src/gpu/ganesh/effects/GrPerlinNoise2Effect.cpp - skia - Git at Google

 /*
  * Copyright 2023 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/ganesh/effects/GrPerlinNoise2Effect.h"

 #include "include/core/SkRefCnt.h"
 #include "include/core/SkScalar.h"
 #include "include/core/SkSize.h"
 #include "include/effects/SkPerlinNoiseShader.h"
 #include "include/private/gpu/ganesh/GrTypesPriv.h"
 #include "src/base/SkRandom.h"
 #include "src/core/SkSLTypeShared.h"
 #include "src/gpu/KeyBuilder.h"
 #include "src/gpu/ganesh/GrFragmentProcessor.h"
 #include "src/gpu/ganesh/GrFragmentProcessors.h"
 #include "src/gpu/ganesh/GrProcessorUnitTest.h"
 #include "src/gpu/ganesh/GrShaderCaps.h"
 #include "src/gpu/ganesh/GrShaderVar.h"
 #include "src/gpu/ganesh/GrTestUtils.h"
 #include "src/gpu/ganesh/glsl/GrGLSLFragmentShaderBuilder.h"
 #include "src/gpu/ganesh/glsl/GrGLSLProgramDataManager.h"
 #include "src/gpu/ganesh/glsl/GrGLSLUniformHandler.h"

 #include <cstdint>
 #include <iterator>

 class SkShader;

 /////////////////////////////////////////////////////////////////////
 GR_DEFINE_FRAGMENT_PROCESSOR_TEST(GrPerlinNoise2Effect)

 #if GR_TEST_UTILS
 std::unique_ptr<GrFragmentProcessor> GrPerlinNoise2Effect::TestCreate(GrProcessorTestData* d) {
     int numOctaves = d->fRandom->nextRangeU(2, 10);
     bool stitchTiles = d->fRandom->nextBool();
     SkScalar seed = SkIntToScalar(d->fRandom->nextU());
     SkISize tileSize;
     tileSize.fWidth = d->fRandom->nextRangeU(4, 4096);
     tileSize.fHeight = d->fRandom->nextRangeU(4, 4096);
     SkScalar baseFrequencyX = d->fRandom->nextRangeScalar(0.01f, 0.99f);
     SkScalar baseFrequencyY = d->fRandom->nextRangeScalar(0.01f, 0.99f);

     sk_sp<SkShader> shader(d->fRandom->nextBool()
                                    ? SkShaders::MakeFractalNoise(baseFrequencyX,
                                                                  baseFrequencyY,
                                                                  numOctaves,
                                                                  seed,
                                                                  stitchTiles ? &tileSize : nullptr)
                                    : SkShaders::MakeTurbulence(baseFrequencyX,
                                                                baseFrequencyY,
                                                                numOctaves,
                                                                seed,
                                                                stitchTiles ? &tileSize : nullptr));

     GrTest::TestAsFPArgs asFPArgs(d);
     return GrFragmentProcessors::Make(
             shader.get(), asFPArgs.args(), GrTest::TestMatrix(d->fRandom));
 }
 #endif

 SkString GrPerlinNoise2Effect::Impl::emitHelper(EmitArgs& args) {
     const GrPerlinNoise2Effect& pne = args.fFp.cast<GrPerlinNoise2Effect>();

     GrGLSLFPFragmentBuilder* fragBuilder = args.fFragBuilder;

     // Add noise function
     const GrShaderVar gPerlinNoiseArgs[] = {{"chanCoord", SkSLType::kHalf},
                                             {"noiseVec ", SkSLType::kHalf2}};

     const GrShaderVar gPerlinNoiseStitchArgs[] = {{"chanCoord", SkSLType::kHalf},
                                                   {"noiseVec", SkSLType::kHalf2},
                                                   {"stitchData", SkSLType::kHalf2}};

     SkString noiseCode;

     noiseCode.append(
             "half4 floorVal;"
             "floorVal.xy = floor(noiseVec);"
             "floorVal.zw = floorVal.xy + half2(1);"
             "half2 fractVal = fract(noiseVec);"

             // smooth curve : t^2*(3 - 2*t)
             "half2 noiseSmooth = fractVal*fractVal*(half2(3) - 2*fractVal);"
     );

