tests/BezierCurveTest.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/private/base/SkFloatingPoint.h"
 #include "include/private/base/SkSpan_impl.h"
 #include "src/base/SkBezierCurves.h"
 #include "src/base/SkQuads.h"
 #include "tests/Test.h"

 #include <algorithm>
 #include <cmath>
 #include <cstddef>
 #include <initializer_list>
 #include <limits>
 #include <set>
 #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 testCubicEvalAtT(skiatest::Reporter* reporter, const std::string& name,
                              SkSpan<const DoublePoint> curveInputs, double t,
                              const DoublePoint& expectedXY) {
     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);

     auto [x, y] = SkBezierCubic::EvalAt(reinterpret_cast<const double*>(curveInputs.data()), t);

     REPORTER_ASSERT(reporter, nearly_equal(expectedXY.x, x),
                     "X wrong %1.16f != %1.16f", expectedXY.x, x);
     REPORTER_ASSERT(reporter, nearly_equal(expectedXY.y, y),
                     "Y wrong %1.16f != %1.16f", expectedXY.y, y);
 }

 DEF_TEST(BezierCubicEvalAt, reporter) {
     testCubicEvalAtT(reporter, "linear curve @0.1234",
                      {{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
                      0.1234,
                      { 0.4192451819200000, 0.4192451819200000 });

     testCubicEvalAtT(reporter, "linear curve @0.2345",
                      {{ 0, 0 }, { 5, 5 }, { 5, 5 }, { 10, 10 }},
                      0.2345,
                      { 2.8215983862500000, 2.8215983862500000 });

     testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.0",
                      {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
                      0.0,
                      { -10, -20 });

     testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.3456",
                      {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
                      0.3456,
                      { -2.503786700800000, -3.31715344793600 });

     testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.5",
                      {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
                      0.5,
                      { 1.75, 0.25 });

     testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.7891",
                      {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
                      0.7891,
                      { 6.158763291450000, 5.938550084434000 });

     testCubicEvalAtT(reporter, "Arbitrary Cubic, t=1.0",
                      {{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
                      1.0,
                      { 3, 13 });
 }

 static void testCubicConvertToPolynomial(skiatest::Reporter* reporter, const std::string& name,
                                          SkSpan<const DoublePoint> curveInputs, bool yValues,
                                          double expectedA, double expectedB,
                                          double expectedC, double expectedD) {
     skiatest::ReporterContext subtest(reporter, name);
     REPORTER_ASSERT(reporter, curveInputs.size() == 4,
                     "Invalid test case. Need 4 points (start, control, control, end)");

     skiatest::ReporterContext subsubtest(reporter, "SkBezierCurve Implementation");
     const double* input = &curveInputs[0].x;
     auto [A, B, C, D] = SkBezierCubic::ConvertToPolynomial(input, yValues);

     REPORTER_ASSERT(reporter, nearly_equal(expectedA, A), "%f != %f", expectedA, A);
     REPORTER_ASSERT(reporter, nearly_equal(expectedB, B), "%f != %f", expectedB, B);
     REPORTER_ASSERT(reporter, nearly_equal(expectedC, C), "%f != %f", expectedC, C);
     REPORTER_ASSERT(reporter, nearly_equal(expectedD, D), "%f != %f", expectedD, D);
 }

 DEF_TEST(BezierCubicToPolynomials, reporter) {
     // See also tests/PathOpsDCubicTest.cpp->SkDCubicPolynomialCoefficients
     testCubicConvertToPolynomial(reporter, "Arbitrary control points X direction",
         {{1, 2}, {-3, 4}, {5, -6}, {7, 8}}, false, /*=yValues*/
         -18, 36, -12, 1
     );
     testCubicConvertToPolynomial(reporter, "Arbitrary control points Y direction",
         {{1, 2}, {-3, 4}, {5, -6}, {7, 8}}, true, /*=yValues*/
         36, -36, 6, 2
     );
 }

