/* * Copyright 2013 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "SkOpSegment.h" #include "SkTArray.h" #include "Test.h" static const SkPoint cubics[][4] = { /* 0 */ {{0, 1}, {2, 6}, {4, 2}, {5, 3}}, /* 1 */ {{10, 234}, {10, 229.581726f}, {13.5817204f, 226}, {18, 226}}, /* 2 */ {{132, 11419}, {130.89543151855469f, 11419}, {130, 11418.1044921875f}, {130, 11417}}, /* 3 */ {{130.04275512695312f, 11417.4130859375f}, {130.23307800292969f, 11418.3193359375f}, {131.03709411621094f, 11419}, {132, 11419}}, /* 4 */ {{0,1}, {0,5}, {4,1}, {6,4}}, /* 5 */ {{1,5}, {4,6}, {1,0}, {4,0}}, /* 6 */ {{0,1}, {0,4}, {5,1}, {6,4}}, /* 7 */ {{0,1}, {1,2}, {1,0}, {6,1}}, /* 8 */ {{0,3}, {0,1}, {2,0}, {1,0}}, /* 9 */ {{189,7}, {189,5.3431458473205566f}, {190.3431396484375f,4}, {192,4}}, /* 10 */ {{0,1}, {1,3}, {1,0}, {6,4}}, /* 11 */ {{0,1}, {2,3}, {2,1}, {4,3}}, /* 12 */ {{1,2}, {3,4}, {1,0}, {3,2}}, /* 13 */ {{0,1}, {4,6}, {4,3}, {5,4}}, /* 14 */ {{806,11419}, {806.962890625f,11419}, {807.76690673828125f,11418.3193359375f}, {807.957275390625f,11417.4130859375f}}, /* 15 */ {{808,11417}, {808,11418.1044921875f}, {807.10455322265625f,11419}, {806,11419}}, /* 16 */ {{132,11419}, {130.89543151855469f,11419}, {130,11418.1044921875f}, {130,11417}}, /* 17 */ {{130.04275512695312f,11417.4130859375f}, {130.23312377929687f,11418.3193359375f}, {131.03707885742187f,11419}, {132,11419}}, }; static const SkPoint quads[][3] = { /* 0 */ {{12.3423996f, 228.342407f}, {10, 230.686295f}, {10, 234}}, /* 1 */ {{304.24319458007812f,591.75677490234375f}, {306,593.51470947265625f}, {306,596}}, /* 2 */ {{0,0}, {3,1}, {0,3}}, /* 3 */ {{0,1}, {3,1}, {0,2}}, }; static const SkPoint lines[][2] = { /* 0 */ {{6, 2}, {2, 4}}, /* 1 */ {{306,617}, {306,590}}, /* 2 */ {{306,596}, {306,617}}, /* 3 */ {{6,4}, {0,1}}, /* 4 */ {{6,1}, {0,1}}, /* 5 */ {{1,0}, {0,3}}, /* 6 */ {{246,4}, {189,4}}, /* 7 */ {{192,4}, {243,4}}, /* 8 */ {{4,3}, {0,1}}, /* 9 */ {{3,2}, {1,2}}, /* 10 */ {{6,4}, {3,4}}, }; struct SortSet { const SkPoint* ptData; int ptCount; double tStart; double tEnd; SkPoint endPt; }; static const SortSet set1[] = { {cubics[0], 4, 0.66666987081928919, 0.875, {0, 0}}, {lines[0], 2, 0.574070336, 0.388888889, {0, 0}}, {cubics[0], 4, 0.66666987081928919, 0.4050371120499307, {0, 0}}, {lines[0], 2, 0.574070336, 0.9140625, {0, 0}}, }; static const SortSet set1a[] = { {cubics[0], 4, 0.666666667, 0.405037112, {4.58007812f,2.83203125f}}, {lines[0], 2, 0.574074074, 0.9140625, {4.44444466f,2.77777767f}}, }; static const SortSet set2[] = { {cubics[0], 4, 0.666666667, 0.875, {0, 0}}, {lines[0], 2, 0.574074074, 0.388888889, {0, 0}}, {cubics[0], 4, 0.666666667, 0.405037112, {0, 0}}, {lines[0], 2, 0.574074074, 0.9140625, {0, 0}}, }; static const SortSet set3[] = { {cubics[1], 4, 0, 1, {0, 0}}, {quads[0], 3, 1, 0, {0, 0}}, }; static const SortSet set4[] = { {cubics[2], 4, 0.812114222, 1, {0, 0}}, {cubics[3], 4, 0.0684734759, 0, {0, 0}}, }; static const SortSet set5[] = { {lines[1], 2, 0.777777778, 1, {0, 0}}, {quads[1], 3, 1, 4.34137342e-06, {0, 0}}, {lines[2], 2, 0, 1, {0, 0}}, }; static const SortSet set5a[] = { {lines[1], 2, 0.777777778, 1, {306,590}}, {quads[1], 3, 