src/gpu/effects/GrCustomXfermode.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "effects/GrCustomXfermode.h"

 #include "GrCaps.h"
 #include "GrCoordTransform.h"
 #include "GrFragmentProcessor.h"
 #include "GrPipeline.h"
 #include "GrProcessor.h"
 #include "GrShaderCaps.h"
 #include "GrTexture.h"
 #include "glsl/GrGLSLBlend.h"
 #include "glsl/GrGLSLFragmentProcessor.h"
 #include "glsl/GrGLSLFragmentShaderBuilder.h"
 #include "glsl/GrGLSLProgramDataManager.h"
 #include "glsl/GrGLSLUniformHandler.h"
 #include "glsl/GrGLSLXferProcessor.h"

 bool GrCustomXfermode::IsSupportedMode(SkBlendMode mode) {
     return (int)mode  > (int)SkBlendMode::kLastCoeffMode &&
            (int)mode <= (int)SkBlendMode::kLastMode;
 }

 ///////////////////////////////////////////////////////////////////////////////
 // Static helpers
 ///////////////////////////////////////////////////////////////////////////////

 static constexpr GrBlendEquation hw_blend_equation(SkBlendMode mode) {
 // In C++14 this could be a constexpr int variable.
 #define EQ_OFFSET (kOverlay_GrBlendEquation - (int)SkBlendMode::kOverlay)
     GR_STATIC_ASSERT(kOverlay_GrBlendEquation == (int)SkBlendMode::kOverlay + EQ_OFFSET);
     GR_STATIC_ASSERT(kDarken_GrBlendEquation == (int)SkBlendMode::kDarken + EQ_OFFSET);
     GR_STATIC_ASSERT(kLighten_GrBlendEquation == (int)SkBlendMode::kLighten + EQ_OFFSET);
     GR_STATIC_ASSERT(kColorDodge_GrBlendEquation == (int)SkBlendMode::kColorDodge + EQ_OFFSET);
     GR_STATIC_ASSERT(kColorBurn_GrBlendEquation == (int)SkBlendMode::kColorBurn + EQ_OFFSET);
     GR_STATIC_ASSERT(kHardLight_GrBlendEquation == (int)SkBlendMode::kHardLight + EQ_OFFSET);
     GR_STATIC_ASSERT(kSoftLight_GrBlendEquation == (int)SkBlendMode::kSoftLight + EQ_OFFSET);
     GR_STATIC_ASSERT(kDifference_GrBlendEquation == (int)SkBlendMode::kDifference + EQ_OFFSET);
     GR_STATIC_ASSERT(kExclusion_GrBlendEquation == (int)SkBlendMode::kExclusion + EQ_OFFSET);
     GR_STATIC_ASSERT(kMultiply_GrBlendEquation == (int)SkBlendMode::kMultiply + EQ_OFFSET);
     GR_STATIC_ASSERT(kHSLHue_GrBlendEquation == (int)SkBlendMode::kHue + EQ_OFFSET);
     GR_STATIC_ASSERT(kHSLSaturation_GrBlendEquation == (int)SkBlendMode::kSaturation + EQ_OFFSET);
     GR_STATIC_ASSERT(kHSLColor_GrBlendEquation == (int)SkBlendMode::kColor + EQ_OFFSET);
     GR_STATIC_ASSERT(kHSLLuminosity_GrBlendEquation == (int)SkBlendMode::kLuminosity + EQ_OFFSET);
     GR_STATIC_ASSERT(kGrBlendEquationCnt == (int)SkBlendMode::kLastMode + 1 + EQ_OFFSET);
     return static_cast<GrBlendEquation>((int)mode + EQ_OFFSET);
 #undef EQ_OFFSET
 }

 static bool can_use_hw_blend_equation(GrBlendEquation equation, GrPipelineAnalysisCoverage coverage,
                                       const GrCaps& caps) {
     if (!caps.advancedBlendEquationSupport()) {
         return false;
     }
     if (GrPipelineAnalysisCoverage::kLCD == coverage) {
         return false; // LCD coverage must be applied after the blend equation.
     }
     if (caps.canUseAdvancedBlendEquation(equation)) {
         return false;
     }
     return true;
 }

 ///////////////////////////////////////////////////////////////////////////////
 // Xfer Processor
 ///////////////////////////////////////////////////////////////////////////////

 class CustomXP : public GrXferProcessor {
 public:
     CustomXP(SkBlendMode mode, GrBlendEquation hwBlendEquation)
         : fMode(mode),
           fHWBlendEquation(hwBlendEquation) {
         this->initClassID<CustomXP>();
     }

     CustomXP(const DstTexture* dstTexture, bool hasMixedSamples, SkBlendMode mode)
         : INHERITED(dstTexture, true, hasMixedSamples),
           fMode(mode),
           fHWBlendEquation(static_cast<GrBlendEquation>(-1)) {
         this->initClassID<CustomXP>();
     }

     const char* name() const override { return "Custom Xfermode"; }

     GrGLSLXferProcessor* createGLSLInstance() const override;

