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path: root/src/gpu/effects/GrPorterDuffXferProcessor.cpp
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/*
 * Copyright 2014 Google Inc.
 *
 * Use of this source code is governed by a BSD-style license that can be
 * found in the LICENSE file.
 */

#include "effects/GrPorterDuffXferProcessor.h"

#include "GrBlend.h"
#include "GrCaps.h"
#include "GrPipeline.h"
#include "GrPipelineAnalysis.h"
#include "GrProcessor.h"
#include "GrTypes.h"
#include "GrXferProcessor.h"
#include "glsl/GrGLSLBlend.h"
#include "glsl/GrGLSLFragmentShaderBuilder.h"
#include "glsl/GrGLSLProgramDataManager.h"
#include "glsl/GrGLSLUniformHandler.h"
#include "glsl/GrGLSLXferProcessor.h"

/**
 * Wraps the shader outputs and HW blend state that comprise a Porter Duff blend mode with coverage.
 */
struct BlendFormula {
public:
    /**
     * Values the shader can write to primary and secondary outputs. These must all be modulated by
     * coverage to support mixed samples. The XP will ignore the multiplies when not using coverage.
     */
    enum OutputType {
        kNone_OutputType,        //<! 0
        kCoverage_OutputType,    //<! inputCoverage
        kModulate_OutputType,    //<! inputColor * inputCoverage
        kSAModulate_OutputType,  //<! inputColor.a * inputCoverage
        kISAModulate_OutputType, //<! (1 - inputColor.a) * inputCoverage
        kISCModulate_OutputType, //<! (1 - inputColor) * inputCoverage

        kLast_OutputType = kISCModulate_OutputType
    };

    enum Properties {
        kModifiesDst_Property              = 1,
        kUsesDstColor_Property             = 1 << 1,
        kUsesInputColor_Property           = 1 << 2,
        kCanTweakAlphaForCoverage_Property = 1 << 3,

        kLast_Property = kCanTweakAlphaForCoverage_Property
    };

    BlendFormula& operator =(const BlendFormula& other) {
        fData = other.fData;
        return *this;
    }

    bool operator ==(const BlendFormula& other) const {
        return fData == other.fData;
    }

    bool hasSecondaryOutput() const { return kNone_OutputType != fSecondaryOutputType; }
    bool modifiesDst() const { return SkToBool(fProps & kModifiesDst_Property); }
    bool usesDstColor() const { return SkToBool(fProps & kUsesDstColor_Property); }
    bool usesInputColor() const { return SkToBool(fProps & kUsesInputColor_Property); }
    bool canTweakAlphaForCoverage() const {
        return SkToBool(fProps & kCanTweakAlphaForCoverage_Property);
    }

    /**
     * Deduce the properties of a compile-time constant BlendFormula.
     */
    template<OutputType PrimaryOut, OutputType SecondaryOut,
             GrBlendEquation BlendEquation, GrBlendCoeff SrcCoeff, GrBlendCoeff DstCoeff>
    struct get_properties : std::integral_constant<Properties, static_cast<Properties>(

        (GR_BLEND_MODIFIES_DST(BlendEquation, SrcCoeff, DstCoeff) ?
            kModifiesDst_Property : 0) |

        (GR_BLEND_COEFFS_USE_DST_COLOR(SrcCoeff, DstCoeff) ?
            kUsesDstColor_Property : 0) |

        ((PrimaryOut >= kModulate_OutputType && GR_BLEND_COEFFS_USE_SRC_COLOR(SrcCoeff,DstCoeff)) ||
         (SecondaryOut >= kModulate_OutputType && GR_BLEND_COEFF_REFS_SRC2(DstCoeff)) ?
            kUsesInputColor_Property : 0) |  // We assert later that SrcCoeff doesn't ref src2.

        ((kModulate_OutputType == PrimaryOut || kNone_OutputType == PrimaryOut) &&
         kNone_OutputType == SecondaryOut &&
         GR_BLEND_CAN_TWEAK_ALPHA_FOR_COVERAGE(BlendEquation, SrcCoeff, DstCoeff) ?
            kCanTweakAlphaForCoverage_Property : 0))> {

        // The provided formula should already be optimized.
        GR_STATIC_ASSERT((kNone_OutputType == PrimaryOut) ==
                         !GR_BLEND_COEFFS_USE_SRC_COLOR(SrcCoeff, DstCoeff));
        GR_STATIC_ASSERT(!GR_BLEND_COEFF_REFS_SRC2(SrcCoeff));
        GR_STATIC_ASSERT((kNone_OutputType == SecondaryOut) ==
                         !GR_BLEND_COEFF_REFS_SRC2(DstCoeff));
        GR_STATIC_ASSERT(PrimaryOut != SecondaryOut || kNone_OutputType == PrimaryOut);
        GR_STATIC_ASSERT(kNone_OutputType != PrimaryOut || kNone_OutputType == SecondaryOut);
    };

    union {
        struct {
            // We allot the enums one more bit than they require because MSVC seems to sign-extend
            // them when the top bit is set. (This is in violation of the C++03 standard 9.6/4)
            OutputType        fPrimaryOutputType    : 4;
            OutputType        fSecondaryOutputType  : 4;
            GrBlendEquation   fBlendEquation        : 6;
            GrBlendCoeff      fSrcCoeff             : 6;
            GrBlendCoeff      fDstCoeff             : 6;
            Properties        fProps                : 32 - (4 + 4 + 6 + 6 + 6);
        };
        uint32_t fData;
    };

