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<title>How to Create Khronos API Extensions</title>
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<h1>How to Create Khronos API Extensions</h1>

<p> This document outlines the steps to create, define, and use
    an extension for some of the APIs supported by Khronos. It
    is currently focused on OpenGL, OpenGL ES, GLX, and EGL.
    Some discussion of OpenVG and WGL is also included.

<ul>
    <li><a href="#spec">Specifying</a> an extension prior to coding it.
    <li><a href="#implementation">Implementing</a> an extension (this
	discusses only aspects of the implemention visible to users -
	primarily determining if the extension is available and
	defining its interface in header files.
    <li><a href="#using">Using</a> an extension in an application (this
	discusses the mechanics of using an extension if and only if
	it's supported by an implementation).
</ul>

<p><hr>

<a name="spec"></a>
<h2>Specification</h2>

<p> When initially creating an extension, take the following steps:

<ul>
    <li><a href="#spec_existing">Determine if an existing extension</a>
	can be used, instead of writing a new one. This may involve
	reuse of an existing specification, or
	<a href="promoting.html">promotion</a> to multivendor or
	Khronos-approved status. In either case, coordinate this use
	with the vendor(s) defining and shipping the existing extension.
    <li>If no suitable extension already exists, determine if you can
	<a href="#spec_category">agree on a multivendor or Khronos
	extension</a>, or if the extension must be specific to a single
	vendor.
    <li>Develop and <a href="#spec_writing">write an extension
	specification</a>, following the <a href="#spec_naming">naming
	conventions</a>.
    <li>When you're ready to release the extension, freeze the
	specification and <a href="#spec_registry">add it to the
	registry</a> maintained by Khronos. At this time (but not
	before), you can obtain permanent token (enumerant) assignments.
    <li>When shipping an extension, make sure that its interfaces are
	defined in header files accessible to ISVs. If the extension is
	Khronos-approved, use the Khronos-provided headers.
</ul>

<a name="spec_existing"></a>
<h3>Is there already an extension that does what I want?</h3>

<p> Specifications for extensions that have already been developed can
be obtained from the <a href="http://opengl.org/registry/"> Extension
Registry</a> maintained by Khronos. Since we are just getting started
with most of the Khronos APIs, the registry currently contains only
OpenGL, GLX, and WGL extension specifications.

<p> It's possible that additional extensions may have been submitted to
the registry but not yet updated on the website, or that another
licensee may be working on a similar extension but not yet have released
the specification. So it's worth asking on the appropriate Working
Group mailing list if anyone has defined related functionality already.

<a name="spec_category"></a>
<h3>Should the extension be Khronos-approved, multivendor, or specific
    to a single vendor?</h3>

<p> OpenGL's history has made clear that ISVs do <b>not</b> want to deal
    with vendor-specific extensions if they can possibly avoid it. So if
    the functionality being exposed is going to be available on multiple
    platforms - as most will - it's a good idea to agree on a single
    extension with other vendors providing that functionality. This
    makes it easier for ISVs to justify using extensions.

<p> If the functionality is well-understood, it may be appropriate to
    define a <b>Khronos-approved extension</b>. This is the most
    &quot;blessed&quot; category of extension; it goes through the
    entire standards process, and is approved by the group, but remains
    optional functionality. Many core features have been promoted
    directly from existing Khronos-approved extensions.

<p> If Khronos as a whole isn't ready to deal with the extension, but
    other vendors are, then it should be defined as a <b>multivendor
    extension</b>. The interested parties can develop the specification
    entirely among themselves, outside the standards process; or they
    may be able to use Khronos Working Groups as a forum to develop the
    specification.

<p> In some cases, vendors may share a common core of functionality,
    with vendor-specific additional features. Here, it may make sense to
    agree on a multivendor extension to access the core, with additional
    vendor-specific extensions layered on the core exposing unique
    features.

<p> Finally, some extensions will probably have to remain proprietary.

