src/transform/vertex_pulling.h - tint - Git at Google

 // Copyright 2020 The Tint Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef SRC_TRANSFORM_VERTEX_PULLING_H_
 #define SRC_TRANSFORM_VERTEX_PULLING_H_

 #include <memory>
 #include <string>
 #include <unordered_map>
 #include <vector>

 #include "src/transform/transform.h"

 namespace tint {
 namespace transform {

 /// Describes the format of data in a vertex buffer
 enum class VertexFormat {
   kUint8x2,    // uint8x2
   kUint8x4,    // uint8x4
   kSint8x2,    // sint8x2
   kSint8x4,    // sint8x4
   kUnorm8x2,   // unorm8x2
   kUnorm8x4,   // unorm8x4
   kSnorm8x2,   // snorm8x2
   kSnorm8x4,   // snorm8x4
   kUint16x2,   // uint16x2
   kUint16x4,   // uint16x4
   kSint16x2,   // sint16x2
   kSint16x4,   // sint16x4
   kUnorm16x2,  // unorm16x2
   kUnorm16x4,  // unorm16x4
   kSnorm16x2,  // snorm16x2
   kSnorm16x4,  // snorm16x4
   kFloat16x2,  // float16x2
   kFloat16x4,  // float16x4
   kFloat32,    // float32
   kFloat32x2,  // float32x2
   kFloat32x3,  // float32x3
   kFloat32x4,  // float32x4
   kUint32,     // uint32
   kUint32x2,   // uint32x2
   kUint32x3,   // uint32x3
   kUint32x4,   // uint32x4
   kSint32,     // sint32
   kSint32x2,   // sint32x2
   kSint32x3,   // sint32x3
   kSint32x4,   // sint32x4

   kLastEntry = kSint32x4,
 };

 /// Describes if a vertex attributes increments with vertex index or instance
 /// index
 enum class VertexStepMode { kVertex, kInstance, kLastEntry = kInstance };

 /// Describes a vertex attribute within a buffer
 struct VertexAttributeDescriptor {
   /// The format of the attribute
   VertexFormat format;
   /// The byte offset of the attribute in the buffer
   uint32_t offset;
   /// The shader location used for the attribute
   uint32_t shader_location;
 };

 /// Describes a buffer containing multiple vertex attributes
 struct VertexBufferLayoutDescriptor {
   /// Constructor
   VertexBufferLayoutDescriptor();
   /// Constructor
   /// @param in_array_stride the array stride of the in buffer
   /// @param in_step_mode the step mode of the in buffer
   /// @param in_attributes the in attributes
   VertexBufferLayoutDescriptor(
       uint32_t in_array_stride,
       VertexStepMode in_step_mode,
       std::vector<VertexAttributeDescriptor> in_attributes);
   /// Copy constructor
   /// @param other the struct to copy
   VertexBufferLayoutDescriptor(const VertexBufferLayoutDescriptor& other);

   /// Assignment operator
   /// @param other the struct to copy
   /// @returns this struct
   VertexBufferLayoutDescriptor& operator=(
       const VertexBufferLayoutDescriptor& other);

   ~VertexBufferLayoutDescriptor();

   /// The array stride used in the in buffer
   uint32_t array_stride = 0u;
   /// The input step mode used
   VertexStepMode step_mode = VertexStepMode::kVertex;
   /// The vertex attributes
   std::vector<VertexAttributeDescriptor> attributes;
 };

 /// Describes vertex state, which consists of many buffers containing vertex
 /// attributes
 using VertexStateDescriptor = std::vector<VertexBufferLayoutDescriptor>;

