samplecode/SampleFitCubicToCircle.cpp - platform/external/skia - Gitiles

 /*
  * 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 "samplecode/Sample.h"

 #include "include/core/SkCanvas.h"
 #include "include/core/SkFont.h"
 #include "include/core/SkPaint.h"
 #include "include/core/SkPath.h"
 #include <tuple>

 // Math constants are not always defined.
 #ifndef M_PI
 #define M_PI 3.14159265358979323846264338327950288
 #endif

 #ifndef M_SQRT2
 #define M_SQRT2 1.41421356237309504880168872420969808
 #endif

 constexpr static int kCenterX = 300;
 constexpr static int kCenterY = 325;
 constexpr static int kRadius = 250;

 // This sample fits a cubic to the arc between two interactive points on a circle. It also finds the
 // T-coordinate of max error, and outputs it and its value in pixels. (It turns out that max error
 // always occurs at T=0.21132486540519.)
 //
 // Press 'E' to iteratively cut the arc in half and report the improvement in max error after each
 // halving. (It turns out that max error improves by exactly 64x on every halving.)
 class SampleFitCubicToCircle : public Sample {
     SkString name() override { return SkString("FitCubicToCircle"); }
     void onOnceBeforeDraw() override { this->fitCubic(); }
     void fitCubic();
     void onDrawContent(SkCanvas*) override;
     Sample::Click* onFindClickHandler(SkScalar x, SkScalar y, skui::ModifierKey) override;
     bool onClick(Sample::Click*) override;
     bool onChar(SkUnichar) override;

     // Coordinates of two points on the unit circle. These are the two endpoints of the arc we fit.
     double fEndptsX[2] = {0, 1};
     double fEndptsY[2] = {-1, 0};

     // Fitted cubic and info, set by fitCubic().
     double fControlLength;  // Length of (p1 - p0) and/or (p3 - p2) in unit circle space.
     double fMaxErrorT;  // T value where the cubic diverges most from the true arc.
     std::array<double, 4> fCubicX;  // Screen space cubic control points.
     std::array<double, 4> fCubicY;
     double fMaxError;  // Max error (in pixels) between the cubic and the screen-space arc.
     double fTheta;  // Angle of the arc. This is only used for informational purposes.
     SkTArray<SkString> fInfoStrings;

     class Click;
 };

 // Fits a cubic to an arc on the unit circle with endpoints (x0, y0) and (x1, y1). Using the
 // following 3 constraints, we arrive at the formula used in the method:
 //
 //   1) The endpoints and tangent directions at the endpoints must match the arc.
 //   2) The cubic must be symmetric (i.e., length(p1 - p0) == length(p3 - p2)).
 //   3) The height of the cubic must match the height of the arc.
 //
 // Returns the "control length", or length of (p1 - p0) and/or (p3 - p2).
 static float fit_cubic_to_unit_circle(double x0, double y0, double x1, double y1,
                                       std::array<double, 4>* X, std::array<double, 4>* Y) {
     constexpr static double kM = -4.0/3;
     constexpr static double kA = 4*M_SQRT2/3;
     double d = x0*x1 + y0*y1;
     double c = (std::sqrt(1 + d) * kM + kA) / std::sqrt(1 - d);
     *X = {x0, x0 - y0*c, x1 + y1*c, x1};
     *Y = {y0, y0 + x0*c, y1 - x1*c, y1};
     return c;
 }

 static double lerp(double x, double y, double T) {
     return x + T*(y - x);
 }

 // Evaluates the cubic and 1st and 2nd derivatives at T.
 static std::tuple<double, double, double> eval_cubic(double x[], double T) {
     // Use De Casteljau's algorithm for better accuracy and stability.
     double ab = lerp(x[0], x[1], T);
     double bc = lerp(x[1], x[2], T);
     double cd = lerp(x[2], x[3], T);
     double abc = lerp(ab, bc, T);
     double bcd = lerp(bc, cd, T);
     double abcd = lerp(abc, bcd, T);
     return {abcd, 3 * (bcd - abc) /*1st derivative.*/, 6 * (cd - 2*bc + ab) /*2nd derivative.*/};
 }

