samplecode/SampleAAGeometry.cpp - Issue 2014993002: toy to play with antialias raytracing

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Issue 2014993002: toy to play with antialias raytracing (Closed) Base URL: https://skia.googlesource.com/skia.git@master

Patch Set: one last linux warning Created 4 years, 6 months ago

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	1 /*

	2 * Copyright 2015 Google Inc.

	3 *

	4 * Use of this source code is governed by a BSD-style license that can be

	5 * found in the LICENSE file.

	6 */

	7

	8 #include "SampleCode.h"

	9 #include "SkCanvas.h"

	10 #include "SkGeometry.h"

	11 #include "SkIntersections.h"

	12 #include "SkOpEdgeBuilder.h"

	13 // #include "SkPathOpsSimplifyAA.h"

	14 // #include "SkPathStroker.h"

	15 #include "SkView.h"

	16

	17 #if 0

	18 void SkStrokeSegment::dump() const {

	19 SkDebugf("{{{%1.9g,%1.9g}, {%1.9g,%1.9g}", fPts[0].fX, fPts[0].fY, fPts[1].f X, fPts[1].fY);

	20 if (SkPath::kQuad_Verb == fVerb) {

	21 SkDebugf(", {%1.9g,%1.9g}", fPts[2].fX, fPts[2].fY);

	22 }

	23 SkDebugf("}}");

	24 #ifdef SK_DEBUG

	25 SkDebugf(" id=%d", fDebugID);

	26 #endif

	27 SkDebugf("\n");

	28 }

	29

	30 void SkStrokeSegment::dumpAll() const {

	31 const SkStrokeSegment* segment = this;

	32 while (segment) {

	33 segment->dump();

	34 segment = segment->fNext;

	35 }

	36 }

	37

	38 void SkStrokeTriple::dump() const {

	39 SkDebugf("{{{%1.9g,%1.9g}, {%1.9g,%1.9g}", fPts[0].fX, fPts[0].fY, fPts[1].f X, fPts[1].fY);

	40 if (SkPath::kQuad_Verb <= fVerb) {

	41 SkDebugf(", {%1.9g,%1.9g}", fPts[2].fX, fPts[2].fY);

	42 }

	43 if (SkPath::kCubic_Verb == fVerb) {

	44 SkDebugf(", {%1.9g,%1.9g}", fPts[3].fX, fPts[3].fY);

	45 } else if (SkPath::kConic_Verb == fVerb) {

	46 SkDebugf(", %1.9g", weight());

	47 }

	48 SkDebugf("}}");

	49 #ifdef SK_DEBUG

	50 SkDebugf(" triple id=%d", fDebugID);

	51 #endif

	52 SkDebugf("\ninner:\n");

	53 fInner->dumpAll();

	54 SkDebugf("outer:\n");

	55 fOuter->dumpAll();

	56 SkDebugf("join:\n");

	57 fJoin->dumpAll();

	58 }

	59

	60 void SkStrokeTriple::dumpAll() const {

	61 const SkStrokeTriple* triple = this;

	62 while (triple) {

	63 triple->dump();

	64 triple = triple->fNext;

	65 }

	66 }

	67

	68 void SkStrokeContour::dump() const {

	69 #ifdef SK_DEBUG

	70 SkDebugf("id=%d ", fDebugID);

	71 #endif

	72 SkDebugf("head:\n");

	73 fHead->dumpAll();

	74 SkDebugf("head cap:\n");

	75 fHeadCap->dumpAll();

	76 SkDebugf("tail cap:\n");

	77 fTailCap->dumpAll();

	78 }

	79

	80 void SkStrokeContour::dumpAll() const {

	81 const SkStrokeContour* contour = this;

	82 while (contour) {

	83 contour->dump();

	84 contour = contour->fNext;

	85 }

	86 }

	87 #endif

	88

	89 SkScalar gCurveDistance = 10;

	90

	91 #if 0 // unused

	92 static SkPath::Verb get_path_verb(int index, const SkPath& path) {

	93 if (index < 0) {

	94 return SkPath::kMove_Verb;

	95 }

	96 SkPoint pts[4];

	97 SkPath::Verb verb;

	98 SkPath::Iter iter(path, true);

	99 int counter = -1;

	100 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	101 if (++counter < index) {

	102 continue;

	103 }

	104 return verb;

	105 }

	106 SkASSERT(0);

	107 return SkPath::kMove_Verb;

	108 }

	109 #endif

	110

	111 static SkScalar get_path_weight(int index, const SkPath& path) {

	112 SkPoint pts[4];

	113 SkPath::Verb verb;

	114 SkPath::Iter iter(path, true);

	115 int counter = -1;

	116 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	117 if (++counter < index) {

	118 continue;

	119 }

	120 return verb == SkPath::kConic_Verb ? iter.conicWeight() : 1;

	121 }

	122 SkASSERT(0);

	123 return 0;

	124 }

	125

	126 static void set_path_pt(int index, const SkPoint& pt, SkPath* path) {

	127 SkPath result;

	128 SkPoint pts[4];

	129 SkPath::Verb verb;

	130 SkPath::RawIter iter(*path);

	131 int startIndex = 0;

	132 int endIndex = 0;

	133 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	134 switch (verb) {

	135 case SkPath::kMove_Verb:

	136 endIndex += 1;

	137 break;

	138 case SkPath::kLine_Verb:

	139 endIndex += 1;

	140 break;

	141 case SkPath::kQuad_Verb:

	142 case SkPath::kConic_Verb:

	143 endIndex += 2;

	144 break;

	145 case SkPath::kCubic_Verb:

	146 endIndex += 3;

	147 break;

	148 case SkPath::kClose_Verb:

	149 break;

	150 case SkPath::kDone_Verb:

	151 break;

	152 default:

	153 SkASSERT(0);

	154 }

	155 if (startIndex <= index && index < endIndex) {

	156 pts[index - startIndex] = pt;

	157 index = -1;

	158 }

	159 switch (verb) {

	160 case SkPath::kMove_Verb:

	161 result.moveTo(pts[0]);

	162 break;

	163 case SkPath::kLine_Verb:

	164 result.lineTo(pts[1]);

	165 startIndex += 1;

	166 break;

	167 case SkPath::kQuad_Verb:

	168 result.quadTo(pts[1], pts[2]);

	169 startIndex += 2;

	170 break;

	171 case SkPath::kConic_Verb:

	172 result.conicTo(pts[1], pts[2], iter.conicWeight());

	173 startIndex += 2;

	174 break;

	175 case SkPath::kCubic_Verb:

	176 result.cubicTo(pts[1], pts[2], pts[3]);

	177 startIndex += 3;

	178 break;

	179 case SkPath::kClose_Verb:

	180 result.close();

	181 startIndex += 1;

	182 break;

	183 case SkPath::kDone_Verb:

	184 break;

	185 default:

	186 SkASSERT(0);

	187 }

	188 }

	189 #if 0

	190 SkDebugf("\n\noriginal\n");

	191 path->dump();

	192 SkDebugf("\nedited\n");

	193 result.dump();

	194 #endif

	195 *path = result;

	196 }

	197

	198 static void add_path_segment(int index, SkPath* path) {

	199 SkPath result;

	200 SkPoint pts[4];

	201 SkPoint firstPt = { 0, 0 }; // init to avoid warning

	202 SkPoint lastPt = { 0, 0 }; // init to avoid warning

	203 SkPath::Verb verb;

	204 SkPath::RawIter iter(*path);

	205 int counter = -1;

	206 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	207 SkScalar weight SK_INIT_TO_AVOID_WARNING;

	208 if (++counter == index) {

	209 switch (verb) {

	210 case SkPath::kLine_Verb:

	211 result.lineTo((pts[0].fX + pts[1].fX) / 2, (pts[0].fY + pts[ 1].fY) / 2);

	212 break;

	213 case SkPath::kQuad_Verb: {

	214 SkPoint chop[5];

	215 SkChopQuadAtHalf(pts, chop);

	216 result.quadTo(chop[1], chop[2]);

	217 pts[1] = chop[3];

	218 } break;

	219 case SkPath::kConic_Verb: {

	220 SkConic chop[2];

	221 SkConic conic;

	222 conic.set(pts, iter.conicWeight());

	223 conic.chopAt(0.5f, chop);

	224 result.conicTo(chop[0].fPts[1], chop[0].fPts[2], chop[0].fW) ;

	225 pts[1] = chop[1].fPts[1];

	226 weight = chop[1].fW;

	227 } break;

	228 case SkPath::kCubic_Verb: {

	229 SkPoint chop[7];

	230 SkChopCubicAtHalf(pts, chop);

	231 result.cubicTo(chop[1], chop[2], chop[3]);

	232 pts[1] = chop[4];

	233 pts[2] = chop[5];

	234 } break;

	235 case SkPath::kClose_Verb: {

	236 result.lineTo((lastPt.fX + firstPt.fX) / 2, (lastPt.fY + fir stPt.fY) / 2);

	237 } break;

	238 default:

	239 SkASSERT(0);

	240 }

	241 } else if (verb == SkPath::kConic_Verb) {

	242 weight = iter.conicWeight();

	243 }

	244 switch (verb) {

	245 case SkPath::kMove_Verb:

	246 result.moveTo(firstPt = pts[0]);

	247 break;

	248 case SkPath::kLine_Verb:

	249 result.lineTo(lastPt = pts[1]);

	250 break;

	251 case SkPath::kQuad_Verb:

	252 result.quadTo(pts[1], lastPt = pts[2]);

	253 break;

	254 case SkPath::kConic_Verb:

	255 result.conicTo(pts[1], lastPt = pts[2], weight);

	256 break;

	257 case SkPath::kCubic_Verb:

	258 result.cubicTo(pts[1], pts[2], lastPt = pts[3]);

	259 break;

	260 case SkPath::kClose_Verb:

	261 result.close();

	262 break;

	263 case SkPath::kDone_Verb:

	264 break;

	265 default:

	266 SkASSERT(0);

	267 }

	268 }

	269 *path = result;

	270 }

	271

	272 static void delete_path_segment(int index, SkPath* path) {

	273 SkPath result;

	274 SkPoint pts[4];

	275 SkPath::Verb verb;

	276 SkPath::RawIter iter(*path);

	277 int counter = -1;

	278 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	279 if (++counter == index) {

	280 continue;

	281 }

	282 switch (verb) {

	283 case SkPath::kMove_Verb:

	284 result.moveTo(pts[0]);

	285 break;

	286 case SkPath::kLine_Verb:

	287 result.lineTo(pts[1]);

	288 break;

	289 case SkPath::kQuad_Verb:

	290 result.quadTo(pts[1], pts[2]);

	291 break;

	292 case SkPath::kConic_Verb:

	293 result.conicTo(pts[1], pts[2], iter.conicWeight());

	294 break;

	295 case SkPath::kCubic_Verb:

	296 result.cubicTo(pts[1], pts[2], pts[3]);

	297 break;

	298 case SkPath::kClose_Verb:

	299 result.close();

	300 break;

	301 case SkPath::kDone_Verb:

	302 break;

	303 default:

	304 SkASSERT(0);

	305 }

	306 }

	307 *path = result;

	308 }

	309

	310 static void set_path_weight(int index, SkScalar w, SkPath* path) {

	311 SkPath result;

	312 SkPoint pts[4];

	313 SkPath::Verb verb;

	314 SkPath::Iter iter(*path, true);

	315 int counter = -1;

	316 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	317 ++counter;

	318 switch (verb) {

	319 case SkPath::kMove_Verb:

	320 result.moveTo(pts[0]);

	321 break;

	322 case SkPath::kLine_Verb:

	323 result.lineTo(pts[1]);

	324 break;

	325 case SkPath::kQuad_Verb:

	326 result.quadTo(pts[1], pts[2]);

	327 break;

	328 case SkPath::kConic_Verb:

	329 result.conicTo(pts[1], pts[2], counter == index ? w : iter.conic Weight());

	330 break;

	331 case SkPath::kCubic_Verb:

	332 result.cubicTo(pts[1], pts[2], pts[3]);

	333 break;

	334 case SkPath::kClose_Verb:

	335 result.close();

	336 break;

	337 case SkPath::kDone_Verb:

	338 break;

	339 default:

	340 SkASSERT(0);

	341 }

	342 }

	343 *path = result;

	344 }

	345

	346 static void set_path_verb(int index, SkPath::Verb v, SkPath* path, SkScalar w) {

	347 SkASSERT(SkPath::kLine_Verb <= v && v <= SkPath::kCubic_Verb);

	348 SkPath result;

	349 SkPoint pts[4];

	350 SkPath::Verb verb;

	351 SkPath::Iter iter(*path, true);

	352 int counter = -1;

	353 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	354 SkScalar weight = verb == SkPath::kConic_Verb ? iter.conicWeight() : 1;

	355 if (++counter == index && v != verb) {

	356 SkASSERT(SkPath::kLine_Verb <= verb && verb <= SkPath::kCubic_Verb);

	357 switch (verb) {

	358 case SkPath::kLine_Verb:

	359 switch (v) {

	360 case SkPath::kConic_Verb:

	361 weight = w;

	362 case SkPath::kQuad_Verb:

	363 pts[2] = pts[1];

	364 pts[1].fX = (pts[0].fX + pts[2].fX) / 2;

	365 pts[1].fY = (pts[0].fY + pts[2].fY) / 2;

	366 break;

	367 case SkPath::kCubic_Verb:

	368 pts[3] = pts[1];

	369 pts[1].fX = (pts[0].fX * 2 + pts[3].fX) / 3;

	370 pts[1].fY = (pts[0].fY * 2 + pts[3].fY) / 3;

	371 pts[2].fX = (pts[0].fX + pts[3].fX * 2) / 3;

	372 pts[2].fY = (pts[0].fY + pts[3].fY * 2) / 3;

	373 break;

	374 default:

	375 SkASSERT(0);

	376 break;

	377 }

	378 break;

	379 case SkPath::kQuad_Verb:

	380 case SkPath::kConic_Verb:

	381 switch (v) {

	382 case SkPath::kLine_Verb:

	383 pts[1] = pts[2];

	384 break;

	385 case SkPath::kConic_Verb:

	386 weight = w;

	387 case SkPath::kQuad_Verb:

	388 break;

	389 case SkPath::kCubic_Verb: {

	390 SkDQuad dQuad;

	391 dQuad.set(pts);

	392 SkDCubic dCubic = dQuad.debugToCubic();

	393 pts[3] = pts[2];

	394 pts[1] = dCubic[1].asSkPoint();

	395 pts[2] = dCubic[2].asSkPoint();

	396 } break;

	397 default:

	398 SkASSERT(0);

	399 break;

	400 }

	401 break;

	402 case SkPath::kCubic_Verb:

	403 switch (v) {

	404 case SkPath::kLine_Verb:

	405 pts[1] = pts[3];

	406 break;

	407 case SkPath::kConic_Verb:

	408 weight = w;

	409 case SkPath::kQuad_Verb: {

	410 SkDCubic dCubic;

	411 dCubic.set(pts);

	412 SkDQuad dQuad = dCubic.toQuad();

	413 pts[1] = dQuad[1].asSkPoint();

	414 pts[2] = pts[3];

	415 } break;

	416 default:

	417 SkASSERT(0);

	418 break;

	419 }

	420 break;

	421 default:

	422 SkASSERT(0);

	423 break;

	424 }

	425 verb = v;

	426 }

	427 switch (verb) {

	428 case SkPath::kMove_Verb:

	429 result.moveTo(pts[0]);

	430 break;

	431 case SkPath::kLine_Verb:

	432 result.lineTo(pts[1]);

	433 break;

	434 case SkPath::kQuad_Verb:

	435 result.quadTo(pts[1], pts[2]);

	436 break;

	437 case SkPath::kConic_Verb:

	438 result.conicTo(pts[1], pts[2], weight);

	439 break;

	440 case SkPath::kCubic_Verb:

	441 result.cubicTo(pts[1], pts[2], pts[3]);

	442 break;

	443 case SkPath::kClose_Verb:

	444 result.close();

	445 break;

	446 default:

	447 SkASSERT(0);

	448 break;

	449 }

	450 }

	451 *path = result;

	452 }

	453

	454 static void add_to_map(SkScalar coverage, int x, int y, uint8_t* distanceMap, in t w, int h) {

	455 int byteCoverage = (int) (coverage * 256);

	456 if (byteCoverage < 0) {

	457 byteCoverage = 0;

	458 } else if (byteCoverage > 255) {

	459 byteCoverage = 255;

	460 }

	461 SkASSERT(x < w);

	462 SkASSERT(y < h);

	463 distanceMap[y * w + x] = SkTMax(distanceMap[y * w + x], (uint8_t) byteCovera ge);

	464 }

	465

	466 static void filter_coverage(const uint8_t* map, int len, uint8_t min, uint8_t ma x,

	467 uint8_t* filter) {

	468 for (int index = 0; index < len; ++index) {

	469 uint8_t in = map[index];

	470 filter[index] = in < min ? 0 : max < in ? 0 : in;

	471 }

	472 }

	473

	474 static void construct_path(SkPath& path) {

	475 path.reset();

	476 path.moveTo(442, 101.5f);

	477 path.quadTo(413.5f, 691, 772, 514);

	478 path.lineTo(346, 721.5f);

	479 path.lineTo(154, 209);

	480 path.lineTo(442, 101.5f);

	481 path.close();

	482 }

	483

	484 struct ButtonPaints {

	485 static const int kMaxStateCount = 3;

	486 SkPaint fDisabled;

	487 SkPaint fStates[kMaxStateCount];

	488 SkPaint fLabel;

	489

	490 ButtonPaints() {

	491 fStates[0].setAntiAlias(true);

	492 fStates[0].setStyle(SkPaint::kStroke_Style);

	493 fStates[0].setColor(0xFF3F0000);

	494 fStates[1] = fStates[0];

	495 fStates[1].setStrokeWidth(3);

	496 fStates[2] = fStates[1];

	497 fStates[2].setColor(0xFFcf0000);

	498 fLabel.setAntiAlias(true);

	499 fLabel.setTextSize(25.0f);

	500 fLabel.setTextAlign(SkPaint::kCenter_Align);

	501 fLabel.setStyle(SkPaint::kFill_Style);

	502 }

	503 };

	504

	505 struct Button {

	506 SkRect fBounds;

	507 int fStateCount;

	508 int fState;

	509 char fLabel;

	510 bool fVisible;

	511

	512 Button(char label) {

	513 fStateCount = 2;

	514 fState = 0;

	515 fLabel = label;

	516 fVisible = false;

	517 }

	518

	519 Button(char label, int stateCount) {

	520 SkASSERT(stateCount <= ButtonPaints::kMaxStateCount);

	521 fStateCount = stateCount;

