tests/CubicChopTest.cpp - skia - Git at Google

 /*
  * Copyright 2023 Google LLC
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "include/core/SkSpan.h"
 #include "include/core/SkTypes.h"
 #include "include/private/base/SkFloatingPoint.h"
 #include "src/base/SkBezierCurves.h"
 #include "src/pathops/SkPathOpsCubic.h"
 #include "src/pathops/SkPathOpsPoint.h"
 #include "src/pathops/SkPathOpsTypes.h"
 #include "tests/Test.h"

 #include <algorithm>
 #include <array>
 #include <cstring>
 #include <iterator>
 #include <string>

 // Grouping the test inputs into DoublePoints makes the test cases easier to read.
 struct DoublePoint {
     double x;
     double y;
 };

 static bool nearly_equal(double expected, double actual) {
     if (sk_double_nearly_zero(expected)) {
         return sk_double_nearly_zero(actual);
     }
     return sk_doubles_nearly_equal_ulps(expected, actual, 64);
 }

 static void testChopCubicAtT(skiatest::Reporter* reporter, std::string name,
                              SkSpan<const DoublePoint> curveInputs, double t,
                              SkSpan<const DoublePoint> expectedOutputs) {
     skiatest::ReporterContext subtest(reporter, name);
     REPORTER_ASSERT(reporter, curveInputs.size() == 4,
                     "Invalid test case. Should have 4 input points.");
     REPORTER_ASSERT(reporter, t >= 0.0 && t <= 1.0,
                     "Invalid test case. t %f should be in [0, 1]", t);
     // Two cubic curves, sharing an input point
     REPORTER_ASSERT(reporter, expectedOutputs.size() == 7,
                     "Invalid test case. Should have 7 output points.");


     {
         skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
         SkDCubic input;
         std::memcpy(&input.fPts[0], curveInputs.begin(), 8 * sizeof(double));
         SkDCubicPair output = input.chopAt(t);

         for (int i = 0; i < 7; ++i) {
             REPORTER_ASSERT(reporter,
                             nearly_equal(expectedOutputs[i].x, output.pts[i].fX) &&
                             nearly_equal(expectedOutputs[i].y, output.pts[i].fY),
                             "(%.16f, %.16f) != (%.16f, %.16f) at index %d",
                             expectedOutputs[i].x, expectedOutputs[i].y,
                             output.pts[i].fX, output.pts[i].fY, i);
         }
     }
     {
         skiatest::ReporterContext subsubtest(reporter, "SkBezier Implementation");
         double input[8];
         double output[14];
         std::memcpy(input, curveInputs.begin(), 8 * sizeof(double));
         SkBezierCubic::Subdivide(input, t, output);

         for (int i = 0; i < 7; ++i) {
             REPORTER_ASSERT(reporter,
                             nearly_equal(expectedOutputs[i].x, output[i*2]) &&
                             nearly_equal(expectedOutputs[i].y, output[i*2 + 1]),
                             "(%.16f, %.16f) != (%.16f, %.16f) at index %d",
                             expectedOutputs[i].x, expectedOutputs[i].y,
                             output[i*2], output[i*2 + 1], i);
         }
     }
 }

 DEF_TEST(ChopCubicAtT_NormalizedCubic, reporter) {
     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.0,
         {{  0.000000,  0.000000 }, {  0.000000,  0.000000 }, {  0.000000,  0.000000 },
          {  0.000000,  0.000000 },
          {  0.120000,  1.800000 }, {  0.920000, -1.650000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.1",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.1,
         {{  0.000000,  0.000000 }, {  0.012000,  0.180000 }, {  0.030800,  0.307500 },
          {  0.055000,  0.393850 },
          {  0.272800,  1.171000 }, {  0.928000, -1.385000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.2",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.2,
         {{  0.000000,  0.000000 }, {  0.024000,  0.360000 }, {  0.075200,  0.510000 },
          {  0.142400,  0.540800 },
          {  0.411200,  0.664000 }, {  0.936000, -1.120000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.3",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.3,
         {{  0.000000,  0.000000 }, {  0.036000,  0.540000 }, {  0.133200,  0.607500 },
          {  0.253800,  0.508950 },
          {  0.535200,  0.279000 }, {  0.944000, -0.855000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.4",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.4,
         {{  0.000000,  0.000000 }, {  0.048000,  0.720000 }, {  0.204800,  0.600000 },
          {  0.380800,  0.366400 },
          {  0.644800,  0.016000 }, {  0.952000, -0.590000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.5",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.5,
         {{  0.000000,  0.000000 }, {  0.060000,  0.900000 }, {  0.290000,  0.487500 },
          {  0.515000,  0.181250 },
          {  0.740000, -0.125000 }, {  0.960000, -0.325000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.6",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.6,
         {{  0.000000,  0.000000 }, {  0.072000,  1.080000 }, {  0.388800,  0.270000 },
          {  0.648000,  0.021600 },
          {  0.820800, -0.144000 }, {  0.968000, -0.060000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.7",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.7,
         {{  0.000000,  0.000000 }, {  0.084000,  1.260000 }, {  0.501200, -0.052500 },
          {  0.771400, -0.044450 },
          {  0.887200, -0.041000 }, {  0.976000,  0.205000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.8",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.8,
         {{  0.000000,  0.000000 }, {  0.096000,  1.440000 }, {  0.627200, -0.480000 },
          {  0.876800,  0.051200 },
          {  0.939200,  0.184000 }, {  0.984000,  0.470000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.9",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         0.9,
         {{  0.000000,  0.000000 }, {  0.108000,  1.620000 }, {  0.766800, -1.012500 },
          {  0.955800,  0.376650 },
          {  0.976800,  0.531000 }, {  0.992000,  0.735000 }, {  1.000000,  1.000000 }}
     );

     testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=1.0",
         {{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
         1.0,
         {{  0.000000,  0.000000 }, {  0.120000,  1.800000 }, {  0.920000, -1.650000 },
          {  1.000000,  1.000000 },
          {  1.000000,  1.000000 }, {  1.000000,  1.000000 }, {  1.000000,  1.000000 }}
     );
 }

