internal static bool IsClockwiseRing(com.epl.geometry.MultiPathImpl polygon, int iring)
{
int high_point_index = polygon.GetHighestPointIndex(iring);
int path_start = polygon.GetPathStart(iring);
int path_end = polygon.GetPathEnd(iring);
com.epl.geometry.Point2D q = polygon.GetXY(high_point_index);
com.epl.geometry.Point2D p;
com.epl.geometry.Point2D r;
if (high_point_index == path_start)
{
p = polygon.GetXY(path_end - 1);
r = polygon.GetXY(path_start + 1);
}
else
{
if (high_point_index == path_end - 1)
{
p = polygon.GetXY(high_point_index - 1);
r = polygon.GetXY(path_start);
}
else
{
p = polygon.GetXY(high_point_index - 1);
r = polygon.GetXY(high_point_index + 1);
}
}
int orientation = com.epl.geometry.Point2D.OrientationRobust(p, q, r);
if (orientation == 0)
{
return(polygon.CalculateRingArea2D(iring) > 0.0);
}
return(orientation == -1);
}
public void ResetToVertex(int vertexIndex, int _pathIndex)
{
if (m_currentPathIndex >= 0 && m_currentPathIndex < m_parent.GetPathCount())
{
// check if we
// are in
// the
// current
// path
int start = _getPathBegin();
if (vertexIndex >= start && vertexIndex < m_parent.GetPathEnd(m_currentPathIndex))
{
m_currentSegmentIndex = -1;
m_nextSegmentIndex = vertexIndex - start;
return;
}
}
int path_index;
if (_pathIndex >= 0 && _pathIndex < m_parent.GetPathCount() && vertexIndex >= m_parent.GetPathStart(_pathIndex) && vertexIndex < m_parent.GetPathEnd(_pathIndex))
{
path_index = _pathIndex;
}
else
{
path_index = m_parent.GetPathIndexFromPointIndex(vertexIndex);
}
m_nextPathIndex = path_index + 1;
m_currentPathIndex = path_index;
m_currentSegmentIndex = -1;
m_nextSegmentIndex = vertexIndex - m_parent.GetPathStart(path_index);
m_segmentCount = _getSegmentCount(path_index);
m_pathBegin = m_parent.GetPathStart(m_currentPathIndex);
}
public SegmentIteratorImpl(com.epl.geometry.MultiPathImpl parent, int pointIndex)
{
if (pointIndex < 0 || pointIndex >= parent.GetPointCount())
{
throw new System.IndexOutOfRangeException();
}
m_currentSegmentIndex = -1;
int path = parent.GetPathIndexFromPointIndex(pointIndex);
m_nextSegmentIndex = pointIndex - parent.GetPathStart(path);
m_nextPathIndex = path + 1;
m_currentPathIndex = path;
m_parent = parent;
m_segmentCount = _getSegmentCount(m_currentPathIndex);
m_bCirculator = false;
m_currentSegment = null;
m_pathBegin = m_parent.GetPathStart(m_currentPathIndex);
m_dummyPoint = new com.epl.geometry.Point2D();
}
public SegmentIteratorImpl(com.epl.geometry.MultiPathImpl parent, int pathIndex, int segmentIndex)
{
if (pathIndex < 0 || pathIndex >= parent.GetPathCount() || segmentIndex < 0)
{
throw new System.IndexOutOfRangeException();
}
int d = parent.IsClosedPath(pathIndex) ? 0 : 1;
if (segmentIndex >= parent.GetPathSize(pathIndex) - d)
{
throw new System.IndexOutOfRangeException();
}
m_currentSegmentIndex = -1;
m_nextSegmentIndex = segmentIndex;
m_currentPathIndex = pathIndex;
m_nextPathIndex = m_nextSegmentIndex + 1;
m_parent = parent;
m_segmentCount = _getSegmentCount(m_nextPathIndex);
m_bCirculator = false;
m_currentSegment = null;
m_pathBegin = m_parent.GetPathStart(m_currentPathIndex);
m_dummyPoint = new com.epl.geometry.Point2D();
}
/// <summary>Returns the start index of the path.</summary>
/// <param name="pathIndex">The index of the path to return the start index from.</param>
/// <returns>The start index of the path.</returns>
public virtual int GetPathStart(int pathIndex)
{
return(m_impl.GetPathStart(pathIndex));
}
/// <summary>Returns true if the given path of the input MultiPath is convex.</summary>
/// <remarks>
/// Returns true if the given path of the input MultiPath is convex. Returns false otherwise.
/// \param multi_path The MultiPath to check if the path is convex.
/// \param path_index The path of the MultiPath to check if its convex.