 // Uses newton-raphson convergence to find the point where the provided cubic diverges most from the
 // unit circle. i.e., the point where the derivative of error == 0. For error we use:
 //
 //     error = x^2 + y^2 - 1
 //     error' = 2xx' + 2yy'
 //     error'' = 2xx'' + 2yy'' + 2x'^2 + 2y'^2
 //
 double find_max_error_T(double cubicX[4], double cubicY[4]) {
     constexpr static double kInitialT = .25;
     double T = kInitialT;
     for (int i = 0; i < 64; ++i) {
         auto [x, dx, ddx] = eval_cubic(cubicX, T);
         auto [y, dy, ddy] = eval_cubic(cubicY, T);
         double dError = 2*(x*dx + y*dy);
         double ddError = 2*(x*ddx + y*ddy + dx*dx + dy*dy);
         T -= dError / ddError;
     }
     return T;
 }

 void SampleFitCubicToCircle::fitCubic() {
     fInfoStrings.reset();

     std::array<double, 4> X, Y;
     // "Control length" is the length of (p1 - p0) and/or (p3 - p2) in unit circle space.
     fControlLength = fit_cubic_to_unit_circle(fEndptsX[0], fEndptsY[0], fEndptsX[1], fEndptsY[1],
                                               &X, &Y);
     fInfoStrings.push_back().printf("control length=%0.14f", fControlLength);

     fMaxErrorT = find_max_error_T(X.data(), Y.data());
     fInfoStrings.push_back().printf("max error T=%0.14f", fMaxErrorT);

     for (int i = 0; i < 4; ++i) {
         fCubicX[i] = X[i] * kRadius + kCenterX;
         fCubicY[i] = Y[i] * kRadius + kCenterY;
     }
     double errX = std::get<0>(eval_cubic(fCubicX.data(), fMaxErrorT)) - kCenterX;
     double errY = std::get<0>(eval_cubic(fCubicY.data(), fMaxErrorT)) - kCenterY;
     fMaxError = std::sqrt(errX*errX + errY*errY) - kRadius;
     fInfoStrings.push_back().printf("max error=%.5gpx", fMaxError);

     fTheta = std::atan2(fEndptsY[1], fEndptsX[1]) - std::atan2(fEndptsY[0], fEndptsX[0]);
     fTheta = std::abs(fTheta * 180/M_PI);
     if (fTheta > 180) {
         fTheta = 360 - fTheta;
     }
     fInfoStrings.push_back().printf("(theta=%.2f)", fTheta);

     SkDebugf("\n");
     for (const SkString& infoString : fInfoStrings) {
         SkDebugf("%s\n", infoString.c_str());
     }
 }

 void SampleFitCubicToCircle::onDrawContent(SkCanvas* canvas) {
     canvas->clear(SK_ColorBLACK);

     SkPaint circlePaint;
     circlePaint.setColor(0x80ffffff);
     circlePaint.setStyle(SkPaint::kStroke_Style);
     circlePaint.setStrokeWidth(0);
     circlePaint.setAntiAlias(true);
     canvas->drawArc(SkRect::MakeXYWH(kCenterX - kRadius, kCenterY - kRadius, kRadius * 2,
                                      kRadius * 2), 0, 360, false, circlePaint);

     SkPaint cubicPaint;
     cubicPaint.setColor(SK_ColorGREEN);
     cubicPaint.setStyle(SkPaint::kStroke_Style);
     cubicPaint.setStrokeWidth(10);
     cubicPaint.setAntiAlias(true);
     SkPath cubicPath;
     cubicPath.moveTo(fCubicX[0], fCubicY[0]);
     cubicPath.cubicTo(fCubicX[1], fCubicY[1], fCubicX[2], fCubicY[2], fCubicX[3], fCubicY[3]);
     canvas->drawPath(cubicPath, cubicPaint);