    GR_STATIC_ASSERT(kLast_OutputType      < (1 << 3));
    GR_STATIC_ASSERT(kLast_GrBlendEquation < (1 << 5));
    GR_STATIC_ASSERT(kLast_GrBlendCoeff    < (1 << 5));
    GR_STATIC_ASSERT(kLast_Property        < (1 << 6));
};

GR_STATIC_ASSERT(4 == sizeof(BlendFormula));

GR_MAKE_BITFIELD_OPS(BlendFormula::Properties);

/**
 * Initialize a compile-time constant BlendFormula and automatically deduce fProps.
 */
#define INIT_BLEND_FORMULA(PRIMARY_OUT, SECONDARY_OUT, BLEND_EQUATION, SRC_COEFF, DST_COEFF) \
    {{{PRIMARY_OUT, \
       SECONDARY_OUT, \
       BLEND_EQUATION, SRC_COEFF, DST_COEFF, \
       BlendFormula::get_properties<PRIMARY_OUT, SECONDARY_OUT, \
                                    BLEND_EQUATION, SRC_COEFF, DST_COEFF>::value}}}

/**
 * When there is no coverage, or the blend mode can tweak alpha for coverage, we use the standard
 * Porter Duff formula.
 */
#define COEFF_FORMULA(SRC_COEFF, DST_COEFF) \
    INIT_BLEND_FORMULA(BlendFormula::kModulate_OutputType, \
                       BlendFormula::kNone_OutputType, \
                       kAdd_GrBlendEquation, SRC_COEFF, DST_COEFF)

/**
 * Basic coeff formula similar to COEFF_FORMULA but we will make the src f*Sa. This is used in
 * LCD dst-out.
 */
#define COEFF_FORMULA_SA_MODULATE(SRC_COEFF, DST_COEFF) \
    INIT_BLEND_FORMULA(BlendFormula::kSAModulate_OutputType, \
                       BlendFormula::kNone_OutputType, \
                       kAdd_GrBlendEquation, SRC_COEFF, DST_COEFF)

/**
 * When the coeffs are (Zero, Zero), we clear the dst. This formula has its own macro so we can set
 * the primary output type to none.
 */
#define DST_CLEAR_FORMULA \
    INIT_BLEND_FORMULA(BlendFormula::kNone_OutputType, \
                       BlendFormula::kNone_OutputType, \
                       kAdd_GrBlendEquation, kZero_GrBlendCoeff, kZero_GrBlendCoeff)

/**
 * When the coeffs are (Zero, One), we don't write to the dst at all. This formula has its own macro
 * so we can set the primary output type to none.
 */
#define NO_DST_WRITE_FORMULA \
    INIT_BLEND_FORMULA(BlendFormula::kNone_OutputType, \
                       BlendFormula::kNone_OutputType, \
                       kAdd_GrBlendEquation, kZero_GrBlendCoeff, kOne_GrBlendCoeff)

/**
 * When there is coverage, the equation with f=coverage is:
 *
 *   D' = f * (S * srcCoeff + D * dstCoeff) + (1-f) * D
 *
 * This can be rewritten as:
 *
 *   D' = f * S * srcCoeff + D * (1 - [f * (1 - dstCoeff)])
 *
 * To implement this formula, we output [f * (1 - dstCoeff)] for the secondary color and replace the
 * HW dst coeff with IS2C.
 *
 * Xfer modes: dst-atop (Sa!=1)
 */
#define COVERAGE_FORMULA(ONE_MINUS_DST_COEFF_MODULATE_OUTPUT, SRC_COEFF) \
    INIT_BLEND_FORMULA(BlendFormula::kModulate_OutputType, \
                       ONE_MINUS_DST_COEFF_MODULATE_OUTPUT, \
                       kAdd_GrBlendEquation, SRC_COEFF, kIS2C_GrBlendCoeff)

/**
 * When there is coverage and the src coeff is Zero, the equation with f=coverage becomes:
 *
 *   D' = f * D * dstCoeff + (1-f) * D
 *
 * This can be rewritten as:
 *
 *   D' = D - D * [f * (1 - dstCoeff)]
 *
 * To implement this formula, we output [f * (1 - dstCoeff)] for the primary color and use a reverse
 * subtract HW blend equation with coeffs of (DC, One).
 *
 * Xfer modes: clear, dst-out (Sa=1), dst-in (Sa!=1), modulate (Sc!=1)
 */
#define COVERAGE_SRC_COEFF_ZERO_FORMULA(ONE_MINUS_DST_COEFF_MODULATE_OUTPUT) \
    INIT_BLEND_FORMULA(ONE_MINUS_DST_COEFF_MODULATE_OUTPUT, \
                       BlendFormula::kNone_OutputType, \
                       kReverseSubtract_GrBlendEquation, kDC_GrBlendCoeff, kOne_GrBlendCoeff)

