src/gpu/GrPrimitiveProcessor.h - platform/external/skia - Gitiles

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrPrimitiveProcessor_DEFINED
 #define GrPrimitiveProcessor_DEFINED

 #include "GrColor.h"
 #include "GrProcessor.h"
 #include "GrShaderVar.h"

 /*
  * The GrPrimitiveProcessor represents some kind of geometric primitive.  This includes the shape
  * of the primitive and the inherent color of the primitive.  The GrPrimitiveProcessor is
  * responsible for providing a color and coverage input into the Ganesh rendering pipeline.  Through
  * optimization, Ganesh may decide a different color, no color, and / or no coverage are required
  * from the GrPrimitiveProcessor, so the GrPrimitiveProcessor must be able to support this
  * functionality.
  *
  * There are two feedback loops between the GrFragmentProcessors, the GrXferProcessor, and the
  * GrPrimitiveProcessor. These loops run on the CPU and to determine known properties of the final
  * color and coverage inputs to the GrXferProcessor in order to perform optimizations that preserve
  * correctness. The GrDrawOp seeds these loops with initial color and coverage, in its
  * getProcessorAnalysisInputs implementation. These seed values are processed by the
  * subsequent
  * stages of the rendering pipeline and the output is then fed back into the GrDrawOp in
  * the applyPipelineOptimizations call, where the op can use the information to inform decisions
  * about GrPrimitiveProcessor creation.
  */

 class GrGLSLPrimitiveProcessor;

 /*
  * GrPrimitiveProcessor defines an interface which all subclasses must implement.  All
  * GrPrimitiveProcessors must proivide seed color and coverage for the Ganesh color / coverage
  * pipelines, and they must provide some notion of equality
  */
 class GrPrimitiveProcessor : public GrResourceIOProcessor, public GrProgramElement {
 public:
     class Attribute {
     public:
         enum class InputRate : bool {
             kPerVertex,
             kPerInstance
         };

         constexpr Attribute() = default;
         constexpr Attribute(const char* name, GrVertexAttribType type, int offset, InputRate rate)
                 : fName(name), fType(type), fOffsetInRecord(offset), fInputRate(rate) {}

         bool isInitialized() const { return SkToBool(fName); }

         const char* name() const { return fName; }
         GrVertexAttribType type() const { return fType; }
         int offsetInRecord() const { return fOffsetInRecord; }
         InputRate inputRate() const { return fInputRate; }

         GrShaderVar asShaderVar() const {
             return {fName, GrVertexAttribTypeToSLType(fType), GrShaderVar::kIn_TypeModifier};
         }

     private:
         const char* fName = nullptr;
         GrVertexAttribType fType = kFloat_GrVertexAttribType;
         int fOffsetInRecord = 0;
         InputRate fInputRate = InputRate::kPerVertex;
     };

     GrPrimitiveProcessor(ClassID classID)
     : GrResourceIOProcessor(classID) {}

     int numAttribs() const { return fAttribs.count(); }
     const Attribute& getAttrib(int index) const { return fAttribs[index]; }

     bool hasVertexAttribs() const { return SkToBool(fVertexStride); }
     bool hasInstanceAttribs() const { return SkToBool(fInstanceStride); }

     /**
      * These return the strides of the vertex and instance buffers. Attributes are expected to be
      * laid out interleaved in their corresponding buffer (vertex or instance). fOffsetInRecord
      * indicates an attribute's location in bytes relative to the first attribute. (These are padded
      * to the nearest 4 bytes for performance reasons.)
      *
      * A common practice is to populate the buffer's memory using an implicit array of structs. In
      * this case, it is best to assert:
      *
      *     stride == sizeof(struct) and
      *     offsetof(struct, field[i]) == attrib[i].fOffsetInRecord
      *
      * NOTE: for instanced draws the vertex buffer has a single record that each instance reuses.
      */
     int getVertexStride() const { return fVertexStride; }
     int getInstanceStride() const { return fInstanceStride; }

     // Only the GrGeometryProcessor subclass actually has a geo shader or vertex attributes, but
     // we put these calls on the base class to prevent having to cast
     virtual bool willUseGeoShader() const = 0;

     /**
      * Computes a transformKey from an array of coord transforms. Will only look at the first
      * <numCoords> transforms in the array.
      *
      * TODO: A better name for this function  would be "compute" instead of "get".
      */
     uint32_t getTransformKey(const SkTArray<const GrCoordTransform*, true>& coords,
                              int numCoords) const;

