src/third_party/skia/src/gpu/glsl/GrGLSLFragmentShaderBuilder.cpp - cobalt - Git at Google

 /*
  * 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 "GrGLSLFragmentShaderBuilder.h"
 #include "GrRenderTarget.h"
 #include "GrRenderTargetPriv.h"
 #include "GrShaderCaps.h"
 #include "gl/GrGLGpu.h"
 #include "glsl/GrGLSLProgramBuilder.h"
 #include "glsl/GrGLSLUniformHandler.h"
 #include "glsl/GrGLSLVarying.h"
 #include "../private/GrGLSL.h"

 const char* GrGLSLFragmentShaderBuilder::kDstColorName = "_dstColor";

 static const char* sample_offset_array_name(GrGLSLFPFragmentBuilder::Coordinates coords) {
     static const char* kArrayNames[] = {
         "deviceSpaceSampleOffsets",
         "windowSpaceSampleOffsets"
     };
     return kArrayNames[coords];

     GR_STATIC_ASSERT(0 == GrGLSLFPFragmentBuilder::kSkiaDevice_Coordinates);
     GR_STATIC_ASSERT(1 == GrGLSLFPFragmentBuilder::kGLSLWindow_Coordinates);
     GR_STATIC_ASSERT(SK_ARRAY_COUNT(kArrayNames) == GrGLSLFPFragmentBuilder::kLast_Coordinates + 1);
 }

 static const char* specific_layout_qualifier_name(GrBlendEquation equation) {
     SkASSERT(GrBlendEquationIsAdvanced(equation));

     static const char* kLayoutQualifierNames[] = {
         "blend_support_screen",
         "blend_support_overlay",
         "blend_support_darken",
         "blend_support_lighten",
         "blend_support_colordodge",
         "blend_support_colorburn",
         "blend_support_hardlight",
         "blend_support_softlight",
         "blend_support_difference",
         "blend_support_exclusion",
         "blend_support_multiply",
         "blend_support_hsl_hue",
         "blend_support_hsl_saturation",
         "blend_support_hsl_color",
         "blend_support_hsl_luminosity"
     };
     return kLayoutQualifierNames[equation - kFirstAdvancedGrBlendEquation];

     GR_STATIC_ASSERT(0 == kScreen_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(1 == kOverlay_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(2 == kDarken_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(3 == kLighten_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(4 == kColorDodge_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(5 == kColorBurn_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(6 == kHardLight_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(7 == kSoftLight_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(8 == kDifference_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(9 == kExclusion_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(10 == kMultiply_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(11 == kHSLHue_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(12 == kHSLSaturation_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(13 == kHSLColor_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(14 == kHSLLuminosity_GrBlendEquation - kFirstAdvancedGrBlendEquation);
     GR_STATIC_ASSERT(SK_ARRAY_COUNT(kLayoutQualifierNames) ==
                      kGrBlendEquationCnt - kFirstAdvancedGrBlendEquation);
 }

 uint8_t GrGLSLFragmentShaderBuilder::KeyForSurfaceOrigin(GrSurfaceOrigin origin) {
     SkASSERT(kTopLeft_GrSurfaceOrigin == origin || kBottomLeft_GrSurfaceOrigin == origin);
     return origin;

     GR_STATIC_ASSERT(1 == kTopLeft_GrSurfaceOrigin);
     GR_STATIC_ASSERT(2 == kBottomLeft_GrSurfaceOrigin);
 }

 GrGLSLFragmentShaderBuilder::GrGLSLFragmentShaderBuilder(GrGLSLProgramBuilder* program)
     : GrGLSLFragmentBuilder(program)
     , fSetupFragPosition(false)
     , fHasCustomColorOutput(false)
     , fCustomColorOutputIndex(-1)
     , fHasSecondaryOutput(false)
     , fUsedSampleOffsetArrays(0)
     , fHasInitializedSampleMask(false)
     , fDefaultPrecision(kMedium_GrSLPrecision) {
     fSubstageIndices.push_back(0);
 #ifdef SK_DEBUG
     fUsedProcessorFeatures = GrProcessor::kNone_RequiredFeatures;
     fHasReadDstColor = false;
 #endif
 }

