docs/shading.html - platform/external/mesa3d - Git at Google

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 <head>
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   <title>Shading Language Support</title>
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 </head>
 <body>

 <h1>Shading Language Support</h1>

 <p>
 This page describes the features and status of Mesa's support for the
 <a href="http://opengl.org/documentation/glsl/" target="_parent">
 OpenGL Shading Language</a>.
 </p>

 <p>
 Contents
 </p>
 <ul>
 <li><a href="#envvars">Environment variables</a>
 <li><a href="#glsl120">GLSL 1.20 support</a>
 <li><a href="#unsup">Unsupported Features</a>
 <li><a href="#notes">Implementation Notes</a>
 <li><a href="#hints">Programming Hints</a>
 <li><a href="#standalone">Stand-alone GLSL Compiler</a>
 <li><a href="#implementation">Compiler Implementation</a>
 <li><a href="#validation">Compiler Validation</a>
 </ul>


 <h2 id="envvars">Environment Variables</h2>

 <p>
 The <b>MESA_GLSL</b> environment variable can be set to a comma-separated
 list of keywords to control some aspects of the GLSL compiler and shader
 execution.  These are generally used for debugging.
 </p>
 <ul>
 <li><b>dump</b> - print GLSL shader code to stdout at link time
 <li><b>log</b> - log all GLSL shaders to files.
     The filenames will be "shader_X.vert" or "shader_X.frag" where X
     the shader ID.
 <li><b>nopt</b> - disable compiler optimizations
 <li><b>opt</b> - force compiler optimizations
 <li><b>uniform</b> - print message to stdout when glUniform is called
 <li><b>nopvert</b> - force vertex shaders to be a simple shader that just transforms
     the vertex position with ftransform() and passes through the color and
     texcoord[0] attributes.
 <li><b>nopfrag</b> - force fragment shader to be a simple shader that passes
     through the color attribute.
 <li><b>useprog</b> - log glUseProgram calls to stderr
 </ul>
 <p>
 Example:  export MESA_GLSL=dump,nopt
 </p>


 <h2 id="glsl120">GLSL Version</h2>

 <p>
 The GLSL compiler currently supports version 1.20 of the shading language.
 </p>

 <p>
 Several GLSL extensions are also supported:
 </p>
 <ul>
 <li>GL_ARB_draw_buffers
 <li>GL_ARB_texture_rectangle
 <li>GL_ARB_fragment_coord_conventions
 <li>GL_EXT_texture_array
 </ul>


 <h2 id="unsup">Unsupported Features</h2>

 <p>XXX update this section</p>

 <p>
 The following features of the shading language are not yet fully supported
 in Mesa:
 </p>

 <ul>
 <li>Linking of multiple shaders does not always work.  Currently, linking
     is implemented through shader concatenation and re-compiling.  This
     doesn't always work because of some #pragma and preprocessor issues.
 <li>gl_ClipVertex
 <li>The gl_Color and gl_SecondaryColor varying vars are interpolated
     without perspective correction
 </ul>

 <p>
 All other major features of the shading language should function.
 </p>


 <h2 id="notes">Implementation Notes</h2>

 <ul>
 <li>Shading language programs are compiled into low-level programs
     very similar to those of GL_ARB_vertex/fragment_program.
 <li>All vector types (vec2, vec3, vec4, bvec2, etc) currently occupy full
     float[4] registers.
 <li>Float constants and variables are packed so that up to four floats
     can occupy one program parameter/register.
 <li>All function calls are inlined.
 <li>Shaders which use too many registers will not compile.
 <li>The quality of generated code is pretty good, register usage is fair.
 <li>Shader error detection and reporting of errors (InfoLog) is not
     very good yet.
 <li>The ftransform() function doesn't necessarily match the results of
     fixed-function transformation.
 </ul>

 <p>
 These issues will be addressed/resolved in the future.
 </p>


 <h2 id="hints">Programming Hints</h2>

 <ul>
 <li>Use the built-in library functions whenever possible.
     For example, instead of writing this:
 <pre>
         float x = 1.0 / sqrt(y);
 </pre>
     Write this:
 <pre>
         float x = inversesqrt(y);
 </pre>
 </li>
 </ul>


 <h2 id="standalone">Stand-alone GLSL Compiler</h2>

 <p>
 The stand-alone GLSL compiler program can be used to compile GLSL shaders
 into low-level GPU code.
 </p>

 <p>
 This tool is useful for:
 </p>
 <ul>
 <li>Inspecting GPU code to gain insight into compilation
 <li>Generating initial GPU code for subsequent hand-tuning
 <li>Debugging the GLSL compiler itself
 </ul>

 <p>
 After building Mesa, the compiler can be found at src/glsl/glsl_compiler
 </p>

 <p>
 Here's an example of using the compiler to compile a vertex shader and
 emit GL_ARB_vertex_program-style instructions:
 </p>
 <pre>
     src/glsl/glsl_compiler --dump-ast myshader.vert
 </pre>

 Options include
 <ul>
 <li><b>--dump-ast</b> - dump GPU code
 <li><b>--dump-hir</b> - dump high-level IR code
 <li><b>--dump-lir</b> - dump low-level IR code
 <li><b>--link</b> - ???
 </ul>