	522 fState = 0;

	523 fLabel = label;

	524 fVisible = false;

	525 }

	526

	527 bool contains(const SkRect& rect) {

	528 return fVisible && fBounds.contains(rect);

	529 }

	530

	531 bool enabled() {

	532 return SkToBool(fState);

	533 }

	534

	535 void draw(SkCanvas* canvas, const ButtonPaints& paints) {

	536 if (!fVisible) {

	537 return;

	538 }

	539 canvas->drawRect(fBounds, paints.fStates[fState]);

	540 canvas->drawText(&fLabel, 1, fBounds.centerX(), fBounds.fBottom - 5, pai nts.fLabel);

	541 }

	542

	543 void toggle() {

	544 if (++fState == fStateCount) {

	545 fState = 0;

	546 }

	547 }

	548

	549 void setEnabled(bool enabled) {

	550 fState = (int) enabled;

	551 }

	552 };

	553

	554 struct ControlPaints {

	555 SkPaint fOutline;

	556 SkPaint fIndicator;

	557 SkPaint fFill;

	558 SkPaint fLabel;

	559 SkPaint fValue;

	560

	561 ControlPaints() {

	562 fOutline.setAntiAlias(true);

	563 fOutline.setStyle(SkPaint::kStroke_Style);

	564 fIndicator = fOutline;

	565 fIndicator.setColor(SK_ColorRED);

	566 fFill.setAntiAlias(true);

	567 fFill.setColor(0x7fff0000);

	568 fLabel.setAntiAlias(true);

	569 fLabel.setTextSize(13.0f);

	570 fValue.setAntiAlias(true);

	571 fValue.setTextSize(11.0f);

	572 }

	573 };

	574

	575 struct UniControl {

	576 SkString fName;

	577 SkRect fBounds;

	578 SkScalar fMin;

	579 SkScalar fMax;

	580 SkScalar fValLo;

	581 SkScalar fYLo;

	582 bool fVisible;

	583

	584 UniControl(const char* name, SkScalar min, SkScalar max) {

	585 fName = name;

	586 fValLo = fMin = min;

	587 fMax = max;

	588 fVisible = false;

	589

	590 }

	591

	592 virtual ~UniControl() {}

	593

	594 bool contains(const SkRect& rect) {

	595 return fVisible && fBounds.contains(rect);

	596 }

	597

	598 virtual void draw(SkCanvas* canvas, const ControlPaints& paints) {

	599 if (!fVisible) {

	600 return;

	601 }

	602 canvas->drawRect(fBounds, paints.fOutline);

	603 fYLo = fBounds.fTop + (fValLo - fMin) * fBounds.height() / (fMax - fMin) ;

	604 canvas->drawLine(fBounds.fLeft - 5, fYLo, fBounds.fRight + 5, fYLo, pain ts.fIndicator);

	605 SkString label;

	606 label.printf("%0.3g", fValLo);

	607 canvas->drawText(label.c_str(), label.size(), fBounds.fLeft + 5, fYLo - 5, paints.fValue);

	608 canvas->drawText(fName.c_str(), fName.size(), fBounds.fLeft, fBounds.bot tom() + 11,

	609 paints.fLabel);

	610 }

	611 };

	612

	613 struct BiControl : public UniControl {

	614 SkScalar fValHi;

	615

	616 BiControl(const char* name, SkScalar min, SkScalar max)

	617 : UniControl(name, min, max)

	618 , fValHi(fMax) {

	619 }

	620

	621 virtual ~BiControl() {}

	622

	623 virtual void draw(SkCanvas* canvas, const ControlPaints& paints) {

	624 UniControl::draw(canvas, paints);

	625 if (!fVisible \|\| fValHi == fValLo) {

	626 return;

	627 }

	628 SkScalar yPos = fBounds.fTop + (fValHi - fMin) * fBounds.height() / (fMa x - fMin);

	629 canvas->drawLine(fBounds.fLeft - 5, yPos, fBounds.fRight + 5, yPos, pain ts.fIndicator);

	630 SkString label;

	631 label.printf("%0.3g", fValHi);

	632 if (yPos < fYLo + 10) {

	633 yPos = fYLo + 10;

	634 }

	635 canvas->drawText(label.c_str(), label.size(), fBounds.fLeft + 5, yPos - 5, paints.fValue);

	636 SkRect fill = { fBounds.fLeft, fYLo, fBounds.fRight, yPos };

	637 canvas->drawRect(fill, paints.fFill);

	638 }

	639 };

	640

	641

	642 class MyClick : public SampleView::Click {

	643 public:

	644 enum ClickType {

	645 kInvalidType = -1,

	646 kPtType,

	647 kVerbType,

	648 kControlType,

	649 kPathType,

	650 } fType;

	651

	652 enum ControlType {

	653 kInvalidControl = -1,

	654 kFirstControl,

	655 kFilterControl = kFirstControl,

	656 kResControl,

	657 kWeightControl,

	658 kWidthControl,

	659 kLastControl = kWidthControl,

	660 kFirstButton,

	661 kCubicButton = kFirstButton,

	662 kConicButton,

	663 kQuadButton,

	664 kLineButton,

	665 kLastVerbButton = kLineButton,

	666 kAddButton,

	667 kDeleteButton,

	668 kInOutButton,

	669 kFillButton,

	670 kSkeletonButton,

	671 kFilterButton,

	672 kBisectButton,

	673 kJoinButton,

	674 kLastButton = kJoinButton,

	675 kPathMove,

	676 } fControl;

	677

	678 SkPath::Verb fVerb;

	679 SkScalar fWeight;

	680

	681 MyClick(SkView* target, ClickType type, ControlType control)

	682 : Click(target)

	683 , fType(type)

	684 , fControl(control)

	685 , fVerb((SkPath::Verb) -1)

	686 , fWeight(1) {

	687 }

	688

	689 MyClick(SkView* target, ClickType type, int index)

	690 : Click(target)

	691 , fType(type)

	692 , fControl((ControlType) index)

	693 , fVerb((SkPath::Verb) -1)

	694 , fWeight(1) {

	695 }

	696

	697 MyClick(SkView* target, ClickType type, int index, SkPath::Verb verb, SkScal ar weight)

	698 : Click(target)

	699 , fType(type)

	700 , fControl((ControlType) index)

	701 , fVerb(verb)

	702 , fWeight(weight) {

	703 }

	704

	705 bool isButton() {

	706 return kFirstButton <= fControl && fControl <= kLastButton;

	707 }

	708

	709 int ptHit() const {

	710 SkASSERT(fType == kPtType);

	711 return (int) fControl;

	712 }

	713

	714 int verbHit() const {

	715 SkASSERT(fType == kVerbType);

	716 return (int) fControl;

	717 }

	718 };

	719

	720 enum {

	721 kControlCount = MyClick::kLastControl - MyClick::kFirstControl + 1,

	722 };

	723

	724 static struct ControlPair {

	725 UniControl* fControl;

	726 MyClick::ControlType fControlType;

	727 } kControlList[kControlCount];

	728

	729 enum {

	730 kButtonCount = MyClick::kLastButton - MyClick::kFirstButton + 1,

	731 kVerbCount = MyClick::kLastVerbButton - MyClick::kFirstButton + 1,

	732 };

	733

	734 static struct ButtonPair {

	735 Button* fButton;

	736 MyClick::ControlType fButtonType;

	737 } kButtonList[kButtonCount];

	738

	739 static void enable_verb_button(MyClick::ControlType type) {

	740 for (int index = 0; index < kButtonCount; ++index) {

	741 MyClick::ControlType testType = kButtonList[index].fButtonType;

	742 if (MyClick::kFirstButton <= testType && testType <= MyClick::kLastVerbB utton) {

	743 Button* button = kButtonList[index].fButton;

	744 button->setEnabled(testType == type);

	745 }

	746 }

	747 }

	748

	749 struct Stroke;

	750

	751 struct Active {

	752 Active* fNext;

	753 Stroke* fParent;

	754 SkScalar fStart;

	755 SkScalar fEnd;

	756

	757 void reset() {

	758 fNext = NULL;

	759 fStart = 0;

	760 fEnd = 1;

	761 }

	762 };

	763

	764 struct Stroke {

	765 SkPath fPath;

	766 Active fActive;

	767 bool fInner;

	768

	769 void reset() {

	770 fPath.reset();

	771 fActive.reset();

	772 }

	773 };

	774

	775 struct PathUndo {

	776 SkPath fPath;

	777 PathUndo* fNext;

	778 };

	779

	780 class AAGeometryView : public SampleView {

	781 SkPaint fActivePaint;

	782 SkPaint fComplexPaint;

	783 SkPaint fCoveragePaint;

	784 SkPaint fLegendLeftPaint;

	785 SkPaint fLegendRightPaint;

	786 SkPaint fPointPaint;

	787 SkPaint fSkeletonPaint;

	788 SkPaint fLightSkeletonPaint;

	789 SkPath fPath;

	790 ControlPaints fControlPaints;

	791 UniControl fResControl;

	792 UniControl fWeightControl;

	793 UniControl fWidthControl;

	794 BiControl fFilterControl;

	795 ButtonPaints fButtonPaints;

	796 Button fCubicButton;

	797 Button fConicButton;

	798 Button fQuadButton;

	799 Button fLineButton;

	800 Button fAddButton;

	801 Button fDeleteButton;

	802 Button fFillButton;

	803 Button fSkeletonButton;

	804 Button fFilterButton;

	805 Button fBisectButton;

	806 Button fJoinButton;

	807 Button fInOutButton;

	808 SkTArray<Stroke> fStrokes;

	809 PathUndo* fUndo;

	810 int fActivePt;