     // Adjust frequencies if we're stitching tiles
     if (pne.stitchTiles()) {
         noiseCode.append("floorVal -= step(stitchData.xyxy, floorVal) * stitchData.xyxy;");
     }

     // NOTE: We need to explicitly pass half4(1) as input color here, because the helper function
     // can't see fInputColor (which is "_input" in the FP's outer function). skbug.com/10506
     SkString sampleX = this->invokeChild(0, "half4(1)", args, "half2(floorVal.x, 0.5)");
     SkString sampleY = this->invokeChild(0, "half4(1)", args, "half2(floorVal.z, 0.5)");
     noiseCode.appendf("half2 latticeIdx = half2(%s.a, %s.a);", sampleX.c_str(), sampleY.c_str());

     if (args.fShaderCaps->fPerlinNoiseRoundingFix) {
         // Android rounding for Tegra devices, like, for example: Xoom (Tegra 2), Nexus 7 (Tegra 3).
         // The issue is that colors aren't accurate enough on Tegra devices. For example, if an
         // 8 bit value of 124 (or 0.486275 here) is entered, we can get a texture value of
         // 123.513725 (or 0.484368 here). The following rounding operation prevents these precision
         // issues from affecting the result of the noise by making sure that we only have multiples
         // of 1/255. (Note that 1/255 is about 0.003921569, which is the value used here).
         noiseCode.append(
                 "latticeIdx = floor(latticeIdx * half2(255.0) + half2(0.5)) * half2(0.003921569);");
     }

     // Get (x,y) coordinates with the permuted x
     noiseCode.append("half4 bcoords = 256*latticeIdx.xyxy + floorVal.yyww;");

     noiseCode.append("half2 uv;");

     // This is the math to convert the two 16bit integer packed into rgba 8 bit input into a
     // [-1,1] vector and perform a dot product between that vector and the provided vector.
     // Save it as a string because we will repeat it 4x.
     static constexpr const char* inc8bit = "0.00390625";  // 1.0 / 256.0
     SkString dotLattice =
             SkStringPrintf("dot((lattice.ga + lattice.rb*%s)*2 - half2(1), fractVal)", inc8bit);

     SkString sampleA = this->invokeChild(1, "half4(1)", args, "half2(bcoords.x, chanCoord)");
     SkString sampleB = this->invokeChild(1, "half4(1)", args, "half2(bcoords.y, chanCoord)");
     SkString sampleC = this->invokeChild(1, "half4(1)", args, "half2(bcoords.w, chanCoord)");
     SkString sampleD = this->invokeChild(1, "half4(1)", args, "half2(bcoords.z, chanCoord)");

     // Compute u, at offset (0,0)
     noiseCode.appendf("half4 lattice = %s;", sampleA.c_str());
     noiseCode.appendf("uv.x = %s;", dotLattice.c_str());

     // Compute v, at offset (-1,0)
     noiseCode.append("fractVal.x -= 1.0;");
     noiseCode.appendf("lattice = %s;", sampleB.c_str());
     noiseCode.appendf("uv.y = %s;", dotLattice.c_str());

     // Compute 'a' as a linear interpolation of 'u' and 'v'
     noiseCode.append("half2 ab;");
     noiseCode.append("ab.x = mix(uv.x, uv.y, noiseSmooth.x);");

     // Compute v, at offset (-1,-1)
     noiseCode.append("fractVal.y -= 1.0;");
     noiseCode.appendf("lattice = %s;", sampleC.c_str());
     noiseCode.appendf("uv.y = %s;", dotLattice.c_str());

     // Compute u, at offset (0,-1)
     noiseCode.append("fractVal.x += 1.0;");
     noiseCode.appendf("lattice = %s;", sampleD.c_str());
     noiseCode.appendf("uv.x = %s;", dotLattice.c_str());

     // Compute 'b' as a linear interpolation of 'u' and 'v'
     noiseCode.append("ab.y = mix(uv.x, uv.y, noiseSmooth.x);");
     // Compute the noise as a linear interpolation of 'a' and 'b'
     noiseCode.append("return mix(ab.x, ab.y, noiseSmooth.y);");