 DEF_TEST(ChopCubicAtT_ArbitraryCubic, reporter) {
     testChopCubicAtT(reporter, "Arbitrary Cubic, t=0.1234",
         {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
         0.1234,
         {{-10.00000000000000, -20.00000000000000 },
          { -9.62980000000000, -16.91500000000000 },
          { -8.98550392000000, -14.31728192000000 },
          { -8.16106580520000, -12.10537539118400 },
          { -2.30448192000000,   3.60740632000000 },
          { 12.64260000000000,  -0.14900000000000 },
          {  3.00000000000000,  13.00000000000000 }}
     );

     testChopCubicAtT(reporter, "Arbitrary Cubic, t=0.3456",
         {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
         0.3456,
         {{-10.00000000000000, -20.00000000000000 },
          { -8.96320000000000, -11.36000000000000 },
          { -5.77649152000000,  -6.54205952000000 },
          { -2.50378670080000,  -3.31715344793600 },
          {  3.69314048000000,   2.78926592000000 },
          { 10.19840000000000,   3.18400000000000 },
          {  3.00000000000000,  13.00000000000000 }}
     );

     testChopCubicAtT(reporter, "Arbitrary Cubic, t=0.8765",
         {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
         0.8765,
         {{-10.00000000000000, -20.00000000000000 },
          { -7.37050000000000,   1.91250000000000 },
          {  9.08754050000000,  -0.75907200000000 },
          {  5.70546664375000,   8.34743124475000 },
          {  5.22892800000000,   9.63054950000000 },
          {  4.35850000000000,  11.14750000000000 },
          {  3.00000000000000,  13.00000000000000 }}
     );
 }

 static void testCubicExtrema(skiatest::Reporter* reporter, std::string name,
                              double A, double B, double C, double D,
                              SkSpan<const double> expectedExtrema) {
     skiatest::ReporterContext subtest(reporter, name);
     // Validate test case
     REPORTER_ASSERT(reporter, expectedExtrema.size() <= 2,
                     "Invalid test case, up to 2 extrema allowed");
     {
         const double inputs[8] = {A, 0, B, 0, C, 0, D, 0};
         std::array<double, 4> bezier = SkBezierCubic::ConvertToPolynomial(inputs, false);
         // The X extrema of the Bezier curve represented by the 4 provided X coordinates
         // (Start, Control Point 1, Control Point 2, Stop) are where the derivative of that
         // polynomial is zero. We can verify this for the expected Extrema.
         // lowercase letters to emphasize we are referring to Bezier curve (using t),
         // not X,Y values.
         auto [a, b, c, d] = bezier;
         a *= 3; // derivative (at^3 -> 3at^2)
         b *= 2; // derivative (bt^2 -> 2bt)
         c *= 1; // derivative (ct^1 -> c)
         d = 0;  // derivative (d    -> 0)
         for (size_t i = 0; i < expectedExtrema.size(); i++) {
             double t = expectedExtrema[i];
             REPORTER_ASSERT(reporter, t >= 0 && t <= 1,
                             "Invalid test case root %zu. Roots must be in [0, 1]", i);
             double shouldBeZero = a * t * t + b * t + c;
             REPORTER_ASSERT(reporter, sk_double_nearly_zero(shouldBeZero),
                     "Invalid test case root %zu. %1.16f != 0", i, shouldBeZero);
         }
     }

     {
         skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
         double extrema[2] = {0, 0};
         // This implementation expects the coefficients to be (X, Y), (X, Y), (X, Y), (X, Y)
         // but it ignores the values at odd indices.
         const double inputs[8] = {A, 0, B, 0, C, 0, D, 0};
         int extremaCount = SkDCubic::FindExtrema(&inputs[0], extrema);
         REPORTER_ASSERT(reporter, expectedExtrema.size() == size_t(extremaCount),
                         "Wrong number of extrema returned %zu != %d",
                         expectedExtrema.size(), extremaCount);

         // We don't care which order the roots are returned from the algorithm.
         // For determinism, we will sort them (and ensure the provided solutions are also sorted).
         std::sort(std::begin(extrema), std::begin(extrema) + extremaCount);
         for (int i = 0; i < extremaCount; i++) {
             if (sk_double_nearly_zero(expectedExtrema[i])) {
                 REPORTER_ASSERT(reporter, sk_double_nearly_zero(extrema[i]),
                                 "0 != %1.16e at index %d", extrema[i], i);
             } else {
                 REPORTER_ASSERT(reporter,
                                 sk_doubles_nearly_equal_ulps(expectedExtrema[i], extrema[i], 64),
                                 "%1.16f != %1.16f at index %d", expectedExtrema[i], extrema[i], i);
             }
         }
     }
 }

 DEF_TEST(CubicExtrema_FindsLocalMinAndMaxInRangeZeroToOneInclusive, reporter) {
     // All answers are given with 16 significant digits (max for a double) or as an integer
     // when the answer is exact.
     // Note that the Y coordinates do not impact the X extrema, so they are omitted from
     // the test case (and labeled as N in the subtest names)

     // https://www.desmos.com/calculator/fejoovy3v1
     testCubicExtrema(reporter, "(24, N) (-46, N) (-29, N) (-6, N) has 2 local extrema",
                     24, -46, 29, -6,
                     {0.3476582809885365,
                      0.7895966209722478});

     testCubicExtrema(reporter, "(10, N) (3, N) (7, N) (10, N) has 2 extrema, only 1 in range",
                 10, 3, 7, 10,
                 {  0.4097697891418150
                 // 0.4097697891418150259166930 according to WolframAlpha
                 // 1.423563544191518307416640 is the other root, but omitted because it is not
                 //                            between 0 and 1 inclusive.
                 });

     testCubicExtrema(reporter, "(10, N) (9.99, N) (20.01, N) (10, N) with extrema near endpoints",
                 10, 9.99, 20.01, 20,
                 { 0.0004987532413361362,
                 //0.0004987532413361221515157644 according to Wolfram Alpha (2.8e-12% error)
                   0.9995012467586639,
                 //0.9995012467586638778484842 according to Wolfram Alpha
                  });

     testCubicExtrema(reporter, "(10, N) (10, N) (20, N) (20, N) has extrema at endpoints",
                     10, 10, 20, 20,
                     {0.0,
                      1.0});