     SkPaint endpointsPaint;
     endpointsPaint.setColor(SK_ColorBLUE);
     endpointsPaint.setStrokeWidth(8);
     endpointsPaint.setAntiAlias(true);
     SkPoint points[2] = {{(float)fCubicX[0], (float)fCubicY[0]},
                          {(float)fCubicX[3], (float)fCubicY[3]}};
     canvas->drawPoints(SkCanvas::kPoints_PointMode, 2, points, endpointsPaint);

     SkPaint textPaint;
     textPaint.setColor(SK_ColorWHITE);
     constexpr static float kInfoTextSize = 16;
     SkFont font(nullptr, kInfoTextSize);
     int infoY = 10 + kInfoTextSize;
     for (const SkString& infoString : fInfoStrings) {
         canvas->drawString(infoString.c_str(), 10, infoY, font, textPaint);
         infoY += kInfoTextSize * 3/2;
     }
 }

 class SampleFitCubicToCircle::Click : public Sample::Click {
 public:
     Click(int ptIdx) : fPtIdx(ptIdx) {}

     void doClick(SampleFitCubicToCircle* that) {
         double dx = fCurr.fX - kCenterX;
         double dy = fCurr.fY - kCenterY;
         double l = std::sqrt(dx*dx + dy*dy);
         that->fEndptsX[fPtIdx] = dx/l;
         that->fEndptsY[fPtIdx] = dy/l;
         if (that->fEndptsX[0] * that->fEndptsY[1] - that->fEndptsY[0] * that->fEndptsX[1] < 0) {
             std::swap(that->fEndptsX[0], that->fEndptsX[1]);
             std::swap(that->fEndptsY[0], that->fEndptsY[1]);
             fPtIdx = 1 - fPtIdx;
         }
         that->fitCubic();
     }

 private:
     int fPtIdx;
 };

 Sample::Click* SampleFitCubicToCircle::onFindClickHandler(SkScalar x, SkScalar y,
                                                           skui::ModifierKey) {
     double dx0 = x - fCubicX[0];
     double dy0 = y - fCubicY[0];
     double dx3 = x - fCubicX[3];
     double dy3 = y - fCubicY[3];
     if (dx0*dx0 + dy0*dy0 < dx3*dx3 + dy3*dy3) {
         return new Click(0);
     } else {
         return new Click(1);
     }
 }

 bool SampleFitCubicToCircle::onClick(Sample::Click* click) {
     Click* myClick = (Click*)click;
     myClick->doClick(this);
     return true;
 }

 bool SampleFitCubicToCircle::onChar(SkUnichar unichar) {
     if (unichar == 'E') {
         constexpr static double kMaxErrorT = 0.21132486540519;  // Always the same.
         // Split the arc in half until error =~0, and report the improvement after each halving.
         double lastError = -1;
         for (double theta = fTheta; lastError != 0; theta /= 2) {
             double rads = theta * M_PI/180;
             std::array<double, 4> X, Y;
             fit_cubic_to_unit_circle(1, 0, std::cos(rads), std::sin(rads), &X, &Y);
             auto [x, dx, ddx] = eval_cubic(X.data(), kMaxErrorT);
             auto [y, dy, ddy] = eval_cubic(Y.data(), kMaxErrorT);
             double error = std::sqrt(x*x + y*y) * kRadius - kRadius;
             if ((float)error <= 0) {
                 error = 0;
             }
             SkDebugf("%6.2f degrees:   error= %10.5gpx", theta, error);
             if (lastError > 0) {
                 SkDebugf(" (%17.14fx improvement)", lastError / error);
             }
             SkDebugf("\n");
             lastError = error;
         }
         return true;
     }
     return false;
 }