 // Since, Roots and EvalAt are separately unit tested, make sure that the parametric pramater t
 // is correctly in range, and checked.
 DEF_TEST(QuadRoots_CheckTRange, reporter) {
     // Pick interesting numbers around 0 and 1.
     const double interestingRoots[] =
             {-1000, -10, -1, -0.1, -0.0001, 0, 0.0001, 0.1, 0.9, 0.9999, 1, 1.0001, 1.1, 10, 1000};

     // Interesting scales to make the quadratic.
     const double interestingScales[] =
             {-1000, -10, -1, -0.1, -0.0001, 0.0001, 0.1, 1, 10, 1000};

     auto outsideTRange = [](double r) {
         return r < 0 || 1 < r;
     };

     auto insideTRange = [&] (double r) {
         return !outsideTRange(r);
     };

     // The original test for AddValidTs (which quad intersect was based on) used 1 float ulp of
     // leeway for comparison. Tighten this up to half a float ulp.
     auto equalAsFloat = [] (double a, double b) {
         // When converted to float, a double will be rounded up to half a float ulp for a double
         // value between two float values.
         return sk_double_to_float(a) == sk_double_to_float(b);
     };

     for (double r1 : interestingRoots) {
         for (double r0 : interestingRoots) {
             for (double s : interestingScales) {
                 // Create a quadratic using the roots r0 and r1.
                 // s(x-r0)(x-r1) = s(x^2 - r0*x - r1*x + r0*r1)
                 const double A = s;
                 // Normally B = -(r0 + r1) but this needs the modified B' = (r0 + r1) / 2.
                 const double B = s * 0.5 * (r0 + r1);
                 const double C = s*r0*r1;

                 float storage[2];
                 // The X coefficients are set to return t's generated by root intersection.
                 // The offset is set to 0, because an arbitrary offset is essentially encoded in C.
                 auto intersections = SkBezierQuad::Intersect(0, -0.5, 0, A, B, C, 0, storage);

                 if (intersections.empty()) {
                     // Either imaginary or both roots are outside [0, 1].
                     REPORTER_ASSERT(reporter,
                                     SkQuads::Discriminant(A, B, C) < 0
                                     || (outsideTRange(r0) && outsideTRange(r1)));
                 } else if (intersections.size() == 1) {
                     // One of the roots is outside [0, 1]
                     REPORTER_ASSERT(reporter, insideTRange(r0) || insideTRange(r1));
                     const double insideRoot = insideTRange(r0) ? r0 : r1;
                     REPORTER_ASSERT(reporter, equalAsFloat(insideRoot, intersections[0]));
                 } else {
                     REPORTER_ASSERT(reporter, intersections.size() == 2);
                     REPORTER_ASSERT(reporter, insideTRange(r0) && insideTRange(r1));
                     auto [smaller, bigger] = std::minmax(intersections[0], intersections[1]);
                     auto [smallerRoot, biggerRoot] = std::minmax(r0, r1);
                     REPORTER_ASSERT(reporter, equalAsFloat(smaller, smallerRoot));
                     REPORTER_ASSERT(reporter, equalAsFloat(bigger, biggerRoot));
                 }
             }
         }
     }

     // Check when A == 0.
     {
         const double A = 0;

         // We need M = 4, so that will be a Kahan style B of -0.5 * M = -2.
         const double B = -2;
         const double C = -1;
         float storage[2];

         // Assume the offset is already encoded in C.
         auto intersections = SkBezierQuad::Intersect(0, -0.5, 0, A, B, C, 0, storage);
         REPORTER_ASSERT(reporter, intersections.size() == 1);
         REPORTER_ASSERT(reporter, intersections[0] == 0.25);
     }
 }

 // Since, Roots and EvalAt are separately unit tested, make sure that the parametric pramater t
 // is correctly in range, and checked.
 DEF_TEST(SkBezierCubic_CheckTRange, reporter) {
     // Pick interesting numbers around 0 and 1.
     const double interestingRoots[] =
             {-10, -5, -2, -1, 0, 0.5, 1, 2, 5, 10};