1, 4.34137342e-06, {304.243195f,591.756775f}}, {lines[2], 2, 0, 1, {306,617}}, }; static const SortSet set6[] = { {lines[3], 2, 0.407407407, 0.554627832, {0, 0}}, {cubics[4], 4, 0.666666667, 0.548022446, {0, 0}}, {lines[3], 2, 0.407407407, 0, {0, 0}}, {cubics[4], 4, 0.666666667, 1, {0, 0}}, }; static const SortSet set6a[] = { {lines[3], 2, 0.407407407, 0.554627832, {2.6722331f,2.33611655f}}, {cubics[4], 4, 0.666666667, 0.548022446, {2.61642241f,2.83718514f}}, {lines[3], 2, 0.407407407, 0, {6,4}}, {cubics[4], 4, 0.666666667, 1, {6,4}}, }; static const SortSet set7[] = { {cubics[5], 4, 0.545233342, 0.545454545, {0, 0}}, {cubics[6], 4, 0.484938134, 0.484805744, {0, 0}}, {cubics[5], 4, 0.545233342, 0, {0, 0}}, {cubics[6], 4, 0.484938134, 0.545454545, {0, 0}}, }; static const SortSet set8[] = { {cubics[7], 4, 0.5, 0.522986744, {0, 0}}, {lines[4], 2, 0.75, 1, {0, 0}}, {cubics[7], 4, 0.5, 0, {0, 0}}, {lines[4], 2, 0.75, 0.737654321, {0, 0}}, }; static const SortSet set8a[] = { {cubics[7], 4, 0.5, 0.522986744, {1.60668361f,0.965592742f}}, {lines[4], 2, 0.75, 1, {0,1}}, {cubics[7], 4, 0.5, 0, {0,1}}, {lines[4], 2, 0.75, 0.737654321, {1.57407403f,1}}, }; static const SortSet set9[] = { {cubics[8], 4, 0.4, 1, {0, 0}}, {lines[5], 2, 0.36, 0, {0, 0}}, {cubics[8], 4, 0.4, 0.394675838, {0, 0}}, {lines[5], 2, 0.36, 0.363999782, {0, 0}}, }; static const SortSet set10[] = { {lines[6], 2, 0.947368421, 1, {0, 0}}, {cubics[9], 4, 1, 0.500000357, {0, 0}}, {lines[7], 2, 0, 1, {0, 0}}, }; static const SortSet set11[] = { {lines[3], 2, 0.75, 1, {0, 0}}, {cubics[10], 4, 0.5, 0.228744269, {0, 0}}, {lines[3], 2, 0.75, 0.627112191, {0, 0}}, {cubics[10], 4, 0.5, 0.6339746, {0, 0}}, }; static const SortSet set12[] = { {cubics[12], 4, 0.5, 1, {0, 0}}, {lines[8], 2, 0.5, 1, {0, 0}}, {cubics[11], 4, 0.5, 0, {0, 0}}, {lines[9], 2, 0.5, 1, {0, 0}}, {cubics[12], 4, 0.5, 0, {0, 0}}, {lines[8], 2, 0.5, 0, {0, 0}}, {cubics[11], 4, 0.5, 1, {0, 0}}, {lines[9], 2, 0.5, 0, {0, 0}}, }; static const SortSet set13[] = { {cubics[13], 4, 0.5, 0.400631046, {0, 0}}, {lines[10], 2, 0.791666667, 0.928, {0, 0}}, {lines[10], 2, 0.791666667, 0.333333333, {0, 0}}, {cubics[13], 4, 0.5, 0.866666667, {0, 0}}, }; static const SortSet set14[] = { {quads[2], 3, 0.5, 0.310102051, {0, 0}}, {quads[3], 3, 0.5, 0.2, {0, 0}}, {quads[3], 3, 0.5, 0.770156212, {0, 0}}, {quads[2], 3, 0.5, 0.7, {0, 0}}, }; static const SortSet set15[] = { {cubics[14], 4, 0.93081374, 1, {0, 0}}, {cubics[15], 4, 0.188518131, 0, {0, 0}}, {cubics[14], 4, 0.93081374, 0, {0, 0}}, }; static const SortSet set16[] = { {cubics[17], 4, 0.0682619216, 0, {130.042755f,11417.4131f}}, {cubics[16], 4, 0.812302088, 1, {130,11417}}, {cubics[17], 4, 0.0682619216, 1, {132,11419}}, }; struct SortSetTests { const char* name; const SortSet* set; size_t count; SkPoint startPt; }; #define TEST_ENTRY(name) #name, name, SK_ARRAY_COUNT(name) static const SortSetTests tests[] = { { TEST_ENTRY(set16), {130.090179f,11417.5957f} }, // { TEST_ENTRY(set15), {0, 0}}, { TEST_ENTRY(set14), {0, 0}}, { TEST_ENTRY(set13), {0, 0}}, { TEST_ENTRY(set12), {0, 0}}, { TEST_ENTRY(set11), {0, 0}}, { TEST_ENTRY(set10), {0, 0}}, { TEST_ENTRY(set9), {0, 