src/third_party/skia/samplecode/SampleCusp.cpp - cobalt - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include <string>
 #include "include/core/SkCanvas.h"
 #include "include/core/SkFont.h"
 #include "include/core/SkPath.h"
 #include "samplecode/Sample.h"
 #include "src/core/SkGeometry.h"
 #include "tools/timer/TimeUtils.h"

 // This draws an animation where every cubic has a cusp, to test drawing a circle
 // at the cusp point. Create a unit square. A cubic with its control points
 // at the four corners crossing over itself has a cusp.

 // Project the unit square through a random affine matrix.
 // Chop the cubic in two. One half of the cubic will have a cusp
 // (unless it was chopped exactly at the cusp point).

 // Running this looks mostly OK, but will occasionally draw something odd.
 // The odd parts don't appear related to the cusp code, but are old stroking
 // bugs that have not been fixed, yet.

 SkMSec start = 0;
 SkMSec curTime;
 bool first = true;

 // Create a path with one or two cubics, where one has a cusp.
 static SkPath cusp(const SkPoint P[4], SkPoint PP[7], bool& split, int speed, SkScalar phase) {
     SkPath path;
     path.moveTo(P[0]);
     SkScalar t = (curTime % speed) / SkIntToFloat(speed);
     t += phase;
     if (t > 1) {
         t -= 1;
     }
     if (0 <= t || t >= 1) {
         path.cubicTo(P[1], P[2], P[3]);
         split = false;
     } else {
         SkChopCubicAt(P, PP, t);
         path.cubicTo(PP[1], PP[2], PP[3]);
         path.cubicTo(PP[4], PP[5], PP[6]);
         split = true;
     }
     return path;
 }

 // Scale the animation counter to a value that oscillates from -scale to +scale.
 static SkScalar linearToLoop(int speed, SkScalar phase, SkScalar scale) {
     SkScalar loop;
     SkScalar linear = (curTime % speed) / SkIntToFloat(speed);  // 0 to 1
     linear += phase;
     if (linear > 1) {
         linear -= 1;
     }
     if (linear < .25) {
         loop = linear * 4;     //  0 to .25  ==> 0 to  1
     } else if (linear < .75) { // .25 to .75 ==> 1 to -1
         loop = (.5 - linear) * 4;
     } else  {                  // .75 to 1   ==> -1 to 0
         loop = (linear - 1) * 4;
     }
     return loop * scale;
 }

 struct data {
     SkIPoint pt[4];
 } dat[] = {
 // When the animation looks funny, pause, and paste the last part of the stream in stdout here.
 // Enable the 1st #if to play the recorded stream backwards.
 // Enable the 2nd #if and replace the second 'i = ##' with the value of datCount that shows the bug.
 {{{0x43480000,0x43960000},{0x4318b999,0x4321570b},{0x432f999a,0x435a0a3d},{0x43311fff,0x43734cce},}},
 {{{0x43480000,0x43960000},{0x431d1ddf,0x4321ae13},{0x4331ddde,0x435c147c},{0x43334001,0x43719997},}},
 {{{0x43480000,0x43960000},{0x43218224,0x43220520},{0x43342223,0x435e1eba},{0x43356001,0x436fe666},}},
 {{{0x43480000,0x43960000},{0x4325a445,0x43225708},{0x43364444,0x43600a3c},{0x43376001,0x436e4ccc},}},
 {{{0x43480000,0x43960000},{0x432a0889,0x4322ae16},{0x43388889,0x4362147b},{0x43398000,0x436c999b},}},
 {{{0x43480000,0x43960000},{0x432e6ccd,0x43230523},{0x433acccd,0x43641eba},{0x433ba000,0x436ae66a},}},
 {{{0x43480000,0x43960000},{0x43328eef,0x4323570c},{0x433ceeee,0x43660a3c},{0x433da000,0x43694cd0},}},
 {{{0x43480000,0x43960000},{0x4336f333,0x4323ae13},{0x433f3333,0x4368147a},{0x433fc000,0x43679998},}},
 {{{0x43480000,0x43960000},{0x433b5777,0x43240520},{0x43417777,0x436a1eb9},{0x4341e000,0x4365e668},}},
 {{{0x43480000,0x43960000},{0x433f799a,0x4324570c},{0x4343999a,0x436c0a3e},{0x4343e000,0x43644cce},}},
 {{{0x43480000,0x43960000},{0x4343ddde,0x4324ae13},{0x4345dddf,0x436e147c},{0x43460000,0x43629996},}},
 {{{0x43480000,0x43960000},{0x43484222,0x4325051e},{0x43482222,0x43701eb9},{0x43481fff,0x4360e666},}},
 {{{0x43480000,0x43960000},{0x434c6446,0x43255709},{0x434a4444,0x43720a3e},{0x434a2002,0x435f4ccc},}},
 {{{0x43480000,0x43960000},{0x4350c888,0x4325ae16},{0x434c8889,0x4374147c},{0x434c3fff,0x435d999a},}},
 {{{0x43480000,0x43960000},{0x43552cce,0x43260521},{0x434ecccd,0x43761eb8},{0x434e6001,0x435be669},}},
 {{{0x43480000,0x43960000},{0x43594eee,0x4326570c},{0x4350eeef,0x43780a3d},{0x43505fff,0x435a4ccf},}},
 {{{0x43480000,0x43960000},{0x435db334,0x4326ae19},{0x43533333,0x437a147c},{0x43528001,0x4358999e},}},
 {{{0x43480000,0x43960000},{0x4361d555,0x43270002},{0x43555555,0x437bfffe},{0x43547fff,0x43570004},}},
 {{{0x43480000,0x43960000},{0x4366399a,0x4327570c},{0x4357999a,0x437e0a3f},{0x4356a001,0x43554ccd},}},
 {{{0x43480000,0x43960000},{0x436a9ddc,0x4327ae12},{0x4359ddde,0x43800a3e},{0x4358bffe,0x43539996},}},
 {{{0x43480000,0x43960000},{0x436f0222,0x4328051c},{0x435c2222,0x43810f5c},{0x435ae000,0x4351e664},}},
 };