     SkString noiseFuncName = fragBuilder->getMangledFunctionName("noiseFuncName");
     if (pne.stitchTiles()) {
         fragBuilder->emitFunction(SkSLType::kHalf,
                                   noiseFuncName.c_str(),
                                   {gPerlinNoiseStitchArgs, std::size(gPerlinNoiseStitchArgs)},
                                   noiseCode.c_str());
     } else {
         fragBuilder->emitFunction(SkSLType::kHalf,
                                   noiseFuncName.c_str(),
                                   {gPerlinNoiseArgs, std::size(gPerlinNoiseArgs)},
                                   noiseCode.c_str());
     }

     return noiseFuncName;
 }

 void GrPerlinNoise2Effect::Impl::emitCode(EmitArgs& args) {
     SkString noiseFuncName = this->emitHelper(args);

     const GrPerlinNoise2Effect& pne = args.fFp.cast<GrPerlinNoise2Effect>();

     GrGLSLFPFragmentBuilder* fragBuilder = args.fFragBuilder;
     GrGLSLUniformHandler* uniformHandler = args.fUniformHandler;

     fBaseFrequencyUni = uniformHandler->addUniform(
             &pne, kFragment_GrShaderFlag, SkSLType::kHalf2, "baseFrequency");
     const char* baseFrequencyUni = uniformHandler->getUniformCStr(fBaseFrequencyUni);

     const char* stitchDataUni = nullptr;
     if (pne.stitchTiles()) {
         fStitchDataUni = uniformHandler->addUniform(
                 &pne, kFragment_GrShaderFlag, SkSLType::kHalf2, "stitchData");
         stitchDataUni = uniformHandler->getUniformCStr(fStitchDataUni);
     }

     // There are rounding errors if the floor operation is not performed here
     fragBuilder->codeAppendf(
             "half2 noiseVec = half2(floor(%s.xy) * %s);", args.fSampleCoord, baseFrequencyUni);

     // Clear the color accumulator
     fragBuilder->codeAppendf("half4 color = half4(0);");

     if (pne.stitchTiles()) {
         fragBuilder->codeAppendf("half2 stitchData = %s;", stitchDataUni);
     }

     fragBuilder->codeAppendf("half ratio = 1.0;");

     // Loop over all octaves
     fragBuilder->codeAppendf("for (int octave = 0; octave < %d; ++octave) {", pne.numOctaves());
     fragBuilder->codeAppendf("color += ");
     if (pne.type() != SkPerlinNoiseShader::kFractalNoise_Type) {
         fragBuilder->codeAppend("abs(");
     }

     // There are 4 lines, put y coords at center of each.
     static constexpr const char* chanCoordR = "0.5";
     static constexpr const char* chanCoordG = "1.5";
     static constexpr const char* chanCoordB = "2.5";
     static constexpr const char* chanCoordA = "3.5";
     if (pne.stitchTiles()) {
         fragBuilder->codeAppendf(
                 "half4(%s(%s, noiseVec, stitchData), %s(%s, noiseVec, stitchData),"
                       "%s(%s, noiseVec, stitchData), %s(%s, noiseVec, stitchData))",
                 noiseFuncName.c_str(),
                 chanCoordR,
                 noiseFuncName.c_str(),
                 chanCoordG,
                 noiseFuncName.c_str(),
                 chanCoordB,
                 noiseFuncName.c_str(),
                 chanCoordA);
     } else {
         fragBuilder->codeAppendf(
                 "half4(%s(%s, noiseVec), %s(%s, noiseVec),"
                       "%s(%s, noiseVec), %s(%s, noiseVec))",
                 noiseFuncName.c_str(),
                 chanCoordR,
                 noiseFuncName.c_str(),
                 chanCoordG,
                 noiseFuncName.c_str(),
                 chanCoordB,
                 noiseFuncName.c_str(),
                 chanCoordA);
     }
     if (pne.type() != SkPerlinNoiseShader::kFractalNoise_Type) {
         fragBuilder->codeAppend(")");  // end of "abs("
     }
     fragBuilder->codeAppend(" * ratio;");

     fragBuilder->codeAppend(
             "noiseVec *= half2(2.0);"
             "ratio *= 0.5;");

     if (pne.stitchTiles()) {
         fragBuilder->codeAppend("stitchData *= half2(2.0);");
     }
     fragBuilder->codeAppend("}");  // end of the for loop on octaves

     if (pne.type() == SkPerlinNoiseShader::kFractalNoise_Type) {
         // The value of turbulenceFunctionResult comes from ((turbulenceFunctionResult) + 1) / 2
         // by fractalNoise and (turbulenceFunctionResult) by turbulence.
         fragBuilder->codeAppendf("color = color * half4(0.5) + half4(0.5);");
     }