	811 int fActiveVerb;

	812 bool fHandlePathMove;

	813 bool fShowLegend;

	814 bool fHideAll;

	815 const int kHitToleranace = 5;

	816

	817 public:

	818

	819 AAGeometryView()

	820 : fResControl("error", 0, 10)

	821 , fWeightControl("weight", 0, 5)

	822 , fWidthControl("width", FLT_EPSILON, 100)

	823 , fFilterControl("filter", 0, 255)

	824 , fCubicButton('C')

	825 , fConicButton('K')

	826 , fQuadButton('Q')

	827 , fLineButton('L')

	828 , fAddButton('+')

	829 , fDeleteButton('x')

	830 , fFillButton('p')

	831 , fSkeletonButton('s')

	832 , fFilterButton('f', 3)

	833 , fBisectButton('b')

	834 , fJoinButton('j')

	835 , fInOutButton('\|')

	836 , fUndo(NULL)

	837 , fActivePt(-1)

	838 , fActiveVerb(-1)

	839 , fHandlePathMove(true)

	840 , fShowLegend(false)

	841 , fHideAll(false)

	842 {

	843 fCoveragePaint.setAntiAlias(true);

	844 fCoveragePaint.setColor(SK_ColorBLUE);

	845 SkPaint strokePaint;

	846 strokePaint.setAntiAlias(true);

	847 strokePaint.setStyle(SkPaint::kStroke_Style);

	848 fPointPaint = strokePaint;

	849 fPointPaint.setColor(0x99ee3300);

	850 fSkeletonPaint = strokePaint;

	851 fSkeletonPaint.setColor(SK_ColorRED);

	852 fLightSkeletonPaint = fSkeletonPaint;

	853 fLightSkeletonPaint.setColor(0xFFFF7f7f);

	854 fActivePaint = strokePaint;

	855 fActivePaint.setColor(0x99ee3300);

	856 fActivePaint.setStrokeWidth(5);

	857 fComplexPaint = fActivePaint;

	858 fComplexPaint.setColor(SK_ColorBLUE);

	859 fLegendLeftPaint.setAntiAlias(true);

	860 fLegendLeftPaint.setTextSize(13);

	861 fLegendRightPaint = fLegendLeftPaint;

	862 fLegendRightPaint.setTextAlign(SkPaint::kRight_Align);

	863 construct_path(fPath);

	864 fFillButton.fVisible = fSkeletonButton.fVisible = fFilterButton.fVisible

	865 = fBisectButton.fVisible = fJoinButton.fVisible = fInOutButton.f Visible = true;

	866 fSkeletonButton.setEnabled(true);

	867 fInOutButton.setEnabled(true);

	868 fJoinButton.setEnabled(true);

	869 fFilterControl.fValLo = 120;

	870 fFilterControl.fValHi = 141;

	871 fFilterControl.fVisible = fFilterButton.fState == 2;

	872 fResControl.fValLo = 5;

	873 fResControl.fVisible = true;

	874 fWidthControl.fValLo = 50;

	875 fWidthControl.fVisible = true;

	876 init_controlList();

	877 init_buttonList();

	878 }

	879

	880 bool constructPath() {

	881 construct_path(fPath);

	882 this->inval(NULL);

	883 return true;

	884 }

	885

	886 void savePath(Click::State state) {

	887 if (state != Click::kDown_State) {

	888 return;

	889 }

	890 if (fUndo && fUndo->fPath == fPath) {

	891 return;

	892 }

	893 PathUndo* undo = new PathUndo;

	894 undo->fPath = fPath;

	895 undo->fNext = fUndo;

	896 fUndo = undo;

	897 }

	898

	899 bool undo() {

	900 if (!fUndo) {

	901 return false;

	902 }

	903 fPath = fUndo->fPath;

	904 validatePath();

	905 PathUndo* next = fUndo->fNext;

	906 delete fUndo;

	907 fUndo = next;

	908 this->inval(NULL);

	909 return true;

	910 }

	911

	912 void validatePath() {

	913 PathUndo* undo = fUndo;

	914 int match = 0;

	915 while (undo) {

	916 match += fPath == undo->fPath;

	917 undo = undo->fNext;

	918 }

	919 }

	920

	921 void set_controlList(int index, UniControl* control, MyClick::ControlType ty pe) {

	922 kControlList[index].fControl = control;

	923 kControlList[index].fControlType = type;

	924 }

	925

	926 #define SET_CONTROL(Name) set_controlList(index++, &f##Name##Control, \

	927 MyClick::k##Name##Control)

	928

	929 bool hideAll() {

	930 fHideAll ^= true;

	931 this->inval(NULL);

	932 return true;

	933 }

	934

	935 void init_controlList() {

	936 int index = 0;

	937 SET_CONTROL(Width);

	938 SET_CONTROL(Res);

	939 SET_CONTROL(Filter);

	940 SET_CONTROL(Weight);

	941 };

	942

	943 #undef SET_CONTROL

	944

	945 void set_buttonList(int index, Button* button, MyClick::ControlType type) {

	946 kButtonList[index].fButton = button;

	947 kButtonList[index].fButtonType = type;

	948 }

	949

	950 #define SET_BUTTON(Name) set_buttonList(index++, &f##Name##Button, \

	951 MyClick::k##Name##Button)

	952

	953 void init_buttonList() {

	954 int index = 0;

	955 SET_BUTTON(Fill);

	956 SET_BUTTON(Skeleton);

	957 SET_BUTTON(Filter);

	958 SET_BUTTON(Bisect);

	959 SET_BUTTON(Join);

	960 SET_BUTTON(InOut);

	961 SET_BUTTON(Cubic);

	962 SET_BUTTON(Conic);

	963 SET_BUTTON(Quad);

	964 SET_BUTTON(Line);

	965 SET_BUTTON(Add);

	966 SET_BUTTON(Delete);

	967 }

	968

	969 #undef SET_BUTTON

	970

	971 // overrides from SkEventSink

	972 bool onQuery(SkEvent* evt) override;

	973

	974 void onSizeChange() override {

	975 setControlButtonsPos();

	976 this->INHERITED::onSizeChange();

	977 }

	978

	979 bool pathDump() {

	980 fPath.dump();

	981 return true;

	982 }

	983

	984 bool scaleDown() {

	985 SkMatrix matrix;

	986 SkRect bounds = fPath.getBounds();

	987 matrix.setScale(1.f / 1.5f, 1.f / 1.5f, bounds.centerX(), bounds.centerY ());

	988 fPath.transform(matrix);

	989 validatePath();

	990 this->inval(NULL);

	991 return true;

	992 }

	993

	994 bool scaleToFit() {

	995 SkMatrix matrix;

	996 SkRect bounds = fPath.getBounds();

	997 SkScalar scale = SkTMin(this->width() / bounds.width(), this->height() / bounds.height())

	998 * 0.8f;

	999 matrix.setScale(scale, scale, bounds.centerX(), bounds.centerY());

	1000 fPath.transform(matrix);

	1001 bounds = fPath.getBounds();

	1002 SkScalar offsetX = (this->width() - bounds.width()) / 2 - bounds.fLeft;

	1003 SkScalar offsetY = (this->height() - bounds.height()) / 2 - bounds.fTop;

	1004 fPath.offset(offsetX, offsetY);

	1005 validatePath();

	1006 this->inval(NULL);

	1007 return true;

	1008 }

	1009

	1010 bool scaleUp() {

	1011 SkMatrix matrix;

	1012 SkRect bounds = fPath.getBounds();

	1013 matrix.setScale(1.5f, 1.5f, bounds.centerX(), bounds.centerY());

	1014 fPath.transform(matrix);

	1015 validatePath();

	1016 this->inval(NULL);

	1017 return true;

	1018 }

	1019

	1020 void setControlButtonsPos() {

	1021 SkScalar widthOffset = this->width() - 100;

	1022 for (int index = 0; index < kControlCount; ++index) {

	1023 if (kControlList[index].fControl->fVisible) {

	1024 kControlList[index].fControl->fBounds.setXYWH(widthOffset, 30, 3 0, 400);

	1025 widthOffset -= 50;

	1026 }

	1027 }

	1028 SkScalar buttonOffset = 0;

	1029 for (int index = 0; index < kButtonCount; ++index) {

	1030 kButtonList[index].fButton->fBounds.setXYWH(this->width() - 50,

	1031 buttonOffset += 50, 30, 30);

	1032 }

	1033 }

	1034

	1035 bool showLegend() {

	1036 fShowLegend ^= true;

	1037 this->inval(NULL);

	1038 return true;

	1039 }

	1040

	1041 void draw_bisect(SkCanvas* canvas, const SkVector& lastVector, const SkVecto r& vector,

	1042 const SkPoint& pt) {

	1043 SkVector lastV = lastVector;

	1044 SkScalar lastLen = lastVector.length();

	1045 SkVector nextV = vector;

	1046 SkScalar nextLen = vector.length();

	1047 if (lastLen < nextLen) {

	1048 lastV.setLength(nextLen);

	1049 } else {

	1050 nextV.setLength(lastLen);

