O resources.  The available flags are defined
-in &s.code;rac/xf86RAC.h&e.code;.  They are:
-
-    &s.code;RAC_FB&e.code;
-	<quote>
-	for framebuffer operations (including hw acceleration)
-	</quote>
-    &s.code;RAC_CURSOR&e.code;
-	<quote>
-	for Cursor operations
-        (??? I'm not sure if we need this for SW cursor it depends
-         on which level the sw cursor is drawn)
-	</quote>
-    &s.code;RAC_COLORMAP&e.code;
-	<quote>
-	for colormap operations
-	</quote>
-    &s.code;RAC_VIEWPORT&e.code;
-	<quote>
-	for the call to &s.code;ChipAdjustFrame()&e.code; </quote>
-
-
-The flags are ORed together.
-
-<sect>Config file ``Option'' entries<label id="options">
-<p>
-
-Option entries are permitted in most sections and subsections of the
-config file.  There are two forms of option entries:
-
-<descrip>
-<tag>Option "option-name"</tag>
-	A boolean option.
-<tag>Option "option-name" "option-value"</tag>
-	An option with an arbitrary value.
-</descrip>
-
-The option entries are handled by the parser, and a list of the parsed
-options is included with each of the appropriate data structures that
-the drivers have access to.  The data structures used to hold the option
-information are opaque to the driver, and a driver must not access the
-option data directly.  Instead, the common layer provides a set of
-functions that may be used to access, check and manipulate the option
-data.
-
-First, the low level option handling functions.  In most cases drivers
-would not need to use these directly.
-
-    <quote><p>
-    &s.code;pointer xf86FindOption(pointer options, const char *name)&e.code;
-    <quote><p>
-      Takes a list of options and an option name, and returns a handle
-      for the first option entry in the list matching the name.  Returns
-      &s.code;NULL&e.code; if no match is found.
-
-    </quote>
-
-    &s.code;char *xf86FindOptionValue(pointer options, const char *name)&e.code;
-    <quote><p>
-      Takes a list of options and an option name, and returns the value
-      associated with the first option entry in the list matching the
-      name.  If the matching option has no value, an empty string
-      (&s.code;""&e.code;) is returned.  Returns &s.code;NULL&e.code;
-      if no match is found.
-
-    </quote>
-
-    &s.code;void xf86MarkOptionUsed(pointer option)&e.code;
-    <quote><p>
-      Takes a handle for an option, and marks that option as used.
-
-    </quote>
-
-    &s.code;void xf86MarkOptionUsedByName(pointer options, const char *name)&e.code;
-    <quote><p>
-      Takes a list of options and an option name and marks the first
-      option entry in the list matching the name as used.
-
-    </quote>
-    </quote>
-
-
-Next, the higher level functions that most drivers would use.
-    <quote><p>
-    &s.code;void xf86CollectOptions(ScrnInfoPtr pScrn, pointer extraOpts)&e.code;
-    <quote><p>
-      Collect the options from each of the config file sections used by
-      the screen (&s.code;pScrn&e.code;) and return the merged list as
-      &s.code;pScrn-&gt;options&e.code;.  This function requires that
-      &s.code;pScrn-&gt;confScreen&e.code;, &s.code;pScrn-&gt;display&e.code;,
-      &s.code;pScrn-&gt;monitor&e.code;,
-      &s.code;pScrn-&gt;numEntities&e.code;, and
-      &s.code;pScrn-&gt;entityList&e.code; are initialised.
-      &s.code;extraOpts&e.code; may optionally be set to an additional
-      list of options to be combined with the others.  The order of
-      precedence for options is &s.code;extraOpts&e.code;, display,
-      confScreen, monitor, device.
-
-    </quote>
-
-    &s.code;void xf86ProcessOptions(int scrnIndex, pointer options,
-			&f.indent;OptionInfoPtr optinfo)&e.code;
-    <quote><p>
-      Processes a list of options according to the information in the
-      array of &s.code;OptionInfoRecs&e.code; (&s.code;optinfo&e.code;).
-      The resulting information is stored in the &s.code;value&e.code;
-      fields of the appropriate &s.code;optinfo&e.code; entries.  The
-      &s.code;found&e.code; fields are set to &s.code;TRUE&e.code;
-      when an option with a value of the correct type if found, and
-      &s.code;FALSE&e.code; otherwise.  The &s.code;type&e.code; field
-      is used to determine the expected value type for each option.
-      Each option in the list of options for which there is a name match
-      (but not necessarily a value type match) is marked as used.
-      Warning messages are printed when option values don't match the
-      types specified in the optinfo data.
-
-      NOTE: If this function is called before a driver's screen number
-      is known (e.g., from the &s.code;ChipProbe()&e.code; function) a
-      &s.code;scrnIndex&e.code; value of &s.code;-1&e.code; should be
-      used.
-
-      NOTE 2: Given that this function stores into the
-      &s.code;OptionInfoRecs&e.code; pointed to by &s.code;optinfo&e.code,
-      the caller should ensure the &s.code;OptionInfoRecs&e.code; are
-      (re-)initialised before the call, especially if the caller expects
-      to use the predefined option values as defaults.
-
-      The &s.code;OptionInfoRec&e.code; is defined as follows:
-
-      <verb>
-      typedef struct {
-          double freq;
-          int units;
-      } OptFrequency;
-
-      typedef union {
-          unsigned long       num;
-          char *              str;
-          double              realnum;
-          Bool                bool;
-          OptFrequency        freq;
-      } ValueUnion;
-
-      typedef enum {
-          OPTV_NONE = 0,
-          OPTV_INTEGER,
-          OPTV_STRING,  /* a non-empty string */
-          OPTV_ANYSTR,  /* Any string, including an empty one */
-          OPTV_REAL,
-          OPTV_BOOLEAN,
-          OPTV_PERCENT,
-          OPTV_FREQ
-      } OptionValueType;
-
-      typedef enum {
-          OPTUNITS_HZ = 1,
-          OPTUNITS_KHZ,
-          OPTUNITS_MHZ
-      } OptFreqUnits;
-
-      typedef struct {
-          int                 token;
-          const char*         name;
-          OptionValueType     type;
-          ValueUnion          value;
-          Bool                found;
-      } OptionInfoRec, *OptionInfoPtr;
-      </verb>
-
-      &s.code;OPTV_FREQ&e.code; can be used for options values that are
-      frequencies.  These values are a floating point number with an
-      optional unit name appended.  The unit name can be one of "Hz",
-      "kHz", "k", "MHz", "M".  The multiplier associated with the unit
-      is stored in &s.code;freq.units&e.code;, and the scaled frequency
-      is stored in &s.code;freq.freq&e.code;.  When no unit is specified,
-      &s.code;freq.units&e.code; is set to &s.code;0&e.code;, and
-      &s.code;freq.freq&e.code; is unscaled.
-
-      &s.code;OPTV_PERCENT&e.code; can be used for option values that are
-      specified in percent (e.g. "20%"). These values are a floating point
-      number with a percent sign appended. If the percent sign is missing,
-      the parser will fail to match the value.
-
-      Typical usage is to setup an array of
-      &s.code;OptionInfoRecs&e.code; with all fields initialised.
-      The &s.code;value&e.code; and &s.code;found&e.code; fields get
-      set by &s.code;xf86ProcessOptions()&e.code;.  For cases where the
-      value parsing is more complex, the driver should specify
-      &s.code;OPTV_STRING&e.code;, and parse the string itself.  An
-      example of using this option handling is included in the
-      <ref id="sample" name="Sample Driver"> section.
-
-    </quote>
-
-    &s.code;void xf86ShowUnusedOptions(int scrnIndex, pointer options)&e.code;
-    <quote><p>
-      Prints out warning messages for each option in the list of options
-      that isn't marked as used.  This is intended to show options that
-      the driver hasn't recognised.  It would normally be called near
-      the end of the &s.code;ChipScreenInit()&e.code; function, but only
-      when &s.code;serverGeneration&nbsp;==&nbsp;1&e.code;.
-
-    </quote>
-
-    &s.code;OptionInfoPtr xf86TokenToOptinfo(const OptionInfoRec *table,
-			&f.indent;int token)&e.code;
-
-    <quote><p>
-      Returns a pointer to the &s.code;OptionInfoRec&e.code; in
-      &s.code;table&e.code; with a token field matching
-      &s.code;token&e.code;.  Returns &s.code;NULL&e.code; if no match
-      is found.
-
-    </quote>
-
-    &s.code;Bool xf86IsOptionSet(const OptionInfoRec *table, int token)&e.code;
-    <quote><p>
-      Returns the &s.code;found&e.code; field of the
-      &s.code;OptionInfoRec&e.code; in &s.code;table&e.code; with a
-      &s.code;token&e.code; field matching &s.code;token&e.code;.  This
-      can be used for options of all types.  Note that for options of
-      type &s.code;OPTV_BOOLEAN&e.code;, it isn't sufficient to check
-      this to determine the value of the option.  Returns
-      &s.code;FALSE&e.code; if no match is found.
-
-    </quote>
-
-    &s.code;char *xf86GetOptValString(const OptionInfoRec *table, int token)&e.code;
-    <quote><p>
-      Returns the &s.code;value.str&e.code; field of the
-      &s.code;OptionInfoRec&e.code; in &s.code;table&e.code; with a
-      token field matching &s.code;token&e.code;.  Returns
-      &s.code;NULL&e.code; if no match is found.
-
-    </quote>
-
-    &s.code;Bool xf86GetOptValInteger(const OptionInfoRec *table, int token,
-			&f.indent;int *value)&e.code;
-    <quote><p>
-      Returns via &s.code;*value&e.code; the &s.code;value.num&e.code;
-      field of the &s.code;OptionInfoRec&e.code; in &s.code;table&e.code;
-      with a &s.code;token&e.code; field matching &s.code;token&e.code;.
-      &s.code;*value&e.code; is only changed when a match is found so
-      it can be safely initialised with a default prior to calling this
-      function.  The function return value is as for
-      &s.code;xf86IsOptionSet()&e.code;.
-
-    </quote>
-
-    &s.code;Bool xf86GetOptValULong(const OptionInfoRec *table, int token,
-			&f.indent;unsigned long *value)&e.code;
-    <quote><p>
-      Like &s.code;xf86GetOptValInteger()&e.code;, except the value is
-      treated as an &s.code;unsigned long&e.code;.
-
-    </quote>
-
-    &s.code;Bool xf86GetOptValReal(const OptionInfoRec *table, int token,
-			&f.indent;double *value)&e.code;
-    <quote><p>
-      Like &s.code;xf86GetOptValInteger()&e.code;, except that
-      &s.code;value.realnum&e.code; is used.
-
-    </quote>
-
-    &s.code;Bool xf86GetOptValFreq(const OptionInfoRec *table, int token,
-			&f.indent;OptFreqUnits expectedUnits, double *value)&e.code;
-    <quote><p>
-      Like &s.code;xf86GetOptValInteger()&e.code;, except that the
-      &s.code;value.freq&e.code; data is returned.  The frequency value
-      is scaled to the units indicated by &s.code;expectedUnits&e.code;.
-      The scaling is exact when the units were specified explicitly in
-      the option's value.  Otherwise, the &s.code;expectedUnits&e.code;
-      field is used as a hint when doing the scaling.  In this case,
-      values larger than &s.code;1000&e.code; are assumed to have be
-      specified in the next smallest units.  For example, if the Option
-      value is "10000" and expectedUnits is &s.code;OPTUNITS_MHZ&e.code;,
-      the value returned is &s.code;10&e.code;.
-
-    </quote>
-
-    &s.code;Bool xf86GetOptValBool(const OptionInfoRec *table, int token, Bool *value)&e.code;
-    <quote><p>
-      This function is used to check boolean options
-      (&s.code;OPTV_BOOLEAN&e.code;).  If the function return value is
-      &s.code;FALSE&e.code;, it means the option wasn't set.  Otherwise
-      &s.code;*value&e.code; is set to the boolean value indicated by
-      the option's value.  No option &s.code;value&e.code; is interpreted
-      as &s.code;TRUE&e.code;.  Option values meaning &s.code;TRUE&e.code;
-      are "1", "yes", "on", "true", and option values meaning
-      &s.code;FALSE&e.code; are "0", "no", "off", "false".  Option names
-      both with the "no" prefix in their names, and with that prefix
-      removed are also checked and handled in the obvious way.
-      &s.code;*value&e.code; is not changed when the option isn't present.
-      It should normally be set to a default value before calling this
-      function.
-
-    </quote>
-
-    &s.code;Bool xf86ReturnOptValBool(const OptionInfoRec *table, int token, Bool def)&e.code;
-    <quote><p>
-      This function is used to check boolean options
-      (&s.code;OPTV_BOOLEAN&e.code;).  If the option is set, its value
-      is returned.  If the options is not set, the default value specified
-      by &s.code;def&e.code; is returned.  The option interpretation is
-      the same as for &s.code;xf86GetOptValBool()&e.code;.
-
-    </quote>
-
-    &s.code;int xf86NameCmp(const char *s1, const char *s2)&e.code;
-    <quote><p>
-      This function should be used when comparing strings from the config
-      file with expected values.  It works like &s.code;strcmp()&e.code;,
-      but is not case sensitive and space, tab, and `<tt>_</tt>' characters
-      are ignored in the comparison.  The use of this function isn't
-      restricted to parsing option values.  It may be used anywhere
-      where this functionality required.
-
-    </quote>
-    </quote>
-
-<sect>Modules, Drivers, Include Files and Interface Issues
-<p>
-
-NOTE: this section is incomplete.
-
-
-<sect1>Include files
-<p>
-
-The following include files are typically required by video drivers:
-
-  <quote><p>
-  All drivers should include these:
-  <quote>
-    &s.code;"xf86.h"&nl;
-    "xf86_OSproc.h"&nl;
-    "xf86_ansic.h"&nl;
-    "xf86Resources.h"&e.code;
-  </quote>
-  Wherever inb/outb (and related things) are used the following should be
-  included:
-  <quote>
-    &s.code;"compiler.h"&e.code;
-  </quote>
-  Note: in drivers, this must be included after &s.code;"xf86_ansic.h"&e.code;.
-
-  Drivers that need to access PCI vendor/device definitions need this:
-  <quote>
-    &s.code;"xf86PciInfo.h"&e.code;
-  </quote>
-
-  Drivers that need to access the PCI config space need this:
-  <quote>
-    &s.code;"xf86Pci.h"&e.code;
-  </quote>
-
-  Drivers that initialise a SW cursor need this:
-  <quote>
-    &s.code;"mipointer.h"&e.code;
-  </quote>
-
-  All drivers implementing backing store need this:
-  <quote>
-    &s.code;"mibstore.h"&e.code;
-  </quote>
-
-  All drivers using the mi colourmap code need this:
-  <quote>
-    &s.code;"micmap.h"&e.code;
-  </quote>
-
-  If a driver uses the vgahw module, it needs this:
-  <quote>
-    &s.code;"vgaHW.h"&e.code;
-  </quote>
-
-  Drivers supporting VGA or Hercules monochrome screens need:
-  <quote>
-    &s.code;"xf1bpp.h"&e.code;
-  </quote>
-
-  Drivers supporting VGA or EGC 16-colour screens need:
-  <quote>
-    &s.code;"xf4bpp.h"&e.code;
-  </quote>
-
-  Drivers using cfb need:
-  <quote>
-    &s.code;#define PSZ 8&nl;
-    #include "cfb.h"&nl;
-    #undef PSZ&e.code;
-  </quote>
-
-  Drivers supporting bpp 16, 24 or 32 with cfb need one or more of:
-  <quote>
-    &s.code;"cfb16.h"&nl;
-    "cfb24.h"&nl;
-    "cfb32.h"&e.code;
-  </quote>
-
-  If a driver uses XAA, it needs these:
-  <quote>
-    &s.code;"xaa.h"&nl;
-    "xaalocal.h"&e.code;
-  </quote>
-
-  If a driver uses the fb manager, it needs this:
-  <quote>
-    &s.code;"xf86fbman.h"&e.code;
-  </quote>
-  </quote>
-
-Non-driver modules should include &s.code;"xf86_ansic.h"&e.code; to get the correct
-wrapping of ANSI C/libc functions.
-
-All modules must NOT include any system include files, or the following:
-
- <quote>
-    &s.code;"xf86Priv.h"&nl;
-    "xf86Privstr.h"&nl;
-    "xf86_OSlib.h"&nl;
-    "Xos.h"&e.code;
- </quote>
-
-In addition, "xf86_libc.h" must not be included explicitly.  It is
-included implicitly by "xf86_ansic.h".
-
-
-<sect>Offscreen Memory Manager
-<p>
-
-Management of offscreen video memory may be handled by the XFree86
-framebuffer manager.  Once the offscreen memory manager is running,
-drivers or extensions may allocate, free or resize areas of offscreen
-video memory using the following functions (definitions taken from
-&s.code;xf86fbman.h&e.code;):
-
-<code>
-    typedef struct _FBArea {
-        ScreenPtr    pScreen;
-        BoxRec       box;
-        int          granularity;
-        void         (*MoveAreaCallback)(struct _FBArea*, struct _FBArea*)
-        void         (*RemoveAreaCallback)(struct _FBArea*)
-        DevUnion     devPrivate;
-    } FBArea, *FBAreaPtr;
-
-    typedef void (*MoveAreaCallbackProcPtr)(FBAreaPtr from, FBAreaPtr to)
-    typedef void (*RemoveAreaCallbackProcPtr)(FBAreaPtr)
-
-    FBAreaPtr xf86AllocateOffscreenArea (
-        ScreenPtr pScreen,
-        int width, int height,
-        int granularity,
-        MoveAreaCallbackProcPtr MoveAreaCallback,
-        RemoveAreaCallbackProcPtr RemoveAreaCallback,
-        pointer privData
-    )
-
-    void xf86FreeOffscreenArea (FBAreaPtr area)
-
-    Bool xf86ResizeOffscreenArea (
-	FBAreaPtr area
-	int w, int h
-    )
-</code>
-
-The function:
-<quote>
-    &s.code;Bool xf86FBManagerRunning(ScreenPtr pScreen)&e.code;
-</quote>
-
-can be used by an extension to check if the driver has initialized
-the memory manager.  The manager is not available if this returns
-&s.code;FALSE&e.code; and the functions above will all fail.
-
-
-&s.code;xf86AllocateOffscreenArea()&e.code; can be used to request a
-rectangle of dimensions &s.code;width&e.code; x &s.code;height&e.code;
-(in pixels) from unused offscreen memory.  &s.code;granularity&e.code;
-specifies that the leftmost edge of the rectangle must lie on some
-multiple of &s.code;granularity&e.code; pixels.  A granularity of zero
-means the same thing as a granularity of one - no alignment preference.
-A &s.code;MoveAreaCallback&e.code; can be provided to notify the requester
-when the offscreen area is moved.  If no &s.code;MoveAreaCallback&e.code;
-is supplied then the area is considered to be immovable.  The
-&s.code;privData&e.code; field will be stored in the manager's internal
-structure for that allocated area and will be returned to the requester
-in the &s.code;FBArea&e.code; passed via the
-&s.code;MoveAreaCallback&e.code;.  An optional
-&s.code;RemoveAreaCallback&e.code; is provided.  If the driver provides
-this it indicates that the area should be allocated with a lower priority.
-Such an area may be removed when a higher priority request (one that
-doesn't have a &s.code;RemoveAreaCallback&e.code;) is made.  When this
-function is called, the driver will have an opportunity to do whatever
-cleanup it needs to do to deal with the loss of the area, but it must
-finish its cleanup before the function exits since the offscreen memory
-manager will free the area immediately after.
-
-&s.code;xf86AllocateOffscreenArea()&e.code; returns &s.code;NULL&e.code;
-if it was unable to allocate the requested area.  When no longer needed,
-areas should be freed with &s.code;xf86FreeOffscreenArea()&e.code;.
-
-&s.code;xf86ResizeOffscreenArea()&e.code; resizes an existing
-&s.code;FBArea&e.code;.  &s.code;xf86ResizeOffscreenArea()&e.code;
-returns &s.code;TRUE&e.code; if the resize was successful.  If
-&s.code;xf86ResizeOffscreenArea()&e.code; returns &s.code;FALSE&e.code;,
-the original &s.code;FBArea&e.code; is left unmodified.  Resizing an
-area maintains the area's original &s.code;granularity&e.code;,
-&s.code;devPrivate&e.code;, and &s.code;MoveAreaCallback&e.code;.
-&s.code;xf86ResizeOffscreenArea()&e.code; has considerably less overhead
-than freeing the old area then reallocating the new size, so it should
-be used whenever possible.
-
-The function:
-  <quote>
-   &s.code;Bool xf86QueryLargestOffscreenArea(
-     &f.indent;ScreenPtr pScreen,
-     &f.indent;int *width, int *height,
-     &f.indent;int granularity,
-     &f.indent;int preferences,
-     &f.indent;int priority
-   &nl)&e.code;
-  </quote>
-
-is provided to query the width and height of the largest single
-&s.code;FBArea&e.code; allocatable given a particular priority.
-&s.code;preferences&e.code; can be one of the following to indicate
-whether width, height or area should be considered when determining
-which is the largest single &s.code;FBArea&e.code; available.
-
-  <quote>
-  &s.code;FAVOR_AREA_THEN_WIDTH&nl;
-  FAVOR_AREA_THEN_HEIGHT&nl;
-  FAVOR_WIDTH_THEN_AREA&nl;
-  FAVOR_HEIGHT_THEN_AREA&e.code;
-  </quote>
-
-&s.code;priority&e.code; is one of the following:
-
-  <quote><p>
-  &s.code;PRIORITY_LOW&e.code;
-  <quote><p>
-     Return the largest block available without stealing anyone else's
-     space.  This corresponds to the priority of allocating a
-     &s.code;FBArea&e.code; when a &s.code;RemoveAreaCallback&e.code;
-     is provided.
-
-  </quote>
-  &s.code;PRIORITY_NORMAL&e.code;
-  <quote><p>
-     Return the largest block available if it is acceptable to steal a
-     lower priority area from someone.  This corresponds to the priority
-     of allocating a &s.code;FBArea&e.code; without providing a
-     &s.code;RemoveAreaCallback&e.code;.
-
-  </quote>
-  &s.code;PRIORITY_EXTREME&e.code;
-  <quote><p>
-     Return the largest block available if all &s.code;FBAreas&e.code;
-     that aren't locked down were expunged from memory first.  This
-     corresponds to any allocation made directly after a call to
-     &s.code;xf86PurgeUnlockedOffscreenAreas()&e.code;.
-
-  </quote>
-  </quote>
-
-
-The function:
-
-  <quote>
-    &s.code;Bool xf86PurgeUnlockedOffscreenAreas(ScreenPtr pScreen)&e.code;
-  </quote>
-
-is provided as an extreme method to free up offscreen memory.  This
-will remove all removable &s.code;FBArea&e.code; allocations.
-
-
-Initialization of the XFree86 framebuffer manager is done via
-
-  <quote>
-    &s.code;Bool xf86InitFBManager(ScreenPtr pScreen, BoxPtr FullBox)&e.code;
-  </quote>
-
-&s.code;FullBox&e.code; represents the area of the framebuffer that the
-manager is allowed to manage.  This is typically a box with a width of
-&s.code;pScrn-&gt;displayWidth&e.code; and a height of as many lines as
-can be fit within the total video memory, however, the driver can reserve
-areas at the extremities by passing a smaller area to the manager.
-
-&s.code;xf86InitFBManager()&e.code; must be called before XAA is
-initialized since XAA uses the manager for it's pixmap cache.
