Esempio n. 1
0
        private void TestCell(S2Cell target)
        {
            // Indicates whether each shape that intersects "target" also contains it.
            Dictionary <int, bool> shape_contains = new();

            Assert.True(region_.VisitIntersectingShapes(
                            target, (S2Shape shape, bool contains_target) => {
                // Verify that each shape is visited at most once.
                Assert.False(shape_contains.ContainsKey(shape.Id));
                shape_contains[shape.Id] = contains_target;
                return(true);
            }));
            for (int s = 0; s < index_.NumShapeIds(); ++s)
            {
                var shape_region = shape_indexes_[s].MakeS2ShapeIndexRegion();
                if (!shape_region.MayIntersect(target))
                {
                    Assert.False(shape_contains.ContainsKey(s));
                }
                else
                {
                    Assert.Equal(shape_contains[s], shape_region.Contains(target));
                }
            }
            var(cellRelation, pos) = index_.LocateCell(target.Id);
            iter_.SetPosition(pos);
            switch (cellRelation)
            {
            case S2ShapeIndex.CellRelation.DISJOINT:
                return;

            case S2ShapeIndex.CellRelation.SUBDIVIDED:
            {
                S2Cell[] children = new S2Cell[4];
                Assert.True(target.Subdivide(children));
                foreach (var child in children)
                {
                    TestCell(child);
                }
                return;
            }

            case S2ShapeIndex.CellRelation.INDEXED:
            {
                // We check a few random descendant cells by continuing randomly down
                // one branch of the tree for a few levels.
                if (target.IsLeaf() || S2Testing.Random.OneIn(3))
                {
                    return;
                }
                TestCell(new S2Cell(target.Id.Child(S2Testing.Random.Uniform(4))));
                return;
            }
            }
        }
Esempio n. 2
0
        static void TestSubdivide(S2Cell cell)
        {
            GatherStats(cell);
            if (cell.IsLeaf())
            {
                return;
            }

            var children = new S2Cell[4];

            Assert.True(cell.Subdivide(children));
            S2CellId child_id     = cell.Id.ChildBegin();
            double   exact_area   = 0;
            double   approx_area  = 0;
            double   average_area = 0;

            for (int i = 0; i < 4; ++i, child_id = child_id.Next())
            {
                exact_area   += children[i].ExactArea();
                approx_area  += children[i].ApproxArea();
                average_area += children[i].AverageArea();

                // Check that the child geometry is consistent with its cell ID.
                Assert.Equal(child_id, children[i].Id);
                Assert.True(S2.ApproxEquals(children[i].Center(), child_id.ToPoint()));
                S2Cell direct = new(child_id);
                Assert.Equal(direct.Face, children[i].Face);
                Assert.Equal(direct.Level, children[i].Level);
                Assert.Equal(direct.Orientation, children[i].Orientation);
                Assert.Equal(direct.CenterRaw(), children[i].CenterRaw());
                for (int k = 0; k < 4; ++k)
                {
                    Assert.Equal(direct.VertexRaw(k), children[i].VertexRaw(k));
                    Assert.Equal(direct.EdgeRaw(k), children[i].EdgeRaw(k));
                }

                // Test Contains() and MayIntersect().
                Assert.True(cell.Contains(children[i]));
                Assert.True(cell.MayIntersect(children[i]));
                Assert.False(children[i].Contains(cell));
                Assert.True(cell.Contains(children[i].CenterRaw()));
                for (int j = 0; j < 4; ++j)
                {
                    Assert.True(cell.Contains(children[i].VertexRaw(j)));
                    if (j != i)
                    {
                        Assert.False(children[i].Contains(children[j].CenterRaw()));
                        Assert.False(children[i].MayIntersect(children[j]));
                    }
                }

