public void Test_FaceUVtoXYZ()
{
// Check that each face appears exactly once.
S2Point sum = S2Point.Empty;
for (int face = 0; face < 6; ++face)
{
S2Point center = S2.FaceUVtoXYZ(face, 0, 0);
Assert.Equal(S2.GetNorm(face), center);
Assert.Equal(1, Math.Abs(center[center.LargestAbsComponent()]));
sum += center.Fabs();
}
Assert.Equal(sum, new S2Point(2, 2, 2));
// Check that each face has a right-handed coordinate system.
for (int face = 0; face < 6; ++face)
{
Assert.Equal(1, S2.GetUAxis(face).CrossProd(S2.GetVAxis(face))
.DotProd(S2.FaceUVtoXYZ(face, 0, 0)));
}
// Check that the Hilbert curves on each face combine to form a
// continuous curve over the entire cube.
for (int face = 0; face < 6; ++face)
{
// The Hilbert curve on each face starts at (-1,-1) and terminates
// at either (1,-1) (if axes not swapped) or (-1,1) (if swapped).
int sign = ((face & S2.kSwapMask) != 0) ? -1 : 1;
Assert.Equal(S2.FaceUVtoXYZ(face, sign, -sign),
S2.FaceUVtoXYZ((face + 1) % 6, -1, -1));
}
}
// In order to make it easier to construct tests that encode particular
// values, this function duplicates the part of EncodedS2PointVector that
// converts an encoded 64-bit value back to an S2Point.
private static S2Point EncodedValueToPoint(UInt64 value, int level)
{
BitsInterleave.DeinterleaveUInt32(value, out var sj, out var tj);
int shift = S2.kMaxCellLevel - level;
uint si = (((sj << 1) | 1) << shift) & 0x7fffffff;
uint ti = (((tj << 1) | 1) << shift) & 0x7fffffff;
int face = (int)(((sj << shift) >> 30) | (((tj << (shift + 1)) >> 29) & 4));
return(S2.FaceUVtoXYZ(face,
S2.STtoUV(S2.SiTitoST(si)),
S2.STtoUV(S2.SiTitoST(ti))).Normalize());
}
private static S2Shape NewPaddedCell(S2CellId id, double padding_uv)
{
var ij = new int[2];
var face = id.ToFaceIJOrientation(out ij[0], out ij[1], out _, false);
var uv = S2CellId.IJLevelToBoundUV(ij, id.Level()).Expanded(padding_uv);
var vertices = new S2Point[4];
for (int i = 0; i < 4; ++i)
{
vertices[i] = S2.FaceUVtoXYZ(face, uv.GetVertex(i)).Normalize();
}
return(new S2LaxLoopShape(vertices));
}
public void Test_VisitCells_QueryEdgeOnFaceBoundary()
{
int kIters = 100;
for (int iter = 0; iter < kIters; ++iter)
{
_logger.WriteLine("Iteration " + iter);
// Choose an edge AB such that B is nearly on the edge between two S2 cube
// faces, and such that the result of clipping AB to the face that nominally
// contains B (according to S2.GetFace) is empty when no padding is used.
int a_face, b_face;
S2Point a, b;
R2Point a_uv, b_uv;
do
{
a_face = S2Testing.Random.Uniform(6);
a = S2.FaceUVtoXYZ(a_face, S2Testing.Random.UniformDouble(-1, 1),
S2Testing.Random.UniformDouble(-1, 1)).Normalize();
b_face = S2.GetUVWFace(a_face, 0, 1); // Towards positive u-axis
var uTmp = 1 - S2Testing.Random.Uniform(2) * 0.5 * S2.DoubleEpsilon;
b = S2.FaceUVtoXYZ(b_face, uTmp, S2Testing.Random.UniformDouble(-1, 1)).Normalize();
} while (S2.GetFace(b) != b_face ||
S2EdgeClipping.ClipToFace(a, b, b_face, out a_uv, out b_uv));
// Verify that the clipping result is non-empty when a padding of
// S2EdgeClipping.kFaceClipErrorUVCoord is used instead.
Assert.True(S2EdgeClipping.ClipToPaddedFace(a, b, b_face, S2EdgeClipping.kFaceClipErrorUVCoord,
out a_uv, out b_uv));
// Create an S2ShapeIndex containing a single edge BC, where C is on the
// same S2 cube face as B (which is different than the face containing A).
