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.canUseAnyFunctionInShader. 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.
 * use sk_Clockwise instead of gl_FrontFacing. This is always relative to an
   upper left origin.
 * 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.
 * Swizzle components, in addition to the normal rgba / xyzw components, can also
   be LTRB (meaning "left/top/right/bottom", for when we store rectangles in
   vectors), and may also be the constants '0' or '1' to produce a constant 0 or
   1 in that channel instead of selecting anything from the source vector.
   foo.rgb1 is equivalent to float4(foo.rgb, 1).
 * All texture functions are named "sample", e.g. sample(sampler2D, float3) is
   equivalent to GLSL's textureProj(sampler2D, float3).
 * Render target width and height are available via sk_Width and sk_Height
 * 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. The 'main' function
 can optionally have a 'float2' parameter that holds the sample coordinates the
 processor is evaluated at.

 Processors do not need to declare this parameter if they do not rely on local
 coordinates or only invoke child processors using the no-arg and matrix-based
 sample() functions.

 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)
     @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. Similarly,
   int2/short2 maps to SkIPoint and int4/half4 maps to SkIRect. 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=SkPMColor4f) in half4 color;' to create a variable that looks
   like a half4 on the SkSL side of things, and a SkPMColor4f 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.
 * 'in uniform' variables support a 'tracked' flag in the layout that will
   have the generated code automatically implement state tracking on the uniform
   value to minimize GPU calls.
 * 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) in 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.
 * child processors can be declared with 'in fragmentProcessor <name>;', and can
   be invoked by calling 'sample(<name>)' or 'sample(<name>, <inputColor>)'.
   The first variant emits the child with a solid white input color. The second
   variant emits the child with the result of the 2nd argument's expression,
   which must evaluate to a half4. The process function returns a half4.
 * The 'fragmentProcessor' type cannot hold a null. Nullable fragment processors
   should use the 'fragmentProcessor?' type: 'in fragmentProcessor? <name>'. You
   can check for null fragment processors by comparing them against 'null', as
   in: 'if (inputFP != null) { ... }'. Invoking 'sample()' on a null fragment
   processor will return the inputColor unchanged (this defaults to solid white
   if not explicitly specified).


 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.canUseAnyFunctionInShader. 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.
	* use sk_Clockwise instead of gl_FrontFacing. This is always relative to an
	upper left origin.
	* 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.
	* Swizzle components, in addition to the normal rgba / xyzw components, can also
	be LTRB (meaning "left/top/right/bottom", for when we store rectangles in
	vectors), and may also be the constants '0' or '1' to produce a constant 0 or
	1 in that channel instead of selecting anything from the source vector.
	foo.rgb1 is equivalent to float4(foo.rgb, 1).
	* All texture functions are named "sample", e.g. sample(sampler2D, float3) is
	equivalent to GLSL's textureProj(sampler2D, float3).
	* Render target width and height are available via sk_Width and sk_Height
	* 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. The 'main' function
	can optionally have a 'float2' parameter that holds the sample coordinates the
	processor is evaluated at.

	Processors do not need to declare this parameter if they do not rely on local
	coordinates or only invoke child processors using the no-arg and matrix-based
	sample() functions.

	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)
	@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. Similarly,
	int2/short2 maps to SkIPoint and int4/half4 maps to SkIRect. 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=SkPMColor4f) in half4 color;' to create a variable that looks
	like a half4 on the SkSL side of things, and a SkPMColor4f 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.
	* 'in uniform' variables support a 'tracked' flag in the layout that will
	have the generated code automatically implement state tracking on the uniform
	value to minimize GPU calls.
	* 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) in 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.
	* child processors can be declared with 'in fragmentProcessor <name>;', and can
	be invoked by calling 'sample(<name>)' or 'sample(<name>, <inputColor>)'.
	The first variant emits the child with a solid white input color. The second
	variant emits the child with the result of the 2nd argument's expression,
	which must evaluate to a half4. The process function returns a half4.
	* The 'fragmentProcessor' type cannot hold a null. Nullable fragment processors
	should use the 'fragmentProcessor?' type: 'in fragmentProcessor? <name>'. You
	can check for null fragment processors by comparing them against 'null', as
	in: 'if (inputFP != null) { ... }'. Invoking 'sample()' on a null fragment
	processor will return the inputColor unchanged (this defaults to solid white
	if not explicitly specified).


	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.