/// </remarks>
internal static bool IsPathConvex(com.epl.geometry.MultiPath multi_path, int path_index, com.epl.geometry.ProgressTracker progress_tracker)
{
com.epl.geometry.MultiPathImpl mimpl = (com.epl.geometry.MultiPathImpl)multi_path._getImpl();
int path_start = mimpl.GetPathStart(path_index);
int path_end = mimpl.GetPathEnd(path_index);
bool bxyclosed = !mimpl.IsClosedPath(path_index) && mimpl.IsClosedPathInXYPlane(path_index);
com.epl.geometry.AttributeStreamOfDbl position = (com.epl.geometry.AttributeStreamOfDbl)(mimpl.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.POSITION));
int position_start = 2 * path_start;
int position_end = 2 * path_end;
if (bxyclosed)
{
position_end -= 2;
}
if (position_end - position_start < 6)
{
return(true);
}
// This matches the logic for case 1 of the tree hull algorithm. The idea is inductive. We assume we have a convex hull pt_0,...,pt_m, and we see if
// a new point (pt_pivot) is among the transitive tournament for pt_0, knowing that pt_pivot comes after pt_m.
// We check three conditions:
// 1) pt_m->pt_pivot->pt_0 is clockwise (closure across the boundary is convex)
// 2) pt_1->pt_pivot->pt_0 is clockwise (the first step forward is convex) (pt_1 is the next point after pt_0)
// 3) pt_m->pt_pivot->pt_m_prev is clockwise (the first step backwards is convex) (pt_m_prev is the previous point before pt_m)
// If all three of the above conditions are clockwise, then pt_pivot is among the transitive tournament for pt_0, and therefore the polygon pt_0, ..., pt_m, pt_pivot is convex.
com.epl.geometry.Point2D pt_0 = new com.epl.geometry.Point2D();
com.epl.geometry.Point2D pt_m = new com.epl.geometry.Point2D();
com.epl.geometry.Point2D pt_pivot = new com.epl.geometry.Point2D();
position.Read(position_start, pt_0);
position.Read(position_start + 2, pt_m);
position.Read(position_start + 4, pt_pivot);
// Initial inductive step
com.epl.geometry.ECoordinate det_ec = Determinant_(pt_m, pt_pivot, pt_0);
if (det_ec.IsFuzzyZero() || !IsClockwise_(det_ec.Value()))
{
return(false);
}
com.epl.geometry.Point2D pt_1 = new com.epl.geometry.Point2D(pt_m.x, pt_m.y);
com.epl.geometry.Point2D pt_m_prev = new com.epl.geometry.Point2D();
// Assume that pt_0,...,pt_m is convex. Check if the next point, pt_pivot, maintains the convex invariant.
for (int i = position_start + 6; i < position_end; i += 2)
{
pt_m_prev.SetCoords(pt_m);
pt_m.SetCoords(pt_pivot);
position.Read(i, pt_pivot);
det_ec = Determinant_(pt_m, pt_pivot, pt_0);
if (det_ec.IsFuzzyZero() || !IsClockwise_(det_ec.Value()))
{
return(false);
}
det_ec = Determinant_(pt_1, pt_pivot, pt_0);
if (det_ec.IsFuzzyZero() || !IsClockwise_(det_ec.Value()))
{
return(false);
}
det_ec = Determinant_(pt_m, pt_pivot, pt_m_prev);
if (det_ec.IsFuzzyZero() || !IsClockwise_(det_ec.Value()))
{
return(false);
}
}
return(true);
}
private static int ExportMultiPathToESRIShape(bool bPolygon, int exportFlags, com.epl.geometry.MultiPath multipath, System.IO.BinaryWriter shapeBuffer)
{
com.epl.geometry.MultiPathImpl multipathImpl = (com.epl.geometry.MultiPathImpl)multipath._getImpl();
bool bExportZs = multipathImpl.HasAttribute(com.epl.geometry.VertexDescription.Semantics.Z) && (exportFlags & com.epl.geometry.ShapeExportFlags.ShapeExportStripZs) == 0;
bool bExportMs = multipathImpl.HasAttribute(com.epl.geometry.VertexDescription.Semantics.M) && (exportFlags & com.epl.geometry.ShapeExportFlags.ShapeExportStripMs) == 0;
bool bExportIDs = multipathImpl.HasAttribute(com.epl.geometry.VertexDescription.Semantics.ID) && (exportFlags & com.epl.geometry.ShapeExportFlags.ShapeExportStripIDs) == 0;
bool bHasCurves = multipathImpl.HasNonLinearSegments();
bool bArcViewNaNs = (exportFlags & com.epl.geometry.ShapeExportFlags.ShapeExportTrueNaNs) == 0;
int partCount = multipathImpl.GetPathCount();
int pointCount = multipathImpl.GetPointCount();
if (!bPolygon)
{
for (int ipart = 0; ipart < partCount; ipart++)
{
if (multipath.IsClosedPath(ipart))
{
