src/shaders/gradients/SkSweepGradient.cpp - skia - Git at Google

 /*
  * Copyright 2012 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/private/base/SkFloatingPoint.h"
 #include "src/core/SkRasterPipeline.h"
 #include "src/core/SkReadBuffer.h"
 #include "src/core/SkWriteBuffer.h"
 #include "src/shaders/SkLocalMatrixShader.h"

 #ifdef SK_GRAPHITE_ENABLED
 #include "src/gpu/graphite/KeyHelpers.h"
 #include "src/gpu/graphite/PaintParamsKey.h"
 #endif

 #include "src/shaders/gradients/SkGradientShaderBase.h"

 class SkSweepGradient final : public SkGradientShaderBase {
 public:
     SkSweepGradient(const SkPoint& center, SkScalar t0, SkScalar t1, const Descriptor&);

     GradientType asGradient(GradientInfo* info, SkMatrix* localMatrix) const override;

 #if SK_SUPPORT_GPU
     std::unique_ptr<GrFragmentProcessor> asFragmentProcessor(const GrFPArgs&) const override;
 #endif
 #ifdef SK_GRAPHITE_ENABLED
     void addToKey(const skgpu::graphite::KeyContext&,
                   skgpu::graphite::PaintParamsKeyBuilder*,
                   skgpu::graphite::PipelineDataGatherer*) const override;
 #endif

 protected:
     void flatten(SkWriteBuffer& buffer) const override;

     void appendGradientStages(SkArenaAlloc* alloc, SkRasterPipeline* tPipeline,
                               SkRasterPipeline* postPipeline) const override;

     skvm::F32 transformT(skvm::Builder*, skvm::Uniforms*,
                          skvm::Coord coord, skvm::I32* mask) const final;
 private:
     friend void ::SkRegisterSweepGradientShaderFlattenable();
     SK_FLATTENABLE_HOOKS(SkSweepGradient)

     const SkPoint  fCenter;
     const SkScalar fTBias;
     const SkScalar fTScale;
 };

 SkSweepGradient::SkSweepGradient(const SkPoint& center, SkScalar t0, SkScalar t1,
                                  const Descriptor& desc)
     : SkGradientShaderBase(desc, SkMatrix::Translate(-center.x(), -center.y()))
     , fCenter(center)
     , fTBias(-t0)
     , fTScale(1 / (t1 - t0))
 {
     SkASSERT(t0 < t1);
 }

 SkShaderBase::GradientType SkSweepGradient::asGradient(GradientInfo* info,
                                                        SkMatrix* localMatrix) const {
     if (info) {
         commonAsAGradient(info);
         info->fPoint[0] = fCenter;
     }
     if (localMatrix) {
         *localMatrix = SkMatrix::I();
     }
     return GradientType::kSweep;
 }

 static std::tuple<SkScalar, SkScalar> angles_from_t_coeff(SkScalar tBias, SkScalar tScale) {
     return std::make_tuple(-tBias * 360, (sk_ieee_float_divide(1, tScale) - tBias) * 360);
 }

 sk_sp<SkFlattenable> SkSweepGradient::CreateProc(SkReadBuffer& buffer) {
     DescriptorScope desc;
     SkMatrix legacyLocalMatrix;
     if (!desc.unflatten(buffer, &legacyLocalMatrix)) {
         return nullptr;
     }
     const SkPoint center = buffer.readPoint();

     const auto tBias  = buffer.readScalar(),
                tScale = buffer.readScalar();
     auto [startAngle, endAngle] = angles_from_t_coeff(tBias, tScale);

     return SkGradientShader::MakeSweep(center.x(), center.y(),
                                        desc.fColors,
                                        std::move(desc.fColorSpace),
                                        desc.fPositions,
                                        desc.fColorCount,
                                        desc.fTileMode,
                                        startAngle,
                                        endAngle,
                                        desc.fInterpolation,
                                        &legacyLocalMatrix);
 }

 void SkSweepGradient::flatten(SkWriteBuffer& buffer) const {
     this->SkGradientShaderBase::flatten(buffer);
     buffer.writePoint(fCenter);
     buffer.writeScalar(fTBias);
     buffer.writeScalar(fTScale);
 }

