src/effects/gradients/SkTwoPointConicalGradient.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 "SkTwoPointConicalGradient.h"
 #include "SkTwoPointConicalGradient_gpu.h"

 struct TwoPtRadialContext {
     const TwoPtRadial&  fRec;
     float               fRelX, fRelY;
     const float         fIncX, fIncY;
     float               fB;
     const float         fDB;

     TwoPtRadialContext(const TwoPtRadial& rec, SkScalar fx, SkScalar fy,
                        SkScalar dfx, SkScalar dfy);
     SkFixed nextT();
 };

 static int valid_divide(float numer, float denom, float* ratio) {
     SkASSERT(ratio);
     if (0 == denom) {
         return 0;
     }
     *ratio = numer / denom;
     return 1;
 }

 // Return the number of distinct real roots, and write them into roots[] in
 // ascending order
 static int find_quad_roots(float A, float B, float C, float roots[2], bool descendingOrder = false) {
     SkASSERT(roots);

     if (A == 0) {
         return valid_divide(-C, B, roots);
     }

     float R = B*B - 4*A*C;
     if (R < 0) {
         return 0;
     }
     R = sk_float_sqrt(R);

 #if 1
     float Q = B;
     if (Q < 0) {
         Q -= R;
     } else {
         Q += R;
     }
 #else
     // on 10.6 this was much slower than the above branch :(
     float Q = B + copysignf(R, B);
 #endif
     Q *= -0.5f;
     if (0 == Q) {
         roots[0] = 0;
         return 1;
     }

     float r0 = Q / A;
     float r1 = C / Q;
     roots[0] = r0 < r1 ? r0 : r1;
     roots[1] = r0 > r1 ? r0 : r1;
     if (descendingOrder) {
         SkTSwap(roots[0], roots[1]);
     }
     return 2;
 }

 static float lerp(float x, float dx, float t) {
     return x + t * dx;
 }

 static float sqr(float x) { return x * x; }

 void TwoPtRadial::init(const SkPoint& center0, SkScalar rad0,
                        const SkPoint& center1, SkScalar rad1,
                        bool flipped) {
     fCenterX = SkScalarToFloat(center0.fX);
     fCenterY = SkScalarToFloat(center0.fY);
     fDCenterX = SkScalarToFloat(center1.fX) - fCenterX;
     fDCenterY = SkScalarToFloat(center1.fY) - fCenterY;
     fRadius = SkScalarToFloat(rad0);
     fDRadius = SkScalarToFloat(rad1) - fRadius;

     fA = sqr(fDCenterX) + sqr(fDCenterY) - sqr(fDRadius);
     fRadius2 = sqr(fRadius);
     fRDR = fRadius * fDRadius;

     fFlipped = flipped;
 }

 TwoPtRadialContext::TwoPtRadialContext(const TwoPtRadial& rec, SkScalar fx, SkScalar fy,
                                        SkScalar dfx, SkScalar dfy)
     : fRec(rec)
     , fRelX(SkScalarToFloat(fx) - rec.fCenterX)
     , fRelY(SkScalarToFloat(fy) - rec.fCenterY)
     , fIncX(SkScalarToFloat(dfx))
     , fIncY(SkScalarToFloat(dfy))
     , fB(-2 * (rec.fDCenterX * fRelX + rec.fDCenterY * fRelY + rec.fRDR))
     , fDB(-2 * (rec.fDCenterX * fIncX + rec.fDCenterY * fIncY)) {}

 SkFixed TwoPtRadialContext::nextT() {
     float roots[2];

     float C = sqr(fRelX) + sqr(fRelY) - fRec.fRadius2;
     int countRoots = find_quad_roots(fRec.fA, fB, C, roots, fRec.fFlipped);

     fRelX += fIncX;
     fRelY += fIncY;
     fB += fDB;

     if (0 == countRoots) {
         return TwoPtRadial::kDontDrawT;
     }

     // Prefer the bigger t value if both give a radius(t) > 0
     // find_quad_roots returns the values sorted, so we start with the last
     float t = roots[countRoots - 1];
     float r = lerp(fRec.fRadius, fRec.fDRadius, t);
     if (r < 0) {
         t = roots[0];   // might be the same as roots[countRoots-1]
         r = lerp(fRec.fRadius, fRec.fDRadius, t);
         if (r < 0) {
             return TwoPtRadial::kDontDrawT;
         }
     }
     return SkFloatToFixed(t);
 }