                // Test GetCapBound and GetRectBound.
                S2Cap        parent_cap  = cell.GetCapBound();
                S2LatLngRect parent_rect = cell.GetRectBound();
                if (cell.Contains(new S2Point(0, 0, 1)) || cell.Contains(new S2Point(0, 0, -1)))
                {
                    Assert.True(parent_rect.Lng.IsFull());
                }
                S2Cap        child_cap  = children[i].GetCapBound();
                S2LatLngRect child_rect = children[i].GetRectBound();
                Assert.True(child_cap.Contains(children[i].Center()));
                Assert.True(child_rect.Contains(children[i].CenterRaw()));
                Assert.True(parent_cap.Contains(children[i].Center()));
                Assert.True(parent_rect.Contains(children[i].CenterRaw()));
                for (int j = 0; j < 4; ++j)
                {
                    Assert.True(child_cap.Contains(children[i].Vertex(j)));
                    Assert.True(child_rect.Contains(children[i].Vertex(j)));
                    Assert.True(child_rect.Contains(children[i].VertexRaw(j)));
                    Assert.True(parent_cap.Contains(children[i].Vertex(j)));
                    Assert.True(parent_rect.Contains(children[i].Vertex(j)));
                    Assert.True(parent_rect.Contains(children[i].VertexRaw(j)));
                    if (j != i)
                    {
                        // The bounding caps and rectangles should be tight enough so that
                        // they exclude at least two vertices of each adjacent cell.
                        int cap_count  = 0;
                        int rect_count = 0;
                        for (int k = 0; k < 4; ++k)
                        {
                            if (child_cap.Contains(children[j].Vertex(k)))
                            {
                                ++cap_count;
                            }
                            if (child_rect.Contains(children[j].VertexRaw(k)))
                            {
                                ++rect_count;
                            }
                        }
                        Assert.True(cap_count <= 2);
                        if (child_rect.LatLo().Radians > -S2.M_PI_2 &&
                            child_rect.LatHi().Radians < S2.M_PI_2)
                        {
                            // Bounding rectangles may be too large at the poles because the
                            // pole itself has an arbitrary fixed longitude.
                            Assert.True(rect_count <= 2);
                        }
                    }
                }

                // Check all children for the first few levels, and then sample randomly.
                // We also always subdivide the cells containing a few chosen points so
                // that we have a better chance of sampling the minimum and maximum metric
                // values.  kMaxSizeUV is the absolute value of the u- and v-coordinate
                // where the cell size at a given level is maximal.
                double    kMaxSizeUV = 0.3964182625366691;
                R2Point[] special_uv =
                {
                    new R2Point(S2.DoubleEpsilon, S2.DoubleEpsilon), // Face center
                    new R2Point(S2.DoubleEpsilon, 1),                // Edge midpoint
                    new R2Point(1, 1),                               // Face corner
                    new R2Point(kMaxSizeUV, kMaxSizeUV),             // Largest cell area
                    new R2Point(S2.DoubleEpsilon, kMaxSizeUV),       // Longest edge/diagonal
                };
                bool force_subdivide = false;
                foreach (R2Point uv in special_uv)
                {
                    if (children[i].BoundUV.Contains(uv))
                    {
                        force_subdivide = true;
                    }
                }

                var debugFlag =
#if s2debug
                    true;
#else
                    false;
#endif

                if (force_subdivide ||
                    cell.Level < (debugFlag ? 5 : 6) ||
                    S2Testing.Random.OneIn(debugFlag ? 5 : 4))
                {
                    TestSubdivide(children[i]);
                }
            }

            // Check sum of child areas equals parent area.
            //
            // For ExactArea(), the best relative error we can expect is about 1e-6
            // because the precision of the unit vector coordinates is only about 1e-15
            // and the edge length of a leaf cell is about 1e-9.
            //
            // For ApproxArea(), the areas are accurate to within a few percent.
            //
            // For AverageArea(), the areas themselves are not very accurate, but
            // the average area of a parent is exactly 4 times the area of a child.

            Assert.True(Math.Abs(Math.Log(exact_area / cell.ExactArea())) <= Math.Abs(Math.Log((1 + 1e-6))));
            Assert.True(Math.Abs(Math.Log((approx_area / cell.ApproxArea()))) <= Math.Abs(Math.Log((1.03))));
            Assert.True(Math.Abs(Math.Log((average_area / cell.AverageArea()))) <= Math.Abs(Math.Log((1 + 1e-15))));
        }