src/third_party/skia/experimental/Intersection/EdgeDemo.cpp - cobalt - Git at Google

 #include "EdgeDemo.h"
 #include "EdgeWalker_Test.h"
 #include "ShapeOps.h"
 #import "SkCanvas.h"
 #import "SkPaint.h"

 extern void showPath(const SkPath& path, const char* str);

 static bool drawPaths(SkCanvas* canvas, const SkPath& path, bool useOld)
 {
     SkPath out;
 #define SHOW_PATH 0
 #if SHOW_PATH
     showPath(path, "original:");
 #endif
     if (useOld) {
         simplify(path, true, out);
     } else {
         simplifyx(path, out);
     }
 #if SHOW_PATH
     showPath(out, "simplified:");
 #endif
     SkPaint paint;
     paint.setAntiAlias(true);
     paint.setStyle(SkPaint::kStroke_Style);
 //   paint.setStrokeWidth(6);
  //  paint.setColor(0x1F003f7f);
  //  canvas->drawPath(path, paint);
     paint.setColor(0xFF305F00);
     paint.setStrokeWidth(1);
     canvas->drawPath(out, paint);
     return true;
 }

 // Three circles bounce inside a rectangle. The circles describe three, four
 // or five points which in turn describe a polygon. The polygon points
 // bounce inside the circles. The circles rotate and scale over time. The
 // polygons are combined into a single path, simplified, and stroked.
 static bool drawCircles(SkCanvas* canvas, int step, bool useOld)
 {
     const int circles = 3;
     int scales[circles];
     int angles[circles];
     int locs[circles * 2];
     int pts[circles * 2 * 4];
     int c, p;
     for (c = 0; c < circles; ++c) {
         scales[c] = abs(10 - (step + c * 4) % 21);
         angles[c] = (step + c * 6) % 600;
         locs[c * 2] = abs(130 - (step + c * 9) % 261);
         locs[c * 2 + 1] = abs(170 - (step + c * 11) % 341);
         for (p = 0; p < 4; ++p) {
             pts[c * 8 + p * 2] = abs(90 - ((step + c * 121 + p * 13) % 190));
             pts[c * 8 + p * 2 + 1] = abs(110 - ((step + c * 223 + p * 17) % 230));
         }
     }
     SkPath path;
     for (c = 0; c < circles; ++c) {
         for (p = 0; p < 4; ++p) {
             SkScalar x = pts[c * 8 + p * 2];
             SkScalar y = pts[c * 8 + p * 2 + 1];
             x *= 3 + scales[c] / 10.0f;
             y *= 3 + scales[c] / 10.0f;
             SkScalar angle = angles[c] * 3.1415f * 2 / 600;
             SkScalar temp = (SkScalar) (x * cos(angle) - y * sin(angle));
             y = (SkScalar) (x * sin(angle) + y * cos(angle));
             x = temp;
             x += locs[c * 2] * 200 / 130.0f;
             y += locs[c * 2 + 1] * 200 / 170.0f;
             x += 50;
     //        y += 200;
             if (p == 0) {
                 path.moveTo(x, y);
             } else {
                 path.lineTo(x, y);
             }
         }
         path.close();
     }
     return drawPaths(canvas, path, useOld);
 }

 static void createStar(SkPath& path, SkScalar innerRadius, SkScalar outerRadius,
         SkScalar startAngle, int points, SkPoint center) {
     SkScalar angle = startAngle;
     for (int index = 0; index < points * 2; ++index) {
         SkScalar radius = index & 1 ? outerRadius : innerRadius;
         SkScalar x = (SkScalar) (radius * cos(angle));
         SkScalar y = (SkScalar) (radius * sin(angle));
         x += center.fX;
         y += center.fY;
         if (index == 0) {
             path.moveTo(x, y);
         } else {
             path.lineTo(x, y);
         }
         angle += 3.1415f / points;
     }
     path.close();
 }

