src/sksl/README - skia - Git at Google

 Overview
 ========

 SkSL ("Skia Shading Language") is a variant of GLSL which is used as Skia's
 internal shading language. SkSL is, at its heart, a single standardized version
 of GLSL which avoids all of the various version and dialect differences found
 in GLSL "in the wild", but it does bring a few of its own changes to the table.

 Skia uses the SkSL compiler to convert SkSL code to GLSL, GLSL ES, or SPIR-V
 before handing it over to the graphics driver.


 Differences from GLSL
 =====================

 * Precision modifiers are not used. 'float', 'int', and 'uint' are always high
   precision. New types 'half', 'short', and 'ushort' are medium precision (we
   do not use low precision).
 * Vector types are named <base type><columns>, so float2 instead of vec2 and
   bool4 instead of bvec4
 * Matrix types are named <base type><columns>x<rows>, so float2x3 instead of
   mat2x3 and double4x4 instead of dmat4
 * "@if" and "@switch" are static versions of if and switch. They behave exactly
   the same as if and switch in all respects other than it being a compile-time
   error to use a non-constant expression as a test.
 * GLSL caps can be referenced via the syntax 'sk_Caps.<name>', e.g.
   sk_Caps.sampleVariablesSupport. The value will be a constant boolean or int,
   as appropriate. As SkSL supports constant folding and branch elimination, this
   means that an 'if' statement which statically queries a cap will collapse down
   to the chosen branch, meaning that:

     if (sk_Caps.externalTextureSupport)
         do_something();
     else
         do_something_else();

   will compile as if you had written either 'do_something();' or
   'do_something_else();', depending on whether that cap is enabled or not.
 * no #version statement is required, and it will be ignored if present
 * the output color is sk_FragColor (do not declare it)
 * use sk_Position instead of gl_Position. sk_Position is in device coordinates
   rather than normalized coordinates.
 * use sk_PointSize instead of gl_PointSize
 * use sk_VertexID instead of gl_VertexID
 * use sk_InstanceID instead of gl_InstanceID
 * the fragment coordinate is sk_FragCoord, and is always relative to the upper
   left.
 * you do not need to include ".0" to make a number a float (meaning that
   "float2(x, y) * 4" is perfectly legal in SkSL, unlike GLSL where it would
   often have to be expressed "float2(x, y) * 4.0". There is no performance
   penalty for this, as the number is converted to a float at compile time)
 * type suffixes on numbers (1.0f, 0xFFu) are both unnecessary and unsupported
 * creating a smaller vector from a larger vector (e.g. float2(float3(1))) is
   intentionally disallowed, as it is just a wordier way of performing a swizzle.
   Use swizzles instead.
 * Use texture() instead of textureProj(), e.g. texture(sampler2D, float3) is
   equivalent to GLSL's textureProj(sampler2D, float3)
 * some built-in functions and one or two rarely-used language features are not
   yet supported (sorry!)

 SkSL is still under development, and is expected to diverge further from GLSL
 over time.


 SkSL Fragment Processors
 ========================

 ********************************************************************************
 *** IMPORTANT: You must set gn arg "skia_compile_processors = true" to cause ***
 *** .fp files to be recompiled! In order for compilation to succeed, you     ***
 *** must run bin/fetch-clang-format (once) to install our blessed version.   ***
 ********************************************************************************

 An extension of SkSL allows for the creation of fragment processors in pure
 SkSL. The program defines its inputs similarly to a normal SkSL program (with
 'in' and 'uniform' variables), but the 'main()' function represents only this
 fragment processor's portion of the overall fragment shader.

 Within an '.fp' fragment processor file:

 * C++ code can be embedded in sections of the form:

   @section_name { <arbitrary C++ code> }

   Supported section are:
     @header            (in the .h file, outside the class declaration)
     @headerEnd         (at the end of the .h file)
     @class             (in the .h file, inside the class declaration)
     @cpp               (in the .cpp file)
     @cppEnd            (at the end of the .cpp file)
     @constructorParams (extra parameters to the constructor, comma-separated)
     @constructor       (replaces the default constructor)
     @initializers      (constructor initializer list, comma-separated)
     @emitCode          (extra code for the emitCode function)
     @fields            (extra private fields, each terminated with a semicolon)
     @make              (replaces the default Make function)
     @clone             (replaces the default clone() function)
     @setData(<pdman>)  (extra code for the setData function, where <pdman> is
                         the name of the GrGLSLProgramDataManager)
     @test(<testData>)  (the body of the TestCreate function, where <testData> is
                         the name of the GrProcessorTestData* parameter)
     @coordTransform(<sampler>)
                        (the matrix to attach to the named sampler2D's
                         GrCoordTransform)
     @samplerParams(<sampler>)
                        (the sampler params to attach to the named sampler2D)
 * global 'in' variables represent data passed to the fragment processor at
   construction time. These variables become constructor parameters and are
   stored in fragment processor fields. By default float2/half2 maps to SkPoints,
   and float4/half4 maps to SkRects (in x, y, width, height) order. Use ctype
   (below) to override this default mapping.
 * global variables support an additional 'ctype' layout key, providing the type
   they should be represented as from within the C++ code. For instance, you can
   use 'layout(ctype=GrColor4f) in half4 color;' to create a variable that looks
   like a half4 on the SkSL side of things, and a GrColor4f on the C++ side of
   things.
 * 'uniform' variables become, as one would expect, top-level uniforms. By
   default they do not have any data provided to them; you will need to provide
   them with data via the @setData section.
 * 'in uniform' variables are uniforms that are automatically wired up to
   fragment processor constructor parameters. The fragment processor will accept
   a parameter representing the uniform's value, and automatically plumb it
   through to the uniform's value in its generated setData() function.
 * the 'sk_TransformedCoords2D' array provides access to 2D transformed
   coordinates. sk_TransformedCoords2D[0] is equivalent to calling
   fragBuilder->ensureCoords2D(args.fTransformedCoords[0]) (and the result is
   cached, so you need not worry about using the value repeatedly).
 * Uniform variables support an additional 'when' layout key.
   'layout(when=foo) uniform int x;' means that this uniform will only be
   emitted when the 'foo' expression is true.
 * 'in' variables support an additional 'key' layout key.
   'layout(key) uniform int x;' means that this uniform should be included in
   the program's key. Matrix variables additionally support 'key=identity',
   which causes the key to consider only whether or not the matrix is an
   identity matrix.


 Creating a new .fp file
 =======================

 1. Ensure that you have set gn arg "skia_compile_processors = true"
 2. Create your new .fp file, generally under src/gpu/effects.
 3. Add the .fp file to sksl.gni.
 4. Build Skia. This will cause the .fp file to be compiled, resulting in a new
    .cpp and .h file for the fragment processor.
 5. Add the .cpp and .h files to gpu.gni.
 6. Add the new processor's ClassID (k<ProcessorName>_ClassID) to
    GrProcessor::ClassID.
 7. At this point you can reference the new fragment processor from within Skia.

 Once you have done this initial setup, simply re-build Skia to pick up any
 changes to the .fp file.
	Overview
	========

	SkSL ("Skia Shading Language") is a variant of GLSL which is used as Skia's
	internal shading language. SkSL is, at its heart, a single standardized version
	of GLSL which avoids all of the various version and dialect differences found
	in GLSL "in the wild", but it does bring a few of its own changes to the table.

	Skia uses the SkSL compiler to convert SkSL code to GLSL, GLSL ES, or SPIR-V
	before handing it over to the graphics driver.


	Differences from GLSL
	=====================

	* Precision modifiers are not used. 'float', 'int', and 'uint' are always high
	precision. New types 'half', 'short', and 'ushort' are medium precision (we
	do not use low precision).
	* Vector types are named <base type><columns>, so float2 instead of vec2 and
	bool4 instead of bvec4
	* Matrix types are named <base type><columns>x<rows>, so float2x3 instead of
	mat2x3 and double4x4 instead of dmat4
	* "@if" and "@switch" are static versions of if and switch. They behave exactly
	the same as if and switch in all respects other than it being a compile-time
	error to use a non-constant expression as a test.
	* GLSL caps can be referenced via the syntax 'sk_Caps.<name>', e.g.
	sk_Caps.sampleVariablesSupport. The value will be a constant boolean or int,
	as appropriate. As SkSL supports constant folding and branch elimination, this
	means that an 'if' statement which statically queries a cap will collapse down
	to the chosen branch, meaning that:

	if (sk_Caps.externalTextureSupport)
	do_something();
	else
	do_something_else();

	will compile as if you had written either 'do_something();' or
	'do_something_else();', depending on whether that cap is enabled or not.
	* no #version statement is required, and it will be ignored if present
	* the output color is sk_FragColor (do not declare it)
	* use sk_Position instead of gl_Position. sk_Position is in device coordinates
	rather than normalized coordinates.
	* use sk_PointSize instead of gl_PointSize
	* use sk_VertexID instead of gl_VertexID
	* use sk_InstanceID instead of gl_InstanceID
	* the fragment coordinate is sk_FragCoord, and is always relative to the upper
	left.
	* you do not need to include ".0" to make a number a float (meaning that
	"float2(x, y) * 4" is perfectly legal in SkSL, unlike GLSL where it would
	often have to be expressed "float2(x, y) * 4.0". There is no performance
	penalty for this, as the number is converted to a float at compile time)
	* type suffixes on numbers (1.0f, 0xFFu) are both unnecessary and unsupported
	* creating a smaller vector from a larger vector (e.g. float2(float3(1))) is
	intentionally disallowed, as it is just a wordier way of performing a swizzle.
	Use swizzles instead.
	* Use texture() instead of textureProj(), e.g. texture(sampler2D, float3) is
	equivalent to GLSL's textureProj(sampler2D, float3)
	* some built-in functions and one or two rarely-used language features are not
	yet supported (sorry!)

