tests/PathOpsAngleTest.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "PathOpsTestCommon.h"
 #include "SkIntersections.h"
 #include "SkOpContour.h"
 #include "SkOpSegment.h"
 #include "SkRandom.h"
 #include "SkTSort.h"
 #include "Test.h"

 static bool gDisableAngleTests = true;

 static float next(float f)
 {
     int fBits = SkFloatAs2sCompliment(f);
     ++fBits;
     float fNext = Sk2sComplimentAsFloat(fBits);
     return fNext;
 }

 static float prev(float f)
 {
     int fBits = SkFloatAs2sCompliment(f);
     --fBits;
     float fNext = Sk2sComplimentAsFloat(fBits);
     return fNext;
 }

 DEF_TEST(PathOpsAngleFindCrossEpsilon, reporter) {
     if (gDisableAngleTests) {
         return;
     }
     SkRandom ran;
     int maxEpsilon = 0;
     for (int index = 0; index < 10000000; ++index) {
         SkDLine line = {{{0, 0}, {ran.nextRangeF(0.0001f, 1000), ran.nextRangeF(0.0001f, 1000)}}};
         for (int inner = 0; inner < 10; ++inner) {
             float t = ran.nextRangeF(0.0001f, 1);
             SkDPoint dPt = line.ptAtT(t);
             SkPoint pt = dPt.asSkPoint();
             float xs[3] = { prev(pt.fX), pt.fX, next(pt.fX) };
             float ys[3] = { prev(pt.fY), pt.fY, next(pt.fY) };
             for (int xIdx = 0; xIdx < 3; ++xIdx) {
                 for (int yIdx = 0; yIdx < 3; ++yIdx) {
                     SkPoint test = { xs[xIdx], ys[yIdx] };
                     float p1 = SkDoubleToScalar(line[1].fX * test.fY);
                     float p2 = SkDoubleToScalar(line[1].fY * test.fX);
                     int p1Bits = SkFloatAs2sCompliment(p1);
                     int p2Bits = SkFloatAs2sCompliment(p2);
                     int epsilon = SkTAbs(p1Bits - p2Bits);
                     if (maxEpsilon < epsilon) {
                         SkDebugf("line={{0, 0}, {%1.7g, %1.7g}} t=%1.7g pt={%1.7g, %1.7g}"
                             " epsilon=%d\n",
                             line[1].fX, line[1].fY, t, test.fX, test.fY, epsilon);
                         maxEpsilon = epsilon;
                     }
                 }
             }
         }
     }
 }

 DEF_TEST(PathOpsAngleFindQuadEpsilon, reporter) {
     if (gDisableAngleTests) {
         return;
     }
     SkRandom ran;
     int maxEpsilon = 0;
     double maxAngle = 0;
     for (int index = 0; index < 100000; ++index) {
         SkDLine line = {{{0, 0}, {ran.nextRangeF(0.0001f, 1000), ran.nextRangeF(0.0001f, 1000)}}};
         float t = ran.nextRangeF(0.0001f, 1);
         SkDPoint dPt = line.ptAtT(t);
         float t2 = ran.nextRangeF(0.0001f, 1);
         SkDPoint qPt = line.ptAtT(t2);
         float t3 = ran.nextRangeF(0.0001f, 1);
         SkDPoint qPt2 = line.ptAtT(t3);
         qPt.fX += qPt2.fY;
         qPt.fY -= qPt2.fX;
         QuadPts q = {{line[0], dPt, qPt}};
         SkDQuad quad;
         quad.debugSet(q.fPts);
         // binary search for maximum movement of quad[1] towards test that still has 1 intersection
         double moveT = 0.5f;
         double deltaT = moveT / 2;
         SkDPoint last;
         do {
             last = quad[1];
             quad[1].fX = dPt.fX - line[1].fY * moveT;
             quad[1].fY = dPt.fY + line[1].fX * moveT;
             SkIntersections i;
             i.intersect(quad, line);
             REPORTER_ASSERT(reporter, i.used() > 0);
             if (i.used() == 1) {
                 moveT += deltaT;
             } else {
                 moveT -= deltaT;
             }
             deltaT /= 2;
         } while (last.asSkPoint() != quad[1].asSkPoint());
         float p1 = SkDoubleToScalar(line[1].fX * last.fY);
         float p2 = SkDoubleToScalar(line[1].fY * last.fX);
         int p1Bits = SkFloatAs2sCompliment(p1);
         int p2Bits = SkFloatAs2sCompliment(p2);
         int epsilon = SkTAbs(p1Bits - p2Bits);
         if (maxEpsilon < epsilon) {
             SkDebugf("line={{0, 0}, {%1.7g, %1.7g}} t=%1.7g/%1.7g/%1.7g moveT=%1.7g"
                     " pt={%1.7g, %1.7g} epsilon=%d\n",
                     line[1].fX, line[1].fY, t, t2, t3, moveT, last.fX, last.fY, epsilon);
             maxEpsilon = epsilon;
         }
         double a1 = atan2(line[1].fY, line[1].fX);
         double a2 = atan2(last.fY, last.fX);
         double angle = fabs(a1 - a2);
         if (maxAngle < angle) {
             SkDebugf("line={{0, 0}, {%1.7g, %1.7g}} t=%1.7g/%1.7g/%1.7g moveT=%1.7g"
                     " pt={%1.7g, %1.7g} angle=%1.7g\n",
                     line[1].fX, line[1].fY, t, t2, t3, moveT, last.fX, last.fY, angle);
             maxAngle = angle;
         }
     }
 }

 static int find_slop(double x, double y, double rx, double ry) {
     int slopBits = 0;
     bool less1, less2;
     double absX = fabs(x);
     double absY = fabs(y);
     double length = absX < absY ? absX / 2 + absY : absX + absY / 2;
     int exponent;
     (void) frexp(length, &exponent);
     double epsilon = ldexp(FLT_EPSILON, exponent);
     do {
         // get the length as the larger plus half the smaller (both same signs)
         // find the ulps of the length
         // compute the offsets from there
         double xSlop = epsilon * slopBits;
         double ySlop = x * y < 0 ? -xSlop : xSlop; // OPTIMIZATION: use copysign / _copysign ?
         double x1 = x - xSlop;
         double y1 = y + ySlop;
         double x_ry1 = x1 * ry;
         double rx_y1 = rx * y1;
         less1 = x_ry1 < rx_y1;
         double x2 = x + xSlop;
         double y2 = y - ySlop;
         double x_ry2 = x2 * ry;
         double rx_y2 = rx * y2;
         less2 = x_ry2 < rx_y2;
     } while (less1 == less2 && ++slopBits);
     return slopBits;
 }