 static bool drawStars(SkCanvas* canvas, int step, bool useOld)
 {
     SkPath path;
     const int stars = 25;
     int pts[stars];
  //   static bool initialize = true;
     int s;
     for (s = 0; s < stars; ++s) {
         pts[s] = 4 + (s % 7);
     }
     SkPoint locs[stars];
     SkScalar angles[stars];
     SkScalar innerRadius[stars];
     SkScalar outerRadius[stars];
     const int width = 640;
     const int height = 480;
     const int margin = 30;
     const int minRadius = 120;
     const int maxInner = 800;
     const int maxOuter = 1153;
     for (s = 0; s < stars; ++s) {
         int starW = (int) (width - margin * 2 + (SkScalar) s * (stars - s) / stars);
         locs[s].fX = (int) (step * (1.3f * (s + 1) / stars) + s * 121) % (starW * 2);
         if (locs[s].fX > starW) {
             locs[s].fX = starW * 2 - locs[s].fX;
         }
         locs[s].fX += margin;
         int starH = (int) (height - margin * 2 + (SkScalar) s * s / stars);
         locs[s].fY = (int) (step * (1.7f * (s + 1) / stars) + s * 183) % (starH * 2);
         if (locs[s].fY > starH) {
             locs[s].fY = starH * 2 - locs[s].fY;
         }
         locs[s].fY += margin;
         angles[s] = ((step + s * 47) % (360 * 4)) * 3.1415f / 180 / 4;
         innerRadius[s] = (step + s * 30) % (maxInner * 2);
         if (innerRadius[s] > maxInner) {
             innerRadius[s] = (maxInner * 2) - innerRadius[s];
         }
         innerRadius[s] = innerRadius[s] / 4 + minRadius;
         outerRadius[s] = (step + s * 70) % (maxOuter * 2);
         if (outerRadius[s] > maxOuter) {
             outerRadius[s] = (maxOuter * 2) - outerRadius[s];
         }
         outerRadius[s] = outerRadius[s] / 4 + minRadius;
         createStar(path, innerRadius[s] / 4.0f, outerRadius[s] / 4.0f,
                 angles[s], pts[s], locs[s]);
     }
     return drawPaths(canvas, path, useOld);
 }

 #if 0
 static void tryRoncoOnce(const SkPath& path, const SkRect& target, bool show) {
     // capture everything in a desired rectangle
     SkPath tiny;
     bool closed = true;
     SkPath::Iter iter(path, false);
     SkPoint pts[4];
     SkPath::Verb verb;
     int count = 0;
     SkPoint lastPt;
     while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {
         switch (verb) {
             case SkPath::kMove_Verb:
                 count = 0;
                 break;
             case SkPath::kLine_Verb:
                 count = 1;
                 break;
             case SkPath::kQuad_Verb:
                 count = 2;
                 break;
             case SkPath::kCubic_Verb:
                 count = 3;
                 break;
             case SkPath::kClose_Verb:
                 if (!closed) {
                     tiny.close();
                     closed = true;
                 }
                 count = 0;
                 break;
             default:
                 SkDEBUGFAIL("bad verb");
         }
         if (!count) {
             continue;
         }
         SkRect bounds;
         bounds.set(pts[0].fX, pts[0].fY, pts[0].fX, pts[0].fY);
         for (int i = 1; i <= count; ++i) {
             bounds.growToInclude(pts[i].fX + 0.1f, pts[i].fY + 0.1f);
         }
         if (!SkRect::Intersects(target, bounds)) {
             continue;
         }
         if (closed) {
             tiny.moveTo(pts[0].fX, pts[0].fY);
             closed = false;
         } else if (pts[0] != lastPt) {
             tiny.lineTo(pts[0].fX, pts[0].fY);
         }
         switch (verb) {
             case SkPath::kLine_Verb:
                 tiny.lineTo(pts[1].fX, pts[1].fY);
                 lastPt = pts[1];
                 break;
             case SkPath::kQuad_Verb:
                 tiny.quadTo(pts[1].fX, pts[1].fY, pts[2].fX, pts[2].fY);
                 lastPt = pts[2];
                 break;
             case SkPath::kCubic_Verb:
                 tiny.cubicTo(pts[1].fX, pts[1].fY, pts[2].fX, pts[2].fY, pts[3].fX, pts[3].fY);
                 lastPt = pts[3];
                 break;
             default:
                 SkDEBUGFAIL("bad verb");
         }
     }
     if (!closed) {
         tiny.close();
     }
     if (show) {
         showPath(tiny, NULL);
         SkDebugf("simplified:\n");
     }
     testSimplifyx(tiny);
 }
 #endif