     // The polynomial for these points is just c(t) = 15t + 10, which has no local extrema.
     testCubicExtrema(reporter, "(10, N) (15, N) (20, N) (25, N) has no extrema at all",
                     10, 15, 20, 25,
                     {});

     // The polynomial for these points is monotonically increasing, so no local extrema.
     testCubicExtrema(reporter, "(10, N) (14, N) (14, N) (20, N) has no extrema at all",
                     10, 14, 14, 20,
                     {});

     // The polynomial for these points has a stationary point at t = 0.5, but still no extrema.
     testCubicExtrema(reporter, "(10, N) (14, N) (14, N) (20, N) has no extrema at all",
                     10, 18, 12, 20,
                     {});

     testCubicExtrema(reporter, "(10, N) (16, N) (16, N) (10, N) has a single local maximum",
                 10, 16, 16, 10,
                 {0.5});

     testCubicExtrema(reporter, "(10, N) (8, N) (8, N) (10, N) has a single local minima",
                 10, 8, 8, 10,
                 {0.5});

     // The polynomial for these points is c(t) = 10. Taking the derivative of that results in
     // c'(t) = 0, which has infinite solutions. Our linear solver handles this case by saying
     // it just has a single solution at t = 0.
     testCubicExtrema(reporter, "(10, N) (10, N) (10, N) (10, N) is defined to have an extrema at 0",
                 10, 10, 10, 10,
                 {0.0});
 }

 static void testCubicInflectionPoints(skiatest::Reporter* reporter,
                                       std::string name, SkSpan<const DoublePoint> curveInputs,
                                       SkSpan<const double> expectedTValues) {
     skiatest::ReporterContext subtest(reporter, name);
     // Validate test case
     REPORTER_ASSERT(reporter, curveInputs.size() == 4,
                     "Invalid test case. Input curve should have 4 points");
     REPORTER_ASSERT(reporter, expectedTValues.size() <= 2,
                     "Invalid test case, up to 2 inflection points possible");

     for (size_t i = 0; i < expectedTValues.size(); i++) {
         double t = expectedTValues[i];
         REPORTER_ASSERT(reporter, t >= 0.0 && t <= 1.0,
                         "Invalid test case t %zu. Should be between 0 and 1 inclusive.", i);

         auto inputs = reinterpret_cast<const double*>(curveInputs.data());
         auto [Ax, Bx, Cx, Dx] = SkBezierCubic::ConvertToPolynomial(inputs, false);
         auto [Ay, By, Cy, Dy] = SkBezierCubic::ConvertToPolynomial(inputs, true);

         // verify that X' * Y'' - X'' * Y' == 0 at the given t
         // https://stackoverflow.com/a/35906870
         double curvature = (3 * (Bx * Ay - Ax * By)) * t * t +
                            (3 * (Cx * Ay - Ax * Cy)) * t +
                            (Cx * By - Bx * Cy);

         REPORTER_ASSERT(reporter, sk_double_nearly_zero(curvature),
                         "Invalid test case t %zu. 0 != %1.16f.", i, curvature);

         if (i > 0) {
             REPORTER_ASSERT(reporter, expectedTValues[i - 1] <= expectedTValues[i],
                             "Invalid test case t %zu. Sort intersections in ascending order", i);
         }
     }

     {
         skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
         SkDCubic inputCubic;
         for (int i = 0; i < 4; i++) {
             inputCubic.fPts[i].fX = curveInputs[i].x;
             inputCubic.fPts[i].fY = curveInputs[i].y;
         }
         double actualTValues[2] = {0, 0};
         int inflectionsFound = inputCubic.findInflections(actualTValues);
         REPORTER_ASSERT(reporter, expectedTValues.size() == size_t(inflectionsFound),
                         "Wrong number of roots returned %zu != %d", expectedTValues.size(),
                         inflectionsFound);

         // We don't care which order the t values which are returned from the algorithm.
         // For determinism, we will sort them (and ensure the provided solutions are also sorted).
         std::sort(std::begin(actualTValues), std::begin(actualTValues) + inflectionsFound);
         for (int i = 0; i < inflectionsFound; i++) {
             REPORTER_ASSERT(reporter,
                     nearly_equal(expectedTValues[i], actualTValues[i]),
                     "%.16f != %.16f at index %d", expectedTValues[i], actualTValues[i], i);
         }
     }
 }

 DEF_TEST(CubicInflectionPoints_FindsConvexityChangesInRangeZeroToOneInclusive, reporter) {
     // All answers are given with 16 significant digits (max for a double) or as an integer
     // when the answer is exact.
     testCubicInflectionPoints(reporter, "curve changes convexity exactly halfway",
                               {{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
                               { 0.5 });

     // https://www.desmos.com/calculator/8qkmrq3n3e
     testCubicInflectionPoints(reporter, "A curve with one inflection point",
                               {{ 10, 5 }, { 9, 12 }, { 24, -2 }, { 25, 3 }},
                               { 0.5194234849019033 });