 DEF_SAMPLE(return new SampleFitCubicToCircle;)
	/*
	* 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 "samplecode/Sample.h"

	#include "include/core/SkCanvas.h"
	#include "include/core/SkFont.h"
	#include "include/core/SkPaint.h"
	#include "include/core/SkPath.h"
	#include <tuple>

	// Math constants are not always defined.
	#ifndef M_PI
	#define M_PI 3.14159265358979323846264338327950288
	#endif

	#ifndef M_SQRT2
	#define M_SQRT2 1.41421356237309504880168872420969808
	#endif

	constexpr static int kCenterX = 300;
	constexpr static int kCenterY = 325;
	constexpr static int kRadius = 250;

	// This sample fits a cubic to the arc between two interactive points on a circle. It also finds the
	// T-coordinate of max error, and outputs it and its value in pixels. (It turns out that max error
	// always occurs at T=0.21132486540519.)
	//
	// Press 'E' to iteratively cut the arc in half and report the improvement in max error after each
	// halving. (It turns out that max error improves by exactly 64x on every halving.)
	class SampleFitCubicToCircle : public Sample {
	SkString name() override { return SkString("FitCubicToCircle"); }
	void onOnceBeforeDraw() override { this->fitCubic(); }
	void fitCubic();
	void onDrawContent(SkCanvas*) override;
	Sample::Click* onFindClickHandler(SkScalar x, SkScalar y, skui::ModifierKey) override;
	bool onClick(Sample::Click*) override;
	bool onChar(SkUnichar) override;

	// Coordinates of two points on the unit circle. These are the two endpoints of the arc we fit.
	double fEndptsX[2] = {0, 1};
	double fEndptsY[2] = {-1, 0};

	// Fitted cubic and info, set by fitCubic().
	double fControlLength; // Length of (p1 - p0) and/or (p3 - p2) in unit circle space.
	double fMaxErrorT; // T value where the cubic diverges most from the true arc.
	std::array<double, 4> fCubicX; // Screen space cubic control points.
	std::array<double, 4> fCubicY;
	double fMaxError; // Max error (in pixels) between the cubic and the screen-space arc.
	double fTheta; // Angle of the arc. This is only used for informational purposes.
	SkTArray<SkString> fInfoStrings;

	class Click;
	};

	// Fits a cubic to an arc on the unit circle with endpoints (x0, y0) and (x1, y1). Using the
	// following 3 constraints, we arrive at the formula used in the method:
	//
	// 1) The endpoints and tangent directions at the endpoints must match the arc.
	// 2) The cubic must be symmetric (i.e., length(p1 - p0) == length(p3 - p2)).
	// 3) The height of the cubic must match the height of the arc.
	//
	// Returns the "control length", or length of (p1 - p0) and/or (p3 - p2).
	static float fit_cubic_to_unit_circle(double x0, double y0, double x1, double y1,
	std::array<double, 4>* X, std::array<double, 4>* Y) {
	constexpr static double kM = -4.0/3;
	constexpr static double kA = 4*M_SQRT2/3;
	double d = x0x1 + y0y1;
	double c = (std::sqrt(1 + d) * kM + kA) / std::sqrt(1 - d);
	X = {x0, x0 - y0c, x1 + y1*c, x1};
	Y = {y0, y0 + x0c, y1 - x1*c, y1};
	return c;
	}

	static double lerp(double x, double y, double T) {
	return x + T*(y - x);
	}

	// Evaluates the cubic and 1st and 2nd derivatives at T.
	static std::tuple<double, double, double> eval_cubic(double x[], double T) {
	// Use De Casteljau's algorithm for better accuracy and stability.
	double ab = lerp(x[0], x[1], T);
	double bc = lerp(x[1], x[2], T);
	double cd = lerp(x[2], x[3], T);
	double abc = lerp(ab, bc, T);
	double bcd = lerp(bc, cd, T);
	double abcd = lerp(abc, bcd, T);
	return {abcd, 3 * (bcd - abc) /1st derivative./, 6 * (cd - 2bc + ab) /2nd derivative.*/};
	}

