src/third_party/skia/experimental/Intersection/QuarticRoot_Test.cpp - cobalt - Git at Google

 #include "CubicUtilities.h"
 #include "Intersection_Tests.h"
 #include "QuadraticUtilities.h"
 #include "QuarticRoot.h"

 double mulA[] = {-3, -1, 1, 3};
 size_t mulACount = sizeof(mulA) / sizeof(mulA[0]);
 double rootB[] = {-9, -6, -3, -1, 0, 1, 3, 6, 9};
 size_t rootBCount = sizeof(rootB) / sizeof(rootB[0]);
 double rootC[] = {-8, -6, -2, -1, 0, 1, 2, 6, 8};
 size_t rootCCount = sizeof(rootC) / sizeof(rootC[0]);
 double rootD[] = {-7, -4, -1, 0, 1, 2, 5};
 size_t rootDCount = sizeof(rootD) / sizeof(rootD[0]);
 double rootE[] = {-5, -1, 0, 1, 7};
 size_t rootECount = sizeof(rootE) / sizeof(rootE[0]);


 static void quadraticTest(bool limit) {
     // (x - a)(x - b) == x^2 - (a + b)x + ab
     for (size_t aIndex = 0; aIndex < mulACount; ++aIndex) {
         for (size_t bIndex = 0; bIndex < rootBCount; ++bIndex) {
             for (size_t cIndex = 0; cIndex < rootCCount; ++cIndex) {
                 const double A = mulA[aIndex];
                 double B = rootB[bIndex];
                 double C = rootC[cIndex];
                 if (limit) {
                     B = (B - 6) / 12;
                     C = (C - 6) / 12;
                 }
                 const double b = A * (B + C);
                 const double c = A * B * C;
                 double roots[2];
                 const int rootCount = limit ? quadraticRootsValidT(A, b, c, roots)
                     : quadraticRootsReal(A, b, c, roots);
                 int expected;
                 if (limit) {
                     expected = B <= 0 && B >= -1;
                     expected += B != C && C <= 0 && C >= -1;
                 } else {
                     expected = 1 + (B != C);
                 }
                 SkASSERT(rootCount == expected);
                 if (!rootCount) {
                     continue;
                 }
                 SkASSERT(approximately_equal(roots[0], -B)
                         || approximately_equal(roots[0], -C));
                 if (expected > 1) {
                     SkASSERT(!approximately_equal(roots[0], roots[1]));
                     SkASSERT(approximately_equal(roots[1], -B)
                             || approximately_equal(roots[1], -C));
                 }
             }
         }
     }
 }

 static void testOneCubic(bool limit, size_t aIndex, size_t bIndex, size_t cIndex, size_t dIndex) {
     const double A = mulA[aIndex];
     double B = rootB[bIndex];
     double C = rootC[cIndex];
     double D = rootD[dIndex];
     if (limit) {
         B = (B - 6) / 12;
         C = (C - 6) / 12;
         D = (C - 2) / 6;
     }
     const double b = A * (B + C + D);
     const double c = A * (B * C + C * D + B * D);
     const double d = A * B * C * D;
     double roots[3];
     const int rootCount = limit ? cubicRootsValidT(A, b, c, d, roots)
             : cubicRootsReal(A, b, c, d, roots);
     int expected;
     if (limit) {
         expected = B <= 0 && B >= -1;
         expected += B != C && C <= 0 && C >= -1;
         expected += B != D && C != D && D <= 0 && D >= -1;
     } else {
         expected = 1 + (B != C) + (B != D && C != D);
     }
     SkASSERT(rootCount == expected);
     if (!rootCount) {
         return;
     }
     SkASSERT(approximately_equal(roots[0], -B)
             || approximately_equal(roots[0], -C)
             || approximately_equal(roots[0], -D));
     if (expected <= 1) {
         return;
     }
     SkASSERT(!approximately_equal(roots[0], roots[1]));
     SkASSERT(approximately_equal(roots[1], -B)
             || approximately_equal(roots[1], -C)
             || approximately_equal(roots[1], -D));
     if (expected <= 2) {
         return;
     }
     SkASSERT(!approximately_equal(roots[0], roots[2])
             && !approximately_equal(roots[1], roots[2]));
     SkASSERT(approximately_equal(roots[2], -B)
             || approximately_equal(roots[2], -C)
             || approximately_equal(roots[2], -D));
 }