     SkBlendMode mode() const { return fMode; }
     bool hasHWBlendEquation() const { return -1 != static_cast<int>(fHWBlendEquation); }

     GrBlendEquation hwBlendEquation() const {
         SkASSERT(this->hasHWBlendEquation());
         return fHWBlendEquation;
     }

 private:
     void onGetGLSLProcessorKey(const GrShaderCaps& caps, GrProcessorKeyBuilder* b) const override;

     GrXferBarrierType onXferBarrier(const GrRenderTarget*, const GrCaps&) const override;

     void onGetBlendInfo(BlendInfo*) const override;

     bool onIsEqual(const GrXferProcessor& xpBase) const override;

     const SkBlendMode      fMode;
     const GrBlendEquation  fHWBlendEquation;

     typedef GrXferProcessor INHERITED;
 };

 ///////////////////////////////////////////////////////////////////////////////

 class GLCustomXP : public GrGLSLXferProcessor {
 public:
     GLCustomXP(const GrXferProcessor&) {}
     ~GLCustomXP() override {}

     static void GenKey(const GrXferProcessor& p, const GrShaderCaps& caps,
                        GrProcessorKeyBuilder* b) {
         const CustomXP& xp = p.cast<CustomXP>();
         uint32_t key = 0;
         if (xp.hasHWBlendEquation()) {
             SkASSERT(caps.advBlendEqInteraction() > 0);  // 0 will mean !xp.hasHWBlendEquation().
             key |= caps.advBlendEqInteraction();
             GR_STATIC_ASSERT(GrShaderCaps::kLast_AdvBlendEqInteraction < 4);
         }
         if (!xp.hasHWBlendEquation() || caps.mustEnableSpecificAdvBlendEqs()) {
             key |= (int)xp.mode() << 3;
         }
         b->add32(key);
     }

 private:
     void emitOutputsForBlendState(const EmitArgs& args) override {
         const CustomXP& xp = args.fXP.cast<CustomXP>();
         SkASSERT(xp.hasHWBlendEquation());

         GrGLSLXPFragmentBuilder* fragBuilder = args.fXPFragBuilder;
         fragBuilder->enableAdvancedBlendEquationIfNeeded(xp.hwBlendEquation());

         // Apply coverage by multiplying it into the src color before blending. Mixed samples will
         // "just work" automatically. (See onGetOptimizations())
         fragBuilder->codeAppendf("%s = %s * %s;", args.fOutputPrimary, args.fInputCoverage,
                                  args.fInputColor);
     }

     void emitBlendCodeForDstRead(GrGLSLXPFragmentBuilder* fragBuilder,
                                  GrGLSLUniformHandler* uniformHandler,
                                  const char* srcColor,
                                  const char* srcCoverage,
                                  const char* dstColor,
                                  const char* outColor,
                                  const char* outColorSecondary,
                                  const GrXferProcessor& proc) override {
         const CustomXP& xp = proc.cast<CustomXP>();
         SkASSERT(!xp.hasHWBlendEquation());

         GrGLSLBlend::AppendMode(fragBuilder, srcColor, dstColor, outColor, xp.mode());

         // Apply coverage.
         INHERITED::DefaultCoverageModulation(fragBuilder, srcCoverage, dstColor, outColor,
                                              outColorSecondary, xp);
     }

     void onSetData(const GrGLSLProgramDataManager&, const GrXferProcessor&) override {}

     typedef GrGLSLXferProcessor INHERITED;
 };

 ///////////////////////////////////////////////////////////////////////////////

 void CustomXP::onGetGLSLProcessorKey(const GrShaderCaps& caps, GrProcessorKeyBuilder* b) const {
     GLCustomXP::GenKey(*this, caps, b);
 }

 GrGLSLXferProcessor* CustomXP::createGLSLInstance() const {
     SkASSERT(this->willReadDstColor() != this->hasHWBlendEquation());
     return new GLCustomXP(*this);
 }

 bool CustomXP::onIsEqual(const GrXferProcessor& other) const {
     const CustomXP& s = other.cast<CustomXP>();
     return fMode == s.fMode && fHWBlendEquation == s.fHWBlendEquation;
 }

 GrXferBarrierType CustomXP::onXferBarrier(const GrRenderTarget* rt, const GrCaps& caps) const {
     if (this->hasHWBlendEquation() && !caps.advancedCoherentBlendEquationSupport()) {
         return kBlend_GrXferBarrierType;
     }
     return kNone_GrXferBarrierType;
 }

 void CustomXP::onGetBlendInfo(BlendInfo* blendInfo) const {
     if (this->hasHWBlendEquation()) {
         blendInfo->fEquation = this->hwBlendEquation();
     }
 }

