tests/CubicRootsTest.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/SkCubics.h"
 #include "src/base/SkUtils.h"
 #include "src/pathops/SkPathOpsCubic.h"
 #include "tests/Test.h"

 #include <algorithm>
 #include <cmath>
 #include <cstddef>
 #include <iterator>
 #include <string>

 static void testCubicRootsReal(skiatest::Reporter* reporter, std::string name,
                                double A, double B, double C, double D,
                                SkSpan<const double> expectedRoots,
                                bool skipPathops = false,
                                bool skipRootValidation = false) {
     skiatest::ReporterContext subtest(reporter, name);
     // Validate test case
     REPORTER_ASSERT(reporter, expectedRoots.size() <= 3,
                     "Invalid test case, up to 3 roots allowed");

     for (size_t i = 0; i < expectedRoots.size(); i++) {
         double x = expectedRoots[i];
         // A*x^3 + B*x^2 + C*x + D should equal 0 (unless floating point error causes issues)
         double y = A * x * x * x + B * x * x + C * x + D;
         if (!skipRootValidation) {
             REPORTER_ASSERT(reporter, sk_double_nearly_zero(y),
                             "Invalid test case root %zu. %.16f != 0", i, y);
         }

         if (i > 0) {
             REPORTER_ASSERT(reporter, expectedRoots[i-1] <= expectedRoots[i],
                     "Invalid test case root %zu. Roots should be sorted in ascending order", i);
         }
     }

     // The old pathops implementation sometimes gives incorrect solutions. We can opt
     // our tests out of checking that older implementation if that causes issues.
     if (!skipPathops) {
         skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
         double roots[3] = {0, 0, 0};
         int rootCount = SkDCubic::RootsReal(A, B, C, D, roots);
         REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
                         "Wrong number of roots returned %zu != %d", expectedRoots.size(),
                         rootCount);

         // 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(roots), std::begin(roots) + rootCount);
         for (int i = 0; i < rootCount; i++) {
             if (sk_double_nearly_zero(expectedRoots[i])) {
                 REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
                                 "0 != %.16f at index %d", roots[i], i);
             } else {
                 REPORTER_ASSERT(reporter,
                                 sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
                                 "%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
             }
         }
     }
     {
         skiatest::ReporterContext subsubtest(reporter, "SkCubics Analytic Implementation");
         double roots[3] = {0, 0, 0};
         int rootCount = SkCubics::RootsReal(A, B, C, D, roots);
         REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
                         "Wrong number of roots returned %zu != %d", expectedRoots.size(),
                         rootCount);

         // 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(roots), std::begin(roots) + rootCount);
         for (int i = 0; i < rootCount; i++) {
             if (sk_double_nearly_zero(expectedRoots[i])) {
                 REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
                                 "0 != %.16f at index %d", roots[i], i);
             } else {
                 REPORTER_ASSERT(reporter,
                                 sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
                                 "%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
             }
         }
     }
 }

 DEF_TEST(CubicRootsReal_ActualCubics, reporter) {
     // All answers are given with 16 significant digits (max for a double) or as an integer
     // when the answer is exact.
     testCubicRootsReal(reporter, "one root 1x^3 + 2x^2 + 3x + 4",
                        1, 2, 3, 4,
                        {-1.650629191439388});
                       //-1.650629191439388218880801 from Wolfram Alpha

     // (3x-5)(6x-10)(x+4) = 18x^3 + 12x^2 - 190x + 200
     testCubicRootsReal(reporter, "touches y axis 18x^3 + 12x^2 - 190x + 200",
                        18, 12, -190, 200,
                        {-4.,
                          1.666666666666667, // 5/3
                        });