	1051 }

	1052

	1053 SkVector bisect = { (lastV.fX + nextV.fX) / 2, (lastV.fY + nextV.fY) / 2 };

	1054 bisect.setLength(fWidthControl.fValLo * 2);

	1055 if (fBisectButton.enabled()) {

	1056 canvas->drawLine(pt.fX, pt.fY, pt.fX + bisect.fX, pt.fY + bisect.fY, fSkeletonPaint);

	1057 }

	1058 lastV.setLength(fWidthControl.fValLo);

	1059 if (fBisectButton.enabled()) {

	1060 canvas->drawLine(pt.fX, pt.fY, pt.fX - lastV.fY, pt.fY + lastV.fX, f SkeletonPaint);

	1061 }

	1062 nextV.setLength(fWidthControl.fValLo);

	1063 if (fBisectButton.enabled()) {

	1064 canvas->drawLine(pt.fX, pt.fY, pt.fX + nextV.fY, pt.fY - nextV.fX, f SkeletonPaint);

	1065 }

	1066 if (fJoinButton.enabled()) {

	1067 SkScalar r = fWidthControl.fValLo;

	1068 SkRect oval = { pt.fX - r, pt.fY - r, pt.fX + r, pt.fY + r};

	1069 SkScalar startAngle = SkScalarATan2(lastV.fX, -lastV.fY) * 180.f / S K_ScalarPI;

	1070 SkScalar endAngle = SkScalarATan2(-nextV.fX, nextV.fY) * 180.f / SK_ ScalarPI;

	1071 if (endAngle > startAngle) {

	1072 canvas->drawArc(oval, startAngle, endAngle - startAngle, false, fSkeletonPaint);

	1073 } else {

	1074 canvas->drawArc(oval, startAngle, 360 - (startAngle - endAngle), false,

	1075 fSkeletonPaint);

	1076 }

	1077 }

	1078 }

	1079

	1080 void draw_bisects(SkCanvas* canvas, bool activeOnly) {

	1081 SkVector firstVector, lastVector, nextLast, vector;

	1082 SkPoint pts[4];

	1083 SkPoint firstPt = { 0, 0 }; // init to avoid warning;

	1084 SkPath::Verb verb;

	1085 SkPath::Iter iter(fPath, true);

	1086 bool foundFirst = false;

	1087 int counter = -1;

	1088 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	1089 ++counter;

	1090 if (activeOnly && counter != fActiveVerb && counter - 1 != fActiveVe rb

	1091 && counter + 1 != fActiveVerb

	1092 && (fActiveVerb != 1 \|\| counter != fPath.countVerbs())) {

	1093 continue;

	1094 }

	1095 switch (verb) {

	1096 case SkPath::kLine_Verb:

	1097 nextLast = pts[0] - pts[1];

	1098 vector = pts[1] - pts[0];

	1099 break;

	1100 case SkPath::kQuad_Verb: {

	1101 nextLast = pts[1] - pts[2];

	1102 if (SkScalarNearlyZero(nextLast.length())) {

	1103 nextLast = pts[0] - pts[2];

	1104 }

	1105 vector = pts[1] - pts[0];

	1106 if (SkScalarNearlyZero(vector.length())) {

	1107 vector = pts[2] - pts[0];

	1108 }

	1109 if (!fBisectButton.enabled()) {

	1110 break;

	1111 }

	1112 SkScalar t = SkFindQuadMaxCurvature(pts);

	1113 if (0 < t && t < 1) {

	1114 SkPoint maxPt = SkEvalQuadAt(pts, t);

	1115 SkVector tangent = SkEvalQuadTangentAt(pts, t);

	1116 tangent.setLength(fWidthControl.fValLo * 2);

	1117 canvas->drawLine(maxPt.fX, maxPt.fY,

	1118 maxPt.fX + tangent.fY, maxPt.fY - tangent.fX, fS keletonPaint);

	1119 }

	1120 } break;

	1121 case SkPath::kConic_Verb:

	1122 nextLast = pts[1] - pts[2];

	1123 if (SkScalarNearlyZero(nextLast.length())) {

	1124 nextLast = pts[0] - pts[2];

	1125 }

	1126 vector = pts[1] - pts[0];

	1127 if (SkScalarNearlyZero(vector.length())) {

	1128 vector = pts[2] - pts[0];

	1129 }

	1130 if (!fBisectButton.enabled()) {

	1131 break;

	1132 }

	1133 // FIXME : need max curvature or equivalent here

	1134 break;

	1135 case SkPath::kCubic_Verb: {

	1136 nextLast = pts[2] - pts[3];

	1137 if (SkScalarNearlyZero(nextLast.length())) {

	1138 nextLast = pts[1] - pts[3];

	1139 if (SkScalarNearlyZero(nextLast.length())) {

	1140 nextLast = pts[0] - pts[3];

	1141 }

	1142 }

	1143 vector = pts[0] - pts[1];

	1144 if (SkScalarNearlyZero(vector.length())) {

	1145 vector = pts[0] - pts[2];

	1146 if (SkScalarNearlyZero(vector.length())) {

	1147 vector = pts[0] - pts[3];

	1148 }

	1149 }

	1150 if (!fBisectButton.enabled()) {

	1151 break;

	1152 }

	1153 SkScalar tMax[2];

	1154 int tMaxCount = SkFindCubicMaxCurvature(pts, tMax);

	1155 for (int tIndex = 0; tIndex < tMaxCount; ++tIndex) {

	1156 if (0 >= tMax[tIndex] \|\| tMax[tIndex] >= 1) {

	1157 continue;

	1158 }

	1159 SkPoint maxPt;

	1160 SkVector tangent;

	1161 SkEvalCubicAt(pts, tMax[tIndex], &maxPt, &tangent, NULL) ;

	1162 tangent.setLength(fWidthControl.fValLo * 2);

	1163 canvas->drawLine(maxPt.fX, maxPt.fY,

	1164 maxPt.fX + tangent.fY, maxPt.fY - tangent.fX, fS keletonPaint);

	1165 }

	1166 } break;

	1167 case SkPath::kClose_Verb:

	1168 if (foundFirst) {

	1169 draw_bisect(canvas, lastVector, firstVector, firstPt);

	1170 foundFirst = false;

	1171 }

	1172 break;

	1173 default:

	1174 break;

	1175 }

	1176 if (SkPath::kLine_Verb <= verb && verb <= SkPath::kCubic_Verb) {

	1177 if (!foundFirst) {

	1178 firstPt = pts[0];

	1179 firstVector = vector;

	1180 foundFirst = true;

	1181 } else {

	1182 draw_bisect(canvas, lastVector, vector, pts[0]);

	1183 }

	1184 lastVector = nextLast;

	1185 }

	1186 }

	1187 }

	1188

	1189 void draw_legend(SkCanvas* canvas);

	1190

	1191 void draw_segment(SkCanvas* canvas) {

	1192 SkPoint pts[4];

	1193 SkPath::Verb verb;

	1194 SkPath::Iter iter(fPath, true);

	1195 int counter = -1;

	1196 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	1197 if (++counter < fActiveVerb) {

	1198 continue;

	1199 }

	1200 switch (verb) {

	1201 case SkPath::kLine_Verb:

	1202 canvas->drawPoints(SkCanvas::kLines_PointMode, 2, pts, fActi vePaint);

	1203 draw_points(canvas, pts, 2);

	1204 break;

	1205 case SkPath::kQuad_Verb: {

	1206 SkPath qPath;

	1207 qPath.moveTo(pts[0]);

	1208 qPath.quadTo(pts[1], pts[2]);

	1209 canvas->drawPath(qPath, fActivePaint);

	1210 draw_points(canvas, pts, 3);

	1211 } break;

	1212 case SkPath::kConic_Verb: {

	1213 SkPath conicPath;

	1214 conicPath.moveTo(pts[0]);

	1215 conicPath.conicTo(pts[1], pts[2], iter.conicWeight());

	1216 canvas->drawPath(conicPath, fActivePaint);

	1217 draw_points(canvas, pts, 3);

	1218 } break;

	1219 case SkPath::kCubic_Verb: {

	1220 SkScalar loopT;

	1221 bool complex = SkDCubic::ComplexBreak(pts, &loopT);

	1222 SkPath cPath;

	1223 cPath.moveTo(pts[0]);

	1224 cPath.cubicTo(pts[1], pts[2], pts[3]);

	1225 canvas->drawPath(cPath, complex ? fComplexPaint : fActivePai nt);

	1226 draw_points(canvas, pts, 4);

	1227 } break;

	1228 default:

	1229 break;

	1230 }

	1231 return;

	1232 }

	1233 }

	1234

	1235 void draw_points(SkCanvas* canvas, SkPoint* points, int count) {

	1236 for (int index = 0; index < count; ++index) {

	1237 canvas->drawCircle(points[index].fX, points[index].fY, 10, fPointPai nt);

	1238 }

	1239 }

	1240

	1241 int hittest_verb(SkPoint pt, SkPath::Verb* verbPtr, SkScalar* weight) {

	1242 SkIntersections i;

	1243 SkDLine hHit = {{{pt.fX - kHitToleranace, pt.fY }, {pt.fX + kHitTolerana ce, pt.fY}}};

	1244 SkDLine vHit = {{{pt.fX, pt.fY - kHitToleranace }, {pt.fX, pt.fY + kHitT oleranace}}};

	1245 SkPoint pts[4];

	1246 SkPath::Verb verb;

	1247 SkPath::Iter iter(fPath, true);

	1248 int counter = -1;