pointCount++;
}
}
}
else
{
pointCount += partCount;
}
int size = (4) + (4 * 8) + (4) + (4) + (partCount * 4) + pointCount * 2 * 8;
/* type */
/* envelope */
/* part count */
/* point count */
/* start indices */
/* xy coordinates */
if (bExportZs)
{
size += (2 * 8) + (pointCount * 8);
}
/* min max */
/* zs */
if (bExportMs)
{
size += (2 * 8) + (pointCount * 8);
}
/* min max */
/* ms */
if (bExportIDs)
{
size += pointCount * 4;
}
/* ids */
if (bHasCurves)
{
}
// to-do: curves
if (size >= com.epl.geometry.NumberUtils.IntMax())
{
throw new com.epl.geometry.GeometryException("invalid call");
}
if (shapeBuffer == null)
{
return(size);
}
else
{
if (((System.IO.MemoryStream)shapeBuffer.BaseStream).Capacity < size)
{
throw new com.epl.geometry.GeometryException("buffer is too small");
}
}
int offset = 0;
// Determine the shape type
int type;
if (!bExportZs && !bExportMs)
{
if (bExportIDs || bHasCurves)
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapeGeneralPolygon : com.epl.geometry.ShapeType.ShapeGeneralPolyline;
if (bExportIDs)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasIDs;
}
if (bHasCurves)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasCurves;
}
}
else
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapePolygon : com.epl.geometry.ShapeType.ShapePolyline;
}
}
else
{
if (bExportZs && !bExportMs)
{
if (bExportIDs || bHasCurves)
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapeGeneralPolygon : com.epl.geometry.ShapeType.ShapeGeneralPolyline;
type |= com.epl.geometry.ShapeModifiers.ShapeHasZs;
if (bExportIDs)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasIDs;
}
if (bHasCurves)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasCurves;
}
}
else
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapePolygonZ : com.epl.geometry.ShapeType.ShapePolylineZ;
}
}
else
{
if (bExportMs && !bExportZs)
{
if (bExportIDs || bHasCurves)
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapeGeneralPolygon : com.epl.geometry.ShapeType.ShapeGeneralPolyline;
type |= com.epl.geometry.ShapeModifiers.ShapeHasMs;
if (bExportIDs)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasIDs;
}
if (bHasCurves)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasCurves;
}
}
else
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapePolygonM : com.epl.geometry.ShapeType.ShapePolylineM;
}
}
else
{
if (bExportIDs || bHasCurves)
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapeGeneralPolygon : com.epl.geometry.ShapeType.ShapeGeneralPolyline;
type |= com.epl.geometry.ShapeModifiers.ShapeHasZs | com.epl.geometry.ShapeModifiers.ShapeHasMs;
if (bExportIDs)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasIDs;
}
if (bHasCurves)
{
type |= com.epl.geometry.ShapeModifiers.ShapeHasCurves;
}
}
else
{
type = bPolygon ? com.epl.geometry.ShapeType.ShapePolygonZM : com.epl.geometry.ShapeType.ShapePolylineZM;
}
}
}
}
// write type
shapeBuffer.Write(type);
offset += 4;
// write Envelope
com.epl.geometry.Envelope2D env = new com.epl.geometry.Envelope2D();
multipathImpl.QueryEnvelope2D(env);
// calls _VerifyAllStreams
shapeBuffer.Write(env.xmin);
offset += 8;
shapeBuffer.Write(env.ymin);
offset += 8;
shapeBuffer.Write(env.xmax);
offset += 8;
shapeBuffer.Write(env.ymax);
offset += 8;
// write part count
shapeBuffer.Write(partCount);
offset += 4;
// to-do: return error if larger than 2^32 - 1
// write pointCount
shapeBuffer.Write(pointCount);
offset += 4;
// write start indices for each part
int pointIndexDelta = 0;
for (int ipart = 0; ipart < partCount; ipart++)
{
int istart = multipathImpl.GetPathStart(ipart) + pointIndexDelta;
shapeBuffer.Write(istart);
offset += 4;
if (bPolygon || multipathImpl.IsClosedPath(ipart))
{
pointIndexDelta++;
}
}
if (pointCount > 0)
{
// write xy coordinates
com.epl.geometry.AttributeStreamBase positionStream = multipathImpl.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.POSITION);
com.epl.geometry.AttributeStreamOfDbl position = (com.epl.geometry.AttributeStreamOfDbl)positionStream;