     testCubicRootsReal(reporter, "three roots 10x^3 - 20x^2 - 30x + 40",
                        10, -20, -30, 40,
                        {-1.561552812808830,
                       //-1.561552812808830274910705 from Wolfram Alpha
                          1.,
                          2.561552812808830,
                       // 2.561552812808830274910705 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "three roots -10x^3 + 200x^2 + 300x - 400",
                        -10, 200, 300, -400,
                        {-2.179884793243323,
                       //-2.179884793243323422232630 from Wolfram Alpha
                          0.8607083693981839,
                       // 0.8607083693981838897123320 from Wolfram Alpha
                         21.31917642384514,
                       //21.31917642384513953252030 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "one root -x^3 + 0x^2 + 5x - 7",
                        -1, 0, 5, -7,
                        {-2.747346540307211,
                       //-2.747346540307210849971436 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "one root 2x^3 - 3x^2 + 0x + 3",
                        2, -3, 0, 3,
                        {-0.806443932358772,
                       //-0.8064439323587723772036250 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "one root x^3 + 0x^2 + 0x - 9",
                        1, 0, 0, -9,
                        {2.080083823051904,
                       //2.0800838230519041145300568 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "three roots 2x^3 - 3x^2 - 4x + 0",
                        2, -3, -4, 0,
                        {-0.8507810593582122,
                       //-0.8507810593582121716220544 from Wolfram Alpha
                         0.,
                         2.350781059358212
                       //2.350781059358212171622054 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "R^2 and Q^3 are near zero",
                        -0.33790159225463867, -0.81997990608215332,
                        -0.66327774524688721, -0.17884063720703125,
                        {-0.7995944894729731});

     // The following three cases fallback to treating the cubic as a quadratic.
     // Otherwise, floating point error mangles the solutions near +- 1
     // This means we don't find all the roots, but usually we only care about roots
     // in the range [0, 1], so that is ok.
     testCubicRootsReal(reporter, "oss-fuzz:55625 Two roots near zero, one big root",
                        sk_bit_cast<double>(0xbf1a8de580000000), // -0.00010129655
                        sk_bit_cast<double>(0x4106c0c680000000), // 186392.8125
                        0.0,
                        sk_bit_cast<double>(0xc104c0ce80000000), // -170009.8125
                        { -0.9550418733785169, // Wolfram Alpha puts the root at X = 0.955042
                           0.9550418733785169, // (~2e7 error)
                          // 1.84007e9 is the other root, which we do not find.
                        },
                        true /* == skipPathops */, true /* == skipRootValidation */);

     testCubicRootsReal(reporter, "oss-fuzz:55625 Two roots near zero, one big root, near linear",
                        sk_bit_cast<double>(0x3c04040400000000), // -1.3563156-19
                        sk_bit_cast<double>(0x4106c0c680000000), // 186392.8125
                        0.0,
                        sk_bit_cast<double>(0xc104c0ce80000000), // -170009.8125
                        { -0.9550418733785169,
                           0.9550418733785169,
                          // 1.84007e9 is the other root, which we do not find.
                        },
                        true /* == skipPathops */);

     testCubicRootsReal(reporter, "oss-fuzz:55680 A nearly zero, C is zero",
                        sk_bit_cast<double>(0x3eb0000000000000), // 9.5367431640625000e-07
                        sk_bit_cast<double>(0x409278a560000000), // 1182.1614990234375
                        0.0,
                        sk_bit_cast<double>(0xc092706160000000), // -1180.0950927734375
                        { -0.9991256228290017,
                       // -0.9991256232316570469050229 according to Wolfram Alpha (~1e-09 error)
                           0.9991256228290017,
                        // 0.9991256224263463476403026 according to Wolfram Alpha (~1e-09 error)
                          // 1.239586176×10^9 is the other root, which we do not find.
                        },
                        true, true /* == skipRootValidation */);
 }

 DEF_TEST(CubicRootsReal_Quadratics, reporter) {
     testCubicRootsReal(reporter, "two roots -2x^2 + 3x + 4",
                        0, -2, 3, 4,
                        {-0.8507810593582122,
                       //-0.8507810593582121716220544 from Wolfram Alpha
                          2.350781059358212,
                       // 2.350781059358212171622054 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "touches y axis -x^2 + 3x + 4",
                        0, -2, 3, 4,
                        {-0.8507810593582122,
                       //-0.8507810593582121716220544 from Wolfram Alpha
                          2.350781059358212,
                       // 2.350781059358212171622054 from Wolfram Alpha
                        });

     testCubicRootsReal(reporter, "no roots x^2 + 2x + 7",
                        0, 1, 2, 7,
                        {});

     // similar to oss-fuzz:55680
     testCubicRootsReal(reporter, "two roots one small one big (and ignored)",
                        0, -0.01, 200000000000000, -120000000000000,
                        { 0.6 },
                         true /* == skipPathops */);
 }