-
-An alternative function is provided to allow the driver to initialize
-the framebuffer manager with a Region rather than a box.
-
-  <quote>
-   &s.code;Bool xf86InitFBManagerRegion(ScreenPtr pScreen,
-	&f.indent;RegionPtr FullRegion)&e.code;
-  </quote>
-
-&s.code;xf86InitFBManagerRegion()&e.code;, unlike
-&s.code;xf86InitFBManager()&e.code;, does not remove the area used for
-the visible screen so that area should not be included in the region
-passed to the function.  &s.code;xf86InitFBManagerRegion()&e.code; is
-useful when non-contiguous areas are available to be managed, and is
-required when multiple framebuffers are stored in video memory (as in
-the case where an overlay of a different depth is stored as a second
-framebuffer in offscreen memory).
-
-
-<sect>Colormap Handling<label id="cmap">
-<p>
-
-A generic colormap handling layer is provided within the XFree86 common
-layer.  This layer takes care of most of the details, and only requires
-a function from the driver that loads the hardware palette when required.
-To use the colormap layer, a driver calls the
-&s.code;xf86HandleColormaps()&e.code; function.
-
-    <quote><p>
-    &s.code;Bool xf86HandleColormaps(ScreenPtr pScreen, int maxColors,
-		&f.indent;int sigRGBbits, LoadPaletteFuncPtr loadPalette,
-		&f.indent;SetOverscanFuncPtr setOverscan,
-		unsigned int flags)&e.code;
-    <quote><p>
-      This function must be called after the default colormap has been
-      initialised.  The &s.code;pScrn-&gt;gamma&e.code; field must also
-      be initialised, preferably by calling &s.code;xf86SetGamma()&e.code;.
-      &s.code;maxColors&e.code; is the number of entries in the palette.
-      &s.code;sigRGBbits&e.code; is the size in bits of each color
-      component in the DAC's palette.  &s.code;loadPalette&e.code;
-      is a driver-provided function for loading a colormap into the
-      hardware, and is described below.  &s.code;setOverscan&e.code; is
-      an optional function that may be provided when the overscan color
-      is an index from the standard LUT and when it needs to be adjusted
-      to keep it as close to black as possible.  The
-      &s.code;setOverscan&e.code; function programs the overscan index.
-      It shouldn't normally be used for depths other than 8.
-      &s.code;setOverscan&e.code; should be set to &s.code;NULL&e.code;
-      when it isn't needed.  &s.code;flags&e.code; may be set to the
-      following (which may be ORed together):
-
-      &s.code;CMAP_PALETTED_TRUECOLOR&e.code;
-      <quote><p>
-				    the TrueColor visual is paletted and is
-				    just a special case of DirectColor.
-				    This flag is only valid for
-				    &s.code;bpp&nbsp;&gt;&nbsp;8&e.code;.
-
-      </quote>
-
-      &s.code;CMAP_RELOAD_ON_MODE_SWITCH&e.code;
-      <quote><p>
-				    reload the colormap automatically
-                                    after mode switches.  This is useful
-                                    for when the driver is resetting the
-                                    hardware during mode switches and
-                                    corrupting or erasing the hardware
-                                    palette.
-
-      </quote>
-
-      &s.code;CMAP_LOAD_EVEN_IF_OFFSCREEN&e.code;
-      <quote><p>
-				    reload the colormap even if the screen
-				    is switched out of the server's VC.
-				    The palette is <it>not</it> reloaded when
-				    the screen is switched back in, nor after
-				    mode switches.  This is useful when the
-				    driver needs to keep track of palette
-				    changes.
-
-      </quote>
-
-      The colormap layer normally reloads the palette after VT enters so it
-      is not necessary for the driver to save and restore the palette
-      when switching VTs.  The driver must, however, still save the
-      initial palette during server start up and restore it during
-      server exit.
-
-    </quote>
-
-    &s.code;void LoadPalette(ScrnInfoPtr pScrn, int numColors, int *indices,
-		&f.indent;LOCO *colors, VisualPtr pVisual)&e.code;
-    <quote><p>
-      &s.code;LoadPalette()&e.code; is a driver-provided function for
-      loading a colormap into hardware.  &s.code;colors&e.code; is the
-      array of RGB values that represent the full colormap.
-      &s.code;indices&e.code; is a list of index values into the colors
-      array.  These indices indicate the entries that need to be updated.
-      &s.code;numColors&e.code; is the number of the indices to be
-      updated.
-
-    </quote>
-
-    &s.code;void SetOverscan(ScrnInfoPtr pScrn, int overscan)&e.code;
-    <quote><p>
-      &s.code;SetOverscan()&e.code; is a driver-provided function for
-      programming the &s.code;overscan&e.code; index.  As described
-      above, it is normally only appropriate for LUT modes where all
-      colormap entries are available for the display, but where one of
-      them is also used for the overscan (typically 8bpp for VGA compatible
-      LUTs).  It isn't required in cases where the overscan area is
-      never visible.
-
-    </quote>
-    </quote>
-
-
-<sect>DPMS Extension
-<p>
-
-Support code for the DPMS extension is included in the XFree86 common layer.
-This code provides an interface between the main extension code, and a means
-for drivers to initialise DPMS when they support it.  One function is
-available to drivers to do this initialisation, and it is always available,
-even when the DPMS extension is not supported by the core server (in
-which case it returns a failure result).
-
-
-    <quote><p>
-    &s.code;Bool xf86DPMSInit(ScreenPtr pScreen, DPMSSetProcPtr set, int flags)&e.code;
-    <quote><p>
-      This function registers a driver's DPMS level programming function
-      &s.code;set&e.code;.  It also checks
-      &s.code;pScrn-&gt;options&e.code; for the "dpms" option, and when
-      present marks DPMS as being enabled for that screen.  The
-      &s.code;set&e.code; function is called whenever the DPMS level
-      changes, and is used to program the requested level.
-      &s.code;flags&e.code; is currently not used, and should be
-      &s.code;0&e.code;.  If the initialisation fails for any reason,
-      including when there is no DPMS support in the core server, the
-      function returns &s.code;FALSE&e.code;.
-
-    </quote>
-    </quote>
-
-
-Drivers that implement DPMS support must provide the following function,
-that gets called when the DPMS level is changed:
-
-
-    <quote><p>
-    &s.code;void ChipDPMSSet(ScrnInfoPtr pScrn, int level, int flags)&e.code;
-    <quote><p>
-      Program the DPMS level specified by &s.code;level&e.code;.  Valid
-      values of &s.code;level&e.code; are &s.code;DPMSModeOn&e.code;,
-      &s.code;DPMSModeStandby&e.code;, &s.code;DPMSModeSuspend&e.code;,
-      &s.code;DPMSModeOff&e.code;.  These values are defined in
-      &s.code;"extensions/dpms.h"&e.code;.
-
-    </quote>
-    </quote>
-
-
-<sect>DGA Extension
-<p>
-
-Drivers can support the XFree86 Direct Graphics Architecture (DGA) by
-filling out a structure of function pointers and a list of modes and
-passing them to DGAInit.
-
-    <quote><p>
-    &s.code;Bool DGAInit(ScreenPtr pScreen, DGAFunctionPtr funcs,
-			&f.indent;DGAModePtr modes, int num)&e.code;
-    <quote><p>
-    <verb>
-/** The DGAModeRec **/
-
-typedef struct {
-  int num;
-  DisplayModePtr mode;
-  int flags;
-  int imageWidth;
-  int imageHeight;
-  int pixmapWidth;
-  int pixmapHeight;
-  int bytesPerScanline;
-  int byteOrder;
-  int depth;
-  int bitsPerPixel;
-  unsigned long red_mask;
-  unsigned long green_mask;
-  unsigned long blue_mask;
-  int viewportWidth;
-  int viewportHeight;
-  int xViewportStep;
-  int yViewportStep;
-  int maxViewportX;
-  int maxViewportY;
-  int viewportFlags;
-  int offset;
-  unsigned char *address;
-  int reserved1;
-  int reserved2;
-} DGAModeRec, *DGAModePtr;
-</verb>
-
-      &s.code;num&e.code;
-	<quote>
-	 Can be ignored.  The DGA DDX will assign these numbers.
-	</quote>
-
-      &s.code;mode&e.code;
-	<quote>
-	A pointer to the &s.code;DisplayModeRec&e.code; for this mode.
-	</quote>
-
-      &s.code;flags&e.code;
-	<quote><p>
-	The following flags are defined and may be OR'd together:
-
-        &s.code;DGA_CONCURRENT_ACCESS&e.code;
-	    <quote><p>
-            Indicates that the driver supports concurrent graphics
-            accelerator and linear framebuffer access.
-
-	    </quote>
-
-        &s.code;DGA_FILL_RECT&nl;
-	DGA_BLIT_RECT&nl;
-        DGA_BLIT_RECT_TRANS&e.code;
-	    <quote><p>
-	    Indicates that the driver supports the FillRect, BlitRect
-            or BlitTransRect functions in this mode.
-
-	    </quote>
-
-        &s.code;DGA_PIXMAP_AVAILABLE&e.code;
-	    <quote><p>
-	    Indicates that Xlib may be used on the framebuffer.
-            This flag will usually be set unless the driver wishes
-            to prohibit this for some reason.
-
-	    </quote>
-
-        &s.code;DGA_INTERLACED&nl;
-        DGA_DOUBLESCAN&e.code;
-	    <quote><p>
-            Indicates that these are interlaced or double scan modes.
-
-	    </quote>
-	</quote>
-
-      &s.code;imageWidth&nl;
-      imageHeight&e.code;
-	<quote><p>
-		    These are the dimensions of the linear framebuffer
-                     accessible by the client.
-
-	</quote>
-
-      &s.code;pixmapWidth&nl;
-      pixmapHeight&e.code;
-	<quote><p>
-		     These are the dimensions of the area of the
-                     framebuffer accessible by the graphics accelerator.
-
-	</quote>
-
-      &s.code;bytesPerScanline&e.code;
-	<quote><p>
-		      Pitch of the framebuffer in bytes.
-
-	</quote>
-
-      &s.code;byteOrder&e.code;
-	<quote><p>
-		     Usually the same as
-		     &s.code;pScrn-&gt;imageByteOrder&e.code;.
-
-	</quote>
-
-      &s.code;depth&e.code;
-	<quote><p>
-		     The depth of the framebuffer in this mode.
-
-	</quote>
-
-      &s.code;bitsPerPixel&e.code;
-	<quote><p>
-		      The number of bits per pixel in this mode.
-
-	</quote>
-
-      &s.code;red_mask&nl;
-      green_mask&nl;
-      blue_mask&e.code;
-	<quote><p>
-		      The RGB masks for this mode, if applicable.
-
-	</quote>
-
-      &s.code;viewportWidth&nl;
-      viewportHeight&e.code;
-	<quote><p>
-		      Dimensions of the visible part of the framebuffer.
-		      Usually &s.code;mode-&gt;HDisplay&e.code; and
-		      &s.code;mode-&gt;VDisplay&e.code;.
-
-	</quote>
-
-      &s.code;xViewportStep&nl;
-      yViewportStep&e.code;
-	<quote><p>
-		     The granularity of x and y viewport positions that
-                     the driver supports in this mode.
-
-	</quote>
-
-      &s.code;maxViewportX&nl;
-      maxViewportY&e.code;
-	<quote><p>
-		      The maximum viewport position supported by the
-                       driver in this mode.
-
-	</quote>
-
-      &s.code;viewportFlags&e.code;
-	<quote><p>
-		     The following may be OR'd together:
-
-       &s.code;DGA_FLIP_IMMEDIATE&e.code;
-	    <quote><p>
-		The driver supports immediate viewport changes.
-
-	    </quote>
-       &s.code;DGA_FLIP_RETRACE&e.code;
-	    <quote<p>
-		The driver supports viewport changes at retrace.
-
-	    </quote>
-	</quote>
-
-      &s.code;offset&e.code;
-	<quote><p>
-	        The offset into the linear framebuffer that corresponds to
-                pixel (0,0) for this mode.
-
-	</quote>
-
-      &s.code;address&e.code;
-        <quote><p>
-                The virtual address of the framebuffer as mapped by the driver.
-                This is needed when DGA_PIXMAP_AVAILABLE is set.
-
-        </quote>
-
-      <verb>
-/** The DGAFunctionRec **/
-
-typedef struct {
-  Bool (*OpenFramebuffer)(
-       ScrnInfoPtr pScrn,
-       char **name,
-       unsigned char **mem,
-       int *size,
-       int *offset,
-       int *extra
-  );
-  void (*CloseFramebuffer)(ScrnInfoPtr pScrn);
-  Bool (*SetMode)(ScrnInfoPtr pScrn, DGAModePtr pMode);
-  void (*SetViewport)(ScrnInfoPtr pScrn, int x, int y, int flags);
-  int  (*GetViewport)(ScrnInfoPtr pScrn);
-  void (*Sync)(ScrnInfoPtr);
-  void (*FillRect)(
-       ScrnInfoPtr pScrn,
-       int x, int y, int w, int h,
-       unsigned long color
-  );
-  void (*BlitRect)(
-       ScrnInfoPtr pScrn,
-       int srcx, int srcy,
-       int w, int h,
-       int dstx, int dsty
-  );
-  void (*BlitTransRect)(
-       ScrnInfoPtr pScrn,
-       int srcx, int srcy,
-       int w, int h,
-       int dstx, int dsty,
-       unsigned long color
-  );
-} DGAFunctionRec, *DGAFunctionPtr;
-</verb>
-
-    </quote>
-
-    &s.code;Bool OpenFramebuffer (pScrn, name, mem, size, offset, extra)&e.code;
-    <quote><p>
-      &s.code;OpenFramebuffer()&e.code; should pass the client everything
-      it needs to know to be able to open the framebuffer.  These
-      parameters are OS specific and their meanings are to be interpreted
-      by an OS specific client library.
-
-      &s.code;name&e.code;
-	<quote><p>
-	      The name of the device to open or &s.code;NULL&e.code; if
-	      there is no special device to open.  A &s.code;NULL&e.code;
-	      name tells the client that it should open whatever device
-	      one would usually open to access physical memory.
-
-	</quote>
-      &s.code;mem&e.code;
-	<quote><p>
-	       The physical address of the start of the framebuffer.
-
-	</quote>
-      &s.code;size&e.code;
-	<quote><p>
-	      The size of the framebuffer in bytes.
-
-	</quote>
-      &s.code;offset&e.code;
-	<quote><p>
-	      Any offset into the device, if applicable.
-
-	</quote>
-      &s.code;flags&e.code;
-	<quote><p>
-	      Any additional information that the client may need.
-	      Currently, only the &s.code;DGA_NEED_ROOT&e.code; flag is
-	      defined.
-
-	</quote>
-   </quote>
-
-    &s.code;void CloseFramebuffer (pScrn)&e.code;
-    <quote><p>
-      &s.code;CloseFramebuffer()&e.code; merely informs the driver (if it
-      even cares) that client no longer needs to access the framebuffer
-      directly.  This function is optional.
-
-    </quote>
-
-    &s.code;Bool SetMode (pScrn, pMode)&e.code;
-    <quote><p>
-      &s.code;SetMode()&e.code; tells the driver to initialize the mode
-      passed to it.  If &s.code;pMode&e.code; is &s.code;NULL&e.code;,
-      then the driver should restore the original pre-DGA mode.
-
-    </quote>
-
-    &s.code;void SetViewport (pScrn, x, y, flags)&e.code;
-    <quote><p>
-      &s.code;SetViewport()&e.code; tells the driver to make the upper
-      left-hand corner of the visible screen correspond to coordinate
-      &s.code;(x,y)&e.code; on the framebuffer.  &s.code;Flags&e.code;
-      currently defined are:
-
-       &s.code;DGA_FLIP_IMMEDIATE&e.code;
-	<quote><p>
-	    The viewport change should occur immediately.
-
-	</quote>
-       &s.code;DGA_FLIP_RETRACE&e.code;
-	<quote><p>
-	    The viewport change should occur at the
-            vertical retrace, but this function should
-            return sooner if possible.
-
-	</quote>
-      The &s.code;(x,y)&e.code; locations will be passed as the client
-      specified them, however, the driver is expected to round these
-      locations down to the next supported location as specified by the
-      &s.code;xViewportStep&e.code; and &s.code;yViewportStep&e.code;
-      for the current mode.
-
-    </quote>
-
-    &s.code;int GetViewport (pScrn)&e.code;
-    <quote><p>
-      &s.code;GetViewport()&e.code; gets the current page flip status.
-      Set bits in the returned int correspond to viewport change requests
-      still pending.  For instance, set bit zero if the last SetViewport
-      request is still pending, bit one if the one before that is still
-      pending, etc.
-
-    </quote>
-
-    &s.code;void Sync (pScrn)&e.code;
-    <quote><p>
-      This function should ensure that any graphics accelerator operations
-      have finished.  This function should not return until the graphics
-      accelerator is idle.
-
-    </quote>
-
-    &s.code;void FillRect (pScrn, x, y, w, h, color)&e.code;
-    <quote><p>
-      This optional function should fill a rectangle
-      &s.code;w&nbsp;&times;&nbsp;h&e.code; located at
-      &s.code;(x,y)&e.code; in the given color.
-
-    </quote>
-
-    &s.code;void BlitRect (pScrn, srcx, srcy, w, h, dstx, dsty)&e.code;
-    <quote><p>
-      This optional function should copy an area
-      &s.code;w&nbsp;&times;&nbsp;h&e.code; located at
-      &s.code;(srcx,srcy)&e.code; to location &s.code;(dstx,dsty)&e.code;.
-      This function will need to handle copy directions as appropriate.
-
-    </quote>
-
-    &s.code;void BlitTransRect (pScrn, srcx, srcy, w, h, dstx, dsty, color)&e.code;
-    <quote><p>
-      This optional function is the same as BlitRect except that pixels
-      in the source corresponding to the color key &s.code;color&e.code;
-      should be skipped.
-
-    </quote>
-    </quote>
-
-<sect>The XFree86 X Video Extension (Xv) Device Dependent Layer
-<p>
-
-XFree86 offers the X Video Extension which allows clients to treat video
-as any another primitive and ``Put'' video into drawables.  By default,
-the extension reports no video adaptors as being available since the
-DDX layer has not been initialized.  The driver can initialize the DDX
-layer by filling out one or more &s.code;XF86VideoAdaptorRecs&e.code;
-as described later in this document and passing a list of
-&s.code;XF86VideoAdaptorPtr&e.code; pointers to the following function:
-
-  <quote>
-  &s.code;Bool xf86XVScreenInit(
-	&f.indent;ScreenPtr pScreen,
-	&f.indent;XF86VideoAdaptorPtr *adaptPtrs,
-	&f.indent;int num)&e.code;
-  </quote>
-
-After doing this, the extension will report video adaptors as being
-available, providing the data in their respective
-&s.code;XF86VideoAdaptorRecs&e.code; was valid.
-&s.code;xf86XVScreenInit()&e.code; <em>copies</em> data from the structure
-passed to it so the driver may free it after the initialization.  At
-the moment, the DDX only supports rendering into Window drawables.
-Pixmap rendering will be supported after a sufficient survey of suitable
-hardware is completed.
-
-The &s.code;XF86VideoAdaptorRec&e.code;:
-
-<quote><p>
-<verb>
-typedef struct {
-	unsigned int type;
-	int flags;
-	char *name;
-	int nEncodings;
-	XF86VideoEncodingPtr pEncodings;
-	int nFormats;
-	XF86VideoFormatPtr pFormats;
-	int nPorts;
-	DevUnion *pPortPrivates;
-	int nAttributes;
-	XF86AttributePtr pAttributes;
-	int nImages;
-	XF86ImagePtr pImages;
-	PutVideoFuncPtr PutVideo;
-	PutStillFuncPtr PutStill;
-	GetVideoFuncPtr GetVideo;
-	GetStillFuncPtr GetStill;
-	StopVideoFuncPtr StopVideo;
-	SetPortAttributeFuncPtr SetPortAttribute;
-	GetPortAttributeFuncPtr GetPortAttribute;
-	QueryBestSizeFuncPtr QueryBestSize;
-	PutImageFuncPtr PutImage;
-	QueryImageAttributesFuncPtr QueryImageAttributes;
-} XF86VideoAdaptorRec, *XF86VideoAdaptorPtr;
-</verb>
-
-   Each adaptor will have its own XF86VideoAdaptorRec.  The fields are
-   as follows:
-
-     &s.code;type&e.code;
-     <quote><p>
-	This can be any of the following flags OR'd together.
-
-	&s.code;XvInputMask&e.code;
-	&s.code;XvOutputMask&e.code;
-	<quote><p>
-	    These refer to the target drawable and are similar to a Window's
-	    class. &s.code;XvInputMask&e.code; indicates that the adaptor
-	    can put video into a drawable.  &s.code;XvOutputMask&e.code;
-	    indicates that the adaptor can get video from a drawable.
-	</quote>
-
-	&s.code;XvVideoMask&e.code;
-	&s.code;XvStillMask&e.code;
-	&s.code;XvImageMask&e.code;
-	<quote><p>
-	    These indicate that the adaptor supports video, still or
-	    image primitives respectively.
-	</quote>
-
-	&s.code;XvWindowMask&e.code;
-	&s.code;XvPixmapMask&e.code;
-	<quote><p>
-	    These indicate the types of drawables the adaptor is capable
-	    of rendering into.  At the moment, Pixmap rendering is not
-	    supported and the &s.code;XvPixmapMask&e.code; flag is ignored.
-	</quote>
-
-     </quote>
-
-     &s.code;flags&e.code;
-     <quote><p>
-	Currently, the following flags are defined:
-
-	&s.code;VIDEO_NO_CLIPPING&e.code;
-	<quote><p>
-	   This indicates that the video adaptor does not support
-	   clipping.  The driver will never receive ``Put'' requests
-	   where less than the entire area determined by
-	   &s.code;drw_x&e.code;, &s.code;drw_y&e.code;,
-	   &s.code;drw_w&e.code; and &s.code;drw_h&e.code; is visible.
-	   This flag does not apply to ``Get'' requests.  Hardware
-	   that is incapable of clipping ``Gets'' may punt or get
-	   the extents of the clipping region passed to it.
-
-	</quote>
-
-	&s.code;VIDEO_INVERT_CLIPLIST&e.code;
-	<quote><p>
-	   This indicates that the video driver requires the clip
-	   list to contain the regions which are obscured rather
-	   than the regions which are are visible.
-
-	</quote>
-
-	&s.code;VIDEO_OVERLAID_STILLS&e.code;
-	<quote><p>
-	   Implementing PutStill for hardware that does video as an
-	   overlay can be awkward since it's unclear how long to leave
-	   the video up for.  When this flag is set, StopVideo will be
-	   called whenever the destination gets clipped or moved so that
-	   the still can be left up until then.
-
-	</quote>
-
-	&s.code;VIDEO_OVERLAID_IMAGES&e.code;
-	<quote><p>
-	    Same as &s.code;VIDEO_OVERLAID_STILLS&e.code; but for images.
-	</quote>
-
-	&s.code;VIDEO_CLIP_TO_VIEWPORT&e.code;
-	<quote><p>
-	    Indicates that the clip region passed to the driver functions
-	    should be clipped to the visible portion of the screen in the
-	    case where the viewport is smaller than the virtual desktop.
-	</quote>
-
-     </quote>
-
-     &s.code;name&e.code;
-     <quote><p>
-	The name of the adaptor.
-
-     </quote>
-
-     &s.code;nEncodings&nl;
-     pEncodings&e.code;
-     <quote><p>
-	The number of encodings the adaptor is capable of and pointer
-	to the &s.code;XF86VideoEncodingRec&e.code; array.  The
-	&s.code;XF86VideoEncodingRec&e.code; is described later on.