 /// Converts a program to use vertex pulling
 ///
 /// Variables which accept vertex input are var<in> with a location decoration.
 /// This transform will convert those to be assigned from storage buffers
 /// instead. The intention is to allow vertex input to rely on a storage buffer
 /// clamping pass for out of bounds reads. We bind the storage buffers as arrays
 /// of u32, so any read to byte position `p` will actually need to read position
 /// `p / 4`, since `sizeof(u32) == 4`.
 ///
 /// `VertexFormat` represents the input type of the attribute. This isn't
 /// related to the type of the variable in the shader. For example,
 /// `VertexFormat::kVec2F16` tells us that the buffer will contain `f16`
 /// elements, to be read as vec2. In the shader, a user would make a `vec2<f32>`
 /// to be able to use them. The conversion between `f16` and `f32` will need to
 /// be handled by us (using unpack functions).
 ///
 /// To be clear, there won't be types such as `f16` or `u8` anywhere in WGSL
 /// code, but these are types that the data may arrive as. We need to convert
 /// these smaller types into the base types such as `f32` and `u32` for the
 /// shader to use.
 class VertexPulling : public Castable<VertexPulling, Transform> {
  public:
   /// Configuration options for the transform
   struct Config : public Castable<Config, Data> {
     /// Constructor
     Config();

     /// Copy constructor
     Config(const Config&);

     /// Destructor
     ~Config() override;

     /// Assignment operator
     /// @returns this Config
     Config& operator=(const Config&);

     /// The entry point to add assignments into
     std::string entry_point_name;

     /// The vertex state descriptor, containing info about attributes
     VertexStateDescriptor vertex_state;

     /// The "group" we will put all our vertex buffers into (as storage buffers)
     /// Default to 4 as it is past the limits of user-accessible groups
     uint32_t pulling_group = 4u;
   };

   /// Constructor
   VertexPulling();

   /// Destructor
   ~VertexPulling() override;

  protected:
   /// Runs the transform using the CloneContext built for transforming a
   /// program. Run() is responsible for calling Clone() on the CloneContext.
   /// @param ctx the CloneContext primed with the input program and
   /// ProgramBuilder
   /// @param inputs optional extra transform-specific input data
   /// @param outputs optional extra transform-specific output data
   void Run(CloneContext& ctx, const DataMap& inputs, DataMap& outputs) override;

  private:
   Config cfg_;
 };

 }  // namespace transform
 }  // namespace tint

 #endif  // SRC_TRANSFORM_VERTEX_PULLING_H_
	// Copyright 2020 The Tint Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef SRC_TRANSFORM_VERTEX_PULLING_H_
	#define SRC_TRANSFORM_VERTEX_PULLING_H_

	#include <memory>
	#include <string>
	#include <unordered_map>
	#include <vector>

	#include "src/transform/transform.h"

	namespace tint {
	namespace transform {

	/// Describes the format of data in a vertex buffer
	enum class VertexFormat {
	kUint8x2, // uint8x2
	kUint8x4, // uint8x4
	kSint8x2, // sint8x2
	kSint8x4, // sint8x4
	kUnorm8x2, // unorm8x2
	kUnorm8x4, // unorm8x4
	kSnorm8x2, // snorm8x2
	kSnorm8x4, // snorm8x4
	kUint16x2, // uint16x2
	kUint16x4, // uint16x4
	kSint16x2, // sint16x2
	kSint16x4, // sint16x4
	kUnorm16x2, // unorm16x2
	kUnorm16x4, // unorm16x4
	kSnorm16x2, // snorm16x2
	kSnorm16x4, // snorm16x4
	kFloat16x2, // float16x2
	kFloat16x4, // float16x4
	kFloat32, // float32
	kFloat32x2, // float32x2
	kFloat32x3, // float32x3
	kFloat32x4, // float32x4
	kUint32, // uint32
	kUint32x2, // uint32x2
	kUint32x3, // uint32x3
	kUint32x4, // uint32x4
	kSint32, // sint32
	kSint32x2, // sint32x2
	kSint32x3, // sint32x3
	kSint32x4, // sint32x4

	kLastEntry = kSint32x4,
	};

	/// Describes if a vertex attributes increments with vertex index or instance
	/// index
	enum class VertexStepMode { kVertex, kInstance, kLastEntry = kInstance };