 void SkSweepGradient::appendGradientStages(SkArenaAlloc* alloc, SkRasterPipeline* p,
                                            SkRasterPipeline*) const {
     p->append(SkRasterPipelineOp::xy_to_unit_angle);
     p->append_matrix(alloc, SkMatrix::Scale(fTScale, 1) * SkMatrix::Translate(fTBias, 0));
 }

 skvm::F32 SkSweepGradient::transformT(skvm::Builder* p, skvm::Uniforms* uniforms,
                                       skvm::Coord coord, skvm::I32* mask) const {
     skvm::F32 xabs = abs(coord.x),
               yabs = abs(coord.y),
              slope = min(xabs, yabs) / max(xabs, yabs);
     skvm::F32 s = slope * slope;

     // Use a 7th degree polynomial to approximate atan.
     // This was generated using sollya.gforge.inria.fr.
     // A float optimized polynomial was generated using the following command.
     // P1 = fpminimax((1/(2*Pi))*atan(x),[|1,3,5,7|],[|24...|],[2^(-40),1],relative);
     skvm::F32 phi = slope * poly(s, -7.0547382347285747528076171875e-3f,
                                     +2.476101927459239959716796875e-2f,
                                     -5.185396969318389892578125e-2f,
                                     +0.15912117063999176025390625f);
     phi = select(   xabs < yabs, (1/4.0f) - phi, phi);
     phi = select(coord.x < 0.0f, (1/2.0f) - phi, phi);
     phi = select(coord.y < 0.0f, (1/1.0f) - phi, phi);

     skvm::F32 t = select(is_NaN(phi), p->splat(0.0f)
                                     , phi);

     if (fTScale != 1.0f || fTBias != 0.0f) {
         t = t * p->uniformF(uniforms->pushF(fTScale))
               + p->uniformF(uniforms->pushF(fTScale*fTBias));
     }
     return t;
 }

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

 #if SK_SUPPORT_GPU

 #include "src/core/SkRuntimeEffectPriv.h"
 #include "src/gpu/ganesh/GrCaps.h"
 #include "src/gpu/ganesh/GrRecordingContextPriv.h"
 #include "src/gpu/ganesh/effects/GrSkSLFP.h"
 #include "src/gpu/ganesh/gradients/GrGradientShader.h"

 std::unique_ptr<GrFragmentProcessor> SkSweepGradient::asFragmentProcessor(
         const GrFPArgs& args) const {
     // On some devices they incorrectly implement atan2(y,x) as atan(y/x). In actuality it is
     // atan2(y,x) = 2 * atan(y / (sqrt(x^2 + y^2) + x)). So to work around this we pass in (sqrt(x^2
     // + y^2) + x) as the second parameter to atan2 in these cases. We let the device handle the
     // undefined behavior of the second paramenter being 0 instead of doing the divide ourselves and
     // using atan instead.
     int useAtanWorkaround =
             args.fContext->priv().caps()->shaderCaps()->fAtan2ImplementedAsAtanYOverX;
     static const SkRuntimeEffect* effect = SkMakeRuntimeEffect(SkRuntimeEffect::MakeForShader,
         "uniform half bias;"
         "uniform half scale;"
         "uniform int useAtanWorkaround;"  // specialized

         "half4 main(float2 coord) {"
             "half angle = bool(useAtanWorkaround)"
                     "? half(2 * atan(-coord.y, length(coord) - coord.x))"
                     ": half(atan(-coord.y, -coord.x));"

             // 0.1591549430918 is 1/(2*pi), used since atan returns values [-pi, pi]
             "half t = (angle * 0.1591549430918 + 0.5 + bias) * scale;"
             "return half4(t, 1, 0, 0);" // y = 1 for always valid
         "}"
     );

     // The sweep gradient never rejects a pixel so it doesn't change opacity
     auto fp = GrSkSLFP::Make(effect, "SweepLayout", /*inputFP=*/nullptr,
                              GrSkSLFP::OptFlags::kPreservesOpaqueInput,
                              "bias", fTBias,
                              "scale", fTScale,
                              "useAtanWorkaround", GrSkSLFP::Specialize(useAtanWorkaround));
     return GrGradientShader::MakeGradientFP(*this, args, std::move(fp));
 }

