include/gpu/GrXferProcessor.h - platform/external/skqp - Gitiles

 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef GrXferProcessor_DEFINED
 #define GrXferProcessor_DEFINED

 #include "GrColor.h"
 #include "GrFragmentProcessor.h"
 #include "GrTypes.h"
 #include "SkXfermode.h"

 class GrProcOptInfo;

 /**
  * GrXferProcessor is responsible for implementing the xfer mode that blends the src color and dst
  * color. It does this by emitting fragment shader code and controlling the fixed-function blend
  * state. The inputs to its shader code are the final computed src color and fractional pixel
  * coverage. The GrXferProcessor's shader code writes the fragment shader output color that goes
  * into the fixed-function blend. When dual-source blending is available, it may also write a
  * seconday fragment shader output color. When allowed by the backend API, the GrXferProcessor may
  * read the destination color. The GrXferProcessor is responsible for setting the blend coefficients
  * and blend constant color.
  *
  * A GrXferProcessor is never installed directly into our draw state, but instead is created from a
  * GrXPFactory once we have finalized the state of our draw.
  */
 class GrXferProcessor : public GrFragmentProcessor {
 public:
     /**
      * Optimizations for blending / coverage that an OptDrawState should apply to itself.
      */
     enum OptFlags {
         /**
          * No optimizations needed
          */
         kNone_Opt                         = 0,
         /**
          * The draw can be skipped completely.
          */
         kSkipDraw_OptFlag                 = 0x1,
         /**
          * Clear color stages, remove color vertex attribs, and use input color
          */
         kClearColorStages_OptFlag         = 0x2,
         /**
          * Clear coverage stages, remove coverage vertex attribs, and use input coverage
          */
         kClearCoverageStages_OptFlag      = 0x4,
         /**
          * Set CoverageDrawing_StateBit
          */
         kSetCoverageDrawing_OptFlag       = 0x8,
     };

     GR_DECL_BITFIELD_OPS_FRIENDS(OptFlags);

     /**
      * Determines which optimizations (as described by the ptFlags above) can be performed by
      * the draw with this xfer processor. If this function is called, the xfer processor may change
      * its state to reflected the given blend optimizations. It will also set the output parameters,
      * color and coverage, to specific values if it decides to remove all color or coverage stages.
      * A caller who calls this function on a XP is required to honor the returned OptFlags
      * and color/coverage values for its draw.
      */
     // TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
     // TODO: remove need for colorWriteDisabled once colorWriteDisabled is its own XP.
     virtual OptFlags getOptimizations(const GrProcOptInfo& colorPOI,
                                       const GrProcOptInfo& coveragePOI,
                                       bool isCoverageDrawing,
                                       bool colorWriteDisabled,
                                       bool doesStencilWrite,
                                       GrColor* color,
                                       uint8_t* coverage) = 0;

     struct BlendInfo {
         GrBlendCoeff fSrcBlend;
         GrBlendCoeff fDstBlend;
         GrColor      fBlendConstant;
     };

     virtual void getBlendInfo(BlendInfo* blendInfo) const = 0;

     /** Will this prceossor read the destination pixel value? */
     bool willReadDstColor() const { return fWillReadDstColor; }

 protected:
     GrXferProcessor() : fWillReadDstColor(false) {}

     /**
      * If the prceossor subclass will read the destination pixel value then it must call this
      * function from its constructor. Otherwise, when its generated backend-specific prceossor class
      * attempts to generate code that reads the destination pixel it will fail.
      */
     void setWillReadDstColor() { fWillReadDstColor = true; }

 private:

     bool         fWillReadDstColor;

     typedef GrFragmentProcessor INHERITED;
 };

 GR_MAKE_BITFIELD_OPS(GrXferProcessor::OptFlags);