     // Interesting scales to make the quadratic.
     const double interestingScales[] =
             {-1000, -10, -1, -0.1, -0.0001, 0.0001, 0.1, 1, 10, 1000};

     auto outsideTRange = [](double r) {
         return r < 0 || 1 < r;
     };

     auto insideTRange = [&] (double r) {
         return !outsideTRange(r);
     };

     auto specialEqual = [] (double actual, double test) {
         // At least a floats worth of digits are correct.
         const double errorFactor = std::numeric_limits<float>::epsilon();
         return std::abs(test - actual) <= errorFactor * std::max(std::abs(test), std::abs(actual));
     };

     for (double r2 : interestingRoots) {
         for (double r1 : interestingRoots) {
             for (double r0 : interestingRoots) {
                 for (double s : interestingScales) {
                     // Create a cubic using the roots r0, r1, and r2.
                     // s(x-r0)(x-r1)(x-r2) = s(x^3 - (r0+r1+r2)x^2 + (r0r1+r1r2+r0r2)x - r0r1r2)
                     const double A =  s,
                                  B = -s * (r0+r1+r2),
                                  C =  s * (r0*r1 + r1*r2 + r0*r2),
                                  D = -s * r0 * r1 * r2;

                     // Accumulate all the valid t's.
                     std::set<double> inRangeRoots;
                     for (auto r : {r0, r1, r2}) {
                         if (insideTRange(r)) {
                             inRangeRoots.insert(r);
                         }
                     }

                     float storage[3];
                     // The X coefficients are set to return t's generated by root intersection.
                     // The offset is set to 0, because an arbitrary offset is essentially encoded
                     // in C.
                     auto intersections =
                             SkBezierCubic::Intersect(0, 0, 1, 0, A, B, C, D, 0, storage);

                     size_t correct = 0;
                     for (auto candidate : intersections) {
                         for (auto answer : inRangeRoots) {
                             if (specialEqual(candidate, answer)) {
                                 correct += 1;
                                 break;
                             }
                         }
                     }
                     REPORTER_ASSERT(reporter, correct == intersections.size());
                 }
             }
         }
     }
 }
	/*
	* 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/private/base/SkFloatingPoint.h"
	#include "include/private/base/SkSpan_impl.h"
	#include "src/base/SkBezierCurves.h"
	#include "src/base/SkQuads.h"
	#include "tests/Test.h"

	#include <algorithm>
	#include <cmath>
	#include <cstddef>
	#include <initializer_list>
	#include <limits>
	#include <set>
	#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 testCubicEvalAtT(skiatest::Reporter* reporter, const std::string& name,
	SkSpan<const DoublePoint> curveInputs, double t,
	const DoublePoint& expectedXY) {
	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);

	auto [x, y] = SkBezierCubic::EvalAt(reinterpret_cast<const double*>(curveInputs.data()), t);

	REPORTER_ASSERT(reporter, nearly_equal(expectedXY.x, x),
	"X wrong %1.16f != %1.16f", expectedXY.x, x);
	REPORTER_ASSERT(reporter, nearly_equal(expectedXY.y, y),
	"Y wrong %1.16f != %1.16f", expectedXY.y, y);
	}

	DEF_TEST(BezierCubicEvalAt, reporter) {
	testCubicEvalAtT(reporter, "linear curve @0.1234",
	{{ 0, 0 }, { 0, 0 }, { 10, 10 }, { 10, 10 }},
	0.1234,
	{ 0.4192451819200000, 0.4192451819200000 });

	testCubicEvalAtT(reporter, "linear curve @0.2345",
	{{ 0, 0 }, { 5, 5 }, { 5, 5 }, { 10, 10 }},
	0.2345,
	{ 2.8215983862500000, 2.8215983862500000 });

	testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.0",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.0,
	{ -10, -20 });

	testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.3456",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.3456,
	{ -2.503786700800000, -3.31715344793600 });

	testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.5",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.5,
	{ 1.75, 0.25 });

	testCubicEvalAtT(reporter, "Arbitrary Cubic, t=0.7891",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	0.7891,
	{ 6.158763291450000, 5.938550084434000 });