 typedef void (*TwoPointConicalProc)(TwoPtRadialContext* rec, SkPMColor* dstC,
                                     const SkPMColor* cache, int toggle, int count);

 static void twopoint_clamp(TwoPtRadialContext* rec, SkPMColor* SK_RESTRICT dstC,
                            const SkPMColor* SK_RESTRICT cache, int toggle,
                            int count) {
     for (; count > 0; --count) {
         SkFixed t = rec->nextT();
         if (TwoPtRadial::DontDrawT(t)) {
             *dstC++ = 0;
         } else {
             SkFixed index = SkClampMax(t, 0xFFFF);
             SkASSERT(index <= 0xFFFF);
             *dstC++ = cache[toggle +
                             (index >> SkGradientShaderBase::kCache32Shift)];
         }
         toggle = next_dither_toggle(toggle);
     }
 }

 static void twopoint_repeat(TwoPtRadialContext* rec, SkPMColor* SK_RESTRICT dstC,
                             const SkPMColor* SK_RESTRICT cache, int toggle,
                             int count) {
     for (; count > 0; --count) {
         SkFixed t = rec->nextT();
         if (TwoPtRadial::DontDrawT(t)) {
             *dstC++ = 0;
         } else {
             SkFixed index = repeat_tileproc(t);
             SkASSERT(index <= 0xFFFF);
             *dstC++ = cache[toggle +
                             (index >> SkGradientShaderBase::kCache32Shift)];
         }
         toggle = next_dither_toggle(toggle);
     }
 }

 static void twopoint_mirror(TwoPtRadialContext* rec, SkPMColor* SK_RESTRICT dstC,
                             const SkPMColor* SK_RESTRICT cache, int toggle,
                             int count) {
     for (; count > 0; --count) {
         SkFixed t = rec->nextT();
         if (TwoPtRadial::DontDrawT(t)) {
             *dstC++ = 0;
         } else {
             SkFixed index = mirror_tileproc(t);
             SkASSERT(index <= 0xFFFF);
             *dstC++ = cache[toggle +
                             (index >> SkGradientShaderBase::kCache32Shift)];
         }
         toggle = next_dither_toggle(toggle);
     }
 }

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

 SkTwoPointConicalGradient::SkTwoPointConicalGradient(
         const SkPoint& start, SkScalar startRadius,
         const SkPoint& end, SkScalar endRadius,
         bool flippedGrad, const Descriptor& desc)
     : SkGradientShaderBase(desc, SkMatrix::I())
     , fCenter1(start)
     , fCenter2(end)
     , fRadius1(startRadius)
     , fRadius2(endRadius)
     , fFlippedGrad(flippedGrad)
 {
     // this is degenerate, and should be caught by our caller
     SkASSERT(fCenter1 != fCenter2 || fRadius1 != fRadius2);
     fRec.init(fCenter1, fRadius1, fCenter2, fRadius2, fFlippedGrad);
 }

 bool SkTwoPointConicalGradient::isOpaque() const {
     // Because areas outside the cone are left untouched, we cannot treat the
     // shader as opaque even if the gradient itself is opaque.
     // TODO(junov): Compute whether the cone fills the plane crbug.com/222380
     return false;
 }

 size_t SkTwoPointConicalGradient::onContextSize(const ContextRec&) const {
     return sizeof(TwoPointConicalGradientContext);
 }

 SkShader::Context* SkTwoPointConicalGradient::onCreateContext(const ContextRec& rec,
                                                               void* storage) const {
     return new (storage) TwoPointConicalGradientContext(*this, rec);
 }

 SkTwoPointConicalGradient::TwoPointConicalGradientContext::TwoPointConicalGradientContext(
         const SkTwoPointConicalGradient& shader, const ContextRec& rec)
     : INHERITED(shader, rec)
 {
     // in general, we might discard based on computed-radius, so clear
     // this flag (todo: sometimes we can detect that we never discard...)
     fFlags &= ~kOpaqueAlpha_Flag;
 }

 void SkTwoPointConicalGradient::TwoPointConicalGradientContext::shadeSpan(
         int x, int y, SkPMColor* dstCParam, int count) {
     const SkTwoPointConicalGradient& twoPointConicalGradient =
             static_cast<const SkTwoPointConicalGradient&>(fShader);

     int toggle = init_dither_toggle(x, y);

