include/GLSLANG/ShaderVars.h - platform/external/angle - Gitiles

 //
 // Copyright 2013 The ANGLE Project Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //
 // ShaderVars.h:
 //  Types to represent GL variables (varyings, uniforms, etc)
 //

 #ifndef GLSLANG_SHADERVARS_H_
 #define GLSLANG_SHADERVARS_H_

 #include <algorithm>
 #include <array>
 #include <string>
 #include <vector>

 // This type is defined here to simplify ANGLE's integration with glslang for SPIRv.
 using ShCompileOptions = uint64_t;

 namespace sh
 {
 // GLenum alias
 typedef unsigned int GLenum;

 // Varying interpolation qualifier, see section 4.3.9 of the ESSL 3.00.4 spec
 enum InterpolationType
 {
     INTERPOLATION_SMOOTH,
     INTERPOLATION_CENTROID,
     INTERPOLATION_FLAT,
     INTERPOLATION_NOPERSPECTIVE
 };

 // Validate link & SSO consistency of interpolation qualifiers
 bool InterpolationTypesMatch(InterpolationType a, InterpolationType b);

 // Uniform block layout qualifier, see section 4.3.8.3 of the ESSL 3.00.4 spec
 enum BlockLayoutType
 {
     BLOCKLAYOUT_STANDARD,
     BLOCKLAYOUT_STD140 = BLOCKLAYOUT_STANDARD,
     BLOCKLAYOUT_STD430,  // Shader storage block layout qualifier
     BLOCKLAYOUT_PACKED,
     BLOCKLAYOUT_SHARED
 };

 // Interface Blocks, see section 4.3.9 of the ESSL 3.10 spec
 enum class BlockType
 {
     BLOCK_UNIFORM,
     BLOCK_BUFFER,

     // Required in OpenGL ES 3.1 extension GL_OES_shader_io_blocks.
     // TODO(jiawei.shao@intel.com): add BLOCK_OUT.
     // Also used in GLSL
     BLOCK_IN
 };

 // Base class for all variables defined in shaders, including Varyings, Uniforms, etc
 // Note: we must override the copy constructor and assignment operator so we can
 // work around excessive GCC binary bloating:
 // See https://code.google.com/p/angleproject/issues/detail?id=697
 struct ShaderVariable
 {
     ShaderVariable();
     ShaderVariable(GLenum typeIn);
     ShaderVariable(GLenum typeIn, unsigned int arraySizeIn);
     ~ShaderVariable();
     ShaderVariable(const ShaderVariable &other);
     ShaderVariable &operator=(const ShaderVariable &other);
     bool operator==(const ShaderVariable &other) const;
     bool operator!=(const ShaderVariable &other) const { return !operator==(other); }

     bool isArrayOfArrays() const { return arraySizes.size() >= 2u; }
     bool isArray() const { return !arraySizes.empty(); }
     unsigned int getArraySizeProduct() const;
     // Return the inner array size product.
     // For example, if there's a variable declared as size 3 array of size 4 array of size 5 array
     // of int:
     //   int a[3][4][5];
     // then getInnerArraySizeProduct of a would be 4*5.
     unsigned int getInnerArraySizeProduct() const;

     // Array size 0 means not an array when passed to or returned from these functions.
     // Note that setArraySize() is deprecated and should not be used inside ANGLE.
     unsigned int getOutermostArraySize() const { return isArray() ? arraySizes.back() : 0; }
     void setArraySize(unsigned int size);

     // Turn this ShaderVariable from an array into a specific element in that array. Will update
     // flattenedOffsetInParentArrays.
     void indexIntoArray(unsigned int arrayIndex);

     // Get the nth nested array size from the top. Caller is responsible for range checking
     // arrayNestingIndex.
     unsigned int getNestedArraySize(unsigned int arrayNestingIndex) const;