for (int ipart = 0; ipart < partCount; ipart++)
{
int partStart = multipathImpl.GetPathStart(ipart);
int partEnd = multipathImpl.GetPathEnd(ipart);
for (int i = partStart; i < partEnd; i++)
{
double x = position.Read(2 * i);
double y = position.Read(2 * i + 1);
shapeBuffer.Write(x);
offset += 8;
shapeBuffer.Write(y);
offset += 8;
}
// If the part is closed, then we need to duplicate the start
// point
if (bPolygon || multipathImpl.IsClosedPath(ipart))
{
double x = position.Read(2 * partStart);
double y = position.Read(2 * partStart + 1);
shapeBuffer.Write(x);
offset += 8;
shapeBuffer.Write(y);
offset += 8;
}
}
}
// write Zs
if (bExportZs)
{
com.epl.geometry.Envelope1D zInterval = multipathImpl.QueryInterval(com.epl.geometry.VertexDescription.Semantics.Z, 0);
shapeBuffer.Write(bArcViewNaNs ? com.epl.geometry.Interop.TranslateToAVNaN(zInterval.vmin) : zInterval.vmin);
offset += 8;
shapeBuffer.Write(bArcViewNaNs ? com.epl.geometry.Interop.TranslateToAVNaN(zInterval.vmax) : zInterval.vmax);
offset += 8;
if (pointCount > 0)
{
if (multipathImpl._attributeStreamIsAllocated(com.epl.geometry.VertexDescription.Semantics.Z))
{
com.epl.geometry.AttributeStreamOfDbl zs = (com.epl.geometry.AttributeStreamOfDbl)multipathImpl.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.Z);
for (int ipart = 0; ipart < partCount; ipart++)
{
int partStart = multipathImpl.GetPathStart(ipart);
int partEnd = multipathImpl.GetPathEnd(ipart);
for (int i = partStart; i < partEnd; i++)
{
double z = zs.Read(i);
shapeBuffer.Write(bArcViewNaNs ? com.epl.geometry.Interop.TranslateToAVNaN(z) : z);
offset += 8;
}
// If the part is closed, then we need to duplicate the
// start z
if (bPolygon || multipathImpl.IsClosedPath(ipart))
{
double z = zs.Read(partStart);
shapeBuffer.Write(z);
offset += 8;
}
}
}
else
{
double z = com.epl.geometry.VertexDescription.GetDefaultValue(com.epl.geometry.VertexDescription.Semantics.Z);
if (bArcViewNaNs)
{
z = com.epl.geometry.Interop.TranslateToAVNaN(z);
}
for (int i = 0; i < pointCount; i++)
{
shapeBuffer.Write(z);
}
offset += 8;
}
}
}
// write Ms
if (bExportMs)
{
com.epl.geometry.Envelope1D mInterval = multipathImpl.QueryInterval(com.epl.geometry.VertexDescription.Semantics.M, 0);
shapeBuffer.Write(bArcViewNaNs ? com.epl.geometry.Interop.TranslateToAVNaN(mInterval.vmin) : mInterval.vmin);
offset += 8;
shapeBuffer.Write(bArcViewNaNs ? com.epl.geometry.Interop.TranslateToAVNaN(mInterval.vmax) : mInterval.vmax);
offset += 8;
if (pointCount > 0)
{
if (multipathImpl._attributeStreamIsAllocated(com.epl.geometry.VertexDescription.Semantics.M))
{
com.epl.geometry.AttributeStreamOfDbl ms = (com.epl.geometry.AttributeStreamOfDbl)multipathImpl.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.M);
for (int ipart = 0; ipart < partCount; ipart++)
{
int partStart = multipathImpl.GetPathStart(ipart);
int partEnd = multipathImpl.GetPathEnd(ipart);
for (int i = partStart; i < partEnd; i++)
{
double m = ms.Read(i);
shapeBuffer.Write(bArcViewNaNs ? com.epl.geometry.Interop.TranslateToAVNaN(m) : m);
offset += 8;
}
// If the part is closed, then we need to duplicate the
// start m
if (bPolygon || multipathImpl.IsClosedPath(ipart))
{
double m = ms.Read(partStart);
shapeBuffer.Write(m);
offset += 8;
}
}
}
else
{
double m = com.epl.geometry.VertexDescription.GetDefaultValue(com.epl.geometry.VertexDescription.Semantics.M);
if (bArcViewNaNs)
{
m = com.epl.geometry.Interop.TranslateToAVNaN(m);
}
for (int i = 0; i < pointCount; i++)
{
shapeBuffer.Write(m);
}
offset += 8;
}
}
}
// write Curves
if (bHasCurves)
{
}
// to-do: We'll finish this later
// write IDs
if (bExportIDs)
{
if (pointCount > 0)
{
if (multipathImpl._attributeStreamIsAllocated(com.epl.geometry.VertexDescription.Semantics.ID))
{
com.epl.geometry.AttributeStreamOfInt32 ids = (com.epl.geometry.AttributeStreamOfInt32)multipathImpl.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.ID);