 // from http://stackoverflow.com/questions/1427422/cheap-algorithm-to-find-measure-of-angle-between-vectors
 static double diamond_angle(double y, double x)
 {
     if (y >= 0)
         return (x >= 0 ? y/(x+y) : 1-x/(-x+y));
     else
         return (x < 0 ? 2-y/(-x-y) : 3+x/(x-y));
 }

 static const double slopTests[][4] = {
    // x                      y                       rx                      ry
     {-0.058554756452593892, -0.18804585843827226, -0.018568569646021160, -0.059615294434479438},
     {-0.0013717412948608398, 0.0041152238845825195, -0.00045837944195925573, 0.0013753175735478074},
     {-2.1033774145221198, -1.4046019261273715e-008, -0.70062688352066704, -1.2706324683777995e-008},
 };

 DEF_TEST(PathOpsAngleFindSlop, reporter) {
     if (gDisableAngleTests) {
         return;
     }
     for (int index = 0; index < (int) SK_ARRAY_COUNT(slopTests); ++index) {
         const double* slopTest = slopTests[index];
         double x = slopTest[0];
         double y = slopTest[1];
         double rx = slopTest[2];
         double ry = slopTest[3];
         SkDebugf("%s  xy %d=%d\n", __FUNCTION__, index, find_slop(x, y, rx, ry));
         SkDebugf("%s rxy %d=%d\n", __FUNCTION__, index, find_slop(rx, ry, x, y));
         double angle = diamond_angle(y, x);
         double rAngle = diamond_angle(ry, rx);
         double diff = fabs(angle - rAngle);
         SkDebugf("%s diamond xy=%1.9g rxy=%1.9g diff=%1.9g factor=%d\n", __FUNCTION__,
                 angle, rAngle, diff, (int) (diff / FLT_EPSILON));
     }
 }

 class PathOpsAngleTester {
 public:
     static int After(SkOpAngle& lh, SkOpAngle& rh) {
         return lh.after(&rh);
     }

     static int AllOnOneSide(SkOpAngle& lh, SkOpAngle& rh) {
         return lh.allOnOneSide(&rh);
     }

     static int ConvexHullOverlaps(SkOpAngle& lh, SkOpAngle& rh) {
         return lh.convexHullOverlaps(&rh);
     }

     static int Orderable(SkOpAngle& lh, SkOpAngle& rh) {
         return lh.orderable(&rh);
     }

     static int EndsIntersect(SkOpAngle& lh, SkOpAngle& rh) {
         return lh.endsIntersect(&rh);
     }

     static void SetNext(SkOpAngle& lh, SkOpAngle& rh) {
         lh.fNext = &rh;
     }
 };

 class PathOpsSegmentTester {
 public:
     static void DebugReset(SkOpSegment* segment) {
         segment->debugReset();
     }
 };

 struct CircleData {
     const CubicPts fPts;
     const int fPtCount;
     SkPoint fShortPts[4];
 };

 static CircleData circleDataSet[] = {
     { {{{313.0155029296875, 207.90290832519531}, {320.05078125, 227.58743286132812}}}, 2, {} },
     { {{{313.0155029296875, 207.90290832519531}, {313.98246891063195, 219.33615203830394},
             {320.05078125, 227.58743286132812}}}, 3, {} },
 };

 static const int circleDataSetSize = (int) SK_ARRAY_COUNT(circleDataSet);

 DEF_TEST(PathOpsAngleCircle, reporter) {
     SkChunkAlloc allocator(4096);
     SkOpContourHead contour;
     SkOpGlobalState state(&contour, &allocator  SkDEBUGPARAMS(false) SkDEBUGPARAMS(nullptr));
     contour.init(&state, false, false);
     for (int index = 0; index < circleDataSetSize; ++index) {
         CircleData& data = circleDataSet[index];
         for (int idx2 = 0; idx2 < data.fPtCount; ++idx2) {
             data.fShortPts[idx2] = data.fPts.fPts[idx2].asSkPoint();
         }
         switch (data.fPtCount) {
             case 2:
                 contour.addLine(data.fShortPts);
                 break;
             case 3:
                 contour.addQuad(data.fShortPts);
                 break;
             case 4:
                 contour.addCubic(data.fShortPts);
                 break;
         }
     }
     SkOpSegment* first = contour.first();
     first->debugAddAngle(0, 1);
     SkOpSegment* next = first->next();
     next->debugAddAngle(0, 1);
     PathOpsAngleTester::Orderable(*first->debugLastAngle(), *next->debugLastAngle());
 }

 struct IntersectData {
     const CubicPts fPts;
     const int fPtCount;
     double fTStart;
     double fTEnd;
     SkPoint fShortPts[4];
 };

 static IntersectData intersectDataSet1[] = {
     { {{{322.935669,231.030273}, {312.832214,220.393295}, {312.832214,203.454178}}}, 3,
             0.865309956, 0.154740299, {} },
     { {{{322.12738,233.397751}, {295.718353,159.505829}}}, 2,
             0.345028807, 0.0786326511, {} },
     { {{{322.935669,231.030273}, {312.832214,220.393295}, {312.832214,203.454178}}}, 3,
             0.865309956, 1, {} },
     { {{{322.12738,233.397751}, {295.718353,159.505829}}}, 2,
             0.345028807, 1, {} },
 };

 static IntersectData intersectDataSet2[] = {
     { {{{364.390686,157.898193}, {375.281769,136.674606}, {396.039917,136.674606}}}, 3,
             0.578520747, 1, {} },
     { {{{364.390686,157.898193}, {375.281769,136.674606}, {396.039917,136.674606}}}, 3,
             0.578520747, 0.536512973, {} },
     { {{{366.608826,151.196014}, {378.803101,136.674606}, {398.164948,136.674606}}}, 3,
             0.490456543, 1, {} },
 };

 static IntersectData intersectDataSet3[] = {
     { {{{2.000000,0.000000}, {1.33333333,0.66666667}}}, 2, 1, 0, {} },
     { {{{1.33333333,0.66666667}, {0.000000,2.000000}}}, 2, 0, 0.25, {} },
     { {{{2.000000,2.000000}, {1.33333333,0.66666667}}}, 2, 1, 0, {} },
 };

 static IntersectData intersectDataSet4[] = {
     { {{{1.3333333,0.6666667}, {0.000,2.000}}}, 2, 0.250000006, 0, {} },
     { {{{1.000,0.000}, {1.000,1.000}}}, 2, 1, 0, {} },
     { {{{1.000,1.000}, {0.000,0.000}}}, 2, 0, 1, {} },
 };

 static IntersectData intersectDataSet5[] = {
     { {{{0.000,0.000}, {1.000,0.000}, {1.000,1.000}}}, 3, 1, 0.666666667, {} },
     { {{{0.000,0.000}, {2.000,1.000}, {0.000,2.000}}}, 3, 0.5, 1, {} },
     { {{{0.000,0.000}, {2.000,1.000}, {0.000,2.000}}}, 3, 0.5, 0, {} },
 };