	testCubicEvalAtT(reporter, "Arbitrary Cubic, t=1.0",
	{{ -10, -20 }, { -7, 5 }, { 14, -2 }, { 3, 13 }},
	1.0,
	{ 3, 13 });
	}

	static void testCubicConvertToPolynomial(skiatest::Reporter* reporter, const std::string& name,
	SkSpan<const DoublePoint> curveInputs, bool yValues,
	double expectedA, double expectedB,
	double expectedC, double expectedD) {
	skiatest::ReporterContext subtest(reporter, name);
	REPORTER_ASSERT(reporter, curveInputs.size() == 4,
	"Invalid test case. Need 4 points (start, control, control, end)");

	skiatest::ReporterContext subsubtest(reporter, "SkBezierCurve Implementation");
	const double* input = &curveInputs[0].x;
	auto [A, B, C, D] = SkBezierCubic::ConvertToPolynomial(input, yValues);

	REPORTER_ASSERT(reporter, nearly_equal(expectedA, A), "%f != %f", expectedA, A);
	REPORTER_ASSERT(reporter, nearly_equal(expectedB, B), "%f != %f", expectedB, B);
	REPORTER_ASSERT(reporter, nearly_equal(expectedC, C), "%f != %f", expectedC, C);
	REPORTER_ASSERT(reporter, nearly_equal(expectedD, D), "%f != %f", expectedD, D);
	}

	DEF_TEST(BezierCubicToPolynomials, reporter) {
	// See also tests/PathOpsDCubicTest.cpp->SkDCubicPolynomialCoefficients
	testCubicConvertToPolynomial(reporter, "Arbitrary control points X direction",
	{{1, 2}, {-3, 4}, {5, -6}, {7, 8}}, false, /=yValues/
	-18, 36, -12, 1
	);
	testCubicConvertToPolynomial(reporter, "Arbitrary control points Y direction",
	{{1, 2}, {-3, 4}, {5, -6}, {7, 8}}, true, /=yValues/
	36, -36, 6, 2
	);
	}

	// Since, Roots and EvalAt are separately unit tested, make sure that the parametric pramater t
	// is correctly in range, and checked.
	DEF_TEST(QuadRoots_CheckTRange, reporter) {
	// Pick interesting numbers around 0 and 1.
	const double interestingRoots[] =
	{-1000, -10, -1, -0.1, -0.0001, 0, 0.0001, 0.1, 0.9, 0.9999, 1, 1.0001, 1.1, 10, 1000};

	// Interesting scales to make the quadratic.
	const double interestingScales[] =
	{-1000, -10, -1, -0.1, -0.0001, 0.0001, 0.1, 1, 10, 1000};

	auto outsideTRange = [](double r) {
	return r < 0 \|\| 1 < r;
	};

	auto insideTRange = [&] (double r) {
	return !outsideTRange(r);
	};

	// The original test for AddValidTs (which quad intersect was based on) used 1 float ulp of
	// leeway for comparison. Tighten this up to half a float ulp.
	auto equalAsFloat = [] (double a, double b) {
	// When converted to float, a double will be rounded up to half a float ulp for a double
	// value between two float values.
	return sk_double_to_float(a) == sk_double_to_float(b);
	};

	for (double r1 : interestingRoots) {
	for (double r0 : interestingRoots) {
	for (double s : interestingScales) {
	// Create a quadratic using the roots r0 and r1.
	// s(x-r0)(x-r1) = s(x^2 - r0x - r1x + r0*r1)
	const double A = s;
	// Normally B = -(r0 + r1) but this needs the modified B' = (r0 + r1) / 2.
	const double B = s * 0.5 * (r0 + r1);
	const double C = sr0r1;

	float storage[2];
	// The X coefficients are set to return t's generated by root intersection.
	// The offset is set to 0, because an arbitrary offset is essentially encoded in C.
	auto intersections = SkBezierQuad::Intersect(0, -0.5, 0, A, B, C, 0, storage);