 static void cubicTest(bool limit) {
     // (x - a)(x - b)(x - c) == x^3 - (a + b + c)x^2 + (ab + bc + ac)x - abc
     for (size_t aIndex = 0; aIndex < mulACount; ++aIndex) {
         for (size_t bIndex = 0; bIndex < rootBCount; ++bIndex) {
             for (size_t cIndex = 0; cIndex < rootCCount; ++cIndex) {
                 for (size_t dIndex = 0; dIndex < rootDCount; ++dIndex) {
                     testOneCubic(limit, aIndex, bIndex, cIndex, dIndex);
                 }
             }
         }
     }
 }

 static void testOneQuartic(size_t aIndex, size_t bIndex, size_t cIndex, size_t dIndex,
         size_t eIndex) {
     const double A = mulA[aIndex];
     const double B = rootB[bIndex];
     const double C = rootC[cIndex];
     const double D = rootD[dIndex];
     const double E = rootE[eIndex];
     const double b = A * (B + C + D + E);
     const double c = A * (B * C + C * D + B * D + B * E + C * E + D * E);
     const double d = A * (B * C * D + B * C * E + B * D * E + C * D * E);
     const double e = A * B * C * D * E;
     double roots[4];
     bool oneHint = approximately_zero(A + b + c + d + e);
     int rootCount = reducedQuarticRoots(A, b, c, d, e, oneHint, roots);
     if (rootCount < 0) {
         rootCount = quarticRootsReal(0, A, b, c, d, e, roots);
     }
     const int expected = 1 + (B != C) + (B != D && C != D) + (B != E && C != E && D != E);
     SkASSERT(rootCount == expected);
     SkASSERT(AlmostEqualUlps(roots[0], -B)
             || AlmostEqualUlps(roots[0], -C)
             || AlmostEqualUlps(roots[0], -D)
             || AlmostEqualUlps(roots[0], -E));
     if (expected <= 1) {
         return;
     }
     SkASSERT(!AlmostEqualUlps(roots[0], roots[1]));
     SkASSERT(AlmostEqualUlps(roots[1], -B)
             || AlmostEqualUlps(roots[1], -C)
             || AlmostEqualUlps(roots[1], -D)
             || AlmostEqualUlps(roots[1], -E));
     if (expected <= 2) {
         return;
     }
     SkASSERT(!AlmostEqualUlps(roots[0], roots[2])
             && !AlmostEqualUlps(roots[1], roots[2]));
     SkASSERT(AlmostEqualUlps(roots[2], -B)
             || AlmostEqualUlps(roots[2], -C)
             || AlmostEqualUlps(roots[2], -D)
             || AlmostEqualUlps(roots[2], -E));
     if (expected <= 3) {
         return;
     }
     SkASSERT(!AlmostEqualUlps(roots[0], roots[3])
             && !AlmostEqualUlps(roots[1], roots[3])
             && !AlmostEqualUlps(roots[2], roots[3]));
     SkASSERT(AlmostEqualUlps(roots[3], -B)
             || AlmostEqualUlps(roots[3], -C)
             || AlmostEqualUlps(roots[3], -D)
             || AlmostEqualUlps(roots[3], -E));
 }

 static void quarticTest() {
     // (x - a)(x - b)(x - c)(x - d) == x^4 - (a + b + c + d)x^3
     //   + (ab + bc + cd + ac + bd + cd)x^2 - (abc + bcd + abd + acd) * x + abcd
     for (size_t aIndex = 0; aIndex < mulACount; ++aIndex) {
         for (size_t bIndex = 0; bIndex < rootBCount; ++bIndex) {
             for (size_t cIndex = 0; cIndex < rootCCount; ++cIndex) {
                 for (size_t dIndex = 0; dIndex < rootDCount; ++dIndex) {
                     for (size_t eIndex = 0; eIndex < rootECount; ++eIndex) {
                         testOneQuartic(aIndex, bIndex, cIndex, dIndex, eIndex);
                     }
                 }
             }
         }
     }
 }

 void QuarticRoot_Test() {
     testOneCubic(false, 0, 5, 5, 4);
     testOneQuartic(0, 0, 2, 4, 3);
     quadraticTest(true);
     quadraticTest(false);
     cubicTest(true);
     cubicTest(false);
     quarticTest();
 }
	#include "CubicUtilities.h"
	#include "Intersection_Tests.h"
	#include "QuadraticUtilities.h"
	#include "QuarticRoot.h"