     // Clamp values
     fragBuilder->codeAppendf("color = saturate(color);");

     // Pre-multiply the result
     fragBuilder->codeAppendf("return half4(color.rgb * color.aaa, color.a);");
 }

 void GrPerlinNoise2Effect::Impl::onSetData(const GrGLSLProgramDataManager& pdman,
                                            const GrFragmentProcessor& processor) {
     const GrPerlinNoise2Effect& turbulence = processor.cast<GrPerlinNoise2Effect>();

     const SkVector& baseFrequency = turbulence.baseFrequency();
     pdman.set2f(fBaseFrequencyUni, baseFrequency.fX, baseFrequency.fY);

     if (turbulence.stitchTiles()) {
         const SkPerlinNoiseShader::StitchData& stitchData = turbulence.stitchData();
         pdman.set2f(fStitchDataUni,
                     SkIntToScalar(stitchData.fWidth),
                     SkIntToScalar(stitchData.fHeight));
     }
 }

 void GrPerlinNoise2Effect::onAddToKey(const GrShaderCaps& caps, skgpu::KeyBuilder* b) const {
     uint32_t key = fNumOctaves;
     key = key << 3;  // Make room for next 3 bits
     switch (fType) {
         case SkPerlinNoiseShader::kFractalNoise_Type:
             key |= 0x1;
             break;
         case SkPerlinNoiseShader::kTurbulence_Type:
             key |= 0x2;
             break;
         default:
             // leave key at 0
             break;
     }
     if (fStitchTiles) {
         key |= 0x4;  // Flip the 3rd bit if tile stitching is on
     }
     b->add32(key);
 }
	/*
	* Copyright 2023 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/ganesh/effects/GrPerlinNoise2Effect.h"

	#include "include/core/SkRefCnt.h"
	#include "include/core/SkScalar.h"
	#include "include/core/SkSize.h"
	#include "include/effects/SkPerlinNoiseShader.h"
	#include "include/private/gpu/ganesh/GrTypesPriv.h"
	#include "src/base/SkRandom.h"
	#include "src/core/SkSLTypeShared.h"
	#include "src/gpu/KeyBuilder.h"
	#include "src/gpu/ganesh/GrFragmentProcessor.h"
	#include "src/gpu/ganesh/GrFragmentProcessors.h"
	#include "src/gpu/ganesh/GrProcessorUnitTest.h"
	#include "src/gpu/ganesh/GrShaderCaps.h"
	#include "src/gpu/ganesh/GrShaderVar.h"
	#include "src/gpu/ganesh/GrTestUtils.h"
	#include "src/gpu/ganesh/glsl/GrGLSLFragmentShaderBuilder.h"
	#include "src/gpu/ganesh/glsl/GrGLSLProgramDataManager.h"
	#include "src/gpu/ganesh/glsl/GrGLSLUniformHandler.h"

	#include <cstdint>
	#include <iterator>

	class SkShader;

	/////////////////////////////////////////////////////////////////////
	GR_DEFINE_FRAGMENT_PROCESSOR_TEST(GrPerlinNoise2Effect)