 DEF_TEST(CubicRootsReal_Linear, reporter) {
     testCubicRootsReal(reporter, "positive slope 3x + 4",
                        0, 0, 3, 4,
                        {-1.333333333333333});

     testCubicRootsReal(reporter, "negative slope -2x - 8",
                        0, 0, -2, -8,
                        {-4.});
 }

 DEF_TEST(CubicRootsReal_Constant, reporter) {
     testCubicRootsReal(reporter, "No intersections y = 4",
                        0, 0, 0, 4,
                        {});

     testCubicRootsReal(reporter, "Infinite solutions y = 0",
                        0, 0, 0, 0,
                        {0.});
 }

 DEF_TEST(CubicRootsReal_NonFiniteNumbers, reporter) {
     // The Pathops implementation does not check for infinities nor nans in all cases.
     double roots[3] = {0, 0, 0};
     REPORTER_ASSERT(reporter,
         SkCubics::RootsReal(NAN, 1, 2, 3, roots) == 0,
         "Nan A"
     );
     REPORTER_ASSERT(reporter,
         SkCubics::RootsReal(1, NAN, 2, 3, roots) == 0,
         "Nan B"
     );
     REPORTER_ASSERT(reporter,
         SkCubics::RootsReal(1, 2, NAN, 3, roots) == 0,
         "Nan C"
     );
     REPORTER_ASSERT(reporter,
         SkCubics::RootsReal(1, 2, 3, NAN, roots) == 0,
         "Nan D"
     );

     {
         skiatest::ReporterContext subtest(reporter, "oss-fuzz:55419 C and D are large");
         int numRoots = SkCubics::RootsReal(
                                            -2, 0,
                                            sk_bit_cast<double>(0xd5422020202020ff), //-5.074559e+102
                                            sk_bit_cast<double>(0x600fff202020ff20), // 5.362551e+154
                                            roots);
         REPORTER_ASSERT(reporter, numRoots == 0, "No finite roots expected, got %d", numRoots);
     }
     {
         skiatest::ReporterContext subtest(reporter, "oss-fuzz:55829 A is zero and B is NAN");
         int numRoots = SkCubics::RootsReal(
                                            0,
                                            sk_bit_cast<double>(0xffffffffffff2020), //-nan
                                            sk_bit_cast<double>(0x20202020202020ff), // 6.013470e-154
                                            sk_bit_cast<double>(0xff20202020202020), //-2.211661e+304
                                            roots);
         REPORTER_ASSERT(reporter, numRoots == 0, "No finite roots expected, got %d", numRoots);
     }
 }

 static void testCubicValidT(skiatest::Reporter* reporter, std::string name,
                             double A, double B, double C, double D,
                             SkSpan<const double> expectedRoots) {
     skiatest::ReporterContext subtest(reporter, name);
     // Validate test case
     REPORTER_ASSERT(reporter, expectedRoots.size() <= 3,
                     "Invalid test case, up to 3 roots allowed");

     for (size_t i = 0; i < expectedRoots.size(); i++) {
         double x = expectedRoots[i];
         REPORTER_ASSERT(reporter, x >= 0 && x <= 1,
                         "Invalid test case root %zu. Roots must be in [0, 1]", i);

         // A*x^3 + B*x^2 + C*x + D should equal 0
         double y = A * x * x * x + B * x * x + C * x + D;
         REPORTER_ASSERT(reporter, sk_double_nearly_zero(y),
                     "Invalid test case root %zu. %.16f != 0", i, y);

         if (i > 0) {
             REPORTER_ASSERT(reporter, expectedRoots[i-1] <= expectedRoots[i],
                     "Invalid test case root %zu. Roots should be sorted in ascending order", i);
         }
     }

     {
         skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
         double roots[3] = {0, 0, 0};
         int rootCount = SkDCubic::RootsValidT(A, B, C, D, roots);
         REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
                         "Wrong number of roots returned %zu != %d",
                         expectedRoots.size(), rootCount);

         // 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(roots), std::begin(roots) + rootCount);
         for (int i = 0; i < rootCount; i++) {
             if (sk_double_nearly_zero(expectedRoots[i])) {
                 REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
                                 "0 != %.16f at index %d", roots[i], i);
             } else {
                 REPORTER_ASSERT(reporter,
                                 sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
                                 "%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
             }
         }
     }
     {
         skiatest::ReporterContext subsubtest(reporter, "SkCubics Analytic Implementation");
         double roots[3] = {0, 0, 0};
         int rootCount = SkCubics::RootsValidT(A, B, C, D, roots);
         REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
                         "Wrong number of roots returned %zu != %d",
                         expectedRoots.size(), rootCount);