/**
 * When there is coverage and the dst coeff is Zero, the equation with f=coverage becomes:
 *
 *   D' = f * S * srcCoeff + (1-f) * D
 *
 * To implement this formula, we output [f] for the secondary color and replace the HW dst coeff
 * with IS2A. (Note that we can avoid dual source blending when Sa=1 by using ISA.)
 *
 * Xfer modes (Sa!=1): src, src-in, src-out
 */
#define COVERAGE_DST_COEFF_ZERO_FORMULA(SRC_COEFF) \
    INIT_BLEND_FORMULA(BlendFormula::kModulate_OutputType, \
                       BlendFormula::kCoverage_OutputType, \
                       kAdd_GrBlendEquation, SRC_COEFF, kIS2A_GrBlendCoeff)

/**
 * This table outlines the blend formulas we will use with each xfermode, with and without coverage,
 * with and without an opaque input color. Optimization properties are deduced at compile time so we
 * can make runtime decisions quickly. RGB coverage is not supported.
 */
static const BlendFormula gBlendTable[2][2][(int)SkBlendMode::kLastCoeffMode + 1] = {

                     /*>> No coverage, input color unknown <<*/ {{

    /* clear */      DST_CLEAR_FORMULA,
    /* src */        COEFF_FORMULA(   kOne_GrBlendCoeff,    kZero_GrBlendCoeff),
    /* dst */        NO_DST_WRITE_FORMULA,
    /* src-over */   COEFF_FORMULA(   kOne_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* dst-over */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* src-in */     COEFF_FORMULA(   kDA_GrBlendCoeff,     kZero_GrBlendCoeff),
    /* dst-in */     COEFF_FORMULA(   kZero_GrBlendCoeff,   kSA_GrBlendCoeff),
    /* src-out */    COEFF_FORMULA(   kIDA_GrBlendCoeff,    kZero_GrBlendCoeff),
    /* dst-out */    COEFF_FORMULA(   kZero_GrBlendCoeff,   kISA_GrBlendCoeff),
    /* src-atop */   COEFF_FORMULA(   kDA_GrBlendCoeff,     kISA_GrBlendCoeff),
    /* dst-atop */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kSA_GrBlendCoeff),
    /* xor */        COEFF_FORMULA(   kIDA_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* plus */       COEFF_FORMULA(   kOne_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* modulate */   COEFF_FORMULA(   kZero_GrBlendCoeff,   kSC_GrBlendCoeff),
    /* screen */     COEFF_FORMULA(   kOne_GrBlendCoeff,    kISC_GrBlendCoeff),

                     }, /*>> Has coverage, input color unknown <<*/ {

    /* clear */      COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kCoverage_OutputType),
    /* src */        COVERAGE_DST_COEFF_ZERO_FORMULA(kOne_GrBlendCoeff),
    /* dst */        NO_DST_WRITE_FORMULA,
    /* src-over */   COEFF_FORMULA(   kOne_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* dst-over */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* src-in */     COVERAGE_DST_COEFF_ZERO_FORMULA(kDA_GrBlendCoeff),
    /* dst-in */     COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kISAModulate_OutputType),
    /* src-out */    COVERAGE_DST_COEFF_ZERO_FORMULA(kIDA_GrBlendCoeff),
    /* dst-out */    COEFF_FORMULA(   kZero_GrBlendCoeff,   kISA_GrBlendCoeff),
    /* src-atop */   COEFF_FORMULA(   kDA_GrBlendCoeff,     kISA_GrBlendCoeff),
    /* dst-atop */   COVERAGE_FORMULA(BlendFormula::kISAModulate_OutputType, kIDA_GrBlendCoeff),
    /* xor */        COEFF_FORMULA(   kIDA_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* plus */       COEFF_FORMULA(   kOne_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* modulate */   COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kISCModulate_OutputType),
    /* screen */     COEFF_FORMULA(   kOne_GrBlendCoeff,    kISC_GrBlendCoeff),

                     }}, /*>> No coverage, input color opaque <<*/ {{

    /* clear */      DST_CLEAR_FORMULA,
    /* src */        COEFF_FORMULA(   kOne_GrBlendCoeff,    kZero_GrBlendCoeff),
    /* dst */        NO_DST_WRITE_FORMULA,
    /* src-over */   COEFF_FORMULA(   kOne_GrBlendCoeff,    kZero_GrBlendCoeff),
    /* dst-over */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* src-in */     COEFF_FORMULA(   kDA_GrBlendCoeff,     kZero_GrBlendCoeff),
    /* dst-in */     NO_DST_WRITE_FORMULA,
    /* src-out */    COEFF_FORMULA(   kIDA_GrBlendCoeff,    kZero_GrBlendCoeff),
    /* dst-out */    DST_CLEAR_FORMULA,
    /* src-atop */   COEFF_FORMULA(   kDA_GrBlendCoeff,     kZero_GrBlendCoeff),
    /* dst-atop */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* xor */        COEFF_FORMULA(   kIDA_GrBlendCoeff,    kZero_GrBlendCoeff),
    /* plus */       COEFF_FORMULA(   kOne_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* modulate */   COEFF_FORMULA(   kZero_GrBlendCoeff,   kSC_GrBlendCoeff),
    /* screen */     COEFF_FORMULA(   kOne_GrBlendCoeff,    kISC_GrBlendCoeff),