 size_t datCount = SK_ARRAY_COUNT(dat);

 class CuspView : public Sample {
 public:
     CuspView() {}
 protected:
     SkString name() override { return SkString("Cusp"); }

     void onDrawContent(SkCanvas* canvas) override {
         SkPaint p;
         p.setAntiAlias(true);
         p.setStyle(SkPaint::kStroke_Style);
         p.setStrokeWidth(20);
     #if 0   // enable to play through the stream above backwards.
         SkPath path;
         int i;
     #if 0  // disable to draw only one problematic cubic
         i = --datCount;
     #else
         i = 14; // index into dat of  problematic cubic
     #endif
         path.moveTo( SkBits2Float(dat[i].pt[0].fX), SkBits2Float(dat[i].pt[0].fY));
         path.cubicTo(SkBits2Float(dat[i].pt[1].fX), SkBits2Float(dat[i].pt[1].fY),
                      SkBits2Float(dat[i].pt[2].fX), SkBits2Float(dat[i].pt[2].fY),
                      SkBits2Float(dat[i].pt[3].fX), SkBits2Float(dat[i].pt[3].fY));
     #else
         SkPath path;
         SkRect rect;
         rect.setWH(100, 100);
         SkMatrix matrix;
         SkScalar vals[9];
         vals[0] = linearToLoop(3000, 0, 1);
         vals[1] = linearToLoop(4000, .25, 1.25);
         vals[2] = 200;
         vals[3] = linearToLoop(5000, .5, 1.5);
         vals[4] = linearToLoop(7000, .75, 1.75);
         vals[5] = 300;
         vals[6] = 0;
         vals[7] = 0;
         vals[8] = 1;
         matrix.set9(vals);
         SkPoint pts[4], pp[7];
         matrix.mapRectToQuad(pts, rect);
         std::swap(pts[1], pts[2]);
         bool split;
         path = cusp(pts, pp, split, 8000, .125);
         auto debugOutCubic = [](const SkPoint* pts) {
             return false; // comment out to capture stream of cusp'd cubics in stdout
             SkDebugf("{{");
             for (int i = 0; i < 4; ++i) {
                 SkDebugf("{0x%08x,0x%08x},", SkFloat2Bits(pts[i].fX), SkFloat2Bits(pts[i].fY));
             }
             SkDebugf("}},\n");
         };
         if (split) {
             debugOutCubic(&pp[0]);
             debugOutCubic(&pp[4]);
         } else {
             debugOutCubic(&pts[0]);
         }
     #endif
         canvas->drawPath(path, p);
         // draw time to make it easier to guess when the bad cubic was drawn
         std::string timeStr = std::to_string((float) (curTime - start) / 1000.f);
         canvas->drawSimpleText(timeStr.c_str(), timeStr.size(), SkTextEncoding::kUTF8, 20, 20, SkFont(), SkPaint());
         SkDebugf("");
     }

     bool onAnimate(double nanos) override {
         curTime = TimeUtils::NanosToMSec(nanos);
         if (!start) {
             start = curTime;
         }
         return true;
     }

 private:

     typedef Sample INHERITED;
 };

 DEF_SAMPLE( return new CuspView(); )
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include <string>
	#include "include/core/SkCanvas.h"
	#include "include/core/SkFont.h"
	#include "include/core/SkPath.h"
	#include "samplecode/Sample.h"
	#include "src/core/SkGeometry.h"
	#include "tools/timer/TimeUtils.h"

	// This draws an animation where every cubic has a cusp, to test drawing a circle
	// at the cusp point. Create a unit square. A cubic with its control points
	// at the four corners crossing over itself has a cusp.