     // https://www.desmos.com/calculator/sk2bbz56kv
     testCubicInflectionPoints(reporter, "A curve with two inflection points",
                               {{ 5, 5 }, { 16, 15 }, { 24, -2 }, { 15, 13 }},
                               {0.5553407889916796,
                                0.8662808326299419});

     testCubicInflectionPoints(reporter, "A curve which overlaps itself",
                               {{ 3, 6 }, { -3, 4 }, { 4, 5 }, { 0, 6 }},
                               {});

     testCubicInflectionPoints(reporter, "A monotonically increasing curve",
                               {{ 10, 15 }, { 20, 25 }, { 30, 35 }, { 40, 45 }},
                                // The curvature equation becomes C(t) = 0, which
                                // our linear solver says has 1 root at t = 0.
                               { 0.0 });
 }

 static void testBezierCurveHorizontalIntersectBinarySearch(skiatest::Reporter* reporter,
                 std::string name, SkSpan<const DoublePoint> curveInputs, double xToIntersect,
                 SkSpan<const double> expectedTValues,
                 bool skipPathops = false) {
     skiatest::ReporterContext subtest(reporter, name);
     // Validate test case
     REPORTER_ASSERT(reporter, curveInputs.size() == 4,
                     "Invalid test case. Input curve should have 4 points");
     REPORTER_ASSERT(reporter, expectedTValues.size() <= 3,
                     "Invalid test case, up to 3 intersections possible");

     for (size_t i = 0; i < expectedTValues.size(); i++) {
         double t = expectedTValues[i];
         REPORTER_ASSERT(reporter, t >= 0.0 && t <= 1.0,
                     "Invalid test case t %zu. Should be between 0 and 1 inclusive.", i);

         auto [x, y] = SkBezierCubic::EvalAt(reinterpret_cast<const double*>(curveInputs.data()), t);
         // This is explicitly approximately_equal and not something more precise because
         // the binary search given by the pathops algorithm is not super precise.
         REPORTER_ASSERT(reporter, approximately_equal(xToIntersect, x),
                     "Invalid test case %zu, %1.16f != %1.16f", i, xToIntersect, x);

         if (i > 0) {
             REPORTER_ASSERT(reporter, expectedTValues[i-1] <= expectedTValues[i],
                     "Invalid test case t %zu. Sort intersections in ascending order", i);
         }
     }

     if (!skipPathops) {
         skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
         // This implementation expects the coefficients to be (X, Y), (X, Y), (X, Y), (X, Y)
         // but it ignores the values at odd indices.
         SkDCubic inputCubic;
         for (int i = 0; i < 4; i++) {
             inputCubic.fPts[i].fX = curveInputs[i].x;
             inputCubic.fPts[i].fY = curveInputs[i].y;
         }
         double actualTValues[3] = {0, 0, 0};
         // There are only 2 extrema that could be found, but the searchRoots will put
         // the inflection points (up to 2) and the end points (0, 1) in to this array
         // as well.
         double extremaAndInflections[6] = {0, 0, 0, 0, 0};
         int extrema = SkDCubic::FindExtrema(&inputCubic[0].fX, extremaAndInflections);
         int rootCount = inputCubic.searchRoots(extremaAndInflections, extrema, xToIntersect,
                                                SkDCubic::kXAxis, actualTValues);
         REPORTER_ASSERT(reporter, expectedTValues.size() == size_t(rootCount),
                         "Wrong number of roots returned %zu != %d", expectedTValues.size(),
                         rootCount);

         // We don't care which order the t values which are returned from the algorithm.
         // For determinism, we will sort them (and ensure the provided solutions are also sorted).
         std::sort(std::begin(actualTValues), std::begin(actualTValues) + rootCount);
         for (int i = 0; i < rootCount; i++) {
             REPORTER_ASSERT(reporter,
                     nearly_equal(expectedTValues[i], actualTValues[i]),
                     "%.16f != %.16f at index %d", expectedTValues[i], actualTValues[i], i);
         }
     }
 }

 DEF_TEST(BezierCurveHorizontalIntersectBinarySearch, reporter) {
     // All answers are given with 16 significant digits (max for a double) or as an integer
     // when the answer is exact.
     // The Y values in these curves do not impact the test case, but make it easier to visualize
     // when plotting the curves to verify the solutions.
     testBezierCurveHorizontalIntersectBinarySearch(reporter,
            "straight curve crosses once @ 2.0",
            {{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
            2.0,
            {0.2871407270431519});

     testBezierCurveHorizontalIntersectBinarySearch(reporter,
            "straight curve crosses once @ 6.0",
            {{ 0, 0 }, { 3, 3 }, { 6, 6 }, { 10, 10 }},
            6.0,
            {0.6378342509269714});


     testBezierCurveHorizontalIntersectBinarySearch(reporter,
            "out and back curve exactly touches @ 3.0",
            {{ 0, 0 }, { 4, 4 }, { 4, 4 }, { 0, 8 }},
            3.0,
            // The binary search algorithm (currently) gets close to, but not quite 0.5
            {0.4999389648437500,
             0.5000610351562500});

     testBezierCurveHorizontalIntersectBinarySearch(reporter,
            "out and back curve crosses twice @ 2.0",
            {{ 0, 0 }, { 4, 4 }, { 4, 4 }, { 0, 8 }},
            2.0,
            {0.2113248705863953,
             0.7886751294136047});

     testBezierCurveHorizontalIntersectBinarySearch(reporter,
            "out and back curve never crosses 4.0",
            {{ 0, 0 }, { 4, 4 }, { 4, 4 }, { 0, 8 }},
            4.0,
            {});


     testBezierCurveHorizontalIntersectBinarySearch(reporter,
             "left right left curve crosses three times @ 2.0",
            {{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
            2.0,
            {  0.1361965624455005,
            // 0.1361965624455005397216403 according to Wolfram Alpha
               0.5,
               0.8638034375544995
            // 0.8638034375544994602783597 according to Wolfram Alpha
             },
             // PathOps version fails to find these roots (has not been investigated yet)
             true /* = skipPathops */);

     testBezierCurveHorizontalIntersectBinarySearch(reporter,
             "left right left curve crosses one time @ 1.0",
            {{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
            1.0,
            {  0.9454060400510326,
            // 0.9454060415952252910201453 according to Wolfram Alpha
             });

     testBezierCurveHorizontalIntersectBinarySearch(reporter,
             "left right left curve crosses three times @ 2.5",
            {{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
            2.5,
            {  0.0898667385750473,
            // 0.08986673805184604633583244 according to Wolfram Alpha
               0.6263520961813417,
            // 0.6263521357441907129444252 according to Wolfram Alpha
               0.7837811281217468,
            // 0.7837811262039632407197424 according to Wolfram Alpha
             });
 }
	/*
	* Copyright 2023 Google LLC
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "include/core/SkSpan.h"
	#include "include/core/SkTypes.h"
	#include "include/private/base/SkFloatingPoint.h"
	#include "src/base/SkBezierCurves.h"
	#include "src/pathops/SkPathOpsCubic.h"
	#include "src/pathops/SkPathOpsPoint.h"
	#include "src/pathops/SkPathOpsTypes.h"
	#include "tests/Test.h"