<a name="spec_writing"></a>
<h3>How do I write a specification?</h3>

<p> Start with the <a href="template.txt">template</a> for writing
    extension specifications. There are different templates for
    different APIs, but general comments apply:

<ul>
<li> It's important to think about all the different areas of the core
    language specification(s) that are affected. How are queries for
    state handled? What attribute group does new state belong in? How
    are existing calls modified or expanded in scope? How are existing
    objects affected by use of the extension? The template helps with
    this by at least reminding you to consider each part of the core
    language specification.
<li> Extension specifications must be written against a specific version
    of the core API specification. If possible, it's highly preferable
    to write against the most recent public version. &quot;Written
    against&quot; means that new language must be written as
    well-defined modifications to the Specification being referenced. It
    should be possible for someone not involved with the development of
    an extension to sit down with a copy of the Specification and the
    extension and produce a merged document identical to that you
    intended.
<li> Extension specifications may also be specified as Docbook XML
    documents, although we're still using plain text for the most part.
    Docbook is a very powerful structural representation of documents,
    but we're still feeling our way into using it. Known <a
    href="toolchain.html">Docbook tools and editors</a> are described
    elsewhere.
</ul>

<p> One complete, shipping example to refer to is the
    <a href="../specs/EXT/fog_coord.txt">Fog Coordinate</a> OpenGL extension
    specification.
<!-- (<a href="fog_coord.xml">Docbook source</a>). -->

<a name="spec_naming"></a>
<h3>Naming Conventions</h3>

<p> API entry points and enumerants in an extension must be named
according to the <a href="syntaxrules.txt">syntax rules</a> specific to
that API. In particular, follow the sections &quot;Extension name
rules&quot; and &quot;Shared extensions&quot;.

<p> All extensions must be named and the name included in the extension
specification. The extension name is of the form
<tt>&quot;api_category_name&quot;</tt> where

<ul>
<li> <tt>&quot;api&quot;</tt> identifies the API
    (<tt>&quot;GL&quot;</tt> for OpenGL and OpenGL ES;
    <tt>&quot;EGL&quot;</tt>, <tt>&quot;GLX&quot;</tt>, and
    <tt>&quot;WGL&quot;</tt> for the corresponding window-system
    abstraction APIs EGL, GLX, and WGL; <tt>&quot;GLU&quot;</tt> for the
    OpenGL Utility Library; and <tt>&quot;OVG&quot;</tt> for OpenVG.

    (<b>Note</b>: OpenMAX, OpenSL, OpenML TBD).

<li> <tt>&quot;category&quot;</tt> identifies the extension category.
    For a vendor-specific extension, the category is a 2-3 letter string
    identifying the vendor: <tt>&quot;NV&quot;</tt> for NVIDIA,
    <tt>&quot;ATI&quot;</tt> for ATI, etc. For a multivendor extensions,
    the category is <tt>&quot;EXT&quot;</tt>. For Khronos-approved
    extensions, one of several API-specific categories is used
    (<tt>&quot;ARB&quot;</tt> for OpenGL extensions,
    <tt>&quot;OES&quot;</tt> for OpenGL ES extensions,
    <tt>&quot;OML&quot;</tt> for OpenML extensions, and so on).

<li> <tt>&quot;name&quot;</tt> is one or more words separated by
    underscores, providing a short label for the extension.
    Conventionally the name is entirely lower-case.
</ul>

<p> For example, the extension name
    <tt>&quot;GL_EXT_framebuffer_object&quot;</tt> is used for a
    multivendor OpenGL extension adding support for framebuffer objects.

<p> Choose names that are

<ul>
<li> Short.
<li> Meaningful.
<li> Not prefixes of any existing extension name (disregarding the
    category). For example, <tt>&quot;GL_ARB_fog&quot;</tt> is a prefix
    of <tt>&quot;GL_EXT_fog_coord&quot;</tt>, so should not be chosen.
<li> Not prefixed by any existing extension name (again, disregarding
    the category).
</ul>

<p> The goal is for names to be clear, but not at the cost of confusion
    or ambiguity.


<h4> Advertising Extension Names to Applications </h4>

<p> Each Khronos API provides a way of describing the supported
    extensions at compile- and run-time. This is done by a combination
    of preprocessor tokens in header files, and queryable extension
    strings.