	// Uses newton-raphson convergence to find the point where the provided cubic diverges most from the
	// unit circle. i.e., the point where the derivative of error == 0. For error we use:
	//
	// error = x^2 + y^2 - 1
	// error' = 2xx' + 2yy'
	// error'' = 2xx'' + 2yy'' + 2x'^2 + 2y'^2
	//
	double find_max_error_T(double cubicX[4], double cubicY[4]) {
	constexpr static double kInitialT = .25;
	double T = kInitialT;
	for (int i = 0; i < 64; ++i) {
	auto [x, dx, ddx] = eval_cubic(cubicX, T);
	auto [y, dy, ddy] = eval_cubic(cubicY, T);
	double dError = 2(xdx + y*dy);
	double ddError = 2(xddx + yddy + dxdx + dy*dy);
	T -= dError / ddError;
	}
	return T;
	}

	void SampleFitCubicToCircle::fitCubic() {
	fInfoStrings.reset();

	std::array<double, 4> X, Y;
	// "Control length" is the length of (p1 - p0) and/or (p3 - p2) in unit circle space.
	fControlLength = fit_cubic_to_unit_circle(fEndptsX[0], fEndptsY[0], fEndptsX[1], fEndptsY[1],
	&X, &Y);
	fInfoStrings.push_back().printf("control length=%0.14f", fControlLength);

	fMaxErrorT = find_max_error_T(X.data(), Y.data());
	fInfoStrings.push_back().printf("max error T=%0.14f", fMaxErrorT);

	for (int i = 0; i < 4; ++i) {
	fCubicX[i] = X[i] * kRadius + kCenterX;
	fCubicY[i] = Y[i] * kRadius + kCenterY;
	}
	double errX = std::get<0>(eval_cubic(fCubicX.data(), fMaxErrorT)) - kCenterX;
	double errY = std::get<0>(eval_cubic(fCubicY.data(), fMaxErrorT)) - kCenterY;
	fMaxError = std::sqrt(errXerrX + errYerrY) - kRadius;
	fInfoStrings.push_back().printf("max error=%.5gpx", fMaxError);

	fTheta = std::atan2(fEndptsY[1], fEndptsX[1]) - std::atan2(fEndptsY[0], fEndptsX[0]);
	fTheta = std::abs(fTheta * 180/M_PI);
	if (fTheta > 180) {
	fTheta = 360 - fTheta;
	}
	fInfoStrings.push_back().printf("(theta=%.2f)", fTheta);

	SkDebugf("\n");
	for (const SkString& infoString : fInfoStrings) {
	SkDebugf("%s\n", infoString.c_str());
	}
	}

	void SampleFitCubicToCircle::onDrawContent(SkCanvas* canvas) {
	canvas->clear(SK_ColorBLACK);

	SkPaint circlePaint;
	circlePaint.setColor(0x80ffffff);
	circlePaint.setStyle(SkPaint::kStroke_Style);
	circlePaint.setStrokeWidth(0);
	circlePaint.setAntiAlias(true);
	canvas->drawArc(SkRect::MakeXYWH(kCenterX - kRadius, kCenterY - kRadius, kRadius * 2,
	kRadius * 2), 0, 360, false, circlePaint);

	SkPaint cubicPaint;
	cubicPaint.setColor(SK_ColorGREEN);
	cubicPaint.setStyle(SkPaint::kStroke_Style);
	cubicPaint.setStrokeWidth(10);
	cubicPaint.setAntiAlias(true);
	SkPath cubicPath;
	cubicPath.moveTo(fCubicX[0], fCubicY[0]);
	cubicPath.cubicTo(fCubicX[1], fCubicY[1], fCubicX[2], fCubicY[2], fCubicX[3], fCubicY[3]);
	canvas->drawPath(cubicPath, cubicPaint);

