DEF_TEST(PathOpsAngleCircle, reporter) {
SkChunkAlloc allocator(4096);
SkOpContour contour;
SkOpGlobalState state(NULL PATH_OPS_DEBUG_PARAMS(&contour));
contour.init(&state, false, false);
for (int index = 0; index < circleDataSetSize; ++index) {
CircleData& data = circleDataSet[index];
for (int idx2 = 0; idx2 < data.fPtCount; ++idx2) {
data.fShortPts[idx2] = data.fPts.fPts[idx2].asSkPoint();
}
switch (data.fPtCount) {
case 2:
contour.addLine(data.fShortPts, &allocator);
break;
case 3:
contour.addQuad(data.fShortPts, &allocator);
break;
case 4:
contour.addCubic(data.fShortPts, &allocator);
break;
}
}
SkOpSegment* first = contour.first();
first->debugAddAngle(0, 1, &allocator);
SkOpSegment* next = first->next();
next->debugAddAngle(0, 1, &allocator);
PathOpsAngleTester::Orderable(*first->debugLastAngle(), *next->debugLastAngle());
}
static void testQuadAngles(skiatest::Reporter* reporter, const SkDQuad& quad1, const SkDQuad& quad2,
int testNo, SkChunkAlloc* allocator) {
SkPoint shortQuads[2][3];
SkOpContour contour;
SkOpGlobalState state(NULL PATH_OPS_DEBUG_PARAMS(&contour));
contour.init(&state, false, false);
makeSegment(&contour, quad1, shortQuads[0], allocator);
makeSegment(&contour, quad1, shortQuads[1], allocator);
SkOpSegment* seg1 = contour.first();
seg1->debugAddAngle(0, 1, allocator);
SkOpSegment* seg2 = seg1->next();
seg2->debugAddAngle(0, 1, allocator);
int realOverlap = PathOpsAngleTester::ConvexHullOverlaps(*seg1->debugLastAngle(),
*seg2->debugLastAngle());
const SkDPoint& origin = quad1[0];
REPORTER_ASSERT(reporter, origin == quad2[0]);
double a1s = atan2(origin.fY - quad1[1].fY, quad1[1].fX - origin.fX);
double a1e = atan2(origin.fY - quad1[2].fY, quad1[2].fX - origin.fX);
double a2s = atan2(origin.fY - quad2[1].fY, quad2[1].fX - origin.fX);
double a2e = atan2(origin.fY - quad2[2].fY, quad2[2].fX - origin.fX);
bool oldSchoolOverlap = radianBetween(a1s, a2s, a1e)
|| radianBetween(a1s, a2e, a1e) || radianBetween(a2s, a1s, a2e)
|| radianBetween(a2s, a1e, a2e);
int overlap = quadHullsOverlap(reporter, quad1, quad2);
bool realMatchesOverlap = realOverlap == overlap || SK_ScalarPI - fabs(a2s - a1s) < 0.002;
if (realOverlap != overlap) {
SkDebugf("\nSK_ScalarPI - fabs(a2s - a1s) = %1.9g\n", SK_ScalarPI - fabs(a2s - a1s));
}
if (!realMatchesOverlap) {
DumpQ(quad1, quad2, testNo);
}
REPORTER_ASSERT(reporter, realMatchesOverlap);
if (oldSchoolOverlap != (overlap < 0)) {
overlap = quadHullsOverlap(reporter, quad1, quad2); // set a breakpoint and debug if assert fires
REPORTER_ASSERT(reporter, oldSchoolOverlap == (overlap < 0));
}
SkDVector v1s = quad1[1] - quad1[0];
SkDVector v1e = quad1[2] - quad1[0];
SkDVector v2s = quad2[1] - quad2[0];
SkDVector v2e = quad2[2] - quad2[0];
double vDir[2] = { v1s.cross(v1e), v2s.cross(v2e) };
bool ray1In2 = v1s.cross(v2s) * vDir[1] <= 0 && v1s.cross(v2e) * vDir[1] >= 0;
bool ray2In1 = v2s.cross(v1s) * vDir[0] <= 0 && v2s.cross(v1e) * vDir[0] >= 0;
if (overlap >= 0) {
// verify that hulls really don't overlap
REPORTER_ASSERT(reporter, !ray1In2);