 ///////////////////////////////////////////////////////////////////////////////

 // See the comment above GrXPFactory's definition about this warning suppression.
 #if defined(__GNUC__) || defined(__clang)
 #pragma GCC diagnostic push
 #pragma GCC diagnostic ignored "-Wnon-virtual-dtor"
 #endif
 class CustomXPFactory : public GrXPFactory {
 public:
     constexpr CustomXPFactory(SkBlendMode mode)
             : fMode(mode), fHWBlendEquation(hw_blend_equation(mode)) {}

 private:
     GrXferProcessor* onCreateXferProcessor(const GrCaps& caps,
                                            const FragmentProcessorAnalysis&,
                                            bool hasMixedSamples,
                                            const DstTexture*) const override;

     AnalysisProperties analysisProperties(const GrPipelineAnalysisColor&,
                                           const GrPipelineAnalysisCoverage&,
                                           const GrCaps&) const override;

     GR_DECLARE_XP_FACTORY_TEST;

     SkBlendMode fMode;
     GrBlendEquation fHWBlendEquation;

     typedef GrXPFactory INHERITED;
 };
 #if defined(__GNUC__) || defined(__clang)
 #pragma GCC diagnostic pop
 #endif

 GrXferProcessor* CustomXPFactory::onCreateXferProcessor(const GrCaps& caps,
                                                         const FragmentProcessorAnalysis& analysis,
                                                         bool hasMixedSamples,
                                                         const DstTexture* dstTexture) const {
     SkASSERT(GrCustomXfermode::IsSupportedMode(fMode));
     if (can_use_hw_blend_equation(fHWBlendEquation, analysis.outputCoverageType(), caps)) {
         SkASSERT(!dstTexture || !dstTexture->texture());
         return new CustomXP(fMode, fHWBlendEquation);
     }
     return new CustomXP(dstTexture, hasMixedSamples, fMode);
 }

 GrXPFactory::AnalysisProperties CustomXPFactory::analysisProperties(
         const GrPipelineAnalysisColor&, const GrPipelineAnalysisCoverage& coverage,
         const GrCaps& caps) const {
     /*
       The general SVG blend equation is defined in the spec as follows:

         Dca' = B(Sc, Dc) * Sa * Da + Y * Sca * (1-Da) + Z * Dca * (1-Sa)
         Da'  = X * Sa * Da + Y * Sa * (1-Da) + Z * Da * (1-Sa)

       (Note that Sca, Dca indicate RGB vectors that are premultiplied by alpha,
        and that B(Sc, Dc) is a mode-specific function that accepts non-multiplied
        RGB colors.)

       For every blend mode supported by this class, i.e. the "advanced" blend
       modes, X=Y=Z=1 and this equation reduces to the PDF blend equation.

       It can be shown that when X=Y=Z=1, these equations can modulate alpha for
       coverage.


       == Color ==

       We substitute Y=Z=1 and define a blend() function that calculates Dca' in
       terms of premultiplied alpha only:

         blend(Sca, Dca, Sa, Da) = {Dca : if Sa == 0,
                                    Sca : if Da == 0,
                                    B(Sca/Sa, Dca/Da) * Sa * Da + Sca * (1-Da) + Dca * (1-Sa) : if
       Sa,Da != 0}

       And for coverage modulation, we use a post blend src-over model:

         Dca'' = f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca

       (Where f is the fractional coverage.)

       Next we show that canTweakAlphaForCoverage() is true by proving the
       following relationship:

         blend(f*Sca, Dca, f*Sa, Da) == f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca

       General case (f,Sa,Da != 0):

         f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
           = f * (B(Sca/Sa, Dca/Da) * Sa * Da + Sca * (1-Da) + Dca * (1-Sa)) + (1-f) * Dca  [Sa,Da !=
       0, definition of blend()]
           = B(Sca/Sa, Dca/Da) * f*Sa * Da + f*Sca * (1-Da) + f*Dca * (1-Sa) + Dca - f*Dca
           = B(Sca/Sa, Dca/Da) * f*Sa * Da + f*Sca - f*Sca * Da + f*Dca - f*Dca * Sa + Dca - f*Dca
           = B(Sca/Sa, Dca/Da) * f*Sa * Da + f*Sca - f*Sca * Da - f*Dca * Sa + Dca
           = B(Sca/Sa, Dca/Da) * f*Sa * Da + f*Sca * (1-Da) - f*Dca * Sa + Dca
           = B(Sca/Sa, Dca/Da) * f*Sa * Da + f*Sca * (1-Da) + Dca * (1 - f*Sa)
           = B(f*Sca/f*Sa, Dca/Da) * f*Sa * Da + f*Sca * (1-Da) + Dca * (1 - f*Sa)  [f!=0]
           = blend(f*Sca, Dca, f*Sa, Da)  [definition of blend()]

       Corner cases (Sa=0, Da=0, and f=0):

         Sa=0: f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
                 = f * Dca + (1-f) * Dca  [Sa=0, definition of blend()]
                 = Dca
                 = blend(0, Dca, 0, Da)  [definition of blend()]
                 = blend(f*Sca, Dca, f*Sa, Da)  [Sa=0]

