samplecode/SampleSimpleStroker.cpp - skia - Git at Google

 /*
  * Copyright 2020 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkBitmap.h"
 #include "include/core/SkCanvas.h"
 #include "include/core/SkPath.h"
 #include "include/utils/SkParsePath.h"
 #include "samplecode/Sample.h"

 #include "src/core/SkGeometry.h"

 namespace {

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

 static SkPoint rotate90(const SkPoint& p) { return {p.fY, -p.fX}; }
 static SkPoint rotate180(const SkPoint& p) { return p * -1; }
 static SkPoint setLength(SkPoint p, float len) {
     if (!p.setLength(len)) {
         SkDebugf("Failed to set point length\n");
     }
     return p;
 }
 static bool isClockwise(const SkPoint& a, const SkPoint& b) { return a.cross(b) > 0; }

 //////////////////////////////////////////////////////////////////////////////
 // Testing ground for a new stroker implementation

 /** Helper class for constructing paths, with undo support */
 class PathRecorder {
 public:
     SkPath getPath() const {
         return SkPath::Make(fPoints.data(), fPoints.size(), fVerbs.data(), fVerbs.size(), nullptr,
                             0, SkPathFillType::kWinding);
     }

     void moveTo(SkPoint p) {
         fVerbs.push_back(SkPath::kMove_Verb);
         fPoints.push_back(p);
     }

     void lineTo(SkPoint p) {
         fVerbs.push_back(SkPath::kLine_Verb);
         fPoints.push_back(p);
     }

     void close() { fVerbs.push_back(SkPath::kClose_Verb); }

     void rewind() {
         fVerbs.clear();
         fPoints.clear();
     }

     int countPoints() const { return fPoints.size(); }

     int countVerbs() const { return fVerbs.size(); }

     bool getLastPt(SkPoint* lastPt) const {
         if (fPoints.empty()) {
             return false;
         }
         *lastPt = fPoints.back();
         return true;
     }

     void setLastPt(SkPoint lastPt) {
         if (fPoints.empty()) {
             moveTo(lastPt);
         } else {
             fPoints.back().set(lastPt.fX, lastPt.fY);
         }
     }

     const std::vector<uint8_t>& verbs() const { return fVerbs; }

     const std::vector<SkPoint>& points() const { return fPoints; }

 private:
     std::vector<uint8_t> fVerbs;
     std::vector<SkPoint> fPoints;
 };

 class SkPathStroker2 {
 public:
     // Returns the fill path
     SkPath getFillPath(const SkPath& path, const SkPaint& paint);

 private:
     struct PathSegment {
         SkPath::Verb fVerb;
         SkPoint fPoints[4];
     };

     float fRadius;
     SkPaint::Cap fCap;
     SkPaint::Join fJoin;
     PathRecorder fInner, fOuter;

     // Initialize stroker state
     void initForPath(const SkPath& path, const SkPaint& paint);

     // Strokes a line segment
     void strokeLine(const PathSegment& line, bool needsMove);

     // Adds an endcap to fOuter
     enum class CapLocation { Start, End };
     void endcap(CapLocation loc);

     // Adds a join between the two segments
     void join(const PathSegment& prev, const PathSegment& curr);

     // Appends path in reverse to result
     static void appendPathReversed(const PathRecorder& path, PathRecorder* result);

     // Returns the segment unit normal
     static SkPoint unitNormal(const PathSegment& seg, float t);

     // Returns squared magnitude of line segments.
     static float squaredLineLength(const PathSegment& lineSeg);
 };

 void SkPathStroker2::initForPath(const SkPath& path, const SkPaint& paint) {
     fRadius = paint.getStrokeWidth() / 2;
     fCap = paint.getStrokeCap();
     fJoin = paint.getStrokeJoin();
     fInner.rewind();
     fOuter.rewind();
 }

 SkPath SkPathStroker2::getFillPath(const SkPath& path, const SkPaint& paint) {
     initForPath(path, paint);

     // Trace the inner and outer paths simultaneously. Inner will therefore be
     // recorded in reverse from how we trace the outline.
     SkPath::Iter it(path, false);
     PathSegment segment, prevSegment;
     bool firstSegment = true;
     while ((segment.fVerb = it.next(segment.fPoints)) != SkPath::kDone_Verb) {
         // Join to the previous segment
         if (!firstSegment) {
             join(prevSegment, segment);
         }