 static IntersectData intersectDataSet6[] = { // pathops_visualizer.htm:3658
     { {{{0.000,1.000}, {3.000,4.000}, {1.000,0.000}, {3.000,0.000}}}, 4, 0.0925339054, 0, {} }, // pathops_visualizer.htm:3616
     { {{{0.000,1.000}, {0.000,3.000}, {1.000,0.000}, {4.000,3.000}}}, 4, 0.453872386, 0, {} }, // pathops_visualizer.htm:3616
     { {{{0.000,1.000}, {3.000,4.000}, {1.000,0.000}, {3.000,0.000}}}, 4, 0.0925339054, 0.417096368, {} }, // pathops_visualizer.htm:3616
 };

 static IntersectData intersectDataSet7[] = { // pathops_visualizer.htm:3748
     { {{{2.000,1.000}, {0.000,1.000}}}, 2, 0.5, 0, {} }, // pathops_visualizer.htm:3706
     { {{{2.000,0.000}, {0.000,2.000}}}, 2, 0.5, 1, {} }, // pathops_visualizer.htm:3706
     { {{{0.000,1.000}, {0.000,2.000}, {2.000,0.000}, {2.000,1.000}}}, 4, 0.5, 1, {} }, // pathops_visualizer.htm:3706
 }; //

 static IntersectData intersectDataSet8[] = { // pathops_visualizer.htm:4194
     { {{{0.000,1.000}, {2.000,3.000}, {5.000,1.000}, {4.000,3.000}}}, 4, 0.311007457, 0.285714286, {} }, // pathops_visualizer.htm:4152
     { {{{1.000,5.000}, {3.000,4.000}, {1.000,0.000}, {3.000,2.000}}}, 4, 0.589885081, 0.999982974, {} }, // pathops_visualizer.htm:4152
     { {{{1.000,5.000}, {3.000,4.000}, {1.000,0.000}, {3.000,2.000}}}, 4, 0.589885081, 0.576935809, {} }, // pathops_visualizer.htm:4152
 }; //

 static IntersectData intersectDataSet9[] = { // pathops_visualizer.htm:4142
     { {{{0.000,1.000}, {2.000,3.000}, {5.000,1.000}, {4.000,3.000}}}, 4, 0.476627072, 0.311007457, {} }, // pathops_visualizer.htm:4100
     { {{{1.000,5.000}, {3.000,4.000}, {1.000,0.000}, {3.000,2.000}}}, 4, 0.999982974, 1, {} }, // pathops_visualizer.htm:4100
     { {{{0.000,1.000}, {2.000,3.000}, {5.000,1.000}, {4.000,3.000}}}, 4, 0.476627072, 1, {} }, // pathops_visualizer.htm:4100
 }; //

 static IntersectData intersectDataSet10[] = { // pathops_visualizer.htm:4186
     { {{{0.000,1.000}, {1.000,6.000}, {1.000,0.000}, {1.000,0.000}}}, 4, 0.788195121, 0.726275769, {} }, // pathops_visualizer.htm:4144
     { {{{0.000,1.000}, {0.000,1.000}, {1.000,0.000}, {6.000,1.000}}}, 4, 0.473378977, 1, {} }, // pathops_visualizer.htm:4144
     { {{{0.000,1.000}, {1.000,6.000}, {1.000,0.000}, {1.000,0.000}}}, 4, 0.788195121, 1, {} }, // pathops_visualizer.htm:4144
 }; //

 static IntersectData intersectDataSet11[] = { // pathops_visualizer.htm:4704
     { {{{979.305,561.000}, {1036.695,291.000}}}, 2, 0.888888874, 0.11111108, {} }, // pathops_visualizer.htm:4662
     { {{{1006.695,291.000}, {1023.264,291.000}, {1033.840,304.431}, {1030.318,321.000}}}, 4, 1, 0, {} }, // pathops_visualizer.htm:4662
     { {{{979.305,561.000}, {1036.695,291.000}}}, 2, 0.888888874, 1, {} }, // pathops_visualizer.htm:4662
 }; //

 static IntersectData intersectDataSet12[] = { // pathops_visualizer.htm:5481
     { {{{67.000,912.000}, {67.000,913.000}}}, 2, 1, 0, {} }, // pathops_visualizer.htm:5439
     { {{{67.000,913.000}, {67.000,917.389}, {67.224,921.726}, {67.662,926.000}}}, 4, 0, 1, {} }, // pathops_visualizer.htm:5439
     { {{{194.000,1041.000}, {123.860,1041.000}, {67.000,983.692}, {67.000,913.000}}}, 4, 1, 0, {} }, // pathops_visualizer.htm:5439
 }; //

 static IntersectData intersectDataSet13[] = { // pathops_visualizer.htm:5735
     { {{{6.000,0.000}, {0.000,4.000}}}, 2, 0.625, 0.25, {} }, // pathops_visualizer.htm:5693
     { {{{0.000,1.000}, {0.000,6.000}, {4.000,0.000}, {6.000,1.000}}}, 4, 0.5, 0.833333333, {} }, // pathops_visualizer.htm:5693
     { {{{0.000,1.000}, {0.000,6.000}, {4.000,0.000}, {6.000,1.000}}}, 4, 0.5, 0.379043969, {} }, // pathops_visualizer.htm:5693
 }; //

 static IntersectData intersectDataSet14[] = { // pathops_visualizer.htm:5875
     { {{{0.000,1.000}, {4.000,6.000}, {2.000,1.000}, {2.000,0.000}}}, 4, 0.0756502183, 0.0594570973, {} }, // pathops_visualizer.htm:5833
     { {{{1.000,2.000}, {0.000,2.000}, {1.000,0.000}, {6.000,4.000}}}, 4, 0.0756502184, 0, {} }, // pathops_visualizer.htm:5833
     { {{{0.000,1.000}, {4.000,6.000}, {2.000,1.000}, {2.000,0.000}}}, 4, 0.0756502183, 0.531917258, {} }, // pathops_visualizer.htm:5833
 }; //

 static IntersectData intersectDataSet15[] = { // pathops_visualizer.htm:6580
     { {{{490.435,879.407}, {405.593,909.436}}}, 2, 0.500554405, 1, {} }, // pathops_visualizer.htm:6538
     { {{{447.967,894.438}, {448.007,894.424}, {448.014,894.422}}}, 3, 0, 1, {} }, // pathops_visualizer.htm:6538
     { {{{490.435,879.407}, {405.593,909.436}}}, 2, 0.500554405, 0.500000273, {} }, // pathops_visualizer.htm:6538
 }; //

 static IntersectData intersectDataSet16[] = { // pathops_visualizer.htm:7419
     { {{{1.000,4.000}, {4.000,5.000}, {3.000,2.000}, {6.000,3.000}}}, 4, 0.5, 0, {} }, // pathops_visualizer.htm:7377
     { {{{2.000,3.000}, {3.000,6.000}, {4.000,1.000}, {5.000,4.000}}}, 4, 0.5, 0.112701665, {} }, // pathops_visualizer.htm:7377
     { {{{5.000,4.000}, {2.000,3.000}}}, 2, 0.5, 0, {} }, // pathops_visualizer.htm:7377
 }; //