                     }, /*>> Has coverage, input color opaque <<*/ {

    /* clear */      COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kCoverage_OutputType),
    /* src */        COEFF_FORMULA(   kOne_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* dst */        NO_DST_WRITE_FORMULA,
    /* src-over */   COEFF_FORMULA(   kOne_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* dst-over */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* src-in */     COEFF_FORMULA(   kDA_GrBlendCoeff,     kISA_GrBlendCoeff),
    /* dst-in */     NO_DST_WRITE_FORMULA,
    /* src-out */    COEFF_FORMULA(   kIDA_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* dst-out */    COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kCoverage_OutputType),
    /* src-atop */   COEFF_FORMULA(   kDA_GrBlendCoeff,     kISA_GrBlendCoeff),
    /* dst-atop */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* xor */        COEFF_FORMULA(   kIDA_GrBlendCoeff,    kISA_GrBlendCoeff),
    /* plus */       COEFF_FORMULA(   kOne_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* modulate */   COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kISCModulate_OutputType),
    /* screen */     COEFF_FORMULA(   kOne_GrBlendCoeff,    kISC_GrBlendCoeff),
}}};

static const BlendFormula gLCDBlendTable[(int)SkBlendMode::kLastCoeffMode + 1] = {
    /* clear */      COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kCoverage_OutputType),
    /* src */        COVERAGE_FORMULA(BlendFormula::kCoverage_OutputType, kOne_GrBlendCoeff),
    /* dst */        NO_DST_WRITE_FORMULA,
    /* src-over */   COVERAGE_FORMULA(BlendFormula::kSAModulate_OutputType, kOne_GrBlendCoeff),
    /* dst-over */   COEFF_FORMULA(   kIDA_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* src-in */     COVERAGE_FORMULA(BlendFormula::kCoverage_OutputType, kDA_GrBlendCoeff),
    /* dst-in */     COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kISAModulate_OutputType),
    /* src-out */    COVERAGE_FORMULA(BlendFormula::kCoverage_OutputType, kIDA_GrBlendCoeff),
    /* dst-out */    COEFF_FORMULA_SA_MODULATE(   kZero_GrBlendCoeff,   kISC_GrBlendCoeff),
    /* src-atop */   COVERAGE_FORMULA(BlendFormula::kSAModulate_OutputType, kDA_GrBlendCoeff),
    /* dst-atop */   COVERAGE_FORMULA(BlendFormula::kISAModulate_OutputType, kIDA_GrBlendCoeff),
    /* xor */        COVERAGE_FORMULA(BlendFormula::kSAModulate_OutputType, kIDA_GrBlendCoeff),
    /* plus */       COEFF_FORMULA(   kOne_GrBlendCoeff,    kOne_GrBlendCoeff),
    /* modulate */   COVERAGE_SRC_COEFF_ZERO_FORMULA(BlendFormula::kISCModulate_OutputType),
    /* screen */     COEFF_FORMULA(   kOne_GrBlendCoeff,    kISC_GrBlendCoeff),
};

static BlendFormula get_blend_formula(bool isOpaque,
                                      bool hasCoverage,
                                      bool hasMixedSamples,
                                      SkBlendMode xfermode) {
    SkASSERT((unsigned)xfermode <= (unsigned)SkBlendMode::kLastCoeffMode);
    bool conflatesCoverage = hasCoverage || hasMixedSamples;
    return gBlendTable[isOpaque][conflatesCoverage][(int)xfermode];
}

static BlendFormula get_lcd_blend_formula(SkBlendMode xfermode) {
    SkASSERT((unsigned)xfermode <= (unsigned)SkBlendMode::kLastCoeffMode);

    return gLCDBlendTable[(int)xfermode];
}

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

class PorterDuffXferProcessor : public GrXferProcessor {
public:
    PorterDuffXferProcessor(BlendFormula blendFormula) : fBlendFormula(blendFormula) {
        this->initClassID<PorterDuffXferProcessor>();
    }

    const char* name() const override { return "Porter Duff"; }

    GrGLSLXferProcessor* createGLSLInstance() const override;

    BlendFormula getBlendFormula() const { return fBlendFormula; }

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

    bool onHasSecondaryOutput() const override { return fBlendFormula.hasSecondaryOutput(); }

    void onGetBlendInfo(GrXferProcessor::BlendInfo* blendInfo) const override {
        blendInfo->fEquation = fBlendFormula.fBlendEquation;
        blendInfo->fSrcBlend = fBlendFormula.fSrcCoeff;
        blendInfo->fDstBlend = fBlendFormula.fDstCoeff;
        blendInfo->fWriteColor = fBlendFormula.modifiesDst();
    }

    bool onIsEqual(const GrXferProcessor& xpBase) const override {
        const PorterDuffXferProcessor& xp = xpBase.cast<PorterDuffXferProcessor>();
        return fBlendFormula == xp.fBlendFormula;
    }

    const BlendFormula fBlendFormula;

    typedef GrXferProcessor INHERITED;
};