-	For drivers that only support XvImages there should be an encoding
-	named "XV_IMAGE" and the width and height should specify
-	the maximum size source image supported.
-
-     </quote>
-
-     &s.code;nFormats&nl;
-     pFormats&e.code;
-     <quote><p>
-	The number of formats the adaptor is capable of and pointer to
-	the &s.code;XF86VideoFormatRec&e.code; array.  The
-	&s.code;XF86VideoFormatRec&e.code; is described later on.
-
-     </quote>
-
-     &s.code;nPorts&nl;
-     pPortPrivates&e.code;
-     <quote><p>
-	The number of ports is the number of separate data streams which
-	the adaptor can handle simultaneously.  If you have more than
-	one port, the adaptor is expected to be able to render into more
-	than one window at a time.  &s.code;pPortPrivates&e.code; is
-	an array of pointers or ints - one for each port.  A port's
-	private data will be passed to the driver any time the port is
-	requested to do something like put the video or stop the video.
-	In the case where there may be many ports, this enables the
-	driver to know which port the request is intended for.  Most
-	commonly, this will contain a pointer to the data structure
-	containing information about the port.  In Xv, all ports on
-	a particular adaptor are expected to be identical in their
-	functionality.
-
-     </quote>
-
-     &s.code;nAttributes&nl;
-     pAttributes&e.code;
-     <quote><p>
-	The number of attributes recognized by the adaptor and a pointer to
-	the array of &s.code;XF86AttributeRecs&e.code;.  The
-	&s.code;XF86AttributeRec&e.code; is described later on.
-
-     </quote>
-
-     &s.code;nImages&nl;
-     pImages&e.code;
-     <quote><p>
-	The number of &s.code;XF86ImageRecs&e.code; supported by the adaptor
-	and a pointer to the array of &s.code;XF86ImageRecs&e.code;. The
-	&s.code;XF86ImageRec&e.code; is described later on.
-
-     </quote>
-
-
-     &s.code;PutVideo PutStill GetVideo GetStill StopVideo
-     SetPortAttribute GetPortAttribute QueryBestSize PutImage
-     QueryImageAttributes&e.code;
-     <quote><p>
-	These functions define the DDX-&gt;driver interface.  In each
-	case, the pointer &s.code;data&e.code; is passed to the driver.
-	This is the port private for that port as described above.  All
-	fields are required except under the following conditions:
-
-	<enum>
-	 <item>&s.code;PutVideo&e.code;, &s.code;PutStill&e.code; and
-	     the image routines &s.code;PutImage&e.code; and
-	     &s.code;QueryImageAttributes&e.code; are not required when the
-	     adaptor type does not contain &s.code;XvInputMask&e.code;.
-
-	 <item>&s.code;GetVideo&e.code; and &s.code;GetStill&e.code;
-	     are not required when the adaptor type does not contain
-	     &s.code;XvOutputMask&e.code;.
-
-	 <item>&s.code;GetVideo&e.code; and &s.code;PutVideo&e.code;
-	     are not required when the adaptor type does not contain
-	     &s.code;XvVideoMask&e.code;.
-
-	 <item>&s.code;GetStill&e.code; and &s.code;PutStill&e.code;
-	     are not required when the adaptor type does not contain
-	     &s.code;XvStillMask&e.code;.
-
-	 <item>&s.code;PutImage&e.code; and &s.code;QueryImageAttributes&e.code;
-	     are not required when the adaptor type does not contain
-	     &s.code;XvImageMask&e.code;.
-
-	</enum>
-
-	With the exception of &s.code;QueryImageAttributes&e.code;, these
-	functions should return &s.code;Success&e.code; if the operation was
-	completed successfully.  They can return &s.code;XvBadAlloc&e.code;
-	otherwise. &s.code;QueryImageAttributes&e.code; returns the size
-	of the XvImage queried.
-
-	If the &s.code;VIDEO_NO_CLIPPING&e.code;
-	flag is set, the &s.code;clipBoxes&e.code; may be ignored by
-	the driver.  &s.code;ClipBoxes&e.code; is an &s.code;X-Y&e.code;
-	banded region identical to those used throughout the server.
-	The clipBoxes represent the visible portions of the area determined
-	by &s.code;drw_x&e.code;, &s.code;drw_y&e.code;,
-	&s.code;drw_w&e.code; and &s.code;drw_h&e.code; in the Get/Put
-	function.  The boxes are in screen coordinates, are guaranteed
-	not to overlap and an empty region will never be passed.
-	If the driver has specified &s.code;VIDEO_INVERT_CLIPLIST&e.code;,
-	&s.code;clipBoxes&e.code; will indicate the areas of the primitive
-	which are obscured rather than the areas visible.
-
-    </quote>
-
-	&s.code;typedef  int (* PutVideoFuncPtr)( ScrnInfoPtr pScrn,
-		&f.indent;short vid_x, short vid_y, short drw_x, short drw_y,
-		&f.indent;short vid_w, short vid_h, short drw_w, short drw_h,
-		&f.indent;RegionPtr clipBoxes, pointer data )&e.code;
-    <quote><p>
-	  This indicates that the driver should take a subsection
-	  &s.code;vid_w&e.code; by &s.code;vid_h&e.code; at location
-	  &s.code;(vid_x,vid_y)&e.code; from the video stream and direct
-	  it into the rectangle &s.code;drw_w&e.code; by &s.code;drw_h&e.code;
-	  at location &s.code;(drw_x,drw_y)&e.code; on the screen, scaling as
-	  necessary.  Due to the large variations in capabilities of
-	  the various hardware expected to be used with this extension,
-	  it is not expected that all hardware will be able to do this
-	  exactly as described.  In that case the driver should just do
-	  ``the best it can,'' scaling as closely to the target rectangle
-	  as it can without rendering outside of it.  In the worst case,
-	  the driver can opt to just not turn on the video.
-
-    </quote>
-
-	&s.code;typedef  int (* PutStillFuncPtr)( ScrnInfoPtr pScrn,
-		&f.indent;short vid_x, short vid_y, short drw_x, short drw_y,
-		&f.indent;short vid_w, short vid_h, short drw_w, short drw_h,
-		&f.indent;RegionPtr clipBoxes, pointer data )&e.code;
-    <quote><p>
-	  This is same as &s.code;PutVideo&e.code; except that the driver
-	  should place only one frame from the stream on the screen.
-
-    </quote>
-
-	&s.code;typedef int (* GetVideoFuncPtr)( ScrnInfoPtr pScrn,
-		&f.indent;short vid_x, short vid_y, short drw_x, short drw_y,
-		&f.indent;short vid_w, short vid_h, short drw_w, short drw_h,
-		&f.indent;RegionPtr clipBoxes, pointer data )&e.code;
-    <quote><p>
-	  This is same as &s.code;PutVideo&e.code; except that the driver
-	  gets video from the screen and outputs it.  The driver should
-	  do the best it can to get the requested dimensions correct
-	  without reading from an area larger than requested.
-
-    </quote>
-
-	&s.code;typedef int (* GetStillFuncPtr)( ScrnInfoPtr pScrn,
-		&f.indent;short vid_x, short vid_y, short drw_x, short drw_y,
-		&f.indent;short vid_w, short vid_h, short drw_w, short drw_h,
-		&f.indent;RegionPtr clipBoxes, pointer data )&e.code;
-    <quote><p>
-	  This is the same as &s.code;GetVideo&e.code; except that the
-	  driver should place only one frame from the screen into the
-	  output stream.
-
-    </quote>
-
-	&s.code;typedef void (* StopVideoFuncPtr)(ScrnInfoPtr pScrn,
-			&f.indent;pointer data, Bool cleanup)&e.code;
-    <quote><p>
-	  This indicates the driver should stop displaying the video.
-	  This is used to stop both input and output video.  The
-	  &s.code;cleanup&e.code; field indicates that the video is
-	  being stopped because the client requested it to stop or
-	  because the server is exiting the current VT.  In that case
-	  the driver should deallocate any offscreen memory areas (if
-	  there are any) being used to put the video to the screen.  If
-	  &s.code;cleanup&e.code; is not set, the video is being stopped
-	  temporarily due to clipping or moving of the window, etc...
-	  and video will likely be restarted soon so the driver should
-	  not deallocate any offscreen areas associated with that port.
-
-    </quote>
-	&s.code;typedef int (* SetPortAttributeFuncPtr)(ScrnInfoPtr pScrn,
-		 &f.indent;Atom attribute,INT32 value, pointer data)&e.code;
-
-	&s.code;typedef int (* GetPortAttributeFuncPtr)(ScrnInfoPtr pScrn,
-		&f.indent;Atom attribute,INT32 *value, pointer data)&e.code;
-
-    <quote><p>
-	  A port may have particular attributes such as hue,
-	  saturation, brightness or contrast.  Xv clients set and
-	  get these attribute values by sending attribute strings
-	  (Atoms) to the server.  Such requests end up at these
-	  driver functions.  It is recommended that the driver provide
-	  at least the following attributes mentioned in the Xv client
-	  library docs:
-	  <quote>
-		&s.code;XV_ENCODING&nl;
-		XV_HUE&nl;
-		XV_SATURATION&nl;
-		XV_BRIGHTNESS&nl;
-  		XV_CONTRAST&e.code;
-	  </quote>
-	  but the driver may recognize as many atoms as it wishes.  If
-	  a requested attribute is unknown by the driver it should return
-	  &s.code;BadMatch&e.code;.  &s.code;XV_ENCODING&e.code; is the
-	  attribute intended to let the client specify which video
-	  encoding the particular port should be using (see the description
-	  of &s.code;XF86VideoEncodingRec&e.code; below).  If the
-	  requested encoding is unsupported, the driver should return
-	  &s.code;XvBadEncoding&e.code;.  If the value lies outside the
-	  advertised range &s.code;BadValue&e.code; may be returned.
-	  &s.code;Success&e.code; should be returned otherwise.
-
-    </quote>
-
-	&s.code;typedef void (* QueryBestSizeFuncPtr)(ScrnInfoPtr pScrn,
-		&f.indent;Bool motion, short vid_w, short vid_h,
-		&f.indent;short drw_w, short drw_h,
-		&f.indent;unsigned int *p_w, unsigned int *p_h, pointer data)&e.code;
-    <quote><p>
-	   &s.code;QueryBestSize&e.code; provides the client with a way
-	   to query what the destination dimensions would end up being
-	   if they were to request that an area
-	   &s.code;vid_w&e.code by &s.code;vid_h&e.code; from the video
-	   stream be scaled to rectangle of
-	   &s.code;drw_w&e.code; by &s.code;drw_h&e.code; on the screen.
-	   Since it is not expected that all hardware will be able to
-	   get the target dimensions exactly, it is important that the
-	   driver provide this function.
-
-    </quote>
-
-	&s.code;typedef  int (* PutImageFuncPtr)( ScrnInfoPtr pScrn,
-		&f.indent;short src_x, short src_y, short drw_x, short drw_y,
-		&f.indent;short src_w, short src_h, short drw_w, short drw_h,
-		&f.indent;int image, char *buf, short width, short height,
-		&f.indent;Bool sync, RegionPtr clipBoxes, pointer data )&e.code;
-    <quote><p>
-	  This is similar to &s.code;PutStill&e.code; except that the
-	  source of the video is not a port but the data stored in a system
-	  memory buffer at &s.code;buf&e.code;.  The data is in the format
-	  indicated by the &s.code;image&e.code; descriptor and represents a
-	  source of size &s.code;width&e.code; by &s.code;height&e.code;.
-	  If &s.code;sync&e.code; is TRUE the driver should not return
-	  from this function until it is through reading the data
-	  from &s.code;buf&e.code;.  Returning when &s.code;sync&e.code;
-	  is TRUE indicates that it is safe for the data at &s.code;buf&e.code;
-	  to be replaced, freed, or modified.
-
-    </quote>
-
-	&s.code;typedef  int (* QueryImageAttributesFuncPtr)( ScrnInfoPtr pScrn,
-		&f.indent;int image, short *width, short *height,
-		&f.indent;int *pitches, int *offsets)&e.code;
-    <quote><p>
-	  This function is called to let the driver specify how data for
-	  a particular &s.code;image&e.code; of size &s.code;width&e.code;
-	  by &s.code;height&e.code; should be stored.  Sometimes only
-	  the size and corrected width and height are needed.  In that
-	  case &s.code;pitches&e.code; and &s.code;offsets&e.code; are
-	  NULL.  The size of the memory required for the image is returned
-	  by this function.  The &s.code;width&e.code; and
-	  &s.code;height&e.code; of the requested image can be altered by
-	  the driver to reflect format limitations (such as component
-	  sampling periods that are larger than one).  If
-	  &s.code;pitches&e.code; and &s.code;offsets&e.code; are not NULL,
-	  these will be arrays with as many elements in them as there
-	  are planes in the &s.code;image&e.code; format.  The driver
-	  should specify the pitch (in bytes) of each scanline in the
-	  particular plane as well as the offset to that plane (in bytes)
-	  from the beginning of the image.
-
-    </quote>
-
-    </quote>
-
-The XF86VideoEncodingRec:
-<quote><p>
-<verb>
-typedef struct {
-	int id;
-	char *name;
-	unsigned short width, height;
-	XvRationalRec rate;
-} XF86VideoEncodingRec, *XF86VideoEncodingPtr;
-
-</verb>
-   The &s.code;XF86VideoEncodingRec&e.code; specifies what encodings
-   the adaptor can support.  Most of this data is just informational
-   and for the client's benefit, and is what will be reported by
-   &s.code;XvQueryEncodings&e.code;.  The &s.code;id&e.code; field is
-   expected to be a unique identifier to allow the client to request a
-   certain encoding via the &s.code;XV_ENCODING&e.code; attribute string.
-
-</quote>
-
-The XF86VideoFormatRec:
-
-<quote><p>
-<verb>
-typedef struct {
-	char  depth;
-	short class;
-} XF86VideoFormatRec, *XF86VideoFormatPtr;
-</verb>
-
-    This specifies what visuals the video is viewable in.
-    &s.code;depth&e.code; is the depth of the visual (not bpp).
-    &s.code;class&e.code; is the visual class such as
-    &s.code;TrueColor&e.code;, &s.code;DirectColor&e.code; or
-    &s.code;PseudoColor&e.code;.  Initialization of an adaptor will fail
-    if none of the visuals on that screen are supported.
-
-</quote>
-
-The XF86AttributeRec:
-
-<quote><p>
-<verb>
-typedef struct {
-	int   flags;
-	int   min_value;
-	int   max_value;
-	char  *name;
-} XF86AttributeListRec, *XF86AttributeListPtr;
-
-</verb>
-
-   Each adaptor may have an array of these advertising the attributes
-   for its ports.  Currently defined flags are &s.code;XvGettable&e.code;
-   and &s.code;XvSettable&e.code; which may be OR'd together indicating that
-   attribute is ``gettable'' or ``settable'' by the client.  The
-   &s.code;min&e.code; and &s.code;max&e.code; field specify the valid range
-   for the value.  &s.code;Name&e.code; is a text string describing the
-   attribute by name.
-
-</quote>
-
-The XF86ImageRec:
-
-<quote><p>
-<verb>
-typedef struct {
-	int id;
-	int type;
-	int byte_order;
-	char guid[16];
-	int bits_per_pixel;
-	int format;
-	int num_planes;
-
-	/* for RGB formats */
-	int depth;
-	unsigned int red_mask;
-	unsigned int green_mask;
-	unsigned int blue_mask;
-
-	/* for YUV formats */
-	unsigned int y_sample_bits;
-	unsigned int u_sample_bits;
-	unsigned int v_sample_bits;
-	unsigned int horz_y_period;
-	unsigned int horz_u_period;
-	unsigned int horz_v_period;
-	unsigned int vert_y_period;
-	unsigned int vert_u_period;
-	unsigned int vert_v_period;
-	char component_order[32];
-	int scanline_order;
-} XF86ImageRec, *XF86ImagePtr;
-</verb>
-
-   XF86ImageRec describes how video source data is laid out in memory.
-   The fields are as follows:
-
-    &s.code;id&e.code;
-    <quote><p>
-	This is a unique descriptor for the format.  It is often good to
-        set this value to the FOURCC for the format when applicable.
-    </quote>
-
-    &s.code;type&e.code;
-    <quote><p>
-	This is &s.code;XvRGB&e.code; or &s.code;XvYUV&e.code;.
-    </quote>
-
-    &s.code;byte_order&e.code;
-    <quote><p>
-	This is &s.code;LSBFirst&e.code; or &s.code;MSBFirst&e.code;.
-    </quote>
-
-    &s.code;guid&e.code;
-    <quote><p>
-	This is the Globally Unique IDentifier for the format.  When
-	not applicable, all characters should be NULL.
-    </quote>
-
-    &s.code;bits_per_pixel&e.code;
-    <quote><p>
-	The number of bits taken up (but not necessarily used) by each
-	pixel.  Note that for some planar formats which have fractional
-	bits per pixel (such as IF09) this number may be rounded _down_.
-    </quote>
-
-    &s.code;format&e.code;
-    <quote><p>
-	This is &s.code;XvPlanar&e.code; or &s.code;XvPacked&e.code;.
-    </quote>
-
-   &s.code;num_planes&e.code;
-    <quote><p>
-	The number of planes in planar formats.  This should be set to
-	one for packed formats.
-    </quote>
-
-   &s.code;depth&e.code;
-    <quote><p>
-	The significant bits per pixel in RGB formats (analgous to the
-	depth of a pixmap format).
-    </quote>
-
-   &s.code;red_mask&e.code;
-   &s.code;green_mask&e.code;
-   &s.code;blue_mask&e.code;
-    <quote><p>
-	The red, green and blue bitmasks for packed RGB formats.
-    </quote>
-
-   &s.code;y_sample_bits&e.code;
-   &s.code;u_sample_bits&e.code;
-   &s.code;v_sample_bits&e.code;
-    <quote><p>
-	The y, u and v sample sizes (in bits).
-    </quote>
-
-   &s.code;horz_y_period&e.code;
-   &s.code;horz_u_period&e.code;
-   &s.code;horz_v_period&e.code;
-    <quote><p>
-	The y, u and v sampling periods in the horizontal direction.
-    </quote>
-
-   &s.code;vert_y_period&e.code;
-   &s.code;vert_u_period&e.code;
-   &s.code;vert_v_period&e.code;
-    <quote><p>
-	The y, u and v sampling periods in the vertical direction.
-    </quote>
-
-   &s.code;component_order&e.code;
-    <quote><p>
-	Uppercase ascii characters representing the order that
-	samples are stored within packed formats.  For planar formats
-	this represents the ordering of the planes.  Unused characters
-	in the 32 byte string should be set to NULL.
-    </quote>
-
-   &s.code;scanline_order&e.code;
-    <quote><p>
-	This is &s.code;XvTopToBottom&e.code; or &s.code;XvBottomToTop&e.code;.
-    </quote>
-
-  Since some formats (particular some planar YUV formats) may not
-be completely defined by the parameters above, the guid, when
-available, should provide the most accurate description of the
-format.
-
-</quote>
-
-<sect>The Loader
-<p>
-
-This section describes the interfaces to the module loader.  The loader
-interfaces can be divided into two groups: those that are only available to
-the XFree86 common layer, and those that are also available to modules.
-
-<sect1>Loader Overview
-<p>
-
-The loader is capable of loading modules in a range of object formats,
-and knowledge of these formats is built in to the loader.  Knowledge of
-new object formats can be added to the loader in a straightforward
-manner.  This makes it possible to provide OS-independent modules (for
-a given CPU architecture type).  In addition to this, the loader can
-load modules via the OS-provided &s.code;dlopen(3)&e.code; service where
-available.  Such modules are not platform independent, and the semantics
-of &s.code;dlopen()&e.code; on most systems results in significant
-limitations in the use of modules of this type.  Support for
-&s.code;dlopen()&e.code; modules in the loader is primarily for
-experimental and development purposes.
-
-Symbols exported by the loader (on behalf of the core X server) to
-modules are determined at compile time.  Only those symbols explicitly
-exported are available to modules.  All external symbols of loaded
-modules are exported to other modules, and to the core X server.  The
-loader can be requested to check for unresolved symbols at any time,
-and the action to be taken for unresolved symbols can be controlled by
-the caller of the loader.  Typically the caller identifies which symbols
-can safely remain unresolved and which cannot.
-
-NOTE:  Now that ISO-C allows pointers to functions and pointers to data to
-have different internal representations, some of the following interfaces
-will need to be revisited.
-
-<sect1>Semi-private Loader Interface
-<p>
-
-The following is the semi-private loader interface that is available to the
-XFree86 common layer.
-
-  <quote><p>
-  &s.code;void LoaderInit(void)&e.code;
-  <quote><p>
-    The &s.code;LoaderInit()&e.code; function initialises the loader,
-    and it must be called once before calling any other loader functions.
-    This function initialises the tables of exported symbols, and anything
-    else that might need to be initialised.
-
-  </quote>
-
-  &s.code;void LoaderSetPath(const char *path)&e.code;
-  <quote><p>
-    The &s.code;LoaderSetPath()&e.code; function initialises a default
-    module search path.  This must be called if calls to other functions
-    are to be made without explicitly specifying a module search path.
-    The search path &s.code;path&e.code; must be a string of one or more
-    comma separated absolute paths.  Modules are expected to be located
-    below these paths, possibly in subdirectories of these paths.
-
-  </quote>
-
-  &s.code;pointer LoadModule(const char *module, const char *path,
-		&f.indent;const char **subdirlist, const char **patternlist,
-		&f.indent;pointer options, const XF86ModReqInfo * modreq,
-		&f.indent;int *errmaj, int *errmin)&e.code;
-  <quote><p>
-    The &s.code;LoadModule()&e.code; function loads the module called
-    &s.code;module&e.code;.  The return value is a module handle, and
-    may be used in future calls to the loader that require a reference
-    to a loaded module.  The module name &s.code;module&e.code; is
-    normally the module's canonical name, which doesn't contain any
-    directory path information, or any object/library file prefixes of
-    suffixes.  Currently a full pathname and/or filename is also accepted.
-    This might change.  The other parameters are:
-
-      &s.code;path&e.code;
-	<quote><p>
-		  An optional comma-separated list of module search paths.
-                  When &s.code;NULL&e.code;, the default search path is used.
-
-	</quote>
-
-      &s.code;subdirlist&e.code;
-	<quote><p>
-		  An optional &s.code;NULL&e.code; terminated list of
-		  subdirectories to search.  When &s.code;NULL&e.code;,
-		  the default built-in list is used (refer to
-		  &s.code;stdSubdirs&e.code; in &s.code;loadmod.c&e.code;).
-		  The default list is also substituted for entries in
-		  &s.code;subdirlist&e.code; with the value
-		  &s.code;DEFAULT_LIST&e.code;.  This makes is possible
-		  to augment the default list instead of replacing it.
-		  Subdir elements must be relative, and must not contain
-		  &s.code;".."&e.code;.  If any violate this requirement,
-		  the load fails.
-
-	</quote>
-
-      &s.code;patternlist&e.code;
-	<quote><p>
-		  An optional &s.code;NULL&e.code; terminated list of
-		  POSIX regular expressions used to connect module
-		  filenames with canonical module names.  Each regex
-		  should contain exactly one subexpression that corresponds
-		  to the canonical module name.  When &s.code;NULL&e.code;,
-		  the default built-in list is used (refer to
-		  &s.code;stdPatterns&e.code; in
-		  &s.code;loadmod.c&e.code;).  The default list is also
-		  substituted for entries in &s.code;patternlist&e.code;
-		  with the value &s.code;DEFAULT_LIST&e.code;.  This
-		  makes it possible to augment the default list instead
-		  of replacing it.