	double mulA[] = {-3, -1, 1, 3};
	size_t mulACount = sizeof(mulA) / sizeof(mulA[0]);
	double rootB[] = {-9, -6, -3, -1, 0, 1, 3, 6, 9};
	size_t rootBCount = sizeof(rootB) / sizeof(rootB[0]);
	double rootC[] = {-8, -6, -2, -1, 0, 1, 2, 6, 8};
	size_t rootCCount = sizeof(rootC) / sizeof(rootC[0]);
	double rootD[] = {-7, -4, -1, 0, 1, 2, 5};
	size_t rootDCount = sizeof(rootD) / sizeof(rootD[0]);
	double rootE[] = {-5, -1, 0, 1, 7};
	size_t rootECount = sizeof(rootE) / sizeof(rootE[0]);


	static void quadraticTest(bool limit) {
	// (x - a)(x - b) == x^2 - (a + b)x + ab
	for (size_t aIndex = 0; aIndex < mulACount; ++aIndex) {
	for (size_t bIndex = 0; bIndex < rootBCount; ++bIndex) {
	for (size_t cIndex = 0; cIndex < rootCCount; ++cIndex) {
	const double A = mulA[aIndex];
	double B = rootB[bIndex];
	double C = rootC[cIndex];
	if (limit) {
	B = (B - 6) / 12;
	C = (C - 6) / 12;
	}
	const double b = A * (B + C);
	const double c = A * B * C;
	double roots[2];
	const int rootCount = limit ? quadraticRootsValidT(A, b, c, roots)
	: quadraticRootsReal(A, b, c, roots);
	int expected;
	if (limit) {
	expected = B <= 0 && B >= -1;
	expected += B != C && C <= 0 && C >= -1;
	} else {
	expected = 1 + (B != C);
	}
	SkASSERT(rootCount == expected);
	if (!rootCount) {
	continue;
	}
	SkASSERT(approximately_equal(roots[0], -B)
	\|\| approximately_equal(roots[0], -C));
	if (expected > 1) {
	SkASSERT(!approximately_equal(roots[0], roots[1]));
	SkASSERT(approximately_equal(roots[1], -B)
	\|\| approximately_equal(roots[1], -C));
	}
	}
	}
	}
	}

	static void testOneCubic(bool limit, size_t aIndex, size_t bIndex, size_t cIndex, size_t dIndex) {
	const double A = mulA[aIndex];
	double B = rootB[bIndex];
	double C = rootC[cIndex];
	double D = rootD[dIndex];
	if (limit) {
	B = (B - 6) / 12;
	C = (C - 6) / 12;
	D = (C - 2) / 6;
	}
	const double b = A * (B + C + D);
	const double c = A * (B * C + C * D + B * D);
	const double d = A * B * C * D;
	double roots[3];
	const int rootCount = limit ? cubicRootsValidT(A, b, c, d, roots)
	: cubicRootsReal(A, b, c, d, roots);
	int expected;
	if (limit) {
	expected = B <= 0 && B >= -1;
	expected += B != C && C <= 0 && C >= -1;
	expected += B != D && C != D && D <= 0 && D >= -1;
	} else {
	expected = 1 + (B != C) + (B != D && C != D);
	}
	SkASSERT(rootCount == expected);
	if (!rootCount) {
	return;
	}
	SkASSERT(approximately_equal(roots[0], -B)
	\|\| approximately_equal(roots[0], -C)
	\|\| approximately_equal(roots[0], -D));
	if (expected <= 1) {
	return;
	}
	SkASSERT(!approximately_equal(roots[0], roots[1]));
	SkASSERT(approximately_equal(roots[1], -B)
	\|\| approximately_equal(roots[1], -C)
	\|\| approximately_equal(roots[1], -D));
	if (expected <= 2) {
	return;
	}
	SkASSERT(!approximately_equal(roots[0], roots[2])
	&& !approximately_equal(roots[1], roots[2]));
	SkASSERT(approximately_equal(roots[2], -B)
	\|\| approximately_equal(roots[2], -C)
	\|\| approximately_equal(roots[2], -D));
	}