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

static void append_color_output(const PorterDuffXferProcessor& xp,
                                GrGLSLXPFragmentBuilder* fragBuilder,
                                BlendFormula::OutputType outputType, const char* output,
                                const char* inColor, const char* inCoverage) {
    SkASSERT(inCoverage);
    SkASSERT(inColor);
    switch (outputType) {
        case BlendFormula::kNone_OutputType:
            fragBuilder->codeAppendf("%s = vec4(0.0);", output);
            break;
        case BlendFormula::kCoverage_OutputType:
            // We can have a coverage formula while not reading coverage if there are mixed samples.
            fragBuilder->codeAppendf("%s = %s;", output, inCoverage);
            break;
        case BlendFormula::kModulate_OutputType:
            fragBuilder->codeAppendf("%s = %s * %s;", output, inColor, inCoverage);
            break;
        case BlendFormula::kSAModulate_OutputType:
            fragBuilder->codeAppendf("%s = %s.a * %s;", output, inColor, inCoverage);
            break;
        case BlendFormula::kISAModulate_OutputType:
            fragBuilder->codeAppendf("%s = (1.0 - %s.a) * %s;", output, inColor, inCoverage);
            break;
        case BlendFormula::kISCModulate_OutputType:
            fragBuilder->codeAppendf("%s = (vec4(1.0) - %s) * %s;", output, inColor, inCoverage);
            break;
        default:
            SkFAIL("Unsupported output type.");
            break;
    }
}

class GLPorterDuffXferProcessor : public GrGLSLXferProcessor {
public:
    static void GenKey(const GrProcessor& processor, GrProcessorKeyBuilder* b) {
        const PorterDuffXferProcessor& xp = processor.cast<PorterDuffXferProcessor>();
        b->add32(xp.getBlendFormula().fPrimaryOutputType |
                 (xp.getBlendFormula().fSecondaryOutputType << 3));
        GR_STATIC_ASSERT(BlendFormula::kLast_OutputType < 8);
    }

private:
    void emitOutputsForBlendState(const EmitArgs& args) override {
        const PorterDuffXferProcessor& xp = args.fXP.cast<PorterDuffXferProcessor>();
        GrGLSLXPFragmentBuilder* fragBuilder = args.fXPFragBuilder;

        BlendFormula blendFormula = xp.getBlendFormula();
        if (blendFormula.hasSecondaryOutput()) {
            append_color_output(xp, fragBuilder, blendFormula.fSecondaryOutputType,
                                args.fOutputSecondary, args.fInputColor, args.fInputCoverage);
        }
        append_color_output(xp, fragBuilder, blendFormula.fPrimaryOutputType,
                            args.fOutputPrimary, args.fInputColor, args.fInputCoverage);
    }

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

    typedef GrGLSLXferProcessor INHERITED;
};

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

void PorterDuffXferProcessor::onGetGLSLProcessorKey(const GrShaderCaps&,
                                                    GrProcessorKeyBuilder* b) const {
    GLPorterDuffXferProcessor::GenKey(*this, b);
}

GrGLSLXferProcessor* PorterDuffXferProcessor::createGLSLInstance() const {
    return new GLPorterDuffXferProcessor;
}

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

class ShaderPDXferProcessor : public GrXferProcessor {
public:
    ShaderPDXferProcessor(const DstTexture* dstTexture,
                          bool hasMixedSamples,
                          SkBlendMode xfermode)
        : INHERITED(dstTexture, true, hasMixedSamples)
        , fXfermode(xfermode) {
        this->initClassID<ShaderPDXferProcessor>();
    }

    const char* name() const override { return "Porter Duff Shader"; }

    GrGLSLXferProcessor* createGLSLInstance() const override;

    SkBlendMode getXfermode() const { return fXfermode; }

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

    bool onIsEqual(const GrXferProcessor& xpBase) const override {
        const ShaderPDXferProcessor& xp = xpBase.cast<ShaderPDXferProcessor>();
        return fXfermode == xp.fXfermode;
    }

    const SkBlendMode fXfermode;

    typedef GrXferProcessor INHERITED;
};

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

class GLShaderPDXferProcessor : public GrGLSLXferProcessor {
public:
    static void GenKey(const GrProcessor& processor, GrProcessorKeyBuilder* b) {
        const ShaderPDXferProcessor& xp = processor.cast<ShaderPDXferProcessor>();
        b->add32((int)xp.getXfermode());
    }

private:
    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 ShaderPDXferProcessor& xp = proc.cast<ShaderPDXferProcessor>();

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

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

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

    typedef GrGLSLXferProcessor INHERITED;
};

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

void ShaderPDXferProcessor::onGetGLSLProcessorKey(const GrShaderCaps&,
                                                  GrProcessorKeyBuilder* b) const {
    GLShaderPDXferProcessor::GenKey(*this, b);
}