 #endif

 #ifdef SK_GRAPHITE_ENABLED
 void SkSweepGradient::addToKey(const skgpu::graphite::KeyContext& keyContext,
                                skgpu::graphite::PaintParamsKeyBuilder* builder,
                                skgpu::graphite::PipelineDataGatherer* gatherer) const {
     using namespace skgpu::graphite;

     GradientShaderBlocks::GradientData data(SkShaderBase::GradientType::kSweep,
                                             fCenter, { 0.0f, 0.0f },
                                             0.0, 0.0f,
                                             fTBias, fTScale,
                                             fTileMode,
                                             fColorCount,
                                             fColors,
                                             fPositions);

     GradientShaderBlocks::BeginBlock(keyContext, builder, gatherer, data);
     builder->endBlock();
 }
 #endif

 sk_sp<SkShader> SkGradientShader::MakeSweep(SkScalar cx, SkScalar cy,
                                             const SkColor4f colors[],
                                             sk_sp<SkColorSpace> colorSpace,
                                             const SkScalar pos[],
                                             int colorCount,
                                             SkTileMode mode,
                                             SkScalar startAngle,
                                             SkScalar endAngle,
                                             const Interpolation& interpolation,
                                             const SkMatrix* localMatrix) {
     if (!SkGradientShaderBase::ValidGradient(colors, colorCount, mode, interpolation)) {
         return nullptr;
     }
     if (1 == colorCount) {
         return SkShaders::Color(colors[0], std::move(colorSpace));
     }
     if (!SkScalarIsFinite(startAngle) || !SkScalarIsFinite(endAngle) || startAngle > endAngle) {
         return nullptr;
     }
     if (localMatrix && !localMatrix->invert(nullptr)) {
         return nullptr;
     }

     if (SkScalarNearlyEqual(startAngle, endAngle, SkGradientShaderBase::kDegenerateThreshold)) {
         // Degenerate gradient, which should follow default degenerate behavior unless it is
         // clamped and the angle is greater than 0.
         if (mode == SkTileMode::kClamp && endAngle > SkGradientShaderBase::kDegenerateThreshold) {
             // In this case, the first color is repeated from 0 to the angle, then a hardstop
             // switches to the last color (all other colors are compressed to the infinitely thin
             // interpolation region).
             static constexpr SkScalar clampPos[3] = {0, 1, 1};
             SkColor4f reColors[3] = {colors[0], colors[0], colors[colorCount - 1]};
             return MakeSweep(cx, cy, reColors, std::move(colorSpace), clampPos, 3, mode, 0,
                              endAngle, interpolation, localMatrix);
         } else {
             return SkGradientShaderBase::MakeDegenerateGradient(colors, pos, colorCount,
                                                                 std::move(colorSpace), mode);
         }
     }

     if (startAngle <= 0 && endAngle >= 360) {
         // If the t-range includes [0,1], then we can always use clamping (presumably faster).
         mode = SkTileMode::kClamp;
     }

     SkGradientShaderBase::ColorStopOptimizer opt(colors, pos, colorCount, mode);

     SkGradientShaderBase::Descriptor desc(opt.fColors, std::move(colorSpace), opt.fPos,
                                           opt.fCount, mode, interpolation);

     const SkScalar t0 = startAngle / 360,
                    t1 =   endAngle / 360;

     return SkLocalMatrixShader::MakeWrapped<SkSweepGradient>(localMatrix,
                                                              SkPoint::Make(cx, cy),
                                                              t0, t1,
                                                              desc);
 }

 sk_sp<SkShader> SkGradientShader::MakeSweep(SkScalar cx, SkScalar cy,
                                             const SkColor colors[],
                                             const SkScalar pos[],
                                             int colorCount,
                                             SkTileMode mode,
                                             SkScalar startAngle,
                                             SkScalar endAngle,
                                             uint32_t flags,
                                             const SkMatrix* localMatrix) {
     SkColorConverter converter(colors, colorCount);
     return MakeSweep(cx, cy, converter.fColors4f.begin(), nullptr, pos, colorCount,
                      mode, startAngle, endAngle, flags, localMatrix);
 }

 void SkRegisterSweepGradientShaderFlattenable() {
     SK_REGISTER_FLATTENABLE(SkSweepGradient);
 }
	/*
	* Copyright 2012 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/private/base/SkFloatingPoint.h"
	#include "src/core/SkRasterPipeline.h"
	#include "src/core/SkReadBuffer.h"
	#include "src/core/SkWriteBuffer.h"
	#include "src/shaders/SkLocalMatrixShader.h"