         Da=0: f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
                 = f * Sca + (1-f) * Dca  [Da=0, definition of blend()]
                 = f * Sca  [Da=0]
                 = blend(f*Sca, 0, f*Sa, 0)  [definition of blend()]
                 = blend(f*Sca, Dca, f*Sa, Da)  [Da=0]

         f=0: f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
                = Dca  [f=0]
                = blend(0, Dca, 0, Da)  [definition of blend()]
                = blend(f*Sca, Dca, f*Sa, Da)  [f=0]

       == Alpha ==

       We substitute X=Y=Z=1 and define a blend() function that calculates Da':

         blend(Sa, Da) = Sa * Da + Sa * (1-Da) + Da * (1-Sa)
                       = Sa * Da + Sa - Sa * Da + Da - Da * Sa
                       = Sa + Da - Sa * Da

       We use the same model for coverage modulation as we did with color:

         Da'' = f * blend(Sa, Da) + (1-f) * Da

       And show that canTweakAlphaForCoverage() is true by proving the following
       relationship:

         blend(f*Sa, Da) == f * blend(Sa, Da) + (1-f) * Da


         f * blend(Sa, Da) + (1-f) * Da
           = f * (Sa + Da - Sa * Da) + (1-f) * Da
           = f*Sa + f*Da - f*Sa * Da + Da - f*Da
           = f*Sa - f*Sa * Da + Da
           = f*Sa + Da - f*Sa * Da
           = blend(f*Sa, Da)
     */
     if (can_use_hw_blend_equation(fHWBlendEquation, coverage, caps)) {
         return AnalysisProperties::kCompatibleWithAlphaAsCoverage;
     }
     return AnalysisProperties::kCompatibleWithAlphaAsCoverage |
            AnalysisProperties::kReadsDstInShader;
 }

 GR_DEFINE_XP_FACTORY_TEST(CustomXPFactory);
 #if GR_TEST_UTILS
 const GrXPFactory* CustomXPFactory::TestGet(GrProcessorTestData* d) {
     int mode = d->fRandom->nextRangeU((int)SkBlendMode::kLastCoeffMode + 1,
                                       (int)SkBlendMode::kLastSeparableMode);

     return GrCustomXfermode::Get((SkBlendMode)mode);
 }
 #endif

 ///////////////////////////////////////////////////////////////////////////////

 const GrXPFactory* GrCustomXfermode::Get(SkBlendMode mode) {
     // If these objects are constructed as static constexpr by cl.exe (2015 SP2) the vtables are
     // null.
 #ifdef SK_BUILD_FOR_WIN
 #define _CONSTEXPR_
 #else
 #define _CONSTEXPR_ constexpr
 #endif
     static _CONSTEXPR_ const CustomXPFactory gOverlay(SkBlendMode::kOverlay);
     static _CONSTEXPR_ const CustomXPFactory gDarken(SkBlendMode::kDarken);
     static _CONSTEXPR_ const CustomXPFactory gLighten(SkBlendMode::kLighten);
     static _CONSTEXPR_ const CustomXPFactory gColorDodge(SkBlendMode::kColorDodge);
     static _CONSTEXPR_ const CustomXPFactory gColorBurn(SkBlendMode::kColorBurn);
     static _CONSTEXPR_ const CustomXPFactory gHardLight(SkBlendMode::kHardLight);
     static _CONSTEXPR_ const CustomXPFactory gSoftLight(SkBlendMode::kSoftLight);
     static _CONSTEXPR_ const CustomXPFactory gDifference(SkBlendMode::kDifference);
     static _CONSTEXPR_ const CustomXPFactory gExclusion(SkBlendMode::kExclusion);
     static _CONSTEXPR_ const CustomXPFactory gMultiply(SkBlendMode::kMultiply);
     static _CONSTEXPR_ const CustomXPFactory gHue(SkBlendMode::kHue);
     static _CONSTEXPR_ const CustomXPFactory gSaturation(SkBlendMode::kSaturation);
     static _CONSTEXPR_ const CustomXPFactory gColor(SkBlendMode::kColor);
     static _CONSTEXPR_ const CustomXPFactory gLuminosity(SkBlendMode::kLuminosity);
 #undef _CONSTEXPR_
     switch (mode) {
         case SkBlendMode::kOverlay:
             return &gOverlay;
         case SkBlendMode::kDarken:
             return &gDarken;
         case SkBlendMode::kLighten:
             return &gLighten;
         case SkBlendMode::kColorDodge:
             return &gColorDodge;
         case SkBlendMode::kColorBurn:
             return &gColorBurn;
         case SkBlendMode::kHardLight:
             return &gHardLight;
         case SkBlendMode::kSoftLight:
             return &gSoftLight;
         case SkBlendMode::kDifference:
             return &gDifference;
         case SkBlendMode::kExclusion:
             return &gExclusion;
         case SkBlendMode::kMultiply:
             return &gMultiply;
         case SkBlendMode::kHue:
             return &gHue;
         case SkBlendMode::kSaturation:
             return &gSaturation;
         case SkBlendMode::kColor:
             return &gColor;
         case SkBlendMode::kLuminosity:
             return &gLuminosity;
         default:
             SkASSERT(!GrCustomXfermode::IsSupportedMode(mode));
             return nullptr;
     }
 }
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "effects/GrCustomXfermode.h"