	SkPaint endpointsPaint;
	endpointsPaint.setColor(SK_ColorBLUE);
	endpointsPaint.setStrokeWidth(8);
	endpointsPaint.setAntiAlias(true);
	SkPoint points[2] = {{(float)fCubicX[0], (float)fCubicY[0]},
	{(float)fCubicX[3], (float)fCubicY[3]}};
	canvas->drawPoints(SkCanvas::kPoints_PointMode, 2, points, endpointsPaint);

	SkPaint textPaint;
	textPaint.setColor(SK_ColorWHITE);
	constexpr static float kInfoTextSize = 16;
	SkFont font(nullptr, kInfoTextSize);
	int infoY = 10 + kInfoTextSize;
	for (const SkString& infoString : fInfoStrings) {
	canvas->drawString(infoString.c_str(), 10, infoY, font, textPaint);
	infoY += kInfoTextSize * 3/2;
	}
	}

	class SampleFitCubicToCircle::Click : public Sample::Click {
	public:
	Click(int ptIdx) : fPtIdx(ptIdx) {}

	void doClick(SampleFitCubicToCircle* that) {
	double dx = fCurr.fX - kCenterX;
	double dy = fCurr.fY - kCenterY;
	double l = std::sqrt(dxdx + dydy);
	that->fEndptsX[fPtIdx] = dx/l;
	that->fEndptsY[fPtIdx] = dy/l;
	if (that->fEndptsX[0] * that->fEndptsY[1] - that->fEndptsY[0] * that->fEndptsX[1] < 0) {
	std::swap(that->fEndptsX[0], that->fEndptsX[1]);
	std::swap(that->fEndptsY[0], that->fEndptsY[1]);
	fPtIdx = 1 - fPtIdx;
	}
	that->fitCubic();
	}

	private:
	int fPtIdx;
	};

	Sample::Click* SampleFitCubicToCircle::onFindClickHandler(SkScalar x, SkScalar y,
	skui::ModifierKey) {
	double dx0 = x - fCubicX[0];
	double dy0 = y - fCubicY[0];
	double dx3 = x - fCubicX[3];
	double dy3 = y - fCubicY[3];
	if (dx0dx0 + dy0dy0 < dx3dx3 + dy3dy3) {
	return new Click(0);
	} else {
	return new Click(1);
	}
	}

	bool SampleFitCubicToCircle::onClick(Sample::Click* click) {
	Click* myClick = (Click*)click;
	myClick->doClick(this);
	return true;
	}

	bool SampleFitCubicToCircle::onChar(SkUnichar unichar) {
	if (unichar == 'E') {
	constexpr static double kMaxErrorT = 0.21132486540519; // Always the same.
	// Split the arc in half until error =~0, and report the improvement after each halving.
	double lastError = -1;
	for (double theta = fTheta; lastError != 0; theta /= 2) {
	double rads = theta * M_PI/180;
	std::array<double, 4> X, Y;
	fit_cubic_to_unit_circle(1, 0, std::cos(rads), std::sin(rads), &X, &Y);
	auto [x, dx, ddx] = eval_cubic(X.data(), kMaxErrorT);
	auto [y, dy, ddy] = eval_cubic(Y.data(), kMaxErrorT);
	double error = std::sqrt(xx + yy) * kRadius - kRadius;
	if ((float)error <= 0) {
	error = 0;
	}
	SkDebugf("%6.2f degrees: error= %10.5gpx", theta, error);
	if (lastError > 0) {
	SkDebugf(" (%17.14fx improvement)", lastError / error);
	}
	SkDebugf("\n");
	lastError = error;
	}
	return true;
	}
	return false;
	}

	DEF_SAMPLE(return new SampleFitCubicToCircle;)