 bool GrGLSLFragmentShaderBuilder::enableFeature(GLSLFeature feature) {
     const GrShaderCaps& shaderCaps = *fProgramBuilder->shaderCaps();
     switch (feature) {
         case kMultisampleInterpolation_GLSLFeature:
             if (!shaderCaps.multisampleInterpolationSupport()) {
                 return false;
             }
             if (const char* extension = shaderCaps.multisampleInterpolationExtensionString()) {
                 this->addFeature(1 << kMultisampleInterpolation_GLSLFeature, extension);
             }
             return true;
         default:
             SkFAIL("Unexpected GLSLFeature requested.");
             return false;
     }
 }

 SkString GrGLSLFragmentShaderBuilder::ensureCoords2D(const GrShaderVar& coords) {
     if (kVec3f_GrSLType != coords.getType()) {
         SkASSERT(kVec2f_GrSLType == coords.getType());
         return coords.getName();
     }

     SkString coords2D;
     coords2D.printf("%s_ensure2D", coords.c_str());
     this->codeAppendf("\tvec2 %s = %s.xy / %s.z;", coords2D.c_str(), coords.c_str(),
                       coords.c_str());
     return coords2D;
 }

 void GrGLSLFragmentShaderBuilder::appendOffsetToSample(const char* sampleIdx, Coordinates coords) {
     SkASSERT(fProgramBuilder->header().fSamplePatternKey);
     SkDEBUGCODE(fUsedProcessorFeatures |= GrProcessor::kSampleLocations_RequiredFeature);
     if (kTopLeft_GrSurfaceOrigin == this->getSurfaceOrigin()) {
         // With a top left origin, device and window space are equal, so we only use device coords.
         coords = kSkiaDevice_Coordinates;
     }
     this->codeAppendf("%s[%s]", sample_offset_array_name(coords), sampleIdx);
     fUsedSampleOffsetArrays |= (1 << coords);
 }

 void GrGLSLFragmentShaderBuilder::maskSampleCoverage(const char* mask, bool invert) {
     const GrShaderCaps& shaderCaps = *fProgramBuilder->shaderCaps();
     if (!shaderCaps.sampleVariablesSupport()) {
         SkDEBUGFAIL("Attempted to mask sample coverage without support.");
         return;
     }
     if (const char* extension = shaderCaps.sampleVariablesExtensionString()) {
         this->addFeature(1 << kSampleVariables_GLSLPrivateFeature, extension);
     }
     if (!fHasInitializedSampleMask) {
         this->codePrependf("gl_SampleMask[0] = -1;");
         fHasInitializedSampleMask = true;
     }
     if (invert) {
         this->codeAppendf("gl_SampleMask[0] &= ~(%s);", mask);
     } else {
         this->codeAppendf("gl_SampleMask[0] &= %s;", mask);
     }
 }

 void GrGLSLFragmentShaderBuilder::overrideSampleCoverage(const char* mask) {
     const GrShaderCaps& shaderCaps = *fProgramBuilder->shaderCaps();
     if (!shaderCaps.sampleMaskOverrideCoverageSupport()) {
         SkDEBUGFAIL("Attempted to override sample coverage without support.");
         return;
     }
     SkASSERT(shaderCaps.sampleVariablesSupport());
     if (const char* extension = shaderCaps.sampleVariablesExtensionString()) {
         this->addFeature(1 << kSampleVariables_GLSLPrivateFeature, extension);
     }
     if (this->addFeature(1 << kSampleMaskOverrideCoverage_GLSLPrivateFeature,
                          "GL_NV_sample_mask_override_coverage")) {
         // Redeclare gl_SampleMask with layout(override_coverage) if we haven't already.
         fOutputs.push_back().set(kInt_GrSLType, "gl_SampleMask", 1, GrShaderVar::kOut_TypeModifier,
                                  kHigh_GrSLPrecision, "override_coverage");
     }
     this->codeAppendf("gl_SampleMask[0] = %s;", mask);
     fHasInitializedSampleMask = true;
 }