 // from skpi_gino_com_16
 static IntersectData intersectDataSet17[] = {
     { /*seg=7*/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
         , 3, 0.74590454, 0.547660352, {} },
     { /*seg=8*/ {{{185, 734}, {252.93103f, 734}, {308, 789.06897f}, {308, 857}}}
         , 4, 0.12052623, 0, {} },
     { /*seg=7*/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
         , 3, 0.74590454, 1, {} },
 };

 static IntersectData intersectDataSet18[] = {
     { /*seg=7*/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
         , 3, 0.74590454, 1, {} },
     { /*seg=8*/ {{{185, 734}, {252.93103f, 734}, {308, 789.06897f}, {308, 857}}}
         , 4, 0.12052623, 0.217351928, {} },
     { /*seg=7*/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
         , 3, 0.74590454, 0.547660352, {} },
 };

 static IntersectData intersectDataSet19[] = {
     { /*seg=1*/ {{{0, 1}, {3, 5}, {2, 1}, {3, 1}}}
         , 4, 0.135148995, 0.134791946, {} },
     { /*seg=3*/ {{{1, 2}, {1, 2.15061641f}, {1, 2.21049166f}, {1.01366711f, 2.21379328f}}}
         , 4, 0.956740456, 0.894913214, {} },
     { /*seg=1*/ {{{0, 1}, {3, 5}, {2, 1}, {3, 1}}}
         , 4, 0.135148995, 0.551812363, {} },
 };

 #define I(x) intersectDataSet##x

 static IntersectData* intersectDataSets[] = {
     I(1), I(2), I(3), I(4), I(5), I(6), I(7), I(8), I(9), I(10),
     I(11), I(12), I(13), I(14), I(15), I(16), I(17), I(18), I(19),
 };

 #undef I
 #define I(x) (int) SK_ARRAY_COUNT(intersectDataSet##x)

 static const int intersectDataSetSizes[] = {
     I(1), I(2), I(3), I(4), I(5), I(6), I(7), I(8), I(9), I(10),
     I(11), I(12), I(13), I(14), I(15), I(16), I(17), I(18), I(19),
 };

 #undef I

 static const int intersectDataSetsSize = (int) SK_ARRAY_COUNT(intersectDataSetSizes);

 struct FourPoints {
     SkPoint pts[4];
 };

 DEF_TEST(PathOpsAngleAfter, reporter) {
     SkChunkAlloc allocator(4096);
     SkOpContourHead contour;
     SkOpGlobalState state(&contour, &allocator  SkDEBUGPARAMS(false) SkDEBUGPARAMS(nullptr));
     contour.init(&state, false, false);
     for (int index = intersectDataSetsSize - 1; index >= 0; --index) {
         IntersectData* dataArray = intersectDataSets[index];
         const int dataSize = intersectDataSetSizes[index];
         for (int index2 = 0; index2 < dataSize - 2; ++index2) {
             allocator.reset();
             contour.reset();
             for (int index3 = 0; index3 < 3; ++index3) {
                 IntersectData& data = dataArray[index2 + index3];
                 SkPoint* temp = (SkPoint*) SkOpTAllocator<FourPoints>::Allocate(&allocator);
                 for (int idx2 = 0; idx2 < data.fPtCount; ++idx2) {
                     temp[idx2] = data.fPts.fPts[idx2].asSkPoint();
                 }
                 switch (data.fPtCount) {
                     case 2: {
                         contour.addLine(temp);
                         } break;
                     case 3: {
                         contour.addQuad(temp);
                         } break;
                     case 4: {
                         contour.addCubic(temp);
                         } break;
                 }
             }
             SkOpSegment* seg1 = contour.first();
             seg1->debugAddAngle(dataArray[index2 + 0].fTStart, dataArray[index2 + 0].fTEnd);
             SkOpSegment* seg2 = seg1->next();
             seg2->debugAddAngle(dataArray[index2 + 1].fTStart, dataArray[index2 + 1].fTEnd);
             SkOpSegment* seg3 = seg2->next();
             seg3->debugAddAngle(dataArray[index2 + 2].fTStart, dataArray[index2 + 2].fTEnd);
             SkOpAngle& angle1 = *seg1->debugLastAngle();
             SkOpAngle& angle2 = *seg2->debugLastAngle();
             SkOpAngle& angle3 = *seg3->debugLastAngle();
             PathOpsAngleTester::SetNext(angle1, angle3);
        // These data sets are seeded when the set itself fails, so likely the dataset does not
        // match the expected result. The tests above return 1 when first added, but
        // return 0 after the bug is fixed.
             SkDEBUGCODE(int result =) PathOpsAngleTester::After(angle2, angle1);
             SkASSERT(result == 0 || result == 1);
         }
     }
 }

 void SkOpSegment::debugAddAngle(double startT, double endT) {
     SkOpPtT* startPtT = startT == 0 ? fHead.ptT() : startT == 1 ? fTail.ptT()
             : this->addT(startT);
     SkOpPtT* endPtT = endT == 0 ? fHead.ptT() : endT == 1 ? fTail.ptT()
             : this->addT(endT);
     SkOpAngle* angle = SkOpTAllocator<SkOpAngle>::Allocate(this->globalState()->allocator());
     SkOpSpanBase* startSpan = &fHead;
     while (startSpan->ptT() != startPtT) {
         startSpan = startSpan->upCast()->next();
     }
     SkOpSpanBase* endSpan = &fHead;
     while (endSpan->ptT() != endPtT) {
         endSpan = endSpan->upCast()->next();
     }
     angle->set(startSpan, endSpan);
     if (startT < endT) {
         startSpan->upCast()->setToAngle(angle);
         endSpan->setFromAngle(angle);
     } else {
         endSpan->upCast()->setToAngle(angle);
         startSpan->setFromAngle(angle);
     }
 }

 DEF_TEST(PathOpsAngleAllOnOneSide, reporter) {
     SkChunkAlloc allocator(4096);
     SkOpContourHead contour;
     SkOpGlobalState state(&contour, &allocator  SkDEBUGPARAMS(false) SkDEBUGPARAMS(nullptr));
     contour.init(&state, false, false);
     SkPoint conicPts[3] = {{494.37100219726562f, 224.66200256347656f},
         {494.37360910682298f, 224.6729026561527f},
         {494.37600708007813f, 224.68400573730469f}};
     SkPoint linePts[2] = {{494.371002f, 224.662003f}, {494.375000f, 224.675995f}};
     for (int i = 10; i >= 0; --i) {
         SkPoint modLinePts[2] = { linePts[0], linePts[1] };
         modLinePts[1].fX += i * .1f;
         contour.addLine(modLinePts);
         contour.addQuad(conicPts);
    //     contour.addConic(conicPts, 0.999935746f, &allocator);
         SkOpSegment* first = contour.first();
         first->debugAddAngle(0, 1);
         SkOpSegment* next = first->next();
         next->debugAddAngle(0, 1);
         /* int result = */
             PathOpsAngleTester::AllOnOneSide(*first->debugLastAngle(), *next->debugLastAngle());
   //      SkDebugf("i=%d result=%d\n", i , result);
   //      SkDebugf("");
     }
 }
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "PathOpsTestCommon.h"
	#include "SkIntersections.h"
	#include "SkOpContour.h"
	#include "SkOpSegment.h"
	#include "SkRandom.h"
	#include "SkTSort.h"
	#include "Test.h"

	static bool gDisableAngleTests = true;

	static float next(float f)
	{
	int fBits = SkFloatAs2sCompliment(f);
	++fBits;
	float fNext = Sk2sComplimentAsFloat(fBits);
	return fNext;
	}

	static float prev(float f)
	{
	int fBits = SkFloatAs2sCompliment(f);
	--fBits;
	float fNext = Sk2sComplimentAsFloat(fBits);
	return fNext;
	}