 /**
  * We install a GrXPFactory (XPF) early on in the pipeline before all the final draw information is
  * known (e.g. whether there is fractional pixel coverage, will coverage be 1 or 4 channel, is the
  * draw opaque, etc.). Once the state of the draw is finalized, we use the XPF along with all the
  * draw information to create a GrXferProcessor (XP) which can implement the desired blending for
  * the draw.
  *
  * Before the XP is created, the XPF is able to answer queries about what functionality the XPs it
  * creates will have. For example, can it create an XP that supports RGB coverage or will the XP
  * blend with the destination color.
  */
 class GrXPFactory : public SkRefCnt {
 public:
     virtual GrXferProcessor* createXferProcessor(const GrProcOptInfo& colorPOI,
                                                  const GrProcOptInfo& coveragePOI) const = 0;

     /**
      * This function returns true if the GrXferProcessor generated from this factory will be able to
      * correctly blend when using RGB coverage. The knownColor and knownColorFlags represent the
      * final computed color from the color stages.
      */
     virtual bool supportsRGBCoverage(GrColor knownColor, uint32_t knownColorFlags) const = 0;

     /**
      * Depending on color blend mode requested it may or may not be possible to correctly blend with
      * fractional pixel coverage generated by the fragment shader.
      *
      * This function considers the known color and coverage input into the xfer processor and
      * certain state information (isCoverageDrawing and colorWriteDisabled) to determine whether
      * coverage can be handled correctly.
      */
     // TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
     // TODO: remove need for colorWriteDisabled once colorWriteDisabled is its own XP.
     virtual bool canApplyCoverage(const GrProcOptInfo& colorPOI, const GrProcOptInfo& coveragePOI,
                                   bool isCoverageDrawing, bool colorWriteDisabled) const = 0;

     /**
      * This function returns true if the destination pixel values will be read for blending during
      * draw.
      */
     // TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
     // TODO: remove need for colorWriteDisabled once only XP can read dst.
     virtual bool willBlendWithDst(const GrProcOptInfo& colorPOI, const GrProcOptInfo& coveragePOI,
                                   bool isCoverageDrawing, bool colorWriteDisabled) const = 0;

     /**
      * Determines whether multiplying the computed per-pixel color by the pixel's fractional
      * coverage before the blend will give the correct final destination color. In general it
      * will not as coverage is applied after blending.
      */
     // TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
     virtual bool canTweakAlphaForCoverage(bool isCoverageDrawing) const = 0;

     virtual bool getOpaqueAndKnownColor(const GrProcOptInfo& colorPOI,
                                         const GrProcOptInfo& coveragePOI, GrColor* solidColor,
                                         uint32_t* solidColorKnownComponents) const = 0;

     bool isEqual(const GrXPFactory& that) const {
         if (this->classID() != that.classID()) {
             return false;
         }
         return this->onIsEqual(that);
     }

     /**
       * Helper for down-casting to a GrXPFactory subclass
       */
     template <typename T> const T& cast() const { return *static_cast<const T*>(this); }

     uint32_t classID() const { SkASSERT(kIllegalXPFClassID != fClassID); return fClassID; }

 protected:
     GrXPFactory() : fClassID(kIllegalXPFClassID) {}

     template <typename XPF_SUBCLASS> void initClassID() {
          static uint32_t kClassID = GenClassID();
          fClassID = kClassID;
     }

     uint32_t fClassID;

 private:
     virtual bool onIsEqual(const GrXPFactory&) const = 0;

     static uint32_t GenClassID() {
         // fCurrXPFactoryID has been initialized to kIllegalXPFactoryID. The
         // atomic inc returns the old value not the incremented value. So we add
         // 1 to the returned value.
         uint32_t id = static_cast<uint32_t>(sk_atomic_inc(&gCurrXPFClassID)) + 1;
         if (!id) {
             SkFAIL("This should never wrap as it should only be called once for each GrXPFactory "
                    "subclass.");
         }
         return id;
     }

     enum {
         kIllegalXPFClassID = 0,
     };
     static int32_t gCurrXPFClassID;

     typedef GrProgramElement INHERITED;
 };