         // 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(roots), std::begin(roots) + rootCount);
         for (int i = 0; i < rootCount; i++) {
             if (sk_double_nearly_zero(expectedRoots[i])) {
                 REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
                                 "0 != %.16f at index %d", roots[i], i);
             } else {
                 REPORTER_ASSERT(reporter,
                                 sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
                                 "%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
             }
         }
     }
     {
         skiatest::ReporterContext subsubtest(reporter, "SkCubics Binary Search Implementation");
         double roots[3] = {0, 0, 0};
         int rootCount = SkCubics::BinarySearchRootsValidT(A, B, C, D, roots);
         REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
                         "Wrong number of roots returned %zu != %d", expectedRoots.size(),
                         rootCount);

         // 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(roots), std::begin(roots) + rootCount);
         for (int i = 0; i < rootCount; i++) {
             double delta = std::abs(roots[i] - expectedRoots[i]);
             REPORTER_ASSERT(reporter,
                             // Binary search is not absolutely accurate all the time, but
                             // it should be accurate enough reliably
                             delta < 0.000001,
                             "%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
         }
     }
 }

 DEF_TEST(CubicRootsValidT, reporter) {
     // All answers are given with 16 significant digits (max for a double) or as an integer
     // when the answer is exact.
     testCubicValidT(reporter, "three roots 24x^3 - 46x^2 + 29x - 6",
                     24, -46, 29, -6,
                     {0.5,
                      0.6666666666666667,
                      0.75});

     testCubicValidT(reporter, "three roots total, two in range 54x^3 - 117x^2 + 45x + 0",
                     54, -117, 45, 0,
                     {0.0,
                      0.5,
                      // 5/3 is the other root, but not in [0, 1]
                     });

     testCubicValidT(reporter, "one root = 1 10x^3 - 20x^2 - 30x + 40",
                     10, -20, -30, 40,
                     {1.0});

     testCubicValidT(reporter, "one root = 0 2x^3 - 3x^2 - 4x + 0",
                     2, -3, -4, 0,
                     {0.0});

     testCubicValidT(reporter, "three roots total, two in range -2x^3 - 3x^2 + 4x + 0",
                     -2, -3, 4, 0,
                     { 0.0,
                       0.8507810593582122,
                    // 0.8507810593582121716220544 from Wolfram Alpha
                     });

     // x(x-1) = x^2 - x
     testCubicValidT(reporter, "Two roots at exactly 0 and 1",
                     0, 1, -1, 0,
                     {0.0, 1.0});

     testCubicValidT(reporter, "Single point has one root",
                     0, 0, 0, 0,
                     {0.0});
 }

 DEF_TEST(CubicRootsValidT_ClampToZeroAndOne, reporter) {
     {
         // (x + 0.00001)(x - 1.00005), but the answers will be 0 and 1
         double A = 0.;
         double B = 1.;
         double C = -1.00004;
         double D = -0.0000100005;
         double roots[3] = {0, 0, 0};
         int rootCount = SkDCubic::RootsValidT(A, B, C, D, roots);

         REPORTER_ASSERT(reporter, rootCount == 2);
         std::sort(std::begin(roots), std::begin(roots) + rootCount);
         REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[0]), "%.16f != 0", roots[0]);
         REPORTER_ASSERT(reporter, sk_doubles_nearly_equal_ulps(roots[1], 1), "%.16f != 1", roots[1]);
     }
     {
         // Three very small roots, all of them are nearly equal zero
         // (1 - 10000000000x)(1 - 20000000000x)(1 - 30000000000x)
         // -6000000000000000000000000000000 x^3 + 1100000000000000000000 x^2 - 60000000000 x + 1
         double A = -6.0e30;
         double B = 1.1e21;
         double C = -6.0e10;
         double D = 1;
         double roots[3] = {0, 0, 0};
         int rootCount = SkDCubic::RootsValidT(A, B, C, D, roots);