	#include "GrCaps.h"
	#include "GrCoordTransform.h"
	#include "GrFragmentProcessor.h"
	#include "GrPipeline.h"
	#include "GrProcessor.h"
	#include "GrShaderCaps.h"
	#include "GrTexture.h"
	#include "glsl/GrGLSLBlend.h"
	#include "glsl/GrGLSLFragmentProcessor.h"
	#include "glsl/GrGLSLFragmentShaderBuilder.h"
	#include "glsl/GrGLSLProgramDataManager.h"
	#include "glsl/GrGLSLUniformHandler.h"
	#include "glsl/GrGLSLXferProcessor.h"

	bool GrCustomXfermode::IsSupportedMode(SkBlendMode mode) {
	return (int)mode > (int)SkBlendMode::kLastCoeffMode &&
	(int)mode <= (int)SkBlendMode::kLastMode;
	}

	///////////////////////////////////////////////////////////////////////////////
	// Static helpers
	///////////////////////////////////////////////////////////////////////////////

	static constexpr GrBlendEquation hw_blend_equation(SkBlendMode mode) {
	// In C++14 this could be a constexpr int variable.
	#define EQ_OFFSET (kOverlay_GrBlendEquation - (int)SkBlendMode::kOverlay)
	GR_STATIC_ASSERT(kOverlay_GrBlendEquation == (int)SkBlendMode::kOverlay + EQ_OFFSET);
	GR_STATIC_ASSERT(kDarken_GrBlendEquation == (int)SkBlendMode::kDarken + EQ_OFFSET);
	GR_STATIC_ASSERT(kLighten_GrBlendEquation == (int)SkBlendMode::kLighten + EQ_OFFSET);
	GR_STATIC_ASSERT(kColorDodge_GrBlendEquation == (int)SkBlendMode::kColorDodge + EQ_OFFSET);
	GR_STATIC_ASSERT(kColorBurn_GrBlendEquation == (int)SkBlendMode::kColorBurn + EQ_OFFSET);
	GR_STATIC_ASSERT(kHardLight_GrBlendEquation == (int)SkBlendMode::kHardLight + EQ_OFFSET);
	GR_STATIC_ASSERT(kSoftLight_GrBlendEquation == (int)SkBlendMode::kSoftLight + EQ_OFFSET);
	GR_STATIC_ASSERT(kDifference_GrBlendEquation == (int)SkBlendMode::kDifference + EQ_OFFSET);
	GR_STATIC_ASSERT(kExclusion_GrBlendEquation == (int)SkBlendMode::kExclusion + EQ_OFFSET);
	GR_STATIC_ASSERT(kMultiply_GrBlendEquation == (int)SkBlendMode::kMultiply + EQ_OFFSET);
	GR_STATIC_ASSERT(kHSLHue_GrBlendEquation == (int)SkBlendMode::kHue + EQ_OFFSET);
	GR_STATIC_ASSERT(kHSLSaturation_GrBlendEquation == (int)SkBlendMode::kSaturation + EQ_OFFSET);
	GR_STATIC_ASSERT(kHSLColor_GrBlendEquation == (int)SkBlendMode::kColor + EQ_OFFSET);
	GR_STATIC_ASSERT(kHSLLuminosity_GrBlendEquation == (int)SkBlendMode::kLuminosity + EQ_OFFSET);
	GR_STATIC_ASSERT(kGrBlendEquationCnt == (int)SkBlendMode::kLastMode + 1 + EQ_OFFSET);
	return static_cast<GrBlendEquation>((int)mode + EQ_OFFSET);
	#undef EQ_OFFSET
	}

	static bool can_use_hw_blend_equation(GrBlendEquation equation, GrPipelineAnalysisCoverage coverage,
	const GrCaps& caps) {
	if (!caps.advancedBlendEquationSupport()) {
	return false;
	}
	if (GrPipelineAnalysisCoverage::kLCD == coverage) {
	return false; // LCD coverage must be applied after the blend equation.
	}
	if (caps.canUseAdvancedBlendEquation(equation)) {
	return false;
	}
	return true;
	}

	///////////////////////////////////////////////////////////////////////////////
	// Xfer Processor
	///////////////////////////////////////////////////////////////////////////////

	class CustomXP : public GrXferProcessor {
	public:
	CustomXP(SkBlendMode mode, GrBlendEquation hwBlendEquation)
	: fMode(mode),
	fHWBlendEquation(hwBlendEquation) {
	this->initClassID<CustomXP>();
	}

	CustomXP(const DstTexture* dstTexture, bool hasMixedSamples, SkBlendMode mode)
	: INHERITED(dstTexture, true, hasMixedSamples),
	fMode(mode),
	fHWBlendEquation(static_cast<GrBlendEquation>(-1)) {
	this->initClassID<CustomXP>();
	}

	const char* name() const override { return "Custom Xfermode"; }

	GrGLSLXferProcessor* createGLSLInstance() const override;