 void GrGLSLFragmentShaderBuilder::elevateDefaultPrecision(GrSLPrecision precision) {
     fDefaultPrecision = SkTMax(fDefaultPrecision, precision);
 }

 const char* GrGLSLFragmentShaderBuilder::dstColor() {
     SkDEBUGCODE(fHasReadDstColor = true;)

     const char* override = fProgramBuilder->primitiveProcessor().getDestColorOverride();
     if (override != nullptr) {
         return override;
     }

     const GrShaderCaps* shaderCaps = fProgramBuilder->shaderCaps();
     if (shaderCaps->fbFetchSupport()) {
         this->addFeature(1 << kFramebufferFetch_GLSLPrivateFeature,
                          shaderCaps->fbFetchExtensionString());

         // Some versions of this extension string require declaring custom color output on ES 3.0+
         const char* fbFetchColorName = shaderCaps->fbFetchColorName();
         if (shaderCaps->fbFetchNeedsCustomOutput()) {
             this->enableCustomOutput();
             fOutputs[fCustomColorOutputIndex].setTypeModifier(GrShaderVar::kInOut_TypeModifier);
             fbFetchColorName = DeclaredColorOutputName();
             // Set the dstColor to an intermediate variable so we don't override it with the output
             this->codeAppendf("vec4 %s = %s;", kDstColorName, fbFetchColorName);
         } else {
             return fbFetchColorName;
         }
     }
     return kDstColorName;
 }

 void GrGLSLFragmentShaderBuilder::enableAdvancedBlendEquationIfNeeded(GrBlendEquation equation) {
     SkASSERT(GrBlendEquationIsAdvanced(equation));

     const GrShaderCaps& caps = *fProgramBuilder->shaderCaps();
     if (!caps.mustEnableAdvBlendEqs()) {
         return;
     }

     this->addFeature(1 << kBlendEquationAdvanced_GLSLPrivateFeature,
                      "GL_KHR_blend_equation_advanced");
     if (caps.mustEnableSpecificAdvBlendEqs()) {
         this->addLayoutQualifier(specific_layout_qualifier_name(equation), kOut_InterfaceQualifier);
     } else {
         this->addLayoutQualifier("blend_support_all_equations", kOut_InterfaceQualifier);
     }
 }

 void GrGLSLFragmentShaderBuilder::enableCustomOutput() {
     if (!fHasCustomColorOutput) {
         fHasCustomColorOutput = true;
         fCustomColorOutputIndex = fOutputs.count();
         fOutputs.push_back().set(kVec4f_GrSLType, DeclaredColorOutputName(),
                                  GrShaderVar::kOut_TypeModifier);
         fProgramBuilder->finalizeFragmentOutputColor(fOutputs.back());
     }
 }

 void GrGLSLFragmentShaderBuilder::enableSecondaryOutput() {
     SkASSERT(!fHasSecondaryOutput);
     fHasSecondaryOutput = true;
     const GrShaderCaps& caps = *fProgramBuilder->shaderCaps();
     if (const char* extension = caps.secondaryOutputExtensionString()) {
         this->addFeature(1 << kBlendFuncExtended_GLSLPrivateFeature, extension);
     }

     // If the primary output is declared, we must declare also the secondary output
     // and vice versa, since it is not allowed to use a built-in gl_FragColor and a custom
     // output. The condition also co-incides with the condition in whici GLES SL 2.0
     // requires the built-in gl_SecondaryFragColorEXT, where as 3.0 requires a custom output.
     if (caps.mustDeclareFragmentShaderOutput()) {
         fOutputs.push_back().set(kVec4f_GrSLType, DeclaredSecondaryColorOutputName(),
                                  GrShaderVar::kOut_TypeModifier);
         fProgramBuilder->finalizeFragmentSecondaryColor(fOutputs.back());
     }
 }

 const char* GrGLSLFragmentShaderBuilder::getPrimaryColorOutputName() const {
     return fHasCustomColorOutput ? DeclaredColorOutputName() : "sk_FragColor";
 }

 void GrGLSLFragmentBuilder::declAppendf(const char* fmt, ...) {
     va_list argp;
     va_start(argp, fmt);
     inputs().appendVAList(fmt, argp);
     va_end(argp);
 }

 const char* GrGLSLFragmentShaderBuilder::getSecondaryColorOutputName() const {
     const GrShaderCaps& caps = *fProgramBuilder->shaderCaps();
     return caps.mustDeclareFragmentShaderOutput() ? DeclaredSecondaryColorOutputName()
                                                   : "gl_SecondaryFragColorEXT";
 }