	#include <algorithm>
	#include <array>
	#include <cstring>
	#include <iterator>
	#include <string>

	// Grouping the test inputs into DoublePoints makes the test cases easier to read.
	struct DoublePoint {
	double x;
	double y;
	};

	static bool nearly_equal(double expected, double actual) {
	if (sk_double_nearly_zero(expected)) {
	return sk_double_nearly_zero(actual);
	}
	return sk_doubles_nearly_equal_ulps(expected, actual, 64);
	}

	static void testChopCubicAtT(skiatest::Reporter* reporter, std::string name,
	SkSpan<const DoublePoint> curveInputs, double t,
	SkSpan<const DoublePoint> expectedOutputs) {
	skiatest::ReporterContext subtest(reporter, name);
	REPORTER_ASSERT(reporter, curveInputs.size() == 4,
	"Invalid test case. Should have 4 input points.");
	REPORTER_ASSERT(reporter, t >= 0.0 && t <= 1.0,
	"Invalid test case. t %f should be in [0, 1]", t);
	// Two cubic curves, sharing an input point
	REPORTER_ASSERT(reporter, expectedOutputs.size() == 7,
	"Invalid test case. Should have 7 output points.");


	{
	skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
	SkDCubic input;
	std::memcpy(&input.fPts[0], curveInputs.begin(), 8 * sizeof(double));
	SkDCubicPair output = input.chopAt(t);

	for (int i = 0; i < 7; ++i) {
	REPORTER_ASSERT(reporter,
	nearly_equal(expectedOutputs[i].x, output.pts[i].fX) &&
	nearly_equal(expectedOutputs[i].y, output.pts[i].fY),
	"(%.16f, %.16f) != (%.16f, %.16f) at index %d",
	expectedOutputs[i].x, expectedOutputs[i].y,
	output.pts[i].fX, output.pts[i].fY, i);
	}
	}
	{
	skiatest::ReporterContext subsubtest(reporter, "SkBezier Implementation");
	double input[8];
	double output[14];
	std::memcpy(input, curveInputs.begin(), 8 * sizeof(double));
	SkBezierCubic::Subdivide(input, t, output);

	for (int i = 0; i < 7; ++i) {
	REPORTER_ASSERT(reporter,
	nearly_equal(expectedOutputs[i].x, output[i*2]) &&
	nearly_equal(expectedOutputs[i].y, output[i*2 + 1]),
	"(%.16f, %.16f) != (%.16f, %.16f) at index %d",
	expectedOutputs[i].x, expectedOutputs[i].y,
	output[i2], output[i2 + 1], i);
	}
	}
	}

	DEF_TEST(ChopCubicAtT_NormalizedCubic, reporter) {
	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.0,
	{{ 0.000000, 0.000000 }, { 0.000000, 0.000000 }, { 0.000000, 0.000000 },
	{ 0.000000, 0.000000 },
	{ 0.120000, 1.800000 }, { 0.920000, -1.650000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.1",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.1,
	{{ 0.000000, 0.000000 }, { 0.012000, 0.180000 }, { 0.030800, 0.307500 },
	{ 0.055000, 0.393850 },
	{ 0.272800, 1.171000 }, { 0.928000, -1.385000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.2",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.2,
	{{ 0.000000, 0.000000 }, { 0.024000, 0.360000 }, { 0.075200, 0.510000 },
	{ 0.142400, 0.540800 },
	{ 0.411200, 0.664000 }, { 0.936000, -1.120000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.3",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.3,
	{{ 0.000000, 0.000000 }, { 0.036000, 0.540000 }, { 0.133200, 0.607500 },
	{ 0.253800, 0.508950 },
	{ 0.535200, 0.279000 }, { 0.944000, -0.855000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.4",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.4,
	{{ 0.000000, 0.000000 }, { 0.048000, 0.720000 }, { 0.204800, 0.600000 },
	{ 0.380800, 0.366400 },
	{ 0.644800, 0.016000 }, { 0.952000, -0.590000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.5",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.5,
	{{ 0.000000, 0.000000 }, { 0.060000, 0.900000 }, { 0.290000, 0.487500 },
	{ 0.515000, 0.181250 },
	{ 0.740000, -0.125000 }, { 0.960000, -0.325000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.6",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.6,
	{{ 0.000000, 0.000000 }, { 0.072000, 1.080000 }, { 0.388800, 0.270000 },
	{ 0.648000, 0.021600 },
	{ 0.820800, -0.144000 }, { 0.968000, -0.060000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.7",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.7,
	{{ 0.000000, 0.000000 }, { 0.084000, 1.260000 }, { 0.501200, -0.052500 },
	{ 0.771400, -0.044450 },
	{ 0.887200, -0.041000 }, { 0.976000, 0.205000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.8",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.8,
	{{ 0.000000, 0.000000 }, { 0.096000, 1.440000 }, { 0.627200, -0.480000 },
	{ 0.876800, 0.051200 },
	{ 0.939200, 0.184000 }, { 0.984000, 0.470000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=0.9",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	0.9,
	{{ 0.000000, 0.000000 }, { 0.108000, 1.620000 }, { 0.766800, -1.012500 },
	{ 0.955800, 0.376650 },
	{ 0.976800, 0.531000 }, { 0.992000, 0.735000 }, { 1.000000, 1.000000 }}
	);

	testChopCubicAtT(reporter, "Cubic between 0,0, and 1,1, t=1.0",
	{{ 0, 0 }, { .12, 1.8 }, { .92, -1.65 }, { 1.0, 1.0 }},
	1.0,
	{{ 0.000000, 0.000000 }, { 0.120000, 1.800000 }, { 0.920000, -1.650000 },
	{ 1.000000, 1.000000 },
	{ 1.000000, 1.000000 }, { 1.000000, 1.000000 }, { 1.000000, 1.000000 }}
	);
	}