0}}, { TEST_ENTRY(set6a), {3.55555558f,2.77777767f} }, { TEST_ENTRY(set8a), {1.5f,1} }, { TEST_ENTRY(set8), {0, 0}}, { TEST_ENTRY(set7), {0, 0}}, { TEST_ENTRY(set6a), {3.55555558f,2.77777767f} }, { TEST_ENTRY(set6), {0, 0}}, { TEST_ENTRY(set5a), {306,596} }, { TEST_ENTRY(set5), {0, 0}}, // { TEST_ENTRY(set4), {0, 0}}, { TEST_ENTRY(set3), {0, 0}}, { TEST_ENTRY(set2), {0, 0}}, // { TEST_ENTRY(set1a), {3.70370364f,3.14814806f} }, { TEST_ENTRY(set1), {0, 0}}, }; #undef TEST_ENTRY static void setup(const SortSet* set, const size_t idx, SkOpSegment* seg, int* ts, const SkPoint& startPt) { SkPoint start, end; const SkPoint* data = set[idx].ptData; bool useIntersectPt = startPt.fX != 0 || startPt.fY != 0; if (useIntersectPt) { start = startPt; end = set[idx].endPt; } switch(set[idx].ptCount) { case 2: { seg->addLine(data, false, false); SkDLine dLine; dLine.set(set[idx].ptData); if (useIntersectPt) { break; } start = dLine.xyAtT(set[idx].tStart).asSkPoint(); end = dLine.xyAtT(set[idx].tEnd).asSkPoint(); } break; case 3: { seg->addQuad(data, false, false); SkDQuad dQuad; dQuad.set(set[idx].ptData); if (useIntersectPt) { break; } start = dQuad.xyAtT(set[idx].tStart).asSkPoint(); end = dQuad.xyAtT(set[idx].tEnd).asSkPoint(); } break; case 4: { seg->addCubic(data, false, false); SkDCubic dCubic; dCubic.set(set[idx].ptData); if (useIntersectPt) { break; } start = dCubic.xyAtT(set[idx].tStart).asSkPoint(); end = dCubic.xyAtT(set[idx].tEnd).asSkPoint(); } break; } double tStart = set[idx].tStart; double tEnd = set[idx].tEnd; seg->addT(NULL, start, tStart); seg->addT(NULL, end, tEnd); if (tStart != 0 && tEnd != 0) { seg->addT(NULL, set[idx].ptData[0], 0); } if (tStart != 1 && tEnd != 1) { seg->addT(NULL, set[idx].ptData[set[idx].ptCount - 1], 1); } int tIndex = 0; ts[0] = 0; ts[1] = 1; do { if (seg->t(tIndex) == set[idx].tStart) { ts[0] = tIndex; } if (seg->t(tIndex) == set[idx].tEnd) { ts[1] = tIndex; } if (seg->t(tIndex) >= 1) { break; } } while (++tIndex); } static void PathOpsAngleTest(skiatest::Reporter* reporter) { for (size_t index = 0; index < SK_ARRAY_COUNT(tests); ++index) { const SortSetTests& test = tests[index]; SkTDArray angles; bool unsortable = false; bool unorderable = false; SkTArray segs; for (size_t idx = 0; idx < test.count; ++idx) { int ts[2]; const SortSet* set = test.set; SkOpSegment& seg = segs.push_back(); setup(set, idx, &seg, ts, test.startPt); SkOpAngle* angle = angles.append(); angle->set(&seg, ts[0], ts[1]); #if DEBUG_ANGLE angle->setID(idx); #endif if (angle->unsortable()) { #if DEBUG_ANGLE SkDebugf("%s test[%s]: angle[%d] unsortable\n", __FUNCTION__, test.name, idx); #endif unsortable = true; } if (angle->unorderable()) { #if DEBUG_ANGLE SkDebugf("%s test[%s]: angle[%d] unorderable\n", __FUNCTION__, test.name, idx); #endif unorderable = true; } reporter->bumpTestCount(); } if (unsortable || unorderable) { continue; } #if DEBUG_ANGLE SkDebugf("%s test[%s]\n", __FUNCTION__, test.name); #endif for (size_t idxL = 0; idxL < test.count; ++idxL) { const SkOpAngle& first = angles[idxL]; for (size_t idxG = 0; idxG < test.count; ++idxG) { if (idxL == idxG) { continue; } const SkOpAngle& second = angles[idxG]; bool compare = first < second; if (idxL < idxG) { if (!compare) { SkDebugf("%s test[%s]: first[%d] > second[%d]\n", __FUNCTION__, test.name, idxL, idxG); compare = first < second; } REPORTER_ASSERT(reporter, compare); } else { SkASSERT(idxL > idxG); if (compare) { SkDebugf("%s test[%s]: first[%d] < second[%d]\n", __FUNCTION__, test.name, idxL, idxG); compare = first < second; } REPORTER_ASSERT(reporter, !compare); } compare = second < first; if (idxL < idxG) { if (compare) { SkDebugf("%s test[%s]: second[%d] < first[%d]\n", __FUNCTION__, test.name, idxL, idxG); compare = second < first; } REPORTER_ASSERT(reporter, !compare); } else { SkASSERT(idxL > idxG); if (!compare) { SkDebugf("%s test[%s]: second[%d] > first[%d]\n", __FUNCTION__, test.name, idxL, idxG); compare = second < first; } REPORTER_ASSERT(reporter, compare); } } } reporter->bumpTestCount(); } } #if 0 static int find_slop(double x, double y, double rx, double ry) { int slopBits = 0; bool less1, less2; double absX = fabs(x); double absY = fabs(y); double length = absX < absY ? absX / 2 + absY : absX + absY / 2; int exponent; (void) frexp(length, &exponent); double epsilon = ldexp(FLT_EPSILON, exponent); do { // get the length as the larger plus half the smaller (both same signs) // find the ulps of the length // compute the offsets from there double xSlop = epsilon * slopBits; double ySlop = x * y < 0 ? -xSlop : xSlop; // OPTIMIZATION: use copysign / _copysign ? double x1 = x - xSlop; double y1 = y + ySlop; double x_ry1 = x1 * ry; double rx_y1 = rx * y1; less1 = x_ry1 < rx_y1; double x2 = x + xSlop; double y2 = y - ySlop; double x_ry2 = x2 * ry; double rx_y2 = rx * y2; less2 = x_ry2 < rx_y2; } while (less1 == less2 && ++slopBits); return slopBits; } // from http://stackoverflow.com/questions/1427422/cheap-algorithm-to-find-measure-of-angle-between-vectors static double diamond_angle(double y, double x) { if (y >= 0) return (x >= 0 ? y/(x+y) : 1-x/(-x+y)); else return (x < 0 ? 2-y/(-x-y) : 3+x/(x-y)); } static const double slopTests[][4] = { // x y rx ry {-0.058554756452593892, -0.18804585843827226, -0.018568569646021160, -0.059615294434479438}, {-0.0013717412948608398, 0.0041152238845825195, -0.00045837944195925573, 0.0013753175735478074}, {-2.1033774145221198, -1.4046019261273715e-008, -0.70062688352066704, -1.2706324683777995e-008}, }; static void PathOpsAngleFindSlop(skiatest::Reporter* reporter) { for (size_t index = 0; index < SK_ARRAY_COUNT(slopTests); ++index) { const double* slopTest = slopTests[index]; double x = slopTest[0]; double y = slopTest[1]; double rx = slopTest[2]; double ry = slopTest[3]; SkDebugf("%s xy %d=%d\n", __FUNCTION__, (int) index, find_slop(x, y, rx, ry)); SkDebugf("%s rxy %d=%d\n", __FUNCTION__, (int) index, find_slop(rx, ry, x, y)); double angle = diamond_angle(y, x); double rAngle = diamond_angle(ry, rx); double diff = fabs(angle - rAngle); SkDebugf("%s diamond xy=%1.9g rxy=%1.9g diff=%1.9g factor=%d\n", __FUNCTION__, angle, rAngle, diff, (int) (diff / FLT_EPSILON)); } } #endif #include "TestClassDef.h" DEFINE_TESTCLASS_SHORT(PathOpsAngleTest) // DEFINE_TESTCLASS_SHORT(PathOpsAngleFindSlop)