 GrSurfaceOrigin GrGLSLFragmentShaderBuilder::getSurfaceOrigin() const {
     SkASSERT(fProgramBuilder->header().fSurfaceOriginKey);
     return static_cast<GrSurfaceOrigin>(fProgramBuilder->header().fSurfaceOriginKey);

     GR_STATIC_ASSERT(1 == kTopLeft_GrSurfaceOrigin);
     GR_STATIC_ASSERT(2 == kBottomLeft_GrSurfaceOrigin);
 }

 void GrGLSLFragmentShaderBuilder::onFinalize() {
     fProgramBuilder->varyingHandler()->getFragDecls(&this->inputs(), &this->outputs());
     GrGLSLAppendDefaultFloatPrecisionDeclaration(fDefaultPrecision,
                                                  *fProgramBuilder->shaderCaps(),
                                                  &this->precisionQualifier());
     if (fUsedSampleOffsetArrays & (1 << kSkiaDevice_Coordinates)) {
         this->defineSampleOffsetArray(sample_offset_array_name(kSkiaDevice_Coordinates),
                                       SkMatrix::MakeTrans(-0.5f, -0.5f));
     }
     if (fUsedSampleOffsetArrays & (1 << kGLSLWindow_Coordinates)) {
         // With a top left origin, device and window space are equal, so we only use device coords.
         SkASSERT(kBottomLeft_GrSurfaceOrigin == this->getSurfaceOrigin());
         SkMatrix m;
         m.setScale(1, -1);
         m.preTranslate(-0.5f, -0.5f);
         this->defineSampleOffsetArray(sample_offset_array_name(kGLSLWindow_Coordinates), m);
     }
 }

 void GrGLSLFragmentShaderBuilder::defineSampleOffsetArray(const char* name, const SkMatrix& m) {
     SkASSERT(fProgramBuilder->caps()->sampleLocationsSupport());
     const GrPipeline& pipeline = fProgramBuilder->pipeline();
     const GrRenderTargetPriv& rtp = pipeline.getRenderTarget()->renderTargetPriv();
     const GrGpu::MultisampleSpecs& specs = rtp.getMultisampleSpecs(pipeline);
     SkSTArray<16, SkPoint, true> offsets;
     offsets.push_back_n(specs.fEffectiveSampleCnt);
     m.mapPoints(offsets.begin(), specs.fSampleLocations, specs.fEffectiveSampleCnt);
     this->definitions().appendf("const highp vec2 %s[] = vec2[](", name);
     for (int i = 0; i < specs.fEffectiveSampleCnt; ++i) {
         this->definitions().appendf("vec2(%f, %f)", offsets[i].x(), offsets[i].y());
         this->definitions().append(i + 1 != specs.fEffectiveSampleCnt ? ", " : ");\n");
     }
 }

 void GrGLSLFragmentShaderBuilder::onBeforeChildProcEmitCode() {
     SkASSERT(fSubstageIndices.count() >= 1);
     fSubstageIndices.push_back(0);
     // second-to-last value in the fSubstageIndices stack is the index of the child proc
     // at that level which is currently emitting code.
     fMangleString.appendf("_c%d", fSubstageIndices[fSubstageIndices.count() - 2]);
 }