 #endif
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrXferProcessor_DEFINED
	#define GrXferProcessor_DEFINED

	#include "GrColor.h"
	#include "GrFragmentProcessor.h"
	#include "GrTypes.h"
	#include "SkXfermode.h"

	class GrProcOptInfo;

	/**
	* GrXferProcessor is responsible for implementing the xfer mode that blends the src color and dst
	* color. It does this by emitting fragment shader code and controlling the fixed-function blend
	* state. The inputs to its shader code are the final computed src color and fractional pixel
	* coverage. The GrXferProcessor's shader code writes the fragment shader output color that goes
	* into the fixed-function blend. When dual-source blending is available, it may also write a
	* seconday fragment shader output color. When allowed by the backend API, the GrXferProcessor may
	* read the destination color. The GrXferProcessor is responsible for setting the blend coefficients
	* and blend constant color.
	*
	* A GrXferProcessor is never installed directly into our draw state, but instead is created from a
	* GrXPFactory once we have finalized the state of our draw.
	*/
	class GrXferProcessor : public GrFragmentProcessor {
	public:
	/**
	* Optimizations for blending / coverage that an OptDrawState should apply to itself.
	*/
	enum OptFlags {
	/**
	* No optimizations needed
	*/
	kNone_Opt = 0,
	/**
	* The draw can be skipped completely.
	*/
	kSkipDraw_OptFlag = 0x1,
	/**
	* Clear color stages, remove color vertex attribs, and use input color
	*/
	kClearColorStages_OptFlag = 0x2,
	/**
	* Clear coverage stages, remove coverage vertex attribs, and use input coverage
	*/
	kClearCoverageStages_OptFlag = 0x4,
	/**
	* Set CoverageDrawing_StateBit
	*/
	kSetCoverageDrawing_OptFlag = 0x8,
	};

	GR_DECL_BITFIELD_OPS_FRIENDS(OptFlags);

	/**
	* Determines which optimizations (as described by the ptFlags above) can be performed by
	* the draw with this xfer processor. If this function is called, the xfer processor may change
	* its state to reflected the given blend optimizations. It will also set the output parameters,
	* color and coverage, to specific values if it decides to remove all color or coverage stages.
	* A caller who calls this function on a XP is required to honor the returned OptFlags
	* and color/coverage values for its draw.
	*/
	// TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
	// TODO: remove need for colorWriteDisabled once colorWriteDisabled is its own XP.
	virtual OptFlags getOptimizations(const GrProcOptInfo& colorPOI,
	const GrProcOptInfo& coveragePOI,
	bool isCoverageDrawing,
	bool colorWriteDisabled,
	bool doesStencilWrite,
	GrColor* color,
	uint8_t* coverage) = 0;

	struct BlendInfo {
	GrBlendCoeff fSrcBlend;
	GrBlendCoeff fDstBlend;
	GrColor fBlendConstant;
	};

	virtual void getBlendInfo(BlendInfo* blendInfo) const = 0;

	/** Will this prceossor read the destination pixel value? */
	bool willReadDstColor() const { return fWillReadDstColor; }

	protected:
	GrXferProcessor() : fWillReadDstColor(false) {}

	/**
	* If the prceossor subclass will read the destination pixel value then it must call this
	* function from its constructor. Otherwise, when its generated backend-specific prceossor class
	* attempts to generate code that reads the destination pixel it will fail.
	*/
	void setWillReadDstColor() { fWillReadDstColor = true; }

	private:

	bool fWillReadDstColor;

	typedef GrFragmentProcessor INHERITED;
	};

	GR_MAKE_BITFIELD_OPS(GrXferProcessor::OptFlags);