         // Stroke the current segment
         switch (segment.fVerb) {
             case SkPath::kLine_Verb:
                 strokeLine(segment, firstSegment);
                 break;
             case SkPath::kMove_Verb:
                 // Don't care about multiple contours currently
                 continue;
             default:
                 SkDebugf("Unhandled path verb %d\n", segment.fVerb);
                 break;
         }

         std::swap(segment, prevSegment);
         firstSegment = false;
     }

     // Open contour => endcap at the end
     const bool isClosed = path.isLastContourClosed();
     if (isClosed) {
         SkDebugf("Unhandled closed contour\n");
     } else {
         endcap(CapLocation::End);
     }

     // Walk inner path in reverse, appending to result
     appendPathReversed(fInner, &fOuter);
     endcap(CapLocation::Start);

     return fOuter.getPath();
 }

 void SkPathStroker2::strokeLine(const PathSegment& line, bool needsMove) {
     const SkPoint tangent = line.fPoints[1] - line.fPoints[0];
     const SkPoint normal = rotate90(tangent);
     const SkPoint offset = setLength(normal, fRadius);
     if (needsMove) {
         fOuter.moveTo(line.fPoints[0] + offset);
         fInner.moveTo(line.fPoints[0] - offset);
     }
     fOuter.lineTo(line.fPoints[1] + offset);
     fInner.lineTo(line.fPoints[1] - offset);
 }

 void SkPathStroker2::endcap(CapLocation loc) {
     const auto buttCap = [this](CapLocation loc) {
         if (loc == CapLocation::Start) {
             // Back at the start of the path: just close the stroked outline
             fOuter.close();
         } else {
             // Inner last pt == first pt when appending in reverse
             SkPoint innerLastPt;
             fInner.getLastPt(&innerLastPt);
             fOuter.lineTo(innerLastPt);
         }
     };

     switch (fCap) {
         case SkPaint::kButt_Cap:
             buttCap(loc);
             break;
         default:
             SkDebugf("Unhandled endcap %d\n", fCap);
             buttCap(loc);
             break;
     }
 }

 void SkPathStroker2::join(const PathSegment& prev, const PathSegment& curr) {
     const auto miterJoin = [this](const PathSegment& prev, const PathSegment& curr) {
         // Common path endpoint of the two segments is the midpoint of the miter line.
         const SkPoint miterMidpt = curr.fPoints[0];

         SkPoint before = unitNormal(prev, 1);
         SkPoint after = unitNormal(curr, 0);

         // Check who's inside and who's outside.
         PathRecorder *outer = &fOuter, *inner = &fInner;
         if (!isClockwise(before, after)) {
             std::swap(inner, outer);
             before = rotate180(before);
             after = rotate180(after);
         }

         const float cosTheta = before.dot(after);
         if (SkScalarNearlyZero(1 - cosTheta)) {
             // Nearly identical normals: don't bother.
             return;
         }

         // Before and after have the same origin and magnitude, so before+after is the diagonal of
         // their rhombus. Origin of this vector is the midpoint of the miter line.
         SkPoint miterVec = before + after;

         // Note the relationship (draw a right triangle with the miter line as its hypoteneuse):
         //     sin(theta/2) = strokeWidth / miterLength
         // so miterLength = strokeWidth / sin(theta/2)
         // where miterLength is the length of the miter from outer point to inner corner.
         // miterVec's origin is the midpoint of the miter line, so we use strokeWidth/2.
         // Sqrt is just an application of half-angle identities.
         const float sinHalfTheta = sqrtf(0.5 * (1 + cosTheta));
         const float halfMiterLength = fRadius / sinHalfTheta;
         miterVec.setLength(halfMiterLength);  // TODO: miter length limit

         // Outer: connect to the miter point, and then to t=0 (on outside stroke) of next segment.
         const SkPoint dest = setLength(after, fRadius);
         outer->lineTo(miterMidpt + miterVec);
         outer->lineTo(miterMidpt + dest);