 void GrGLSLFragmentShaderBuilder::onAfterChildProcEmitCode() {
     SkASSERT(fSubstageIndices.count() >= 2);
     fSubstageIndices.pop_back();
     fSubstageIndices.back()++;
     int removeAt = fMangleString.findLastOf('_');
     fMangleString.remove(removeAt, fMangleString.size() - removeAt);
 }
	/*
	* 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 "GrGLSLFragmentShaderBuilder.h"
	#include "GrRenderTarget.h"
	#include "GrRenderTargetPriv.h"
	#include "GrShaderCaps.h"
	#include "gl/GrGLGpu.h"
	#include "glsl/GrGLSLProgramBuilder.h"
	#include "glsl/GrGLSLUniformHandler.h"
	#include "glsl/GrGLSLVarying.h"
	#include "../private/GrGLSL.h"

	const char* GrGLSLFragmentShaderBuilder::kDstColorName = "_dstColor";

	static const char* sample_offset_array_name(GrGLSLFPFragmentBuilder::Coordinates coords) {
	static const char* kArrayNames[] = {
	"deviceSpaceSampleOffsets",
	"windowSpaceSampleOffsets"
	};
	return kArrayNames[coords];

	GR_STATIC_ASSERT(0 == GrGLSLFPFragmentBuilder::kSkiaDevice_Coordinates);
	GR_STATIC_ASSERT(1 == GrGLSLFPFragmentBuilder::kGLSLWindow_Coordinates);
	GR_STATIC_ASSERT(SK_ARRAY_COUNT(kArrayNames) == GrGLSLFPFragmentBuilder::kLast_Coordinates + 1);
	}

	static const char* specific_layout_qualifier_name(GrBlendEquation equation) {
	SkASSERT(GrBlendEquationIsAdvanced(equation));

	static const char* kLayoutQualifierNames[] = {
	"blend_support_screen",
	"blend_support_overlay",
	"blend_support_darken",
	"blend_support_lighten",
	"blend_support_colordodge",
	"blend_support_colorburn",
	"blend_support_hardlight",
	"blend_support_softlight",
	"blend_support_difference",
	"blend_support_exclusion",
	"blend_support_multiply",
	"blend_support_hsl_hue",
	"blend_support_hsl_saturation",
	"blend_support_hsl_color",
	"blend_support_hsl_luminosity"
	};
	return kLayoutQualifierNames[equation - kFirstAdvancedGrBlendEquation];

	GR_STATIC_ASSERT(0 == kScreen_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(1 == kOverlay_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(2 == kDarken_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(3 == kLighten_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(4 == kColorDodge_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(5 == kColorBurn_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(6 == kHardLight_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(7 == kSoftLight_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(8 == kDifference_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(9 == kExclusion_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(10 == kMultiply_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(11 == kHSLHue_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(12 == kHSLSaturation_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(13 == kHSLColor_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(14 == kHSLLuminosity_GrBlendEquation - kFirstAdvancedGrBlendEquation);
	GR_STATIC_ASSERT(SK_ARRAY_COUNT(kLayoutQualifierNames) ==
	kGrBlendEquationCnt - kFirstAdvancedGrBlendEquation);
	}

	uint8_t GrGLSLFragmentShaderBuilder::KeyForSurfaceOrigin(GrSurfaceOrigin origin) {
	SkASSERT(kTopLeft_GrSurfaceOrigin == origin \|\| kBottomLeft_GrSurfaceOrigin == origin);
	return origin;

	GR_STATIC_ASSERT(1 == kTopLeft_GrSurfaceOrigin);
	GR_STATIC_ASSERT(2 == kBottomLeft_GrSurfaceOrigin);
	}

	GrGLSLFragmentShaderBuilder::GrGLSLFragmentShaderBuilder(GrGLSLProgramBuilder* program)
	: GrGLSLFragmentBuilder(program)
	, fSetupFragPosition(false)
	, fHasCustomColorOutput(false)
	, fCustomColorOutputIndex(-1)
	, fHasSecondaryOutput(false)
	, fUsedSampleOffsetArrays(0)
	, fHasInitializedSampleMask(false)
	, fDefaultPrecision(kMedium_GrSLPrecision) {
	fSubstageIndices.push_back(0);
	#ifdef SK_DEBUG
	fUsedProcessorFeatures = GrProcessor::kNone_RequiredFeatures;
	fHasReadDstColor = false;
	#endif
	}