	SkBlendMode mode() const { return fMode; }
	bool hasHWBlendEquation() const { return -1 != static_cast<int>(fHWBlendEquation); }

	GrBlendEquation hwBlendEquation() const {
	SkASSERT(this->hasHWBlendEquation());
	return fHWBlendEquation;
	}

	private:
	void onGetGLSLProcessorKey(const GrShaderCaps& caps, GrProcessorKeyBuilder* b) const override;

	GrXferBarrierType onXferBarrier(const GrRenderTarget*, const GrCaps&) const override;

	void onGetBlendInfo(BlendInfo*) const override;

	bool onIsEqual(const GrXferProcessor& xpBase) const override;

	const SkBlendMode fMode;
	const GrBlendEquation fHWBlendEquation;

	typedef GrXferProcessor INHERITED;
	};

	///////////////////////////////////////////////////////////////////////////////

	class GLCustomXP : public GrGLSLXferProcessor {
	public:
	GLCustomXP(const GrXferProcessor&) {}
	~GLCustomXP() override {}

	static void GenKey(const GrXferProcessor& p, const GrShaderCaps& caps,
	GrProcessorKeyBuilder* b) {
	const CustomXP& xp = p.cast<CustomXP>();
	uint32_t key = 0;
	if (xp.hasHWBlendEquation()) {
	SkASSERT(caps.advBlendEqInteraction() > 0); // 0 will mean !xp.hasHWBlendEquation().
	key \|= caps.advBlendEqInteraction();
	GR_STATIC_ASSERT(GrShaderCaps::kLast_AdvBlendEqInteraction < 4);
	}
	if (!xp.hasHWBlendEquation() \|\| caps.mustEnableSpecificAdvBlendEqs()) {
	key \|= (int)xp.mode() << 3;
	}
	b->add32(key);
	}

	private:
	void emitOutputsForBlendState(const EmitArgs& args) override {
	const CustomXP& xp = args.fXP.cast<CustomXP>();
	SkASSERT(xp.hasHWBlendEquation());

	GrGLSLXPFragmentBuilder* fragBuilder = args.fXPFragBuilder;
	fragBuilder->enableAdvancedBlendEquationIfNeeded(xp.hwBlendEquation());

	// Apply coverage by multiplying it into the src color before blending. Mixed samples will
	// "just work" automatically. (See onGetOptimizations())
	fragBuilder->codeAppendf("%s = %s * %s;", args.fOutputPrimary, args.fInputCoverage,
	args.fInputColor);
	}

	void emitBlendCodeForDstRead(GrGLSLXPFragmentBuilder* fragBuilder,
	GrGLSLUniformHandler* uniformHandler,
	const char* srcColor,
	const char* srcCoverage,
	const char* dstColor,
	const char* outColor,
	const char* outColorSecondary,
	const GrXferProcessor& proc) override {
	const CustomXP& xp = proc.cast<CustomXP>();
	SkASSERT(!xp.hasHWBlendEquation());

	GrGLSLBlend::AppendMode(fragBuilder, srcColor, dstColor, outColor, xp.mode());

	// Apply coverage.
	INHERITED::DefaultCoverageModulation(fragBuilder, srcCoverage, dstColor, outColor,
	outColorSecondary, xp);
	}

	void onSetData(const GrGLSLProgramDataManager&, const GrXferProcessor&) override {}

	typedef GrGLSLXferProcessor INHERITED;
	};

	///////////////////////////////////////////////////////////////////////////////

	void CustomXP::onGetGLSLProcessorKey(const GrShaderCaps& caps, GrProcessorKeyBuilder* b) const {
	GLCustomXP::GenKey(*this, caps, b);
	}

	GrGLSLXferProcessor* CustomXP::createGLSLInstance() const {
	SkASSERT(this->willReadDstColor() != this->hasHWBlendEquation());
	return new GLCustomXP(*this);
	}

	bool CustomXP::onIsEqual(const GrXferProcessor& other) const {
	const CustomXP& s = other.cast<CustomXP>();
	return fMode == s.fMode && fHWBlendEquation == s.fHWBlendEquation;
	}

	GrXferBarrierType CustomXP::onXferBarrier(const GrRenderTarget* rt, const GrCaps& caps) const {
	if (this->hasHWBlendEquation() && !caps.advancedCoherentBlendEquationSupport()) {
	return kBlend_GrXferBarrierType;
	}
	return kNone_GrXferBarrierType;
	}

	void CustomXP::onGetBlendInfo(BlendInfo* blendInfo) const {
	if (this->hasHWBlendEquation()) {
	blendInfo->fEquation = this->hwBlendEquation();
	}
	}