<p> <b>OpenGL and OpenGL ES</b> #define a preprocessor token
    corresponding to the extension name in <tt>&lt;GL/gl.h&gt;</tt> (or
    an include file that <tt>gl.h</tt> includes, such as the
    <tt>glext.h</tt> header provided in the registry). When this token
    is defined, it indicates that the function prototypes and enumerant
    definitions required to use the extension are available at compile
    time.

<p> If an OpenGL or OpenGL ES extension is supported at runtime, the
    extension name must also be included in the string returned by
    <tt>glGetString(GL_EXTENSIONS)</tt>.

<p> <b>GLX</b> #defines a preprocessor token corresponding to the
    extension name in <tt>&lt;GL/glx.h&gt;</tt> (or an include file that
    <tt>glx.h</tt> includes, such as the <tt>glxext.h</tt> header
    provided in the registry). When this token is defined, it indicates
    that the function prototypes and enumerant definitions required to
    use the extension are available at compile time.

<p> If a GLX extension is supported at runtime, the extension name must
    also be included in the strings returned by
    <b>glXQueryExtensionsString</b>, <b>glXGetClientString</b>, and/or
    <b>glXQueryServerString</b> (see below for a description of the
    different routines).

<p> <b>WGL</b> #defines a preprocessor token corresponding to the
    extension name in the <tt>wglext.h</tt> header provided in the
    registry (the wgl.h supplied with Microsoft Windows does not
    #include <tt>wglext.h</tt>, or define any extensions itself). When
    this token is defined, it indicates that the function prototypes and
    enumerant definitions required to use the extension are available at
    compile time.

<p> If a WGL extension is supported at runtime, the extension name must
    also be included in the string returned by
    <b>wglGetExtensionsStringEXT</b>.

<p> <b>OpenVG</b> extension conventions are <i>To Be Determined</i>.

<p> Note that extensions can have both OpenGL components and windowing
    system components. For example, the ARB multisampling extension
    modifies both GLX and OpenGL. In this case there will be two tokens
    associated with the extension (e.g., <tt>GL_ARB_multisample</tt> and
    <tt>GLX_ARB_multisample</tt>) and the extension will be advertised
    by both OpenGL and GLX.

<a name="spec_registry"></a>
<h3>Extension Registry</h3>

<p> Khronos keeps a registry of extension specifications, enumerated
    type values, GLX codes (vendor private opcodes, vendor private with
    reply opcodes, new visual attribute type values, GLX error codes and
    GLX event codes), OpenGL rendering codes for GLX, and OpenGL
    rendering codes for GLS and extension numbers. Vendors shipping
    extensions using any of these values must obtain them from Khronos.

<p> If an extension defines new OpenGL enumerant names, values for those
    names must be requested in one or more blocks of 16 values. If an
    extension defines new OpenGL rendering commands then you need to
    register GLS rendering codes for it. If you want the extensions to
    work with the X windowing system (i.e., with GLX), then you must
    request GLX opcodes and define GLX protocol for it.

<p> There are detailed <a href="enums.html">enumerant allocation
    policies</a> for OpenGL, GLX, and WGL enumerants.

<p> All new extensions must have a number associated with them for
    documentation purposes. If an extension depends on another
    extension, the other extension must have a lower number. (Note that
    when an extension is deprecated, the number associated with it is
    not reassigned.) This number will also be assigned by Khronos when
    you register the extension.

<p> Include all new enumerated values, GLX codes, and the extension
    number in the specification.

<p> Once you have completed the extension, please make it available to
    other Khronos members and application developers, by submitting the
    extension specification to the Khronos Registrar for inclusion in
    the public registry.

<p><hr>

<a name="implementation"></a>
<h2>Implementing and Advertising Extensions</h2>

<h4><u>Errors</u></h4>

<p> Whenever possible, extensions should use existing errors instead of
    defining new error returns. For GLX, if a new protocol error is
    introduced, then an error number must be obtained from and
    registered with Khronos.

<p> Vendors may ship a single OpenGL library, containing extensions, for
    a variety of platforms. It is possible that some of the extension
    routines defined in the library may not be supported on some of the
    platforms. If this is the case and an application calls a routine
    that is not supported by the current OpenGL renderer then a
    <tt>GL_INVALID_OPERATION</tt> error should be returned.