-
-	</quote>
-
-      &s.code;options&e.code;
-	<quote><p>
-		  An optional parameter that is passed to the newly
-		  loaded module's &s.code;SetupProc&e.code; function
-		  (if it has one).  This argument is normally a
-		  &s.code;NULL&e.code; terminated list of
-		  &s.code;Options&e.code;, and must be interpreted that
-		  way by modules loaded directly by the XFree86 common
-		  layer.  However, it may be used for application-specific
-		  parameter passing in other situations.
-
-		  When loading ``external'' modules (modules that don't
-		  have the standard entry point, for example a
-		  special shared library) the options parameter can be
-		  set to &s.code;EXTERN_MODULE&e.code; to tell the
-		  loader not to reject the module when it doesn't find
-		  the standard entry point.
-
-	</quote>
-
-      &s.code;modreq&e.code;
-	<quote><p>
-		  An optional &s.code;XF86ModReqInfo*&e.code; containing
-		  version/ABI/vendor information to requirements to
-		  check the newly loaded module against.  The main
-		  purpose of this is to allow the loader to verify that
-		  a module of the correct type/version before running
-		  its &s.code;SetupProc&e.code; function.
-
-		  The &s.code;XF86ModReqInfo&e.code; struct is defined
-		  as follows:
-<verb>
-typedef struct {
-	CARD8        majorversion;  /* MAJOR_UNSPEC */
-	CARD8        minorversion;  /* MINOR_UNSPEC */
-	CARD16       patchlevel;    /* PATCH_UNSPEC */
-	const char * abiclass;      /* ABI_CLASS_NONE */
-	CARD32       abiversion;    /* ABI_VERS_UNSPEC */
-	const char * moduleclass;   /* MOD_CLASS_NONE */
-} XF86ModReqInfo;
-</verb>
-
-		  The information here is compared against the equivalent
-		  information in the module's
-		  &s.code;XF86ModuleVersionInfo&e.code; record (which
-		  is described below).  The values in comments above
-		  indicate ``don't care'' settings for each of the fields.
-		  The comparisons made are as follows:
-
-                    &s.code;majorversion&e.code;
-			<quote><p>
-				   Must match the module's majorversion
-				   exactly.
-
-			</quote>
-                    &s.code;minorversion&e.code;
-			<quote><p>
-				   The module's minor version must be
-				   no less than this value.  This
-				   comparison is only made if
-				   &s.code;majorversion&e.code; is
-				   specified and matches.
-
-			</quote>
-                    &s.code;patchlevel&e.code;
-			<quote><p>
-				   The module's patchlevel must be no
-				   less than this value.  This comparison
-				   is only made if
-				   &s.code;minorversion&e.code; is
-				   specified and matches.
-
-			</quote>
-                    &s.code;abiclass&e.code;
-			<quote><p>
-				   String must match the module's abiclass
-				   string.
-
-			</quote>
-                    &s.code;abiversion&e.code;
-			<quote><p>
-				   Must be consistent with the module's
-				   abiversion (major equal, minor no
-				   older).
-
-			</quote>
-                    &s.code;moduleclass&e.code;
-			<quote><p>
-				   String must match the module's
-				   moduleclass string.
-
-			</quote>
-
-	</quote>
-
-      &s.code;errmaj&e.code;
-	<quote><p>
-		  An optional pointer to a variable holding the major
-		  part or the error code.  When provided,
-		  &s.code;*errmaj&e.code; is filled in when
-		  &s.code;LoadModule()&e.code; fails.
-
-	</quote>
-
-      &s.code;errmin&e.code;
-	<quote><p>
-		  Like &s.code;errmaj&e.code;, but for the minor part
-		  of the error code.
-
-	</quote>
-
-  </quote>
-
-  &s.code;void UnloadModule(pointer mod)&e.code;
-  <quote><p>
-    This function unloads the module referred to by the handle mod.
-    All child modules are also unloaded recursively.  This function must
-    not be used to directly unload modules that are child modules (i.e.,
-    those that have been loaded with the &s.code;LoadSubModule()&e.code;
-    described below).
-
-  </quote>
-  </quote>
-
-<sect1>Module Requirements
-<p>
-
-Modules must provide information about themselves to the loader, and
-may optionally provide entry points for "setup" and "teardown" functions
-(those two functions are referred to here as &s.code;SetupProc&e.code;
-and &s.code;TearDownProc&e.code;).
-
-The module information is contained in the
-&s.code;XF86ModuleVersionInfo&e.code; struct, which is defined as follows:
-
-<quote><p><verb>
-typedef struct {
-    const char * modname;      /* name of module, e.g. "foo" */
-    const char * vendor;       /* vendor specific string */
-    CARD32       _modinfo1_;   /* constant MODINFOSTRING1/2 to find */
-    CARD32       _modinfo2_;   /* infoarea with a binary editor/sign tool */
-    CARD32       xf86version;  /* contains XF86_VERSION_CURRENT */
-    CARD8        majorversion; /* module-specific major version */
-    CARD8        minorversion; /* module-specific minor version */
-    CARD16       patchlevel;   /* module-specific patch level */
-    const char * abiclass;     /* ABI class that the module uses */
-    CARD32       abiversion;   /* ABI version */
-    const char * moduleclass;  /* module class */
-    CARD32       checksum[4];  /* contains a digital signature of the */
-                               /* version info structure */
-} XF86ModuleVersionInfo;
-</verb>
-
-The fields are used as follows:
-
-  &s.code;modname&e.code;
-	<quote><p>
-		The module's name.  This field is currently only for
-		informational purposes, but the loader may be modified
-		in future to require it to match the module's canonical
-                name.
-
-	</quote>
-
-  &s.code;vendor&e.code;
-	<quote><p>
-		The module vendor.  This field is for informational purposes
-                only.
-
-	</quote>
-
-  &s.code;_modinfo1_&e.code;
-	<quote><p>
-		This field holds the first part of a signature that can
-                be used to locate this structure in the binary.  It should
-                always be initialised to &s.code;MODINFOSTRING1&e.code;.
-
-	</quote>
-
-  &s.code;_modinfo2_&e.code;
-	<quote><p>
-		This field holds the second part of a signature that can
-                be used to locate this structure in the binary.  It should
-                always be initialised to &s.code;MODINFOSTRING2&e.code;.
-
-	</quote>
-
-  &s.code;xf86version&e.code;
-	<quote><p>
-		The XFree86 version against which the module was compiled.
-                This is mostly for informational/diagnostic purposes.  It
-                should be initialised to &s.code;XF86_VERSION_CURRENT&e.code;, which is
-                defined in &s.code;xf86Version.h&e.code;.
-
-	</quote>
-
-  &s.code;majorversion&e.code;
-	<quote><p>
-		The module-specific major version.  For modules where this
-		version is used for more than simply informational
-		purposes, the major version should only change (be
-		incremented) when ABI incompatibilities are introduced,
-		or ABI components are removed.
-
-	</quote>
-
-  &s.code;minorversion&e.code;
-	<quote><p>
-		The module-specific minor version.  For modules where this
-		version is used for more than simply informational
-		purposes, the minor version should only change (be
-		incremented) when ABI additions are made in a backward
-		compatible way.  It should be reset to zero when the major
-                version is increased.
-
-	</quote>
-
-  &s.code;patchlevel&e.code;
-	<quote><p>
-		The module-specific patch level.  The patch level should
-		increase with new revisions of the module where there
-		are no ABI changes, and it should be reset to zero when
-		the minor version is increased.
-
-	</quote>
-
-  &s.code;abiclass&e.code;
-	<quote><p>
-		The ABI class that the module requires.  The class is
-                specified as a string for easy extensibility.  It should
-		indicate which (if any) of the X server's built-in ABI
-		classes that the module relies on, or a third-party ABI
-                if appropriate.  Built-in ABI classes currently defined are:
-
-		<quote>
-                   &s.code;ABI_CLASS_NONE&e.code;
-			<quote>no class</quote>
-                   &s.code;ABI_CLASS_ANSIC&e.code;
-			<quote>only requires the ANSI C interfaces</quote>
-                   &s.code;ABI_CLASS_VIDEODRV&e.code;
-			<quote>requires the video driver ABI</quote>
-                   &s.code;ABI_CLASS_XINPUT&e.code;
-			<quote>requires the XInput driver ABI</quote>
-                   &s.code;ABI_CLASS_EXTENSION&e.code;
-			<quote>requires the extension module ABI</quote>
-                   &s.code;ABI_CLASS_FONT&e.code;
-			<quote>requires the font module ABI</quote>
-		</quote>
-
-	</quote>
-
-  &s.code;abiversion&e.code;
-	<quote><p>
-		The version of abiclass that the module requires.  The
-		version consists of major and minor components.  The
-		major version must match and the minor version must be
-		no newer than that provided by the server or parent
-		module.  Version identifiers for the built-in classes
-		currently defined are:
-
-		<quote>
-                   &s.code;ABI_ANSIC_VERSION&nl;
-                   ABI_VIDEODRV_VERSION&nl;
-                   ABI_XINPUT_VERSION&nl;
-                   ABI_EXTENSION_VERSION&nl;
-                   ABI_FONT_VERSION&e.code;
-		</quote>
-
-	</quote>
-
-  &s.code;moduleclass&e.code;
-	<quote><p>
-		This is similar to the abiclass field, except that it
-		defines the type of module rather than the ABI it
-		requires.  For example, although all video drivers require
-		the video driver ABI, not all modules that require the
-		video driver ABI are video drivers.  This distinction
-		can be made with the moduleclass.  Currently pre-defined
-		module classes are:
-
-		<quote>
-                   &s.code;MOD_CLASS_NONE&nl;
-                   MOD_CLASS_VIDEODRV&nl;
-                   MOD_CLASS_XINPUT&nl;
-                   MOD_CLASS_FONT&nl;
-                   MOD_CLASS_EXTENSION&e.code;
-		</quote>
-
-	</quote>
-
-  &s.code;checksum&e.code;
-	<quote><p>
-		Not currently used.
-
-	</quote>
-
-</quote>
-
-The module version information, and the optional &s.code;SetupProc&e.code;
-and &s.code;TearDownProc&e.code; entry points are found by the loader
-by locating a data object in the module called "modnameModuleData",
-where "modname" is the canonical name of the module.  Modules must
-contain such a data object, and it must be declared with global scope,
-be compile-time initialised, and is of the following type:
-
-<quote>
-<verb>
-typedef struct {
-    XF86ModuleVersionInfo *     vers;
-    ModuleSetupProc             setup;
-    ModuleTearDownProc          teardown;
-} XF86ModuleData;
-</verb>
-</quote>
-
-The vers parameter must be initialised to a pointer to a correctly
-initialised &s.code;XF86ModuleVersionInfo&e.code; struct.  The other
-two parameter are optional, and should be initialised to
-&s.code;NULL&e.code; when not required.  The other parameters are defined
-as
-
-  <quote><p>
-  &s.code;typedef pointer (*ModuleSetupProc)(pointer, pointer, int *, int *)&e.code;
-
-  &s.code;typedef void (*ModuleTearDownProc)(pointer)&e.code;
-
-
-  &s.code;pointer SetupProc(pointer module, pointer options,
-		&f.indent;int *errmaj, int *errmin)&e.code;
-  <quote><p>
-    When defined, this function is called by the loader after successfully
-    loading a module.  module is a handle for the newly loaded module,
-    and maybe used by the &s.code;SetupProc&e.code; if it calls other
-    loader functions that require a reference to it.   The remaining
-    arguments are those that were passed to the
-    &s.code;LoadModule()&e.code; (or &s.code;LoadSubModule()&e.code;),
-    and are described above. When the &s.code;SetupProc&e.code; is
-    successful it must return a non-&s.code;NULL&e.code; value.  The
-    loader checks this, and if it is &s.code;NULL&e.code; it unloads
-    the module and reports the failure to the caller of
-    &s.code;LoadModule()&e.code;.  If the &s.code;SetupProc&e.code;
-    does things that need to be undone when the module is unloaded,
-    it should define a &s.code;TearDownProc&e.code;, and return a
-    pointer that the &s.code;TearDownProc&e.code; can use to undo what
-    has been done.
-
-    When a module is loaded multiple times, the &s.code;SetupProc&e.code;
-    is called once for each time it is loaded.
-
-  </quote>
-
-  &s.code;void TearDownProc(pointer tearDownData)&e.code;
-  <quote><p>
-    When defined, this function is called when the loader unloads a
-    module.  The &s.code;tearDownData&e.code; parameter is the return
-    value of the &s.code;SetupProc()&e.code; that was called when the
-    module was loaded.  The purpose of this function is to clean up
-    before the module is unloaded (for example, by freeing allocated
-    resources).
-
-  </quote>
-  </quote>
-
-<sect1>Public Loader Interface
-<p>
-
-The following is the Loader interface that is available to any part of
-the server, and may also be used from within modules.
-
-  <quote><p>
-  &s.code;pointer LoadSubModule(pointer parent, const char *module,
-		&f.indent;const char **subdirlist, const char **patternlist,
-		&f.indent;pointer options, const XF86ModReqInfo * modreq,
-		&f.indent;int *errmaj, int *errmin)&e.code;
-  <quote><p>
-    This function is like the &s.code;LoadModule()&e.code; function
-    described above, except that the module loaded is registered as a
-    child of the calling module.  The &s.code;parent&e.code; parameter
-    is the calling module's handle.  Modules loaded with this function
-    are automatically unloaded when the parent module is unloaded.  The
-    other difference is that the path parameter may not be specified.
-    The module search path used for modules loaded with this function
-    is the default search path as initialised with
-    &s.code;LoaderSetPath()&e.code;.
-
-  </quote>
-
-  &s.code;void UnloadSubModule(pointer module)&e.code;
-  <quote><p>
-    This function unloads the module with handle &s.code;module&e.code;.
-    If that module itself has children, they are also unloaded.  It is
-    like &s.code;UnloadModule()&e.code;, except that it is safe to use
-    for unloading child modules.
-
-  </quote>
-
-  &s.code;pointer LoaderSymbol(const char *symbol)&e.code;
-  <quote><p>
-    This function returns the address of the symbol with name
-    &s.code;symbol&e.code;.  This may be used to locate a module entry
-    point with a known name.
-
-  </quote>
-
-  &s.code;char **LoaderlistDirs(const char **subdirlist,
-			&f.indent;const char **patternlist)&e.code;
-  <quote><p>
-    This function returns a &s.code;NULL&e.code; terminated list of
-    canonical modules names for modules found in the default module
-    search path.  The &s.code;subdirlist&e.code; and
-    &s.code;patternlist&e.code; parameters are as described above, and
-    can be used to control the locations and names that are searched.
-    If no modules are found, the return value is &s.code;NULL&e.code;.
-    The returned list should be freed by calling
-    &s.code;LoaderFreeDirList()&e.code; when it is no longer needed.
-
-  </quote>
-
-  &s.code;void LoaderFreeDirList(char **list)&e.code;
-  <quote><p>
-    This function frees a module list created by
-    &s.code;LoaderlistDirs()&e.code;.
-
-  </quote>
-
-  &s.code;void LoaderReqSymLists(const char **list0, ...)&e.code;
-  <quote><p>
-    This function allows the registration of required symbols with the
-    loader.  It is normally used by a caller of
-    &s.code;LoadSubModule()&e.code;.  If any symbols registered in this
-    way are found to be unresolved when
-    &s.code;LoaderCheckUnresolved()&e.code; is called then
-    &s.code;LoaderCheckUnresolved()&e.code; will report a failure.
-    The function takes one or more &s.code;NULL&e.code; terminated
-    lists of symbols.  The end of the argument list is indicated by a
-    &s.code;NULL&e.code; argument.
-
-  </quote>
-
-  &s.code;void LoaderReqSymbols(const char *sym0, ...)&e.code;
-  <quote><p>
-    This function is like &s.code;LoaderReqSymLists()&e.code; except
-    that its arguments are symbols rather than lists of symbols.  This
-    function is more convenient when single functions are to be registered,
-    especially when the single function might depend on runtime factors.
-    The end of the argument list is indicated by a &s.code;NULL&e.code;
-    argument.
-
-  </quote>
-
-  &s.code;void LoaderRefSymLists(const char **list0, ...)&e.code;
-  <quote><p>
-    This function allows the registration of possibly unresolved symbols
-    with the loader.  When &s.code;LoaderCheckUnresolved()&e.code; is
-    run it won't generate warnings for symbols registered in this way
-    unless they were also registered as required symbols.
-    The function takes one or more &s.code;NULL&e.code; terminated
-    lists of symbols.  The end of the argument list is indicated by a
-    &s.code;NULL&e.code; argument.
-
-  </quote>
-
-  &s.code;void LoaderRefSymbols(const char *sym0, ...)&e.code;
-  <quote><p>
-    This function is like &s.code;LoaderRefSymLists()&e.code; except
-    that its arguments are symbols rather than lists of symbols.  This
-    function is more convenient when single functions are to be registered,
-    especially when the single function might depend on runtime factors.
-    The end of the argument list is indicated by a &s.code;NULL&e.code;
-    argument.
-
-  </quote>
-
-  &s.code;int LoaderCheckUnresolved(int delayflag)&e.code;
-  <quote><p>
-    This function checks for unresolved symbols.  It generates warnings
-    for unresolved symbols that have not been registered with
-    &s.code;LoaderRefSymLists()&e.code;, and maps them to a dummy
-    function.  This behaviour may change in future.  If unresolved
-    symbols are found that have been registered with
-    &s.code;LoaderReqSymLists()&e.code; or
-    &s.code;LoaderReqSymbols()&e.code; then this function returns a
-    non-zero value.  If none of these symbols are unresolved the return
-    value is zero, indicating success.
-
-    The &s.code;delayflag&e.code; parameter should normally be set to
-    &s.code;LD_RESOLV_IFDONE&e.code;.
-
-  </quote>
-
-  &s.code;LoaderErrorMsg(const char *name, const char *modname,
-			&f.indent;int errmaj, int errmin)&e.code;
-  <quote><p>
-    This function prints an error message that includes the text ``Failed
-    to load module'', the module name &s.code;modname&e.code;, a message
-    specific to the &s.code;errmaj&e.code; value, and the value if
-    &s.code;errmin&e.code;.  If &s.code;name&e.code; is
-    non-&s.code;NULL&e.code;, it is printed as an identifying prefix
-    to the message (followed by a `:').
-
-  </quote>
-  </quote>
-
-<sect1>Special Registration Functions
-<p>
-
-The loader contains some functions for registering some classes of modules.
-These may be moved out of the loader at some point.
-
-  <quote><p>
-  &s.code;void LoadExtension(ExtensionModule *ext)&e.code;
-  <quote><p>
-    This registers the entry points for the extension identified by
-    &s.code;ext&e.code;.  The &s.code;ExtensionModule&e.code; struct is
-    defined as:
-
-<quote>
-<verb>
-typedef struct {
-    InitExtension       initFunc;
-    char *              name;
-    Bool                *disablePtr;
-    InitExtension       setupFunc;
-} ExtensionModule;
-</verb>
-</quote>
-
-  </quote>
-
-  &s.code;void LoadFont(FontModule *font)&e.code;
-  <quote><p>
-    This registers the entry points for the font rasteriser module
-    identified by &s.code;font&e.code;.  The &s.code;FontModule&e.code;
-    struct is defined as:
-
-<quote>
-<verb>
-typedef struct {
-    InitFont    initFunc;
-    char *      name;
-    pointer     module;
-} FontModule;
-</verb>
-</quote>
-
-  </quote>
-  </quote>
-
-</sect>
-
-
-<sect>Helper Functions
-<p>
-
-This section describe ``helper'' functions that video driver
-might find useful.  While video drivers are not required to use any of
-these to be considered ``compliant'', the use of appropriate helpers is
-strongly encouraged to improve the consistency of driver behaviour.
-
-<sect1>Functions for printing messages
-<p>
-
-  <quote><p>
-    &s.code;ErrorF(const char *format, ...)&e.code;
-    <quote><p>
-      This is the basic function for writing to the error log (typically
-      stderr and/or a log file).  Video drivers should usually avoid
-      using this directly in favour of the more specialised functions
-      described below.  This function is useful for printing messages
-      while debugging a driver.
-
-    </quote>
-
-    &s.code;FatalError(const char *format, ...)&e.code;
-    <quote><p>
-      This prints a message and causes the Xserver to abort.  It should
-      rarely be used within a video driver, as most error conditions
-      should be flagged by the return values of the driver functions.
-      This allows the higher layers to decide how to proceed.  In rare
-      cases, this can be used within a driver if a fatal unexpected
-      condition is found.
-
-    </quote>
-
-    &s.code;xf86ErrorF(const char *format, ...)&e.code;
-    <quote><p>
-      This is like &s.code;ErrorF()&e.code;, except that the message is
-      only printed when the Xserver's verbosity level is set to the
-      default (&s.code;1&e.code;) or higher.  It means that the messages
-      are not printed when the server is started with the
-      &s.cmd;-quiet&e.cmd; flag.  Typically this function would only be
-      used for continuing messages started with one of the more specialised
-      functions described below.
-
-    </quote>
-
-    &s.code;xf86ErrorFVerb(int verb, const char *format, ...)&e.code;
-    <quote><p>
-      Like &s.code;xf86ErrorF()&e.code;, except the minimum verbosity
-      level for which the message is to be printed is given explicitly.
-      Passing a &s.code;verb&e.code; value of zero means the message
-      is always printed.  A value higher than &s.code;1&e.code; can be
-      used for information would normally not be needed, but which might
-      be useful when diagnosing problems.
-
-    </quote>
-
-    &s.code;xf86Msg(MessageType type, const char *format, ...)&e.code;
-    <quote><p>
-      This is like &s.code;xf86ErrorF()&e.code;, except that the message
-      is prefixed with a marker determined by the value of
-      &s.code;type&e.code;.  The marker is used to indicate the type of
-      message (warning, error, probed value, config value, etc).  Note
-      the &s.code;xf86Verbose&e.code; value is ignored for messages of
-      type &s.code;X_ERROR&e.code;.
-
-      The marker values are:
-
-      <quote>
-      &s.code;X_PROBED&e.code;
-	<quote>Value was probed.</quote>
-      &s.code;X_CONFIG&e.code;
-	<quote>Value was given in the config file.</quote>
-      &s.code;X_DEFAULT&e.code;
-	<quote>Value is a default.</quote>
-      &s.code;X_CMDLINE&e.code;
-	<quote>Value was given on the command line.</quote>
-      &s.code;X_NOTICE&e.code;
-	<quote>Notice.</quote>
-      &s.code;X_ERROR&e.code;
-	<quote>Error message.</quote>
-      &s.code;X_WARNING&e.code;
-	<quote>Warning message.</quote>
-      &s.code;X_INFO&e.code;
-	<quote>Informational message.</quote>
-      &s.code;X_NONE&e.code;
-	<quote>No prefix.</quote>
-      &s.code;X_NOT_IMPLEMENTED&e.code;
-	<quote>The message relates to functionality that is not yet
-               implemented.</quote>
-      </quote>
-
-
-    </quote>
-
-    &s.code;xf86MsgVerb(MessageType type, int verb, const char *format, ...)&e.code;
-    <quote><p>
-      Like &s.code;xf86Msg()&e.code;, but with the verbosity level given
-      explicitly.