     /**
      * Sets a unique key on the GrProcessorKeyBuilder that is directly associated with this geometry
      * processor's GL backend implementation.
      *
      * TODO: A better name for this function  would be "compute" instead of "get".
      */
     virtual void getGLSLProcessorKey(const GrShaderCaps&, GrProcessorKeyBuilder*) const = 0;


     /** Returns a new instance of the appropriate *GL* implementation class
         for the given GrProcessor; caller is responsible for deleting
         the object. */
     virtual GrGLSLPrimitiveProcessor* createGLSLInstance(const GrShaderCaps&) const = 0;

     virtual bool isPathRendering() const { return false; }

     /**
      * If non-null, overrides the dest color returned by GrGLSLFragmentShaderBuilder::dstColor().
      */
     virtual const char* getDestColorOverride() const { return nullptr; }

     virtual float getSampleShading() const {
         return 0.0;
     }

 protected:
     /**
      * Subclasses call these from their constructor to register vertex and instance attributes.
      */
     const Attribute& addVertexAttrib(const char* name, GrVertexAttribType type) {
         fAttribs.push_back() = {name, type, fVertexStride, Attribute::InputRate::kPerVertex};
         fVertexStride += static_cast<int>(SkAlign4(GrVertexAttribTypeSize(type)));
         return fAttribs.back();
     }
     const Attribute& addInstanceAttrib(const char* name, GrVertexAttribType type) {
         fAttribs.push_back() = {name, type, fInstanceStride, Attribute::InputRate::kPerInstance};
         fInstanceStride += static_cast<int>(SkAlign4(GrVertexAttribTypeSize(type)));
         return fAttribs.back();
     }

 private:
     void addPendingIOs() const override { GrResourceIOProcessor::addPendingIOs(); }
     void removeRefs() const override { GrResourceIOProcessor::removeRefs(); }
     void pendingIOComplete() const override { GrResourceIOProcessor::pendingIOComplete(); }
     void notifyRefCntIsZero() const final {}

     SkSTArray<8, Attribute> fAttribs;
     int fVertexStride = 0;
     int fInstanceStride = 0;

     typedef GrProcessor INHERITED;
 };

 #endif
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrPrimitiveProcessor_DEFINED
	#define GrPrimitiveProcessor_DEFINED

	#include "GrColor.h"
	#include "GrProcessor.h"
	#include "GrShaderVar.h"

	/*
	* The GrPrimitiveProcessor represents some kind of geometric primitive. This includes the shape
	* of the primitive and the inherent color of the primitive. The GrPrimitiveProcessor is
	* responsible for providing a color and coverage input into the Ganesh rendering pipeline. Through
	* optimization, Ganesh may decide a different color, no color, and / or no coverage are required
	* from the GrPrimitiveProcessor, so the GrPrimitiveProcessor must be able to support this
	* functionality.
	*
	* There are two feedback loops between the GrFragmentProcessors, the GrXferProcessor, and the
	* GrPrimitiveProcessor. These loops run on the CPU and to determine known properties of the final
	* color and coverage inputs to the GrXferProcessor in order to perform optimizations that preserve
	* correctness. The GrDrawOp seeds these loops with initial color and coverage, in its
	* getProcessorAnalysisInputs implementation. These seed values are processed by the
	* subsequent
	* stages of the rendering pipeline and the output is then fed back into the GrDrawOp in
	* the applyPipelineOptimizations call, where the op can use the information to inform decisions
	* about GrPrimitiveProcessor creation.
	*/

	class GrGLSLPrimitiveProcessor;

	/*
	* GrPrimitiveProcessor defines an interface which all subclasses must implement. All
	* GrPrimitiveProcessors must proivide seed color and coverage for the Ganesh color / coverage
	* pipelines, and they must provide some notion of equality
	*/
	class GrPrimitiveProcessor : public GrResourceIOProcessor, public GrProgramElement {
	public:
	class Attribute {
	public:
	enum class InputRate : bool {
	kPerVertex,
	kPerInstance
	};

	constexpr Attribute() = default;
	constexpr Attribute(const char* name, GrVertexAttribType type, int offset, InputRate rate)
	: fName(name), fType(type), fOffsetInRecord(offset), fInputRate(rate) {}

	bool isInitialized() const { return SkToBool(fName); }

	const char* name() const { return fName; }
	GrVertexAttribType type() const { return fType; }
	int offsetInRecord() const { return fOffsetInRecord; }
	InputRate inputRate() const { return fInputRate; }