	bool GrGLSLFragmentShaderBuilder::enableFeature(GLSLFeature feature) {
	const GrShaderCaps& shaderCaps = *fProgramBuilder->shaderCaps();
	switch (feature) {
	case kMultisampleInterpolation_GLSLFeature:
	if (!shaderCaps.multisampleInterpolationSupport()) {
	return false;
	}
	if (const char* extension = shaderCaps.multisampleInterpolationExtensionString()) {
	this->addFeature(1 << kMultisampleInterpolation_GLSLFeature, extension);
	}
	return true;
	default:
	SkFAIL("Unexpected GLSLFeature requested.");
	return false;
	}
	}

	SkString GrGLSLFragmentShaderBuilder::ensureCoords2D(const GrShaderVar& coords) {
	if (kVec3f_GrSLType != coords.getType()) {
	SkASSERT(kVec2f_GrSLType == coords.getType());
	return coords.getName();
	}

	SkString coords2D;
	coords2D.printf("%s_ensure2D", coords.c_str());
	this->codeAppendf("\tvec2 %s = %s.xy / %s.z;", coords2D.c_str(), coords.c_str(),
	coords.c_str());
	return coords2D;
	}

	void GrGLSLFragmentShaderBuilder::appendOffsetToSample(const char* sampleIdx, Coordinates coords) {
	SkASSERT(fProgramBuilder->header().fSamplePatternKey);
	SkDEBUGCODE(fUsedProcessorFeatures \|= GrProcessor::kSampleLocations_RequiredFeature);
	if (kTopLeft_GrSurfaceOrigin == this->getSurfaceOrigin()) {
	// With a top left origin, device and window space are equal, so we only use device coords.
	coords = kSkiaDevice_Coordinates;
	}
	this->codeAppendf("%s[%s]", sample_offset_array_name(coords), sampleIdx);
	fUsedSampleOffsetArrays \|= (1 << coords);
	}

	void GrGLSLFragmentShaderBuilder::maskSampleCoverage(const char* mask, bool invert) {
	const GrShaderCaps& shaderCaps = *fProgramBuilder->shaderCaps();
	if (!shaderCaps.sampleVariablesSupport()) {
	SkDEBUGFAIL("Attempted to mask sample coverage without support.");
	return;
	}
	if (const char* extension = shaderCaps.sampleVariablesExtensionString()) {
	this->addFeature(1 << kSampleVariables_GLSLPrivateFeature, extension);
	}
	if (!fHasInitializedSampleMask) {
	this->codePrependf("gl_SampleMask[0] = -1;");
	fHasInitializedSampleMask = true;
	}
	if (invert) {
	this->codeAppendf("gl_SampleMask[0] &= ~(%s);", mask);
	} else {
	this->codeAppendf("gl_SampleMask[0] &= %s;", mask);
	}
	}

	void GrGLSLFragmentShaderBuilder::overrideSampleCoverage(const char* mask) {
	const GrShaderCaps& shaderCaps = *fProgramBuilder->shaderCaps();
	if (!shaderCaps.sampleMaskOverrideCoverageSupport()) {
	SkDEBUGFAIL("Attempted to override sample coverage without support.");
	return;
	}
	SkASSERT(shaderCaps.sampleVariablesSupport());
	if (const char* extension = shaderCaps.sampleVariablesExtensionString()) {
	this->addFeature(1 << kSampleVariables_GLSLPrivateFeature, extension);
	}
	if (this->addFeature(1 << kSampleMaskOverrideCoverage_GLSLPrivateFeature,
	"GL_NV_sample_mask_override_coverage")) {
	// Redeclare gl_SampleMask with layout(override_coverage) if we haven't already.
	fOutputs.push_back().set(kInt_GrSLType, "gl_SampleMask", 1, GrShaderVar::kOut_TypeModifier,
	kHigh_GrSLPrecision, "override_coverage");
	}
	this->codeAppendf("gl_SampleMask[0] = %s;", mask);
	fHasInitializedSampleMask = true;
	}