-
-    </quote>
-
-    &s.code;xf86DrvMsg(int scrnIndex, MessageType type, const char *format, ...)&e.code;
-    <quote><p>
-      This is like &s.code;xf86Msg()&e.code; except that the driver's
-      name (the &s.code;name&e.code; field of the
-      &s.code;ScrnInfoRec&e.code;) followed by the
-      &s.code;scrnIndex&e.code; in parentheses is printed following the
-      prefix.  This should be used by video drivers in most cases as it
-      clearly indicates which driver/screen the message is for.  If
-      &s.code;scrnIndex&e.code; is negative, this function behaves
-      exactly like &s.code;xf86Msg()&e.code;.
-
-      NOTE: This function can only be used after the
-      &s.code;ScrnInfoRec&e.code; and its &s.code;name&e.code; field
-      have been allocated.  Normally, this means that it can not be
-      used before the END of the &s.code;ChipProbe()&e.code; function.
-      Prior to that, use &s.code;xf86Msg()&e.code;, providing the
-      driver's name explicitly.  No screen number can be supplied at
-      that point.
-
-    </quote>
-
-    &s.code;xf86DrvMsgVerb(int scrnIndex, MessageType type, int verb,
-		&f.indent;const char *format, ...)&e.code;
-    <quote><p>
-      Like &s.code;xf86DrvMsg()&e.code;, but with the verbosity level
-      given explicitly.
-
-    </quote>
-  </quote>
-
-
-<sect1>Functions for setting values based on command line and config file
-<p>
-
-  <quote><p>
-    &s.code;Bool xf86SetDepthBpp(ScrnInfoPtr scrp, int depth, int bpp,
-                        &f.indent;int fbbpp, int depth24flags)&e.code;
-    <quote><p>
-      This function sets the &s.code;depth&e.code;, &s.code;pixmapBPP&e.code; and &s.code;bitsPerPixel&e.code; fields
-      of the &s.code;ScrnInfoRec&e.code;.  It also determines the defaults for display-wide
-      attributes and pixmap formats the screen will support, and finds
-      the Display subsection that matches the depth/bpp.  This function
-      should normally be called very early from the
-      &s.code;ChipPreInit()&e.code; function.
-
-      It requires that the &s.code;confScreen&e.code; field of the &s.code;ScrnInfoRec&e.code; be
-      initialised prior to calling it.  This is done by the XFree86
-      common layer prior to calling &s.code;ChipPreInit()&e.code;.
-
-      The parameters passed are:
-
-        &s.code;depth&e.code;
-	<quote><p>
-		driver's preferred default depth if no other is given.
-                If zero, use the overall server default.
-
-	</quote>
-        &s.code;bpp&e.code;
-	<quote><p>
-		Same, but for the pixmap bpp.
-
-	</quote>
-        &s.code;fbbpp&e.code;
-	<quote><p>
-		Same, but for the framebuffer bpp.
-
-	</quote>
-        &s.code;depth24flags&e.code;
-	<quote><p>
-		Flags that indicate the level of 24/32bpp support
-                and whether conversion between different framebuffer
-                and pixmap formats is supported.  The flags for this
-                argument are defined as follows, and multiple flags
-                may be ORed together:
-
-               &s.code;NoDepth24Support&e.code;
-		<quote>No depth 24 formats supported</quote>
-               &s.code;Support24bppFb&e.code;
-		<quote>24bpp framebuffer supported</quote>
-               &s.code;Support32bppFb&e.code;
-		<quote>32bpp framebuffer supported</quote>
-               &s.code;SupportConvert24to32&e.code;
-		<quote>Can convert 24bpp pixmap to 32bpp fb</quote>
-               &s.code;SupportConvert32to24&e.code;
-		<quote>Can convert 32bpp pixmap to 24bpp fb</quote>
-               &s.code;ForceConvert24to32&e.code;
-		<quote>Force 24bpp pixmap to 32bpp fb conversion</quote>
-               &s.code;ForceConvert32to24&e.code;
-		<quote>Force 32bpp pixmap to 24bpp fb conversion</quote>
-
-	</quote>
-
-      It uses the command line, config file, and default values in the
-      correct order of precedence to determine the depth and bpp values.
-      It is up to the driver to check the results to see that it supports
-      them.  If not the &s.code;ChipPreInit()&e.code; function should
-      return &s.code;FALSE&e.code;.
-
-      If only one of depth/bpp is given, the other is set to a reasonable
-      (and consistent) default.
-
-      If a driver finds that the initial &s.code;depth24flags&e.code;
-      it uses later results in a fb format that requires more video
-      memory than is available it may call this function a second time
-      with a different &s.code;depth24flags&e.code; setting.
-
-      On success, the return value is &s.code;TRUE&e.code;.  On failure
-      it prints an error message and returns &s.code;FALSE&e.code;.
-
-      The following fields of the &s.code;ScrnInfoRec&e.code; are
-      initialised by this function:
-
-	<quote>
-	&s.code;depth&e.code;, &s.code;bitsPerPixel&e.code;,
-	&s.code;display&e.code;, &s.code;imageByteOrder&e.code;,
-	&s.code;bitmapScanlinePad&e.code;,
-	&s.code;bitmapScanlineUnit&e.code;, &s.code;bitmapBitOrder&e.code;,
-	&s.code;numFormats&e.code;, &s.code;formats&e.code;,
-	&s.code;fbFormat&e.code;.
-	</quote>
-
-    </quote>
-
-    &s.code;void xf86PrintDepthBpp(scrnInfoPtr scrp)&e.code;
-    <quote><p>
-      This function can be used to print out the depth and bpp settings.
-      It should be called after the final call to
-      &s.code;xf86SetDepthBpp()&e.code;.
-
-    </quote>
-
-    &s.code;Bool xf86SetWeight(ScrnInfoPtr scrp, rgb weight, rgb mask)&e.code;
-    <quote><p>
-      This function sets the &s.code;weight&e.code;, &s.code;mask&e.code;,
-      &s.code;offset&e.code; and &s.code;rgbBits&e.code; fields of the
-      &s.code;ScrnInfoRec&e.code;.  It would normally be called fairly
-      early in the &s.code;ChipPreInit()&e.code; function for
-      depths&nbsp;>&nbsp;8bpp.
-
-      It requires that the &s.code;depth&e.code; and
-      &s.code;display&e.code; fields of the &s.code;ScrnInfoRec&e.code;
-      be initialised prior to calling it.
-
-      The parameters passed are:
-
-        &s.code;weight&e.code;
-	<quote><p>
-		driver's preferred default weight if no other is given.
-                If zero, use the overall server default.
-
-	</quote>
-
-        &s.code;mask&e.code;
-	<quote><p>
-		Same, but for mask.
-
-	</quote>
-
-      It uses the command line, config file, and default values in the
-      correct order of precedence to determine the weight value.  It
-      derives the mask and offset values from the weight and the defaults.
-      It is up to the driver to check the results to see that it supports
-      them.  If not the &s.code;ChipPreInit()&e.code; function should
-      return &s.code;FALSE&e.code;.
-
-      On success, this function prints a message showing the weight
-      values selected, and returns &s.code;TRUE&e.code;.
-
-      On failure it prints an error message and returns &s.code;FALSE&e.code;.
-
-      The following fields of the &s.code;ScrnInfoRec&e.code; are
-      initialised by this function:
-
-	<quote>
-        &s.code;weight&e.code;, &s.code;mask&e.code;, &s.code;offset&e.code;.
-	</quote>
-
-    </quote>
-
-    &s.code;Bool xf86SetDefaultVisual(ScrnInfoPtr scrp, int visual)&e.code;
-    <quote><p>
-      This function sets the &s.code;defaultVisual&e.code; field of the
-      &s.code;ScrnInfoRec&e.code;.  It would normally be called fairly
-      early from the &s.code;ChipPreInit()&e.code; function.
-
-      It requires that the &s.code;depth&e.code; and
-      &s.code;display&e.code; fields of the &s.code;ScrnInfoRec&e.code;
-      be initialised prior to calling it.
-
-      The parameters passed are:
-
-        &s.code;visual&e.code;
-	<quote><p>
-		driver's preferred default visual if no other is given.
-		If &s.code;-1&e.code;, use the overall server default.
-
-	</quote>
-
-      It uses the command line, config file, and default values in the
-      correct order of precedence to determine the default visual value.
-      It is up to the driver to check the result to see that it supports
-      it.  If not the &s.code;ChipPreInit()&e.code; function should
-      return &s.code;FALSE&e.code;.
-
-      On success, this function prints a message showing the default visual
-      selected, and returns &s.code;TRUE&e.code;.
-
-      On failure it prints an error message and returns &s.code;FALSE&e.code;.
-
-    </quote>
-
-    &s.code;Bool xf86SetGamma(ScrnInfoPtr scrp, Gamma gamma)&e.code;
-    <quote><p>
-      This function sets the &s.code;gamma&e.code; field of the
-      &s.code;ScrnInfoRec&e.code;.  It would normally be called fairly
-      early from the &s.code;ChipPreInit()&e.code; function in cases
-      where the driver supports gamma correction.
-
-      It requires that the &s.code;monitor&e.code; field of the
-      &s.code;ScrnInfoRec&e.code; be initialised prior to calling it.
-
-      The parameters passed are:
-
-        &s.code;gamma&e.code;
-	<quote><p>
-		driver's preferred default gamma if no other is given.
-		If zero (&s.code;< 0.01&e.code;), use the overall server
-		default.
-
-	</quote>
-
-      It uses the command line, config file, and default values in the
-      correct order of precedence to determine the gamma value.  It is
-      up to the driver to check the results to see that it supports
-      them.  If not the &s.code;ChipPreInit()&e.code; function should
-      return &s.code;FALSE&e.code;.
-
-      On success, this function prints a message showing the gamma
-      value selected, and returns &s.code;TRUE&e.code;.
-
-      On failure it prints an error message and returns &s.code;FALSE&e.code;.
-
-    </quote>
-
-    &s.code;void xf86SetDpi(ScrnInfoPtr pScrn, int x, int y)&e.code;
-    <quote><p>
-      This function sets the &s.code;xDpi&e.code; and &s.code;yDpi&e.code;
-      fields of the &s.code;ScrnInfoRec&e.code;.  The driver can specify
-      preferred defaults by setting &s.code;x&e.code; and &s.code;y&e.code;
-      to non-zero values.  The &s.cmd;-dpi&e.cmd; command line option
-      overrides all other settings.  Otherwise, if the
-      &s.key;DisplaySize&e.key; entry is present in the screen's &k.monitor;
-      config file section, it is used together with the virtual size to
-      calculate the dpi values.  This function should be called after
-      all the mode resolution has been done.
-
-    </quote>
-
-    &s.code;void xf86SetBlackWhitePixels(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      This functions sets the &s.code;blackPixel&e.code; and
-      &s.code;whitePixel&e.code; fields of the &s.code;ScrnInfoRec&e.code;
-      according to whether or not the &s.cmd;-flipPixels&e.cmd; command
-      line options is present.
-
-    </quote>
-
-    &s.code;const char *xf86GetVisualName(int visual)&e.code;
-    <quote><p>
-      Returns a printable string with the visual name matching the
-      numerical visual class provided.  If the value is outside the
-      range of valid visual classes, &s.code;NULL&e.code; is returned.
-
-    </quote>
-  </quote>
-
-
-<sect1>Primary Mode functions
-<p>
-
-The primary mode helper functions are those which would normally be
-used by a driver, unless it has unusual requirements which cannot
-be catered for the by the helpers.
-
-  <quote><p>
-    &s.code;int xf86ValidateModes(ScrnInfoPtr scrp, DisplayModePtr availModes,
-		&f.indent;char **modeNames, ClockRangePtr clockRanges,
-		&f.indent;int *linePitches, int minPitch, int maxPitch,
-		&f.indent;int pitchInc, int minHeight, int maxHeight,
-		&f.indent;int virtualX, int virtualY,
-		&f.indent;unsigned long apertureSize,
-		&f.indent;LookupModeFlags strategy)&e.code;
-    <quote><p>
-      This function basically selects the set of modes to use based on
-      those available and the various constraints.  It also sets some
-      other related parameters.  It is normally called near the end of
-      the &s.code;ChipPreInit()&e.code; function.
-
-      The parameters passed to the function are:
-
-        &s.code;availModes&e.code;
-	<quote><p>
-		List of modes available for the monitor.
-
-	</quote>
-        &s.code;modeNames&e.code;
-	<quote><p>
-		List of mode names that the screen is requesting.
-
-	</quote>
-        &s.code;clockRanges&e.code;
-	<quote><p>
-		A list of clock ranges allowed by the driver.  Each
-		range includes whether interlaced or multiscan modes
-		are supported for that range.  See below for more on
-		&s.code;clockRanges&e.code;.
-
-	</quote>
-        &s.code;linePitches&e.code;
-	<quote><p>
-		List of line pitches supported by the driver.
-		This is optional and should be &s.code;NULL&e.code; when
-		not used.
-
-	</quote>
-        &s.code;minPitch&e.code;
-	<quote><p>
-		Minimum line pitch supported by the driver.  This must
-		be supplied when &s.code;linePitches&e.code; is
-		&s.code;NULL&e.code;, and is ignored otherwise.
-
-	</quote>
-        &s.code;maxPitch&e.code;
-	<quote><p>
-		Maximum line pitch supported by the driver.  This is
-		required when &s.code;minPitch&e.code; is required.
-
-	</quote>
-        &s.code;pitchInc&e.code;
-	<quote><p>
-		Granularity of horizontal pitch values as supported by
-		the chipset.  This is expressed in bits.  This must be
-		supplied.
-
-	</quote>
-        &s.code;minHeight&e.code;
-	<quote><p>
-		minimum virtual height allowed.  If zero, no limit is
-		imposed.
-
-	</quote>
-        &s.code;maxHeight&e.code;
-	<quote><p>
-		maximum virtual height allowed.  If zero, no limit is
-		imposed.
-
-	</quote>
-        &s.code;virtualX&e.code;
-	<quote><p>
-		If greater than zero, this is the virtual width value
-		that will be used.  Otherwise, the virtual width is
-		chosen to be the smallest that can accommodate the modes
-		selected.
-
-	</quote>
-        &s.code;virtualY&e.code;
-	<quote><p>
-		If greater than zero, this is the virtual height value
-		that will be used.  Otherwise, the virtual height is
-		chosen to be the smallest that can accommodate the modes
-		selected.
-
-	</quote>
-        &s.code;apertureSize&e.code;
-	<quote><p>
-		The size (in bytes) of the aperture used to access video
-		memory.
-
-	</quote>
-        &s.code;strategy&e.code;
-	<quote><p>
-		The strategy to use when choosing from multiple modes
-		with the same name.  The options are:
-
-                &s.code;LOOKUP_DEFAULT&e.code;
-		<quote>???</quote>
-                &s.code;LOOKUP_BEST_REFRESH&e.code;
-		<quote>mode with best refresh rate</quote>
-                &s.code;LOOKUP_CLOSEST_CLOCK&e.code;
-		<quote>mode with closest matching clock</quote>
-                &s.code;LOOKUP_LIST_ORDER&e.code;
-		<quote>first usable mode in list</quote>
-
-		The following options can also be combined (OR'ed) with
-		one of the above:
-
-                &s.code;LOOKUP_CLKDIV2&e.code;
-		<quote>Allow halved clocks</quote>
-		&s.code;LOOKUP_OPTIONAL_TOLERANCES&e.code;
-		<quote>Allow missing horizontal sync and/or vertical refresh
-		ranges in the xorg.conf Monitor section</quote>
-
-		&s.code;LOOKUP_OPTIONAL_TOLERANCES&e.code; should only be
-		specified when the driver can ensure all modes it generates
-		can sync on, or at least not damage, the monitor or digital
-		flat panel.  Horizontal sync and/or vertical refresh ranges
-		specified by the user will still be honoured (and acted upon).
-
-	</quote>
-
-      This function requires that the following fields of the
-      &s.code;ScrnInfoRec&e.code; are initialised prior to calling it:
-
-        &s.code;clock[]&e.code;
-	<quote>List of discrete clocks (when non-programmable)</quote>
-        &s.code;numClocks&e.code;
-	<quote>Number of discrete clocks (when non-programmable)</quote>
-        &s.code;progClock&e.code;
-	<quote>Whether the clock is programmable or not</quote>
-        &s.code;monitor&e.code;
-	<quote>Pointer to the applicable xorg.conf monitor section</quote>
-        &s.code;fdFormat&e.code;
-	<quote>Format of the screen buffer</quote>
-        &s.code;videoRam&e.code;
-	<quote>total video memory size (in bytes)</quote>
-        &s.code;maxHValue&e.code;
-	<quote>Maximum horizontal timing value allowed</quote>
-        &s.code;maxVValue&e.code;
-	<quote>Maximum vertical timing value allowed</quote>
-        &s.code;xInc&e.code;
-	<quote>Horizontal timing increment in pixels (defaults to 8)</quote>
-
-      This function fills in the following &s.code;ScrnInfoRec&e.code;
-      fields:
-
-        &s.code;modePool&e.code;
-	<quote><p>
-		A subset of the modes available to the monitor which
-                are compatible with the driver.
-
-	</quote>
-        &s.code;modes&e.code;
-	<quote><p>
-		One mode entry for each of the requested modes, with
-                the status field of each filled in to indicate if
-                the mode has been accepted or not.  This list of
-                modes is a circular list.
-
-	</quote>
-        &s.code;virtualX&e.code;
-	<quote><p>
-		The resulting virtual width.
-
-	</quote>
-        &s.code;virtualY&e.code;
-	<quote><p>
-		The resulting virtual height.
-
-	</quote>
-        &s.code;displayWidth&e.code;
-	<quote><p>
-		The resulting line pitch.
-
-	</quote>
-        &s.code;virtualFrom&e.code;
-	<quote><p>
-		Where the virtual size was determined from.
-
-	</quote>
-
-      The first stage of this function checks that the
-      &s.code;virtualX&e.code; and &s.code;virtualY&e.code; values
-      supplied (if greater than zero) are consistent with the line pitch
-      and &s.code;maxHeight&e.code; limitations.  If not, an error
-      message is printed, and the return value is &s.code;-1&e.code;.
-
-      The second stage sets up the mode pool, eliminating immediately
-      any modes that exceed the driver's line pitch limits, and also
-      the virtual width and height limits (if greater than zero).  For
-      each mode removed an informational message is printed at verbosity
-      level &s.code;2&e.code;.  If the mode pool ends up being empty,
-      a warning message is printed, and the return value is
-      &s.code;0&e.code;.
-
-      The final stage is to lookup each mode name, and fill in the remaining
-      parameters.  If an error condition is encountered, a message is
-      printed, and the return value is &s.code;-1&e.code;.  Otherwise,
-      the return value is the number of valid modes found
-      (&s.code;0&e.code; if none are found).
-
-      Even if the supplied mode names include duplicates, no two names will
-      ever match the same mode.  Furthermore, if the supplied mode names do not
-      yield a valid mode (including the case where no names are passed at all),
-      the function will continue looking through the mode pool until it finds
-      a mode that survives all checks, or until the mode pool is exhausted.
-
-      A message is only printed by this function when a fundamental
-      problem is found.  It is intended that this function may be called
-      more than once if there is more than one set of constraints that
-      the driver can work within.
-
-      If this function returns &s.code;-1&e.code;, the
-      &s.code;ChipPreInit()&e.code; function should return
-      &s.code;FALSE&e.code;.
-
-      &s.code;clockRanges&e.code; is a linked list of clock ranges
-      allowed by the driver.  If a mode doesn't fit in any of the defined
-      &s.code;clockRanges&e.code;, it is rejected.  The first
-      &s.code;clockRange&e.code; that matches all requirements is used.
-      This structure needs to be initialized to NULL when allocated.
-
-      &s.code;clockRanges&e.code; contains the following fields:
-
-        &s.code;minClock&nl;
-        maxClock&e.code;
-	<quote><p>
-		The lower and upper mode clock bounds for which the rest
-		of the &s.code;clockRange&e.code; parameters apply.
-		Since these are the mode clocks, they are not scaled
-		with the &s.code;ClockMulFactor&e.code; and
-		&s.code;ClockDivFactor&e.code;.  It is up to the driver
-		to adjust these values if they depend on the clock
-		scaling factors.
-
-	</quote>
-        &s.code;clockIndex&e.code;
-	<quote><p>
-		(not used yet) &s.code;-1&e.code; for programmable clocks
-
-	</quote>
-        &s.code;interlaceAllowed&e.code;
-	<quote><p>
-		&s.code;TRUE&e.code; if interlacing is allowed for this
-		range
-
-	</quote>
-        &s.code;doubleScanAllowed&e.code;
-	<quote><p>
-		&s.code;TRUE&e.code; if doublescan or multiscan is allowed
-		for this range
-
-	</quote>
-        &s.code;ClockMulFactor&nl;
-        ClockDivFactor&e.code;
-	<quote><p>
-		Scaling factors that are applied to the mode clocks ONLY
-		before selecting a clock index (when there is no
-		programmable clock) or a &s.code;SynthClock&e.code;
-		value.  This is useful for drivers that support pixel
-		multiplexing or that need to scale the clocks because
-		of hardware restrictions (like sending 24bpp data to an
-		8 bit RAMDAC using a tripled clock).
-
-		Note that these parameters describe what must be done
-		to the mode clock to achieve the data transport clock
-		between graphics controller and RAMDAC.  For example
-		for &s.code;2:1&e.code; pixel multiplexing, two pixels
-		are sent to the RAMDAC on each clock.  This allows the
-		RAMDAC clock to be half of the actual pixel clock.
-		Hence, &s.code;ClockMulFactor=1&e.code; and
-		&s.code;ClockDivFactor=2&e.code;.  This means that the
-		clock used for clock selection (ie, determining the
-		correct clock index from the list of discrete clocks)
-		or for the &s.code;SynthClock&e.code; field in case of
-		a programmable clock is:  (&s.code;mode-&gt;Clock *
-		ClockMulFactor) / ClockDivFactor&e.code;.
-
-	</quote>
-	&s.code;PrivFlags&e.code;
-	<quote><p>
-		This field is copied into the
-		&s.code;mode-&gt;PrivFlags&e.code; field when this
-		&s.code;clockRange&e.code; is selected by
-		&s.code;xf86ValidateModes()&e.code;.  It allows the
-		driver to find out what clock range was selected, so it
-		knows it needs to set up pixel multiplexing or any other
-		range-dependent feature.  This field is purely
-		driver-defined: it may contain flag bits, an index or
-		anything else (as long as it is an &s.code;INT&e.code;).
-	</quote>
-
-      Note that the &s.code;mode-&gt;SynthClock&e.code; field is always
-      filled in by &s.code;xf86ValidateModes()&e.code;: it will contain
-      the ``data transport clock'', which is the clock that will have
-      to be programmed in the chip when it has a programmable clock, or
-      the clock that will be picked from the clocks list when it is not
-      a programmable one.  Thus:
-
-         &s.code;mode-&gt;SynthClock =
-		&f.indent;(mode-&gt;Clock * ClockMulFactor) / ClockDivFactor&e.code;
-
-    </quote>
-
-    &s.code;void xf86PruneDriverModes(ScrnInfoPtr scrp)&e.code;
-    <quote><p>
-      This function deletes modes in the modes field of the
-      &s.code;ScrnInfoRec&e.code; that have been marked as invalid.
-      This is normally run after having run
-      &s.code;xf86ValidateModes()&e.code; for the last time.  For each
-      mode that is deleted, a warning message is printed out indicating
-      the reason for it being deleted.