for (int ipart = 0; ipart < partCount; ipart++)
{
int partStart = multipathImpl.GetPathStart(ipart);
int partEnd = multipathImpl.GetPathEnd(ipart);
for (int i = partStart; i < partEnd; i++)
{
int id = ids.Read(i);
shapeBuffer.Write(id);
offset += 4;
}
// If the part is closed, then we need to duplicate the
// start id
if (bPolygon || multipathImpl.IsClosedPath(ipart))
{
int id = ids.Read(partStart);
shapeBuffer.Write(id);
offset += 4;
}
}
}
else
{
int id = (int)com.epl.geometry.VertexDescription.GetDefaultValue(com.epl.geometry.VertexDescription.Semantics.ID);
for (int i = 0; i < pointCount; i++)
{
shapeBuffer.Write(id);
}
offset += 4;
}
}
}
return(offset);
}
internal virtual com.epl.geometry.Geometry TryFastIntersectPolylinePolygon_(com.epl.geometry.Polyline polyline, com.epl.geometry.Polygon polygon)
{
com.epl.geometry.MultiPathImpl polylineImpl = (com.epl.geometry.MultiPathImpl)polyline._getImpl();
com.epl.geometry.MultiPathImpl polygonImpl = (com.epl.geometry.MultiPathImpl)polygon._getImpl();
double tolerance = com.epl.geometry.InternalUtils.CalculateToleranceFromGeometry(m_spatial_reference, polygon, false);
com.epl.geometry.Envelope2D clipEnvelope = new com.epl.geometry.Envelope2D();
{
polygonImpl.QueryEnvelope2D(clipEnvelope);
com.epl.geometry.Envelope2D env1 = new com.epl.geometry.Envelope2D();
polylineImpl.QueryEnvelope2D(env1);
env1.Inflate(2.0 * tolerance, 2.0 * tolerance);
clipEnvelope.Intersect(env1);
System.Diagnostics.Debug.Assert((!clipEnvelope.IsEmpty()));
}
clipEnvelope.Inflate(10 * tolerance, 10 * tolerance);
if (true)
{
double tol = 0;
com.epl.geometry.Geometry clippedPolyline = com.epl.geometry.Clipper.Clip(polyline, clipEnvelope, tol, 0.0);
polyline = (com.epl.geometry.Polyline)clippedPolyline;
polylineImpl = (com.epl.geometry.MultiPathImpl)polyline._getImpl();
}
com.epl.geometry.AttributeStreamOfInt32 clipResult = new com.epl.geometry.AttributeStreamOfInt32(0);
int unresolvedSegments = -1;
com.epl.geometry.GeometryAccelerators accel = polygonImpl._getAccelerators();
if (accel != null)
{
com.epl.geometry.RasterizedGeometry2D rgeom = accel.GetRasterizedGeometry();
if (rgeom != null)
{
unresolvedSegments = 0;
clipResult.Reserve(polylineImpl.GetPointCount() + polylineImpl.GetPathCount());
com.epl.geometry.Envelope2D seg_env = new com.epl.geometry.Envelope2D();
com.epl.geometry.SegmentIteratorImpl iter = polylineImpl.QuerySegmentIterator();
while (iter.NextPath())
{
while (iter.HasNextSegment())
{
com.epl.geometry.Segment seg = iter.NextSegment();
seg.QueryEnvelope2D(seg_env);
com.epl.geometry.RasterizedGeometry2D.HitType hit = rgeom.QueryEnvelopeInGeometry(seg_env);
if (hit == com.epl.geometry.RasterizedGeometry2D.HitType.Inside)
{
clipResult.Add(1);
}
else
{
if (hit == com.epl.geometry.RasterizedGeometry2D.HitType.Outside)
{
clipResult.Add(0);
}
else
{
clipResult.Add(-1);
unresolvedSegments++;
}
}
}
}
}
}
if (polygon.GetPointCount() > 5)
{
double tol = 0;
com.epl.geometry.Geometry clippedPolygon = com.epl.geometry.Clipper.Clip(polygon, clipEnvelope, tol, 0.0);
polygon = (com.epl.geometry.Polygon)clippedPolygon;
polygonImpl = (com.epl.geometry.MultiPathImpl)polygon._getImpl();
accel = polygonImpl._getAccelerators();
}
//update accelerators
if (unresolvedSegments < 0)
{
unresolvedSegments = polylineImpl.GetSegmentCount();
}
// Some heuristics to decide if it makes sense to go with fast intersect
// vs going with the regular planesweep.
double totalPoints = (double)(polylineImpl.GetPointCount() + polygonImpl.GetPointCount());
double thisAlgorithmComplexity = ((double)unresolvedSegments * polygonImpl.GetPointCount());
// assume the worst case.
double planesweepComplexity = System.Math.Log(totalPoints) * totalPoints;
double empiricConstantFactorPlaneSweep = 4;
if (thisAlgorithmComplexity > planesweepComplexity * empiricConstantFactorPlaneSweep)
{
// Based on the number of input points, we deduced that the
// plansweep performance should be better than the brute force
// performance.