     SkASSERT(count > 0);

     SkPMColor* SK_RESTRICT dstC = dstCParam;

     SkMatrix::MapXYProc dstProc = fDstToIndexProc;

     const SkPMColor* SK_RESTRICT cache = fCache->getCache32();

     TwoPointConicalProc shadeProc = twopoint_repeat;
     if (SkShader::kClamp_TileMode == twoPointConicalGradient.fTileMode) {
         shadeProc = twopoint_clamp;
     } else if (SkShader::kMirror_TileMode == twoPointConicalGradient.fTileMode) {
         shadeProc = twopoint_mirror;
     } else {
         SkASSERT(SkShader::kRepeat_TileMode == twoPointConicalGradient.fTileMode);
     }

     if (fDstToIndexClass != kPerspective_MatrixClass) {
         SkPoint srcPt;
         dstProc(fDstToIndex, SkIntToScalar(x) + SK_ScalarHalf,
                 SkIntToScalar(y) + SK_ScalarHalf, &srcPt);
         SkScalar dx, fx = srcPt.fX;
         SkScalar dy, fy = srcPt.fY;

         if (fDstToIndexClass == kFixedStepInX_MatrixClass) {
             const auto step = fDstToIndex.fixedStepInX(SkIntToScalar(y));
             dx = step.fX;
             dy = step.fY;
         } else {
             SkASSERT(fDstToIndexClass == kLinear_MatrixClass);
             dx = fDstToIndex.getScaleX();
             dy = fDstToIndex.getSkewY();
         }

         TwoPtRadialContext rec(twoPointConicalGradient.fRec, fx, fy, dx, dy);
         (*shadeProc)(&rec, dstC, cache, toggle, count);
     } else {    // perspective case
         SkScalar dstX = SkIntToScalar(x) + SK_ScalarHalf;
         SkScalar dstY = SkIntToScalar(y) + SK_ScalarHalf;
         for (; count > 0; --count) {
             SkPoint srcPt;
             dstProc(fDstToIndex, dstX, dstY, &srcPt);
             TwoPtRadialContext rec(twoPointConicalGradient.fRec, srcPt.fX, srcPt.fY, 0, 0);
             (*shadeProc)(&rec, dstC, cache, toggle, 1);

             dstX += SK_Scalar1;
             toggle = next_dither_toggle(toggle);
             dstC += 1;
         }
     }
 }

 // Returns the original non-sorted version of the gradient
 SkShader::GradientType SkTwoPointConicalGradient::asAGradient(
     GradientInfo* info) const {
     if (info) {
         commonAsAGradient(info, fFlippedGrad);
         info->fPoint[0] = fCenter1;
         info->fPoint[1] = fCenter2;
         info->fRadius[0] = fRadius1;
         info->fRadius[1] = fRadius2;
         if (fFlippedGrad) {
             SkTSwap(info->fPoint[0], info->fPoint[1]);
             SkTSwap(info->fRadius[0], info->fRadius[1]);
         }
     }
     return kConical_GradientType;
 }

 sk_sp<SkFlattenable> SkTwoPointConicalGradient::CreateProc(SkReadBuffer& buffer) {
     DescriptorScope desc;
     if (!desc.unflatten(buffer)) {
         return nullptr;
     }
     SkPoint c1 = buffer.readPoint();
     SkPoint c2 = buffer.readPoint();
     SkScalar r1 = buffer.readScalar();
     SkScalar r2 = buffer.readScalar();

     if (buffer.readBool()) {    // flipped
         SkTSwap(c1, c2);
         SkTSwap(r1, r2);