     // This function should only be used with variables that are of a basic type or an array of a
     // basic type. Shader interface variables that are enumerated according to rules in GLES 3.1
     // spec section 7.3.1.1 page 77 are fine. For those variables the return value should match the
     // ARRAY_SIZE value that can be queried through the API.
     unsigned int getBasicTypeElementCount() const;

     unsigned int getExternalSize() const;

     bool isStruct() const { return !fields.empty(); }

     // All of the shader's variables are described using nested data
     // structures. This is needed in order to disambiguate similar looking
     // types, such as two structs containing the same fields, but in
     // different orders. "findInfoByMappedName" provides an easy query for
     // users to dive into the data structure and fetch the unique variable
     // instance corresponding to a dereferencing chain of the top-level
     // variable.
     // Given a mapped name like 'a[0].b.c[0]', return the ShaderVariable
     // that defines 'c' in |leafVar|, and the original name 'A[0].B.C[0]'
     // in |originalName|, based on the assumption that |this| defines 'a'.
     // If no match is found, return false.
     bool findInfoByMappedName(const std::string &mappedFullName,
                               const ShaderVariable **leafVar,
                               std::string *originalFullName) const;

     bool isBuiltIn() const;
     bool isEmulatedBuiltIn() const;

     GLenum type;
     GLenum precision;
     std::string name;
     std::string mappedName;

     // Used to make an array type. Outermost array size is stored at the end of the vector.
     std::vector<unsigned int> arraySizes;

     // Offset of this variable in parent arrays. In case the parent is an array of arrays, the
     // offset is outerArrayElement * innerArraySize + innerArrayElement.
     // For example, if there's a variable declared as size 3 array of size 4 array of int:
     //   int a[3][4];
     // then the flattenedOffsetInParentArrays of a[2] would be 2.
     // and flattenedOffsetInParentArrays of a[2][1] would be 2*4 + 1 = 9.
     int parentArrayIndex() const
     {
         return hasParentArrayIndex() ? flattenedOffsetInParentArrays : 0;
     }

     void setParentArrayIndex(int indexIn) { flattenedOffsetInParentArrays = indexIn; }

     bool hasParentArrayIndex() const { return flattenedOffsetInParentArrays != -1; }

     // Static use means that the variable is accessed somewhere in the shader source.
     bool staticUse;
     // A variable is active unless the compiler determined that it is not accessed by the shader.
     // All active variables are statically used, but not all statically used variables are
     // necessarily active. GLES 3.0.5 section 2.12.6. GLES 3.1 section 7.3.1.
     bool active;
     std::vector<ShaderVariable> fields;
     std::string structName;

     // Only applies to interface block fields. Kept here for simplicity.
     bool isRowMajorLayout;

     // VariableWithLocation
     int location;

     // Uniform
     int binding;
     // Decide whether two uniforms are the same at shader link time,
     // assuming one from vertex shader and the other from fragment shader.
     // GLSL ES Spec 3.00.3, section 4.3.5.
     // GLSL ES Spec 3.10.4, section 4.4.5
     bool isSameUniformAtLinkTime(const ShaderVariable &other) const;
     GLenum imageUnitFormat;
     int offset;
     bool readonly;
     bool writeonly;

     // OutputVariable
     // From EXT_blend_func_extended.
     int index;

     // InterfaceBlockField
     // Decide whether two InterfaceBlock fields are the same at shader
     // link time, assuming one from vertex shader and the other from
     // fragment shader.
     // See GLSL ES Spec 3.00.3, sec 4.3.7.
     bool isSameInterfaceBlockFieldAtLinkTime(const ShaderVariable &other) const;

     // Varying
     InterpolationType interpolation;
     bool isInvariant;
     // Decide whether two varyings are the same at shader link time,
     // assuming one from vertex shader and the other from fragment shader.
     // Invariance needs to match only in ESSL1. Relevant spec sections:
     // GLSL ES 3.00.4, sections 4.6.1 and 4.3.9.
     // GLSL ES 1.00.17, section 4.6.4.
     bool isSameVaryingAtLinkTime(const ShaderVariable &other, int shaderVersion) const;
     // Deprecated version of isSameVaryingAtLinkTime, which assumes ESSL1.
     bool isSameVaryingAtLinkTime(const ShaderVariable &other) const;

   protected:
     bool isSameVariableAtLinkTime(const ShaderVariable &other,
                                   bool matchPrecision,
                                   bool matchName) const;

     int flattenedOffsetInParentArrays;
 };

 // TODO: anglebug.com/3899
 // For backwards compatibility for other codebases (e.g., chromium/src/gpu/command_buffer/service)
 using Uniform             = ShaderVariable;
 using Attribute           = ShaderVariable;
 using OutputVariable      = ShaderVariable;
 using InterfaceBlockField = ShaderVariable;
 using Varying             = ShaderVariable;

 struct InterfaceBlock
 {
     InterfaceBlock();
     ~InterfaceBlock();
     InterfaceBlock(const InterfaceBlock &other);
     InterfaceBlock &operator=(const InterfaceBlock &other);