REPORTER_ASSERT(reporter, !ray2In1);
bool ctrl1In2 = v1e.cross(v2s) * vDir[1] <= 0 && v1e.cross(v2e) * vDir[1] >= 0;
REPORTER_ASSERT(reporter, !ctrl1In2);
bool ctrl2In1 = v2e.cross(v1s) * vDir[0] <= 0 && v2e.cross(v1e) * vDir[0] >= 0;
REPORTER_ASSERT(reporter, !ctrl2In1);
// check answer against reference
bruteForce(reporter, quad1, quad2, overlap > 0);
}
// continue end point rays and see if they intersect the opposite curve
SkDLine rays[] = {{{origin, quad2[2]}}, {{origin, quad1[2]}}};
const SkDQuad* quads[] = {&quad1, &quad2};
SkDVector midSpokes[2];
SkIntersections intersect[2];
double minX, minY, maxX, maxY;
minX = minY = SK_ScalarInfinity;
maxX = maxY = -SK_ScalarInfinity;
double maxWidth = 0;
bool useIntersect = false;
double smallestTs[] = {1, 1};
for (unsigned index = 0; index < SK_ARRAY_COUNT(quads); ++index) {
const SkDQuad& q = *quads[index];
midSpokes[index] = q.ptAtT(0.5) - origin;
minX = SkTMin(SkTMin(SkTMin(minX, origin.fX), q[1].fX), q[2].fX);
minY = SkTMin(SkTMin(SkTMin(minY, origin.fY), q[1].fY), q[2].fY);
maxX = SkTMax(SkTMax(SkTMax(maxX, origin.fX), q[1].fX), q[2].fX);
maxY = SkTMax(SkTMax(SkTMax(maxY, origin.fY), q[1].fY), q[2].fY);
maxWidth = SkTMax(maxWidth, SkTMax(maxX - minX, maxY - minY));
intersect[index].intersectRay(q, rays[index]);
const SkIntersections& i = intersect[index];
REPORTER_ASSERT(reporter, i.used() >= 1);
bool foundZero = false;
double smallT = 1;
for (int idx2 = 0; idx2 < i.used(); ++idx2) {
double t = i[0][idx2];
if (t == 0) {
foundZero = true;
continue;
}
if (smallT > t) {
smallT = t;
}
}
REPORTER_ASSERT(reporter, foundZero == true);
if (smallT == 1) {
continue;
}
SkDVector ray = q.ptAtT(smallT) - origin;
SkDVector end = rays[index][1] - origin;
if (ray.fX * end.fX < 0 || ray.fY * end.fY < 0) {
continue;
}
double rayDist = ray.length();
double endDist = end.length();
double delta = fabs(rayDist - endDist) / maxWidth;
if (delta > 1e-4) {
useIntersect ^= true;
}
smallestTs[index] = smallT;
}
bool firstInside;
if (useIntersect) {
int sIndex = (int) (smallestTs[1] < 1);
REPORTER_ASSERT(reporter, smallestTs[sIndex ^ 1] == 1);
double t = smallestTs[sIndex];
const SkDQuad& q = *quads[sIndex];
SkDVector ray = q.ptAtT(t) - origin;
SkDVector end = rays[sIndex][1] - origin;
double rayDist = ray.length();
double endDist = end.length();
SkDVector mid = q.ptAtT(t / 2) - origin;
double midXray = mid.crossCheck(ray);
if (gPathOpsAngleIdeasVerbose) {
SkDebugf("rayDist>endDist:%d sIndex==0:%d vDir[sIndex]<0:%d midXray<0:%d\n",
rayDist > endDist, sIndex == 0, vDir[sIndex] < 0, midXray < 0);
}
SkASSERT(SkScalarSignAsInt(SkDoubleToScalar(midXray))
== SkScalarSignAsInt(SkDoubleToScalar(vDir[sIndex])));
firstInside = (rayDist > endDist) ^ (sIndex == 0) ^ (vDir[sIndex] < 0);
} else if (overlap >= 0) {
return; // answer has already been determined
} else {
firstInside = checkParallel(reporter, quad1, quad2);
}
if (overlap < 0) {
SkDEBUGCODE(int realEnds =)
PathOpsAngleTester::EndsIntersect(*seg1->debugLastAngle(),
*seg2->debugLastAngle());
SkASSERT(realEnds == (firstInside ? 1 : 0));
}