         SkColor* colors = desc.mutableColors();
         SkScalar* pos = desc.mutablePos();
         const int last = desc.fCount - 1;
         const int half = desc.fCount >> 1;
         for (int i = 0; i < half; ++i) {
             SkTSwap(colors[i], colors[last - i]);
             if (pos) {
                 SkScalar tmp = pos[i];
                 pos[i] = SK_Scalar1 - pos[last - i];
                 pos[last - i] = SK_Scalar1 - tmp;
             }
         }
         if (pos) {
             if (desc.fCount & 1) {
                 pos[half] = SK_Scalar1 - pos[half];
             }
         }
     }

     return SkGradientShader::MakeTwoPointConical(c1, r1, c2, r2, desc.fColors, desc.fPos,
                                                  desc.fCount, desc.fTileMode, desc.fGradFlags,
                                                  desc.fLocalMatrix);
 }

 void SkTwoPointConicalGradient::flatten(SkWriteBuffer& buffer) const {
     this->INHERITED::flatten(buffer);
     buffer.writePoint(fCenter1);
     buffer.writePoint(fCenter2);
     buffer.writeScalar(fRadius1);
     buffer.writeScalar(fRadius2);
     buffer.writeBool(fFlippedGrad);
 }

 #if SK_SUPPORT_GPU

 #include "SkGr.h"

 sk_sp<GrFragmentProcessor> SkTwoPointConicalGradient::asFragmentProcessor(
                                                   GrContext* context,
                                                   const SkMatrix& viewM,
                                                   const SkMatrix* localMatrix,
                                                   SkFilterQuality,
                                                   SkSourceGammaTreatment) const {
     SkASSERT(context);
     SkASSERT(fPtsToUnit.isIdentity());
     sk_sp<GrFragmentProcessor> inner(
         Gr2PtConicalGradientEffect::Make(context, *this, fTileMode, localMatrix));
     return GrFragmentProcessor::MulOutputByInputAlpha(std::move(inner));
 }

 #endif

 #ifndef SK_IGNORE_TO_STRING
 void SkTwoPointConicalGradient::toString(SkString* str) const {
     str->append("SkTwoPointConicalGradient: (");

     str->append("center1: (");
     str->appendScalar(fCenter1.fX);
     str->append(", ");
     str->appendScalar(fCenter1.fY);
     str->append(") radius1: ");
     str->appendScalar(fRadius1);
     str->append(" ");

     str->append("center2: (");
     str->appendScalar(fCenter2.fX);
     str->append(", ");
     str->appendScalar(fCenter2.fY);
     str->append(") radius2: ");
     str->appendScalar(fRadius2);
     str->append(" ");

     this->INHERITED::toString(str);

     str->append(")");
 }
 #endif
	/*
	* 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 "SkTwoPointConicalGradient.h"
	#include "SkTwoPointConicalGradient_gpu.h"

	struct TwoPtRadialContext {
	const TwoPtRadial& fRec;
	float fRelX, fRelY;
	const float fIncX, fIncY;
	float fB;
	const float fDB;

	TwoPtRadialContext(const TwoPtRadial& rec, SkScalar fx, SkScalar fy,
	SkScalar dfx, SkScalar dfy);
	SkFixed nextT();
	};

	static int valid_divide(float numer, float denom, float* ratio) {
	SkASSERT(ratio);
	if (0 == denom) {
	return 0;
	}
	*ratio = numer / denom;
	return 1;
	}

	// Return the number of distinct real roots, and write them into roots[] in
	// ascending order
	static int find_quad_roots(float A, float B, float C, float roots[2], bool descendingOrder = false) {
	SkASSERT(roots);

	if (A == 0) {
	return valid_divide(-C, B, roots);
	}

	float R = BB - 4A*C;
	if (R < 0) {
	return 0;
	}
	R = sk_float_sqrt(R);

	#if 1
	float Q = B;
	if (Q < 0) {
	Q -= R;
	} else {
	Q += R;
	}
	#else
	// on 10.6 this was much slower than the above branch :(
	float Q = B + copysignf(R, B);
	#endif
	Q *= -0.5f;
	if (0 == Q) {
	roots[0] = 0;
	return 1;
	}

	float r0 = Q / A;
	float r1 = C / Q;
	roots[0] = r0 < r1 ? r0 : r1;
	roots[1] = r0 > r1 ? r0 : r1;
	if (descendingOrder) {
	SkTSwap(roots[0], roots[1]);
	}
	return 2;
	}