     // Fields from blocks with non-empty instance names are prefixed with the block name.
     std::string fieldPrefix() const;
     std::string fieldMappedPrefix() const;

     // Decide whether two interface blocks are the same at shader link time.
     bool isSameInterfaceBlockAtLinkTime(const InterfaceBlock &other) const;

     bool isBuiltIn() const;

     bool isArray() const { return arraySize > 0; }
     unsigned int elementCount() const { return std::max(1u, arraySize); }

     std::string name;
     std::string mappedName;
     std::string instanceName;
     unsigned int arraySize;
     BlockLayoutType layout;

     // Deprecated. Matrix packing should only be queried from individual fields of the block.
     // TODO(oetuaho): Remove this once it is no longer used in Chromium.
     bool isRowMajorLayout;

     int binding;
     bool staticUse;
     bool active;
     BlockType blockType;
     std::vector<ShaderVariable> fields;
 };

 struct WorkGroupSize
 {
     // Must have a trivial default constructor since it is used in YYSTYPE.
     inline WorkGroupSize() = default;
     inline explicit constexpr WorkGroupSize(int initialSize);

     void fill(int fillValue);
     void setLocalSize(int localSizeX, int localSizeY, int localSizeZ);

     int &operator[](size_t index);
     int operator[](size_t index) const;
     size_t size() const;

     // Checks whether two work group size declarations match.
     // Two work group size declarations are the same if the explicitly specified elements are the
     // same or if one of them is specified as one and the other one is not specified
     bool isWorkGroupSizeMatching(const WorkGroupSize &right) const;

     // Checks whether any of the values are set.
     bool isAnyValueSet() const;

     // Checks whether all of the values are set.
     bool isDeclared() const;

     // Checks whether either all of the values are set, or none of them are.
     bool isLocalSizeValid() const;

     int localSizeQualifiers[3];
 };

 inline constexpr WorkGroupSize::WorkGroupSize(int initialSize)
     : localSizeQualifiers{initialSize, initialSize, initialSize}
 {}

 }  // namespace sh

 #endif  // GLSLANG_SHADERVARS_H_
	//
	// Copyright 2013 The ANGLE Project Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//
	// ShaderVars.h:
	// Types to represent GL variables (varyings, uniforms, etc)
	//

	#ifndef GLSLANG_SHADERVARS_H_
	#define GLSLANG_SHADERVARS_H_

	#include <algorithm>
	#include <array>
	#include <string>
	#include <vector>

	// This type is defined here to simplify ANGLE's integration with glslang for SPIRv.
	using ShCompileOptions = uint64_t;

	namespace sh
	{
	// GLenum alias
	typedef unsigned int GLenum;

	// Varying interpolation qualifier, see section 4.3.9 of the ESSL 3.00.4 spec
	enum InterpolationType
	{
	INTERPOLATION_SMOOTH,
	INTERPOLATION_CENTROID,
	INTERPOLATION_FLAT,
	INTERPOLATION_NOPERSPECTIVE
	};

	// Validate link & SSO consistency of interpolation qualifiers
	bool InterpolationTypesMatch(InterpolationType a, InterpolationType b);

	// Uniform block layout qualifier, see section 4.3.8.3 of the ESSL 3.00.4 spec
	enum BlockLayoutType
	{
	BLOCKLAYOUT_STANDARD,
	BLOCKLAYOUT_STD140 = BLOCKLAYOUT_STANDARD,
	BLOCKLAYOUT_STD430, // Shader storage block layout qualifier
	BLOCKLAYOUT_PACKED,
	BLOCKLAYOUT_SHARED
	};

	// Interface Blocks, see section 4.3.9 of the ESSL 3.10 spec
	enum class BlockType
	{
	BLOCK_UNIFORM,
	BLOCK_BUFFER,

	// Required in OpenGL ES 3.1 extension GL_OES_shader_io_blocks.
	// TODO(jiawei.shao@intel.com): add BLOCK_OUT.
	// Also used in GLSL
	BLOCK_IN
	};