         REPORTER_ASSERT(reporter, rootCount == 1);
         std::sort(std::begin(roots), std::begin(roots) + rootCount);
         REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[0]), "%.16f != 0", roots[0]);
     }
 }
	/*
	* 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/SkCubics.h"
	#include "src/base/SkUtils.h"
	#include "src/pathops/SkPathOpsCubic.h"
	#include "tests/Test.h"

	#include <algorithm>
	#include <cmath>
	#include <cstddef>
	#include <iterator>
	#include <string>

	static void testCubicRootsReal(skiatest::Reporter* reporter, std::string name,
	double A, double B, double C, double D,
	SkSpan<const double> expectedRoots,
	bool skipPathops = false,
	bool skipRootValidation = false) {
	skiatest::ReporterContext subtest(reporter, name);
	// Validate test case
	REPORTER_ASSERT(reporter, expectedRoots.size() <= 3,
	"Invalid test case, up to 3 roots allowed");

	for (size_t i = 0; i < expectedRoots.size(); i++) {
	double x = expectedRoots[i];
	// Ax^3 + Bx^2 + C*x + D should equal 0 (unless floating point error causes issues)
	double y = A * x * x * x + B * x * x + C * x + D;
	if (!skipRootValidation) {
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(y),
	"Invalid test case root %zu. %.16f != 0", i, y);
	}

	if (i > 0) {
	REPORTER_ASSERT(reporter, expectedRoots[i-1] <= expectedRoots[i],
	"Invalid test case root %zu. Roots should be sorted in ascending order", i);
	}
	}

	// The old pathops implementation sometimes gives incorrect solutions. We can opt
	// our tests out of checking that older implementation if that causes issues.
	if (!skipPathops) {
	skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
	double roots[3] = {0, 0, 0};
	int rootCount = SkDCubic::RootsReal(A, B, C, D, roots);
	REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
	"Wrong number of roots returned %zu != %d", expectedRoots.size(),
	rootCount);

	// 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(roots), std::begin(roots) + rootCount);
	for (int i = 0; i < rootCount; i++) {
	if (sk_double_nearly_zero(expectedRoots[i])) {
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
	"0 != %.16f at index %d", roots[i], i);
	} else {
	REPORTER_ASSERT(reporter,
	sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
	"%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
	}
	}
	}
	{
	skiatest::ReporterContext subsubtest(reporter, "SkCubics Analytic Implementation");
	double roots[3] = {0, 0, 0};
	int rootCount = SkCubics::RootsReal(A, B, C, D, roots);
	REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
	"Wrong number of roots returned %zu != %d", expectedRoots.size(),
	rootCount);

	// 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(roots), std::begin(roots) + rootCount);
	for (int i = 0; i < rootCount; i++) {
	if (sk_double_nearly_zero(expectedRoots[i])) {
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
	"0 != %.16f at index %d", roots[i], i);
	} else {
	REPORTER_ASSERT(reporter,
	sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
	"%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
	}
	}
	}
	}

	DEF_TEST(CubicRootsReal_ActualCubics, reporter) {
	// All answers are given with 16 significant digits (max for a double) or as an integer
	// when the answer is exact.
	testCubicRootsReal(reporter, "one root 1x^3 + 2x^2 + 3x + 4",
	1, 2, 3, 4,
	{-1.650629191439388});
	//-1.650629191439388218880801 from Wolfram Alpha

	// (3x-5)(6x-10)(x+4) = 18x^3 + 12x^2 - 190x + 200
	testCubicRootsReal(reporter, "touches y axis 18x^3 + 12x^2 - 190x + 200",
	18, 12, -190, 200,
	{-4.,
	1.666666666666667, // 5/3
	});