 #if 0
 static void tryRonco(const SkPath& path) {
     int divMax = 64;
     int divMin = 1;
     int xDivMin = 0;
     int yDivMin = 0;
     bool allYs = true;
     bool allXs = true;
     if (1) {
         divMax = divMin = 64;
         xDivMin = 11;
         yDivMin = 0;
         allXs = true;
         allYs = true;
     }
     for (int divs = divMax; divs >= divMin; divs /= 2) {
         SkDebugf("divs=%d\n",divs);
         const SkRect& overall = path.getBounds();
         SkScalar cellWidth = overall.width() / divs * 2;
         SkScalar cellHeight = overall.height() / divs * 2;
         SkRect target;
         int xDivMax = divMax == divMin && !allXs ? xDivMin + 1 : divs;
         int yDivMax = divMax == divMin && !allYs ? yDivMin + 1 : divs;
         for (int xDiv = xDivMin; xDiv < xDivMax; ++xDiv) {
             SkDebugf("xDiv=%d\n",xDiv);
             for (int yDiv = yDivMin; yDiv < yDivMax; ++yDiv) {
                 SkDebugf("yDiv=%d\n",yDiv);
                 target.setXYWH(overall.fLeft + (overall.width() - cellWidth) * xDiv / divs,
                         overall.fTop + (overall.height() - cellHeight) * yDiv / divs,
                          cellWidth, cellHeight);
                 tryRoncoOnce(path, target, divMax == divMin);
             }
         }
     }
 }
 #endif

 static bool drawLetters(SkCanvas* canvas, int step, bool useOld)
 {
     SkPath path;
     const int width = 640;
     const int height = 480;
     const char testStr[] = "Merge";
     const int testStrLen = sizeof(testStr) - 1;
     SkPoint textPos[testStrLen];
     SkScalar widths[testStrLen];
     SkPaint paint;
     paint.setTextSize(40);
     paint.setAntiAlias(true);
     paint.getTextWidths(testStr, testStrLen, widths, NULL);
     SkScalar running = 0;
     for (int x = 0; x < testStrLen; ++x) {
         SkScalar width = widths[x];
         widths[x] = running;
         running += width;
     }
     SkScalar bias = (width - widths[testStrLen - 1]) / 2;
     for (int x = 0; x < testStrLen; ++x) {
         textPos[x].fX = bias + widths[x];
         textPos[x].fY = height / 2;
     }
     paint.setTextSize(40 + step / 100.0f);
 #if 0
     bool oneShot = false;
     for (int mask = 0; mask < 1 << testStrLen; ++mask) {
         char maskStr[testStrLen];
 #if 1
         mask = 12;
         oneShot = true;
 #endif
         SkDebugf("mask=%d\n", mask);
         for (int letter = 0; letter < testStrLen; ++letter) {
             maskStr[letter] = mask & (1 << letter) ? testStr[letter] : ' ';
         }
         paint.getPosTextPath(maskStr, testStrLen, textPos, &path);
    //     showPath(path, NULL);
    //     SkDebugf("%d simplified:\n", mask);
         tryRonco(path);
     //    testSimplifyx(path);
         if (oneShot) {
             break;
         }
     }
 #endif
     paint.getPosTextPath(testStr, testStrLen, textPos, &path);
 #if 0
     tryRonco(path);
     SkDebugf("RoncoDone!\n");
 #endif
 #if 0
     showPath(path, NULL);
     SkDebugf("simplified:\n");
 #endif
     return drawPaths(canvas, path, false);
 }

 static bool (*drawDemos[])(SkCanvas* , int , bool ) = {
     drawStars,
     drawCircles,
     drawLetters,
 };

 static size_t drawDemosCount = sizeof(drawDemos) / sizeof(drawDemos[0]);

 static bool (*firstTest)(SkCanvas* , int , bool) = drawStars;


