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


 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */


 #ifndef GrPaint_DEFINED
 #define GrPaint_DEFINED

 #include "GrColor.h"
 #include "GrFragmentProcessor.h"
 #include "SkBlendMode.h"
 #include "SkRefCnt.h"
 #include "SkRegion.h"
 #include "SkTLazy.h"

 class GrTextureProxy;
 class GrXPFactory;

 /**
  * The paint describes how color and coverage are computed at each pixel by GrContext draw
  * functions and the how color is blended with the destination pixel.
  *
  * The paint allows installation of custom color and coverage stages. New types of stages are
  * created by subclassing GrProcessor.
  *
  * The primitive color computation starts with the color specified by setColor(). This color is the
  * input to the first color stage. Each color stage feeds its output to the next color stage.
  *
  * Fractional pixel coverage follows a similar flow. The GrGeometryProcessor (specified elsewhere)
  * provides the initial coverage which is passed to the first coverage fragment processor, which
  * feeds its output to next coverage fragment processor.
  *
  * setXPFactory is used to control blending between the output color and dest. It also implements
  * the application of fractional coverage from the coverage pipeline.
  */
 class GrPaint {
 public:
     GrPaint() = default;
     ~GrPaint() = default;

     static GrPaint Clone(const GrPaint& src) { return GrPaint(src); }

     /**
      * The initial color of the drawn primitive. Defaults to solid white.
      */
     void setColor4f(const GrColor4f& color) { fColor = color; }
     const GrColor4f& getColor4f() const { return fColor; }

     /**
      * Legacy getter, until all code handles 4f directly.
      */
     GrColor getColor() const { return fColor.toGrColor(); }

     void setXPFactory(const GrXPFactory* xpFactory) {
         fXPFactory = xpFactory;
         fTrivial &= !SkToBool(xpFactory);
     }

     void setPorterDuffXPFactory(SkBlendMode mode);

     void setCoverageSetOpXPFactory(SkRegion::Op, bool invertCoverage = false);

     /**
      * Appends an additional color processor to the color computation.
      */
     void addColorFragmentProcessor(std::unique_ptr<GrFragmentProcessor> fp) {
         SkASSERT(fp);
         fColorFragmentProcessors.push_back(std::move(fp));
         fTrivial = false;
     }

     /**
      * Appends an additional coverage processor to the coverage computation.
      */
     void addCoverageFragmentProcessor(std::unique_ptr<GrFragmentProcessor> fp) {
         SkASSERT(fp);
         fCoverageFragmentProcessors.push_back(std::move(fp));
         fTrivial = false;
     }

     /**
      * Helpers for adding color or coverage effects that sample a texture. The matrix is applied
      * to the src space position to compute texture coordinates.
      */
     void addColorTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&);
     void addColorTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&, const GrSamplerState&);

     void addCoverageTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&);
     void addCoverageTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&, const GrSamplerState&);

     int numColorFragmentProcessors() const { return fColorFragmentProcessors.count(); }
     int numCoverageFragmentProcessors() const { return fCoverageFragmentProcessors.count(); }
     int numTotalFragmentProcessors() const { return this->numColorFragmentProcessors() +
                                               this->numCoverageFragmentProcessors(); }

     const GrXPFactory* getXPFactory() const { return fXPFactory; }

     GrFragmentProcessor* getColorFragmentProcessor(int i) const {
         return fColorFragmentProcessors[i].get();
     }
     GrFragmentProcessor* getCoverageFragmentProcessor(int i) const {
         return fCoverageFragmentProcessors[i].get();
     }

     /**
      * Returns true if the paint's output color will be constant after blending. If the result is
      * true, constantColor will be updated to contain the constant color. Note that we can conflate
      * coverage and color, so the actual values written to pixels with partial coverage may still
      * not seem constant, even if this function returns true.
      */
     bool isConstantBlendedColor(GrColor* constantColor) const;

     /**
      * A trivial paint is one that uses src-over and has no fragment processors.
      * It may have variable sRGB settings.
      **/
     bool isTrivial() const { return fTrivial; }

 private:
     // Since paint copying is expensive if there are fragment processors, we require going through
     // the Clone() method.
     GrPaint(const GrPaint&);
     GrPaint& operator=(const GrPaint&) = delete;

     friend class GrProcessorSet;

     const GrXPFactory* fXPFactory = nullptr;
     SkSTArray<4, std::unique_ptr<GrFragmentProcessor>> fColorFragmentProcessors;
     SkSTArray<2, std::unique_ptr<GrFragmentProcessor>> fCoverageFragmentProcessors;
     bool fTrivial = true;
     GrColor4f fColor = GrColor4f::OpaqueWhite();
 };