	testCubicRootsReal(reporter, "three roots 10x^3 - 20x^2 - 30x + 40",
	10, -20, -30, 40,
	{-1.561552812808830,
	//-1.561552812808830274910705 from Wolfram Alpha
	1.,
	2.561552812808830,
	// 2.561552812808830274910705 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "three roots -10x^3 + 200x^2 + 300x - 400",
	-10, 200, 300, -400,
	{-2.179884793243323,
	//-2.179884793243323422232630 from Wolfram Alpha
	0.8607083693981839,
	// 0.8607083693981838897123320 from Wolfram Alpha
	21.31917642384514,
	//21.31917642384513953252030 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "one root -x^3 + 0x^2 + 5x - 7",
	-1, 0, 5, -7,
	{-2.747346540307211,
	//-2.747346540307210849971436 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "one root 2x^3 - 3x^2 + 0x + 3",
	2, -3, 0, 3,
	{-0.806443932358772,
	//-0.8064439323587723772036250 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "one root x^3 + 0x^2 + 0x - 9",
	1, 0, 0, -9,
	{2.080083823051904,
	//2.0800838230519041145300568 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "three roots 2x^3 - 3x^2 - 4x + 0",
	2, -3, -4, 0,
	{-0.8507810593582122,
	//-0.8507810593582121716220544 from Wolfram Alpha
	0.,
	2.350781059358212
	//2.350781059358212171622054 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "R^2 and Q^3 are near zero",
	-0.33790159225463867, -0.81997990608215332,
	-0.66327774524688721, -0.17884063720703125,
	{-0.7995944894729731});

	// The following three cases fallback to treating the cubic as a quadratic.
	// Otherwise, floating point error mangles the solutions near +- 1
	// This means we don't find all the roots, but usually we only care about roots
	// in the range [0, 1], so that is ok.
	testCubicRootsReal(reporter, "oss-fuzz:55625 Two roots near zero, one big root",
	sk_bit_cast<double>(0xbf1a8de580000000), // -0.00010129655
	sk_bit_cast<double>(0x4106c0c680000000), // 186392.8125
	0.0,
	sk_bit_cast<double>(0xc104c0ce80000000), // -170009.8125
	{ -0.9550418733785169, // Wolfram Alpha puts the root at X = 0.955042
	0.9550418733785169, // (~2e7 error)
	// 1.84007e9 is the other root, which we do not find.
	},
	true /* == skipPathops /, true / == skipRootValidation */);

	testCubicRootsReal(reporter, "oss-fuzz:55625 Two roots near zero, one big root, near linear",
	sk_bit_cast<double>(0x3c04040400000000), // -1.3563156-19
	sk_bit_cast<double>(0x4106c0c680000000), // 186392.8125
	0.0,
	sk_bit_cast<double>(0xc104c0ce80000000), // -170009.8125
	{ -0.9550418733785169,
	0.9550418733785169,
	// 1.84007e9 is the other root, which we do not find.
	},
	true /* == skipPathops */);

	testCubicRootsReal(reporter, "oss-fuzz:55680 A nearly zero, C is zero",
	sk_bit_cast<double>(0x3eb0000000000000), // 9.5367431640625000e-07
	sk_bit_cast<double>(0x409278a560000000), // 1182.1614990234375
	0.0,
	sk_bit_cast<double>(0xc092706160000000), // -1180.0950927734375
	{ -0.9991256228290017,
	// -0.9991256232316570469050229 according to Wolfram Alpha (~1e-09 error)
	0.9991256228290017,
	// 0.9991256224263463476403026 according to Wolfram Alpha (~1e-09 error)
	// 1.239586176×10^9 is the other root, which we do not find.
	},
	true, true /* == skipRootValidation */);
	}

	DEF_TEST(CubicRootsReal_Quadratics, reporter) {
	testCubicRootsReal(reporter, "two roots -2x^2 + 3x + 4",
	0, -2, 3, 4,
	{-0.8507810593582122,
	//-0.8507810593582121716220544 from Wolfram Alpha
	2.350781059358212,
	// 2.350781059358212171622054 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "touches y axis -x^2 + 3x + 4",
	0, -2, 3, 4,
	{-0.8507810593582122,
	//-0.8507810593582121716220544 from Wolfram Alpha
	2.350781059358212,
	// 2.350781059358212171622054 from Wolfram Alpha
	});

	testCubicRootsReal(reporter, "no roots x^2 + 2x + 7",
	0, 1, 2, 7,
	{});

	// similar to oss-fuzz:55680
	testCubicRootsReal(reporter, "two roots one small one big (and ignored)",
	0, -0.01, 200000000000000, -120000000000000,
	{ 0.6 },
	true /* == skipPathops */);
	}

	DEF_TEST(CubicRootsReal_Linear, reporter) {
	testCubicRootsReal(reporter, "positive slope 3x + 4",
	0, 0, 3, 4,
	{-1.333333333333333});

	testCubicRootsReal(reporter, "negative slope -2x - 8",
	0, 0, -2, -8,
	{-4.});
	}