 bool DrawEdgeDemo(SkCanvas* canvas, int step, bool useOld) {
     size_t index = 0;
     if (firstTest) {
         while (index < drawDemosCount && drawDemos[index] != firstTest) {
             ++index;
         }
     }
     return (*drawDemos[index])(canvas, step, useOld);
 }
	#include "EdgeDemo.h"
	#include "EdgeWalker_Test.h"
	#include "ShapeOps.h"
	#import "SkCanvas.h"
	#import "SkPaint.h"

	extern void showPath(const SkPath& path, const char* str);

	static bool drawPaths(SkCanvas* canvas, const SkPath& path, bool useOld)
	{
	SkPath out;
	#define SHOW_PATH 0
	#if SHOW_PATH
	showPath(path, "original:");
	#endif
	if (useOld) {
	simplify(path, true, out);
	} else {
	simplifyx(path, out);
	}
	#if SHOW_PATH
	showPath(out, "simplified:");
	#endif
	SkPaint paint;
	paint.setAntiAlias(true);
	paint.setStyle(SkPaint::kStroke_Style);
	// paint.setStrokeWidth(6);
	// paint.setColor(0x1F003f7f);
	// canvas->drawPath(path, paint);
	paint.setColor(0xFF305F00);
	paint.setStrokeWidth(1);
	canvas->drawPath(out, paint);
	return true;
	}

	// Three circles bounce inside a rectangle. The circles describe three, four
	// or five points which in turn describe a polygon. The polygon points
	// bounce inside the circles. The circles rotate and scale over time. The
	// polygons are combined into a single path, simplified, and stroked.
	static bool drawCircles(SkCanvas* canvas, int step, bool useOld)
	{
	const int circles = 3;
	int scales[circles];
	int angles[circles];
	int locs[circles * 2];
	int pts[circles * 2 * 4];
	int c, p;
	for (c = 0; c < circles; ++c) {
	scales[c] = abs(10 - (step + c * 4) % 21);
	angles[c] = (step + c * 6) % 600;
	locs[c * 2] = abs(130 - (step + c * 9) % 261);
	locs[c * 2 + 1] = abs(170 - (step + c * 11) % 341);
	for (p = 0; p < 4; ++p) {
	pts[c * 8 + p * 2] = abs(90 - ((step + c * 121 + p * 13) % 190));
	pts[c * 8 + p * 2 + 1] = abs(110 - ((step + c * 223 + p * 17) % 230));
	}
	}
	SkPath path;
	for (c = 0; c < circles; ++c) {
	for (p = 0; p < 4; ++p) {
	SkScalar x = pts[c * 8 + p * 2];
	SkScalar y = pts[c * 8 + p * 2 + 1];
	x *= 3 + scales[c] / 10.0f;
	y *= 3 + scales[c] / 10.0f;
	SkScalar angle = angles[c] * 3.1415f * 2 / 600;
	SkScalar temp = (SkScalar) (x * cos(angle) - y * sin(angle));
	y = (SkScalar) (x * sin(angle) + y * cos(angle));
	x = temp;
	x += locs[c * 2] * 200 / 130.0f;
	y += locs[c * 2 + 1] * 200 / 170.0f;
	x += 50;
	// y += 200;
	if (p == 0) {
	path.moveTo(x, y);
	} else {
	path.lineTo(x, y);
	}
	}
	path.close();
	}
	return drawPaths(canvas, path, useOld);
	}

	static void createStar(SkPath& path, SkScalar innerRadius, SkScalar outerRadius,
	SkScalar startAngle, int points, SkPoint center) {
	SkScalar angle = startAngle;
	for (int index = 0; index < points * 2; ++index) {
	SkScalar radius = index & 1 ? outerRadius : innerRadius;
	SkScalar x = (SkScalar) (radius * cos(angle));
	SkScalar y = (SkScalar) (radius * sin(angle));
	x += center.fX;
	y += center.fY;
	if (index == 0) {
	path.moveTo(x, y);
	} else {
	path.lineTo(x, y);
	}
	angle += 3.1415f / points;
	}
	path.close();
	}