 <h2 id="implementation">Compiler Implementation</h2>

 <p>
 The source code for Mesa's shading language compiler is in the
 <code>src/glsl/</code> directory.
 </p>

 <p>
 XXX provide some info about the compiler....
 </p>

 <p>
 The final vertex and fragment programs may be interpreted in software
 (see prog_execute.c) or translated into a specific hardware architecture
 (see drivers/dri/i915/i915_fragprog.c for example).
 </p>

 <h3>Code Generation Options</h3>

 <p>
 Internally, there are several options that control the compiler's code
 generation and instruction selection.
 These options are seen in the gl_shader_state struct and may be set
 by the device driver to indicate its preferences:

 <pre>
 struct gl_shader_state
 {
    ...
    /** Driver-selectable options: */
    GLboolean EmitHighLevelInstructions;
    GLboolean EmitCondCodes;
    GLboolean EmitComments;
 };
 </pre>

 <dl>
 <dt>EmitHighLevelInstructions</dt>
 <dd>
 This option controls instruction selection for loops and conditionals.
 If the option is set high-level IF/ELSE/ENDIF, LOOP/ENDLOOP, CONT/BRK
 instructions will be emitted.
 Otherwise, those constructs will be implemented with BRA instructions.
 </dd>

 <dt>EmitCondCodes</dt>
 <dd>
 If set, condition codes (ala GL_NV_fragment_program) will be used for
 branching and looping.
 Otherwise, ordinary registers will be used (the IF instruction will
 examine the first operand's X component and do the if-part if non-zero).
 This option is only relevant if EmitHighLevelInstructions is set.
 </dd>

 <dt>EmitComments</dt>
 <dd>
 If set, instructions will be annoted with comments to help with debugging.
 Extra NOP instructions will also be inserted.
 </dd>
 </dl>


 <h2 id="validation">Compiler Validation</h2>

 <p>
 Developers working on the GLSL compiler should test frequently to avoid
 regressions.
 </p>

 <p>
 The <a href="http://piglit.freedesktop.org/" target="_parent">Piglit</a> project
 has many GLSL tests and the
 <a href="http://glean.sf.net" target="_parent">Glean</a> glsl1 test
 tests GLSL features.
 </p>

 <p>
 The Mesa demos repository also has some good GLSL tests.
 </p>

 </body>
 </html>
	<!DOCTYPE HTML PUBLIC "-//W3C//DTD HTML 4.01 Transitional//EN" "http://www.w3.org/TR/html4/loose.dtd">
	<html lang="en">
	<head>
	<meta http-equiv="content-type" content="text/html; charset=utf-8">
	<title>Shading Language Support</title>
	<link rel="stylesheet" type="text/css" href="mesa.css">
	</head>
	<body>

	<h1>Shading Language Support</h1>

	<p>
	This page describes the features and status of Mesa's support for the
	<a href="http://opengl.org/documentation/glsl/" target="_parent">
	OpenGL Shading Language</a>.
	</p>

	<p>
	Contents
	</p>
	<ul>
	<li><a href="#envvars">Environment variables</a>
	<li><a href="#glsl120">GLSL 1.20 support</a>
	<li><a href="#unsup">Unsupported Features</a>
	<li><a href="#notes">Implementation Notes</a>
	<li><a href="#hints">Programming Hints</a>
	<li><a href="#standalone">Stand-alone GLSL Compiler</a>
	<li><a href="#implementation">Compiler Implementation</a>
	<li><a href="#validation">Compiler Validation</a>
	</ul>


	<h2 id="envvars">Environment Variables</h2>

	<p>
	The <b>MESA_GLSL</b> environment variable can be set to a comma-separated
	list of keywords to control some aspects of the GLSL compiler and shader
	execution. These are generally used for debugging.
	</p>
	<ul>
	<li><b>dump</b> - print GLSL shader code to stdout at link time
	<li><b>log</b> - log all GLSL shaders to files.
	The filenames will be "shader_X.vert" or "shader_X.frag" where X
	the shader ID.
	<li><b>nopt</b> - disable compiler optimizations
	<li><b>opt</b> - force compiler optimizations
	<li><b>uniform</b> - print message to stdout when glUniform is called
	<li><b>nopvert</b> - force vertex shaders to be a simple shader that just transforms
	the vertex position with ftransform() and passes through the color and
	texcoord[0] attributes.
	<li><b>nopfrag</b> - force fragment shader to be a simple shader that passes
	through the color attribute.
	<li><b>useprog</b> - log glUseProgram calls to stderr
	</ul>
	<p>
	Example: export MESA_GLSL=dump,nopt
	</p>


	<h2 id="glsl120">GLSL Version</h2>

	<p>
	The GLSL compiler currently supports version 1.20 of the shading language.
	</p>

	<p>
	Several GLSL extensions are also supported:
	</p>
	<ul>
	<li>GL_ARB_draw_buffers
	<li>GL_ARB_texture_rectangle
	<li>GL_ARB_fragment_coord_conventions
	<li>GL_EXT_texture_array
	</ul>