	1249 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	1250 ++counter;

	1251 switch (verb) {

	1252 case SkPath::kLine_Verb: {

	1253 SkDLine line;

	1254 line.set(pts);

	1255 if (i.intersect(line, hHit) \|\| i.intersect(line, vHit)) {

	1256 *verbPtr = verb;

	1257 *weight = 1;

	1258 return counter;

	1259 }

	1260 } break;

	1261 case SkPath::kQuad_Verb: {

	1262 SkDQuad quad;

	1263 quad.set(pts);

	1264 if (i.intersect(quad, hHit) \|\| i.intersect(quad, vHit)) {

	1265 *verbPtr = verb;

	1266 *weight = 1;

	1267 return counter;

	1268 }

	1269 } break;

	1270 case SkPath::kConic_Verb: {

	1271 SkDConic conic;

	1272 SkScalar w = iter.conicWeight();

	1273 conic.set(pts, w);

	1274 if (i.intersect(conic, hHit) \|\| i.intersect(conic, vHit)) {

	1275 *verbPtr = verb;

	1276 *weight = w;

	1277 return counter;

	1278 }

	1279 } break;

	1280 case SkPath::kCubic_Verb: {

	1281 SkDCubic cubic;

	1282 cubic.set(pts);

	1283 if (i.intersect(cubic, hHit) \|\| i.intersect(cubic, vHit)) {

	1284 *verbPtr = verb;

	1285 *weight = 1;

	1286 return counter;

	1287 }

	1288 } break;

	1289 default:

	1290 break;

	1291 }

	1292 }

	1293 return -1;

	1294 }

	1295

	1296 SkScalar pt_to_line(SkPoint s, SkPoint e, int x, int y) {

	1297 SkScalar radius = fWidthControl.fValLo;

	1298 SkVector adjOpp = e - s;

	1299 SkScalar lenSq = adjOpp.lengthSqd();

	1300 SkPoint rotated = {

	1301 (y - s.fY) * adjOpp.fY + (x - s.fX) * adjOpp.fX,

	1302 (y - s.fY) * adjOpp.fX - (x - s.fX) * adjOpp.fY,

	1303 };

	1304 if (rotated.fX < 0 \|\| rotated.fX > lenSq) {

	1305 return -radius;

	1306 }

	1307 rotated.fY /= SkScalarSqrt(lenSq);

	1308 return SkTMax(-radius, SkTMin(radius, rotated.fY));

	1309 }

	1310

	1311 // given a line, compute the interior and exterior gradient coverage

	1312 bool coverage(SkPoint s, SkPoint e, uint8_t* distanceMap, int w, int h) {

	1313 SkScalar radius = fWidthControl.fValLo;

	1314 int minX = SkTMax(0, (int) (SkTMin(s.fX, e.fX) - radius));

	1315 int minY = SkTMax(0, (int) (SkTMin(s.fY, e.fY) - radius));

	1316 int maxX = SkTMin(w, (int) (SkTMax(s.fX, e.fX) + radius) + 1);

	1317 int maxY = SkTMin(h, (int) (SkTMax(s.fY, e.fY) + radius) + 1);

	1318 for (int y = minY; y < maxY; ++y) {

	1319 for (int x = minX; x < maxX; ++x) {

	1320 SkScalar ptToLineDist = pt_to_line(s, e, x, y);

	1321 if (ptToLineDist > -radius && ptToLineDist < radius) {

	1322 SkScalar coverage = ptToLineDist / radius;

	1323 add_to_map(1 - SkScalarAbs(coverage), x, y, distanceMap, w, h);

	1324 }

	1325 SkVector ptToS = { x - s.fX, y - s.fY };

	1326 SkScalar dist = ptToS.length();

	1327 if (dist < radius) {

	1328 SkScalar coverage = dist / radius;

	1329 add_to_map(1 - SkScalarAbs(coverage), x, y, distanceMap, w, h);

	1330 }

	1331 SkVector ptToE = { x - e.fX, y - e.fY };

	1332 dist = ptToE.length();

	1333 if (dist < radius) {

	1334 SkScalar coverage = dist / radius;

	1335 add_to_map(1 - SkScalarAbs(coverage), x, y, distanceMap, w, h);

	1336 }

	1337 }

	1338 }

	1339 return true;

	1340 }

	1341

	1342 void quad_coverage(SkPoint pts[3], uint8_t* distanceMap, int w, int h) {

	1343 SkScalar dist = pts[0].Distance(pts[0], pts[2]);

	1344 if (dist < gCurveDistance) {

	1345 (void) coverage(pts[0], pts[2], distanceMap, w, h);

	1346 return;

	1347 }

	1348 SkPoint split[5];

	1349 SkChopQuadAt(pts, split, 0.5f);

	1350 quad_coverage(&split[0], distanceMap, w, h);

	1351 quad_coverage(&split[2], distanceMap, w, h);

	1352 }

	1353

	1354 void conic_coverage(SkPoint pts[3], SkScalar weight, uint8_t* distanceMap, i nt w, int h) {

	1355 SkScalar dist = pts[0].Distance(pts[0], pts[2]);

	1356 if (dist < gCurveDistance) {

	1357 (void) coverage(pts[0], pts[2], distanceMap, w, h);

	1358 return;

	1359 }

	1360 SkConic split[2];

	1361 SkConic conic;

	1362 conic.set(pts, weight);

	1363 conic.chopAt(0.5f, split);

	1364 conic_coverage(split[0].fPts, split[0].fW, distanceMap, w, h);

	1365 conic_coverage(split[1].fPts, split[1].fW, distanceMap, w, h);

	1366 }

	1367

	1368 void cubic_coverage(SkPoint pts[4], uint8_t* distanceMap, int w, int h) {

	1369 SkScalar dist = pts[0].Distance(pts[0], pts[3]);

	1370 if (dist < gCurveDistance) {

	1371 (void) coverage(pts[0], pts[3], distanceMap, w, h);

	1372 return;

	1373 }

	1374 SkPoint split[7];

	1375 SkChopCubicAt(pts, split, 0.5f);

	1376 cubic_coverage(&split[0], distanceMap, w, h);

	1377 cubic_coverage(&split[3], distanceMap, w, h);

	1378 }

	1379

	1380 void path_coverage(const SkPath& path, uint8_t* distanceMap, int w, int h) {

	1381 memset(distanceMap, 0, sizeof(distanceMap[0]) * w * h);

	1382 SkPoint pts[4];

	1383 SkPath::Verb verb;

	1384 SkPath::Iter iter(path, true);

	1385 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	1386 switch (verb) {

	1387 case SkPath::kLine_Verb:

	1388 (void) coverage(pts[0], pts[1], distanceMap, w, h);

	1389 break;

	1390 case SkPath::kQuad_Verb:

	1391 quad_coverage(pts, distanceMap, w, h);

	1392 break;

	1393 case SkPath::kConic_Verb:

	1394 conic_coverage(pts, iter.conicWeight(), distanceMap, w, h);

	1395 break;

	1396 case SkPath::kCubic_Verb:

	1397 cubic_coverage(pts, distanceMap, w, h);

	1398 break;

	1399 default:

	1400 break;

	1401 }

	1402 }

	1403 }

	1404

	1405 static uint8_t* set_up_dist_map(const SkImageInfo& imageInfo, SkBitmap* dist Map) {

	1406 distMap->setInfo(imageInfo);

	1407 distMap->setIsVolatile(true);

	1408 SkAssertResult(distMap->tryAllocPixels());

	1409 SkASSERT((int) distMap->rowBytes() == imageInfo.width());

	1410 return distMap->getAddr8(0, 0);

	1411 }

	1412

	1413 void path_stroke(int index, SkPath* inner, SkPath* outer) {

	1414 #if 0

	1415 SkPathStroker stroker(fPath, fWidthControl.fValLo, 0,

	1416 SkPaint::kRound_Cap, SkPaint::kRound_Join, fResControl.fValLo);

	1417 SkPoint pts[4], firstPt, lastPt;

	1418 SkPath::Verb verb;

	1419 SkPath::Iter iter(fPath, true);

	1420 int counter = -1;

	1421 while ((verb = iter.next(pts)) != SkPath::kDone_Verb) {

	1422 ++counter;

	1423 switch (verb) {

	1424 case SkPath::kMove_Verb:

	1425 firstPt = pts[0];

	1426 break;

	1427 case SkPath::kLine_Verb:

	1428 if (counter == index) {

	1429 stroker.moveTo(pts[0]);

	1430 stroker.lineTo(pts[1]);

	1431 goto done;

	1432 }

	1433 lastPt = pts[1];

	1434 break;

	1435 case SkPath::kQuad_Verb:

	1436 if (counter == index) {

	1437 stroker.moveTo(pts[0]);

	1438 stroker.quadTo(pts[1], pts[2]);

	1439 goto done;

	1440 }

	1441 lastPt = pts[2];

	1442 break;

	1443 case SkPath::kConic_Verb:

	1444 if (counter == index) {

	1445 stroker.moveTo(pts[0]);

	1446 stroker.conicTo(pts[1], pts[2], iter.conicWeight());

	1447 goto done;

	1448 }

	1449 lastPt = pts[2];

	1450 break;

	1451 case SkPath::kCubic_Verb:

	1452 if (counter == index) {

	1453 stroker.moveTo(pts[0]);

	1454 stroker.cubicTo(pts[1], pts[2], pts[3]);

	1455 goto done;

	1456 }

	1457 lastPt = pts[3];