         // Inner miter is more involved. We're already at t=1 (on inside stroke) of 'prev'.
         // Check 2 cases to see we can directly connect to the inner miter point
         // (midpoint - miterVec), or if we need to add extra "loop" geometry.
         const SkPoint prevUnitTangent = rotate90(before);
         const float radiusSquared = fRadius * fRadius;
         // 'alpha' is angle between prev tangent and the curr inwards normal
         const float cosAlpha = prevUnitTangent.dot(-after);
         // Solve triangle for len^2:  radius^2 = len^2 + (radius * sin(alpha))^2
         // This is the point at which the inside "corner" of curr at t=0 will lie on a
         // line connecting the inner and outer corners of prev at t=0. If len is below
         // this threshold, the inside corner of curr will "poke through" the start of prev,
         // and we'll need the inner loop geometry.
         const float threshold1 = radiusSquared * cosAlpha * cosAlpha;
         // Solve triangle for len^2:  halfMiterLen^2 = radius^2 + len^2
         // This is the point at which the inner miter point will lie on the inner stroke
         // boundary of the curr segment. If len is below this threshold, the miter point
         // moves 'inside' of the stroked outline, and we'll need the inner loop geometry.
         const float threshold2 = halfMiterLength * halfMiterLength - radiusSquared;
         // If a segment length is smaller than the larger of the two thresholds,
         // we'll have to add the inner loop geometry.
         const float maxLenSqd = std::max(threshold1, threshold2);
         const bool needsInnerLoop =
                 squaredLineLength(prev) < maxLenSqd || squaredLineLength(curr) < maxLenSqd;
         if (needsInnerLoop) {
             // Connect to the miter midpoint (common path endpoint of the two segments),
             // and then to t=0 (on inside) of the next segment. This adds an interior "loop" of
             // geometry that handles edge cases where segment lengths are shorter than the
             // stroke width.
             inner->lineTo(miterMidpt);
             inner->lineTo(miterMidpt - dest);
         } else {
             // Directly connect to inner miter point.
             inner->setLastPt(miterMidpt - miterVec);
         }
     };

     switch (fJoin) {
         case SkPaint::kMiter_Join:
             miterJoin(prev, curr);
             break;
         default:
             SkDebugf("Unhandled join %d\n", fJoin);
             miterJoin(prev, curr);
             break;
     }
 }

 void SkPathStroker2::appendPathReversed(const PathRecorder& path, PathRecorder* result) {
     const int numVerbs = path.countVerbs();
     const int numPoints = path.countPoints();
     const std::vector<uint8_t>& verbs = path.verbs();
     const std::vector<SkPoint>& points = path.points();

     for (int i = numVerbs - 1, j = numPoints; i >= 0; i--) {
         auto verb = static_cast<SkPath::Verb>(verbs[i]);
         switch (verb) {
             case SkPath::kLine_Verb: {
                 j -= 1;
                 SkASSERT(j >= 1);
                 result->lineTo(points[j - 1]);
                 break;
             }
             case SkPath::kMove_Verb:
                 // Ignore
                 break;
             default:
                 SkASSERT(false);
                 break;
         }
     }
 }

 SkPoint SkPathStroker2::unitNormal(const PathSegment& seg, float t) {
     if (seg.fVerb != SkPath::kLine_Verb) {
         SkDebugf("Unhandled verb for unit normal %d\n", seg.fVerb);
     }

     (void)t;  // Not needed for lines
     const SkPoint tangent = seg.fPoints[1] - seg.fPoints[0];
     const SkPoint normal = rotate90(tangent);
     return setLength(normal, 1);
 }

 float SkPathStroker2::squaredLineLength(const PathSegment& lineSeg) {
     SkASSERT(lineSeg.fVerb == SkPath::kLine_Verb);
     const SkPoint diff = lineSeg.fPoints[1] - lineSeg.fPoints[0];
     return diff.dot(diff);
 }

 }  // namespace

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

 class SimpleStroker : public Sample {
     bool fShowSkiaStroke, fShowHidden, fShowSkeleton;
     float fWidth = 175;
     SkPaint fPtsPaint, fStrokePaint, fMirrorStrokePaint, fNewFillPaint, fHiddenPaint,
             fSkeletonPaint;
     inline static constexpr int kN = 3;

 public:
     SkPoint fPts[kN];

