/// <summary>
///
/// </summary>
/// <param name="geomGraph"></param>
public virtual void Build(GeometryGraph geomGraph)
{
// compute nodes for intersections between previously noded edges
ComputeIntersectionNodes(geomGraph, 0);
/*
* Copy the labelling for the nodes in the parent Geometry. These override
* any labels determined by intersections.
*/
CopyNodesAndLabels(geomGraph, 0);
/*
* Build EdgeEnds for all intersections.
*/
EdgeEndBuilder eeBuilder = new EdgeEndBuilder();
IList eeList = eeBuilder.ComputeEdgeEnds(geomGraph.GetEdgeEnumerator());
InsertEdgeEnds(eeList);
}
/// <summary>
///
/// </summary>
/// <param name="geomGraph"></param>
public virtual void Build(GeometryGraph geomGraph)
{
// compute nodes for intersections between previously noded edges
ComputeIntersectionNodes(geomGraph, 0);
/*
* Copy the labelling for the nodes in the parent Geometry. These override
* any labels determined by intersections.
*/
CopyNodesAndLabels(geomGraph, 0);
/*
* Build EdgeEnds for all intersections.
*/
EdgeEndBuilder eeBuilder = new EdgeEndBuilder();
IList eeList = eeBuilder.ComputeEdgeEnds(geomGraph.GetEdgeEnumerator());
InsertEdgeEnds(eeList);
}
/// <summary>
///
/// </summary>
/// <returns></returns>
public virtual IntersectionMatrix ComputeIm()
{
IntersectionMatrix im = new IntersectionMatrix();
// since Geometries are finite and embedded in a 2-D space, the EE element must always be 2
im.Set(LocationType.Exterior, LocationType.Exterior, DimensionType.Surface);
// if the Geometries don't overlap there is nothing to do
if (!_arg[0].Geometry.EnvelopeInternal.Intersects(_arg[1].Geometry.EnvelopeInternal))
{
ComputeDisjointIm(im);
return im;
}
_arg[0].ComputeSelfNodes(_li, false);
_arg[1].ComputeSelfNodes(_li, false);
// compute intersections between edges of the two input geometries
SegmentIntersector intersector = _arg[0].ComputeEdgeIntersections(_arg[1], _li, false);
ComputeIntersectionNodes(0);
ComputeIntersectionNodes(1);
/*
* Copy the labelling for the nodes in the parent Geometries. These override
* any labels determined by intersections between the geometries.
*/
CopyNodesAndLabels(0);
CopyNodesAndLabels(1);
// complete the labelling for any nodes which only have a label for a single point
LabelIsolatedNodes();
// If a proper intersection was found, we can set a lower bound on the IM.
ComputeProperIntersectionIm(intersector, im);
/*
* Now process improper intersections
* (eg where one or other of the geometries has a vertex at the intersection point)
* We need to compute the edge graph at all nodes to determine the IM.
*/
// build EdgeEnds for all intersections
EdgeEndBuilder eeBuilder = new EdgeEndBuilder();
IList ee0 = eeBuilder.ComputeEdgeEnds(_arg[0].GetEdgeEnumerator());
InsertEdgeEnds(ee0);
IList ee1 = eeBuilder.ComputeEdgeEnds(_arg[1].GetEdgeEnumerator());
InsertEdgeEnds(ee1);
LabelNodeEdges();
/*
* Compute the labeling for isolated components
* <br>
* Isolated components are components that do not touch any other components in the graph.
* They can be identified by the fact that they will
* contain labels containing ONLY a single element, the one for their parent point.
* We only need to check components contained in the input graphs, since
* isolated components will not have been replaced by new components formed by intersections.
*/
LabelIsolatedEdges(0, 1);
LabelIsolatedEdges(1, 0);
// update the IM from all components
UpdateIm(im);
return im;
}
/// <summary>
///
/// </summary>
/// <returns></returns>
public virtual IntersectionMatrix ComputeIm()
{
IntersectionMatrix im = new IntersectionMatrix();
// since Geometries are finite and embedded in a 2-D space, the EE element must always be 2
im.Set(LocationType.Exterior, LocationType.Exterior, DimensionType.Surface);
// if the Geometries don't overlap there is nothing to do
if (!_arg[0].Geometry.EnvelopeInternal.Intersects(_arg[1].Geometry.EnvelopeInternal))
{
ComputeDisjointIm(im);
return(im);
}
_arg[0].ComputeSelfNodes(_li, false);
_arg[1].ComputeSelfNodes(_li, false);
// compute intersections between edges of the two input geometries
SegmentIntersector intersector = _arg[0].ComputeEdgeIntersections(_arg[1], _li, false);
ComputeIntersectionNodes(0);
ComputeIntersectionNodes(1);
/*
* Copy the labelling for the nodes in the parent Geometries. These override
* any labels determined by intersections between the geometries.
*/
CopyNodesAndLabels(0);
CopyNodesAndLabels(1);
// complete the labelling for any nodes which only have a label for a single point
LabelIsolatedNodes();
// If a proper intersection was found, we can set a lower bound on the IM.
ComputeProperIntersectionIm(intersector, im);
/*
* Now process improper intersections
* (eg where one or other of the geometries has a vertex at the intersection point)
* We need to compute the edge graph at all nodes to determine the IM.
*/
// build EdgeEnds for all intersections
EdgeEndBuilder eeBuilder = new EdgeEndBuilder();
IList ee0 = eeBuilder.ComputeEdgeEnds(_arg[0].GetEdgeEnumerator());
InsertEdgeEnds(ee0);
IList ee1 = eeBuilder.ComputeEdgeEnds(_arg[1].GetEdgeEnumerator());
InsertEdgeEnds(ee1);
LabelNodeEdges();
/*
* Compute the labeling for isolated components
* <br>
* Isolated components are components that do not touch any other components in the graph.
* They can be identified by the fact that they will
* contain labels containing ONLY a single element, the one for their parent point.
* We only need to check components contained in the input graphs, since
* isolated components will not have been replaced by new components formed by intersections.
*/
LabelIsolatedEdges(0, 1);
LabelIsolatedEdges(1, 0);
// update the IM from all components
UpdateIm(im);
return(im);
}