	///////////////////////////////////////////////////////////////////////////////

	// See the comment above GrXPFactory's definition about this warning suppression.
	#if defined(__GNUC__) \|\| defined(__clang)
	#pragma GCC diagnostic push
	#pragma GCC diagnostic ignored "-Wnon-virtual-dtor"
	#endif
	class CustomXPFactory : public GrXPFactory {
	public:
	constexpr CustomXPFactory(SkBlendMode mode)
	: fMode(mode), fHWBlendEquation(hw_blend_equation(mode)) {}

	private:
	GrXferProcessor* onCreateXferProcessor(const GrCaps& caps,
	const FragmentProcessorAnalysis&,
	bool hasMixedSamples,
	const DstTexture*) const override;

	AnalysisProperties analysisProperties(const GrPipelineAnalysisColor&,
	const GrPipelineAnalysisCoverage&,
	const GrCaps&) const override;

	GR_DECLARE_XP_FACTORY_TEST;

	SkBlendMode fMode;
	GrBlendEquation fHWBlendEquation;

	typedef GrXPFactory INHERITED;
	};
	#if defined(__GNUC__) \|\| defined(__clang)
	#pragma GCC diagnostic pop
	#endif

	GrXferProcessor* CustomXPFactory::onCreateXferProcessor(const GrCaps& caps,
	const FragmentProcessorAnalysis& analysis,
	bool hasMixedSamples,
	const DstTexture* dstTexture) const {
	SkASSERT(GrCustomXfermode::IsSupportedMode(fMode));
	if (can_use_hw_blend_equation(fHWBlendEquation, analysis.outputCoverageType(), caps)) {
	SkASSERT(!dstTexture \|\| !dstTexture->texture());
	return new CustomXP(fMode, fHWBlendEquation);
	}
	return new CustomXP(dstTexture, hasMixedSamples, fMode);
	}

	GrXPFactory::AnalysisProperties CustomXPFactory::analysisProperties(
	const GrPipelineAnalysisColor&, const GrPipelineAnalysisCoverage& coverage,
	const GrCaps& caps) const {
	/*
	The general SVG blend equation is defined in the spec as follows:

	Dca' = B(Sc, Dc) * Sa * Da + Y * Sca * (1-Da) + Z * Dca * (1-Sa)
	Da' = X * Sa * Da + Y * Sa * (1-Da) + Z * Da * (1-Sa)

	(Note that Sca, Dca indicate RGB vectors that are premultiplied by alpha,
	and that B(Sc, Dc) is a mode-specific function that accepts non-multiplied
	RGB colors.)

	For every blend mode supported by this class, i.e. the "advanced" blend
	modes, X=Y=Z=1 and this equation reduces to the PDF blend equation.

	It can be shown that when X=Y=Z=1, these equations can modulate alpha for
	coverage.


	== Color ==

	We substitute Y=Z=1 and define a blend() function that calculates Dca' in
	terms of premultiplied alpha only:

	blend(Sca, Dca, Sa, Da) = {Dca : if Sa == 0,
	Sca : if Da == 0,
	B(Sca/Sa, Dca/Da) * Sa * Da + Sca * (1-Da) + Dca * (1-Sa) : if
	Sa,Da != 0}

	And for coverage modulation, we use a post blend src-over model:

	Dca'' = f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca

	(Where f is the fractional coverage.)

	Next we show that canTweakAlphaForCoverage() is true by proving the
	following relationship:

	blend(fSca, Dca, fSa, Da) == f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca

	General case (f,Sa,Da != 0):

	f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
	= f * (B(Sca/Sa, Dca/Da) * Sa * Da + Sca * (1-Da) + Dca * (1-Sa)) + (1-f) * Dca [Sa,Da !=
	0, definition of blend()]
	= B(Sca/Sa, Dca/Da) * fSa Da + fSca (1-Da) + fDca (1-Sa) + Dca - f*Dca
	= B(Sca/Sa, Dca/Da) * fSa Da + fSca - fSca * Da + fDca - fDca * Sa + Dca - f*Dca
	= B(Sca/Sa, Dca/Da) * fSa Da + fSca - fSca * Da - fDca Sa + Dca
	= B(Sca/Sa, Dca/Da) * fSa Da + fSca (1-Da) - fDca Sa + Dca
	= B(Sca/Sa, Dca/Da) * fSa Da + fSca (1-Da) + Dca * (1 - f*Sa)
	= B(fSca/fSa, Dca/Da) * fSa Da + fSca (1-Da) + Dca * (1 - f*Sa) [f!=0]
	= blend(fSca, Dca, fSa, Da) [definition of blend()]

	Corner cases (Sa=0, Da=0, and f=0):

	Sa=0: f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
	= f * Dca + (1-f) * Dca [Sa=0, definition of blend()]
	= Dca
	= blend(0, Dca, 0, Da) [definition of blend()]
	= blend(fSca, Dca, fSa, Da) [Sa=0]