	DEF_TEST(ChopCubicAtT_ArbitraryCubic, reporter) {
	testChopCubicAtT(reporter, "Arbitrary Cubic, t=0.1234",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.1234,
	{{-10.00000000000000, -20.00000000000000 },
	{ -9.62980000000000, -16.91500000000000 },
	{ -8.98550392000000, -14.31728192000000 },
	{ -8.16106580520000, -12.10537539118400 },
	{ -2.30448192000000, 3.60740632000000 },
	{ 12.64260000000000, -0.14900000000000 },
	{ 3.00000000000000, 13.00000000000000 }}
	);

	testChopCubicAtT(reporter, "Arbitrary Cubic, t=0.3456",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.3456,
	{{-10.00000000000000, -20.00000000000000 },
	{ -8.96320000000000, -11.36000000000000 },
	{ -5.77649152000000, -6.54205952000000 },
	{ -2.50378670080000, -3.31715344793600 },
	{ 3.69314048000000, 2.78926592000000 },
	{ 10.19840000000000, 3.18400000000000 },
	{ 3.00000000000000, 13.00000000000000 }}
	);

	testChopCubicAtT(reporter, "Arbitrary Cubic, t=0.8765",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.8765,
	{{-10.00000000000000, -20.00000000000000 },
	{ -7.37050000000000, 1.91250000000000 },
	{ 9.08754050000000, -0.75907200000000 },
	{ 5.70546664375000, 8.34743124475000 },
	{ 5.22892800000000, 9.63054950000000 },
	{ 4.35850000000000, 11.14750000000000 },
	{ 3.00000000000000, 13.00000000000000 }}
	);
	}

	static void testCubicExtrema(skiatest::Reporter* reporter, std::string name,
	double A, double B, double C, double D,
	SkSpan<const double> expectedExtrema) {
	skiatest::ReporterContext subtest(reporter, name);
	// Validate test case
	REPORTER_ASSERT(reporter, expectedExtrema.size() <= 2,
	"Invalid test case, up to 2 extrema allowed");
	{
	const double inputs[8] = {A, 0, B, 0, C, 0, D, 0};
	std::array<double, 4> bezier = SkBezierCubic::ConvertToPolynomial(inputs, false);
	// The X extrema of the Bezier curve represented by the 4 provided X coordinates
	// (Start, Control Point 1, Control Point 2, Stop) are where the derivative of that
	// polynomial is zero. We can verify this for the expected Extrema.
	// lowercase letters to emphasize we are referring to Bezier curve (using t),
	// not X,Y values.
	auto [a, b, c, d] = bezier;
	a *= 3; // derivative (at^3 -> 3at^2)
	b *= 2; // derivative (bt^2 -> 2bt)
	c *= 1; // derivative (ct^1 -> c)
	d = 0; // derivative (d -> 0)
	for (size_t i = 0; i < expectedExtrema.size(); i++) {
	double t = expectedExtrema[i];
	REPORTER_ASSERT(reporter, t >= 0 && t <= 1,
	"Invalid test case root %zu. Roots must be in [0, 1]", i);
	double shouldBeZero = a * t * t + b * t + c;
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(shouldBeZero),
	"Invalid test case root %zu. %1.16f != 0", i, shouldBeZero);
	}
	}

	{
	skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
	double extrema[2] = {0, 0};
	// This implementation expects the coefficients to be (X, Y), (X, Y), (X, Y), (X, Y)
	// but it ignores the values at odd indices.
	const double inputs[8] = {A, 0, B, 0, C, 0, D, 0};
	int extremaCount = SkDCubic::FindExtrema(&inputs[0], extrema);
	REPORTER_ASSERT(reporter, expectedExtrema.size() == size_t(extremaCount),
	"Wrong number of extrema returned %zu != %d",
	expectedExtrema.size(), extremaCount);

	// We don't care which order the roots are returned from the algorithm.
	// For determinism, we will sort them (and ensure the provided solutions are also sorted).
	std::sort(std::begin(extrema), std::begin(extrema) + extremaCount);
	for (int i = 0; i < extremaCount; i++) {
	if (sk_double_nearly_zero(expectedExtrema[i])) {
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(extrema[i]),
	"0 != %1.16e at index %d", extrema[i], i);
	} else {
	REPORTER_ASSERT(reporter,
	sk_doubles_nearly_equal_ulps(expectedExtrema[i], extrema[i], 64),
	"%1.16f != %1.16f at index %d", expectedExtrema[i], extrema[i], i);
	}
	}
	}
	}

	DEF_TEST(CubicExtrema_FindsLocalMinAndMaxInRangeZeroToOneInclusive, reporter) {
	// All answers are given with 16 significant digits (max for a double) or as an integer
	// when the answer is exact.
	// Note that the Y coordinates do not impact the X extrema, so they are omitted from
	// the test case (and labeled as N in the subtest names)