     SimpleStroker() : fShowSkiaStroke(true), fShowHidden(true), fShowSkeleton(true) {
         fPts[0] = {500, 200};
         fPts[1] = {300, 200};
         fPts[2] = {100, 100};

         fPtsPaint.setAntiAlias(true);
         fPtsPaint.setStrokeWidth(10);
         fPtsPaint.setStrokeCap(SkPaint::kRound_Cap);

         fStrokePaint.setAntiAlias(true);
         fStrokePaint.setStyle(SkPaint::kStroke_Style);
         fStrokePaint.setColor(0x80FF0000);

         fMirrorStrokePaint.setAntiAlias(true);
         fMirrorStrokePaint.setStyle(SkPaint::kStroke_Style);
         fMirrorStrokePaint.setColor(0x80FFFF00);

         fNewFillPaint.setAntiAlias(true);
         fNewFillPaint.setColor(0x8000FF00);

         fHiddenPaint.setAntiAlias(true);
         fHiddenPaint.setStyle(SkPaint::kStroke_Style);
         fHiddenPaint.setColor(0xFF0000FF);

         fSkeletonPaint.setAntiAlias(true);
         fSkeletonPaint.setStyle(SkPaint::kStroke_Style);
         fSkeletonPaint.setColor(SK_ColorRED);
     }

     void toggle(bool& value) { value = !value; }

 protected:
     SkString name() override { return SkString("SimpleStroker"); }

     bool onChar(SkUnichar uni) override {
         switch (uni) {
             case '1':
                 this->toggle(fShowSkeleton);
                 return true;
             case '2':
                 this->toggle(fShowSkiaStroke);
                 return true;
             case '3':
                 this->toggle(fShowHidden);
                 return true;
             case '-':
                 fWidth -= 5;
                 return true;
             case '=':
                 fWidth += 5;
                 return true;
             default:
                 break;
         }
         return false;
     }

     void makePath(SkPath* path) {
         path->moveTo(fPts[0]);
         for (int i = 1; i < kN; ++i) {
             path->lineTo(fPts[i]);
         }
     }

     void onDrawContent(SkCanvas* canvas) override {
         canvas->drawColor(0xFFEEEEEE);

         SkPath path;
         this->makePath(&path);

         fStrokePaint.setStrokeWidth(fWidth);

         // The correct result
         if (fShowSkiaStroke) {
             canvas->drawPath(path, fStrokePaint);
         }

         // Simple stroker result
         SkPathStroker2 stroker;
         SkPath fillPath = stroker.getFillPath(path, fStrokePaint);
         canvas->drawPath(fillPath, fNewFillPaint);

         if (fShowHidden) {
             canvas->drawPath(fillPath, fHiddenPaint);
         }
         if (fShowSkeleton) {
             canvas->drawPath(path, fSkeletonPaint);
         }
         canvas->drawPoints(SkCanvas::kPoints_PointMode, kN, fPts, fPtsPaint);

         // Draw a mirror but using Skia's stroker.
         canvas->translate(0, 400);
         fMirrorStrokePaint.setStrokeWidth(fWidth);
         canvas->drawPath(path, fMirrorStrokePaint);
         if (fShowHidden) {
             SkPath hidden;
             fStrokePaint.getFillPath(path, &hidden);
             canvas->drawPath(hidden, fHiddenPaint);
         }
         if (fShowSkeleton) {
             canvas->drawPath(path, fSkeletonPaint);
         }
     }

     Sample::Click* onFindClickHandler(SkScalar x, SkScalar y, skui::ModifierKey modi) override {
         const SkScalar tol = 4;
         const SkRect r = SkRect::MakeXYWH(x - tol, y - tol, tol * 2, tol * 2);
         for (int i = 0; i < kN; ++i) {
             if (r.intersects(SkRect::MakeXYWH(fPts[i].fX, fPts[i].fY, 1, 1))) {
                 return new Click([this, i](Click* c) {
                     fPts[i] = c->fCurr;
                     return true;
                 });
             }
         }
         return nullptr;
     }

 private:
     using INHERITED = Sample;
 };