return null;
}
// resort to planesweep if quadtree does not help
com.epl.geometry.QuadTreeImpl polygonQuadTree = null;
com.epl.geometry.SegmentIteratorImpl polygonIter = polygonImpl.QuerySegmentIterator();
// Some logic to decide if it makes sense to build a quadtree on the
// polygon segments
if (accel != null && accel.GetQuadTree() != null)
{
polygonQuadTree = accel.GetQuadTree();
}
if (polygonQuadTree == null && polygonImpl.GetPointCount() > 20)
{
polygonQuadTree = com.epl.geometry.InternalUtils.BuildQuadTree(polygonImpl);
}
com.epl.geometry.Polyline result_polyline = (com.epl.geometry.Polyline)polyline.CreateInstance();
com.epl.geometry.MultiPathImpl resultPolylineImpl = (com.epl.geometry.MultiPathImpl)result_polyline._getImpl();
com.epl.geometry.QuadTreeImpl.QuadTreeIteratorImpl qIter = null;
com.epl.geometry.SegmentIteratorImpl polylineIter = polylineImpl.QuerySegmentIterator();
double[] @params = new double[9];
com.epl.geometry.AttributeStreamOfDbl intersections = new com.epl.geometry.AttributeStreamOfDbl(0);
com.epl.geometry.SegmentBuffer segmentBuffer = new com.epl.geometry.SegmentBuffer();
int start_index = -1;
int inCount = 0;
int segIndex = 0;
bool bOptimized = clipResult.Size() > 0;
// The algorithm is like that:
// Loop through all the segments of the polyline.
// For each polyline segment, intersect it with each of the polygon
// segments.
// If no intersections found then,
// If the polyline segment is completely inside, it is added to the
// result polyline.
// If it is outside, it is thrown out.
// If it intersects, then cut the polyline segment to pieces and test
// each part of the intersected result.
// The cut pieces will either have one point inside, or one point
// outside, or the middle point inside/outside.
//
int polylinePathIndex = -1;
while (polylineIter.NextPath())
{
polylinePathIndex = polylineIter.GetPathIndex();
int stateNewPath = 0;
int stateAddSegment = 1;
int stateManySegments = 2;
int stateManySegmentsContinuePath = 2;
int stateManySegmentsNewPath = 3;
int state = stateNewPath;
start_index = -1;
inCount = 0;
while (polylineIter.HasNextSegment())
{
int clipStatus = bOptimized ? (int)clipResult.Get(segIndex) : -1;
segIndex++;
com.epl.geometry.Segment polylineSeg = polylineIter.NextSegment();
if (clipStatus < 0)
{
System.Diagnostics.Debug.Assert((clipStatus == -1));
// Analyse polyline segment for intersection with the
// polygon.
if (polygonQuadTree != null)
{
if (qIter == null)
{
qIter = polygonQuadTree.GetIterator(polylineSeg, tolerance);
}
else
{
qIter.ResetIterator(polylineSeg, tolerance);
}
int path_index = -1;
for (int ind = qIter.Next(); ind != -1; ind = qIter.Next())
{
polygonIter.ResetToVertex(polygonQuadTree.GetElement(ind));
// path_index
path_index = polygonIter.GetPathIndex();
com.epl.geometry.Segment polygonSeg = polygonIter.NextSegment();
// intersect polylineSeg and polygonSeg.
int count = polylineSeg.Intersect(polygonSeg, null, @params, null, tolerance);
for (int i = 0; i < count; i++)
{
intersections.Add(@params[i]);
}
}
}
else
{
// no quadtree built
polygonIter.ResetToFirstPath();
while (polygonIter.NextPath())
{
while (polygonIter.HasNextSegment())
{
com.epl.geometry.Segment polygonSeg = polygonIter.NextSegment();
// intersect polylineSeg and polygonSeg.
int count = polylineSeg.Intersect(polygonSeg, null, @params, null, tolerance);
for (int i = 0; i < count; i++)
{
intersections.Add(@params[i]);
}
}
}
}
if (intersections.Size() > 0)
{
// intersections detected.
intersections.Sort(0, intersections.Size());
// std::sort(intersections.begin(),
// intersections.end());
double t0 = 0;
intersections.Add(1.0);
int status = -1;
for (int i = 0, n = intersections.Size(); i < n; i++)
{
double t = intersections.Get(i);
if (t == t0)
{
continue;
}
bool bWholeSegment = false;
com.epl.geometry.Segment resSeg;
if (t0 != 0 || t != 1.0)
{
polylineSeg.Cut(t0, t, segmentBuffer);
resSeg = segmentBuffer.Get();
}
else
{
resSeg = polylineSeg;
bWholeSegment = true;
}
if (state >= stateManySegments)
{
resultPolylineImpl.AddSegmentsFromPath(polylineImpl, polylinePathIndex, start_index, inCount, state == stateManySegmentsNewPath);
if (AnalyseClipSegment_(polygon, resSeg.GetStartXY(), tolerance) != 1)
{
if (AnalyseClipSegment_(polygon, resSeg, tolerance) != 1)
{
return null;
}
}
//someting went wrong we'll falback to slower but robust planesweep code.