	#ifdef SK_GRAPHITE_ENABLED
	#include "src/gpu/graphite/KeyHelpers.h"
	#include "src/gpu/graphite/PaintParamsKey.h"
	#endif

	#include "src/shaders/gradients/SkGradientShaderBase.h"

	class SkSweepGradient final : public SkGradientShaderBase {
	public:
	SkSweepGradient(const SkPoint& center, SkScalar t0, SkScalar t1, const Descriptor&);

	GradientType asGradient(GradientInfo* info, SkMatrix* localMatrix) const override;

	#if SK_SUPPORT_GPU
	std::unique_ptr<GrFragmentProcessor> asFragmentProcessor(const GrFPArgs&) const override;
	#endif
	#ifdef SK_GRAPHITE_ENABLED
	void addToKey(const skgpu::graphite::KeyContext&,
	skgpu::graphite::PaintParamsKeyBuilder*,
	skgpu::graphite::PipelineDataGatherer*) const override;
	#endif

	protected:
	void flatten(SkWriteBuffer& buffer) const override;

	void appendGradientStages(SkArenaAlloc* alloc, SkRasterPipeline* tPipeline,
	SkRasterPipeline* postPipeline) const override;

	skvm::F32 transformT(skvm::Builder, skvm::Uniforms,
	skvm::Coord coord, skvm::I32* mask) const final;
	private:
	friend void ::SkRegisterSweepGradientShaderFlattenable();
	SK_FLATTENABLE_HOOKS(SkSweepGradient)

	const SkPoint fCenter;
	const SkScalar fTBias;
	const SkScalar fTScale;
	};

	SkSweepGradient::SkSweepGradient(const SkPoint& center, SkScalar t0, SkScalar t1,
	const Descriptor& desc)
	: SkGradientShaderBase(desc, SkMatrix::Translate(-center.x(), -center.y()))
	, fCenter(center)
	, fTBias(-t0)
	, fTScale(1 / (t1 - t0))
	{
	SkASSERT(t0 < t1);
	}

	SkShaderBase::GradientType SkSweepGradient::asGradient(GradientInfo* info,
	SkMatrix* localMatrix) const {
	if (info) {
	commonAsAGradient(info);
	info->fPoint[0] = fCenter;
	}
	if (localMatrix) {
	*localMatrix = SkMatrix::I();
	}
	return GradientType::kSweep;
	}

	static std::tuple<SkScalar, SkScalar> angles_from_t_coeff(SkScalar tBias, SkScalar tScale) {
	return std::make_tuple(-tBias * 360, (sk_ieee_float_divide(1, tScale) - tBias) * 360);
	}

	sk_sp<SkFlattenable> SkSweepGradient::CreateProc(SkReadBuffer& buffer) {
	DescriptorScope desc;
	SkMatrix legacyLocalMatrix;
	if (!desc.unflatten(buffer, &legacyLocalMatrix)) {
	return nullptr;
	}
	const SkPoint center = buffer.readPoint();

	const auto tBias = buffer.readScalar(),
	tScale = buffer.readScalar();
	auto [startAngle, endAngle] = angles_from_t_coeff(tBias, tScale);

	return SkGradientShader::MakeSweep(center.x(), center.y(),
	desc.fColors,
	std::move(desc.fColorSpace),
	desc.fPositions,
	desc.fColorCount,
	desc.fTileMode,
	startAngle,
	endAngle,
	desc.fInterpolation,
	&legacyLocalMatrix);
	}

	void SkSweepGradient::flatten(SkWriteBuffer& buffer) const {
	this->SkGradientShaderBase::flatten(buffer);
	buffer.writePoint(fCenter);
	buffer.writeScalar(fTBias);
	buffer.writeScalar(fTScale);
	}