	static void cubicTest(bool limit) {
	// (x - a)(x - b)(x - c) == x^3 - (a + b + c)x^2 + (ab + bc + ac)x - abc
	for (size_t aIndex = 0; aIndex < mulACount; ++aIndex) {
	for (size_t bIndex = 0; bIndex < rootBCount; ++bIndex) {
	for (size_t cIndex = 0; cIndex < rootCCount; ++cIndex) {
	for (size_t dIndex = 0; dIndex < rootDCount; ++dIndex) {
	testOneCubic(limit, aIndex, bIndex, cIndex, dIndex);
	}
	}
	}
	}
	}

	static void testOneQuartic(size_t aIndex, size_t bIndex, size_t cIndex, size_t dIndex,
	size_t eIndex) {
	const double A = mulA[aIndex];
	const double B = rootB[bIndex];
	const double C = rootC[cIndex];
	const double D = rootD[dIndex];
	const double E = rootE[eIndex];
	const double b = A * (B + C + D + E);
	const double c = A * (B * C + C * D + B * D + B * E + C * E + D * E);
	const double d = A * (B * C * D + B * C * E + B * D * E + C * D * E);
	const double e = A * B * C * D * E;
	double roots[4];
	bool oneHint = approximately_zero(A + b + c + d + e);
	int rootCount = reducedQuarticRoots(A, b, c, d, e, oneHint, roots);
	if (rootCount < 0) {
	rootCount = quarticRootsReal(0, A, b, c, d, e, roots);
	}
	const int expected = 1 + (B != C) + (B != D && C != D) + (B != E && C != E && D != E);
	SkASSERT(rootCount == expected);
	SkASSERT(AlmostEqualUlps(roots[0], -B)
	\|\| AlmostEqualUlps(roots[0], -C)
	\|\| AlmostEqualUlps(roots[0], -D)
	\|\| AlmostEqualUlps(roots[0], -E));
	if (expected <= 1) {
	return;
	}
	SkASSERT(!AlmostEqualUlps(roots[0], roots[1]));
	SkASSERT(AlmostEqualUlps(roots[1], -B)
	\|\| AlmostEqualUlps(roots[1], -C)
	\|\| AlmostEqualUlps(roots[1], -D)
	\|\| AlmostEqualUlps(roots[1], -E));
	if (expected <= 2) {
	return;
	}
	SkASSERT(!AlmostEqualUlps(roots[0], roots[2])
	&& !AlmostEqualUlps(roots[1], roots[2]));
	SkASSERT(AlmostEqualUlps(roots[2], -B)
	\|\| AlmostEqualUlps(roots[2], -C)
	\|\| AlmostEqualUlps(roots[2], -D)
	\|\| AlmostEqualUlps(roots[2], -E));
	if (expected <= 3) {
	return;
	}
	SkASSERT(!AlmostEqualUlps(roots[0], roots[3])
	&& !AlmostEqualUlps(roots[1], roots[3])
	&& !AlmostEqualUlps(roots[2], roots[3]));
	SkASSERT(AlmostEqualUlps(roots[3], -B)
	\|\| AlmostEqualUlps(roots[3], -C)
	\|\| AlmostEqualUlps(roots[3], -D)
	\|\| AlmostEqualUlps(roots[3], -E));
	}

	static void quarticTest() {
	// (x - a)(x - b)(x - c)(x - d) == x^4 - (a + b + c + d)x^3
	// + (ab + bc + cd + ac + bd + cd)x^2 - (abc + bcd + abd + acd) * x + abcd
	for (size_t aIndex = 0; aIndex < mulACount; ++aIndex) {
	for (size_t bIndex = 0; bIndex < rootBCount; ++bIndex) {
	for (size_t cIndex = 0; cIndex < rootCCount; ++cIndex) {
	for (size_t dIndex = 0; dIndex < rootDCount; ++dIndex) {
	for (size_t eIndex = 0; eIndex < rootECount; ++eIndex) {
	testOneQuartic(aIndex, bIndex, cIndex, dIndex, eIndex);
	}
	}
	}
	}
	}
	}

	void QuarticRoot_Test() {
	testOneCubic(false, 0, 5, 5, 4);
	testOneQuartic(0, 0, 2, 4, 3);
	quadraticTest(true);
	quadraticTest(false);
	cubicTest(true);
	cubicTest(false);
	quarticTest();
	}