	/**
	* We install a GrXPFactory (XPF) early on in the pipeline before all the final draw information is
	* known (e.g. whether there is fractional pixel coverage, will coverage be 1 or 4 channel, is the
	* draw opaque, etc.). Once the state of the draw is finalized, we use the XPF along with all the
	* draw information to create a GrXferProcessor (XP) which can implement the desired blending for
	* the draw.
	*
	* Before the XP is created, the XPF is able to answer queries about what functionality the XPs it
	* creates will have. For example, can it create an XP that supports RGB coverage or will the XP
	* blend with the destination color.
	*/
	class GrXPFactory : public SkRefCnt {
	public:
	virtual GrXferProcessor* createXferProcessor(const GrProcOptInfo& colorPOI,
	const GrProcOptInfo& coveragePOI) const = 0;

	/**
	* This function returns true if the GrXferProcessor generated from this factory will be able to
	* correctly blend when using RGB coverage. The knownColor and knownColorFlags represent the
	* final computed color from the color stages.
	*/
	virtual bool supportsRGBCoverage(GrColor knownColor, uint32_t knownColorFlags) const = 0;

	/**
	* Depending on color blend mode requested it may or may not be possible to correctly blend with
	* fractional pixel coverage generated by the fragment shader.
	*
	* This function considers the known color and coverage input into the xfer processor and
	* certain state information (isCoverageDrawing and colorWriteDisabled) to determine whether
	* coverage can be handled correctly.
	*/
	// TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
	// TODO: remove need for colorWriteDisabled once colorWriteDisabled is its own XP.
	virtual bool canApplyCoverage(const GrProcOptInfo& colorPOI, const GrProcOptInfo& coveragePOI,
	bool isCoverageDrawing, bool colorWriteDisabled) const = 0;

	/**
	* This function returns true if the destination pixel values will be read for blending during
	* draw.
	*/
	// TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
	// TODO: remove need for colorWriteDisabled once only XP can read dst.
	virtual bool willBlendWithDst(const GrProcOptInfo& colorPOI, const GrProcOptInfo& coveragePOI,
	bool isCoverageDrawing, bool colorWriteDisabled) const = 0;

	/**
	* Determines whether multiplying the computed per-pixel color by the pixel's fractional
	* coverage before the blend will give the correct final destination color. In general it
	* will not as coverage is applied after blending.
	*/
	// TODO: remove need for isCoverageDrawing once coverageDrawing is its own XP.
	virtual bool canTweakAlphaForCoverage(bool isCoverageDrawing) const = 0;

	virtual bool getOpaqueAndKnownColor(const GrProcOptInfo& colorPOI,
	const GrProcOptInfo& coveragePOI, GrColor* solidColor,
	uint32_t* solidColorKnownComponents) const = 0;

	bool isEqual(const GrXPFactory& that) const {
	if (this->classID() != that.classID()) {
	return false;
	}
	return this->onIsEqual(that);
	}

	/**
	* Helper for down-casting to a GrXPFactory subclass
	*/
	template <typename T> const T& cast() const { return static_cast<const T>(this); }

	uint32_t classID() const { SkASSERT(kIllegalXPFClassID != fClassID); return fClassID; }

	protected:
	GrXPFactory() : fClassID(kIllegalXPFClassID) {}

	template <typename XPF_SUBCLASS> void initClassID() {
	static uint32_t kClassID = GenClassID();
	fClassID = kClassID;
	}

	uint32_t fClassID;

	private:
	virtual bool onIsEqual(const GrXPFactory&) const = 0;

	static uint32_t GenClassID() {
	// fCurrXPFactoryID has been initialized to kIllegalXPFactoryID. The
	// atomic inc returns the old value not the incremented value. So we add
	// 1 to the returned value.
	uint32_t id = static_cast<uint32_t>(sk_atomic_inc(&gCurrXPFClassID)) + 1;
	if (!id) {
	SkFAIL("This should never wrap as it should only be called once for each GrXPFactory "
	"subclass.");
	}
	return id;
	}

	enum {
	kIllegalXPFClassID = 0,
	};
	static int32_t gCurrXPFClassID;

	typedef GrProgramElement INHERITED;
	};

	#endif