 DEF_SAMPLE(return new SimpleStroker;)
	/*
	* Copyright 2020 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkBitmap.h"
	#include "include/core/SkCanvas.h"
	#include "include/core/SkPath.h"
	#include "include/utils/SkParsePath.h"
	#include "samplecode/Sample.h"

	#include "src/core/SkGeometry.h"

	namespace {

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

	static SkPoint rotate90(const SkPoint& p) { return {p.fY, -p.fX}; }
	static SkPoint rotate180(const SkPoint& p) { return p * -1; }
	static SkPoint setLength(SkPoint p, float len) {
	if (!p.setLength(len)) {
	SkDebugf("Failed to set point length\n");
	}
	return p;
	}
	static bool isClockwise(const SkPoint& a, const SkPoint& b) { return a.cross(b) > 0; }

	//////////////////////////////////////////////////////////////////////////////
	// Testing ground for a new stroker implementation

	/** Helper class for constructing paths, with undo support */
	class PathRecorder {
	public:
	SkPath getPath() const {
	return SkPath::Make(fPoints.data(), fPoints.size(), fVerbs.data(), fVerbs.size(), nullptr,
	0, SkPathFillType::kWinding);
	}

	void moveTo(SkPoint p) {
	fVerbs.push_back(SkPath::kMove_Verb);
	fPoints.push_back(p);
	}

	void lineTo(SkPoint p) {
	fVerbs.push_back(SkPath::kLine_Verb);
	fPoints.push_back(p);
	}

	void close() { fVerbs.push_back(SkPath::kClose_Verb); }

	void rewind() {
	fVerbs.clear();
	fPoints.clear();
	}

	int countPoints() const { return fPoints.size(); }

	int countVerbs() const { return fVerbs.size(); }

	bool getLastPt(SkPoint* lastPt) const {
	if (fPoints.empty()) {
	return false;
	}
	*lastPt = fPoints.back();
	return true;
	}

	void setLastPt(SkPoint lastPt) {
	if (fPoints.empty()) {
	moveTo(lastPt);
	} else {
	fPoints.back().set(lastPt.fX, lastPt.fY);
	}
	}

	const std::vector<uint8_t>& verbs() const { return fVerbs; }

	const std::vector<SkPoint>& points() const { return fPoints; }

	private:
	std::vector<uint8_t> fVerbs;
	std::vector<SkPoint> fPoints;
	};

	class SkPathStroker2 {
	public:
	// Returns the fill path
	SkPath getFillPath(const SkPath& path, const SkPaint& paint);

	private:
	struct PathSegment {
	SkPath::Verb fVerb;
	SkPoint fPoints[4];
	};

	float fRadius;
	SkPaint::Cap fCap;
	SkPaint::Join fJoin;
	PathRecorder fInner, fOuter;

	// Initialize stroker state
	void initForPath(const SkPath& path, const SkPaint& paint);

	// Strokes a line segment
	void strokeLine(const PathSegment& line, bool needsMove);

	// Adds an endcap to fOuter
	enum class CapLocation { Start, End };
	void endcap(CapLocation loc);

	// Adds a join between the two segments
	void join(const PathSegment& prev, const PathSegment& curr);

	// Appends path in reverse to result
	static void appendPathReversed(const PathRecorder& path, PathRecorder* result);

	// Returns the segment unit normal
	static SkPoint unitNormal(const PathSegment& seg, float t);

	// Returns squared magnitude of line segments.
	static float squaredLineLength(const PathSegment& lineSeg);
	};

	void SkPathStroker2::initForPath(const SkPath& path, const SkPaint& paint) {
	fRadius = paint.getStrokeWidth() / 2;
	fCap = paint.getStrokeCap();
	fJoin = paint.getStrokeJoin();
	fInner.rewind();
	fOuter.rewind();
	}

	SkPath SkPathStroker2::getFillPath(const SkPath& path, const SkPaint& paint) {
	initForPath(path, paint);

	// Trace the inner and outer paths simultaneously. Inner will therefore be
	// recorded in reverse from how we trace the outline.
	SkPath::Iter it(path, false);
	PathSegment segment, prevSegment;
	bool firstSegment = true;
	while ((segment.fVerb = it.next(segment.fPoints)) != SkPath::kDone_Verb) {
	// Join to the previous segment
	if (!firstSegment) {
	join(prevSegment, segment);
	}