	// Base class for all variables defined in shaders, including Varyings, Uniforms, etc
	// Note: we must override the copy constructor and assignment operator so we can
	// work around excessive GCC binary bloating:
	// See https://code.google.com/p/angleproject/issues/detail?id=697
	struct ShaderVariable
	{
	ShaderVariable();
	ShaderVariable(GLenum typeIn);
	ShaderVariable(GLenum typeIn, unsigned int arraySizeIn);
	~ShaderVariable();
	ShaderVariable(const ShaderVariable &other);
	ShaderVariable &operator=(const ShaderVariable &other);
	bool operator==(const ShaderVariable &other) const;
	bool operator!=(const ShaderVariable &other) const { return !operator==(other); }

	bool isArrayOfArrays() const { return arraySizes.size() >= 2u; }
	bool isArray() const { return !arraySizes.empty(); }
	unsigned int getArraySizeProduct() const;
	// Return the inner array size product.
	// For example, if there's a variable declared as size 3 array of size 4 array of size 5 array
	// of int:
	// int a[3][4][5];
	// then getInnerArraySizeProduct of a would be 4*5.
	unsigned int getInnerArraySizeProduct() const;

	// Array size 0 means not an array when passed to or returned from these functions.
	// Note that setArraySize() is deprecated and should not be used inside ANGLE.
	unsigned int getOutermostArraySize() const { return isArray() ? arraySizes.back() : 0; }
	void setArraySize(unsigned int size);

	// Turn this ShaderVariable from an array into a specific element in that array. Will update
	// flattenedOffsetInParentArrays.
	void indexIntoArray(unsigned int arrayIndex);

	// Get the nth nested array size from the top. Caller is responsible for range checking
	// arrayNestingIndex.
	unsigned int getNestedArraySize(unsigned int arrayNestingIndex) const;

	// This function should only be used with variables that are of a basic type or an array of a
	// basic type. Shader interface variables that are enumerated according to rules in GLES 3.1
	// spec section 7.3.1.1 page 77 are fine. For those variables the return value should match the
	// ARRAY_SIZE value that can be queried through the API.
	unsigned int getBasicTypeElementCount() const;

	unsigned int getExternalSize() const;

	bool isStruct() const { return !fields.empty(); }

	// All of the shader's variables are described using nested data
	// structures. This is needed in order to disambiguate similar looking
	// types, such as two structs containing the same fields, but in
	// different orders. "findInfoByMappedName" provides an easy query for
	// users to dive into the data structure and fetch the unique variable
	// instance corresponding to a dereferencing chain of the top-level
	// variable.
	// Given a mapped name like 'a[0].b.c[0]', return the ShaderVariable
	// that defines 'c' in \|leafVar\|, and the original name 'A[0].B.C[0]'
	// in \|originalName\|, based on the assumption that \|this\| defines 'a'.
	// If no match is found, return false.
	bool findInfoByMappedName(const std::string &mappedFullName,
	const ShaderVariable **leafVar,
	std::string *originalFullName) const;

	bool isBuiltIn() const;
	bool isEmulatedBuiltIn() const;

	GLenum type;
	GLenum precision;
	std::string name;
	std::string mappedName;

	// Used to make an array type. Outermost array size is stored at the end of the vector.
	std::vector<unsigned int> arraySizes;

	// Offset of this variable in parent arrays. In case the parent is an array of arrays, the
	// offset is outerArrayElement * innerArraySize + innerArrayElement.
	// For example, if there's a variable declared as size 3 array of size 4 array of int:
	// int a[3][4];
	// then the flattenedOffsetInParentArrays of a[2] would be 2.
	// and flattenedOffsetInParentArrays of a[2][1] would be 2*4 + 1 = 9.
	int parentArrayIndex() const
	{
	return hasParentArrayIndex() ? flattenedOffsetInParentArrays : 0;
	}

	void setParentArrayIndex(int indexIn) { flattenedOffsetInParentArrays = indexIn; }

	bool hasParentArrayIndex() const { return flattenedOffsetInParentArrays != -1; }

	// Static use means that the variable is accessed somewhere in the shader source.
	bool staticUse;
	// A variable is active unless the compiler determined that it is not accessed by the shader.
	// All active variables are statically used, but not all statically used variables are
	// necessarily active. GLES 3.0.5 section 2.12.6. GLES 3.1 section 7.3.1.
	bool active;
	std::vector<ShaderVariable> fields;
	std::string structName;

	// Only applies to interface block fields. Kept here for simplicity.
	bool isRowMajorLayout;

	// VariableWithLocation
	int location;