GrGLSLXferProcessor* ShaderPDXferProcessor::createGLSLInstance() const {
    return new GLShaderPDXferProcessor;
}

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

class PDLCDXferProcessor : public GrXferProcessor {
public:
    static GrXferProcessor* Create(SkBlendMode xfermode, const GrPipelineAnalysisColor& inputColor);

    ~PDLCDXferProcessor() override;

    const char* name() const override { return "Porter Duff LCD"; }

    GrGLSLXferProcessor* createGLSLInstance() const override;

    uint8_t alpha() const { return fAlpha; }

private:
    PDLCDXferProcessor(GrColor blendConstant, uint8_t alpha);

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

    void onGetBlendInfo(GrXferProcessor::BlendInfo* blendInfo) const override {
        blendInfo->fSrcBlend = kConstC_GrBlendCoeff;
        blendInfo->fDstBlend = kISC_GrBlendCoeff;
        blendInfo->fBlendConstant = fBlendConstant;
    }

    bool onIsEqual(const GrXferProcessor& xpBase) const override {
        const PDLCDXferProcessor& xp = xpBase.cast<PDLCDXferProcessor>();
        if (fBlendConstant != xp.fBlendConstant || fAlpha != xp.fAlpha) {
            return false;
        }
        return true;
    }

    GrColor fBlendConstant;
    uint8_t fAlpha;

    typedef GrXferProcessor INHERITED;
};

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

class GLPDLCDXferProcessor : public GrGLSLXferProcessor {
public:
    GLPDLCDXferProcessor(const GrProcessor&) : fLastAlpha(SK_MaxU32) {}

    ~GLPDLCDXferProcessor() override {}

    static void GenKey(const GrProcessor& processor, const GrShaderCaps& caps,
                       GrProcessorKeyBuilder* b) {}

private:
    void emitOutputsForBlendState(const EmitArgs& args) override {
        const char* alpha;
        fAlphaUniform = args.fUniformHandler->addUniform(kFragment_GrShaderFlag, kFloat_GrSLType,
                                                         kDefault_GrSLPrecision, "alpha", &alpha);
        GrGLSLXPFragmentBuilder* fragBuilder = args.fXPFragBuilder;
        // We want to force our primary output to be alpha * Coverage, where alpha is the alpha
        // value of the src color. We know that there are no color stages (or we wouldn't have
        // created this xp) and the r,g, and b channels of the op's input color are baked into the
        // blend constant.
        SkASSERT(args.fInputCoverage);
        fragBuilder->codeAppendf("%s = %s * %s;", args.fOutputPrimary, alpha, args.fInputCoverage);
    }

    void onSetData(const GrGLSLProgramDataManager& pdm, const GrXferProcessor& xp) override {
        uint32_t alpha = SkToU32(xp.cast<PDLCDXferProcessor>().alpha());
        if (fLastAlpha != alpha) {
            pdm.set1f(fAlphaUniform, alpha / 255.f);
            fLastAlpha = alpha;
        }
    }

    GrGLSLUniformHandler::UniformHandle fAlphaUniform;
    uint32_t fLastAlpha;
    typedef GrGLSLXferProcessor INHERITED;
};

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

PDLCDXferProcessor::PDLCDXferProcessor(GrColor blendConstant, uint8_t alpha)
    : fBlendConstant(blendConstant)
    , fAlpha(alpha) {
    this->initClassID<PDLCDXferProcessor>();
}

GrXferProcessor* PDLCDXferProcessor::Create(SkBlendMode xfermode,
                                            const GrPipelineAnalysisColor& color) {
    if (SkBlendMode::kSrcOver != xfermode) {
        return nullptr;
    }
    GrColor blendConstant;
    if (!color.isConstant(&blendConstant)) {
        return nullptr;
    }
    blendConstant = GrUnpremulColor(blendConstant);
    uint8_t alpha = GrColorUnpackA(blendConstant);
    blendConstant |= (0xff << GrColor_SHIFT_A);
    return new PDLCDXferProcessor(blendConstant, alpha);
}

PDLCDXferProcessor::~PDLCDXferProcessor() {
}

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

GrGLSLXferProcessor* PDLCDXferProcessor::createGLSLInstance() const {
    return new GLPDLCDXferProcessor(*this);
}

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

constexpr GrPorterDuffXPFactory::GrPorterDuffXPFactory(SkBlendMode xfermode)
        : fBlendMode(xfermode) {}

const GrXPFactory* GrPorterDuffXPFactory::Get(SkBlendMode blendMode) {
    SkASSERT((unsigned)blendMode <= (unsigned)SkBlendMode::kLastCoeffMode);