	// Project the unit square through a random affine matrix.
	// Chop the cubic in two. One half of the cubic will have a cusp
	// (unless it was chopped exactly at the cusp point).

	// Running this looks mostly OK, but will occasionally draw something odd.
	// The odd parts don't appear related to the cusp code, but are old stroking
	// bugs that have not been fixed, yet.

	SkMSec start = 0;
	SkMSec curTime;
	bool first = true;

	// Create a path with one or two cubics, where one has a cusp.
	static SkPath cusp(const SkPoint P[4], SkPoint PP[7], bool& split, int speed, SkScalar phase) {
	SkPath path;
	path.moveTo(P[0]);
	SkScalar t = (curTime % speed) / SkIntToFloat(speed);
	t += phase;
	if (t > 1) {
	t -= 1;
	}
	if (0 <= t \|\| t >= 1) {
	path.cubicTo(P[1], P[2], P[3]);
	split = false;
	} else {
	SkChopCubicAt(P, PP, t);
	path.cubicTo(PP[1], PP[2], PP[3]);
	path.cubicTo(PP[4], PP[5], PP[6]);
	split = true;
	}
	return path;
	}

	// Scale the animation counter to a value that oscillates from -scale to +scale.
	static SkScalar linearToLoop(int speed, SkScalar phase, SkScalar scale) {
	SkScalar loop;
	SkScalar linear = (curTime % speed) / SkIntToFloat(speed); // 0 to 1
	linear += phase;
	if (linear > 1) {
	linear -= 1;
	}
	if (linear < .25) {
	loop = linear * 4; // 0 to .25 ==> 0 to 1
	} else if (linear < .75) { // .25 to .75 ==> 1 to -1
	loop = (.5 - linear) * 4;
	} else { // .75 to 1 ==> -1 to 0
	loop = (linear - 1) * 4;
	}
	return loop * scale;
	}

	struct data {
	SkIPoint pt[4];
	} dat[] = {
	// When the animation looks funny, pause, and paste the last part of the stream in stdout here.
	// Enable the 1st #if to play the recorded stream backwards.
	// Enable the 2nd #if and replace the second 'i = ##' with the value of datCount that shows the bug.
	{{{0x43480000,0x43960000},{0x4318b999,0x4321570b},{0x432f999a,0x435a0a3d},{0x43311fff,0x43734cce},}},
	{{{0x43480000,0x43960000},{0x431d1ddf,0x4321ae13},{0x4331ddde,0x435c147c},{0x43334001,0x43719997},}},
	{{{0x43480000,0x43960000},{0x43218224,0x43220520},{0x43342223,0x435e1eba},{0x43356001,0x436fe666},}},
	{{{0x43480000,0x43960000},{0x4325a445,0x43225708},{0x43364444,0x43600a3c},{0x43376001,0x436e4ccc},}},
	{{{0x43480000,0x43960000},{0x432a0889,0x4322ae16},{0x43388889,0x4362147b},{0x43398000,0x436c999b},}},
	{{{0x43480000,0x43960000},{0x432e6ccd,0x43230523},{0x433acccd,0x43641eba},{0x433ba000,0x436ae66a},}},
	{{{0x43480000,0x43960000},{0x43328eef,0x4323570c},{0x433ceeee,0x43660a3c},{0x433da000,0x43694cd0},}},
	{{{0x43480000,0x43960000},{0x4336f333,0x4323ae13},{0x433f3333,0x4368147a},{0x433fc000,0x43679998},}},
	{{{0x43480000,0x43960000},{0x433b5777,0x43240520},{0x43417777,0x436a1eb9},{0x4341e000,0x4365e668},}},
	{{{0x43480000,0x43960000},{0x433f799a,0x4324570c},{0x4343999a,0x436c0a3e},{0x4343e000,0x43644cce},}},
	{{{0x43480000,0x43960000},{0x4343ddde,0x4324ae13},{0x4345dddf,0x436e147c},{0x43460000,0x43629996},}},
	{{{0x43480000,0x43960000},{0x43484222,0x4325051e},{0x43482222,0x43701eb9},{0x43481fff,0x4360e666},}},
	{{{0x43480000,0x43960000},{0x434c6446,0x43255709},{0x434a4444,0x43720a3e},{0x434a2002,0x435f4ccc},}},
	{{{0x43480000,0x43960000},{0x4350c888,0x4325ae16},{0x434c8889,0x4374147c},{0x434c3fff,0x435d999a},}},
	{{{0x43480000,0x43960000},{0x43552cce,0x43260521},{0x434ecccd,0x43761eb8},{0x434e6001,0x435be669},}},
	{{{0x43480000,0x43960000},{0x43594eee,0x4326570c},{0x4350eeef,0x43780a3d},{0x43505fff,0x435a4ccf},}},
	{{{0x43480000,0x43960000},{0x435db334,0x4326ae19},{0x43533333,0x437a147c},{0x43528001,0x4358999e},}},
	{{{0x43480000,0x43960000},{0x4361d555,0x43270002},{0x43555555,0x437bfffe},{0x43547fff,0x43570004},}},
	{{{0x43480000,0x43960000},{0x4366399a,0x4327570c},{0x4357999a,0x437e0a3f},{0x4356a001,0x43554ccd},}},
	{{{0x43480000,0x43960000},{0x436a9ddc,0x4327ae12},{0x4359ddde,0x43800a3e},{0x4358bffe,0x43539996},}},
	{{{0x43480000,0x43960000},{0x436f0222,0x4328051c},{0x435c2222,0x43810f5c},{0x435ae000,0x4351e664},}},
	};