	void GrGLSLFragmentShaderBuilder::elevateDefaultPrecision(GrSLPrecision precision) {
	fDefaultPrecision = SkTMax(fDefaultPrecision, precision);
	}

	const char* GrGLSLFragmentShaderBuilder::dstColor() {
	SkDEBUGCODE(fHasReadDstColor = true;)

	const char* override = fProgramBuilder->primitiveProcessor().getDestColorOverride();
	if (override != nullptr) {
	return override;
	}

	const GrShaderCaps* shaderCaps = fProgramBuilder->shaderCaps();
	if (shaderCaps->fbFetchSupport()) {
	this->addFeature(1 << kFramebufferFetch_GLSLPrivateFeature,
	shaderCaps->fbFetchExtensionString());

	// Some versions of this extension string require declaring custom color output on ES 3.0+
	const char* fbFetchColorName = shaderCaps->fbFetchColorName();
	if (shaderCaps->fbFetchNeedsCustomOutput()) {
	this->enableCustomOutput();
	fOutputs[fCustomColorOutputIndex].setTypeModifier(GrShaderVar::kInOut_TypeModifier);
	fbFetchColorName = DeclaredColorOutputName();
	// Set the dstColor to an intermediate variable so we don't override it with the output
	this->codeAppendf("vec4 %s = %s;", kDstColorName, fbFetchColorName);
	} else {
	return fbFetchColorName;
	}
	}
	return kDstColorName;
	}

	void GrGLSLFragmentShaderBuilder::enableAdvancedBlendEquationIfNeeded(GrBlendEquation equation) {
	SkASSERT(GrBlendEquationIsAdvanced(equation));

	const GrShaderCaps& caps = *fProgramBuilder->shaderCaps();
	if (!caps.mustEnableAdvBlendEqs()) {
	return;
	}

	this->addFeature(1 << kBlendEquationAdvanced_GLSLPrivateFeature,
	"GL_KHR_blend_equation_advanced");
	if (caps.mustEnableSpecificAdvBlendEqs()) {
	this->addLayoutQualifier(specific_layout_qualifier_name(equation), kOut_InterfaceQualifier);
	} else {
	this->addLayoutQualifier("blend_support_all_equations", kOut_InterfaceQualifier);
	}
	}

	void GrGLSLFragmentShaderBuilder::enableCustomOutput() {
	if (!fHasCustomColorOutput) {
	fHasCustomColorOutput = true;
	fCustomColorOutputIndex = fOutputs.count();
	fOutputs.push_back().set(kVec4f_GrSLType, DeclaredColorOutputName(),
	GrShaderVar::kOut_TypeModifier);
	fProgramBuilder->finalizeFragmentOutputColor(fOutputs.back());
	}
	}

	void GrGLSLFragmentShaderBuilder::enableSecondaryOutput() {
	SkASSERT(!fHasSecondaryOutput);
	fHasSecondaryOutput = true;
	const GrShaderCaps& caps = *fProgramBuilder->shaderCaps();
	if (const char* extension = caps.secondaryOutputExtensionString()) {
	this->addFeature(1 << kBlendFuncExtended_GLSLPrivateFeature, extension);
	}

	// If the primary output is declared, we must declare also the secondary output
	// and vice versa, since it is not allowed to use a built-in gl_FragColor and a custom
	// output. The condition also co-incides with the condition in whici GLES SL 2.0
	// requires the built-in gl_SecondaryFragColorEXT, where as 3.0 requires a custom output.
	if (caps.mustDeclareFragmentShaderOutput()) {
	fOutputs.push_back().set(kVec4f_GrSLType, DeclaredSecondaryColorOutputName(),
	GrShaderVar::kOut_TypeModifier);
	fProgramBuilder->finalizeFragmentSecondaryColor(fOutputs.back());
	}
	}

	const char* GrGLSLFragmentShaderBuilder::getPrimaryColorOutputName() const {
	return fHasCustomColorOutput ? DeclaredColorOutputName() : "sk_FragColor";
	}

	void GrGLSLFragmentBuilder::declAppendf(const char* fmt, ...) {
	va_list argp;
	va_start(argp, fmt);
	inputs().appendVAList(fmt, argp);
	va_end(argp);
	}

	const char* GrGLSLFragmentShaderBuilder::getSecondaryColorOutputName() const {
	const GrShaderCaps& caps = *fProgramBuilder->shaderCaps();
	return caps.mustDeclareFragmentShaderOutput() ? DeclaredSecondaryColorOutputName()
	: "gl_SecondaryFragColorEXT";
	}