	if (intersections.empty()) {
	// Either imaginary or both roots are outside [0, 1].
	REPORTER_ASSERT(reporter,
	SkQuads::Discriminant(A, B, C) < 0
	\|\| (outsideTRange(r0) && outsideTRange(r1)));
	} else if (intersections.size() == 1) {
	// One of the roots is outside [0, 1]
	REPORTER_ASSERT(reporter, insideTRange(r0) \|\| insideTRange(r1));
	const double insideRoot = insideTRange(r0) ? r0 : r1;
	REPORTER_ASSERT(reporter, equalAsFloat(insideRoot, intersections[0]));
	} else {
	REPORTER_ASSERT(reporter, intersections.size() == 2);
	REPORTER_ASSERT(reporter, insideTRange(r0) && insideTRange(r1));
	auto [smaller, bigger] = std::minmax(intersections[0], intersections[1]);
	auto [smallerRoot, biggerRoot] = std::minmax(r0, r1);
	REPORTER_ASSERT(reporter, equalAsFloat(smaller, smallerRoot));
	REPORTER_ASSERT(reporter, equalAsFloat(bigger, biggerRoot));
	}
	}
	}
	}

	// Check when A == 0.
	{
	const double A = 0;

	// We need M = 4, so that will be a Kahan style B of -0.5 * M = -2.
	const double B = -2;
	const double C = -1;
	float storage[2];

	// Assume the offset is already encoded in C.
	auto intersections = SkBezierQuad::Intersect(0, -0.5, 0, A, B, C, 0, storage);
	REPORTER_ASSERT(reporter, intersections.size() == 1);
	REPORTER_ASSERT(reporter, intersections[0] == 0.25);
	}
	}

	// Since, Roots and EvalAt are separately unit tested, make sure that the parametric pramater t
	// is correctly in range, and checked.
	DEF_TEST(SkBezierCubic_CheckTRange, reporter) {
	// Pick interesting numbers around 0 and 1.
	const double interestingRoots[] =
	{-10, -5, -2, -1, 0, 0.5, 1, 2, 5, 10};

	// Interesting scales to make the quadratic.
	const double interestingScales[] =
	{-1000, -10, -1, -0.1, -0.0001, 0.0001, 0.1, 1, 10, 1000};

	auto outsideTRange = [](double r) {
	return r < 0 \|\| 1 < r;
	};

	auto insideTRange = [&] (double r) {
	return !outsideTRange(r);
	};

	auto specialEqual = [] (double actual, double test) {
	// At least a floats worth of digits are correct.
	const double errorFactor = std::numeric_limits<float>::epsilon();
	return std::abs(test - actual) <= errorFactor * std::max(std::abs(test), std::abs(actual));
	};

	for (double r2 : interestingRoots) {
	for (double r1 : interestingRoots) {
	for (double r0 : interestingRoots) {
	for (double s : interestingScales) {
	// Create a cubic using the roots r0, r1, and r2.
	// s(x-r0)(x-r1)(x-r2) = s(x^3 - (r0+r1+r2)x^2 + (r0r1+r1r2+r0r2)x - r0r1r2)
	const double A = s,
	B = -s * (r0+r1+r2),
	C = s * (r0r1 + r1r2 + r0*r2),
	D = -s * r0 * r1 * r2;

	// Accumulate all the valid t's.
	std::set<double> inRangeRoots;
	for (auto r : {r0, r1, r2}) {
	if (insideTRange(r)) {
	inRangeRoots.insert(r);
	}
	}

	float storage[3];
	// The X coefficients are set to return t's generated by root intersection.
	// The offset is set to 0, because an arbitrary offset is essentially encoded
	// in C.
	auto intersections =
	SkBezierCubic::Intersect(0, 0, 1, 0, A, B, C, D, 0, storage);

	size_t correct = 0;
	for (auto candidate : intersections) {
	for (auto answer : inRangeRoots) {
	if (specialEqual(candidate, answer)) {
	correct += 1;
	break;
	}
	}
	}
	REPORTER_ASSERT(reporter, correct == intersections.size());
	}
	}
	}
	}
	}