	static float lerp(float x, float dx, float t) {
	return x + t * dx;
	}

	static float sqr(float x) { return x * x; }

	void TwoPtRadial::init(const SkPoint& center0, SkScalar rad0,
	const SkPoint& center1, SkScalar rad1,
	bool flipped) {
	fCenterX = SkScalarToFloat(center0.fX);
	fCenterY = SkScalarToFloat(center0.fY);
	fDCenterX = SkScalarToFloat(center1.fX) - fCenterX;
	fDCenterY = SkScalarToFloat(center1.fY) - fCenterY;
	fRadius = SkScalarToFloat(rad0);
	fDRadius = SkScalarToFloat(rad1) - fRadius;

	fA = sqr(fDCenterX) + sqr(fDCenterY) - sqr(fDRadius);
	fRadius2 = sqr(fRadius);
	fRDR = fRadius * fDRadius;

	fFlipped = flipped;
	}

	TwoPtRadialContext::TwoPtRadialContext(const TwoPtRadial& rec, SkScalar fx, SkScalar fy,
	SkScalar dfx, SkScalar dfy)
	: fRec(rec)
	, fRelX(SkScalarToFloat(fx) - rec.fCenterX)
	, fRelY(SkScalarToFloat(fy) - rec.fCenterY)
	, fIncX(SkScalarToFloat(dfx))
	, fIncY(SkScalarToFloat(dfy))
	, fB(-2 * (rec.fDCenterX * fRelX + rec.fDCenterY * fRelY + rec.fRDR))
	, fDB(-2 * (rec.fDCenterX * fIncX + rec.fDCenterY * fIncY)) {}

	SkFixed TwoPtRadialContext::nextT() {
	float roots[2];

	float C = sqr(fRelX) + sqr(fRelY) - fRec.fRadius2;
	int countRoots = find_quad_roots(fRec.fA, fB, C, roots, fRec.fFlipped);

	fRelX += fIncX;
	fRelY += fIncY;
	fB += fDB;

	if (0 == countRoots) {
	return TwoPtRadial::kDontDrawT;
	}

	// Prefer the bigger t value if both give a radius(t) > 0
	// find_quad_roots returns the values sorted, so we start with the last
	float t = roots[countRoots - 1];
	float r = lerp(fRec.fRadius, fRec.fDRadius, t);
	if (r < 0) {
	t = roots[0]; // might be the same as roots[countRoots-1]
	r = lerp(fRec.fRadius, fRec.fDRadius, t);
	if (r < 0) {
	return TwoPtRadial::kDontDrawT;
	}
	}
	return SkFloatToFixed(t);
	}

	typedef void (TwoPointConicalProc)(TwoPtRadialContext rec, SkPMColor* dstC,
	const SkPMColor* cache, int toggle, int count);

	static void twopoint_clamp(TwoPtRadialContext* rec, SkPMColor* SK_RESTRICT dstC,
	const SkPMColor* SK_RESTRICT cache, int toggle,
	int count) {
	for (; count > 0; --count) {
	SkFixed t = rec->nextT();
	if (TwoPtRadial::DontDrawT(t)) {
	*dstC++ = 0;
	} else {
	SkFixed index = SkClampMax(t, 0xFFFF);
	SkASSERT(index <= 0xFFFF);
	*dstC++ = cache[toggle +
	(index >> SkGradientShaderBase::kCache32Shift)];
	}
	toggle = next_dither_toggle(toggle);
	}
	}

	static void twopoint_repeat(TwoPtRadialContext* rec, SkPMColor* SK_RESTRICT dstC,
	const SkPMColor* SK_RESTRICT cache, int toggle,
	int count) {
	for (; count > 0; --count) {
	SkFixed t = rec->nextT();
	if (TwoPtRadial::DontDrawT(t)) {
	*dstC++ = 0;
	} else {
	SkFixed index = repeat_tileproc(t);
	SkASSERT(index <= 0xFFFF);
	*dstC++ = cache[toggle +
	(index >> SkGradientShaderBase::kCache32Shift)];
	}
	toggle = next_dither_toggle(toggle);
	}
	}

	static void twopoint_mirror(TwoPtRadialContext* rec, SkPMColor* SK_RESTRICT dstC,
	const SkPMColor* SK_RESTRICT cache, int toggle,
	int count) {
	for (; count > 0; --count) {
	SkFixed t = rec->nextT();
	if (TwoPtRadial::DontDrawT(t)) {
	*dstC++ = 0;
	} else {
	SkFixed index = mirror_tileproc(t);
	SkASSERT(index <= 0xFFFF);
	*dstC++ = cache[toggle +
	(index >> SkGradientShaderBase::kCache32Shift)];
	}
	toggle = next_dither_toggle(toggle);
	}
	}