	<h2 id="unsup">Unsupported Features</h2>

	<p>XXX update this section</p>

	<p>
	The following features of the shading language are not yet fully supported
	in Mesa:
	</p>

	<ul>
	<li>Linking of multiple shaders does not always work. Currently, linking
	is implemented through shader concatenation and re-compiling. This
	doesn't always work because of some #pragma and preprocessor issues.
	<li>gl_ClipVertex
	<li>The gl_Color and gl_SecondaryColor varying vars are interpolated
	without perspective correction
	</ul>

	<p>
	All other major features of the shading language should function.
	</p>


	<h2 id="notes">Implementation Notes</h2>

	<ul>
	<li>Shading language programs are compiled into low-level programs
	very similar to those of GL_ARB_vertex/fragment_program.
	<li>All vector types (vec2, vec3, vec4, bvec2, etc) currently occupy full
	float[4] registers.
	<li>Float constants and variables are packed so that up to four floats
	can occupy one program parameter/register.
	<li>All function calls are inlined.
	<li>Shaders which use too many registers will not compile.
	<li>The quality of generated code is pretty good, register usage is fair.
	<li>Shader error detection and reporting of errors (InfoLog) is not
	very good yet.
	<li>The ftransform() function doesn't necessarily match the results of
	fixed-function transformation.
	</ul>

	<p>
	These issues will be addressed/resolved in the future.
	</p>


	<h2 id="hints">Programming Hints</h2>

	<ul>
	<li>Use the built-in library functions whenever possible.
	For example, instead of writing this:
	<pre>
	float x = 1.0 / sqrt(y);
	</pre>
	Write this:
	<pre>
	float x = inversesqrt(y);
	</pre>
	</li>
	</ul>


	<h2 id="standalone">Stand-alone GLSL Compiler</h2>

	<p>
	The stand-alone GLSL compiler program can be used to compile GLSL shaders
	into low-level GPU code.
	</p>

	<p>
	This tool is useful for:
	</p>
	<ul>
	<li>Inspecting GPU code to gain insight into compilation
	<li>Generating initial GPU code for subsequent hand-tuning
	<li>Debugging the GLSL compiler itself
	</ul>

	<p>
	After building Mesa, the compiler can be found at src/glsl/glsl_compiler
	</p>

	<p>
	Here's an example of using the compiler to compile a vertex shader and
	emit GL_ARB_vertex_program-style instructions:
	</p>
	<pre>
	src/glsl/glsl_compiler --dump-ast myshader.vert
	</pre>

	Options include
	<ul>
	<li><b>--dump-ast</b> - dump GPU code
	<li><b>--dump-hir</b> - dump high-level IR code
	<li><b>--dump-lir</b> - dump low-level IR code
	<li><b>--link</b> - ???
	</ul>


	<h2 id="implementation">Compiler Implementation</h2>

	<p>
	The source code for Mesa's shading language compiler is in the
	<code>src/glsl/</code> directory.
	</p>

	<p>
	XXX provide some info about the compiler....
	</p>

	<p>
	The final vertex and fragment programs may be interpreted in software
	(see prog_execute.c) or translated into a specific hardware architecture
	(see drivers/dri/i915/i915_fragprog.c for example).
	</p>

	<h3>Code Generation Options</h3>

	<p>
	Internally, there are several options that control the compiler's code
	generation and instruction selection.
	These options are seen in the gl_shader_state struct and may be set
	by the device driver to indicate its preferences:

	<pre>
	struct gl_shader_state
	{
	...
	/** Driver-selectable options: */
	GLboolean EmitHighLevelInstructions;
	GLboolean EmitCondCodes;
	GLboolean EmitComments;
	};
	</pre>

	<dl>
	<dt>EmitHighLevelInstructions</dt>
	<dd>
	This option controls instruction selection for loops and conditionals.
	If the option is set high-level IF/ELSE/ENDIF, LOOP/ENDLOOP, CONT/BRK
	instructions will be emitted.
	Otherwise, those constructs will be implemented with BRA instructions.
	</dd>

	<dt>EmitCondCodes</dt>
	<dd>
	If set, condition codes (ala GL_NV_fragment_program) will be used for
	branching and looping.
	Otherwise, ordinary registers will be used (the IF instruction will
	examine the first operand's X component and do the if-part if non-zero).
	This option is only relevant if EmitHighLevelInstructions is set.
	</dd>

	<dt>EmitComments</dt>
	<dd>
	If set, instructions will be annoted with comments to help with debugging.
	Extra NOP instructions will also be inserted.
	</dd>
	</dl>


	<h2 id="validation">Compiler Validation</h2>

	<p>
	Developers working on the GLSL compiler should test frequently to avoid
	regressions.
	</p>

	<p>
	The <a href="http://piglit.freedesktop.org/" target="_parent">Piglit</a> project
	has many GLSL tests and the
	<a href="http://glean.sf.net" target="_parent">Glean</a> glsl1 test
	tests GLSL features.
	</p>

	<p>
	The Mesa demos repository also has some good GLSL tests.
	</p>

	</body>
	</html>