	#if GR_TEST_UTILS
	std::unique_ptr<GrFragmentProcessor> GrPerlinNoise2Effect::TestCreate(GrProcessorTestData* d) {
	int numOctaves = d->fRandom->nextRangeU(2, 10);
	bool stitchTiles = d->fRandom->nextBool();
	SkScalar seed = SkIntToScalar(d->fRandom->nextU());
	SkISize tileSize;
	tileSize.fWidth = d->fRandom->nextRangeU(4, 4096);
	tileSize.fHeight = d->fRandom->nextRangeU(4, 4096);
	SkScalar baseFrequencyX = d->fRandom->nextRangeScalar(0.01f, 0.99f);
	SkScalar baseFrequencyY = d->fRandom->nextRangeScalar(0.01f, 0.99f);

	sk_sp<SkShader> shader(d->fRandom->nextBool()
	? SkShaders::MakeFractalNoise(baseFrequencyX,
	baseFrequencyY,
	numOctaves,
	seed,
	stitchTiles ? &tileSize : nullptr)
	: SkShaders::MakeTurbulence(baseFrequencyX,
	baseFrequencyY,
	numOctaves,
	seed,
	stitchTiles ? &tileSize : nullptr));

	GrTest::TestAsFPArgs asFPArgs(d);
	return GrFragmentProcessors::Make(
	shader.get(), asFPArgs.args(), GrTest::TestMatrix(d->fRandom));
	}
	#endif

	SkString GrPerlinNoise2Effect::Impl::emitHelper(EmitArgs& args) {
	const GrPerlinNoise2Effect& pne = args.fFp.cast<GrPerlinNoise2Effect>();

	GrGLSLFPFragmentBuilder* fragBuilder = args.fFragBuilder;

	// Add noise function
	const GrShaderVar gPerlinNoiseArgs[] = {{"chanCoord", SkSLType::kHalf},
	{"noiseVec ", SkSLType::kHalf2}};

	const GrShaderVar gPerlinNoiseStitchArgs[] = {{"chanCoord", SkSLType::kHalf},
	{"noiseVec", SkSLType::kHalf2},
	{"stitchData", SkSLType::kHalf2}};

	SkString noiseCode;

	noiseCode.append(
	"half4 floorVal;"
	"floorVal.xy = floor(noiseVec);"
	"floorVal.zw = floorVal.xy + half2(1);"
	"half2 fractVal = fract(noiseVec);"

	// smooth curve : t^2(3 - 2t)
	"half2 noiseSmooth = fractValfractVal(half2(3) - 2*fractVal);"
	);

	// Adjust frequencies if we're stitching tiles
	if (pne.stitchTiles()) {
	noiseCode.append("floorVal -= step(stitchData.xyxy, floorVal) * stitchData.xyxy;");
	}

	// NOTE: We need to explicitly pass half4(1) as input color here, because the helper function
	// can't see fInputColor (which is "_input" in the FP's outer function). skbug.com/10506
	SkString sampleX = this->invokeChild(0, "half4(1)", args, "half2(floorVal.x, 0.5)");
	SkString sampleY = this->invokeChild(0, "half4(1)", args, "half2(floorVal.z, 0.5)");
	noiseCode.appendf("half2 latticeIdx = half2(%s.a, %s.a);", sampleX.c_str(), sampleY.c_str());

	if (args.fShaderCaps->fPerlinNoiseRoundingFix) {
	// Android rounding for Tegra devices, like, for example: Xoom (Tegra 2), Nexus 7 (Tegra 3).
	// The issue is that colors aren't accurate enough on Tegra devices. For example, if an
	// 8 bit value of 124 (or 0.486275 here) is entered, we can get a texture value of
	// 123.513725 (or 0.484368 here). The following rounding operation prevents these precision
	// issues from affecting the result of the noise by making sure that we only have multiples
	// of 1/255. (Note that 1/255 is about 0.003921569, which is the value used here).
	noiseCode.append(
	"latticeIdx = floor(latticeIdx * half2(255.0) + half2(0.5)) * half2(0.003921569);");
	}

	// Get (x,y) coordinates with the permuted x
	noiseCode.append("half4 bcoords = 256*latticeIdx.xyxy + floorVal.yyww;");

	noiseCode.append("half2 uv;");

	// This is the math to convert the two 16bit integer packed into rgba 8 bit input into a
	// [-1,1] vector and perform a dot product between that vector and the provided vector.
	// Save it as a string because we will repeat it 4x.
	static constexpr const char* inc8bit = "0.00390625"; // 1.0 / 256.0
	SkString dotLattice =
	SkStringPrintf("dot((lattice.ga + lattice.rb%s)2 - half2(1), fractVal)", inc8bit);