	DEF_TEST(PathOpsAngleFindCrossEpsilon, reporter) {
	if (gDisableAngleTests) {
	return;
	}
	SkRandom ran;
	int maxEpsilon = 0;
	for (int index = 0; index < 10000000; ++index) {
	SkDLine line = {{{0, 0}, {ran.nextRangeF(0.0001f, 1000), ran.nextRangeF(0.0001f, 1000)}}};
	for (int inner = 0; inner < 10; ++inner) {
	float t = ran.nextRangeF(0.0001f, 1);
	SkDPoint dPt = line.ptAtT(t);
	SkPoint pt = dPt.asSkPoint();
	float xs[3] = { prev(pt.fX), pt.fX, next(pt.fX) };
	float ys[3] = { prev(pt.fY), pt.fY, next(pt.fY) };
	for (int xIdx = 0; xIdx < 3; ++xIdx) {
	for (int yIdx = 0; yIdx < 3; ++yIdx) {
	SkPoint test = { xs[xIdx], ys[yIdx] };
	float p1 = SkDoubleToScalar(line[1].fX * test.fY);
	float p2 = SkDoubleToScalar(line[1].fY * test.fX);
	int p1Bits = SkFloatAs2sCompliment(p1);
	int p2Bits = SkFloatAs2sCompliment(p2);
	int epsilon = SkTAbs(p1Bits - p2Bits);
	if (maxEpsilon < epsilon) {
	SkDebugf("line={{0, 0}, {%1.7g, %1.7g}} t=%1.7g pt={%1.7g, %1.7g}"
	" epsilon=%d\n",
	line[1].fX, line[1].fY, t, test.fX, test.fY, epsilon);
	maxEpsilon = epsilon;
	}
	}
	}
	}
	}
	}

	DEF_TEST(PathOpsAngleFindQuadEpsilon, reporter) {
	if (gDisableAngleTests) {
	return;
	}
	SkRandom ran;
	int maxEpsilon = 0;
	double maxAngle = 0;
	for (int index = 0; index < 100000; ++index) {
	SkDLine line = {{{0, 0}, {ran.nextRangeF(0.0001f, 1000), ran.nextRangeF(0.0001f, 1000)}}};
	float t = ran.nextRangeF(0.0001f, 1);
	SkDPoint dPt = line.ptAtT(t);
	float t2 = ran.nextRangeF(0.0001f, 1);
	SkDPoint qPt = line.ptAtT(t2);
	float t3 = ran.nextRangeF(0.0001f, 1);
	SkDPoint qPt2 = line.ptAtT(t3);
	qPt.fX += qPt2.fY;
	qPt.fY -= qPt2.fX;
	QuadPts q = {{line[0], dPt, qPt}};
	SkDQuad quad;
	quad.debugSet(q.fPts);
	// binary search for maximum movement of quad[1] towards test that still has 1 intersection
	double moveT = 0.5f;
	double deltaT = moveT / 2;
	SkDPoint last;
	do {
	last = quad[1];
	quad[1].fX = dPt.fX - line[1].fY * moveT;
	quad[1].fY = dPt.fY + line[1].fX * moveT;
	SkIntersections i;
	i.intersect(quad, line);
	REPORTER_ASSERT(reporter, i.used() > 0);
	if (i.used() == 1) {
	moveT += deltaT;
	} else {
	moveT -= deltaT;
	}
	deltaT /= 2;
	} while (last.asSkPoint() != quad[1].asSkPoint());
	float p1 = SkDoubleToScalar(line[1].fX * last.fY);
	float p2 = SkDoubleToScalar(line[1].fY * last.fX);
	int p1Bits = SkFloatAs2sCompliment(p1);
	int p2Bits = SkFloatAs2sCompliment(p2);
	int epsilon = SkTAbs(p1Bits - p2Bits);
	if (maxEpsilon < epsilon) {
	SkDebugf("line={{0, 0}, {%1.7g, %1.7g}} t=%1.7g/%1.7g/%1.7g moveT=%1.7g"
	" pt={%1.7g, %1.7g} epsilon=%d\n",
	line[1].fX, line[1].fY, t, t2, t3, moveT, last.fX, last.fY, epsilon);
	maxEpsilon = epsilon;
	}
	double a1 = atan2(line[1].fY, line[1].fX);
	double a2 = atan2(last.fY, last.fX);
	double angle = fabs(a1 - a2);
	if (maxAngle < angle) {
	SkDebugf("line={{0, 0}, {%1.7g, %1.7g}} t=%1.7g/%1.7g/%1.7g moveT=%1.7g"
	" pt={%1.7g, %1.7g} angle=%1.7g\n",
	line[1].fX, line[1].fY, t, t2, t3, moveT, last.fX, last.fY, angle);
	maxAngle = angle;
	}
	}
	}

	static int find_slop(double x, double y, double rx, double ry) {
	int slopBits = 0;
	bool less1, less2;
	double absX = fabs(x);
	double absY = fabs(y);
	double length = absX < absY ? absX / 2 + absY : absX + absY / 2;
	int exponent;
	(void) frexp(length, &exponent);
	double epsilon = ldexp(FLT_EPSILON, exponent);
	do {
	// get the length as the larger plus half the smaller (both same signs)
	// find the ulps of the length
	// compute the offsets from there
	double xSlop = epsilon * slopBits;
	double ySlop = x * y < 0 ? -xSlop : xSlop; // OPTIMIZATION: use copysign / _copysign ?
	double x1 = x - xSlop;
	double y1 = y + ySlop;
	double x_ry1 = x1 * ry;
	double rx_y1 = rx * y1;
	less1 = x_ry1 < rx_y1;
	double x2 = x + xSlop;
	double y2 = y - ySlop;
	double x_ry2 = x2 * ry;
	double rx_y2 = rx * y2;
	less2 = x_ry2 < rx_y2;
	} while (less1 == less2 && ++slopBits);
	return slopBits;
	}

	// from http://stackoverflow.com/questions/1427422/cheap-algorithm-to-find-measure-of-angle-between-vectors
	static double diamond_angle(double y, double x)
	{
	if (y >= 0)
	return (x >= 0 ? y/(x+y) : 1-x/(-x+y));
	else
	return (x < 0 ? 2-y/(-x-y) : 3+x/(x-y));
	}

	static const double slopTests[][4] = {
	// x y rx ry
	{-0.058554756452593892, -0.18804585843827226, -0.018568569646021160, -0.059615294434479438},
	{-0.0013717412948608398, 0.0041152238845825195, -0.00045837944195925573, 0.0013753175735478074},
	{-2.1033774145221198, -1.4046019261273715e-008, -0.70062688352066704, -1.2706324683777995e-008},
	};