S2Point c = S2.FaceUVtoXYZ(b_face, S2Testing.Random.UniformDouble(-1, 1),
S2Testing.Random.UniformDouble(-1, 1)).Normalize();
MutableS2ShapeIndex index = new();
index.Add(new S2Polyline.OwningShape(
new S2Polyline(new S2Point[] { b, c })));
// Check that the intersection between AB and BC is detected when the face
// containing BC is specified as a root cell. (Note that VisitCells()
// returns false only if the CellVisitor returns false, and otherwise
// returns true.)
S2CrossingEdgeQuery query = new(index);
S2PaddedCell root = new(S2CellId.FromFace(b_face), 0);
Assert.False(query.VisitCells(a, b, root, (S2ShapeIndexCell x) => false));
}
}
public void Test_GetCrossingCandidates_PerturbedCubeEdges()
{
List <(S2Point, S2Point)> edges = new();
for (int iter = 0; iter < 10; ++iter)
{
int face = S2Testing.Random.Uniform(6);
double scale = Math.Pow(S2.DoubleError, S2Testing.Random.RandDouble());
R2Point uv = new(2 * S2Testing.Random.Uniform(2) - 1, 2 * S2Testing.Random.Uniform(2) - 1); // vertex
S2Point a0 = S2.FaceUVtoXYZ(face, scale * uv);
S2Point b0 = a0 - 2 * S2.GetNorm(face);
// TODO(ericv): This test is currently slow because *every* crossing test
// needs to invoke S2Pred.ExpensiveSign().
GetPerturbedSubEdges(a0, b0, 30, edges);
TestAllCrossings(edges);
}
}
public void Test_UVNorms()
{
// Check that GetUNorm and GetVNorm compute right-handed normals for
// an edge in the increasing U or V direction.
for (int face = 0; face < 6; ++face)
{
for (double x = -1; x <= 1; x += 1 / 1024.0)
{
Assert2.DoubleEqual(S2.FaceUVtoXYZ(face, x, -1)
.CrossProd(S2.FaceUVtoXYZ(face, x, 1))
.Angle(S2.GetUNorm(face, x)), 0);
Assert2.DoubleEqual(S2.FaceUVtoXYZ(face, -1, x)
.CrossProd(S2.FaceUVtoXYZ(face, 1, x))
.Angle(S2.GetVNorm(face, x)), 0);
}
}
}
public void Test_UVWAxis()
{
for (int face = 0; face < 6; ++face)
{
// Check that axes are consistent with FaceUVtoXYZ.
Assert.Equal(S2.FaceUVtoXYZ(face, 1, 0) - S2.FaceUVtoXYZ(face, 0, 0),
S2.GetUAxis(face));
Assert.Equal(S2.FaceUVtoXYZ(face, 0, 1) - S2.FaceUVtoXYZ(face, 0, 0),
S2.GetVAxis(face));
Assert.Equal(S2.FaceUVtoXYZ(face, 0, 0), S2.GetNorm(face));
// Check that every face coordinate frame is right-handed.
Assert.Equal(1, S2.GetUAxis(face).CrossProd(S2.GetVAxis(face))
.DotProd(S2.GetNorm(face)));
// Check that GetUVWAxis is consistent with GetUAxis, GetVAxis, GetNorm.
Assert.Equal(S2.GetUAxis(face), S2.GetUVWAxis(face, 0));
Assert.Equal(S2.GetVAxis(face), S2.GetUVWAxis(face, 1));
Assert.Equal(S2.GetNorm(face), S2.GetUVWAxis(face, 2));
}
}
public void Test_S2_FaceClipping()
{
// Start with a few simple cases.
// An edge that is entirely contained within one cube face:
TestFaceClippingEdgePair(new S2Point(1, -0.5, -0.5), new S2Point(1, 0.5, 0.5));
// An edge that crosses one cube edge:
TestFaceClippingEdgePair(new S2Point(1, 0, 0), new S2Point(0, 1, 0));
// An edge that crosses two opposite edges of face 0:
TestFaceClippingEdgePair(new S2Point(0.75, 0, -1), new S2Point(0.75, 0, 1));
// An edge that crosses two adjacent edges of face 2:
TestFaceClippingEdgePair(new S2Point(1, 0, 0.75), new S2Point(0, 1, 0.75));
// An edge that crosses three cube edges (four faces):
TestFaceClippingEdgePair(new S2Point(1, 0.9, 0.95), new S2Point(-1, 0.95, 0.9));
// Comprehensively test edges that are difficult to handle, especially those
// that nearly follow one of the 12 cube edges.