	// Stroke the current segment
	switch (segment.fVerb) {
	case SkPath::kLine_Verb:
	strokeLine(segment, firstSegment);
	break;
	case SkPath::kMove_Verb:
	// Don't care about multiple contours currently
	continue;
	default:
	SkDebugf("Unhandled path verb %d\n", segment.fVerb);
	break;
	}

	std::swap(segment, prevSegment);
	firstSegment = false;
	}

	// Open contour => endcap at the end
	const bool isClosed = path.isLastContourClosed();
	if (isClosed) {
	SkDebugf("Unhandled closed contour\n");
	} else {
	endcap(CapLocation::End);
	}

	// Walk inner path in reverse, appending to result
	appendPathReversed(fInner, &fOuter);
	endcap(CapLocation::Start);

	return fOuter.getPath();
	}

	void SkPathStroker2::strokeLine(const PathSegment& line, bool needsMove) {
	const SkPoint tangent = line.fPoints[1] - line.fPoints[0];
	const SkPoint normal = rotate90(tangent);
	const SkPoint offset = setLength(normal, fRadius);
	if (needsMove) {
	fOuter.moveTo(line.fPoints[0] + offset);
	fInner.moveTo(line.fPoints[0] - offset);
	}
	fOuter.lineTo(line.fPoints[1] + offset);
	fInner.lineTo(line.fPoints[1] - offset);
	}

	void SkPathStroker2::endcap(CapLocation loc) {
	const auto buttCap = [this](CapLocation loc) {
	if (loc == CapLocation::Start) {
	// Back at the start of the path: just close the stroked outline
	fOuter.close();
	} else {
	// Inner last pt == first pt when appending in reverse
	SkPoint innerLastPt;
	fInner.getLastPt(&innerLastPt);
	fOuter.lineTo(innerLastPt);
	}
	};

	switch (fCap) {
	case SkPaint::kButt_Cap:
	buttCap(loc);
	break;
	default:
	SkDebugf("Unhandled endcap %d\n", fCap);
	buttCap(loc);
	break;
	}
	}

	void SkPathStroker2::join(const PathSegment& prev, const PathSegment& curr) {
	const auto miterJoin = [this](const PathSegment& prev, const PathSegment& curr) {
	// Common path endpoint of the two segments is the midpoint of the miter line.
	const SkPoint miterMidpt = curr.fPoints[0];

	SkPoint before = unitNormal(prev, 1);
	SkPoint after = unitNormal(curr, 0);

	// Check who's inside and who's outside.
	PathRecorder outer = &fOuter, inner = &fInner;
	if (!isClockwise(before, after)) {
	std::swap(inner, outer);
	before = rotate180(before);
	after = rotate180(after);
	}

	const float cosTheta = before.dot(after);
	if (SkScalarNearlyZero(1 - cosTheta)) {
	// Nearly identical normals: don't bother.
	return;
	}

	// Before and after have the same origin and magnitude, so before+after is the diagonal of
	// their rhombus. Origin of this vector is the midpoint of the miter line.
	SkPoint miterVec = before + after;

	// Note the relationship (draw a right triangle with the miter line as its hypoteneuse):
	// sin(theta/2) = strokeWidth / miterLength
	// so miterLength = strokeWidth / sin(theta/2)
	// where miterLength is the length of the miter from outer point to inner corner.
	// miterVec's origin is the midpoint of the miter line, so we use strokeWidth/2.
	// Sqrt is just an application of half-angle identities.
	const float sinHalfTheta = sqrtf(0.5 * (1 + cosTheta));
	const float halfMiterLength = fRadius / sinHalfTheta;
	miterVec.setLength(halfMiterLength); // TODO: miter length limit

	// Outer: connect to the miter point, and then to t=0 (on outside stroke) of next segment.
	const SkPoint dest = setLength(after, fRadius);
	outer->lineTo(miterMidpt + miterVec);
	outer->lineTo(miterMidpt + dest);