	DEF_TEST(PathOpsAngleFindSlop, reporter) {
	if (gDisableAngleTests) {
	return;
	}
	for (int index = 0; index < (int) SK_ARRAY_COUNT(slopTests); ++index) {
	const double* slopTest = slopTests[index];
	double x = slopTest[0];
	double y = slopTest[1];
	double rx = slopTest[2];
	double ry = slopTest[3];
	SkDebugf("%s xy %d=%d\n", __FUNCTION__, index, find_slop(x, y, rx, ry));
	SkDebugf("%s rxy %d=%d\n", __FUNCTION__, index, find_slop(rx, ry, x, y));
	double angle = diamond_angle(y, x);
	double rAngle = diamond_angle(ry, rx);
	double diff = fabs(angle - rAngle);
	SkDebugf("%s diamond xy=%1.9g rxy=%1.9g diff=%1.9g factor=%d\n", __FUNCTION__,
	angle, rAngle, diff, (int) (diff / FLT_EPSILON));
	}
	}

	class PathOpsAngleTester {
	public:
	static int After(SkOpAngle& lh, SkOpAngle& rh) {
	return lh.after(&rh);
	}

	static int AllOnOneSide(SkOpAngle& lh, SkOpAngle& rh) {
	return lh.allOnOneSide(&rh);
	}

	static int ConvexHullOverlaps(SkOpAngle& lh, SkOpAngle& rh) {
	return lh.convexHullOverlaps(&rh);
	}

	static int Orderable(SkOpAngle& lh, SkOpAngle& rh) {
	return lh.orderable(&rh);
	}

	static int EndsIntersect(SkOpAngle& lh, SkOpAngle& rh) {
	return lh.endsIntersect(&rh);
	}

	static void SetNext(SkOpAngle& lh, SkOpAngle& rh) {
	lh.fNext = &rh;
	}
	};

	class PathOpsSegmentTester {
	public:
	static void DebugReset(SkOpSegment* segment) {
	segment->debugReset();
	}
	};

	struct CircleData {
	const CubicPts fPts;
	const int fPtCount;
	SkPoint fShortPts[4];
	};

	static CircleData circleDataSet[] = {
	{ {{{313.0155029296875, 207.90290832519531}, {320.05078125, 227.58743286132812}}}, 2, {} },
	{ {{{313.0155029296875, 207.90290832519531}, {313.98246891063195, 219.33615203830394},
	{320.05078125, 227.58743286132812}}}, 3, {} },
	};

	static const int circleDataSetSize = (int) SK_ARRAY_COUNT(circleDataSet);

	DEF_TEST(PathOpsAngleCircle, reporter) {
	SkChunkAlloc allocator(4096);
	SkOpContourHead contour;
	SkOpGlobalState state(&contour, &allocator SkDEBUGPARAMS(false) SkDEBUGPARAMS(nullptr));
	contour.init(&state, false, false);
	for (int index = 0; index < circleDataSetSize; ++index) {
	CircleData& data = circleDataSet[index];
	for (int idx2 = 0; idx2 < data.fPtCount; ++idx2) {
	data.fShortPts[idx2] = data.fPts.fPts[idx2].asSkPoint();
	}
	switch (data.fPtCount) {
	case 2:
	contour.addLine(data.fShortPts);
	break;
	case 3:
	contour.addQuad(data.fShortPts);
	break;
	case 4:
	contour.addCubic(data.fShortPts);
	break;
	}
	}
	SkOpSegment* first = contour.first();
	first->debugAddAngle(0, 1);
	SkOpSegment* next = first->next();
	next->debugAddAngle(0, 1);
	PathOpsAngleTester::Orderable(first->debugLastAngle(), next->debugLastAngle());
	}

	struct IntersectData {
	const CubicPts fPts;
	const int fPtCount;
	double fTStart;
	double fTEnd;
	SkPoint fShortPts[4];
	};

	static IntersectData intersectDataSet1[] = {
	{ {{{322.935669,231.030273}, {312.832214,220.393295}, {312.832214,203.454178}}}, 3,
	0.865309956, 0.154740299, {} },
	{ {{{322.12738,233.397751}, {295.718353,159.505829}}}, 2,
	0.345028807, 0.0786326511, {} },
	{ {{{322.935669,231.030273}, {312.832214,220.393295}, {312.832214,203.454178}}}, 3,
	0.865309956, 1, {} },
	{ {{{322.12738,233.397751}, {295.718353,159.505829}}}, 2,
	0.345028807, 1, {} },
	};

	static IntersectData intersectDataSet2[] = {
	{ {{{364.390686,157.898193}, {375.281769,136.674606}, {396.039917,136.674606}}}, 3,
	0.578520747, 1, {} },
	{ {{{364.390686,157.898193}, {375.281769,136.674606}, {396.039917,136.674606}}}, 3,
	0.578520747, 0.536512973, {} },
	{ {{{366.608826,151.196014}, {378.803101,136.674606}, {398.164948,136.674606}}}, 3,
	0.490456543, 1, {} },
	};

	static IntersectData intersectDataSet3[] = {
	{ {{{2.000000,0.000000}, {1.33333333,0.66666667}}}, 2, 1, 0, {} },
	{ {{{1.33333333,0.66666667}, {0.000000,2.000000}}}, 2, 0, 0.25, {} },
	{ {{{2.000000,2.000000}, {1.33333333,0.66666667}}}, 2, 1, 0, {} },
	};

	static IntersectData intersectDataSet4[] = {
	{ {{{1.3333333,0.6666667}, {0.000,2.000}}}, 2, 0.250000006, 0, {} },
	{ {{{1.000,0.000}, {1.000,1.000}}}, 2, 1, 0, {} },
	{ {{{1.000,1.000}, {0.000,0.000}}}, 2, 0, 1, {} },
	};

	static IntersectData intersectDataSet5[] = {
	{ {{{0.000,0.000}, {1.000,0.000}, {1.000,1.000}}}, 3, 1, 0.666666667, {} },
	{ {{{0.000,0.000}, {2.000,1.000}, {0.000,2.000}}}, 3, 0.5, 1, {} },
	{ {{{0.000,0.000}, {2.000,1.000}, {0.000,2.000}}}, 3, 0.5, 0, {} },
	};

	static IntersectData intersectDataSet6[] = { // pathops_visualizer.htm:3658
	{ {{{0.000,1.000}, {3.000,4.000}, {1.000,0.000}, {3.000,0.000}}}, 4, 0.0925339054, 0, {} }, // pathops_visualizer.htm:3616
	{ {{{0.000,1.000}, {0.000,3.000}, {1.000,0.000}, {4.000,3.000}}}, 4, 0.453872386, 0, {} }, // pathops_visualizer.htm:3616
	{ {{{0.000,1.000}, {3.000,4.000}, {1.000,0.000}, {3.000,0.000}}}, 4, 0.0925339054, 0.417096368, {} }, // pathops_visualizer.htm:3616
	};