<h4><u>OpenGL Extension Availability</u></h4>

<p> OpenGL extensions must be advertised in the extension string
    returned by <b>glGetString</b>. Note that in a client-server
    environment, this call returns the set of extensions that can be
    supported on the connection. GLX client libraries must send a
    <b>glXClientInfo</b> request to the server at start up time (if the
    client libarary is 1.1 or later) indicating the version of the
    client library and the OpenGL extensions that it supports. Then,
    when <b>glGetString</b> is called, the client issues a GetString
    request. The server intersects the set of extensions that the client
    supports with the set of extensions that it supports (if a
    <b>glXClientInfo</b> request was never received then the server
    assumes that the client supports no OpenGL extensions) and returns
    the result to the client. The client library then appends any
    client-side only extensions to the list and returns the result.

<p> Extension names for all known OpenGL extensions are #defined in the
    <tt>glext.h</tt> header included in the registry.

<h4><u>EGL Extension Availability</u></h4>

<p> EGL extensions must be advertised in the extension string returned
    by <tt>eglQueryString(EGL_EXTENSIONS)</tt>. Extension names for all
    known EGL extensions are #defined in the <tt>eglext.h</tt> header
    included in the registry.

<h4><u>GLX Extension Availability</u></h4>

<p> GLX client-side extensions must be advertised in the extension
    string returned by <b>glXGetClientString</b>; server-side extensions
    must be advertised in the extension string returned by
    <b>glXQueryServerString</b>.

<p> <b>glXQueryExtensionsString</b> returns the list of extensions that
    can be supported on the connection. The client then issues a
    <b>glXQueryServerString</b> request, intersects the returned string
    with the set of extensions it can support and then appends any
    client-side only extensions to the list.

<p> Extension names for all known GLX extensions are #defined in the
    <tt>glxext.h</tt> header included in the registry.

<h4><u>WGL Extension Availability</u></h4>

<p> WGL initially had no mechanism for returning its own extensions
    string. For this reason, WGL extension names were initially
    advertised in the GL extensions string returned by
    <b>glGetString</b>. With the creation of a more formal WGL extension
    mechanism, all implementations offering WGL extensions should export
    the <tt>WGL_EXT_extensions_string</tt> extension, and should
    advertise WGL extensions in the extensions string returned by the
    <b>wglGetExtensionsStringEXT</b> interface defined by
    <tt>WGL_EXT_extensions_string</tt>, as well as via
    <b>glGetString</b>, for compatibility with older programs.</p>

<p> Extension names for all known WGL extensions are #defined in the
    <tt>wglext.h</tt> header included in the registry.

<p><hr>

<a name="using"></a>
<h2>Use of Extensions</h2>

<h4><u>Using OpenGL Extensions</u></h4>

<p> Programmers that wish to use a particular OpenGL extension should
    check both compile-time defines (to ensure that the extension is
    supported by the library they are compiling against) and the
    extension string returned by <b>glGetString</b> (to ensure that the
    renderer supports the extension). For Windows, extensions usually
    are not defined at link time, and function pointers to extension
    APIs should be obtained by calling <b>wglGetProcAddress</b>.

<p> For example, the following code could be used to check whether the
    renderer supports an OpenGL extension called
    <tt>GL_EXT_new_extension</tt>. This code would need to be executed
    after the context had been made current:

<blockquote><pre><tt>
    static GLboolean CheckExtension(char *extName, const char *extString)
    {
	/*
	 ** Search for extName in the extensions string.  Use of strstr()
	 ** is not sufficient because extension names can be prefixes of
	 ** other extension names.  Could use strtok() but the constant
	 ** string returned by glGetString can be in read-only memory.
	 */
	char *p = (char *)extString;
	char *end;
	int extNameLen;

	extNameLen = strlen(extName);
	end = p + strlen(p);

	while (p < end) {
	    int n = strcspn(p, " ");
	    if ((extNameLen == n) && (strncmp(extName, p, n) == 0)) {
		return GL_TRUE;
	    }
	    p += (n + 1);
	}
	return GL_FALSE;
    }

    const GLubyte *ext_string;
    int new_ext_supported = GL_FALSE;

    if (CheckExtension("GL_EXT_new_extension", glGetString(GL_EXTENSIONS)))
	new_ext_supported = GL_TRUE;
</tt></pre></blockquote>