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

	SkTwoPointConicalGradient::SkTwoPointConicalGradient(
	const SkPoint& start, SkScalar startRadius,
	const SkPoint& end, SkScalar endRadius,
	bool flippedGrad, const Descriptor& desc)
	: SkGradientShaderBase(desc, SkMatrix::I())
	, fCenter1(start)
	, fCenter2(end)
	, fRadius1(startRadius)
	, fRadius2(endRadius)
	, fFlippedGrad(flippedGrad)
	{
	// this is degenerate, and should be caught by our caller
	SkASSERT(fCenter1 != fCenter2 \|\| fRadius1 != fRadius2);
	fRec.init(fCenter1, fRadius1, fCenter2, fRadius2, fFlippedGrad);
	}

	bool SkTwoPointConicalGradient::isOpaque() const {
	// Because areas outside the cone are left untouched, we cannot treat the
	// shader as opaque even if the gradient itself is opaque.
	// TODO(junov): Compute whether the cone fills the plane crbug.com/222380
	return false;
	}

	size_t SkTwoPointConicalGradient::onContextSize(const ContextRec&) const {
	return sizeof(TwoPointConicalGradientContext);
	}

	SkShader::Context* SkTwoPointConicalGradient::onCreateContext(const ContextRec& rec,
	void* storage) const {
	return new (storage) TwoPointConicalGradientContext(*this, rec);
	}

	SkTwoPointConicalGradient::TwoPointConicalGradientContext::TwoPointConicalGradientContext(
	const SkTwoPointConicalGradient& shader, const ContextRec& rec)
	: INHERITED(shader, rec)
	{
	// in general, we might discard based on computed-radius, so clear
	// this flag (todo: sometimes we can detect that we never discard...)
	fFlags &= ~kOpaqueAlpha_Flag;
	}

	void SkTwoPointConicalGradient::TwoPointConicalGradientContext::shadeSpan(
	int x, int y, SkPMColor* dstCParam, int count) {
	const SkTwoPointConicalGradient& twoPointConicalGradient =
	static_cast<const SkTwoPointConicalGradient&>(fShader);

	int toggle = init_dither_toggle(x, y);

	SkASSERT(count > 0);

	SkPMColor* SK_RESTRICT dstC = dstCParam;

	SkMatrix::MapXYProc dstProc = fDstToIndexProc;

	const SkPMColor* SK_RESTRICT cache = fCache->getCache32();

	TwoPointConicalProc shadeProc = twopoint_repeat;
	if (SkShader::kClamp_TileMode == twoPointConicalGradient.fTileMode) {
	shadeProc = twopoint_clamp;
	} else if (SkShader::kMirror_TileMode == twoPointConicalGradient.fTileMode) {
	shadeProc = twopoint_mirror;
	} else {
	SkASSERT(SkShader::kRepeat_TileMode == twoPointConicalGradient.fTileMode);
	}

	if (fDstToIndexClass != kPerspective_MatrixClass) {
	SkPoint srcPt;
	dstProc(fDstToIndex, SkIntToScalar(x) + SK_ScalarHalf,
	SkIntToScalar(y) + SK_ScalarHalf, &srcPt);
	SkScalar dx, fx = srcPt.fX;
	SkScalar dy, fy = srcPt.fY;

	if (fDstToIndexClass == kFixedStepInX_MatrixClass) {
	const auto step = fDstToIndex.fixedStepInX(SkIntToScalar(y));
	dx = step.fX;
	dy = step.fY;
	} else {
	SkASSERT(fDstToIndexClass == kLinear_MatrixClass);
	dx = fDstToIndex.getScaleX();
	dy = fDstToIndex.getSkewY();
	}