	GrSurfaceOrigin GrGLSLFragmentShaderBuilder::getSurfaceOrigin() const {
	SkASSERT(fProgramBuilder->header().fSurfaceOriginKey);
	return static_cast<GrSurfaceOrigin>(fProgramBuilder->header().fSurfaceOriginKey);

	GR_STATIC_ASSERT(1 == kTopLeft_GrSurfaceOrigin);
	GR_STATIC_ASSERT(2 == kBottomLeft_GrSurfaceOrigin);
	}

	void GrGLSLFragmentShaderBuilder::onFinalize() {
	fProgramBuilder->varyingHandler()->getFragDecls(&this->inputs(), &this->outputs());
	GrGLSLAppendDefaultFloatPrecisionDeclaration(fDefaultPrecision,
	*fProgramBuilder->shaderCaps(),
	&this->precisionQualifier());
	if (fUsedSampleOffsetArrays & (1 << kSkiaDevice_Coordinates)) {
	this->defineSampleOffsetArray(sample_offset_array_name(kSkiaDevice_Coordinates),
	SkMatrix::MakeTrans(-0.5f, -0.5f));
	}
	if (fUsedSampleOffsetArrays & (1 << kGLSLWindow_Coordinates)) {
	// With a top left origin, device and window space are equal, so we only use device coords.
	SkASSERT(kBottomLeft_GrSurfaceOrigin == this->getSurfaceOrigin());
	SkMatrix m;
	m.setScale(1, -1);
	m.preTranslate(-0.5f, -0.5f);
	this->defineSampleOffsetArray(sample_offset_array_name(kGLSLWindow_Coordinates), m);
	}
	}

	void GrGLSLFragmentShaderBuilder::defineSampleOffsetArray(const char* name, const SkMatrix& m) {
	SkASSERT(fProgramBuilder->caps()->sampleLocationsSupport());
	const GrPipeline& pipeline = fProgramBuilder->pipeline();
	const GrRenderTargetPriv& rtp = pipeline.getRenderTarget()->renderTargetPriv();
	const GrGpu::MultisampleSpecs& specs = rtp.getMultisampleSpecs(pipeline);
	SkSTArray<16, SkPoint, true> offsets;
	offsets.push_back_n(specs.fEffectiveSampleCnt);
	m.mapPoints(offsets.begin(), specs.fSampleLocations, specs.fEffectiveSampleCnt);
	this->definitions().appendf("const highp vec2 %s[] = vec2[](", name);
	for (int i = 0; i < specs.fEffectiveSampleCnt; ++i) {
	this->definitions().appendf("vec2(%f, %f)", offsets[i].x(), offsets[i].y());
	this->definitions().append(i + 1 != specs.fEffectiveSampleCnt ? ", " : ");\n");
	}
	}

	void GrGLSLFragmentShaderBuilder::onBeforeChildProcEmitCode() {
	SkASSERT(fSubstageIndices.count() >= 1);
	fSubstageIndices.push_back(0);
	// second-to-last value in the fSubstageIndices stack is the index of the child proc
	// at that level which is currently emitting code.
	fMangleString.appendf("_c%d", fSubstageIndices[fSubstageIndices.count() - 2]);
	}

	void GrGLSLFragmentShaderBuilder::onAfterChildProcEmitCode() {
	SkASSERT(fSubstageIndices.count() >= 2);
	fSubstageIndices.pop_back();
	fSubstageIndices.back()++;
	int removeAt = fMangleString.findLastOf('_');
	fMangleString.remove(removeAt, fMangleString.size() - removeAt);
	}