	SkString sampleA = this->invokeChild(1, "half4(1)", args, "half2(bcoords.x, chanCoord)");
	SkString sampleB = this->invokeChild(1, "half4(1)", args, "half2(bcoords.y, chanCoord)");
	SkString sampleC = this->invokeChild(1, "half4(1)", args, "half2(bcoords.w, chanCoord)");
	SkString sampleD = this->invokeChild(1, "half4(1)", args, "half2(bcoords.z, chanCoord)");

	// Compute u, at offset (0,0)
	noiseCode.appendf("half4 lattice = %s;", sampleA.c_str());
	noiseCode.appendf("uv.x = %s;", dotLattice.c_str());

	// Compute v, at offset (-1,0)
	noiseCode.append("fractVal.x -= 1.0;");
	noiseCode.appendf("lattice = %s;", sampleB.c_str());
	noiseCode.appendf("uv.y = %s;", dotLattice.c_str());

	// Compute 'a' as a linear interpolation of 'u' and 'v'
	noiseCode.append("half2 ab;");
	noiseCode.append("ab.x = mix(uv.x, uv.y, noiseSmooth.x);");

	// Compute v, at offset (-1,-1)
	noiseCode.append("fractVal.y -= 1.0;");
	noiseCode.appendf("lattice = %s;", sampleC.c_str());
	noiseCode.appendf("uv.y = %s;", dotLattice.c_str());

	// Compute u, at offset (0,-1)
	noiseCode.append("fractVal.x += 1.0;");
	noiseCode.appendf("lattice = %s;", sampleD.c_str());
	noiseCode.appendf("uv.x = %s;", dotLattice.c_str());

	// Compute 'b' as a linear interpolation of 'u' and 'v'
	noiseCode.append("ab.y = mix(uv.x, uv.y, noiseSmooth.x);");
	// Compute the noise as a linear interpolation of 'a' and 'b'
	noiseCode.append("return mix(ab.x, ab.y, noiseSmooth.y);");

	SkString noiseFuncName = fragBuilder->getMangledFunctionName("noiseFuncName");
	if (pne.stitchTiles()) {
	fragBuilder->emitFunction(SkSLType::kHalf,
	noiseFuncName.c_str(),
	{gPerlinNoiseStitchArgs, std::size(gPerlinNoiseStitchArgs)},
	noiseCode.c_str());
	} else {
	fragBuilder->emitFunction(SkSLType::kHalf,
	noiseFuncName.c_str(),
	{gPerlinNoiseArgs, std::size(gPerlinNoiseArgs)},
	noiseCode.c_str());
	}

	return noiseFuncName;
	}

	void GrPerlinNoise2Effect::Impl::emitCode(EmitArgs& args) {
	SkString noiseFuncName = this->emitHelper(args);

	const GrPerlinNoise2Effect& pne = args.fFp.cast<GrPerlinNoise2Effect>();

	GrGLSLFPFragmentBuilder* fragBuilder = args.fFragBuilder;
	GrGLSLUniformHandler* uniformHandler = args.fUniformHandler;

	fBaseFrequencyUni = uniformHandler->addUniform(
	&pne, kFragment_GrShaderFlag, SkSLType::kHalf2, "baseFrequency");
	const char* baseFrequencyUni = uniformHandler->getUniformCStr(fBaseFrequencyUni);

	const char* stitchDataUni = nullptr;
	if (pne.stitchTiles()) {
	fStitchDataUni = uniformHandler->addUniform(
	&pne, kFragment_GrShaderFlag, SkSLType::kHalf2, "stitchData");
	stitchDataUni = uniformHandler->getUniformCStr(fStitchDataUni);
	}

	// There are rounding errors if the floor operation is not performed here
	fragBuilder->codeAppendf(
	"half2 noiseVec = half2(floor(%s.xy) * %s);", args.fSampleCoord, baseFrequencyUni);

	// Clear the color accumulator
	fragBuilder->codeAppendf("half4 color = half4(0);");

	if (pne.stitchTiles()) {
	fragBuilder->codeAppendf("half2 stitchData = %s;", stitchDataUni);
	}

	fragBuilder->codeAppendf("half ratio = 1.0;");