    // 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 GrPorterDuffXPFactory gClearPDXPF(SkBlendMode::kClear);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gSrcPDXPF(SkBlendMode::kSrc);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gDstPDXPF(SkBlendMode::kDst);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gSrcOverPDXPF(SkBlendMode::kSrcOver);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gDstOverPDXPF(SkBlendMode::kDstOver);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gSrcInPDXPF(SkBlendMode::kSrcIn);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gDstInPDXPF(SkBlendMode::kDstIn);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gSrcOutPDXPF(SkBlendMode::kSrcOut);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gDstOutPDXPF(SkBlendMode::kDstOut);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gSrcATopPDXPF(SkBlendMode::kSrcATop);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gDstATopPDXPF(SkBlendMode::kDstATop);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gXorPDXPF(SkBlendMode::kXor);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gPlusPDXPF(SkBlendMode::kPlus);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gModulatePDXPF(SkBlendMode::kModulate);
    static _CONSTEXPR_ const GrPorterDuffXPFactory gScreenPDXPF(SkBlendMode::kScreen);
#undef _CONSTEXPR_

    switch (blendMode) {
        case SkBlendMode::kClear:
            return &gClearPDXPF;
        case SkBlendMode::kSrc:
            return &gSrcPDXPF;
        case SkBlendMode::kDst:
            return &gDstPDXPF;
        case SkBlendMode::kSrcOver:
            return &gSrcOverPDXPF;
        case SkBlendMode::kDstOver:
            return &gDstOverPDXPF;
        case SkBlendMode::kSrcIn:
            return &gSrcInPDXPF;
        case SkBlendMode::kDstIn:
            return &gDstInPDXPF;
        case SkBlendMode::kSrcOut:
            return &gSrcOutPDXPF;
        case SkBlendMode::kDstOut:
            return &gDstOutPDXPF;
        case SkBlendMode::kSrcATop:
            return &gSrcATopPDXPF;
        case SkBlendMode::kDstATop:
            return &gDstATopPDXPF;
        case SkBlendMode::kXor:
            return &gXorPDXPF;
        case SkBlendMode::kPlus:
            return &gPlusPDXPF;
        case SkBlendMode::kModulate:
            return &gModulatePDXPF;
        case SkBlendMode::kScreen:
            return &gScreenPDXPF;
        default:
            SkFAIL("Unexpected blend mode.");
            return nullptr;
    }
}

GrXferProcessor* GrPorterDuffXPFactory::onCreateXferProcessor(const GrCaps& caps,
                                                              const GrPipelineAnalysisColor& color,
                                                              GrPipelineAnalysisCoverage coverage,
                                                              bool hasMixedSamples,
                                                              const DstTexture* dstTexture) const {
    BlendFormula blendFormula;
    if (coverage == GrPipelineAnalysisCoverage::kLCD) {
        if (SkBlendMode::kSrcOver == fBlendMode && color.isConstant() &&
            !caps.shaderCaps()->dualSourceBlendingSupport() &&
            !caps.shaderCaps()->dstReadInShaderSupport()) {
            // If we don't have dual source blending or in shader dst reads, we fall back to this
            // trick for rendering SrcOver LCD text instead of doing a dst copy.
            SkASSERT(!dstTexture || !dstTexture->texture());
            return PDLCDXferProcessor::Create(fBlendMode, color);
        }
        blendFormula = get_lcd_blend_formula(fBlendMode);
    } else {
        blendFormula =
                get_blend_formula(color.isOpaque(), GrPipelineAnalysisCoverage::kNone != coverage,
                                  hasMixedSamples, fBlendMode);
    }

    if (blendFormula.hasSecondaryOutput() && !caps.shaderCaps()->dualSourceBlendingSupport()) {
        return new ShaderPDXferProcessor(dstTexture, hasMixedSamples, fBlendMode);
    }

    SkASSERT(!dstTexture || !dstTexture->texture());
    return new PorterDuffXferProcessor(blendFormula);
}

static inline GrXPFactory::AnalysisProperties analysis_properties(
        const GrPipelineAnalysisColor& color, const GrPipelineAnalysisCoverage& coverage,
        const GrCaps& caps, SkBlendMode mode) {
    using AnalysisProperties = GrXPFactory::AnalysisProperties;
    AnalysisProperties props = AnalysisProperties::kNone;
    bool hasCoverage = GrPipelineAnalysisCoverage::kNone != coverage;
    auto formula = gBlendTable[color.isOpaque()][hasCoverage][(int)mode];
    if (formula.canTweakAlphaForCoverage()) {
        props |= AnalysisProperties::kCompatibleWithAlphaAsCoverage;
    }
    // With dual-source blending we never need the destination color in the shader.
    if (!caps.shaderCaps()->dualSourceBlendingSupport()) {
        // Mixed samples implicity computes a fractional coverage from sample coverage. This could
        // affect the formula used. However, we don't expect to have mixed samples without dual
        // source blending.
        SkASSERT(!caps.usesMixedSamples());
        if (GrPipelineAnalysisCoverage::kLCD == coverage) {
            // Check for special case of srcover with a known color which can be done using the
            // blend constant.
            if (SkBlendMode::kSrcOver == mode && color.isConstant()) {
                props |= AnalysisProperties::kIgnoresInputColor;
            } else {
                if (get_lcd_blend_formula(mode).hasSecondaryOutput()) {
                    props |= AnalysisProperties::kReadsDstInShader;
                }
            }
        } else if (formula.hasSecondaryOutput()) {
            props |= AnalysisProperties::kReadsDstInShader;
        }
    }
    if (!formula.modifiesDst() || !formula.usesInputColor()) {
        props |= AnalysisProperties::kIgnoresInputColor;
    }
    // Ignore the effect of coverage here for overlap stencil and cover property
    auto colorFormula = gBlendTable[color.isOpaque()][0][(int)mode];
    SkASSERT(kAdd_GrBlendEquation == colorFormula.fBlendEquation);
    if (!colorFormula.usesDstColor()) {
        props |= AnalysisProperties::kCanCombineOverlappedStencilAndCover;
    }
    return props;
}