resultPolylineImpl.AddSegment(resSeg, false);
state = stateAddSegment;
inCount = 0;
}
else
{
status = AnalyseClipSegment_(polygon, resSeg, tolerance);
switch (status)
{
case 1:
{
if (!bWholeSegment)
{
resultPolylineImpl.AddSegment(resSeg, state == stateNewPath);
state = stateAddSegment;
}
else
{
if (state < stateManySegments)
{
start_index = polylineIter.GetStartPointIndex() - polylineImpl.GetPathStart(polylinePathIndex);
inCount = 1;
if (state == stateNewPath)
{
state = stateManySegmentsNewPath;
}
else
{
System.Diagnostics.Debug.Assert((state == stateAddSegment));
state = stateManySegmentsContinuePath;
}
}
else
{
inCount++;
}
}
break;
}
case 0:
{
state = stateNewPath;
start_index = -1;
inCount = 0;
break;
}
default:
{
return null;
}
}
}
// may happen if a segment
// coincides with the border.
t0 = t;
}
}
else
{
clipStatus = AnalyseClipSegment_(polygon, polylineSeg.GetStartXY(), tolerance);
// simple
// case
// no
// intersection.
// Both
// points
// must
// be
// inside.
if (clipStatus < 0)
{
System.Diagnostics.Debug.Assert((clipStatus >= 0));
return null;
}
// something goes wrong, resort to
// planesweep
System.Diagnostics.Debug.Assert((AnalyseClipSegment_(polygon, polylineSeg.GetEndXY(), tolerance) == clipStatus));
if (clipStatus == 1)
{
// the whole segment inside
if (state < stateManySegments)
{
System.Diagnostics.Debug.Assert((inCount == 0));
start_index = polylineIter.GetStartPointIndex() - polylineImpl.GetPathStart(polylinePathIndex);
if (state == stateNewPath)
{
state = stateManySegmentsNewPath;
}
else
{
System.Diagnostics.Debug.Assert((state == stateAddSegment));
state = stateManySegmentsContinuePath;
}
}
inCount++;
}
else
{
System.Diagnostics.Debug.Assert((state < stateManySegments));
start_index = -1;
inCount = 0;
}
}
intersections.Clear(false);
}
else
{
// clip status is determined by other means
if (clipStatus == 0)
{
// outside
System.Diagnostics.Debug.Assert((AnalyseClipSegment_(polygon, polylineSeg, tolerance) == 0));
System.Diagnostics.Debug.Assert((start_index < 0));
System.Diagnostics.Debug.Assert((inCount == 0));
continue;
}
if (clipStatus == 1)
{
System.Diagnostics.Debug.Assert((AnalyseClipSegment_(polygon, polylineSeg, tolerance) == 1));
if (state == stateNewPath)
{
state = stateManySegmentsNewPath;
start_index = polylineIter.GetStartPointIndex() - polylineImpl.GetPathStart(polylinePathIndex);
}
else
{
if (state == stateAddSegment)
{
state = stateManySegmentsContinuePath;
start_index = polylineIter.GetStartPointIndex() - polylineImpl.GetPathStart(polylinePathIndex);
}
else
{
System.Diagnostics.Debug.Assert((state >= stateManySegments));
}
}
inCount++;
continue;
}
}
}
if (state >= stateManySegments)
{
resultPolylineImpl.AddSegmentsFromPath(polylineImpl, polylinePathIndex, start_index, inCount, state == stateManySegmentsNewPath);
start_index = -1;
}
}
return result_polyline;
}
private void GeneralizePath(com.epl.geometry.MultiPathImpl mpsrc, int ipath, com.epl.geometry.MultiPathImpl mpdst, com.epl.geometry.Line lineHelper)
{
if (mpsrc.GetPathSize(ipath) < 2)
{
return;
}
int start = mpsrc.GetPathStart(ipath);
int end = mpsrc.GetPathEnd(ipath) - 1;
com.epl.geometry.AttributeStreamOfDbl xy = (com.epl.geometry.AttributeStreamOfDbl)mpsrc.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.POSITION);
bool bClosed = mpsrc.IsClosedPath(ipath);
com.epl.geometry.AttributeStreamOfInt32 stack = new com.epl.geometry.AttributeStreamOfInt32(0);
stack.Reserve(mpsrc.GetPathSize(ipath) + 1);
com.epl.geometry.AttributeStreamOfInt32 resultStack = new com.epl.geometry.AttributeStreamOfInt32(0);
resultStack.Reserve(mpsrc.GetPathSize(ipath) + 1);
stack.Add(bClosed ? start : end);
stack.Add(start);
com.epl.geometry.Point2D pt = new com.epl.geometry.Point2D();
while (stack.Size() > 1)
{
int i1 = stack.GetLast();
stack.RemoveLast();
int i2 = stack.GetLast();
mpsrc.GetXY(i1, pt);
lineHelper.SetStartXY(pt);
mpsrc.GetXY(i2, pt);
lineHelper.SetEndXY(pt);