-
-    </quote>
-
-    &s.code;void xf86SetCrtcForModes(ScrnInfoPtr scrp, int adjustFlags)&e.code;
-    <quote><p>
-      This function fills in the &s.code;Crtc*&e.code; fields for all
-      the modes in the &s.code;modes&e.code; field of the
-      &s.code;ScrnInfoRec&e.code;.  The &s.code;adjustFlags&e.code;
-      parameter determines how the vertical CRTC values are scaled for
-      interlaced modes.  They are halved if it is
-      &s.code;INTERLACE_HALVE_V&e.code;.  The vertical CRTC values are
-      doubled for doublescan modes, and are further multiplied by the
-      &s.code;VScan&e.code; value.
-
-      This function is normally called after calling
-      &s.code;xf86PruneDriverModes()&e.code;.
-
-    </quote>
-
-    &s.code;void xf86PrintModes(ScrnInfoPtr scrp)&e.code;
-    <quote><p>
-      This function prints out the virtual size setting, and the line
-      pitch being used.  It also prints out two lines for each mode being
-      used.  The first line includes the mode's pixel clock, horizontal sync
-      rate, refresh rate, and whether it is interlaced, doublescanned and/or
-      multi-scanned.  The second line is the mode's Modeline.
-
-      This function is normally called after calling
-      &s.code;xf86SetCrtcForModes()&e.code;.
-
-    </quote>
-  </quote>
-
-
-<sect1>Secondary Mode functions
-<p>
-
-The secondary mode helper functions are functions which are normally
-used by the primary mode helper functions, and which are not normally
-called directly by a driver.  If a driver has unusual requirements
-and needs to do its own mode validation, it might be able to make
-use of some of these secondary mode helper functions.
-
-  <quote><p>
-    &s.code;int xf86GetNearestClock(ScrnInfoPtr scrp, int freq, Bool allowDiv2,
-			&f.indent;int *divider)&e.code;
-    <quote><p>
-      This function returns the index of the closest clock to the
-      frequency &s.code;freq&e.code; given (in kHz).  It assumes that
-      the number of clocks is greater than zero.  It requires that the
-      &s.code;numClocks&e.code; and &s.code;clock&e.code; fields of the
-      &s.code;ScrnInfoRec&e.code; are initialised.  The
-      &s.code;allowDiv2&e.code; field determines if the clocks can be
-      halved.  The &s.code;*divider&e.code; return value indicates
-      whether clock division is used when determining the clock returned.
-
-      This function is only for non-programmable clocks.
-
-    </quote>
-
-    &s.code;const char *xf86ModeStatusToString(ModeStatus status)&e.code;
-    <quote><p>
-      This function converts the &s.code;status&e.code; value to a
-      descriptive printable string.
-
-    </quote>
-
-    &s.code;ModeStatus xf86LookupMode(ScrnInfoPtr scrp, DisplayModePtr modep,
-		&f.indent;ClockRangePtr clockRanges, LookupModeFlags strategy)&e.code;
-    <quote><p>
-      This function takes a pointer to a mode with the name filled in,
-      and looks for a mode in the &s.code;modePool&e.code; list which
-      matches.  The parameters of the matching mode are filled in to
-      &s.code;*modep&e.code;.  The &s.code;clockRanges&e.code; and
-      &s.code;strategy&e.code; parameters are as for the
-      &s.code;xf86ValidateModes()&e.code; function above.
-
-      This function requires the &s.code;modePool&e.code;,
-      &s.code;clock[]&e.code;, &s.code;numClocks&e.code; and
-      &s.code;progClock&e.code; fields of the &s.code;ScrnInfoRec&e.code;
-      to be initialised before being called.
-
-      The return value is &s.code;MODE_OK&e.code; if a mode was found.
-      Otherwise it indicates why a matching mode could not be found.
-
-    </quote>
-
-    &s.code;ModeStatus xf86InitialCheckModeForDriver(ScrnInfoPtr scrp,
-		&f.indent;DisplayModePtr mode, ClockRangePtr clockRanges,
-		&f.indent;LookupModeFlags strategy, int maxPitch,
-		&f.indent;int virtualX, int virtualY)&e.code;
-    <quote><p>
-      This function checks the passed mode against some basic driver
-      constraints.  Apart from the ones passed explicitly, the
-      &s.code;maxHValue&e.code; and &s.code;maxVValue&e.code; fields of
-      the &s.code;ScrnInfoRec&e.code; are also used.  If the
-      &s.code;ValidMode&e.code; field of the &s.code;ScrnInfoRec&e.code;
-      is set, that function is also called to check the mode.  Next, the
-      mode is checked against the monitor's constraints.
-
-      If the mode is consistent with all constraints, the return value
-      is &s.code;MODE_OK&e.code;.  Otherwise the return value indicates
-      which constraint wasn't met.
-
-    </quote>
-
-    &s.code;void xf86DeleteMode(DisplayModePtr *modeList, DisplayModePtr mode)&e.code;
-    <quote><p>
-      This function deletes the &s.code;mode&e.code; given from the
-      &s.code;modeList&e.code;.  It never prints any messages, so it is
-      up to the caller to print a message if required.
-
-    </quote>
-  </quote>
-
-<sect1>Functions for handling strings and tokens
-<p>
-
-    Tables associating strings and numerical tokens combined with the
-    following functions provide a compact way of handling strings from
-    the config file, and for converting tokens into printable strings.
-    The table data structure is:
-
-<quote><verb>
-typedef struct {
-    int                 token;
-    const char *        name;
-} SymTabRec, *SymTabPtr;
-</verb></quote>
-
-    A table is an initialised array of &s.code;SymTabRec&e.code;.  The
-    tokens must be non-negative integers.  Multiple names may be mapped
-    to a single token.  The table is terminated with an element with a
-    &s.code;token&e.code; value of &s.code;-1&e.code; and
-    &s.code;NULL&e.code; for the &s.code;name&e.code;.
-
-
-  <quote><p>
-    &s.code;const char *xf86TokenToString(SymTabPtr table, int token)&e.code;
-    <quote><p>
-      This function returns the first string in &s.code;table&e.code;
-      that matches &s.code;token&e.code;.  If no match is found,
-      &s.code;NULL&e.code; is returned (NOTE, older versions of this
-      function would return the string "unknown" when no match is found).
-
-    </quote>
-
-    &s.code;int xf86StringToToken(SymTabPtr table, const char *string)&e.code;
-    <quote><p>
-      This function returns the first token in &s.code;table&e.code;
-      that matches &s.code;string&e.code;.  The
-      &s.code;xf86NameCmp()&e.code; function is used to determine the
-      match.  If no match is found, &s.code;-1&e.code; is returned.
-
-    </quote>
-  </quote>
-
-
-<sect1>Functions for finding which config file entries to use
-<p>
-
-    These functions can be used to select the appropriate config file
-    entries that match the detected hardware.  They are described above
-    in the <ref id="probe" name="Probe"> and
-    <ref id="avail" name="Available Functions"> sections.
-
-
-<sect1>Probing discrete clocks on old hardware
-<p>
-
-    The &s.code;xf86GetClocks()&e.code; function may be used to assist
-    in finding the discrete pixel clock values on older hardware.
-
-
-  <quote><p>
-    &s.code;void xf86GetClocks(ScrnInfoPtr pScrn, int num,
-		&f.indent;Bool (*ClockFunc)(ScrnInfoPtr, int),
-		&f.indent;void (*ProtectRegs)(ScrnInfoPtr, Bool),
-		&f.indent;void (*BlankScreen)(ScrnInfoPtr, Bool),
-		&f.indent;int vertsyncreg, int maskval, int knownclkindex,
-		&f.indent;int knownclkvalue)&e.code;
-    <quote><p>
-      This function uses a comparative sampling method to measure the
-      discrete pixel clock values.  The number of discrete clocks to
-      measure is given by &s.code;num&e.code;.  &s.code;clockFunc&e.code;
-      is a function that selects the &s.code;n&e.code;'th clock.  It
-      should also save or restore any state affected by programming the
-      clocks when the index passed is &s.code;CLK_REG_SAVE&e.code; or
-      &s.code;CLK_REG_RESTORE&e.code;.  &s.code;ProtectRegs&e.code; is
-      a function that does whatever is required to protect the hardware
-      state while selecting a new clock.  &s.code;BlankScreen&e.code;
-      is a function that blanks the screen.  &s.code;vertsyncreg&e.code;
-      and &s.code;maskval&e.code; are the register and bitmask to
-      check for the presence of vertical sync pulses.
-      &s.code;knownclkindex&e.code; and &s.code;knownclkvalue&e.code;
-      are the index and value of a known clock.  These are the known
-      references on which the comparative measurements are based.  The
-      number of clocks probed is set in &s.code;pScrn-&gt;numClocks&e.code;,
-      and the probed clocks are set in the &s.code;pScrn-&gt;clock[]&e.code;
-      array.  All of the clock values are in units of kHz.
-
-    </quote>
-
-    &s.code;void xf86ShowClocks(ScrnInfoPtr scrp, MessageType from)&e.code;
-    <quote><p>
-      Print out the pixel clocks &s.code;scrp-&gt;clock[]&e.code;.
-      &s.code;from&e.code; indicates whether the clocks were probed
-      or from the config file.
-
-    </quote>
-  </quote>
-
-<sect1>Other helper functions
-<p>
-  <quote><p>
-    &s.code;Bool xf86IsUnblank(int mode)&e.code;
-    <quote><p>
-      Returns &s.code;TRUE&e.code; when the screen saver mode specified
-      by &s.code;mode&e.code; requires the screen be unblanked,
-      and &s.code;FALSE&e.code; otherwise.  The screen saver modes that
-      require blanking are &s.code;SCREEN_SAVER_ON&e.code; and
-      &s.code;SCREEN_SAVER_CYCLE&e.code;, and the screen saver modes that
-      require unblanking are &s.code;SCREEN_SAVER_OFF&e.code; and
-      &s.code;SCREEN_SAVER_FORCER&e.code;.  Drivers may call this helper
-      from their &s.code;SaveScreen()&e.code; function to interpret the
-      screen saver modes.
-
-    </quote>
-  </quote>
-
-<sect>The vgahw module
-<p>
-
-The vgahw modules provides an interface for saving, restoring and
-programming the standard VGA registers, and for handling VGA colourmaps.
-
-<sect1>Data Structures
-<p>
-
-    The public data structures used by the vgahw module are
-    &s.code;vgaRegRec&e.code; and &s.code;vgaHWRec&e.code;.  They are
-    defined in &s.code;vgaHW.h.&e.code;
-
-
-<sect1>General vgahw Functions
-<p>
-
-  <quote><p>
-    &s.code;Bool vgaHWGetHWRec(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      This function allocates a &s.code;vgaHWRec&e.code; structure, and
-      hooks it into the &s.code;ScrnInfoRec&e.code;'s
-      &s.code;privates&e.code;.  Like all information hooked into the
-      &s.code;privates&e.code;, it is persistent, and only needs to be
-      allocated once per screen.  This function should normally be called
-      from the driver's &s.code;ChipPreInit()&e.code; function.  The
-      &s.code;vgaHWRec&e.code; is zero-allocated, and the following
-      fields are explicitly initialised:
-
-        &s.code;ModeReg.DAC[]&e.code;
-	<quote>initialised with a default colourmap</quote>
-        &s.code;ModeReg.Attribute[0x11]&e.code;
-	<quote>initialised with the default overscan index</quote>
-        &s.code;ShowOverscan&e.code;
-	<quote>initialised according to the "ShowOverscan" option</quote>
-        &s.code;paletteEnabled&e.code;
-	<quote>initialised to FALSE</quote>
-        &s.code;cmapSaved&e.code;
-	<quote>initialised to FALSE</quote>
-        &s.code;pScrn&e.code;
-	<quote>initialised to pScrn</quote>
-
-      In addition to the above, &s.code;vgaHWSetStdFuncs()&e.code; is
-      called to initialise the register access function fields with the
-      standard VGA set of functions.
-
-      Once allocated, a pointer to the &s.code;vgaHWRec&e.code; can be
-      obtained from the &s.code;ScrnInfoPtr&e.code; with the
-      &s.code;VGAHWPTR(pScrn)&e.code; macro.
-
-    </quote>
-
-    &s.code;void vgaHWFreeHWRec(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      This function frees a &s.code;vgaHWRec&e.code; structure.  It
-      should be called from a driver's &s.code;ChipFreeScreen()&e.code;
-      function.
-
-    </quote>
-
-    &s.code;Bool vgaHWSetRegCounts(ScrnInfoPtr pScrn, int numCRTC,
-		&f.indent;int numSequencer, int numGraphics, int numAttribute)&e.code;
-    <quote><p>
-      This function allows the number of CRTC, Sequencer, Graphics and
-      Attribute registers to be changed.  This makes it possible for
-      extended registers to be saved and restored with
-      &s.code;vgaHWSave()&e.code; and &s.code;vgaHWRestore()&e.code;.
-      This function should be called after a &s.code;vgaHWRec&e.code;
-      has been allocated with &s.code;vgaHWGetHWRec()&e.code;.  The
-      default values are defined in &s.code;vgaHW.h&e.code; as follows:
-
-      <quote><verb>
-#define VGA_NUM_CRTC 25
-#define VGA_NUM_SEQ   5
-#define VGA_NUM_GFX   9
-#define VGA_NUM_ATTR 21
-      </verb></quote>
-
-    </quote>
-
-    &s.code;Bool vgaHWCopyReg(vgaRegPtr dst, vgaRegPtr src)&e.code;
-    <quote><p>
-      This function copies the contents of the VGA saved registers in
-      &s.code;src&e.code; to &s.code;dst&e.code;.  Note that it isn't
-      possible to simply do this with &s.code;memcpy()&e.code; (or
-      similar).  This function returns &s.code;TRUE&e.code; unless there
-      is a problem allocating space for the &s.code;CRTC&e.code and
-      related fields in &s.code;dst&e.code;.
-
-    </quote>
-
-    &s.code;void vgaHWSetStdFuncs(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      This function initialises the register access function fields of
-      &s.code;hwp&e.code; with the standard VGA set of functions.  This
-      is called by &s.code;vgaHWGetHWRec()&e.code;, so there is usually
-      no need to call this explicitly.  The register access functions
-      are described below.  If the registers are shadowed in some other
-      port I/O space (for example a PCI I/O region), these functions
-      can be used to access the shadowed registers if
-      &s.code;hwp-&gt;PIOOffset&e.code; is initialised with
-      &s.code;offset&e.code;, calculated in such a way that when the
-      standard VGA I/O port value is added to it the correct offset into
-      the PIO area results.  This value is initialised to zero in
-      &s.code;vgaHWGetHWRec()&e.code;.  (Note: the PIOOffset functionality
-      is present in XFree86 4.1.0 and later.)
-
-    </quote>
-
-    &s.code;void vgaHWSetMmioFuncs(vgaHWPtr hwp, CARD8 *base, int offset)&e.code;
-    <quote><p>
-      This function initialised the register access function fields of
-      hwp with a generic MMIO set of functions.
-      &s.code;hwp-&gt;MMIOBase&e.code; is initialised with
-      &s.code;base&e.code;, which must be the virtual address that the
-      start of MMIO area is mapped to.  &s.code;hwp-&gt;MMIOOffset&e.code;
-      is initialised with &s.code;offset&e.code;, which must be calculated
-      in such a way that when the standard VGA I/O port value is added
-      to it the correct offset into the MMIO area results.  That means
-      that these functions are only suitable when the VGA I/O ports are
-      made available in a direct mapping to the MMIO space.  If that is
-      not the case, the driver will need to provide its own register
-      access functions.  The register access functions are described
-      below.
-
-    </quote>
-
-    &s.code;Bool vgaHWMapMem(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      This function maps the VGA memory window.  It requires that the
-      &s.code;vgaHWRec&e.code; be allocated.  If a driver requires
-      non-default &s.code;MapPhys&e.code; or &s.code;MapSize&e.code;
-      settings (the physical location and size of the VGA memory window)
-      then those fields of the &s.code;vgaHWRec&e.code; must be initialised
-      before calling this function.  Otherwise, this function initialiases
-      the default values of &s.code;0xA0000&e.code; for
-      &s.code;MapPhys&e.code; and &s.code;(64&nbsp;*&nbsp;1024)&e.code; for
-      &s.code;MapSize&e.code;.  This function must be called before
-      attempting to save or restore the VGA state.  If the driver doesn't
-      call it explicitly, the &s.code;vgaHWSave()&e.code; and
-      &s.code;vgaHWRestore()&e.code; functions may call it if they need
-      to access the VGA memory (in which case they will also call
-      &s.code;vgaHWUnmapMem()&e.code; to unmap the VGA memory before
-      exiting).
-
-    </quote>
-
-    &s.code;void vgaHWUnmapMem(ScrnInfoPtr pScrn)&e.code;
-    <quote><p>
-      This function unmaps the VGA memory window.  It must only be called
-      after the memory has been mapped.  The &s.code;Base&e.code; field
-      of the &s.code;vgaHWRec&e.code; field is set to &s.code;NULL&e.code;
-      to indicate that the memory is no longer mapped.
-
-    </quote>
-
-    &s.code;void vgaHWGetIOBase(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      This function initialises the &s.code;IOBase&e.code; field of the
-      &s.code;vgaHWRec&e.code;.  This function must be called before
-      using any other functions that access the video hardware.
-
-      A macro &s.code;VGAHW_GET_IOBASE()&e.code; is also available in
-      &s.code;vgaHW.h&e.code; that returns the I/O base, and this may
-      be used when the vgahw module is not loaded (for example, in the
-      &s.code;ChipProbe()&e.code; function).
-
-    </quote>
-
-    &s.code;void vgaHWUnlock(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      This function unlocks the VGA &s.code;CRTC[0-7]&e.code; registers,
-      and must be called before attempting to write to those registers.
-
-    </quote>
-
-    &s.code;void vgaHWLock(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      This function locks the VGA &s.code;CRTC[0-7]&e.code; registers.
-
-    </quote>
-
-    &s.code;void vgaHWEnable(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      This function enables the VGA subsystem.  (Note, this function is
-      present in XFree86 4.1.0 and later.).
-
-    </quote>
-
-    &s.code;void vgaHWDisable(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      This function disables the VGA subsystem.  (Note, this function is
-      present in XFree86 4.1.0 and later.).
-
-    </quote>
-
-    &s.code;void vgaHWSave(ScrnInfoPtr pScrn, vgaRegPtr save, int flags)&e.code;
-    <quote><p>
-      This function saves the VGA state.  The state is written to the
-      &s.code;vgaRegRec&e.code; pointed to by &s.code;save&e.code;.
-      &s.code;flags&e.code; is set to one or more of the following flags
-      ORed together:
-
-        &s.code;VGA_SR_MODE&e.code;
-	<quote>the mode setting registers are saved</quote>
-        &s.code;VGA_SR_FONTS&e.code;
-	<quote>the text mode font/text data is saved</quote>
-        &s.code;VGA_SR_CMAP&e.code;
-	<quote>the colourmap (LUT) is saved</quote>
-        &s.code;VGA_SR_ALL&e.code;
-	<quote>all of the above are saved</quote>
-
-      The &s.code;vgaHWRec&e.code; and its &s.code;IOBase&e.code; fields
-      must be initialised before this function is called.  If
-      &s.code;VGA_SR_FONTS&e.code; is set in &s.code;flags&e.code;, the
-      VGA memory window must be mapped.  If it isn't then
-      &s.code;vgaHWMapMem()&e.code; will be called to map it, and
-      &s.code;vgaHWUnmapMem()&e.code; will be called to unmap it
-      afterwards.  &s.code;vgaHWSave()&e.code; uses the three functions
-      below in the order &s.code;vgaHWSaveColormap()&e.code;,
-      &s.code;vgaHWSaveMode()&e.code;, &s.code;vgaHWSaveFonts()&e.code; to
-      carry out the different save phases.  It is undecided at this
-      stage whether they will remain part of the vgahw module's public
-      interface or not.
-
-    </quote>
-
-    &s.code;void vgaHWSaveMode(ScrnInfoPtr pScrn, vgaRegPtr save)&e.code;
-    <quote><p>
-      This function saves the VGA mode registers.  They are saved to
-      the &s.code;vgaRegRec&e.code; pointed to by &s.code;save&e.code;.
-      The registers saved are:
-
-	<quote>
-        &s.code;MiscOut&nl;
-        CRTC[0-0x18]&nl;
-        Attribute[0-0x14]&nl;
-        Graphics[0-8]&nl;
-        Sequencer[0-4]&e.code;
-	</quote>
-
-    The number of registers actually saved may be modified by a prior call
-    to &s.code;vgaHWSetRegCounts()&e.code;.
-
-    </quote>
-
-    &s.code;void vgaHWSaveFonts(ScrnInfoPtr pScrn, vgaRegPtr save)&e.code;
-    <quote><p>
-      This function saves the text mode font and text data held in the
-      video memory.  If called while in a graphics mode, no save is
-      done.  The VGA memory window must be mapped with
-      &s.code;vgaHWMapMem()&e.code; before to calling this function.
-
-      On some platforms, one or more of the font/text plane saves may be
-      no-ops.  This is the case when the platform's VC driver already
-      takes care of this.
-
-    </quote>
-
-    &s.code;void vgaHWSaveColormap(ScrnInfoPtr pScrn, vgaRegPtr save)&e.code;
-    <quote><p>
-      This function saves the VGA colourmap (LUT).  Before saving it, it
-      attempts to verify that the colourmap is readable.  In rare cases
-      where it isn't readable, a default colourmap is saved instead.
-
-    </quote>
-
-    &s.code;void vgaHWRestore(ScrnInfoPtr pScrn, vgaRegPtr restore, int flags)&e.code;
-    <quote><p>
-      This function programs the VGA state.  The state programmed is
-      that contained in the &s.code;vgaRegRec&e.code; pointed to by
-      &s.code;restore&e.code;.  &s.code;flags&e.code; is the same
-      as described above for the &s.code;vgaHWSave()&e.code; function.
-
-      The &s.code;vgaHWRec&e.code; and its &s.code;IOBase&e.code; fields
-      must be initialised before this function is called.  If
-      &s.code;VGA_SR_FONTS&e.code; is set in &s.code;flags&e.code;, the
-      VGA memory window must be mapped.  If it isn't then
-      &s.code;vgaHWMapMem()&e.code; will be called to map it, and
-      &s.code;vgaHWUnmapMem()&e.code; will be called to unmap it
-      afterwards.  &s.code;vgaHWRestore()&e.code; uses the three functions
-      below in the order &s.code;vgaHWRestoreFonts()&e.code;,
-      &s.code;vgaHWRestoreMode()&e.code;,
-      &s.code;vgaHWRestoreColormap()&e.code; to carry out the different
-      restore phases.  It is undecided at this stage whether they will
-      remain part of the vgahw module's public interface or not.
-
-    </quote>
-
-    &s.code;void vgaHWRestoreMode(ScrnInfoPtr pScrn, vgaRegPtr restore)&e.code;
-    <quote><p>
-      This function restores the VGA mode registers.  They are restored
-      from the data in the &s.code;vgaRegRec&e.code; pointed to by
-      &s.code;restore&e.code;.  The registers restored are:
-
-	<quote>
-        &s.code;MiscOut&nl;
-        CRTC[0-0x18]&nl;
-        Attribute[0-0x14]&nl;
-        Graphics[0-8]&nl;
-        Sequencer[0-4]&e.code;
-	</quote>
-
-    The number of registers actually restored may be modified by a prior call
-    to &s.code;vgaHWSetRegCounts()&e.code;.
-
-    </quote>
-
-    &s.code;void vgaHWRestoreFonts(ScrnInfoPtr pScrn, vgaRegPtr restore)&e.code;
-    <quote><p>
-      This function restores the text mode font and text data to the
-      video memory.  The VGA memory window must be mapped with
-      &s.code;vgaHWMapMem()&e.code; before to calling this function.