	void SkSweepGradient::appendGradientStages(SkArenaAlloc* alloc, SkRasterPipeline* p,
	SkRasterPipeline*) const {
	p->append(SkRasterPipelineOp::xy_to_unit_angle);
	p->append_matrix(alloc, SkMatrix::Scale(fTScale, 1) * SkMatrix::Translate(fTBias, 0));
	}

	skvm::F32 SkSweepGradient::transformT(skvm::Builder* p, skvm::Uniforms* uniforms,
	skvm::Coord coord, skvm::I32* mask) const {
	skvm::F32 xabs = abs(coord.x),
	yabs = abs(coord.y),
	slope = min(xabs, yabs) / max(xabs, yabs);
	skvm::F32 s = slope * slope;

	// Use a 7th degree polynomial to approximate atan.
	// This was generated using sollya.gforge.inria.fr.
	// A float optimized polynomial was generated using the following command.
	// P1 = fpminimax((1/(2Pi))atan(x),[\|1,3,5,7\|],[\|24...\|],[2^(-40),1],relative);
	skvm::F32 phi = slope * poly(s, -7.0547382347285747528076171875e-3f,
	+2.476101927459239959716796875e-2f,
	-5.185396969318389892578125e-2f,
	+0.15912117063999176025390625f);
	phi = select( xabs < yabs, (1/4.0f) - phi, phi);
	phi = select(coord.x < 0.0f, (1/2.0f) - phi, phi);
	phi = select(coord.y < 0.0f, (1/1.0f) - phi, phi);

	skvm::F32 t = select(is_NaN(phi), p->splat(0.0f)
	, phi);

	if (fTScale != 1.0f \|\| fTBias != 0.0f) {
	t = t * p->uniformF(uniforms->pushF(fTScale))
	+ p->uniformF(uniforms->pushF(fTScale*fTBias));
	}
	return t;
	}

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

	#if SK_SUPPORT_GPU

	#include "src/core/SkRuntimeEffectPriv.h"
	#include "src/gpu/ganesh/GrCaps.h"
	#include "src/gpu/ganesh/GrRecordingContextPriv.h"
	#include "src/gpu/ganesh/effects/GrSkSLFP.h"
	#include "src/gpu/ganesh/gradients/GrGradientShader.h"

	std::unique_ptr<GrFragmentProcessor> SkSweepGradient::asFragmentProcessor(
	const GrFPArgs& args) const {
	// On some devices they incorrectly implement atan2(y,x) as atan(y/x). In actuality it is
	// atan2(y,x) = 2 * atan(y / (sqrt(x^2 + y^2) + x)). So to work around this we pass in (sqrt(x^2
	// + y^2) + x) as the second parameter to atan2 in these cases. We let the device handle the
	// undefined behavior of the second paramenter being 0 instead of doing the divide ourselves and
	// using atan instead.
	int useAtanWorkaround =
	args.fContext->priv().caps()->shaderCaps()->fAtan2ImplementedAsAtanYOverX;
	static const SkRuntimeEffect* effect = SkMakeRuntimeEffect(SkRuntimeEffect::MakeForShader,
	"uniform half bias;"
	"uniform half scale;"
	"uniform int useAtanWorkaround;" // specialized

	"half4 main(float2 coord) {"
	"half angle = bool(useAtanWorkaround)"
	"? half(2 * atan(-coord.y, length(coord) - coord.x))"
	": half(atan(-coord.y, -coord.x));"

	// 0.1591549430918 is 1/(2*pi), used since atan returns values [-pi, pi]
	"half t = (angle * 0.1591549430918 + 0.5 + bias) * scale;"
	"return half4(t, 1, 0, 0);" // y = 1 for always valid
	"}"
	);

	// The sweep gradient never rejects a pixel so it doesn't change opacity
	auto fp = GrSkSLFP::Make(effect, "SweepLayout", /inputFP=/nullptr,
	GrSkSLFP::OptFlags::kPreservesOpaqueInput,
	"bias", fTBias,
	"scale", fTScale,
	"useAtanWorkaround", GrSkSLFP::Specialize(useAtanWorkaround));
	return GrGradientShader::MakeGradientFP(*this, args, std::move(fp));
	}