GrXPFactory::AnalysisProperties GrPorterDuffXPFactory::analysisProperties(
        const GrPipelineAnalysisColor& color,
        const GrPipelineAnalysisCoverage& coverage,
        const GrCaps& caps) const {
    return analysis_properties(color, coverage, caps, fBlendMode);
}

GR_DEFINE_XP_FACTORY_TEST(GrPorterDuffXPFactory);

#if GR_TEST_UTILS
const GrXPFactory* GrPorterDuffXPFactory::TestGet(GrProcessorTestData* d) {
    SkBlendMode mode = SkBlendMode(d->fRandom->nextULessThan((int)SkBlendMode::kLastCoeffMode));
    return GrPorterDuffXPFactory::Get(mode);
}
#endif

void GrPorterDuffXPFactory::TestGetXPOutputTypes(const GrXferProcessor* xp,
                                                 int* outPrimary,
                                                 int* outSecondary) {
    if (!!strcmp(xp->name(), "Porter Duff")) {
        *outPrimary = *outSecondary = -1;
        return;
    }
    BlendFormula blendFormula = static_cast<const PorterDuffXferProcessor*>(xp)->getBlendFormula();
    *outPrimary = blendFormula.fPrimaryOutputType;
    *outSecondary = blendFormula.fSecondaryOutputType;
}

////////////////////////////////////////////////////////////////////////////////////////////////
// SrcOver Global functions
////////////////////////////////////////////////////////////////////////////////////////////////
const GrXferProcessor& GrPorterDuffXPFactory::SimpleSrcOverXP() {
    static BlendFormula gSrcOverBlendFormula = COEFF_FORMULA(kOne_GrBlendCoeff,
                                                             kISA_GrBlendCoeff);
    static PorterDuffXferProcessor gSrcOverXP(gSrcOverBlendFormula);
    return gSrcOverXP;
}

GrXferProcessor* GrPorterDuffXPFactory::CreateSrcOverXferProcessor(
        const GrCaps& caps,
        const GrPipelineAnalysisColor& color,
        GrPipelineAnalysisCoverage coverage,
        bool hasMixedSamples,
        const GrXferProcessor::DstTexture* dstTexture) {
    // We want to not make an xfer processor if possible. Thus for the simple case where we are not
    // doing lcd blending we will just use our global SimpleSrcOverXP. This slightly differs from
    // the general case where we convert a src-over blend that has solid coverage and an opaque
    // color to src-mode, which allows disabling of blending.
    if (coverage != GrPipelineAnalysisCoverage::kLCD) {
        // We return nullptr here, which our caller interprets as meaning "use SimpleSrcOverXP".
        // We don't simply return the address of that XP here because our caller would have to unref
        // it and since it is a global object and GrProgramElement's ref-cnting system is not thread
        // safe.
        return nullptr;
    }

    if (color.isConstant() && !caps.shaderCaps()->dualSourceBlendingSupport() &&
        !caps.shaderCaps()->dstReadInShaderSupport()) {
        // If we don't have dual source blending or in shader dst reads, we fall
        // back to this trick for rendering SrcOver LCD text instead of doing a
        // dst copy.
        SkASSERT(!dstTexture || !dstTexture->texture());
        return PDLCDXferProcessor::Create(SkBlendMode::kSrcOver, color);
    }

    BlendFormula blendFormula;
    blendFormula = get_lcd_blend_formula(SkBlendMode::kSrcOver);
    if (blendFormula.hasSecondaryOutput() && !caps.shaderCaps()->dualSourceBlendingSupport()) {
        return new ShaderPDXferProcessor(dstTexture, hasMixedSamples, SkBlendMode::kSrcOver);
    }

    SkASSERT(!dstTexture || !dstTexture->texture());
    return new PorterDuffXferProcessor(blendFormula);
}

sk_sp<GrXferProcessor> GrPorterDuffXPFactory::CreateNoCoverageXP(SkBlendMode blendmode) {
    BlendFormula formula = get_blend_formula(false, false, false, blendmode);
    return sk_make_sp<PorterDuffXferProcessor>(formula);
}

GrXPFactory::AnalysisProperties GrPorterDuffXPFactory::SrcOverAnalysisProperties(
        const GrPipelineAnalysisColor& color,
        const GrPipelineAnalysisCoverage& coverage,
        const GrCaps& caps) {
    return analysis_properties(color, coverage, caps, SkBlendMode::kSrcOver);
}