	Da=0: f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
	= f * Sca + (1-f) * Dca [Da=0, definition of blend()]
	= f * Sca [Da=0]
	= blend(fSca, 0, fSa, 0) [definition of blend()]
	= blend(fSca, Dca, fSa, Da) [Da=0]

	f=0: f * blend(Sca, Dca, Sa, Da) + (1-f) * Dca
	= Dca [f=0]
	= blend(0, Dca, 0, Da) [definition of blend()]
	= blend(fSca, Dca, fSa, Da) [f=0]

	== Alpha ==

	We substitute X=Y=Z=1 and define a blend() function that calculates Da':

	blend(Sa, Da) = Sa * Da + Sa * (1-Da) + Da * (1-Sa)
	= Sa * Da + Sa - Sa * Da + Da - Da * Sa
	= Sa + Da - Sa * Da

	We use the same model for coverage modulation as we did with color:

	Da'' = f * blend(Sa, Da) + (1-f) * Da

	And show that canTweakAlphaForCoverage() is true by proving the following
	relationship:

	blend(fSa, Da) == f blend(Sa, Da) + (1-f) * Da


	f * blend(Sa, Da) + (1-f) * Da
	= f * (Sa + Da - Sa * Da) + (1-f) * Da
	= fSa + fDa - fSa Da + Da - f*Da
	= fSa - fSa * Da + Da
	= fSa + Da - fSa * Da
	= blend(f*Sa, Da)
	*/
	if (can_use_hw_blend_equation(fHWBlendEquation, coverage, caps)) {
	return AnalysisProperties::kCompatibleWithAlphaAsCoverage;
	}
	return AnalysisProperties::kCompatibleWithAlphaAsCoverage \|
	AnalysisProperties::kReadsDstInShader;
	}

	GR_DEFINE_XP_FACTORY_TEST(CustomXPFactory);
	#if GR_TEST_UTILS
	const GrXPFactory* CustomXPFactory::TestGet(GrProcessorTestData* d) {
	int mode = d->fRandom->nextRangeU((int)SkBlendMode::kLastCoeffMode + 1,
	(int)SkBlendMode::kLastSeparableMode);

	return GrCustomXfermode::Get((SkBlendMode)mode);
	}
	#endif

	///////////////////////////////////////////////////////////////////////////////

	const GrXPFactory* GrCustomXfermode::Get(SkBlendMode mode) {
	// If these objects are constructed as static constexpr by cl.exe (2015 SP2) the vtables are
	// null.
	#ifdef SK_BUILD_FOR_WIN
	#define _CONSTEXPR_
	#else
	#define _CONSTEXPR_ constexpr
	#endif
	static _CONSTEXPR_ const CustomXPFactory gOverlay(SkBlendMode::kOverlay);
	static _CONSTEXPR_ const CustomXPFactory gDarken(SkBlendMode::kDarken);
	static _CONSTEXPR_ const CustomXPFactory gLighten(SkBlendMode::kLighten);
	static _CONSTEXPR_ const CustomXPFactory gColorDodge(SkBlendMode::kColorDodge);
	static _CONSTEXPR_ const CustomXPFactory gColorBurn(SkBlendMode::kColorBurn);
	static _CONSTEXPR_ const CustomXPFactory gHardLight(SkBlendMode::kHardLight);
	static _CONSTEXPR_ const CustomXPFactory gSoftLight(SkBlendMode::kSoftLight);
	static _CONSTEXPR_ const CustomXPFactory gDifference(SkBlendMode::kDifference);
	static _CONSTEXPR_ const CustomXPFactory gExclusion(SkBlendMode::kExclusion);
	static _CONSTEXPR_ const CustomXPFactory gMultiply(SkBlendMode::kMultiply);
	static _CONSTEXPR_ const CustomXPFactory gHue(SkBlendMode::kHue);
	static _CONSTEXPR_ const CustomXPFactory gSaturation(SkBlendMode::kSaturation);
	static _CONSTEXPR_ const CustomXPFactory gColor(SkBlendMode::kColor);
	static _CONSTEXPR_ const CustomXPFactory gLuminosity(SkBlendMode::kLuminosity);
	#undef _CONSTEXPR_
	switch (mode) {
	case SkBlendMode::kOverlay:
	return &gOverlay;
	case SkBlendMode::kDarken:
	return &gDarken;
	case SkBlendMode::kLighten:
	return &gLighten;
	case SkBlendMode::kColorDodge:
	return &gColorDodge;
	case SkBlendMode::kColorBurn:
	return &gColorBurn;
	case SkBlendMode::kHardLight:
	return &gHardLight;
	case SkBlendMode::kSoftLight:
	return &gSoftLight;
	case SkBlendMode::kDifference:
	return &gDifference;
	case SkBlendMode::kExclusion:
	return &gExclusion;
	case SkBlendMode::kMultiply:
	return &gMultiply;
	case SkBlendMode::kHue:
	return &gHue;
	case SkBlendMode::kSaturation:
	return &gSaturation;
	case SkBlendMode::kColor:
	return &gColor;
	case SkBlendMode::kLuminosity:
	return &gLuminosity;
	default:
	SkASSERT(!GrCustomXfermode::IsSupportedMode(mode));
	return nullptr;
	}
	}