	// Inner miter is more involved. We're already at t=1 (on inside stroke) of 'prev'.
	// Check 2 cases to see we can directly connect to the inner miter point
	// (midpoint - miterVec), or if we need to add extra "loop" geometry.
	const SkPoint prevUnitTangent = rotate90(before);
	const float radiusSquared = fRadius * fRadius;
	// 'alpha' is angle between prev tangent and the curr inwards normal
	const float cosAlpha = prevUnitTangent.dot(-after);
	// Solve triangle for len^2: radius^2 = len^2 + (radius * sin(alpha))^2
	// This is the point at which the inside "corner" of curr at t=0 will lie on a
	// line connecting the inner and outer corners of prev at t=0. If len is below
	// this threshold, the inside corner of curr will "poke through" the start of prev,
	// and we'll need the inner loop geometry.
	const float threshold1 = radiusSquared * cosAlpha * cosAlpha;
	// Solve triangle for len^2: halfMiterLen^2 = radius^2 + len^2
	// This is the point at which the inner miter point will lie on the inner stroke
	// boundary of the curr segment. If len is below this threshold, the miter point
	// moves 'inside' of the stroked outline, and we'll need the inner loop geometry.
	const float threshold2 = halfMiterLength * halfMiterLength - radiusSquared;
	// If a segment length is smaller than the larger of the two thresholds,
	// we'll have to add the inner loop geometry.
	const float maxLenSqd = std::max(threshold1, threshold2);
	const bool needsInnerLoop =
	squaredLineLength(prev) < maxLenSqd \|\| squaredLineLength(curr) < maxLenSqd;
	if (needsInnerLoop) {
	// Connect to the miter midpoint (common path endpoint of the two segments),
	// and then to t=0 (on inside) of the next segment. This adds an interior "loop" of
	// geometry that handles edge cases where segment lengths are shorter than the
	// stroke width.
	inner->lineTo(miterMidpt);
	inner->lineTo(miterMidpt - dest);
	} else {
	// Directly connect to inner miter point.
	inner->setLastPt(miterMidpt - miterVec);
	}
	};

	switch (fJoin) {
	case SkPaint::kMiter_Join:
	miterJoin(prev, curr);
	break;
	default:
	SkDebugf("Unhandled join %d\n", fJoin);
	miterJoin(prev, curr);
	break;
	}
	}

	void SkPathStroker2::appendPathReversed(const PathRecorder& path, PathRecorder* result) {
	const int numVerbs = path.countVerbs();
	const int numPoints = path.countPoints();
	const std::vector<uint8_t>& verbs = path.verbs();
	const std::vector<SkPoint>& points = path.points();

	for (int i = numVerbs - 1, j = numPoints; i >= 0; i--) {
	auto verb = static_cast<SkPath::Verb>(verbs[i]);
	switch (verb) {
	case SkPath::kLine_Verb: {
	j -= 1;
	SkASSERT(j >= 1);
	result->lineTo(points[j - 1]);
	break;
	}
	case SkPath::kMove_Verb:
	// Ignore
	break;
	default:
	SkASSERT(false);
	break;
	}
	}
	}

	SkPoint SkPathStroker2::unitNormal(const PathSegment& seg, float t) {
	if (seg.fVerb != SkPath::kLine_Verb) {
	SkDebugf("Unhandled verb for unit normal %d\n", seg.fVerb);
	}

	(void)t; // Not needed for lines
	const SkPoint tangent = seg.fPoints[1] - seg.fPoints[0];
	const SkPoint normal = rotate90(tangent);
	return setLength(normal, 1);
	}

	float SkPathStroker2::squaredLineLength(const PathSegment& lineSeg) {
	SkASSERT(lineSeg.fVerb == SkPath::kLine_Verb);
	const SkPoint diff = lineSeg.fPoints[1] - lineSeg.fPoints[0];
	return diff.dot(diff);
	}

	} // namespace

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

	class SimpleStroker : public Sample {
	bool fShowSkiaStroke, fShowHidden, fShowSkeleton;
	float fWidth = 175;
	SkPaint fPtsPaint, fStrokePaint, fMirrorStrokePaint, fNewFillPaint, fHiddenPaint,
	fSkeletonPaint;
	inline static constexpr int kN = 3;

	public:
	SkPoint fPts[kN];