-
-      On some platforms, one or more of the font/text plane restores
-      may be no-ops.  This is the case when the platform's VC driver
-      already takes care of this.
-
-    </quote>
-
-    &s.code;void vgaHWRestoreColormap(ScrnInfoPtr pScrn, vgaRegPtr restore)&e.code;
-    <quote><p>
-      This function restores the VGA colourmap (LUT).
-
-    </quote>
-
-    &s.code;void vgaHWInit(ScrnInfoPtr pScrn, DisplayModePtr mode)&e.code;
-    <quote><p>
-      This function fills in the &s.code;vgaHWRec&e.code;'s
-      &s.code;ModeReg&e.code; field with the values appropriate for
-      programming the given video mode.  It requires that the
-      &s.code;ScrnInfoRec&e.code;'s &s.code;depth&e.code; field is
-      initialised, which determines how the registers are programmed.
-
-    </quote>
-
-    &s.code;void vgaHWSeqReset(vgaHWPtr hwp, Bool start)&e.code;
-    <quote><p>
-      Do a VGA sequencer reset.  If start is &s.code;TRUE&e.code;, the
-      reset is started.  If start is &s.code;FALSE&e.code;, the reset
-      is ended.
-
-    </quote>
-
-    &s.code;void vgaHWProtect(ScrnInfoPtr pScrn, Bool on)&e.code;
-    <quote><p>
-      This function protects VGA registers and memory from corruption
-      during loads.  It is typically called with on set to
-      &s.code;TRUE&e.code; before programming, and with on set to
-      &s.code;FALSE&e.code; after programming.
-
-    </quote>
-
-    &s.code;Bool vgaHWSaveScreen(ScreenPtr pScreen, int mode)&e.code;
-    <quote><p>
-      This function blanks and unblanks the screen.  It is blanked when
-      &s.code;mode&e.code; is &s.code;SCREEN_SAVER_ON&e.code; or
-      &s.code;SCREEN_SAVER_CYCLE&e.code;, and unblanked when
-      &s.code;mode&e.code; is &s.code;SCREEN_SAVER_OFF&e.code; or
-      &s.code;SCREEN_SAVER_FORCER&e.code;.
-
-    </quote>
-
-    &s.code;void vgaHWBlankScreen(ScrnInfoPtr pScrn, Bool on)&e.code;
-    <quote><p>
-      This function blanks and unblanks the screen.  It is blanked when
-      &s.code;on&e.code; is &s.code;FALSE&e.code;, and unblanked when
-      &s.code;on&e.code; is &s.code;TRUE&e.code;.  This function is
-      provided for use in cases where the &s.code;ScrnInfoRec&e.code;
-      can't be derived from the &s.code;ScreenRec&e.code; (while probing
-      for clocks, for example).
-
-    </quote>
-  </quote>
-
-<sect1>VGA Colormap Functions
-<p>
-
-    The vgahw module uses the standard colormap support (see the
-    <ref id="cmap" name="Colormap Handling"> section.  This is initialised
-    with the following function:
-
-  <quote>
-      &s.code;Bool vgaHWHandleColormaps(ScreenPtr pScreen)&e.code;
-  </quote>
-
-
-<sect1>VGA Register Access Functions
-<p>
-
-    The vgahw module abstracts access to the standard VGA registers by
-    using a set of functions held in the &s.code;vgaHWRec&e.code;.  When
-    the &s.code;vgaHWRec&e.code; is created these function pointers are
-    initialised with the set of standard VGA I/O register access functions.
-    In addition to these, the vgahw module includes a basic set of MMIO
-    register access functions, and the &s.code;vgaHWRec&e.code; function
-    pointers can be initialised to these by calling the
-    &s.code;vgaHWSetMmioFuncs()&e.code; function described above.  Some
-    drivers/platforms may require a different set of functions for VGA
-    access.  The access functions are described here.
-
-
-  <quote><p>
-    &s.code;void writeCrtc(vgaHWPtr hwp, CARD8 index, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to CRTC register &s.code;index&e.code;.
-
-    </quote>
-
-    &s.code;CARD8 readCrtc(vgaHWPtr hwp, CARD8 index)&e.code;
-    <quote><p>
-      Return the value read from CRTC register &s.code;index&e.code;.
-
-    </quote>
-
-    &s.code;void writeGr(vgaHWPtr hwp, CARD8 index, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to Graphics Controller register
-      &s.code;index&e.code;.
-
-    </quote>
-
-    &s.code;CARD8 readGR(vgaHWPtr hwp, CARD8 index)&e.code;
-    <quote><p>
-      Return the value read from Graphics Controller register
-      &s.code;index&e.code;.
-
-    </quote>
-
-    &s.code;void writeSeq(vgaHWPtr hwp, CARD8 index, CARD8, value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to Sequencer register
-      &s.code;index&e.code;.
-
-    </quote>
-
-    &s.code;CARD8 readSeq(vgaHWPtr hwp, CARD8 index)&e.code;
-    <quote><p>
-      Return the value read from Sequencer register &s.code;index&e.code;.
-
-    </quote>
-
-    &s.code;void writeAttr(vgaHWPtr hwp, CARD8 index, CARD8, value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to Attribute Controller register
-      &s.code;index&e.code;.  When writing out the index value this
-      function should set bit 5 (&s.code;0x20&e.code;) according to the
-      setting of &s.code;hwp-&gt;paletteEnabled&e.code; in order to
-      preserve the palette access state.  It should be cleared when
-      &s.code;hwp-&gt;paletteEnabled&e.code; is &s.code;TRUE&e.code;
-      and set when it is &s.code;FALSE&e.code;.
-
-    </quote>
-
-    &s.code;CARD8 readAttr(vgaHWPtr hwp, CARD8 index)&e.code;
-    <quote><p>
-      Return the value read from Attribute Controller register
-      &s.code;index&e.code;.  When writing out the index value this
-      function should set bit 5 (&s.code;0x20&e.code;) according to the
-      setting of &s.code;hwp-&gt;paletteEnabled&e.code; in order to
-      preserve the palette access state.  It should be cleared when
-      &s.code;hwp-&gt;paletteEnabled&e.code; is &s.code;TRUE&e.code;
-      and set when it is &s.code;FALSE&e.code;.
-
-    </quote>
-
-    &s.code;void writeMiscOut(vgaHWPtr hwp, CARD8 value)&e.code;
-    <quote><p>
-      Write `&s.code;value&e.code;' to the Miscellaneous Output register.
-
-    </quote>
-
-    &s.code;CARD8 readMiscOut(vgwHWPtr hwp)&e.code;
-    <quote><p>
-      Return the value read from the Miscellaneous Output register.
-
-    </quote>
-
-    &s.code;void enablePalette(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      Clear the palette address source bit in the Attribute Controller
-      index register and set &s.code;hwp-&gt;paletteEnabled&e.code; to
-      &s.code;TRUE&e.code;.
-
-    </quote>
-
-    &s.code;void disablePalette(vgaHWPtr hwp)&e.code;
-    <quote><p>
-      Set the palette address source bit in the Attribute Controller
-      index register and set &s.code;hwp-&gt;paletteEnabled&e.code; to
-      &s.code;FALSE&e.code;.
-
-    </quote>
-
-    &s.code;void writeDacMask(vgaHWPtr hwp, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to the DAC Mask register.
-
-    </quote>
-
-    &s.code;CARD8 readDacMask(vgaHWptr hwp)&e.code;
-    <quote><p>
-      Return the value read from the DAC Mask register.
-
-    </quote>
-
-    &s.code;void writeDacReadAddress(vgaHWPtr hwp, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to the DAC Read Address register.
-
-    </quote>
-
-    &s.code;void writeDacWriteAddress(vgaHWPtr hwp, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to the DAC Write Address register.
-
-    </quote>
-
-    &s.code;void writeDacData(vgaHWPtr hwp, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to the DAC Data register.
-
-    </quote>
-
-    &s.code;CARD8 readDacData(vgaHWptr hwp)&e.code;
-    <quote><p>
-      Return the value read from the DAC Data register.
-
-    </quote>
-
-    &s.code;CARD8 readEnable(vgaHWptr hwp)&e.code;
-    <quote><p>
-      Return the value read from the VGA Enable register.  (Note: This
-      function is present in XFree86 4.1.0 and later.)
-
-    </quote>
-
-    &s.code;void writeEnable(vgaHWPtr hwp, CARD8 value)&e.code;
-    <quote><p>
-      Write &s.code;value&e.code; to the VGA Enable register.  (Note: This
-      function is present in XFree86 4.1.0 and later.)
-
-    </quote>
-  </quote>
-
-<sect>Some notes about writing a driver<label id="sample">
-<p>
-
-<em>NOTE: some parts of this are not up to date</em>
-
-The following is an outline for writing a basic unaccelerated driver
-for a PCI video card with a linear mapped framebuffer, and which has a
-VGA core.  It is includes some general information that is relevant to
-most drivers (even those which don't fit that basic description).
-
-The information here is based on the initial conversion of the Matrox
-Millennium driver to the ``new design''.  For a fleshing out and sample
-implementation of some of the bits outlined here, refer to that driver.
-Note that this is an example only.  The approach used here will not be
-appropriate for all drivers.
-
-Each driver must reserve a unique driver name, and a string that is used
-to prefix all of its externally visible symbols.  This is to avoid name
-space clashes when loading multiple drivers.  The examples here are for
-the ``ZZZ'' driver, which uses the ``ZZZ'' or ``zzz'' prefix for its externally
-visible symbols.
-
-
-<sect1>Include files
-<p>
-
-  All drivers normally include the following headers:
-  <quote>
-    &s.code;"xf86.h"&nl;
-    "xf86_OSproc.h"&nl;
-    "xf86_ansic.h"&nl;
-    "xf86Resources.h"&e.code;
-  </quote>
-  Wherever inb/outb (and related things) are used the following should be
-  included:
-  <quote>
-    &s.code;"compiler.h"&e.code;
-  </quote>
-  Note: in drivers, this must be included after &s.code;"xf86_ansic.h"&e.code;.
-
-  Drivers that need to access PCI vendor/device definitions need this:
-  <quote>
-    &s.code;"xf86PciInfo.h"&e.code;
-  </quote>
-
-  Drivers that need to access the PCI config space need this:
-  <quote>
-    &s.code;"xf86Pci.h"&e.code;
-  </quote>
-
-  Drivers using the mi banking wrapper need:
-
-  <quote>
-    &s.code;"mibank.h"&e.code;
-  </quote>
-
-  Drivers that initialise a SW cursor need this:
-  <quote>
-    &s.code;"mipointer.h"&e.code;
-  </quote>
-
-  All drivers implementing backing store need this:
-  <quote>
-    &s.code;"mibstore.h"&e.code;
-  </quote>
-
-  All drivers using the mi colourmap code need this:
-  <quote>
-    &s.code;"micmap.h"&e.code;
-  </quote>
-
-  If a driver uses the vgahw module, it needs this:
-  <quote>
-    &s.code;"vgaHW.h"&e.code;
-  </quote>
-
-  Drivers supporting VGA or Hercules monochrome screens need:
-  <quote>
-    &s.code;"xf1bpp.h"&e.code;
-  </quote>
-
-  Drivers supporting VGA or EGC 16-colour screens need:
-  <quote>
-    &s.code;"xf4bpp.h"&e.code;
-  </quote>
-
-  Drivers using cfb need:
-  <quote>
-    &s.code;#define PSZ 8&nl;
-    #include "cfb.h"&nl;
-    #undef PSZ&e.code;
-  </quote>
-
-  Drivers supporting bpp 16, 24 or 32 with cfb need one or more of:
-  <quote>
-    &s.code;"cfb16.h"&nl;
-    "cfb24.h"&nl;
-    "cfb32.h"&e.code;
-  </quote>
-
-  The driver's own header file:
-  <quote>
-    &s.code;"zzz.h"&e.code;
-  </quote>
-
-  Drivers must NOT include the following:
-
- <quote>
-    &s.code;"xf86Priv.h"&nl;
-    "xf86Privstr.h"&nl;
-    "xf86_libc.h"&nl;
-    "xf86_OSlib.h"&nl;
-    "Xos.h"&e.code;&nl;
-    any OS header
- </quote>
-
-
-<sect1>Data structures and initialisation
-<p>
-
-<itemize>
-  <item>The following macros should be defined:
-    <code>
-#define VERSION <version-as-an-int>
-#define ZZZ_NAME "ZZZ"         /* the name used to prefix messages */
-#define ZZZ_DRIVER_NAME "zzz"  /* the driver name as used in config file */
-#define ZZZ_MAJOR_VERSION <int>
-#define ZZZ_MINOR_VERSION <int>
-#define ZZZ_PATCHLEVEL    <int>
-    </code>
-<p>
-    NOTE: &s.code;ZZZ_DRIVER_NAME&e.code; should match the name of the
-    driver module without things like the "lib" prefix, the "_drv" suffix
-    or filename extensions.
-<p>
-
-  <item>A DriverRec must be defined, which includes the functions required
-    at the pre-probe phase.  The name of this DriverRec must be an
-    upper-case version of ZZZ_DRIVER_NAME (for the purposes of static
-    linking).
-<p>
-    <code>
-DriverRec ZZZ = {
-    VERSION,
-    ZZZ_DRIVER_NAME,
-    ZZZIdentify,
-    ZZZProbe,
-    ZZZAvailableOptions,
-    NULL,
-    0
-};
-    </code>
-
-  <item>Define list of supported chips and their matching ID:
-<p>
-    <code>
-static SymTabRec ZZZChipsets[] = {
-    { PCI_CHIP_ZZZ1234, "zzz1234a" },
-    { PCI_CHIP_ZZZ5678, "zzz5678a" },
-    { -1,               NULL }
-};
-    </code>
-<p>
-    The token field may be any integer value that the driver may use to
-    uniquely identify the supported chipsets.  For drivers that support
-    only PCI devices using the PCI device IDs might be a natural choice,
-    but this isn't mandatory.  For drivers that support both PCI and other
-    devices (like ISA), some other ID should probably used.  When other
-    IDs are used as the tokens it is recommended that the names be
-    defined as an &s.code;enum&e.code; type.
-<p>
-  <item>If the driver uses the &s.code;xf86MatchPciInstances(&e.code;)
-    helper (recommended for drivers that support PCI cards) a list that
-    maps PCI IDs to chip IDs and fixed resources must be defined:
-<p>
-    <code>
-static PciChipsets ZZZPciChipsets[] = {
-    { PCI_CHIP_ZZZ1234, PCI_CHIP_ZZZ1234, RES_SHARED_VGA },
-    { PCI_CHIP_ZZZ5678, PCI_CHIP_ZZZ5678, RES_SHARED_VGA },
-    { -1,               -1,               RES_UNDEFINED }
-}
-    </code>
-<p>
-  <item>Define the &s.code;XF86ModuleVersionInfo&e.code; struct for the
-    driver.  This is required for the dynamically loaded version:
-<p>
-    <code>
-static XF86ModuleVersionInfo zzzVersRec =
-{
-    "zzz",
-    MODULEVENDORSTRING,
-    MODINFOSTRING1,
-    MODINFOSTRING2,
-    XF86_VERSION_CURRENT,
-    ZZZ_MAJOR_VERSION, ZZZ_MINOR_VERSION, ZZZ_PATCHLEVEL,
-    ABI_CLASS_VIDEODRV,
-    ABI_VIDEODRV_VERSION,
-    MOD_CLASS_VIDEODRV,
-    {0,0,0,0}
-};
-    </code>
-<p>
-  <item>Define a data structure to hold the driver's screen-specific data.
-    This must be used instead of global variables.  This would be defined
-    in the &s.code;"zzz.h"&e.code; file, something like:
-<p>
-    <code>
-typedef struct {
-    type1  field1;
-    type2  field2;
-    int    fooHack;
-    Bool   pciRetry;
-    Bool   noAccel;
-    Bool   hwCursor;
-    CloseScreenProcPtr CloseScreen;
-    OptionInfoPtr Options;
-    ...
-} ZZZRec, *ZZZPtr;
-    </code>
-<p>
-  <item>Define the list of config file Options that the driver accepts.  For
-    consistency between drivers those in the list of ``standard'' options
-    should be used where appropriate before inventing new options.
-<p>
-    <code>
-typedef enum {
-    OPTION_FOO_HACK,
-    OPTION_PCI_RETRY,
-    OPTION_HW_CURSOR,
-    OPTION_NOACCEL
-} ZZZOpts;
-
-static const OptionInfoRec ZZZOptions[] = {
-  { OPTION_FOO_HACK,  "FooHack",   OPTV_INTEGER, {0}, FALSE },
-  { OPTION_PCI_RETRY, "PciRetry",  OPTV_BOOLEAN, {0}, FALSE },
-  { OPTION_HW_CURSOR, "HWcursor",  OPTV_BOOLEAN, {0}, FALSE },
-  { OPTION_NOACCEL,   "NoAccel",   OPTV_BOOLEAN, {0}, FALSE },
-  { -1,               NULL,        OPTV_NONE,    {0}, FALSE }
-};
-    </code>
-<p>
-</itemize>
-
-<sect1>Functions
-<p>
-
-
-<sect2>SetupProc
-<p>
-
-    For dynamically loaded modules, a &s.code;ModuleData&e.code;
-    variable is required.  It is should be the name of the driver
-    prepended to "ModuleData".  A &s.code;Setup()&e.code; function is
-    also required, which calls &s.code;xf86AddDriver()&e.code; to add
-    the driver to the main list of drivers.
-
-    <code>
-static MODULESETUPPROTO(zzzSetup);
-
-XF86ModuleData zzzModuleData = { &amp;zzzVersRec, zzzSetup, NULL };
-
-static pointer
-zzzSetup(pointer module, pointer opts, int *errmaj, int *errmin)
-{
-    static Bool setupDone = FALSE;
-
-    /* This module should be loaded only once, but check to be sure. */
-
-    if (!setupDone) {
-        /*
-         * Modules that this driver always requires may be loaded
-         * here  by calling LoadSubModule().
-         */
-
-        setupDone = TRUE;
-        xf86AddDriver(&amp;MGA, module, 0);
-
-        /*
-         * The return value must be non-NULL on success even though
-         * there is no TearDownProc.
-         */
-        return (pointer)1;
-    } else {
-        if (errmaj) *errmaj = LDR_ONCEONLY;
-        return NULL;
-    }
-}
-    </code>
-
-<sect2>GetRec, FreeRec
-<p>
-
-    A function is usually required to allocate the driver's
-    screen-specific data structure and hook it into the
-    &s.code;ScrnInfoRec&e.code;'s &s.code;driverPrivate&e.code; field.
-    The &s.code;ScrnInfoRec&e.code;'s &s.code;driverPrivate&e.code; is
-    initialised to &s.code;NULL&e.code;, so it is easy to check if the
-    initialisation has already been done.  After allocating it, initialise
-    the fields.  By using &s.code;xnfcalloc()&e.code; to do the allocation
-    it is zeroed, and if the allocation fails the server exits.
-<p>
-    NOTE:
-    When allocating structures from inside the driver which are defined
-    on the common level it is important to initialize the structure to
-    zero.
-    Only this guarantees that the server remains source compatible to
-    future changes in common level structures.
-
-    <code>
-static Bool
-ZZZGetRec(ScrnInfoPtr pScrn)
-{
-    if (pScrn->driverPrivate != NULL)
-        return TRUE;
-    pScrn->driverPrivate = xnfcalloc(sizeof(ZZZRec), 1);
-    /* Initialise as required */
-    ...
-    return TRUE;
-}
-    </code>
-
-    Define a macro in &s.code;"zzz.h"&e.code; which gets a pointer to
-    the &s.code;ZZZRec&e.code; when given &s.code;pScrn&e.code;:
-
-    <code>
-#define ZZZPTR(p) ((ZZZPtr)((p)->driverPrivate))
-    </code>
-
-    Define a function to free the above, setting it to &s.code;NULL&e.code;
-    once it has been freed:
-
-    <code>
-static void
-ZZZFreeRec(ScrnInfoPtr pScrn)
-{
-    if (pScrn->driverPrivate == NULL)
-        return;
-    xfree(pScrn->driverPrivate);
-    pScrn->driverPrivate = NULL;
-}
-    </code>
-
-<sect2>Identify
-<p>
-
-    Define the &s.code;Identify()&e.code; function.  It is run before
-    the Probe, and typically prints out an identifying message, which
-    might include the chipsets it supports.  This function is mandatory:
-
-    <code>
-static void
-ZZZIdentify(int flags)
-{
-    xf86PrintChipsets(ZZZ_NAME, "driver for ZZZ Tech chipsets",
-                      ZZZChipsets);
-}
-    </code>
-
-<sect2>Probe
-<p>
-
-    Define the &s.code;Probe()&e.code; function.  The purpose of this
-    is to find all instances of the hardware that the driver supports,
-    and for the ones not already claimed by another driver, claim the
-    slot, and allocate a &s.code;ScrnInfoRec&e.code;.  This should be
-    a minimal probe, and it should under no circumstances leave the
-    state of the hardware changed.  Because a device is found, don't
-    assume that it will be used.  Don't do any initialisations other
-    than the required &s.code;ScrnInfoRec&e.code; initialisations.
-    Don't allocate any new data structures.
-
-    This function is mandatory.
-
-    NOTE: The &s.code;xf86DrvMsg()&e.code; functions cannot be used from
-    the Probe.
-
-    <code>
-static Bool
-ZZZProbe(DriverPtr drv, int flags)
-{
-    Bool foundScreen = FALSE;
-    int numDevSections, numUsed;
-    GDevPtr *devSections;
-    int *usedChips;
-    int i;
-
-    /*
-     * Find the config file Device sections that match this
-     * driver, and return if there are none.
-     */
-    if ((numDevSections = xf86MatchDevice(ZZZ_DRIVER_NAME,
-                                          &amp;devSections)) <= 0) {
-        return FALSE;
-    }
-
-    /*
-     * Since this is a PCI card, "probing" just amounts to checking
-     * the PCI data that the server has already collected.  If there
-     * is none, return.
-     *
-     * Although the config file is allowed to override things, it
-     * is reasonable to not allow it to override the detection
-     * of no PCI video cards.
-     *
-     * The provided xf86MatchPciInstances() helper takes care of
-     * the details.
-     */
-    /* test if PCI bus present */
-    if (xf86GetPciVideoInfo()) {
-
-        numUsed = xf86MatchPciInstances(ZZZ_NAME, PCI_VENDOR_ZZZ,
-                            ZZZChipsets, ZZZPciChipsets, devSections,
-                            numDevSections, drv, &amp;usedChips);
-
-        for (i = 0; i < numUsed; i++) {
-            ScrnInfoPtr pScrn = NULL;
-            if ((pScrn = xf86ConfigPciEntity(pScrn, flags, usedChips[i],
-                                             ZZZPciChipsets, NULL, NULL,
-                                             NULL, NULL, NULL))) {
-               /* Allocate a ScrnInfoRec */
-               pScrn->driverVersion = VERSION;
-               pScrn->driverName    = ZZZ_DRIVER_NAME;
-               pScrn->name          = ZZZ_NAME;
-               pScrn->Probe         = ZZZProbe;
-               pScrn->PreInit       = ZZZPreInit;
-               pScrn->ScreenInit    = ZZZScreenInit;
-               pScrn->SwitchMode    = ZZZSwitchMode;
-               pScrn->AdjustFrame   = ZZZAdjustFrame;
-               pScrn->EnterVT       = ZZZEnterVT;
-               pScrn->LeaveVT       = ZZZLeaveVT;
-               pScrn->FreeScreen    = ZZZFreeScreen;
-               pScrn->ValidMode     = ZZZValidMode;
-               foundScreen = TRUE;
-               /* add screen to entity */
-           }
-        }
-        xfree(usedChips);
-    }
-
-#ifdef HAS_ISA_DEVS
-    /*
-     * If the driver supports ISA hardware, the following block
-     * can be included too.