 #endif

	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/


	#ifndef GrPaint_DEFINED
	#define GrPaint_DEFINED

	#include "GrColor.h"
	#include "GrFragmentProcessor.h"
	#include "SkBlendMode.h"
	#include "SkRefCnt.h"
	#include "SkRegion.h"
	#include "SkTLazy.h"

	class GrTextureProxy;
	class GrXPFactory;

	/**
	* The paint describes how color and coverage are computed at each pixel by GrContext draw
	* functions and the how color is blended with the destination pixel.
	*
	* The paint allows installation of custom color and coverage stages. New types of stages are
	* created by subclassing GrProcessor.
	*
	* The primitive color computation starts with the color specified by setColor(). This color is the
	* input to the first color stage. Each color stage feeds its output to the next color stage.
	*
	* Fractional pixel coverage follows a similar flow. The GrGeometryProcessor (specified elsewhere)
	* provides the initial coverage which is passed to the first coverage fragment processor, which
	* feeds its output to next coverage fragment processor.
	*
	* setXPFactory is used to control blending between the output color and dest. It also implements
	* the application of fractional coverage from the coverage pipeline.
	*/
	class GrPaint {
	public:
	GrPaint() = default;
	~GrPaint() = default;

	static GrPaint Clone(const GrPaint& src) { return GrPaint(src); }

	/**
	* The initial color of the drawn primitive. Defaults to solid white.
	*/
	void setColor4f(const GrColor4f& color) { fColor = color; }
	const GrColor4f& getColor4f() const { return fColor; }

	/**
	* Legacy getter, until all code handles 4f directly.
	*/
	GrColor getColor() const { return fColor.toGrColor(); }

	void setXPFactory(const GrXPFactory* xpFactory) {
	fXPFactory = xpFactory;
	fTrivial &= !SkToBool(xpFactory);
	}

	void setPorterDuffXPFactory(SkBlendMode mode);

	void setCoverageSetOpXPFactory(SkRegion::Op, bool invertCoverage = false);

	/**
	* Appends an additional color processor to the color computation.
	*/
	void addColorFragmentProcessor(std::unique_ptr<GrFragmentProcessor> fp) {
	SkASSERT(fp);
	fColorFragmentProcessors.push_back(std::move(fp));
	fTrivial = false;
	}

	/**
	* Appends an additional coverage processor to the coverage computation.
	*/
	void addCoverageFragmentProcessor(std::unique_ptr<GrFragmentProcessor> fp) {
	SkASSERT(fp);
	fCoverageFragmentProcessors.push_back(std::move(fp));
	fTrivial = false;
	}

	/**
	* Helpers for adding color or coverage effects that sample a texture. The matrix is applied
	* to the src space position to compute texture coordinates.
	*/
	void addColorTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&);
	void addColorTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&, const GrSamplerState&);

	void addCoverageTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&);
	void addCoverageTextureProcessor(sk_sp<GrTextureProxy>, const SkMatrix&, const GrSamplerState&);

	int numColorFragmentProcessors() const { return fColorFragmentProcessors.count(); }
	int numCoverageFragmentProcessors() const { return fCoverageFragmentProcessors.count(); }
	int numTotalFragmentProcessors() const { return this->numColorFragmentProcessors() +
	this->numCoverageFragmentProcessors(); }

	const GrXPFactory* getXPFactory() const { return fXPFactory; }

	GrFragmentProcessor* getColorFragmentProcessor(int i) const {
	return fColorFragmentProcessors[i].get();
	}
	GrFragmentProcessor* getCoverageFragmentProcessor(int i) const {
	return fCoverageFragmentProcessors[i].get();
	}

	/**
	* Returns true if the paint's output color will be constant after blending. If the result is
	* true, constantColor will be updated to contain the constant color. Note that we can conflate
	* coverage and color, so the actual values written to pixels with partial coverage may still
	* not seem constant, even if this function returns true.
	*/
	bool isConstantBlendedColor(GrColor* constantColor) const;

	/**
	* A trivial paint is one that uses src-over and has no fragment processors.
	* It may have variable sRGB settings.
	**/
	bool isTrivial() const { return fTrivial; }

	private:
	// Since paint copying is expensive if there are fragment processors, we require going through
	// the Clone() method.
	GrPaint(const GrPaint&);
	GrPaint& operator=(const GrPaint&) = delete;

	friend class GrProcessorSet;

	const GrXPFactory* fXPFactory = nullptr;
	SkSTArray<4, std::unique_ptr<GrFragmentProcessor>> fColorFragmentProcessors;
	SkSTArray<2, std::unique_ptr<GrFragmentProcessor>> fCoverageFragmentProcessors;
	bool fTrivial = true;
	GrColor4f fColor = GrColor4f::OpaqueWhite();
	};

	#endif