	// https://www.desmos.com/calculator/fejoovy3v1
	testCubicExtrema(reporter, "(24, N) (-46, N) (-29, N) (-6, N) has 2 local extrema",
	24, -46, 29, -6,
	{0.3476582809885365,
	0.7895966209722478});

	testCubicExtrema(reporter, "(10, N) (3, N) (7, N) (10, N) has 2 extrema, only 1 in range",
	10, 3, 7, 10,
	{ 0.4097697891418150
	// 0.4097697891418150259166930 according to WolframAlpha
	// 1.423563544191518307416640 is the other root, but omitted because it is not
	// between 0 and 1 inclusive.
	});

	testCubicExtrema(reporter, "(10, N) (9.99, N) (20.01, N) (10, N) with extrema near endpoints",
	10, 9.99, 20.01, 20,
	{ 0.0004987532413361362,
	//0.0004987532413361221515157644 according to Wolfram Alpha (2.8e-12% error)
	0.9995012467586639,
	//0.9995012467586638778484842 according to Wolfram Alpha
	});

	testCubicExtrema(reporter, "(10, N) (10, N) (20, N) (20, N) has extrema at endpoints",
	10, 10, 20, 20,
	{0.0,
	1.0});

	// The polynomial for these points is just c(t) = 15t + 10, which has no local extrema.
	testCubicExtrema(reporter, "(10, N) (15, N) (20, N) (25, N) has no extrema at all",
	10, 15, 20, 25,
	{});

	// The polynomial for these points is monotonically increasing, so no local extrema.
	testCubicExtrema(reporter, "(10, N) (14, N) (14, N) (20, N) has no extrema at all",
	10, 14, 14, 20,
	{});

	// The polynomial for these points has a stationary point at t = 0.5, but still no extrema.
	testCubicExtrema(reporter, "(10, N) (14, N) (14, N) (20, N) has no extrema at all",
	10, 18, 12, 20,
	{});

	testCubicExtrema(reporter, "(10, N) (16, N) (16, N) (10, N) has a single local maximum",
	10, 16, 16, 10,
	{0.5});

	testCubicExtrema(reporter, "(10, N) (8, N) (8, N) (10, N) has a single local minima",
	10, 8, 8, 10,
	{0.5});

	// The polynomial for these points is c(t) = 10. Taking the derivative of that results in
	// c'(t) = 0, which has infinite solutions. Our linear solver handles this case by saying
	// it just has a single solution at t = 0.
	testCubicExtrema(reporter, "(10, N) (10, N) (10, N) (10, N) is defined to have an extrema at 0",
	10, 10, 10, 10,
	{0.0});
	}

	static void testCubicInflectionPoints(skiatest::Reporter* reporter,
	std::string name, SkSpan<const DoublePoint> curveInputs,
	SkSpan<const double> expectedTValues) {
	skiatest::ReporterContext subtest(reporter, name);
	// Validate test case
	REPORTER_ASSERT(reporter, curveInputs.size() == 4,
	"Invalid test case. Input curve should have 4 points");
	REPORTER_ASSERT(reporter, expectedTValues.size() <= 2,
	"Invalid test case, up to 2 inflection points possible");

	for (size_t i = 0; i < expectedTValues.size(); i++) {
	double t = expectedTValues[i];
	REPORTER_ASSERT(reporter, t >= 0.0 && t <= 1.0,
	"Invalid test case t %zu. Should be between 0 and 1 inclusive.", i);

	auto inputs = reinterpret_cast<const double*>(curveInputs.data());
	auto [Ax, Bx, Cx, Dx] = SkBezierCubic::ConvertToPolynomial(inputs, false);
	auto [Ay, By, Cy, Dy] = SkBezierCubic::ConvertToPolynomial(inputs, true);

	// verify that X' * Y'' - X'' * Y' == 0 at the given t
	// https://stackoverflow.com/a/35906870
	double curvature = (3 * (Bx * Ay - Ax * By)) * t * t +
	(3 * (Cx * Ay - Ax * Cy)) * t +
	(Cx * By - Bx * Cy);

	REPORTER_ASSERT(reporter, sk_double_nearly_zero(curvature),
	"Invalid test case t %zu. 0 != %1.16f.", i, curvature);

	if (i > 0) {
	REPORTER_ASSERT(reporter, expectedTValues[i - 1] <= expectedTValues[i],
	"Invalid test case t %zu. Sort intersections in ascending order", i);
	}
	}

	{
	skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
	SkDCubic inputCubic;
	for (int i = 0; i < 4; i++) {
	inputCubic.fPts[i].fX = curveInputs[i].x;
	inputCubic.fPts[i].fY = curveInputs[i].y;
	}
	double actualTValues[2] = {0, 0};
	int inflectionsFound = inputCubic.findInflections(actualTValues);
	REPORTER_ASSERT(reporter, expectedTValues.size() == size_t(inflectionsFound),
	"Wrong number of roots returned %zu != %d", expectedTValues.size(),
	inflectionsFound);

	// We don't care which order the t values which are returned from the algorithm.
	// For determinism, we will sort them (and ensure the provided solutions are also sorted).
	std::sort(std::begin(actualTValues), std::begin(actualTValues) + inflectionsFound);
	for (int i = 0; i < inflectionsFound; i++) {
	REPORTER_ASSERT(reporter,
	nearly_equal(expectedTValues[i], actualTValues[i]),
	"%.16f != %.16f at index %d", expectedTValues[i], actualTValues[i], i);
	}
	}
	}

	DEF_TEST(CubicInflectionPoints_FindsConvexityChangesInRangeZeroToOneInclusive, reporter) {
	// All answers are given with 16 significant digits (max for a double) or as an integer
	// when the answer is exact.
	testCubicInflectionPoints(reporter, "curve changes convexity exactly halfway",
	{{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
	{ 0.5 });

	// https://www.desmos.com/calculator/8qkmrq3n3e
	testCubicInflectionPoints(reporter, "A curve with one inflection point",
	{{ 10, 5 }, { 9, 12 }, { 24, -2 }, { 25, 3 }},
	{ 0.5194234849019033 });