	GrShaderVar asShaderVar() const {
	return {fName, GrVertexAttribTypeToSLType(fType), GrShaderVar::kIn_TypeModifier};
	}

	private:
	const char* fName = nullptr;
	GrVertexAttribType fType = kFloat_GrVertexAttribType;
	int fOffsetInRecord = 0;
	InputRate fInputRate = InputRate::kPerVertex;
	};

	GrPrimitiveProcessor(ClassID classID)
	: GrResourceIOProcessor(classID) {}

	int numAttribs() const { return fAttribs.count(); }
	const Attribute& getAttrib(int index) const { return fAttribs[index]; }

	bool hasVertexAttribs() const { return SkToBool(fVertexStride); }
	bool hasInstanceAttribs() const { return SkToBool(fInstanceStride); }

	/**
	* These return the strides of the vertex and instance buffers. Attributes are expected to be
	* laid out interleaved in their corresponding buffer (vertex or instance). fOffsetInRecord
	* indicates an attribute's location in bytes relative to the first attribute. (These are padded
	* to the nearest 4 bytes for performance reasons.)
	*
	* A common practice is to populate the buffer's memory using an implicit array of structs. In
	* this case, it is best to assert:
	*
	* stride == sizeof(struct) and
	* offsetof(struct, field[i]) == attrib[i].fOffsetInRecord
	*
	* NOTE: for instanced draws the vertex buffer has a single record that each instance reuses.
	*/
	int getVertexStride() const { return fVertexStride; }
	int getInstanceStride() const { return fInstanceStride; }

	// Only the GrGeometryProcessor subclass actually has a geo shader or vertex attributes, but
	// we put these calls on the base class to prevent having to cast
	virtual bool willUseGeoShader() const = 0;

	/**
	* Computes a transformKey from an array of coord transforms. Will only look at the first
	* <numCoords> transforms in the array.
	*
	* TODO: A better name for this function would be "compute" instead of "get".
	*/
	uint32_t getTransformKey(const SkTArray<const GrCoordTransform*, true>& coords,
	int numCoords) const;

	/**
	* Sets a unique key on the GrProcessorKeyBuilder that is directly associated with this geometry
	* processor's GL backend implementation.
	*
	* TODO: A better name for this function would be "compute" instead of "get".
	*/
	virtual void getGLSLProcessorKey(const GrShaderCaps&, GrProcessorKeyBuilder*) const = 0;


	/** Returns a new instance of the appropriate GL implementation class
	for the given GrProcessor; caller is responsible for deleting
	the object. */
	virtual GrGLSLPrimitiveProcessor* createGLSLInstance(const GrShaderCaps&) const = 0;

	virtual bool isPathRendering() const { return false; }

	/**
	* If non-null, overrides the dest color returned by GrGLSLFragmentShaderBuilder::dstColor().
	*/
	virtual const char* getDestColorOverride() const { return nullptr; }

	virtual float getSampleShading() const {
	return 0.0;
	}

	protected:
	/**
	* Subclasses call these from their constructor to register vertex and instance attributes.
	*/
	const Attribute& addVertexAttrib(const char* name, GrVertexAttribType type) {
	fAttribs.push_back() = {name, type, fVertexStride, Attribute::InputRate::kPerVertex};
	fVertexStride += static_cast<int>(SkAlign4(GrVertexAttribTypeSize(type)));
	return fAttribs.back();
	}
	const Attribute& addInstanceAttrib(const char* name, GrVertexAttribType type) {
	fAttribs.push_back() = {name, type, fInstanceStride, Attribute::InputRate::kPerInstance};
	fInstanceStride += static_cast<int>(SkAlign4(GrVertexAttribTypeSize(type)));
	return fAttribs.back();
	}

	private:
	void addPendingIOs() const override { GrResourceIOProcessor::addPendingIOs(); }
	void removeRefs() const override { GrResourceIOProcessor::removeRefs(); }
	void pendingIOComplete() const override { GrResourceIOProcessor::pendingIOComplete(); }
	void notifyRefCntIsZero() const final {}

	SkSTArray<8, Attribute> fAttribs;
	int fVertexStride = 0;
	int fInstanceStride = 0;

	typedef GrProcessor INHERITED;
	};

	#endif