	/// Describes a vertex attribute within a buffer
	struct VertexAttributeDescriptor {
	/// The format of the attribute
	VertexFormat format;
	/// The byte offset of the attribute in the buffer
	uint32_t offset;
	/// The shader location used for the attribute
	uint32_t shader_location;
	};

	/// Describes a buffer containing multiple vertex attributes
	struct VertexBufferLayoutDescriptor {
	/// Constructor
	VertexBufferLayoutDescriptor();
	/// Constructor
	/// @param in_array_stride the array stride of the in buffer
	/// @param in_step_mode the step mode of the in buffer
	/// @param in_attributes the in attributes
	VertexBufferLayoutDescriptor(
	uint32_t in_array_stride,
	VertexStepMode in_step_mode,
	std::vector<VertexAttributeDescriptor> in_attributes);
	/// Copy constructor
	/// @param other the struct to copy
	VertexBufferLayoutDescriptor(const VertexBufferLayoutDescriptor& other);

	/// Assignment operator
	/// @param other the struct to copy
	/// @returns this struct
	VertexBufferLayoutDescriptor& operator=(
	const VertexBufferLayoutDescriptor& other);

	~VertexBufferLayoutDescriptor();

	/// The array stride used in the in buffer
	uint32_t array_stride = 0u;
	/// The input step mode used
	VertexStepMode step_mode = VertexStepMode::kVertex;
	/// The vertex attributes
	std::vector<VertexAttributeDescriptor> attributes;
	};

	/// Describes vertex state, which consists of many buffers containing vertex
	/// attributes
	using VertexStateDescriptor = std::vector<VertexBufferLayoutDescriptor>;

	/// Converts a program to use vertex pulling
	///
	/// Variables which accept vertex input are var<in> with a location decoration.
	/// This transform will convert those to be assigned from storage buffers
	/// instead. The intention is to allow vertex input to rely on a storage buffer
	/// clamping pass for out of bounds reads. We bind the storage buffers as arrays
	/// of u32, so any read to byte position `p` will actually need to read position
	/// `p / 4`, since `sizeof(u32) == 4`.
	///
	/// `VertexFormat` represents the input type of the attribute. This isn't
	/// related to the type of the variable in the shader. For example,
	/// `VertexFormat::kVec2F16` tells us that the buffer will contain `f16`
	/// elements, to be read as vec2. In the shader, a user would make a `vec2<f32>`
	/// to be able to use them. The conversion between `f16` and `f32` will need to
	/// be handled by us (using unpack functions).
	///
	/// To be clear, there won't be types such as `f16` or `u8` anywhere in WGSL
	/// code, but these are types that the data may arrive as. We need to convert
	/// these smaller types into the base types such as `f32` and `u32` for the
	/// shader to use.
	class VertexPulling : public Castable<VertexPulling, Transform> {
	public:
	/// Configuration options for the transform
	struct Config : public Castable<Config, Data> {
	/// Constructor
	Config();

	/// Copy constructor
	Config(const Config&);

	/// Destructor
	~Config() override;

	/// Assignment operator
	/// @returns this Config
	Config& operator=(const Config&);

	/// The entry point to add assignments into
	std::string entry_point_name;

	/// The vertex state descriptor, containing info about attributes
	VertexStateDescriptor vertex_state;

	/// The "group" we will put all our vertex buffers into (as storage buffers)
	/// Default to 4 as it is past the limits of user-accessible groups
	uint32_t pulling_group = 4u;
	};

	/// Constructor
	VertexPulling();

	/// Destructor
	~VertexPulling() override;

	protected:
	/// Runs the transform using the CloneContext built for transforming a
	/// program. Run() is responsible for calling Clone() on the CloneContext.
	/// @param ctx the CloneContext primed with the input program and
	/// ProgramBuilder
	/// @param inputs optional extra transform-specific input data
	/// @param outputs optional extra transform-specific output data
	void Run(CloneContext& ctx, const DataMap& inputs, DataMap& outputs) override;

	private:
	Config cfg_;
	};

	} // namespace transform
	} // namespace tint

	#endif // SRC_TRANSFORM_VERTEX_PULLING_H_