	// Uniform
	int binding;
	// Decide whether two uniforms are the same at shader link time,
	// assuming one from vertex shader and the other from fragment shader.
	// GLSL ES Spec 3.00.3, section 4.3.5.
	// GLSL ES Spec 3.10.4, section 4.4.5
	bool isSameUniformAtLinkTime(const ShaderVariable &other) const;
	GLenum imageUnitFormat;
	int offset;
	bool readonly;
	bool writeonly;

	// OutputVariable
	// From EXT_blend_func_extended.
	int index;

	// InterfaceBlockField
	// Decide whether two InterfaceBlock fields are the same at shader
	// link time, assuming one from vertex shader and the other from
	// fragment shader.
	// See GLSL ES Spec 3.00.3, sec 4.3.7.
	bool isSameInterfaceBlockFieldAtLinkTime(const ShaderVariable &other) const;

	// Varying
	InterpolationType interpolation;
	bool isInvariant;
	// Decide whether two varyings are the same at shader link time,
	// assuming one from vertex shader and the other from fragment shader.
	// Invariance needs to match only in ESSL1. Relevant spec sections:
	// GLSL ES 3.00.4, sections 4.6.1 and 4.3.9.
	// GLSL ES 1.00.17, section 4.6.4.
	bool isSameVaryingAtLinkTime(const ShaderVariable &other, int shaderVersion) const;
	// Deprecated version of isSameVaryingAtLinkTime, which assumes ESSL1.
	bool isSameVaryingAtLinkTime(const ShaderVariable &other) const;

	protected:
	bool isSameVariableAtLinkTime(const ShaderVariable &other,
	bool matchPrecision,
	bool matchName) const;

	int flattenedOffsetInParentArrays;
	};

	// TODO: anglebug.com/3899
	// For backwards compatibility for other codebases (e.g., chromium/src/gpu/command_buffer/service)
	using Uniform = ShaderVariable;
	using Attribute = ShaderVariable;
	using OutputVariable = ShaderVariable;
	using InterfaceBlockField = ShaderVariable;
	using Varying = ShaderVariable;

	struct InterfaceBlock
	{
	InterfaceBlock();
	~InterfaceBlock();
	InterfaceBlock(const InterfaceBlock &other);
	InterfaceBlock &operator=(const InterfaceBlock &other);

	// Fields from blocks with non-empty instance names are prefixed with the block name.
	std::string fieldPrefix() const;
	std::string fieldMappedPrefix() const;

	// Decide whether two interface blocks are the same at shader link time.
	bool isSameInterfaceBlockAtLinkTime(const InterfaceBlock &other) const;

	bool isBuiltIn() const;

	bool isArray() const { return arraySize > 0; }
	unsigned int elementCount() const { return std::max(1u, arraySize); }

	std::string name;
	std::string mappedName;
	std::string instanceName;
	unsigned int arraySize;
	BlockLayoutType layout;

	// Deprecated. Matrix packing should only be queried from individual fields of the block.
	// TODO(oetuaho): Remove this once it is no longer used in Chromium.
	bool isRowMajorLayout;

	int binding;
	bool staticUse;
	bool active;
	BlockType blockType;
	std::vector<ShaderVariable> fields;
	};

	struct WorkGroupSize
	{
	// Must have a trivial default constructor since it is used in YYSTYPE.
	inline WorkGroupSize() = default;
	inline explicit constexpr WorkGroupSize(int initialSize);

	void fill(int fillValue);
	void setLocalSize(int localSizeX, int localSizeY, int localSizeZ);

	int &operator[](size_t index);
	int operator[](size_t index) const;
	size_t size() const;

	// Checks whether two work group size declarations match.
	// Two work group size declarations are the same if the explicitly specified elements are the
	// same or if one of them is specified as one and the other one is not specified
	bool isWorkGroupSizeMatching(const WorkGroupSize &right) const;

	// Checks whether any of the values are set.
	bool isAnyValueSet() const;

	// Checks whether all of the values are set.
	bool isDeclared() const;

	// Checks whether either all of the values are set, or none of them are.
	bool isLocalSizeValid() const;

	int localSizeQualifiers[3];
	};

	inline constexpr WorkGroupSize::WorkGroupSize(int initialSize)
	: localSizeQualifiers{initialSize, initialSize, initialSize}
	{}

	} // namespace sh

	#endif // GLSLANG_SHADERVARS_H_