	static IntersectData intersectDataSet7[] = { // pathops_visualizer.htm:3748
	{ {{{2.000,1.000}, {0.000,1.000}}}, 2, 0.5, 0, {} }, // pathops_visualizer.htm:3706
	{ {{{2.000,0.000}, {0.000,2.000}}}, 2, 0.5, 1, {} }, // pathops_visualizer.htm:3706
	{ {{{0.000,1.000}, {0.000,2.000}, {2.000,0.000}, {2.000,1.000}}}, 4, 0.5, 1, {} }, // pathops_visualizer.htm:3706
	}; //

	static IntersectData intersectDataSet8[] = { // pathops_visualizer.htm:4194
	{ {{{0.000,1.000}, {2.000,3.000}, {5.000,1.000}, {4.000,3.000}}}, 4, 0.311007457, 0.285714286, {} }, // pathops_visualizer.htm:4152
	{ {{{1.000,5.000}, {3.000,4.000}, {1.000,0.000}, {3.000,2.000}}}, 4, 0.589885081, 0.999982974, {} }, // pathops_visualizer.htm:4152
	{ {{{1.000,5.000}, {3.000,4.000}, {1.000,0.000}, {3.000,2.000}}}, 4, 0.589885081, 0.576935809, {} }, // pathops_visualizer.htm:4152
	}; //

	static IntersectData intersectDataSet9[] = { // pathops_visualizer.htm:4142
	{ {{{0.000,1.000}, {2.000,3.000}, {5.000,1.000}, {4.000,3.000}}}, 4, 0.476627072, 0.311007457, {} }, // pathops_visualizer.htm:4100
	{ {{{1.000,5.000}, {3.000,4.000}, {1.000,0.000}, {3.000,2.000}}}, 4, 0.999982974, 1, {} }, // pathops_visualizer.htm:4100
	{ {{{0.000,1.000}, {2.000,3.000}, {5.000,1.000}, {4.000,3.000}}}, 4, 0.476627072, 1, {} }, // pathops_visualizer.htm:4100
	}; //

	static IntersectData intersectDataSet10[] = { // pathops_visualizer.htm:4186
	{ {{{0.000,1.000}, {1.000,6.000}, {1.000,0.000}, {1.000,0.000}}}, 4, 0.788195121, 0.726275769, {} }, // pathops_visualizer.htm:4144
	{ {{{0.000,1.000}, {0.000,1.000}, {1.000,0.000}, {6.000,1.000}}}, 4, 0.473378977, 1, {} }, // pathops_visualizer.htm:4144
	{ {{{0.000,1.000}, {1.000,6.000}, {1.000,0.000}, {1.000,0.000}}}, 4, 0.788195121, 1, {} }, // pathops_visualizer.htm:4144
	}; //

	static IntersectData intersectDataSet11[] = { // pathops_visualizer.htm:4704
	{ {{{979.305,561.000}, {1036.695,291.000}}}, 2, 0.888888874, 0.11111108, {} }, // pathops_visualizer.htm:4662
	{ {{{1006.695,291.000}, {1023.264,291.000}, {1033.840,304.431}, {1030.318,321.000}}}, 4, 1, 0, {} }, // pathops_visualizer.htm:4662
	{ {{{979.305,561.000}, {1036.695,291.000}}}, 2, 0.888888874, 1, {} }, // pathops_visualizer.htm:4662
	}; //

	static IntersectData intersectDataSet12[] = { // pathops_visualizer.htm:5481
	{ {{{67.000,912.000}, {67.000,913.000}}}, 2, 1, 0, {} }, // pathops_visualizer.htm:5439
	{ {{{67.000,913.000}, {67.000,917.389}, {67.224,921.726}, {67.662,926.000}}}, 4, 0, 1, {} }, // pathops_visualizer.htm:5439
	{ {{{194.000,1041.000}, {123.860,1041.000}, {67.000,983.692}, {67.000,913.000}}}, 4, 1, 0, {} }, // pathops_visualizer.htm:5439
	}; //

	static IntersectData intersectDataSet13[] = { // pathops_visualizer.htm:5735
	{ {{{6.000,0.000}, {0.000,4.000}}}, 2, 0.625, 0.25, {} }, // pathops_visualizer.htm:5693
	{ {{{0.000,1.000}, {0.000,6.000}, {4.000,0.000}, {6.000,1.000}}}, 4, 0.5, 0.833333333, {} }, // pathops_visualizer.htm:5693
	{ {{{0.000,1.000}, {0.000,6.000}, {4.000,0.000}, {6.000,1.000}}}, 4, 0.5, 0.379043969, {} }, // pathops_visualizer.htm:5693
	}; //

	static IntersectData intersectDataSet14[] = { // pathops_visualizer.htm:5875
	{ {{{0.000,1.000}, {4.000,6.000}, {2.000,1.000}, {2.000,0.000}}}, 4, 0.0756502183, 0.0594570973, {} }, // pathops_visualizer.htm:5833
	{ {{{1.000,2.000}, {0.000,2.000}, {1.000,0.000}, {6.000,4.000}}}, 4, 0.0756502184, 0, {} }, // pathops_visualizer.htm:5833
	{ {{{0.000,1.000}, {4.000,6.000}, {2.000,1.000}, {2.000,0.000}}}, 4, 0.0756502183, 0.531917258, {} }, // pathops_visualizer.htm:5833
	}; //

	static IntersectData intersectDataSet15[] = { // pathops_visualizer.htm:6580
	{ {{{490.435,879.407}, {405.593,909.436}}}, 2, 0.500554405, 1, {} }, // pathops_visualizer.htm:6538
	{ {{{447.967,894.438}, {448.007,894.424}, {448.014,894.422}}}, 3, 0, 1, {} }, // pathops_visualizer.htm:6538
	{ {{{490.435,879.407}, {405.593,909.436}}}, 2, 0.500554405, 0.500000273, {} }, // pathops_visualizer.htm:6538
	}; //

	static IntersectData intersectDataSet16[] = { // pathops_visualizer.htm:7419
	{ {{{1.000,4.000}, {4.000,5.000}, {3.000,2.000}, {6.000,3.000}}}, 4, 0.5, 0, {} }, // pathops_visualizer.htm:7377
	{ {{{2.000,3.000}, {3.000,6.000}, {4.000,1.000}, {5.000,4.000}}}, 4, 0.5, 0.112701665, {} }, // pathops_visualizer.htm:7377
	{ {{{5.000,4.000}, {2.000,3.000}}}, 2, 0.5, 0, {} }, // pathops_visualizer.htm:7377
	}; //