	SkSL is still under development, and is expected to diverge further from GLSL
	over time.


	SkSL Fragment Processors
	========================

	********************************************************************************
	* IMPORTANT: You must set gn arg "skia_compile_processors = true" to cause *
	* .fp files to be recompiled! In order for compilation to succeed, you *
	* must run bin/fetch-clang-format (once) to install our blessed version. *
	********************************************************************************

	An extension of SkSL allows for the creation of fragment processors in pure
	SkSL. The program defines its inputs similarly to a normal SkSL program (with
	'in' and 'uniform' variables), but the 'main()' function represents only this
	fragment processor's portion of the overall fragment shader.

	Within an '.fp' fragment processor file:

	* C++ code can be embedded in sections of the form:

	@section_name { <arbitrary C++ code> }

	Supported section are:
	@header (in the .h file, outside the class declaration)
	@headerEnd (at the end of the .h file)
	@class (in the .h file, inside the class declaration)
	@cpp (in the .cpp file)
	@cppEnd (at the end of the .cpp file)
	@constructorParams (extra parameters to the constructor, comma-separated)
	@constructor (replaces the default constructor)
	@initializers (constructor initializer list, comma-separated)
	@emitCode (extra code for the emitCode function)
	@fields (extra private fields, each terminated with a semicolon)
	@make (replaces the default Make function)
	@clone (replaces the default clone() function)
	@setData(<pdman>) (extra code for the setData function, where <pdman> is
	the name of the GrGLSLProgramDataManager)
	@test(<testData>) (the body of the TestCreate function, where <testData> is
	the name of the GrProcessorTestData* parameter)
	@coordTransform(<sampler>)
	(the matrix to attach to the named sampler2D's
	GrCoordTransform)
	@samplerParams(<sampler>)
	(the sampler params to attach to the named sampler2D)
	* global 'in' variables represent data passed to the fragment processor at
	construction time. These variables become constructor parameters and are
	stored in fragment processor fields. By default float2/half2 maps to SkPoints,
	and float4/half4 maps to SkRects (in x, y, width, height) order. Use ctype
	(below) to override this default mapping.
	* global variables support an additional 'ctype' layout key, providing the type
	they should be represented as from within the C++ code. For instance, you can
	use 'layout(ctype=GrColor4f) in half4 color;' to create a variable that looks
	like a half4 on the SkSL side of things, and a GrColor4f on the C++ side of
	things.
	* 'uniform' variables become, as one would expect, top-level uniforms. By
	default they do not have any data provided to them; you will need to provide
	them with data via the @setData section.
	* 'in uniform' variables are uniforms that are automatically wired up to
	fragment processor constructor parameters. The fragment processor will accept
	a parameter representing the uniform's value, and automatically plumb it
	through to the uniform's value in its generated setData() function.
	* the 'sk_TransformedCoords2D' array provides access to 2D transformed
	coordinates. sk_TransformedCoords2D[0] is equivalent to calling
	fragBuilder->ensureCoords2D(args.fTransformedCoords[0]) (and the result is
	cached, so you need not worry about using the value repeatedly).
	* Uniform variables support an additional 'when' layout key.
	'layout(when=foo) uniform int x;' means that this uniform will only be
	emitted when the 'foo' expression is true.
	* 'in' variables support an additional 'key' layout key.
	'layout(key) uniform int x;' means that this uniform should be included in
	the program's key. Matrix variables additionally support 'key=identity',
	which causes the key to consider only whether or not the matrix is an
	identity matrix.


	Creating a new .fp file
	=======================

	1. Ensure that you have set gn arg "skia_compile_processors = true"
	2. Create your new .fp file, generally under src/gpu/effects.
	3. Add the .fp file to sksl.gni.
	4. Build Skia. This will cause the .fp file to be compiled, resulting in a new
	.cpp and .h file for the fragment processor.
	5. Add the .cpp and .h files to gpu.gni.
	6. Add the new processor's ClassID (k<ProcessorName>_ClassID) to
	GrProcessor::ClassID.
	7. At this point you can reference the new fragment processor from within Skia.

	Once you have done this initial setup, simply re-build Skia to pick up any
	changes to the .fp file.