	DEF_TEST(CubicRootsReal_Constant, reporter) {
	testCubicRootsReal(reporter, "No intersections y = 4",
	0, 0, 0, 4,
	{});

	testCubicRootsReal(reporter, "Infinite solutions y = 0",
	0, 0, 0, 0,
	{0.});
	}

	DEF_TEST(CubicRootsReal_NonFiniteNumbers, reporter) {
	// The Pathops implementation does not check for infinities nor nans in all cases.
	double roots[3] = {0, 0, 0};
	REPORTER_ASSERT(reporter,
	SkCubics::RootsReal(NAN, 1, 2, 3, roots) == 0,
	"Nan A"
	);
	REPORTER_ASSERT(reporter,
	SkCubics::RootsReal(1, NAN, 2, 3, roots) == 0,
	"Nan B"
	);
	REPORTER_ASSERT(reporter,
	SkCubics::RootsReal(1, 2, NAN, 3, roots) == 0,
	"Nan C"
	);
	REPORTER_ASSERT(reporter,
	SkCubics::RootsReal(1, 2, 3, NAN, roots) == 0,
	"Nan D"
	);

	{
	skiatest::ReporterContext subtest(reporter, "oss-fuzz:55419 C and D are large");
	int numRoots = SkCubics::RootsReal(
	-2, 0,
	sk_bit_cast<double>(0xd5422020202020ff), //-5.074559e+102
	sk_bit_cast<double>(0x600fff202020ff20), // 5.362551e+154
	roots);
	REPORTER_ASSERT(reporter, numRoots == 0, "No finite roots expected, got %d", numRoots);
	}
	{
	skiatest::ReporterContext subtest(reporter, "oss-fuzz:55829 A is zero and B is NAN");
	int numRoots = SkCubics::RootsReal(
	0,
	sk_bit_cast<double>(0xffffffffffff2020), //-nan
	sk_bit_cast<double>(0x20202020202020ff), // 6.013470e-154
	sk_bit_cast<double>(0xff20202020202020), //-2.211661e+304
	roots);
	REPORTER_ASSERT(reporter, numRoots == 0, "No finite roots expected, got %d", numRoots);
	}
	}

	static void testCubicValidT(skiatest::Reporter* reporter, std::string name,
	double A, double B, double C, double D,
	SkSpan<const double> expectedRoots) {
	skiatest::ReporterContext subtest(reporter, name);
	// Validate test case
	REPORTER_ASSERT(reporter, expectedRoots.size() <= 3,
	"Invalid test case, up to 3 roots allowed");

	for (size_t i = 0; i < expectedRoots.size(); i++) {
	double x = expectedRoots[i];
	REPORTER_ASSERT(reporter, x >= 0 && x <= 1,
	"Invalid test case root %zu. Roots must be in [0, 1]", i);

	// Ax^3 + Bx^2 + C*x + D should equal 0
	double y = A * x * x * x + B * x * x + C * x + D;
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(y),
	"Invalid test case root %zu. %.16f != 0", i, y);

	if (i > 0) {
	REPORTER_ASSERT(reporter, expectedRoots[i-1] <= expectedRoots[i],
	"Invalid test case root %zu. Roots should be sorted in ascending order", i);
	}
	}

	{
	skiatest::ReporterContext subsubtest(reporter, "Pathops Implementation");
	double roots[3] = {0, 0, 0};
	int rootCount = SkDCubic::RootsValidT(A, B, C, D, roots);
	REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
	"Wrong number of roots returned %zu != %d",
	expectedRoots.size(), rootCount);

	// 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(roots), std::begin(roots) + rootCount);
	for (int i = 0; i < rootCount; i++) {
	if (sk_double_nearly_zero(expectedRoots[i])) {
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
	"0 != %.16f at index %d", roots[i], i);
	} else {
	REPORTER_ASSERT(reporter,
	sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
	"%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
	}
	}
	}
	{
	skiatest::ReporterContext subsubtest(reporter, "SkCubics Analytic Implementation");
	double roots[3] = {0, 0, 0};
	int rootCount = SkCubics::RootsValidT(A, B, C, D, roots);
	REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
	"Wrong number of roots returned %zu != %d",
	expectedRoots.size(), rootCount);