	// from skpi_gino_com_16
	static IntersectData intersectDataSet17[] = {
	{ /seg=7/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
	, 3, 0.74590454, 0.547660352, {} },
	{ /seg=8/ {{{185, 734}, {252.93103f, 734}, {308, 789.06897f}, {308, 857}}}
	, 4, 0.12052623, 0, {} },
	{ /seg=7/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
	, 3, 0.74590454, 1, {} },
	};

	static IntersectData intersectDataSet18[] = {
	{ /seg=7/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
	, 3, 0.74590454, 1, {} },
	{ /seg=8/ {{{185, 734}, {252.93103f, 734}, {308, 789.06897f}, {308, 857}}}
	, 4, 0.12052623, 0.217351928, {} },
	{ /seg=7/ {{{270.974121f, 770.025879f}, {234.948273f, 734}, {184, 734}}}
	, 3, 0.74590454, 0.547660352, {} },
	};

	static IntersectData intersectDataSet19[] = {
	{ /seg=1/ {{{0, 1}, {3, 5}, {2, 1}, {3, 1}}}
	, 4, 0.135148995, 0.134791946, {} },
	{ /seg=3/ {{{1, 2}, {1, 2.15061641f}, {1, 2.21049166f}, {1.01366711f, 2.21379328f}}}
	, 4, 0.956740456, 0.894913214, {} },
	{ /seg=1/ {{{0, 1}, {3, 5}, {2, 1}, {3, 1}}}
	, 4, 0.135148995, 0.551812363, {} },
	};

	#define I(x) intersectDataSet##x

	static IntersectData* intersectDataSets[] = {
	I(1), I(2), I(3), I(4), I(5), I(6), I(7), I(8), I(9), I(10),
	I(11), I(12), I(13), I(14), I(15), I(16), I(17), I(18), I(19),
	};

	#undef I
	#define I(x) (int) SK_ARRAY_COUNT(intersectDataSet##x)

	static const int intersectDataSetSizes[] = {
	I(1), I(2), I(3), I(4), I(5), I(6), I(7), I(8), I(9), I(10),
	I(11), I(12), I(13), I(14), I(15), I(16), I(17), I(18), I(19),
	};

	#undef I

	static const int intersectDataSetsSize = (int) SK_ARRAY_COUNT(intersectDataSetSizes);

	struct FourPoints {
	SkPoint pts[4];
	};

	DEF_TEST(PathOpsAngleAfter, reporter) {
	SkChunkAlloc allocator(4096);
	SkOpContourHead contour;
	SkOpGlobalState state(&contour, &allocator SkDEBUGPARAMS(false) SkDEBUGPARAMS(nullptr));
	contour.init(&state, false, false);
	for (int index = intersectDataSetsSize - 1; index >= 0; --index) {
	IntersectData* dataArray = intersectDataSets[index];
	const int dataSize = intersectDataSetSizes[index];
	for (int index2 = 0; index2 < dataSize - 2; ++index2) {
	allocator.reset();
	contour.reset();
	for (int index3 = 0; index3 < 3; ++index3) {
	IntersectData& data = dataArray[index2 + index3];
	SkPoint* temp = (SkPoint*) SkOpTAllocator<FourPoints>::Allocate(&allocator);
	for (int idx2 = 0; idx2 < data.fPtCount; ++idx2) {
	temp[idx2] = data.fPts.fPts[idx2].asSkPoint();
	}
	switch (data.fPtCount) {
	case 2: {
	contour.addLine(temp);
	} break;
	case 3: {
	contour.addQuad(temp);
	} break;
	case 4: {
	contour.addCubic(temp);
	} break;
	}
	}
	SkOpSegment* seg1 = contour.first();
	seg1->debugAddAngle(dataArray[index2 + 0].fTStart, dataArray[index2 + 0].fTEnd);
	SkOpSegment* seg2 = seg1->next();
	seg2->debugAddAngle(dataArray[index2 + 1].fTStart, dataArray[index2 + 1].fTEnd);
	SkOpSegment* seg3 = seg2->next();
	seg3->debugAddAngle(dataArray[index2 + 2].fTStart, dataArray[index2 + 2].fTEnd);
	SkOpAngle& angle1 = *seg1->debugLastAngle();
	SkOpAngle& angle2 = *seg2->debugLastAngle();
	SkOpAngle& angle3 = *seg3->debugLastAngle();
	PathOpsAngleTester::SetNext(angle1, angle3);
	// These data sets are seeded when the set itself fails, so likely the dataset does not
	// match the expected result. The tests above return 1 when first added, but
	// return 0 after the bug is fixed.
	SkDEBUGCODE(int result =) PathOpsAngleTester::After(angle2, angle1);
	SkASSERT(result == 0 \|\| result == 1);
	}
	}
	}

	void SkOpSegment::debugAddAngle(double startT, double endT) {
	SkOpPtT* startPtT = startT == 0 ? fHead.ptT() : startT == 1 ? fTail.ptT()
	: this->addT(startT);
	SkOpPtT* endPtT = endT == 0 ? fHead.ptT() : endT == 1 ? fTail.ptT()
	: this->addT(endT);
	SkOpAngle* angle = SkOpTAllocator<SkOpAngle>::Allocate(this->globalState()->allocator());
	SkOpSpanBase* startSpan = &fHead;
	while (startSpan->ptT() != startPtT) {
	startSpan = startSpan->upCast()->next();
	}
	SkOpSpanBase* endSpan = &fHead;
	while (endSpan->ptT() != endPtT) {
	endSpan = endSpan->upCast()->next();
	}
	angle->set(startSpan, endSpan);
	if (startT < endT) {
	startSpan->upCast()->setToAngle(angle);
	endSpan->setFromAngle(angle);
	} else {
	endSpan->upCast()->setToAngle(angle);
	startSpan->setFromAngle(angle);
	}
	}

	DEF_TEST(PathOpsAngleAllOnOneSide, reporter) {
	SkChunkAlloc allocator(4096);
	SkOpContourHead contour;
	SkOpGlobalState state(&contour, &allocator SkDEBUGPARAMS(false) SkDEBUGPARAMS(nullptr));
	contour.init(&state, false, false);
	SkPoint conicPts[3] = {{494.37100219726562f, 224.66200256347656f},
	{494.37360910682298f, 224.6729026561527f},
	{494.37600708007813f, 224.68400573730469f}};
	SkPoint linePts[2] = {{494.371002f, 224.662003f}, {494.375000f, 224.675995f}};
	for (int i = 10; i >= 0; --i) {
	SkPoint modLinePts[2] = { linePts[0], linePts[1] };
	modLinePts[1].fX += i * .1f;
	contour.addLine(modLinePts);
	contour.addQuad(conicPts);
	// contour.addConic(conicPts, 0.999935746f, &allocator);
	SkOpSegment* first = contour.first();
	first->debugAddAngle(0, 1);
	SkOpSegment* next = first->next();
	next->debugAddAngle(0, 1);
	/* int result = */
	PathOpsAngleTester::AllOnOneSide(first->debugLastAngle(), next->debugLastAngle());
	// SkDebugf("i=%d result=%d\n", i , result);
	// SkDebugf("");
	}
	}