-     */
-    numUsed = xf86MatchIsaInstances(ZZZ_NAME, ZZZChipsets,
-                             ZZZIsaChipsets, drv, ZZZFindIsaDevice,
-                             devSections, numDevSections, &amp;usedChips);
-    for (i = 0; i < numUsed; i++) {
-        ScrnInfoPtr pScrn = NULL;
-	if ((pScrn = xf86ConfigIsaEntity(pScrn, flags, usedChips[i],
-					 ZZZIsaChipsets, NULL, NULL, NULL,
-					 NULL, NULL))) {
-            pScrn->driverVersion = VERSION;
-            pScrn->driverName    = ZZZ_DRIVER_NAME;
-            pScrn->name          = ZZZ_NAME;
-            pScrn->Probe         = ZZZProbe;
-            pScrn->PreInit       = ZZZPreInit;
-            pScrn->ScreenInit    = ZZZScreenInit;
-            pScrn->SwitchMode    = ZZZSwitchMode;
-            pScrn->AdjustFrame   = ZZZAdjustFrame;
-            pScrn->EnterVT       = ZZZEnterVT;
-            pScrn->LeaveVT       = ZZZLeaveVT;
-            pScrn->FreeScreen    = ZZZFreeScreen;
-            pScrn->ValidMode     = ZZZValidMode;
-            foundScreen = TRUE;
-        }
-    }
-    xfree(usedChips);
-#endif /* HAS_ISA_DEVS */
-
-    xfree(devSections);
-    return foundScreen;
-    </code>
-
-<sect2>AvailableOptions
-<p>
-
-    Define the &s.code;AvailableOptions()&e.code; function. The purpose
-    of this is to return the available driver options back to the
-    -configure option, so that an xorg.conf file can be built and the
-    user can see which options are available for them to use.
-
-<sect2>PreInit
-<p>
-
-    Define the &s.code;PreInit()&e.code; function.  The purpose of
-    this is to find all the information required to determine if the
-    configuration is usable, and to initialise those parts of the
-    &s.code;ScrnInfoRec&e.code; that can be set once at the beginning
-    of the first server generation.  The information should be found in
-    the least intrusive way possible.
-
-    This function is mandatory.
-
-    NOTES:
-    <enum>
-      <item>The &s.code;PreInit()&e.code; function is only called once
-	 during the life of the X server (at the start of the first
-	 generation).
-
-      <item>Data allocated here must be of the type that persists for
-	 the life of the X server.  This means that data that hooks into
-	 the &s.code;ScrnInfoRec&e.code;'s &s.code;privates&e.code;
-	 field should be allocated here, but data that hooks into the
-	 &s.code;ScreenRec&e.code;'s &s.code;devPrivates&e.code; field
-	 should not be allocated here.  The &s.code;driverPrivate&e.code;
-	 field should also be allocated here.
-
-      <item>Although the &s.code;ScrnInfoRec&e.code; has been allocated
-	 before this function is called, the &s.code;ScreenRec&e.code;
-	 has not been allocated.  That means that things requiring it
-	 cannot be used in this function.
-
-      <item>Very little of the &s.code;ScrnInfoRec&e.code; has been
-	 initialised when this function is called.  It is important to
-	 get the order of doing things right in this function.
-
-    </enum>
-
-    <code>
-static Bool
-ZZZPreInit(ScrnInfoPtr pScrn, int flags)
-{
-    /* Fill in the monitor field */
-    pScrn->monitor = pScrn->confScreen->monitor;
-
-    /*
-     * If using the vgahw module, it will typically be loaded
-     * here by calling xf86LoadSubModule(pScrn, "vgahw");
-     */
-
-    /*
-     * Set the depth/bpp.  Use the globally preferred depth/bpp.  If the
-     * driver has special default depth/bpp requirements, the defaults should
-     * be specified here explicitly.
-     * We support both 24bpp and 32bpp framebuffer layouts.
-     * This sets pScrn->display also.
-     */
-    if (!xf86SetDepthBpp(pScrn, 0, 0, 0,
-                         Support24bppFb | Support32bppFb)) {
-        return FALSE;
-    } else {
-        if (depth/bpp isn't one we support) {
-            print error message;
-            return FALSE;
-        }
-    }
-    /* Print out the depth/bpp that was set */
-    xf86PrintDepthBpp(pScrn);
-
-    /* Set bits per RGB for 8bpp */
-    if (pScrn->depth <= 8) {
-        /* Take into account a dac_6_bit option here */
-        pScrn->rgbBits = 6 or 8;
-    }
-
-    /*
-     * xf86SetWeight() and xf86SetDefaultVisual() must be called
-     * after pScrn->display is initialised.
-     */
-
-    /* Set weight/mask/offset for depth > 8 */
-    if (pScrn->depth > 8) {
-        if (!xf86SetWeight(pScrn, defaultWeight, defaultMask)) {
-            return FALSE;
-        } else {
-            if (weight isn't one we support) {
-                print error message;
-                return FALSE;
-            }
-        }
-    }
-
-    /* Set the default visual. */
-    if (!xf86SetDefaultVisual(pScrn, -1)) {
-        return FALSE;
-    } else {
-        if (visual isn't one we support) {
-            print error message;
-            return FALSE;
-        }
-    }
-
-    /* If the driver supports gamma correction, set the gamma. */
-    if (!xf86SetGamma(pScrn, default_gamma)) {
-        return FALSE;
-    }
-
-    /* This driver uses a programmable clock */
-    pScrn->progClock = TRUE;
-
-    /* Allocate the ZZZRec driverPrivate */
-    if (!ZZZGetRec(pScrn)) {
-        return FALSE;
-    }
-
-    pZzz = ZZZPTR(pScrn);
-
-    /* Collect all of the option flags (fill in pScrn->options) */
-    xf86CollectOptions(pScrn, NULL);
-
-    /*
-     * Process the options based on the information in ZZZOptions.
-     * The results are written to pZzz->Options.  If all of the options
-     * processing is done within this function a local variable "options"
-     * can be used instead of pZzz->Options.
-     */
-    if (!(pZzz->Options = xalloc(sizeof(ZZZOptions))))
-        return FALSE;
-    (void)memcpy(pZzz->Options, ZZZOptions, sizeof(ZZZOptions));
-    xf86ProcessOptions(pScrn->scrnIndex, pScrn->options, pZzz->Options);
-
-    /*
-     * Set various fields of ScrnInfoRec and/or ZZZRec based on
-     * the options found.
-     */
-    from = X_DEFAULT;
-    pZzz->hwCursor = FALSE;
-    if (xf86IsOptionSet(pZzz->Options, OPTION_HW_CURSOR)) {
-        from = X_CONFIG;
-        pZzz->hwCursor = TRUE;
-    }
-    xf86DrvMsg(pScrn->scrnIndex, from, "Using %s cursor\n",
-               pZzz->hwCursor ? "HW" : "SW");
-    if (xf86IsOptionSet(pZzz->Options, OPTION_NOACCEL)) {
-        pZzz->noAccel = TRUE;
-        xf86DrvMsg(pScrn->scrnIndex, X_CONFIG,
-                   "Acceleration disabled\n");
-    } else {
-        pZzz->noAccel = FALSE;
-    }
-    if (xf86IsOptionSet(pZzz->Options, OPTION_PCI_RETRY)) {
-        pZzz->UsePCIRetry = TRUE;
-        xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "PCI retry enabled\n");
-    }
-    pZzz->fooHack = 0;
-    if (xf86GetOptValInteger(pZzz->Options, OPTION_FOO_HACK,
-                             &amp;pZzz->fooHack)) {
-        xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Foo Hack set to %d\n",
-                   pZzz->fooHack);
-    }
-
-    /*
-     * Find the PCI slot(s) that this screen claimed in the probe.
-     * In this case, exactly one is expected, so complain otherwise.
-     * Note in this case we're not interested in the card types so
-     * that parameter is set to NULL.
-     */
-    if ((i = xf86GetPciInfoForScreen(pScrn->scrnIndex, &amp;pciList, NULL))
-        != 1) {
-        print error message;
-        ZZZFreeRec(pScrn);
-        if (i > 0)
-            xfree(pciList);
-        return FALSE;
-    }
-    /* Note that pciList should be freed below when no longer needed */
-
-    /*
-     * Determine the chipset, allowing config file chipset and
-     * chipid values to override the probed information.  The config
-     * chipset value has precedence over its chipid value if both
-     * are present.
-     *
-     * It isn't necessary to fill in pScrn->chipset if the driver
-     * keeps track of the chipset in its ZZZRec.
-     */
-
-    ...
-
-    /*
-     * Determine video memory, fb base address, I/O addresses, etc,
-     * allowing the config file to override probed values.
-     *
-     * Set the appropriate pScrn fields (videoRam is probably the
-     * most important one that other code might require), and
-     * print out the settings.
-     */
-
-    ...
-
-    /* Initialise a clockRanges list. */
-
-    ...
-
-    /* Set any other chipset specific things in the ZZZRec */
-
-    ...
-
-    /* Select valid modes from those available */
-
-    i = xf86ValidateModes(pScrn, pScrn->monitor->Modes,
-                          pScrn->display->modes, clockRanges,
-                          NULL, minPitch, maxPitch, rounding,
-                          minHeight, maxHeight,
-                          pScrn->display->virtualX,
-                          pScrn->display->virtualY,
-                          pScrn->videoRam * 1024,
-                          LOOKUP_BEST_REFRESH);
-    if (i == -1) {
-        ZZZFreeRec(pScrn);
-        return FALSE;
-    }
-
-    /* Prune the modes marked as invalid */
-
-    xf86PruneDriverModes(pScrn);
-
-    /* If no valid modes, return */
-
-    if (i == 0 || pScrn->modes == NULL) {
-        print error message;
-        ZZZFreeRec(pScrn);
-        return FALSE;
-    }
-
-    /*
-     * Initialise the CRTC fields for the modes.  This driver expects
-     * vertical values to be halved for interlaced modes.
-     */
-    xf86SetCrtcForModes(pScrn, INTERLACE_HALVE_V);
-
-    /* Set the current mode to the first in the list. */
-    pScrn->currentMode = pScrn->modes;
-
-    /* Print the list of modes being used. */
-    xf86PrintModes(pScrn);
-
-    /* Set the DPI */
-    xf86SetDpi(pScrn, 0, 0);
-
-    /* Load bpp-specific modules */
-    switch (pScrn->bitsPerPixel) {
-    case 1:
-        mod = "xf1bpp";
-        break;
-    case 4:
-        mod = "xf4bpp";
-        break;
-    case 8:
-        mod = "cfb";
-        break;
-    case 16:
-        mod = "cfb16";
-        break;
-    case 24:
-        mod = "cfb24";
-        break;
-    case 32:
-        mod = "cfb32";
-        break;
-    }
-    if (mod && !xf86LoadSubModule(pScrn, mod))
-        ZZZFreeRec(pScrn);
-        return FALSE;
-
-    /* Load XAA if needed */
-    if (!pZzz->noAccel || pZzz->hwCursor)
-        if (!xf86LoadSubModule(pScrn, "xaa")) {
-            ZZZFreeRec(pScrn);
-            return FALSE;
-        }
-
-    /* Done */
-    return TRUE;
-}
-    </code>
-
-<sect2>MapMem, UnmapMem
-<p>
-
-    Define functions to map and unmap the video memory and any other
-    memory apertures required.  These functions are not mandatory, but
-    it is often useful to have such functions.
-
-    <code>
-static Bool
-ZZZMapMem(ScrnInfoPtr pScrn)
-{
-    /* Call xf86MapPciMem() to map each PCI memory area */
-    ...
-    return TRUE or FALSE;
-}
-
-static Bool
-ZZZUnmapMem(ScrnInfoPtr pScrn)
-{
-    /* Call xf86UnMapVidMem() to unmap each memory area */
-    ...
-    return TRUE or FALSE;
-}
-    </code>
-
-<sect2>Save, Restore
-<p>
-
-    Define functions to save and restore the original video state.  These
-    functions are not mandatory, but are often useful.
-
-    <code>
-static void
-ZZZSave(ScrnInfoPtr pScrn)
-{
-    /*
-     * Save state into per-screen data structures.
-     * If using the vgahw module, vgaHWSave will typically be
-     * called here.
-     */
-    ...
-}
-
-static void
-ZZZRestore(ScrnInfoPtr pScrn)
-{
-    /*
-     * Restore state from per-screen data structures.
-     * If using the vgahw module, vgaHWRestore will typically be
-     * called here.
-     */
-    ...
-}
-    </code>
-
-<sect2>ModeInit
-<p>
-
-    Define a function to initialise a new video mode.  This function isn't
-    mandatory, but is often useful.
-
-    <code>
-static Bool
-ZZZModeInit(ScrnInfoPtr pScrn, DisplayModePtr mode)
-{
-    /*
-     * Program a video mode.  If using the vgahw module,
-     * vgaHWInit and vgaRestore will typically be called here.
-     * Once up to the point where there can't be a failure
-     * set pScrn->vtSema to TRUE.
-     */
-    ...
-}
-    </code>
-
-<sect2>ScreenInit
-<p>
-
-    Define the &s.code;ScreenInit()&e.code; function.  This is called
-    at the start of each server generation, and should fill in as much
-    of the &s.code;ScreenRec&e.code; as possible as well as any other
-    data that is initialised once per generation.  It should initialise
-    the framebuffer layers it is using, and initialise the initial video
-    mode.
-
-    This function is mandatory.
-
-    NOTE: The &s.code;ScreenRec&e.code; (&s.code;pScreen&e.code;) is
-	  passed to this driver, but it and the
-	  &s.code;ScrnInfoRecs&e.code; are not yet hooked into each
-	  other.  This means that in this function, and functions it
-	  calls, one cannot be found from the other.
-
-    <code>
-static Bool
-ZZZScreenInit(int scrnIndex, ScreenPtr pScreen, int argc, char **argv)
-{
-    /* Get the ScrnInfoRec */
-    pScrn = xf86Screens[pScreen->myNum];
-
-    /*
-     * If using the vgahw module, its data structures and related
-     * things are typically initialised/mapped here.
-     */
-
-    /* Save the current video state */
-    ZZZSave(pScrn);
-
-    /* Initialise the first mode */
-    ZZZModeInit(pScrn, pScrn->currentMode);
-
-    /* Set the viewport if supported */
-
-    ZZZAdjustFrame(scrnIndex, pScrn->frameX0, pScrn->frameY0, 0);
-
-    /*
-     * Setup the screen's visuals, and initialise the framebuffer
-     * code.
-     */
-
-    /* Reset the visual list */
-    miClearVisualTypes();
-
-    /*
-     * Setup the visuals supported.  This driver only supports
-     * TrueColor for bpp > 8, so the default set of visuals isn't
-     * acceptable.  To deal with this, call miSetVisualTypes with
-     * the appropriate visual mask.
-     */
-
-    if (pScrn->bitsPerPixel > 8) {
-        if (!miSetVisualTypes(pScrn->depth, TrueColorMask,
-                              pScrn->rgbBits, pScrn->defaultVisual))
-            return FALSE;
-    } else {
-        if (!miSetVisualTypes(pScrn->depth,
-                              miGetDefaultVisualMask(pScrn->depth),
-                              pScrn->rgbBits, pScrn->defaultVisual))
-            return FALSE;
-    }
-
-    /*
-     * Initialise the framebuffer.
-     */
-
-    switch (pScrn->bitsPerPixel) {
-    case 1:
-        ret = xf1bppScreenInit(pScreen, FbBase,
-                               pScrn->virtualX, pScrn->virtualY,
-                               pScrn->xDpi, pScrn->yDpi,
-                               pScrn->displayWidth);
-        break;
-    case 4:
-        ret = xf4bppScreenInit(pScreen, FbBase,
-                               pScrn->virtualX, pScrn->virtualY,
-                               pScrn->xDpi, pScrn->yDpi,
-                               pScrn->displayWidth);
-        break;
-    case 8:
-        ret = cfbScreenInit(pScreen, FbBase,
-                            pScrn->virtualX, pScrn->virtualY,
-                            pScrn->xDpi, pScrn->yDpi,
-                            pScrn->displayWidth);
-        break;
-    case 16:
-        ret = cfb16ScreenInit(pScreen, FbBase,
-                              pScrn->virtualX, pScrn->virtualY,
-                              pScrn->xDpi, pScrn->yDpi,
-                              pScrn->displayWidth);
-        break;
-    case 24:
-        ret = cfb24ScreenInit(pScreen, FbBase,
-                              pScrn->virtualX, pScrn->virtualY,
-                              pScrn->xDpi, pScrn->yDpi,
-                              pScrn->displayWidth);
-        break;
-    case 32:
-        ret = cfb32ScreenInit(pScreen, FbBase,
-                              pScrn->virtualX, pScrn->virtualY,
-                              pScrn->xDpi, pScrn->yDpi,
-                              pScrn->displayWidth);
-        break;
-    default:
-        print a message about an internal error;
-        ret = FALSE;
-        break;
-    }
-
-    if (!ret)
-        return FALSE;
-
-    /* Override the default mask/offset settings */
-    if (pScrn->bitsPerPixel > 8) {
-        for (i = 0, visual = pScreen->visuals;
-             i < pScreen->numVisuals; i++, visual++) {
-            if ((visual->class | DynamicClass) == DirectColor) {
-                visual->offsetRed = pScrn->offset.red;
-                visual->offsetGreen = pScrn->offset.green;
-                visual->offsetBlue = pScrn->offset.blue;
-                visual->redMask = pScrn->mask.red;
-                visual->greenMask = pScrn->mask.green;
-                visual->blueMask = pScrn->mask.blue;
-            }
-        }
-    }
-
-    /*
-     * If banking is needed, initialise an miBankInfoRec (defined in
-     * "mibank.h"), and call miInitializeBanking().
-     */
-    if (!miInitializeBanking(pScreen, pScrn->virtualX, pScrn->virtualY,
-                                     pScrn->displayWidth, pBankInfo))
-        return FALSE;
-
-    /*
-     * If backing store is to be supported (as is usually the case),
-     * initialise it.
-     */
-    miInitializeBackingStore(pScreen);
-
-    /*
-     * Set initial black & white colourmap indices.
-     */
-    xf86SetBlackWhitePixels(pScreen);
-
-    /*
-     * Install colourmap functions.  If using the vgahw module,
-     * vgaHandleColormaps would usually be called here.
-     */
-
-    ...
-
-    /*
-     * Initialise cursor functions.  This example is for the mi
-     * software cursor.
-     */
-    miDCInitialize(pScreen, xf86GetPointerScreenFuncs());
-
-    /* Initialise the default colourmap */
-    switch (pScrn->depth) {
-    case 1:
-        if (!xf1bppCreateDefColormap(pScreen))
-            return FALSE;
-        break;
-    case 4:
-        if (!xf4bppCreateDefColormap(pScreen))
-            return FALSE;
-        break;
-    default:
-        if (!cfbCreateDefColormap(pScreen))
-            return FALSE;
-        break;
-    }
-
-    /*
-     * Wrap the CloseScreen vector and set SaveScreen.
-     */
-    ZZZPTR(pScrn)->CloseScreen = pScreen->CloseScreen;
-    pScreen->CloseScreen = ZZZCloseScreen;
-    pScreen->SaveScreen = ZZZSaveScreen;
-
-    /* Report any unused options (only for the first generation) */
-    if (serverGeneration == 1) {
-        xf86ShowUnusedOptions(pScrn->scrnIndex, pScrn->options);
-    }
-
-    /* Done */
-    return TRUE;
-}
-    </code>
-
-
-<sect2>SwitchMode
-<p>
-
-    Define the &s.code;SwitchMode()&e.code; function if mode switching
-    is supported by the driver.
-
-    <code>
-static Bool
-ZZZSwitchMode(int scrnIndex, DisplayModePtr mode, int flags)
-{
-    return ZZZModeInit(xf86Screens[scrnIndex], mode);
-}
-    </code>
-
-
-<sect2>AdjustFrame
-<p>
-
-    Define the &s.code;AdjustFrame()&e.code; function if the driver
-    supports this.
-
-    <code>
-static void
-ZZZAdjustFrame(int scrnIndex, int x, int y, int flags)
-{
-    /* Adjust the viewport */
-}
-    </code>
-
-
-<sect2>EnterVT, LeaveVT
-<p>
-
-    Define the &s.code;EnterVT()&e.code; and &s.code;LeaveVT()&e.code;
-    functions.
-
-    These functions are mandatory.
-
-    <code>
-static Bool
-ZZZEnterVT(int scrnIndex, int flags)
-{
-    ScrnInfoPtr pScrn = xf86Screens[scrnIndex];
-    return ZZZModeInit(pScrn, pScrn->currentMode);
-}
-
-static void
-ZZZLeaveVT(int scrnIndex, int flags)
-{
-    ScrnInfoPtr pScrn = xf86Screens[scrnIndex];
-    ZZZRestore(pScrn);
-}
-    </code>
-
-<sect2>CloseScreen
-<p>
-
-    Define the &s.code;CloseScreen()&e.code; function:
-
-    This function is mandatory.  Note that it unwraps the previously
-    wrapped &s.code;pScreen-&gt;CloseScreen&e.code;, and finishes by
-    calling it.
-
-    <code>
-static Bool
-ZZZCloseScreen(int scrnIndex, ScreenPtr pScreen)
-{
-    ScrnInfoPtr pScrn = xf86Screens[scrnIndex];
-    if (pScrn->vtSema) {
-        ZZZRestore(pScrn);
-        ZZZUnmapMem(pScrn);
-    }
-    pScrn->vtSema = FALSE;
-    pScreen->CloseScreen = ZZZPTR(pScrn)->CloseScreen;
-    return (*pScreen->CloseScreen)(scrnIndex, pScreen);
-}
-    </code>
-
-<sect2>SaveScreen
-<p>
-
-    Define the &s.code;SaveScreen()&e.code; function (the screen
-    blanking function).  When using the vgahw module, this will typically
-    be:
-
-    <code>
-static Bool
-ZZZSaveScreen(ScreenPtr pScreen, int mode)
-{
-    return vgaHWSaveScreen(pScreen, mode);
-}
-    </code>
-
-    This function is mandatory.  Before modifying any hardware register
-    directly this function needs to make sure that the Xserver is active
-    by checking if &s.code;pScrn&e.code; is non-NULL and for
-    &s.code;pScrn->vtSema == TRUE&e.code;.
-
-<sect2>FreeScreen
-<p>
-
-    Define the &s.code;FreeScreen()&e.code; function.  This function
-    is optional.  It should be defined if the &s.code;ScrnInfoRec&e.code;
-    &s.code;driverPrivate&e.code; field is used so that it can be freed
-    when a screen is deleted by the common layer for reasons possibly
-    beyond the driver's control.  This function is not used in during
-    normal (error free) operation.  The per-generation data is freed by
-    the &s.code;CloseScreen()&e.code; function.
-
-    <code>
-static void
-ZZZFreeScreen(int scrnIndex, int flags)
-{
-    /*
-     * If the vgahw module is used vgaHWFreeHWRec() would be called
-     * here.
-     */
-    ZZZFreeRec(xf86Screens[scrnIndex]);
-}
-    </code>
-
-
-</article>
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