	size_t datCount = SK_ARRAY_COUNT(dat);

	class CuspView : public Sample {
	public:
	CuspView() {}
	protected:
	SkString name() override { return SkString("Cusp"); }

	void onDrawContent(SkCanvas* canvas) override {
	SkPaint p;
	p.setAntiAlias(true);
	p.setStyle(SkPaint::kStroke_Style);
	p.setStrokeWidth(20);
	#if 0 // enable to play through the stream above backwards.
	SkPath path;
	int i;
	#if 0 // disable to draw only one problematic cubic
	i = --datCount;
	#else
	i = 14; // index into dat of problematic cubic
	#endif
	path.moveTo( SkBits2Float(dat[i].pt[0].fX), SkBits2Float(dat[i].pt[0].fY));
	path.cubicTo(SkBits2Float(dat[i].pt[1].fX), SkBits2Float(dat[i].pt[1].fY),
	SkBits2Float(dat[i].pt[2].fX), SkBits2Float(dat[i].pt[2].fY),
	SkBits2Float(dat[i].pt[3].fX), SkBits2Float(dat[i].pt[3].fY));
	#else
	SkPath path;
	SkRect rect;
	rect.setWH(100, 100);
	SkMatrix matrix;
	SkScalar vals[9];
	vals[0] = linearToLoop(3000, 0, 1);
	vals[1] = linearToLoop(4000, .25, 1.25);
	vals[2] = 200;
	vals[3] = linearToLoop(5000, .5, 1.5);
	vals[4] = linearToLoop(7000, .75, 1.75);
	vals[5] = 300;
	vals[6] = 0;
	vals[7] = 0;
	vals[8] = 1;
	matrix.set9(vals);
	SkPoint pts[4], pp[7];
	matrix.mapRectToQuad(pts, rect);
	std::swap(pts[1], pts[2]);
	bool split;
	path = cusp(pts, pp, split, 8000, .125);
	auto debugOutCubic = [](const SkPoint* pts) {
	return false; // comment out to capture stream of cusp'd cubics in stdout
	SkDebugf("{{");
	for (int i = 0; i < 4; ++i) {
	SkDebugf("{0x%08x,0x%08x},", SkFloat2Bits(pts[i].fX), SkFloat2Bits(pts[i].fY));
	}
	SkDebugf("}},\n");
	};
	if (split) {
	debugOutCubic(&pp[0]);
	debugOutCubic(&pp[4]);
	} else {
	debugOutCubic(&pts[0]);
	}
	#endif
	canvas->drawPath(path, p);
	// draw time to make it easier to guess when the bad cubic was drawn
	std::string timeStr = std::to_string((float) (curTime - start) / 1000.f);
	canvas->drawSimpleText(timeStr.c_str(), timeStr.size(), SkTextEncoding::kUTF8, 20, 20, SkFont(), SkPaint());
	SkDebugf("");
	}

	bool onAnimate(double nanos) override {
	curTime = TimeUtils::NanosToMSec(nanos);
	if (!start) {
	start = curTime;
	}
	return true;
	}

	private:

	typedef Sample INHERITED;
	};

	DEF_SAMPLE( return new CuspView(); )