	// https://www.desmos.com/calculator/sk2bbz56kv
	testCubicInflectionPoints(reporter, "A curve with two inflection points",
	{{ 5, 5 }, { 16, 15 }, { 24, -2 }, { 15, 13 }},
	{0.5553407889916796,
	0.8662808326299419});

	testCubicInflectionPoints(reporter, "A curve which overlaps itself",
	{{ 3, 6 }, { -3, 4 }, { 4, 5 }, { 0, 6 }},
	{});

	testCubicInflectionPoints(reporter, "A monotonically increasing curve",
	{{ 10, 15 }, { 20, 25 }, { 30, 35 }, { 40, 45 }},
	// The curvature equation becomes C(t) = 0, which
	// our linear solver says has 1 root at t = 0.
	{ 0.0 });
	}

	static void testBezierCurveHorizontalIntersectBinarySearch(skiatest::Reporter* reporter,
	std::string name, SkSpan<const DoublePoint> curveInputs, double xToIntersect,
	SkSpan<const double> expectedTValues,
	bool skipPathops = false) {
	skiatest::ReporterContext subtest(reporter, name);
	// Validate test case
	REPORTER_ASSERT(reporter, curveInputs.size() == 4,
	"Invalid test case. Input curve should have 4 points");
	REPORTER_ASSERT(reporter, expectedTValues.size() <= 3,
	"Invalid test case, up to 3 intersections possible");

	for (size_t i = 0; i < expectedTValues.size(); i++) {
	double t = expectedTValues[i];
	REPORTER_ASSERT(reporter, t >= 0.0 && t <= 1.0,
	"Invalid test case t %zu. Should be between 0 and 1 inclusive.", i);

	auto [x, y] = SkBezierCubic::EvalAt(reinterpret_cast<const double*>(curveInputs.data()), t);
	// This is explicitly approximately_equal and not something more precise because
	// the binary search given by the pathops algorithm is not super precise.
	REPORTER_ASSERT(reporter, approximately_equal(xToIntersect, x),
	"Invalid test case %zu, %1.16f != %1.16f", i, xToIntersect, x);

	if (i > 0) {
	REPORTER_ASSERT(reporter, expectedTValues[i-1] <= expectedTValues[i],
	"Invalid test case t %zu. Sort intersections in ascending order", i);
	}
	}

	if (!skipPathops) {
	skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
	// This implementation expects the coefficients to be (X, Y), (X, Y), (X, Y), (X, Y)
	// but it ignores the values at odd indices.
	SkDCubic inputCubic;
	for (int i = 0; i < 4; i++) {
	inputCubic.fPts[i].fX = curveInputs[i].x;
	inputCubic.fPts[i].fY = curveInputs[i].y;
	}
	double actualTValues[3] = {0, 0, 0};
	// There are only 2 extrema that could be found, but the searchRoots will put
	// the inflection points (up to 2) and the end points (0, 1) in to this array
	// as well.
	double extremaAndInflections[6] = {0, 0, 0, 0, 0};
	int extrema = SkDCubic::FindExtrema(&inputCubic[0].fX, extremaAndInflections);
	int rootCount = inputCubic.searchRoots(extremaAndInflections, extrema, xToIntersect,
	SkDCubic::kXAxis, actualTValues);
	REPORTER_ASSERT(reporter, expectedTValues.size() == size_t(rootCount),
	"Wrong number of roots returned %zu != %d", expectedTValues.size(),
	rootCount);

	// We don't care which order the t values which are returned from the algorithm.
	// For determinism, we will sort them (and ensure the provided solutions are also sorted).
	std::sort(std::begin(actualTValues), std::begin(actualTValues) + rootCount);
	for (int i = 0; i < rootCount; i++) {
	REPORTER_ASSERT(reporter,
	nearly_equal(expectedTValues[i], actualTValues[i]),
	"%.16f != %.16f at index %d", expectedTValues[i], actualTValues[i], i);
	}
	}
	}

	DEF_TEST(BezierCurveHorizontalIntersectBinarySearch, reporter) {
	// All answers are given with 16 significant digits (max for a double) or as an integer
	// when the answer is exact.
	// The Y values in these curves do not impact the test case, but make it easier to visualize
	// when plotting the curves to verify the solutions.
	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"straight curve crosses once @ 2.0",
	{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
	2.0,
	{0.2871407270431519});

	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"straight curve crosses once @ 6.0",
	{{ 0, 0 }, { 3, 3 }, { 6, 6 }, { 10, 10 }},
	6.0,
	{0.6378342509269714});


	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"out and back curve exactly touches @ 3.0",
	{{ 0, 0 }, { 4, 4 }, { 4, 4 }, { 0, 8 }},
	3.0,
	// The binary search algorithm (currently) gets close to, but not quite 0.5
	{0.4999389648437500,
	0.5000610351562500});

	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"out and back curve crosses twice @ 2.0",
	{{ 0, 0 }, { 4, 4 }, { 4, 4 }, { 0, 8 }},
	2.0,
	{0.2113248705863953,
	0.7886751294136047});

	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"out and back curve never crosses 4.0",
	{{ 0, 0 }, { 4, 4 }, { 4, 4 }, { 0, 8 }},
	4.0,
	{});


	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"left right left curve crosses three times @ 2.0",
	{{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
	2.0,
	{ 0.1361965624455005,
	// 0.1361965624455005397216403 according to Wolfram Alpha
	0.5,
	0.8638034375544995
	// 0.8638034375544994602783597 according to Wolfram Alpha
	},
	// PathOps version fails to find these roots (has not been investigated yet)
	true /* = skipPathops */);

	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"left right left curve crosses one time @ 1.0",
	{{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
	1.0,
	{ 0.9454060400510326,
	// 0.9454060415952252910201453 according to Wolfram Alpha
	});

	testBezierCurveHorizontalIntersectBinarySearch(reporter,
	"left right left curve crosses three times @ 2.5",
	{{ 4, 0 }, { -3, 4 }, { 7, 4 }, { 0, 8 }},
	2.5,
	{ 0.0898667385750473,
	// 0.08986673805184604633583244 according to Wolfram Alpha
	0.6263520961813417,
	// 0.6263521357441907129444252 according to Wolfram Alpha
	0.7837811281217468,
	// 0.7837811262039632407197424 according to Wolfram Alpha
	});
	}