R2Rect biunit = new(new R1Interval(-1, 1), new R1Interval(-1, 1));
int kIters = 1000; // Test passes with 1e6 iterations
for (int iter = 0; iter < kIters; ++iter)
{
_logger.WriteLine($"Iteration {iter}");
// Choose two adjacent cube corners P and Q.
int face = S2Testing.Random.Uniform(6);
int i = S2Testing.Random.Uniform(4);
int j = (i + 1) & 3;
S2Point p = S2.FaceUVtoXYZ(face, biunit.GetVertex(i));
S2Point q = S2.FaceUVtoXYZ(face, biunit.GetVertex(j));
// Now choose two points that are nearly on the edge PQ, preferring points
// that are near cube corners, face midpoints, or edge midpoints.
S2Point a = PerturbedCornerOrMidpoint(p, q);
S2Point b = PerturbedCornerOrMidpoint(p, q);
TestFaceClipping(a, b);
}
}
private static S2Point FacePiQitoXYZ(int face, int pi, int qi, int level)
{
return(S2.FaceUVtoXYZ(face,
S2.STtoUV(PiQitoST(pi, level)),
S2.STtoUV(PiQitoST(qi, level))).Normalize());
}
private void TestFaceClipping(S2Point a_raw, S2Point b_raw)
{
S2Point a = a_raw.Normalize();
S2Point b = b_raw.Normalize();
// First we test GetFaceSegments.
FaceSegmentVector segments = new();
GetFaceSegments(a, b, segments);
int n = segments.Count;
Assert.True(n >= 1);
var msg = new StringBuilder($"\nA={a_raw}\nB={b_raw}\nN={S2.RobustCrossProd(a, b)}\nSegments:\n");
int i1 = 0;
foreach (var s in segments)
{
msg.AppendLine($"{i1++}: face={s.face}, a={s.a}, b={s.b}");
}
_logger.WriteLine(msg.ToString());
R2Rect biunit = new(new R1Interval(-1, 1), new R1Interval(-1, 1));
var kErrorRadians = kFaceClipErrorRadians;
// The first and last vertices should approximately equal A and B.
Assert.True(a.Angle(S2.FaceUVtoXYZ(segments[0].face, segments[0].a)) <=
kErrorRadians);
Assert.True(b.Angle(S2.FaceUVtoXYZ(segments[n - 1].face, segments[n - 1].b)) <=
kErrorRadians);
S2Point norm = S2.RobustCrossProd(a, b).Normalize();
S2Point a_tangent = norm.CrossProd(a);
S2Point b_tangent = b.CrossProd(norm);
for (int i = 0; i < n; ++i)
{
// Vertices may not protrude outside the biunit square.
Assert.True(biunit.Contains(segments[i].a));
Assert.True(biunit.Contains(segments[i].b));
if (i == 0)
{
continue;
}
// The two representations of each interior vertex (on adjacent faces)
// must correspond to exactly the same S2Point.
Assert.NotEqual(segments[i - 1].face, segments[i].face);
Assert.Equal(S2.FaceUVtoXYZ(segments[i - 1].face, segments[i - 1].b),
S2.FaceUVtoXYZ(segments[i].face, segments[i].a));
// Interior vertices should be in the plane containing A and B, and should
// be contained in the wedge of angles between A and B (i.e., the dot
// products with a_tangent and b_tangent should be non-negative).
S2Point p = S2.FaceUVtoXYZ(segments[i].face, segments[i].a).Normalize();
Assert.True(Math.Abs(p.DotProd(norm)) <= kErrorRadians);
Assert.True(p.DotProd(a_tangent) >= -kErrorRadians);
Assert.True(p.DotProd(b_tangent) >= -kErrorRadians);
}
// Now we test ClipToPaddedFace (sometimes with a padding of zero). We do
// this by defining an (x,y) coordinate system for the plane containing AB,
// and converting points along the great circle AB to angles in the range
// [-Pi, Pi]. We then accumulate the angle intervals spanned by each
// clipped edge; the union over all 6 faces should approximately equal the
// interval covered by the original edge.