	1458 break;

	1459 case SkPath::kClose_Verb:

	1460 if (counter == index) {

	1461 stroker.moveTo(lastPt);

	1462 stroker.lineTo(firstPt);

	1463 goto done;

	1464 }

	1465 break;

	1466 case SkPath::kDone_Verb:

	1467 break;

	1468 default:

	1469 SkASSERT(0);

	1470 }

	1471 }

	1472 done:

	1473 *inner = stroker.fInner;

	1474 *outer = stroker.fOuter;

	1475 #endif

	1476 }

	1477

	1478 void draw_stroke(SkCanvas* canvas, int active) {

	1479 SkPath inner, outer;

	1480 path_stroke(active, &inner, &outer);

	1481 canvas->drawPath(inner, fSkeletonPaint);

	1482 canvas->drawPath(outer, fSkeletonPaint);

	1483 }

	1484

	1485 void gather_strokes() {

	1486 fStrokes.reset();

	1487 for (int index = 0; index < fPath.countVerbs(); ++index) {

	1488 Stroke& inner = fStrokes.push_back();

	1489 inner.reset();

	1490 inner.fInner = true;

	1491 Stroke& outer = fStrokes.push_back();

	1492 outer.reset();

	1493 outer.fInner = false;

	1494 path_stroke(index, &inner.fPath, &outer.fPath);

	1495 }

	1496 }

	1497

	1498 void trim_strokes() {

	1499 // eliminate self-itersecting loops

	1500 // trim outside edges

	1501 gather_strokes();

	1502 for (int index = 0; index < fStrokes.count(); ++index) {

	1503 SkPath& outPath = fStrokes[index].fPath;

	1504 for (int inner = 0; inner < fStrokes.count(); ++inner) {

	1505 if (index == inner) {

	1506 continue;

	1507 }

	1508 SkPath& inPath = fStrokes[inner].fPath;

	1509 if (!outPath.getBounds().intersects(inPath.getBounds())) {

	1510 continue;

	1511 }

	1512

	1513 }

	1514 }

	1515 }

	1516

	1517 void onDrawContent(SkCanvas* canvas) override {

	1518 #if 0

	1519 SkDEBUGCODE(SkDebugStrokeGlobals debugGlobals);

	1520 SkOpAA aaResult(fPath, fWidthControl.fValLo, fResControl.fValLo

	1521 SkDEBUGPARAMS(&debugGlobals));

	1522 #endif

	1523 SkPath strokePath;

	1524 // aaResult.simplify(&strokePath);

	1525 canvas->drawPath(strokePath, fSkeletonPaint);

	1526 SkRect bounds = fPath.getBounds();

	1527 SkScalar radius = fWidthControl.fValLo;

	1528 int w = (int) (bounds.fRight + radius + 1);

	1529 int h = (int) (bounds.fBottom + radius + 1);

	1530 SkImageInfo imageInfo = SkImageInfo::MakeA8(w, h);

	1531 SkBitmap distMap;

	1532 uint8_t* distanceMap = set_up_dist_map(imageInfo, &distMap);

	1533 path_coverage(fPath, distanceMap, w, h);

	1534 if (fFillButton.enabled()) {

	1535 canvas->drawPath(fPath, fCoveragePaint);

	1536 }

	1537 if (fFilterButton.fState == 2

	1538 && (0 < fFilterControl.fValLo \|\| fFilterControl.fValHi < 255)) {

	1539 SkBitmap filteredMap;

	1540 uint8_t* filtered = set_up_dist_map(imageInfo, &filteredMap);

	1541 filter_coverage(distanceMap, sizeof(uint8_t) * w * h, (uint8_t) fFil terControl.fValLo,

	1542 (uint8_t) fFilterControl.fValHi, filtered);

	1543 canvas->drawBitmap(filteredMap, 0, 0, &fCoveragePaint);

	1544 } else if (fFilterButton.enabled()) {

	1545 canvas->drawBitmap(distMap, 0, 0, &fCoveragePaint);

	1546 }

	1547 if (fSkeletonButton.enabled()) {

	1548 canvas->drawPath(fPath, fActiveVerb >= 0 ? fLightSkeletonPaint : fSk eletonPaint);

	1549 }

	1550 if (fActiveVerb >= 0) {

	1551 draw_segment(canvas);

	1552 }

	1553 if (fBisectButton.enabled() \|\| fJoinButton.enabled()) {

	1554 draw_bisects(canvas, fActiveVerb >= 0);

	1555 }

	1556 if (fInOutButton.enabled()) {

	1557 if (fActiveVerb >= 0) {

	1558 draw_stroke(canvas, fActiveVerb);

	1559 } else {

	1560 for (int index = 0; index < fPath.countVerbs(); ++index) {

	1561 draw_stroke(canvas, index);

	1562 }

	1563 }

	1564 }

	1565 if (fHideAll) {

	1566 return;

	1567 }

	1568 for (int index = 0; index < kControlCount; ++index) {

	1569 kControlList[index].fControl->draw(canvas, fControlPaints);

	1570 }

	1571 for (int index = 0; index < kButtonCount; ++index) {

	1572 kButtonList[index].fButton->draw(canvas, fButtonPaints);

	1573 }

	1574 if (fShowLegend) {

	1575 draw_legend(canvas);

	1576 }

	1577

	1578 #if 0

	1579 SkPaint paint;

	1580 paint.setARGB(255, 34, 31, 31);

	1581 paint.setAntiAlias(true);

	1582

	1583 SkPath path;

	1584 path.moveTo(18,439);

	1585 path.lineTo(414,439);

	1586 path.lineTo(414,702);

	1587 path.lineTo(18,702);

	1588 path.lineTo(18,439);

	1589

	1590 path.moveTo(19,701);

	1591 path.lineTo(413,701);

	1592 path.lineTo(413,440);

	1593 path.lineTo(19,440);

	1594 path.lineTo(19,701);

	1595 path.close();

	1596 canvas->drawPath(path, paint);

	1597

	1598 canvas->scale(1.0f, -1.0f);

	1599 canvas->translate(0.0f, -800.0f);

	1600 canvas->drawPath(path, paint);

	1601 #endif

	1602

	1603 }

	1604

	1605 int hittest_pt(SkPoint pt) {

	1606 for (int index = 0; index < fPath.countPoints(); ++index) {

	1607 if (SkPoint::Distance(fPath.getPoint(index), pt) <= kHitToleranace * 2) {

	1608 return index;

	1609 }

	1610 }

	1611 return -1;

	1612 }

	1613

	1614 virtual SkView::Click* onFindClickHandler(SkScalar x, SkScalar y, unsigned m odi) override {

	1615 SkPoint pt = {x, y};

	1616 int ptHit = hittest_pt(pt);

	1617 if (ptHit >= 0) {

	1618 return new MyClick(this, MyClick::kPtType, ptHit);

	1619 }

	1620 SkPath::Verb verb;

	1621 SkScalar weight;

	1622 int verbHit = hittest_verb(pt, &verb, &weight);

	1623 if (verbHit >= 0) {

	1624 return new MyClick(this, MyClick::kVerbType, verbHit, verb, weight);

	1625 }

	1626 if (!fHideAll) {

	1627 const SkRect& rectPt = SkRect::MakeXYWH(x, y, 1, 1);

	1628 for (int index = 0; index < kControlCount; ++index) {

	1629 if (kControlList[index].fControl->contains(rectPt)) {

	1630 return new MyClick(this, MyClick::kControlType,

	1631 kControlList[index].fControlType);

	1632 }

	1633 }

	1634 for (int index = 0; index < kButtonCount; ++index) {

	1635 if (kButtonList[index].fButton->contains(rectPt)) {

	1636 return new MyClick(this, MyClick::kControlType, kButtonList[ index].fButtonType);

	1637 }

	1638 }

	1639 }

	1640 fLineButton.fVisible = fQuadButton.fVisible = fConicButton.fVisible

	1641 = fCubicButton.fVisible = fWeightControl.fVisible = fAddButton.f Visible

	1642 = fDeleteButton.fVisible = false;

	1643 fActiveVerb = -1;

	1644 fActivePt = -1;

	1645 if (fHandlePathMove) {

	1646 return new MyClick(this, MyClick::kPathType, MyClick::kPathMove);

	1647 }

	1648 return this->INHERITED::onFindClickHandler(x, y, modi);

	1649 }

	1650

	1651 static SkScalar MapScreenYtoValue(int y, const UniControl& control) {

	1652 return SkTMin(1.f, SkTMax(0.f,

	1653 SkIntToScalar(y) - control.fBounds.fTop) / control.fBounds.heigh t())

	1654 * (control.fMax - control.fMin) + control.fMin;

	1655 }

	1656

	1657 bool onClick(Click* click) override {

	1658 MyClick* myClick = (MyClick*) click;

	1659 switch (myClick->fType) {

	1660 case MyClick::kPtType: {

	1661 savePath(click->fState);

	1662 fActivePt = myClick->ptHit();

	1663 SkPoint pt = fPath.getPoint((int) myClick->fControl);

	1664 pt.offset(SkIntToScalar(click->fICurr.fX - click->fIPrev.fX),

	1665 SkIntToScalar(click->fICurr.fY - click->fIPrev.fY));

	1666 set_path_pt(fActivePt, pt, &fPath);

	1667 validatePath();

	1668 this->inval(NULL);

	1669 return true;

	1670 }

	1671 case MyClick::kPathType:

	1672 savePath(click->fState);

	1673 fPath.offset(SkIntToScalar(click->fICurr.fX - click->fIPrev.fX),

	1674 SkIntToScalar(click->fICurr.fY - click->fIPrev.fY));

	1675 validatePath();

	1676 this->inval(NULL);

	1677 return true;

	1678 case MyClick::kVerbType: {

	1679 fActiveVerb = myClick->verbHit();

	1680 fLineButton.fVisible = fQuadButton.fVisible = fConicButton.fVisi ble

	1681 = fCubicButton.fVisible = fAddButton.fVisible = fDeleteB utton.fVisible

	1682 = true;

	1683 fLineButton.setEnabled(myClick->fVerb == SkPath::kLine_Verb);

	1684 fQuadButton.setEnabled(myClick->fVerb == SkPath::kQuad_Verb);

	1685 fConicButton.setEnabled(myClick->fVerb == SkPath::kConic_Verb);

	1686 fCubicButton.setEnabled(myClick->fVerb == SkPath::kCubic_Verb);

	1687 fWeightControl.fValLo = myClick->fWeight;

	1688 fWeightControl.fVisible = myClick->fVerb == SkPath::kConic_Verb;

	1689 } break;

	1690 case MyClick::kControlType: {

	1691 if (click->fState != Click::kDown_State && myClick->isButton()) {

	1692 return true;

	1693 }

	1694 switch (myClick->fControl) {

	1695 case MyClick::kFilterControl: {

	1696 SkScalar val = MapScreenYtoValue(click->fICurr.fY, fFilt erControl);

	1697 if (val - fFilterControl.fValLo < fFilterControl.fValHi - val) {

	1698 fFilterControl.fValLo = SkTMax(0.f, val);

	1699 } else {

	1700 fFilterControl.fValHi = SkTMin(255.f, val);

	1701 }

	1702 } break;

	1703 case MyClick::kResControl:

	1704 fResControl.fValLo = MapScreenYtoValue(click->fICurr.fY, fResControl);

	1705 break;

	1706 case MyClick::kWeightControl: {

	1707 savePath(click->fState);

	1708 SkScalar w = MapScreenYtoValue(click->fICurr.fY, fWeight Control);

	1709 set_path_weight(fActiveVerb, w, &fPath);

	1710 validatePath();

	1711 fWeightControl.fValLo = w;

	1712 } break;

	1713 case MyClick::kWidthControl:

	1714 fWidthControl.fValLo = MapScreenYtoValue(click->fICurr.f Y, fWidthControl);

	1715 break;

	1716 case MyClick::kLineButton:

	1717 savePath(click->fState);

	1718 enable_verb_button(myClick->fControl);

	1719 fWeightControl.fVisible = false;

	1720 set_path_verb(fActiveVerb, SkPath::kLine_Verb, &fPath, 1 );

	1721 validatePath();

	1722 break;

	1723 case MyClick::kQuadButton:

	1724 savePath(click->fState);

	1725 enable_verb_button(myClick->fControl);

	1726 fWeightControl.fVisible = false;

	1727 set_path_verb(fActiveVerb, SkPath::kQuad_Verb, &fPath, 1 );

	1728 validatePath();

	1729 break;

	1730 case MyClick::kConicButton: {

	1731 savePath(click->fState);

	1732 enable_verb_button(myClick->fControl);

	1733 fWeightControl.fVisible = true;

	1734 const SkScalar defaultConicWeight = 1.f / SkScalarSqrt(2 );

	1735 set_path_verb(fActiveVerb, SkPath::kConic_Verb, &fPath, defaultConicWeight);

	1736 validatePath();

	1737 fWeightControl.fValLo = get_path_weight(fActiveVerb, fPa th);

	1738 } break;

	1739 case MyClick::kCubicButton:

	1740 savePath(click->fState);

	1741 enable_verb_button(myClick->fControl);

	1742 fWeightControl.fVisible = false;

	1743 set_path_verb(fActiveVerb, SkPath::kCubic_Verb, &fPath, 1);

	1744 validatePath();

	1745 break;

	1746 case MyClick::kAddButton:

	1747 savePath(click->fState);

	1748 add_path_segment(fActiveVerb, &fPath);

	1749 validatePath();

	1750 if (fWeightControl.fVisible) {

	1751 fWeightControl.fValLo = get_path_weight(fActiveVerb, fPath);

	1752 }

	1753 break;

	1754 case MyClick::kDeleteButton:

	1755 savePath(click->fState);

	1756 delete_path_segment(fActiveVerb, &fPath);

	1757 validatePath();

	1758 break;

	1759 case MyClick::kFillButton:

	1760 fFillButton.toggle();

	1761 break;

	1762 case MyClick::kSkeletonButton:

	1763 fSkeletonButton.toggle();

	1764 break;

	1765 case MyClick::kFilterButton:

	1766 fFilterButton.toggle();

	1767 fFilterControl.fVisible = fFilterButton.fState == 2;

	1768 break;

	1769 case MyClick::kBisectButton:

	1770 fBisectButton.toggle();

	1771 break;

	1772 case MyClick::kJoinButton:

	1773 fJoinButton.toggle();

	1774 break;

	1775 case MyClick::kInOutButton:

	1776 fInOutButton.toggle();

	1777 break;

	1778 default:

	1779 SkASSERT(0);

	1780 break;

	1781 }

	1782 } break;

	1783 default:

	1784 SkASSERT(0);

	1785 break;

	1786 }

	1787 setControlButtonsPos();

	1788 this->inval(NULL);

	1789 return true;

	1790 }

	1791

	1792 private:

	1793 typedef SampleView INHERITED;

	1794 };

	1795

	1796 static struct KeyCommand {

	1797 char fKey;

	1798 char fAlternate;

	1799 const char* fDescriptionL;

	1800 const char* fDescriptionR;

	1801 bool (AAGeometryView::*fFunction)();

	1802 } kKeyCommandList[] = {

	1803 { ' ', 0, "space", "center path", &AAGeometryView::scaleToFit },

	1804 { '-', 0, "-", "zoom out", &AAGeometryView::scaleDown },

	1805 { '+', '=', "+/=", "zoom in", &AAGeometryView::scaleUp },

	1806 { 'd', 0, "d", "dump to console", &AAGeometryView::pathDump },

	1807 { 'h', 0, "h", "hide controls", &AAGeometryView::hideAll },

	1808 { 'r', 0, "r", "reset path", &AAGeometryView::constructPath },

	1809 { 'z', 0, "z", "undo", &AAGeometryView::undo },

	1810 { '?', 0, "?", "show legend", &AAGeometryView::showLegend },

	1811 };

	1812

	1813 const int kKeyCommandCount = (int) SK_ARRAY_COUNT(kKeyCommandList);

	1814

	1815 void AAGeometryView::draw_legend(SkCanvas* canvas) {

	1816 SkScalar bottomOffset = this->height() - 10;

	1817 for (int index = kKeyCommandCount - 1; index >= 0; --index) {

	1818 bottomOffset -= 15;

	1819 canvas->drawText(kKeyCommandList[index].fDescriptionL,

	1820 strlen(kKeyCommandList[index].fDescriptionL), this->width() - 16 0, bottomOffset,

	1821 fLegendLeftPaint);

	1822 canvas->drawText(kKeyCommandList[index].fDescriptionR,

	1823 strlen(kKeyCommandList[index].fDescriptionR), this->width() - 20 , bottomOffset,

	1824 fLegendRightPaint);

	1825 }

	1826 }

	1827

	1828 // overrides from SkEventSink

	1829 bool AAGeometryView::onQuery(SkEvent* evt) {

	1830 if (SampleCode::TitleQ(*evt)) {

	1831 SampleCode::TitleR(evt, "AAGeometry");

	1832 return true;

	1833 }

	1834 SkUnichar uni;

	1835 if (false) {

	1836 return this->INHERITED::onQuery(evt);

	1837 }

	1838 if (SampleCode::CharQ(*evt, &uni)) {

	1839 for (int index = 0; index < kButtonCount; ++index) {

	1840 Button* button = kButtonList[index].fButton;

	1841 if (button->fVisible && uni == button->fLabel) {

	1842 MyClick click(this, MyClick::kControlType, kButtonList[index].fB uttonType);

	1843 click.fState = Click::kDown_State;

	1844 (void) this->onClick(&click);

	1845 return true;

	1846 }

	1847 }

	1848 for (int index = 0; index < kKeyCommandCount; ++index) {

	1849 KeyCommand& keyCommand = kKeyCommandList[index];

	1850 if (uni == keyCommand.fKey \|\| uni == keyCommand.fAlternate) {

	1851 return (this->*keyCommand.fFunction)();

	1852 }

	1853 }

	1854 if (('A' <= uni && uni <= 'Z') \|\| ('a' <= uni && uni <= 'z')) {

	1855 for (int index = 0; index < kButtonCount; ++index) {

	1856 Button* button = kButtonList[index].fButton;

	1857 if (button->fVisible && (uni & ~0x20) == (button->fLabel & ~0x20 )) {

	1858 MyClick click(this, MyClick::kControlType, kButtonList[index ].fButtonType);

	1859 click.fState = Click::kDown_State;

	1860 (void) this->onClick(&click);

	1861 return true;

	1862 }

	1863 }

	1864 }

	1865 }

	1866 return this->INHERITED::onQuery(evt);

	1867 }

	1868

	1869 DEF_SAMPLE( return new AAGeometryView; )

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