	SimpleStroker() : fShowSkiaStroke(true), fShowHidden(true), fShowSkeleton(true) {
	fPts[0] = {500, 200};
	fPts[1] = {300, 200};
	fPts[2] = {100, 100};

	fPtsPaint.setAntiAlias(true);
	fPtsPaint.setStrokeWidth(10);
	fPtsPaint.setStrokeCap(SkPaint::kRound_Cap);

	fStrokePaint.setAntiAlias(true);
	fStrokePaint.setStyle(SkPaint::kStroke_Style);
	fStrokePaint.setColor(0x80FF0000);

	fMirrorStrokePaint.setAntiAlias(true);
	fMirrorStrokePaint.setStyle(SkPaint::kStroke_Style);
	fMirrorStrokePaint.setColor(0x80FFFF00);

	fNewFillPaint.setAntiAlias(true);
	fNewFillPaint.setColor(0x8000FF00);

	fHiddenPaint.setAntiAlias(true);
	fHiddenPaint.setStyle(SkPaint::kStroke_Style);
	fHiddenPaint.setColor(0xFF0000FF);

	fSkeletonPaint.setAntiAlias(true);
	fSkeletonPaint.setStyle(SkPaint::kStroke_Style);
	fSkeletonPaint.setColor(SK_ColorRED);
	}

	void toggle(bool& value) { value = !value; }

	protected:
	SkString name() override { return SkString("SimpleStroker"); }

	bool onChar(SkUnichar uni) override {
	switch (uni) {
	case '1':
	this->toggle(fShowSkeleton);
	return true;
	case '2':
	this->toggle(fShowSkiaStroke);
	return true;
	case '3':
	this->toggle(fShowHidden);
	return true;
	case '-':
	fWidth -= 5;
	return true;
	case '=':
	fWidth += 5;
	return true;
	default:
	break;
	}
	return false;
	}

	void makePath(SkPath* path) {
	path->moveTo(fPts[0]);
	for (int i = 1; i < kN; ++i) {
	path->lineTo(fPts[i]);
	}
	}

	void onDrawContent(SkCanvas* canvas) override {
	canvas->drawColor(0xFFEEEEEE);

	SkPath path;
	this->makePath(&path);

	fStrokePaint.setStrokeWidth(fWidth);

	// The correct result
	if (fShowSkiaStroke) {
	canvas->drawPath(path, fStrokePaint);
	}

	// Simple stroker result
	SkPathStroker2 stroker;
	SkPath fillPath = stroker.getFillPath(path, fStrokePaint);
	canvas->drawPath(fillPath, fNewFillPaint);

	if (fShowHidden) {
	canvas->drawPath(fillPath, fHiddenPaint);
	}
	if (fShowSkeleton) {
	canvas->drawPath(path, fSkeletonPaint);
	}
	canvas->drawPoints(SkCanvas::kPoints_PointMode, kN, fPts, fPtsPaint);

	// Draw a mirror but using Skia's stroker.
	canvas->translate(0, 400);
	fMirrorStrokePaint.setStrokeWidth(fWidth);
	canvas->drawPath(path, fMirrorStrokePaint);
	if (fShowHidden) {
	SkPath hidden;
	fStrokePaint.getFillPath(path, &hidden);
	canvas->drawPath(hidden, fHiddenPaint);
	}
	if (fShowSkeleton) {
	canvas->drawPath(path, fSkeletonPaint);
	}
	}

	Sample::Click* onFindClickHandler(SkScalar x, SkScalar y, skui::ModifierKey modi) override {
	const SkScalar tol = 4;
	const SkRect r = SkRect::MakeXYWH(x - tol, y - tol, tol * 2, tol * 2);
	for (int i = 0; i < kN; ++i) {
	if (r.intersects(SkRect::MakeXYWH(fPts[i].fX, fPts[i].fY, 1, 1))) {
	return new Click([this, i](Click* c) {
	fPts[i] = c->fCurr;
	return true;
	});
	}
	}
	return nullptr;
	}

	private:
	using INHERITED = Sample;
	};

	DEF_SAMPLE(return new SimpleStroker;)