double padding = S2Testing.Random.OneIn(10) ? 0.0 : 1e-10 * Math.Pow(1e-5, S2Testing.Random.RandDouble());
S2Point x_axis = a, y_axis = a_tangent;
S1Interval expected_angles = new(0, a.Angle(b));
S1Interval max_angles = expected_angles.Expanded(kErrorRadians);
S1Interval actual_angles = new();
for (int face = 0; face < 6; ++face)
{
if (ClipToPaddedFace(a, b, face, padding, out var a_uv, out var b_uv))
{
S2Point a_clip = S2.FaceUVtoXYZ(face, a_uv).Normalize();
S2Point b_clip = S2.FaceUVtoXYZ(face, b_uv).Normalize();
Assert.True(Math.Abs(a_clip.DotProd(norm)) <= kErrorRadians);
Assert.True(Math.Abs(b_clip.DotProd(norm)) <= kErrorRadians);
if (a_clip.Angle(a) > kErrorRadians)
{
Assert2.DoubleEqual(1 + padding, Math.Max(Math.Abs(a_uv[0]), Math.Abs(a_uv[1])));
}
if (b_clip.Angle(b) > kErrorRadians)
{
Assert2.DoubleEqual(1 + padding, Math.Max(Math.Abs(b_uv[0]), Math.Abs(b_uv[1])));
}
double a_angle = Math.Atan2(a_clip.DotProd(y_axis), a_clip.DotProd(x_axis));
double b_angle = Math.Atan2(b_clip.DotProd(y_axis), b_clip.DotProd(x_axis));
// Rounding errors may cause b_angle to be slightly less than a_angle.
// We handle this by constructing the interval with FromPointPair(),
// which is okay since the interval length is much less than Math.PI.
S1Interval face_angles = S1Interval.FromPointPair(a_angle, b_angle);
Assert.True(max_angles.Contains(face_angles));
actual_angles = actual_angles.Union(face_angles);
}
}
Assert.True(actual_angles.Expanded(kErrorRadians).Contains(expected_angles));
}
public void Test_S2Cap_S2CellMethods()
{
// For each cube face, we construct some cells on
// that face and some caps whose positions are relative to that face,
// and then check for the expected intersection/containment results.
for (var face = 0; face < 6; ++face)
{
// The cell consisting of the entire face.
S2Cell root_cell = S2Cell.FromFace(face);
// A leaf cell at the midpoint of the v=1 edge.
S2Cell edge_cell = new(S2.FaceUVtoXYZ(face, 0, 1 - kEps));
// A leaf cell at the u=1, v=1 corner.
S2Cell corner_cell = new(S2.FaceUVtoXYZ(face, 1 - kEps, 1 - kEps));
// Quick check for full and empty caps.
Assert.True(S2Cap.Full.Contains(root_cell));
Assert.False(S2Cap.Empty.MayIntersect(root_cell));
// Check intersections with the bounding caps of the leaf cells that are
// adjacent to 'corner_cell' along the Hilbert curve. Because this corner
// is at (u=1,v=1), the curve stays locally within the same cube face.
S2CellId first = corner_cell.Id.Advance(-3);
S2CellId last = corner_cell.Id.Advance(4);
for (S2CellId id = first; id < last; id = id.Next())
{
S2Cell cell = new(id);
Assert.Equal(id == corner_cell.Id,
cell.GetCapBound().Contains(corner_cell));
Assert.Equal(id.Parent().Contains(corner_cell.Id),
cell.GetCapBound().MayIntersect(corner_cell));
}
var anti_face = (face + 3) % 6; // Opposite face.
for (var cap_face = 0; cap_face < 6; ++cap_face)
{
// A cap that barely contains all of 'cap_face'.
S2Point center = S2.GetNorm(cap_face);
S2Cap covering = new(center, S1Angle.FromRadians(kFaceRadius + kEps));
Assert.Equal(cap_face == face, covering.Contains(root_cell));
Assert.Equal(cap_face != anti_face, covering.MayIntersect(root_cell));
Assert.Equal(center.DotProd(edge_cell.Center()) > 0.1,
covering.Contains(edge_cell));
Assert.Equal(covering.MayIntersect(edge_cell), covering.Contains(edge_cell));
Assert.Equal(cap_face == face, covering.Contains(corner_cell));
Assert.Equal(center.DotProd(corner_cell.Center()) > 0,
covering.MayIntersect(corner_cell));
// A cap that barely intersects the edges of 'cap_face'.
S2Cap bulging = new(center, S1Angle.FromRadians(S2.M_PI_4 + kEps));
Assert.False(bulging.Contains(root_cell));
Assert.Equal(cap_face != anti_face, bulging.MayIntersect(root_cell));
Assert.Equal(cap_face == face, bulging.Contains(edge_cell));
Assert.Equal(center.DotProd(edge_cell.Center()) > 0.1,
bulging.MayIntersect(edge_cell));
Assert.False(bulging.Contains(corner_cell));
Assert.False(bulging.MayIntersect(corner_cell));
// A singleton cap.
S2Cap singleton = new(center, S1Angle.Zero);
Assert.Equal(cap_face == face, singleton.MayIntersect(root_cell));
Assert.False(singleton.MayIntersect(edge_cell));
Assert.False(singleton.MayIntersect(corner_cell));
}
}
}