	static bool drawStars(SkCanvas* canvas, int step, bool useOld)
	{
	SkPath path;
	const int stars = 25;
	int pts[stars];
	// static bool initialize = true;
	int s;
	for (s = 0; s < stars; ++s) {
	pts[s] = 4 + (s % 7);
	}
	SkPoint locs[stars];
	SkScalar angles[stars];
	SkScalar innerRadius[stars];
	SkScalar outerRadius[stars];
	const int width = 640;
	const int height = 480;
	const int margin = 30;
	const int minRadius = 120;
	const int maxInner = 800;
	const int maxOuter = 1153;
	for (s = 0; s < stars; ++s) {
	int starW = (int) (width - margin * 2 + (SkScalar) s * (stars - s) / stars);
	locs[s].fX = (int) (step * (1.3f * (s + 1) / stars) + s * 121) % (starW * 2);
	if (locs[s].fX > starW) {
	locs[s].fX = starW * 2 - locs[s].fX;
	}
	locs[s].fX += margin;
	int starH = (int) (height - margin * 2 + (SkScalar) s * s / stars);
	locs[s].fY = (int) (step * (1.7f * (s + 1) / stars) + s * 183) % (starH * 2);
	if (locs[s].fY > starH) {
	locs[s].fY = starH * 2 - locs[s].fY;
	}
	locs[s].fY += margin;
	angles[s] = ((step + s * 47) % (360 * 4)) * 3.1415f / 180 / 4;
	innerRadius[s] = (step + s * 30) % (maxInner * 2);
	if (innerRadius[s] > maxInner) {
	innerRadius[s] = (maxInner * 2) - innerRadius[s];
	}
	innerRadius[s] = innerRadius[s] / 4 + minRadius;
	outerRadius[s] = (step + s * 70) % (maxOuter * 2);
	if (outerRadius[s] > maxOuter) {
	outerRadius[s] = (maxOuter * 2) - outerRadius[s];
	}
	outerRadius[s] = outerRadius[s] / 4 + minRadius;
	createStar(path, innerRadius[s] / 4.0f, outerRadius[s] / 4.0f,
	angles[s], pts[s], locs[s]);
	}
	return drawPaths(canvas, path, useOld);
	}

	#if 0
	static void tryRoncoOnce(const SkPath& path, const SkRect& target, bool show) {
	// capture everything in a desired rectangle
	SkPath tiny;
	bool closed = true;
	SkPath::Iter iter(path, false);
	SkPoint pts[4];
	SkPath::Verb verb;
	int count = 0;
	SkPoint lastPt;
	while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {
	switch (verb) {
	case SkPath::kMove_Verb:
	count = 0;
	break;
	case SkPath::kLine_Verb:
	count = 1;
	break;
	case SkPath::kQuad_Verb:
	count = 2;
	break;
	case SkPath::kCubic_Verb:
	count = 3;
	break;
	case SkPath::kClose_Verb:
	if (!closed) {
	tiny.close();
	closed = true;
	}
	count = 0;
	break;
	default:
	SkDEBUGFAIL("bad verb");
	}
	if (!count) {
	continue;
	}
	SkRect bounds;
	bounds.set(pts[0].fX, pts[0].fY, pts[0].fX, pts[0].fY);
	for (int i = 1; i <= count; ++i) {
	bounds.growToInclude(pts[i].fX + 0.1f, pts[i].fY + 0.1f);
	}
	if (!SkRect::Intersects(target, bounds)) {
	continue;
	}
	if (closed) {
	tiny.moveTo(pts[0].fX, pts[0].fY);
	closed = false;
	} else if (pts[0] != lastPt) {
	tiny.lineTo(pts[0].fX, pts[0].fY);
	}
	switch (verb) {
	case SkPath::kLine_Verb:
	tiny.lineTo(pts[1].fX, pts[1].fY);
	lastPt = pts[1];
	break;
	case SkPath::kQuad_Verb:
	tiny.quadTo(pts[1].fX, pts[1].fY, pts[2].fX, pts[2].fY);
	lastPt = pts[2];
	break;
	case SkPath::kCubic_Verb:
	tiny.cubicTo(pts[1].fX, pts[1].fY, pts[2].fX, pts[2].fY, pts[3].fX, pts[3].fY);
	lastPt = pts[3];
	break;
	default:
	SkDEBUGFAIL("bad verb");
	}
	}
	if (!closed) {
	tiny.close();
	}
	if (show) {
	showPath(tiny, NULL);
	SkDebugf("simplified:\n");
	}
	testSimplifyx(tiny);
	}
	#endif