	// Loop over all octaves
	fragBuilder->codeAppendf("for (int octave = 0; octave < %d; ++octave) {", pne.numOctaves());
	fragBuilder->codeAppendf("color += ");
	if (pne.type() != SkPerlinNoiseShader::kFractalNoise_Type) {
	fragBuilder->codeAppend("abs(");
	}

	// There are 4 lines, put y coords at center of each.
	static constexpr const char* chanCoordR = "0.5";
	static constexpr const char* chanCoordG = "1.5";
	static constexpr const char* chanCoordB = "2.5";
	static constexpr const char* chanCoordA = "3.5";
	if (pne.stitchTiles()) {
	fragBuilder->codeAppendf(
	"half4(%s(%s, noiseVec, stitchData), %s(%s, noiseVec, stitchData),"
	"%s(%s, noiseVec, stitchData), %s(%s, noiseVec, stitchData))",
	noiseFuncName.c_str(),
	chanCoordR,
	noiseFuncName.c_str(),
	chanCoordG,
	noiseFuncName.c_str(),
	chanCoordB,
	noiseFuncName.c_str(),
	chanCoordA);
	} else {
	fragBuilder->codeAppendf(
	"half4(%s(%s, noiseVec), %s(%s, noiseVec),"
	"%s(%s, noiseVec), %s(%s, noiseVec))",
	noiseFuncName.c_str(),
	chanCoordR,
	noiseFuncName.c_str(),
	chanCoordG,
	noiseFuncName.c_str(),
	chanCoordB,
	noiseFuncName.c_str(),
	chanCoordA);
	}
	if (pne.type() != SkPerlinNoiseShader::kFractalNoise_Type) {
	fragBuilder->codeAppend(")"); // end of "abs("
	}
	fragBuilder->codeAppend(" * ratio;");

	fragBuilder->codeAppend(
	"noiseVec *= half2(2.0);"
	"ratio *= 0.5;");

	if (pne.stitchTiles()) {
	fragBuilder->codeAppend("stitchData *= half2(2.0);");
	}
	fragBuilder->codeAppend("}"); // end of the for loop on octaves

	if (pne.type() == SkPerlinNoiseShader::kFractalNoise_Type) {
	// The value of turbulenceFunctionResult comes from ((turbulenceFunctionResult) + 1) / 2
	// by fractalNoise and (turbulenceFunctionResult) by turbulence.
	fragBuilder->codeAppendf("color = color * half4(0.5) + half4(0.5);");
	}

	// Clamp values
	fragBuilder->codeAppendf("color = saturate(color);");

	// Pre-multiply the result
	fragBuilder->codeAppendf("return half4(color.rgb * color.aaa, color.a);");
	}

	void GrPerlinNoise2Effect::Impl::onSetData(const GrGLSLProgramDataManager& pdman,
	const GrFragmentProcessor& processor) {
	const GrPerlinNoise2Effect& turbulence = processor.cast<GrPerlinNoise2Effect>();

	const SkVector& baseFrequency = turbulence.baseFrequency();
	pdman.set2f(fBaseFrequencyUni, baseFrequency.fX, baseFrequency.fY);

	if (turbulence.stitchTiles()) {
	const SkPerlinNoiseShader::StitchData& stitchData = turbulence.stitchData();
	pdman.set2f(fStitchDataUni,
	SkIntToScalar(stitchData.fWidth),
	SkIntToScalar(stitchData.fHeight));
	}
	}

	void GrPerlinNoise2Effect::onAddToKey(const GrShaderCaps& caps, skgpu::KeyBuilder* b) const {
	uint32_t key = fNumOctaves;
	key = key << 3; // Make room for next 3 bits
	switch (fType) {
	case SkPerlinNoiseShader::kFractalNoise_Type:
	key \|= 0x1;
	break;
	case SkPerlinNoiseShader::kTurbulence_Type:
	key \|= 0x2;
	break;
	default:
	// leave key at 0
	break;
	}
	if (fStitchTiles) {
	key \|= 0x4; // Flip the 3rd bit if tile stitching is on
	}
	b->add32(key);
	}