/* * Copyright 2012 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "Simplify.h" namespace SimplifyAngleTest { #include "Simplify.cpp" } // end of SimplifyAngleTest namespace #include "Intersection_Tests.h" static const SkPoint lines[][2] = { { { 10, 10}, { 10, 20} }, { { 10, 10}, { 20, 10} }, { { 10, 10}, {-20, 10} }, { { 10, 10}, { 10, -20} }, { { 10, 10}, { 20, 20} }, { { 10, 10}, {-20, -20} }, { { 10, 10}, {-20, 40} }, { { 10, 10}, { 40, -20} } }; static const size_t lineCount = sizeof(lines) / sizeof(lines[0]); static const SkPoint quads[][3] = { {{ 1, 1}, { 2, 2}, { 1, 3}}, // 0 {{ 1, 1}, { 3, 3}, { 1, 5}}, // 1 {{ 1, 1}, { 4, 4}, { 1, 7}}, // 2 {{ 1, 1}, { 5, 5}, { 9, 9}}, // 3 {{ 1, 1}, { 4, 4}, { 7, 1}}, // 4 {{ 1, 1}, { 3, 3}, { 5, 1}}, // 5 {{ 1, 1}, { 2, 2}, { 3, 1}}, // 6 }; static const size_t quadCount = sizeof(quads) / sizeof(quads[0]); static const SkPoint cubics[][4] = { {{ 1, 1}, { 2, 2}, { 2, 3}, { 1, 4}}, {{ 1, 1}, { 3, 3}, { 3, 5}, { 1, 7}}, {{ 1, 1}, { 4, 4}, { 4, 7}, { 1, 10}}, {{ 1, 1}, { 5, 5}, { 8, 8}, { 9, 9}}, {{ 1, 1}, { 4, 4}, { 7, 4}, { 10, 1}}, {{ 1, 1}, { 3, 3}, { 5, 3}, { 7, 1}}, {{ 1, 1}, { 2, 2}, { 3, 2}, { 4, 1}}, }; static const size_t cubicCount = sizeof(cubics) / sizeof(cubics[0]); struct segment { SkPath::Verb verb; SkPoint pts[4]; }; static const segment segmentTest1[] = { {SkPath::kLine_Verb, {{2, 1}, {1, 0} }}, {SkPath::kQuad_Verb, {{2, 1}, {1, 0}, {0, 0}}}, {SkPath::kQuad_Verb, {{2, 1}, {3, 2}, {2, 3}}}, {SkPath::kLine_Verb, {{2, 1}, {3, 2} }}, {SkPath::kMove_Verb } }; static const segment segmentTest2[] = { {SkPath::kLine_Verb, {{1, 0}, {0, 0} }}, {SkPath::kQuad_Verb, {{1, 0}, {1.89897954f, 0.898979485f}, {2.39387703f, 1.59591794f}}}, {SkPath::kLine_Verb, {{1, 0}, {3, 2} }}, {SkPath::kMove_Verb } }; static const segment segmentTest3[] = { {SkPath::kQuad_Verb, {{0, 0}, {2, 0}, {0, 1}}}, {SkPath::kQuad_Verb, {{0, 0}, {1, 0}, {0, 1}}}, {SkPath::kMove_Verb } }; static const segment* segmentTests[] = { segmentTest3, segmentTest2, segmentTest1, }; static const size_t segmentTestCount = sizeof(segmentTests) / sizeof(segmentTests[0]); static void testSegments(bool testFlat) { for (size_t testIndex = 0; testIndex < segmentTestCount; ++testIndex) { const segment* segPtr = segmentTests[testIndex]; SimplifyAngleTest::Angle lesser, greater; int index = 0; do { int next = index + 1; SkTDArray dummy; lesser.set(segPtr[index].pts, segPtr[index].verb, NULL, index, next, dummy); if (segPtr[next].verb == SkPath::kMove_Verb) { break; } greater.set(segPtr[next].pts, segPtr[next].verb, NULL, index, next, dummy); bool result = lesser < greater; SkASSERT(result); index = next; } while (true); } } static void testLines(bool testFlat) { // create angles in a circle SkTDArray angles; SkTDArray angleList; SkTDArray arcTans; size_t x; for (x = 0; x < lineCount; ++x) { SimplifyAngleTest::Angle* angle = angles.append(); SkTDArray dummy; angle->set(lines[x], SkPath::kLine_Verb, 0, x, x + 1, dummy); double arcTan = atan2(lines[x][0].fX - lines[x][1].fX, lines[x][0].fY - lines[x][1].fY); arcTans.push(arcTan); } for (x = 0; x < lineCount; ++x) { angleList.push(&angles[x]); } QSort(angleList.begin(), angleList.end() - 1); bool first = true; bool wrap = false; double base, last; for (size_t x = 0; x < lineCount; ++x) { const SimplifyAngleTest::Angle* angle = angleList[x]; int span = angle->start(); // SkDebugf("%s [%d] %1.9g (%1.9g,%1.9g %1.9g,%1.9g)\n", __FUNCTION__, // span, arcTans[span], lines[span][0].fX, lines[span][0].fY, // lines[span][1].fX, lines[span][1].fY); if (first) { base = last = arcTans[span]; first = false; continue; } if (last < arcTans[span]) { last = arcTans[span]; continue; } if (!wrap) { if (base < arcTans[span]) { SkDebugf("%s !wrap [%d] %g\n", __FUNCTION__, span, arcTans[span]); SkASSERT(0); } last = arcTans[span]; wrap = true; continue; } SkDebugf("%s wrap [%d] %g\n", __FUNCTION__, span, arcTans[span]); SkASSERT(0); } } static void testQuads(bool testFlat) { SkTDArray angles; SkTDArray angleList; size_t x; for (x = 0; x < quadCount; ++x) { SimplifyAngleTest::Angle* angle = angles.append(); SkTDArray dummy; angle->set(quads[x], SkPath::kQuad_Verb, 0, x, x + 1, dummy); } for (x = 0; x < quadCount; ++x) { angleList.push(&angles[x]); } QSort(angleList.begin(), angleList.end() - 1); for (size_t x = 0; x < quadCount; ++x) { *angleList[x] < *angleList[x + 1]; SkASSERT(x == quadCount - 1 || *angleList[x] < *angleList[x + 1]); const SimplifyAngleTest::Angle* angle = angleList[x]; if ((int) x != angle->start()) { SkDebugf("%s [%d] [%d]\n", __FUNCTION__, x, angle->start()); SkASSERT(0); } } } static void testCubics(bool testFlat) { SkTDArray angles; SkTDArray angleList; for (size_t x = 0; x < cubicCount; ++x) { SimplifyAngleTest::Angle* angle = angles.append(); SkTDArray dummy; angle->set(cubics[x], SkPath::kCubic_Verb, 0, x, x + 1, dummy); angleList.push(angle); } QSort(angleList.begin(), angleList.end() - 1); for (size_t x = 0; x < cubicCount; ++x) { const SimplifyAngleTest::Angle* angle = angleList[x]; if ((int) x != angle->start()) { SkDebugf("%s [%d] [%d]\n", __FUNCTION__, x, angle->start()); SkASSERT(0); } } } struct segmentWithT { SkPath::Verb verb; SkPoint pts[4]; double ts[2]; }; static const segmentWithT oneOffTest1[] = { {SkPath::kQuad_Verb, {{391.653534f, 183.286819f}, {391.653534f, 157.724487f}, {405.469604f, 141.372879f}}, {0.62346946335026932, 0.62344389027237135}}, {SkPath::kQuad_Verb, {{399.365234f, 171.695801f}, {399.365234f, 140.337967f}, {375.976227f, 140.337967f}}, {0.31638302676995866, 0.31637992418411398}}, {SkPath::kMove_Verb } }; static const segmentWithT oneOffTest2[] = { {SkPath::kQuad_Verb, {{399.070374f, 151.722f}, {391.101532f, 163.002533f}, {391.101532f, 182.665863f}}, {0.13793711854916513, 0.13790171160614006}}, {SkPath::kQuad_Verb, {{391.653534f, 183.286819f}, {391.653534f, 157.724487f}, {405.469604f, 141.372879f}}, {0.62344389027237135, 0.62346946335026932}}, {SkPath::kMove_Verb } }; static const segmentWithT oneOffTest3[] = { {SkPath::kQuad_Verb, {{399.365234f, 171.695801f}, {399.365234f, 140.337967f}, {375.976227f, 140.337967f}}, {0.31637992418411398, 0.31638302676995866, }}, {SkPath::kQuad_Verb, {{399.070374f, 151.722f}, {391.101532f, 163.002533f}, {391.101532f, 182.665863f}}, {0.13790171160614006, 0.13793711854916513}}, {SkPath::kMove_Verb } }; static const segmentWithT oneOffTest4[] = { {SkPath::kCubic_Verb, {{1,2}, {1,3}, {1,0}, {5,3}}, {0.134792, 0}}, {SkPath::kCubic_Verb, {{0,1}, {3,5}, {2,1}, {3,1}}, {0.134792094, 