	#if 0
	static void tryRonco(const SkPath& path) {
	int divMax = 64;
	int divMin = 1;
	int xDivMin = 0;
	int yDivMin = 0;
	bool allYs = true;
	bool allXs = true;
	if (1) {
	divMax = divMin = 64;
	xDivMin = 11;
	yDivMin = 0;
	allXs = true;
	allYs = true;
	}
	for (int divs = divMax; divs >= divMin; divs /= 2) {
	SkDebugf("divs=%d\n",divs);
	const SkRect& overall = path.getBounds();
	SkScalar cellWidth = overall.width() / divs * 2;
	SkScalar cellHeight = overall.height() / divs * 2;
	SkRect target;
	int xDivMax = divMax == divMin && !allXs ? xDivMin + 1 : divs;
	int yDivMax = divMax == divMin && !allYs ? yDivMin + 1 : divs;
	for (int xDiv = xDivMin; xDiv < xDivMax; ++xDiv) {
	SkDebugf("xDiv=%d\n",xDiv);
	for (int yDiv = yDivMin; yDiv < yDivMax; ++yDiv) {
	SkDebugf("yDiv=%d\n",yDiv);
	target.setXYWH(overall.fLeft + (overall.width() - cellWidth) * xDiv / divs,
	overall.fTop + (overall.height() - cellHeight) * yDiv / divs,
	cellWidth, cellHeight);
	tryRoncoOnce(path, target, divMax == divMin);
	}
	}
	}
	}
	#endif

	static bool drawLetters(SkCanvas* canvas, int step, bool useOld)
	{
	SkPath path;
	const int width = 640;
	const int height = 480;
	const char testStr[] = "Merge";
	const int testStrLen = sizeof(testStr) - 1;
	SkPoint textPos[testStrLen];
	SkScalar widths[testStrLen];
	SkPaint paint;
	paint.setTextSize(40);
	paint.setAntiAlias(true);
	paint.getTextWidths(testStr, testStrLen, widths, NULL);
	SkScalar running = 0;
	for (int x = 0; x < testStrLen; ++x) {
	SkScalar width = widths[x];
	widths[x] = running;
	running += width;
	}
	SkScalar bias = (width - widths[testStrLen - 1]) / 2;
	for (int x = 0; x < testStrLen; ++x) {
	textPos[x].fX = bias + widths[x];
	textPos[x].fY = height / 2;
	}
	paint.setTextSize(40 + step / 100.0f);
	#if 0
	bool oneShot = false;
	for (int mask = 0; mask < 1 << testStrLen; ++mask) {
	char maskStr[testStrLen];
	#if 1
	mask = 12;
	oneShot = true;
	#endif
	SkDebugf("mask=%d\n", mask);
	for (int letter = 0; letter < testStrLen; ++letter) {
	maskStr[letter] = mask & (1 << letter) ? testStr[letter] : ' ';
	}
	paint.getPosTextPath(maskStr, testStrLen, textPos, &path);
	// showPath(path, NULL);
	// SkDebugf("%d simplified:\n", mask);
	tryRonco(path);
	// testSimplifyx(path);
	if (oneShot) {
	break;
	}
	}
	#endif
	paint.getPosTextPath(testStr, testStrLen, textPos, &path);
	#if 0
	tryRonco(path);
	SkDebugf("RoncoDone!\n");
	#endif
	#if 0
	showPath(path, NULL);
	SkDebugf("simplified:\n");
	#endif
	return drawPaths(canvas, path, false);
	}

	static bool (drawDemos[])(SkCanvas , int , bool ) = {
	drawStars,
	drawCircles,
	drawLetters,
	};

	static size_t drawDemosCount = sizeof(drawDemos) / sizeof(drawDemos[0]);

	static bool (firstTest)(SkCanvas , int , bool) = drawStars;


	bool DrawEdgeDemo(SkCanvas* canvas, int step, bool useOld) {
	size_t index = 0;
	if (firstTest) {
	while (index < drawDemosCount && drawDemos[index] != firstTest) {
	++index;
	}
	}
	return (*drawDemos[index])(canvas, step, useOld);
	}