<p> If the renderer supports the extension, then it is safe to use it at
    runtime. (Note that in a client-server environment,
    <b>glGetString</b> will only return the set of extensions that can
    be supported by the client and server.) However, compile time checks
    must be made to ensure that the library that you are linked against
    supports the extension. For example:

<blockquote><pre><tt>
    #ifdef GL_EXT_new_extension
	if (new_ext_supported)
	    glNewExtensionEXT()
    #endif
</tt></pre></blockquote>

<p> For a Windows OpenGL implementation, extensions are usually
    dynamically loaded from the device driver, rather than statically
    linked. Function pointers to extension APIs are obtained from
    <b>wglGetProcAddress</b> and use to invoke the extension. For
    example:

<blockquote><pre><tt>
    typedef void (WINAPI *PFNGLNEWEXTENSIONEXTPROC)();
    PFNGLNEWEXTENSIONEXTPROC *glNewExtensionEXT = NULL;

    /* Do this once, after context creation */
    #ifdef GL_EXT_new_extension
	if (new_ext_supported)
	    glNewExtensionEXT = (PFNGLNEWEXTENSIONEXTPROC)
		wglGetProcAddress("glNewExtensionEXT");
    #endif

    /* Do this when calling the extension */
    #ifdef GL_EXT_new_extension
	if (new_ext_supported)
	    (*glNewExtensionEXT)();
    #endif
</tt></pre></blockquote>

<h4><u>Using EGL Extensions</u></h4>

<p> Before using an EGL extension, check for the extension name in both
    the compile-time #defines and the extension string returned by
    <tt>eglGetString(EGL_EXTENSIONS)</tt>. For example, this code could
    be used to check whether an extension called
    <tt>EGL_OES_new_extension</tt> can be used.

<blockquote><pre><tt>
	EGLDisplay dpy; // Initialized elsewhere
	int new_ext_supported = FALSE;

	if (CheckExtension("EGL_OES_new_extension",
			       eglGetString(display, EGL_EXTENSIONS));
		new_ext_supported = TRUE;
    #endif
</tt></pre></blockquote>

<p> If the extension is supported, then it is safe to use it at runtime.
    However, compile time checks must be made to ensure that you can
    call the extension. For example:

<blockquote><pre><tt>
    #ifdef EGL_OES_new_extension
	if (new_ext_supported)
	    eglNewExtensionEXT(...);
    #endif
</tt></pre></blockquote>

<h4><u>Using GLX Extensions</u></h4>

<p> Before using a GLX extension, programmers should check the compile
    time defines and the extension string returned by
    <b>glXQueryExtensionsString</b>.

<p> The following code could be used to check whether an extension
    called <tt>GLX_EXT_new_extension</tt> can be used on the connection.
    This code would be executed after the connection had been opened and
    the existence of the GLX extension had been established.

<blockquote><pre><tt>
	Display *dpy;
	int new_ext_supported = GL_FALSE;
	int major, minor, screen;

	if (!glXQueryVersion(dpy, &major, &minor))
	    exit(1);
	screen = DefaultScreen(dpy);

    #ifdef GLX_VERSION_1_1
	if (minor > 0 || major > 1)
	    if (CheckExtension("GLX_EXT_new_extension",
			       glXQueryExtensionsString(dpy, screen)))
		new_ext_supported = GL_TRUE;
    #endif
</tt></pre></blockquote>

<p> If the extension is supported on the connection, then it is safe to
    use it at runtime. However, compile time checks must be made to
    ensure that the library that you are linked against supports the
    extension. For example:

<blockquote><pre><tt>
    #ifdef GLX_EXT_new_extension
	if (new_ext_supported)
	    glXNewExtensionEXT(...);
    #endif
</tt></pre></blockquote>

<h4><u>Using WGL Extensions</u></h4>

<p> Before using a WGL extension, check for its presence in the WGL
    extensions string. Note that the WGL extension string query is
    itself an extension; if not supported, WGL extensions are also
    advertised in the base GL extensions string.

    <p> <i>Code snippet should go here</i>

<p> <hr>

<p> Last modified August 13, 2006 by Jon Leech

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