	// 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(roots), std::begin(roots) + rootCount);
	for (int i = 0; i < rootCount; i++) {
	if (sk_double_nearly_zero(expectedRoots[i])) {
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[i]),
	"0 != %.16f at index %d", roots[i], i);
	} else {
	REPORTER_ASSERT(reporter,
	sk_doubles_nearly_equal_ulps(expectedRoots[i], roots[i], 64),
	"%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
	}
	}
	}
	{
	skiatest::ReporterContext subsubtest(reporter, "SkCubics Binary Search Implementation");
	double roots[3] = {0, 0, 0};
	int rootCount = SkCubics::BinarySearchRootsValidT(A, B, C, D, roots);
	REPORTER_ASSERT(reporter, expectedRoots.size() == size_t(rootCount),
	"Wrong number of roots returned %zu != %d", expectedRoots.size(),
	rootCount);

	// 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(roots), std::begin(roots) + rootCount);
	for (int i = 0; i < rootCount; i++) {
	double delta = std::abs(roots[i] - expectedRoots[i]);
	REPORTER_ASSERT(reporter,
	// Binary search is not absolutely accurate all the time, but
	// it should be accurate enough reliably
	delta < 0.000001,
	"%.16f != %.16f at index %d", expectedRoots[i], roots[i], i);
	}
	}
	}

	DEF_TEST(CubicRootsValidT, reporter) {
	// All answers are given with 16 significant digits (max for a double) or as an integer
	// when the answer is exact.
	testCubicValidT(reporter, "three roots 24x^3 - 46x^2 + 29x - 6",
	24, -46, 29, -6,
	{0.5,
	0.6666666666666667,
	0.75});

	testCubicValidT(reporter, "three roots total, two in range 54x^3 - 117x^2 + 45x + 0",
	54, -117, 45, 0,
	{0.0,
	0.5,
	// 5/3 is the other root, but not in [0, 1]
	});

	testCubicValidT(reporter, "one root = 1 10x^3 - 20x^2 - 30x + 40",
	10, -20, -30, 40,
	{1.0});

	testCubicValidT(reporter, "one root = 0 2x^3 - 3x^2 - 4x + 0",
	2, -3, -4, 0,
	{0.0});

	testCubicValidT(reporter, "three roots total, two in range -2x^3 - 3x^2 + 4x + 0",
	-2, -3, 4, 0,
	{ 0.0,
	0.8507810593582122,
	// 0.8507810593582121716220544 from Wolfram Alpha
	});

	// x(x-1) = x^2 - x
	testCubicValidT(reporter, "Two roots at exactly 0 and 1",
	0, 1, -1, 0,
	{0.0, 1.0});

	testCubicValidT(reporter, "Single point has one root",
	0, 0, 0, 0,
	{0.0});
	}

	DEF_TEST(CubicRootsValidT_ClampToZeroAndOne, reporter) {
	{
	// (x + 0.00001)(x - 1.00005), but the answers will be 0 and 1
	double A = 0.;
	double B = 1.;
	double C = -1.00004;
	double D = -0.0000100005;
	double roots[3] = {0, 0, 0};
	int rootCount = SkDCubic::RootsValidT(A, B, C, D, roots);

	REPORTER_ASSERT(reporter, rootCount == 2);
	std::sort(std::begin(roots), std::begin(roots) + rootCount);
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[0]), "%.16f != 0", roots[0]);
	REPORTER_ASSERT(reporter, sk_doubles_nearly_equal_ulps(roots[1], 1), "%.16f != 1", roots[1]);
	}
	{
	// Three very small roots, all of them are nearly equal zero
	// (1 - 10000000000x)(1 - 20000000000x)(1 - 30000000000x)
	// -6000000000000000000000000000000 x^3 + 1100000000000000000000 x^2 - 60000000000 x + 1
	double A = -6.0e30;
	double B = 1.1e21;
	double C = -6.0e10;
	double D = 1;
	double roots[3] = {0, 0, 0};
	int rootCount = SkDCubic::RootsValidT(A, B, C, D, roots);

	REPORTER_ASSERT(reporter, rootCount == 1);
	std::sort(std::begin(roots), std::begin(roots) + rootCount);
	REPORTER_ASSERT(reporter, sk_double_nearly_zero(roots[0]), "%.16f != 0", roots[0]);
	}
	}