int mid = FindGreatestDistance(lineHelper, pt, xy, i1, i2, end);
if (mid >= 0)
{
stack.Add(mid);
stack.Add(i1);
}
else
{
resultStack.Add(i1);
}
}
if (!bClosed)
{
resultStack.Add(stack.Get(0));
}
int rs_size = resultStack.Size();
int path_size = mpsrc.GetPathSize(ipath);
if (rs_size == path_size && rs_size == stack.Size())
{
mpdst.AddPath(mpsrc, ipath, true);
}
else
{
if (resultStack.Size() > 0)
{
if (m_bRemoveDegenerateParts && resultStack.Size() <= 2)
{
if (bClosed || resultStack.Size() == 1)
{
return;
}
double d = com.epl.geometry.Point2D.Distance(mpsrc.GetXY(resultStack.Get(0)), mpsrc.GetXY(resultStack.Get(1)));
if (d <= m_maxDeviation)
{
return;
}
}
com.epl.geometry.Point point = new com.epl.geometry.Point();
for (int i = 0, n = resultStack.Size(); i < n; i++)
{
mpsrc.GetPointByVal(resultStack.Get(i), point);
if (i == 0)
{
mpdst.StartPath(point);
}
else
{
mpdst.LineTo(point);
}
}
if (bClosed)
{
for (int i_1 = resultStack.Size(); i_1 < 3; i_1++)
{
mpdst.LineTo(point);
}
mpdst.ClosePathWithLine();
}
}
}
}
internal static com.epl.geometry.MultiPoint CalculatePolylineBoundary_(object impl, com.epl.geometry.ProgressTracker progress_tracker, bool only_check_non_empty_boundary, bool[] not_empty)
{
if (not_empty != null)
{
not_empty[0] = false;
}
com.epl.geometry.MultiPathImpl mpImpl = (com.epl.geometry.MultiPathImpl)impl;
com.epl.geometry.MultiPoint dst = null;
if (!only_check_non_empty_boundary)
{
dst = new com.epl.geometry.MultiPoint(mpImpl.GetDescription());
}
if (!mpImpl.IsEmpty())
{
com.epl.geometry.AttributeStreamOfInt32 indices = new com.epl.geometry.AttributeStreamOfInt32(0);
indices.Reserve(mpImpl.GetPathCount() * 2);
for (int ipath = 0, nPathCount = mpImpl.GetPathCount(); ipath < nPathCount; ipath++)
{
int path_size = mpImpl.GetPathSize(ipath);
if (path_size > 0 && !mpImpl.IsClosedPathInXYPlane(ipath))
{
// closed
// paths
// of
// polyline
// do
// not
// contribute
// to
// the
// boundary.
int start = mpImpl.GetPathStart(ipath);
indices.Add(start);
int end = mpImpl.GetPathEnd(ipath) - 1;
indices.Add(end);
}
}
if (indices.Size() > 0)
{
com.epl.geometry.BucketSort sorter = new com.epl.geometry.BucketSort();
com.epl.geometry.AttributeStreamOfDbl xy = (com.epl.geometry.AttributeStreamOfDbl)(mpImpl.GetAttributeStreamRef(com.epl.geometry.VertexDescription.Semantics.POSITION));
sorter.Sort(indices, 0, indices.Size(), new com.epl.geometry.Boundary.MultiPathImplBoundarySorter(xy));
com.epl.geometry.Point2D ptPrev = new com.epl.geometry.Point2D();
xy.Read(2 * indices.Get(0), ptPrev);
int ind = 0;
int counter = 1;
com.epl.geometry.Point point = new com.epl.geometry.Point();
com.epl.geometry.Point2D pt = new com.epl.geometry.Point2D();
for (int i = 1, n = indices.Size(); i < n; i++)
{
xy.Read(2 * indices.Get(i), pt);
if (pt.IsEqual(ptPrev))
{
if (indices.Get(ind) > indices.Get(i))
{
// remove duplicate point
indices.Set(ind, com.epl.geometry.NumberUtils.IntMax());
ind = i;
}
else
{
// just for the heck of it, have the first
// point in the order to be added to the
// boundary.
indices.Set(i, com.epl.geometry.NumberUtils.IntMax());
}
counter++;
}
else
{
if ((counter & 1) == 0)
{
// remove boundary point
indices.Set(ind, com.epl.geometry.NumberUtils.IntMax());
}
else
{
if (only_check_non_empty_boundary)
{
if (not_empty != null)
{
not_empty[0] = true;
}
return(null);
}
}
ptPrev.SetCoords(pt);
ind = i;
counter = 1;
}
}
if ((counter & 1) == 0)
{
// remove the point
indices.Set(ind, com.epl.geometry.NumberUtils.IntMax());
}
else
{
if (only_check_non_empty_boundary)
{
if (not_empty != null)
{
not_empty[0] = true;
}
return(null);
}
}
if (!only_check_non_empty_boundary)
{
indices.Sort(0, indices.Size());
for (int i_1 = 0, n = indices.Size(); i_1 < n; i_1++)
{
if (indices.Get(i_1) == com.epl.geometry.NumberUtils.IntMax())
{
break;
}
mpImpl.GetPointByVal(indices.Get(i_1), point);
dst.Add(point);
}
}
}
}
if (only_check_non_empty_boundary)
{
return(null);
}
return(dst);
}