0}}, {SkPath::kCubic_Verb, {{0,1}, {3,5}, {2,1}, {3,1}}, {0.134792094, 0.551812363}}, {SkPath::kCubic_Verb, {{1,2}, {1,3}, {1,0}, {5,3}}, {0.134792, 0.333333333}}, {SkPath::kMove_Verb } }; static const segmentWithT* oneOffTests[] = { oneOffTest1, oneOffTest2, oneOffTest3, oneOffTest4, }; static const size_t oneOffTestCount = sizeof(oneOffTests) / sizeof(oneOffTests[0]); static void oneOffTest(bool testFlat) { for (size_t testIndex = 0; testIndex < oneOffTestCount; ++testIndex) { const segmentWithT* segPtr = oneOffTests[testIndex]; SimplifyAngleTest::Angle lesser, greater; int index = 0; do { int next = index + 1; SkTDArray dummy; // FIXME lesser.set(segPtr[index].pts, segPtr[index].verb, 0, index, next, dummy); // FIXME: segPtr[index].ts[0], segPtr[index].ts[1]); if (segPtr[next].verb == SkPath::kMove_Verb) { break; } greater.set(segPtr[next].pts, segPtr[next].verb, 0, index, next, dummy); // FIXME: segPtr[next].ts[0], segPtr[next].ts[1]); bool result = lesser < greater; SkASSERT(result); index = next; } while (true); } SkDebugf("%s finished\n", __FUNCTION__); } #if 0 // seems too complicated for this to be useful (didn't finish writing/debugging this) // this (trys to) take a pair of curves, construct segments/spans, and verify that they sort correctly static void oneOffTestNew() { const segmentWithT* segPtr = oneOffTest4; SimplifyAngleTest::Segment segOne, segTwo; segOne.init(segPtr[0].pts, segPtr[0].verb, false, false); segTwo.init(segPtr[1].pts, segPtr[1].verb, false, false); int index = 0; do { int next = index + 1; if (segPtr[index].verb == SkPath::kMove_Verb) { break; } SkPoint sub[4]; (*SegmentSubDivide[segPtr[index].verb])(segPtr[index].pts, segPtr[index].ts[0], segPtr[index].ts[1], sub); if (memcmp(segPtr[index].pts, segPtr[0].pts, sizeof(SkPoint) * (segPtr[index].verb + 1) == 0) { segOne.addT(&segTwo, sub[0], segPtr[index].ts[0]); segOne.addT(&segTwo, sub[segPtr[index].verb], segPtr[index].ts[1]); } else { segTwo.addT(&segOne, sub[0], segPtr[index].ts[0]); segTwo.addT(&v, sub[segPtr[index].verb], segPtr[index].ts[1]); } } while (true); SimplifyAngleTest::Angle lesser, greater; do { int next = index + 1; if (segPtr[next].verb == SkPath::kMove_Verb) { break; } SkPoint one[4], two[4]; bool use1 = memcmp(segPtr[index].pts, segPtr[0].pts, sizeof(SkPoint) * (segPtr[index].verb + 1) == 0; lesser.set(segPtr[index].pts, segPtr[index].verb, use1 ? &segOne : &segTwo, index, next, dummy); use1 = memcmp(segPtr[next].pts, segPtr[0].pts, sizeof(SkPoint) * (segPtr[next].verb + 1) == 0; greater.set(segPtr[next].pts, segPtr[next].verb, use1 ? &segOne : &segTwo, index, next, dummy); bool result = lesser < greater; SkASSERT(result); index = next; } while (true); SkDebugf("%s finished\n", __FUNCTION__); } #endif static void (*tests[])(bool) = { oneOffTest, testSegments, testLines, testQuads, testCubics }; static const size_t testCount = sizeof(tests) / sizeof(tests[0]); static void (*firstTest)(bool) = 0; static bool skipAll = false; void SimplifyAngle_Test() { if (skipAll) { return; } size_t index = 0; if (firstTest) { while (index < testCount && tests[index] != firstTest) { ++index; } } bool firstTestComplete = false; for ( ; index < testCount; ++index) { (*tests[index])(false); // set to true to exercise setFlat firstTestComplete = true; } }