	TwoPtRadialContext rec(twoPointConicalGradient.fRec, fx, fy, dx, dy);
	(*shadeProc)(&rec, dstC, cache, toggle, count);
	} else { // perspective case
	SkScalar dstX = SkIntToScalar(x) + SK_ScalarHalf;
	SkScalar dstY = SkIntToScalar(y) + SK_ScalarHalf;
	for (; count > 0; --count) {
	SkPoint srcPt;
	dstProc(fDstToIndex, dstX, dstY, &srcPt);
	TwoPtRadialContext rec(twoPointConicalGradient.fRec, srcPt.fX, srcPt.fY, 0, 0);
	(*shadeProc)(&rec, dstC, cache, toggle, 1);

	dstX += SK_Scalar1;
	toggle = next_dither_toggle(toggle);
	dstC += 1;
	}
	}
	}

	// Returns the original non-sorted version of the gradient
	SkShader::GradientType SkTwoPointConicalGradient::asAGradient(
	GradientInfo* info) const {
	if (info) {
	commonAsAGradient(info, fFlippedGrad);
	info->fPoint[0] = fCenter1;
	info->fPoint[1] = fCenter2;
	info->fRadius[0] = fRadius1;
	info->fRadius[1] = fRadius2;
	if (fFlippedGrad) {
	SkTSwap(info->fPoint[0], info->fPoint[1]);
	SkTSwap(info->fRadius[0], info->fRadius[1]);
	}
	}
	return kConical_GradientType;
	}

	sk_sp<SkFlattenable> SkTwoPointConicalGradient::CreateProc(SkReadBuffer& buffer) {
	DescriptorScope desc;
	if (!desc.unflatten(buffer)) {
	return nullptr;
	}
	SkPoint c1 = buffer.readPoint();
	SkPoint c2 = buffer.readPoint();
	SkScalar r1 = buffer.readScalar();
	SkScalar r2 = buffer.readScalar();

	if (buffer.readBool()) { // flipped
	SkTSwap(c1, c2);
	SkTSwap(r1, r2);

	SkColor* colors = desc.mutableColors();
	SkScalar* pos = desc.mutablePos();
	const int last = desc.fCount - 1;
	const int half = desc.fCount >> 1;
	for (int i = 0; i < half; ++i) {
	SkTSwap(colors[i], colors[last - i]);
	if (pos) {
	SkScalar tmp = pos[i];
	pos[i] = SK_Scalar1 - pos[last - i];
	pos[last - i] = SK_Scalar1 - tmp;
	}
	}
	if (pos) {
	if (desc.fCount & 1) {
	pos[half] = SK_Scalar1 - pos[half];
	}
	}
	}

	return SkGradientShader::MakeTwoPointConical(c1, r1, c2, r2, desc.fColors, desc.fPos,
	desc.fCount, desc.fTileMode, desc.fGradFlags,
	desc.fLocalMatrix);
	}

	void SkTwoPointConicalGradient::flatten(SkWriteBuffer& buffer) const {
	this->INHERITED::flatten(buffer);
	buffer.writePoint(fCenter1);
	buffer.writePoint(fCenter2);
	buffer.writeScalar(fRadius1);
	buffer.writeScalar(fRadius2);
	buffer.writeBool(fFlippedGrad);
	}

	#if SK_SUPPORT_GPU

	#include "SkGr.h"

	sk_sp<GrFragmentProcessor> SkTwoPointConicalGradient::asFragmentProcessor(
	GrContext* context,
	const SkMatrix& viewM,
	const SkMatrix* localMatrix,
	SkFilterQuality,
	SkSourceGammaTreatment) const {
	SkASSERT(context);
	SkASSERT(fPtsToUnit.isIdentity());
	sk_sp<GrFragmentProcessor> inner(
	Gr2PtConicalGradientEffect::Make(context, *this, fTileMode, localMatrix));
	return GrFragmentProcessor::MulOutputByInputAlpha(std::move(inner));
	}

	#endif

	#ifndef SK_IGNORE_TO_STRING
	void SkTwoPointConicalGradient::toString(SkString* str) const {
	str->append("SkTwoPointConicalGradient: (");

	str->append("center1: (");
	str->appendScalar(fCenter1.fX);
	str->append(", ");
	str->appendScalar(fCenter1.fY);
	str->append(") radius1: ");
	str->appendScalar(fRadius1);
	str->append(" ");

	str->append("center2: (");
	str->appendScalar(fCenter2.fX);
	str->append(", ");
	str->appendScalar(fCenter2.fY);
	str->append(") radius2: ");
	str->appendScalar(fRadius2);
	str->append(" ");

	this->INHERITED::toString(str);

	str->append(")");
	}
	#endif