	#endif

	#ifdef SK_GRAPHITE_ENABLED
	void SkSweepGradient::addToKey(const skgpu::graphite::KeyContext& keyContext,
	skgpu::graphite::PaintParamsKeyBuilder* builder,
	skgpu::graphite::PipelineDataGatherer* gatherer) const {
	using namespace skgpu::graphite;

	GradientShaderBlocks::GradientData data(SkShaderBase::GradientType::kSweep,
	fCenter, { 0.0f, 0.0f },
	0.0, 0.0f,
	fTBias, fTScale,
	fTileMode,
	fColorCount,
	fColors,
	fPositions);

	GradientShaderBlocks::BeginBlock(keyContext, builder, gatherer, data);
	builder->endBlock();
	}
	#endif

	sk_sp<SkShader> SkGradientShader::MakeSweep(SkScalar cx, SkScalar cy,
	const SkColor4f colors[],
	sk_sp<SkColorSpace> colorSpace,
	const SkScalar pos[],
	int colorCount,
	SkTileMode mode,
	SkScalar startAngle,
	SkScalar endAngle,
	const Interpolation& interpolation,
	const SkMatrix* localMatrix) {
	if (!SkGradientShaderBase::ValidGradient(colors, colorCount, mode, interpolation)) {
	return nullptr;
	}
	if (1 == colorCount) {
	return SkShaders::Color(colors[0], std::move(colorSpace));
	}
	if (!SkScalarIsFinite(startAngle) \|\| !SkScalarIsFinite(endAngle) \|\| startAngle > endAngle) {
	return nullptr;
	}
	if (localMatrix && !localMatrix->invert(nullptr)) {
	return nullptr;
	}

	if (SkScalarNearlyEqual(startAngle, endAngle, SkGradientShaderBase::kDegenerateThreshold)) {
	// Degenerate gradient, which should follow default degenerate behavior unless it is
	// clamped and the angle is greater than 0.
	if (mode == SkTileMode::kClamp && endAngle > SkGradientShaderBase::kDegenerateThreshold) {
	// In this case, the first color is repeated from 0 to the angle, then a hardstop
	// switches to the last color (all other colors are compressed to the infinitely thin
	// interpolation region).
	static constexpr SkScalar clampPos[3] = {0, 1, 1};
	SkColor4f reColors[3] = {colors[0], colors[0], colors[colorCount - 1]};
	return MakeSweep(cx, cy, reColors, std::move(colorSpace), clampPos, 3, mode, 0,
	endAngle, interpolation, localMatrix);
	} else {
	return SkGradientShaderBase::MakeDegenerateGradient(colors, pos, colorCount,
	std::move(colorSpace), mode);
	}
	}

	if (startAngle <= 0 && endAngle >= 360) {
	// If the t-range includes [0,1], then we can always use clamping (presumably faster).
	mode = SkTileMode::kClamp;
	}

	SkGradientShaderBase::ColorStopOptimizer opt(colors, pos, colorCount, mode);

	SkGradientShaderBase::Descriptor desc(opt.fColors, std::move(colorSpace), opt.fPos,
	opt.fCount, mode, interpolation);

	const SkScalar t0 = startAngle / 360,
	t1 = endAngle / 360;

	return SkLocalMatrixShader::MakeWrapped<SkSweepGradient>(localMatrix,
	SkPoint::Make(cx, cy),
	t0, t1,
	desc);
	}

	sk_sp<SkShader> SkGradientShader::MakeSweep(SkScalar cx, SkScalar cy,
	const SkColor colors[],
	const SkScalar pos[],
	int colorCount,
	SkTileMode mode,
	SkScalar startAngle,
	SkScalar endAngle,
	uint32_t flags,
	const SkMatrix* localMatrix) {
	SkColorConverter converter(colors, colorCount);
	return MakeSweep(cx, cy, converter.fColors4f.begin(), nullptr, pos, colorCount,
	mode, startAngle, endAngle, flags, localMatrix);
	}

	void SkRegisterSweepGradientShaderFlattenable() {
	SK_REGISTER_FLATTENABLE(SkSweepGradient);
	}