OpenCV 5.0.0-pre
Open Source Computer Vision
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cv::Subdiv2D Class Reference

#include <opencv2/imgproc.hpp>

Collaboration diagram for cv::Subdiv2D:

Classes

struct  QuadEdge
 
struct  Vertex
 

Public Types

enum  {
  PTLOC_ERROR = -2 ,
  PTLOC_OUTSIDE_RECT = -1 ,
  PTLOC_INSIDE = 0 ,
  PTLOC_VERTEX = 1 ,
  PTLOC_ON_EDGE = 2
}
 
enum  {
  NEXT_AROUND_ORG = 0x00 ,
  NEXT_AROUND_DST = 0x22 ,
  PREV_AROUND_ORG = 0x11 ,
  PREV_AROUND_DST = 0x33 ,
  NEXT_AROUND_LEFT = 0x13 ,
  NEXT_AROUND_RIGHT = 0x31 ,
  PREV_AROUND_LEFT = 0x20 ,
  PREV_AROUND_RIGHT = 0x02
}
 

Public Member Functions

 Subdiv2D ()
 
 Subdiv2D (Rect rect)
 
int edgeDst (int edge, Point2f *dstpt=0) const
 Returns the edge destination.
 
int edgeOrg (int edge, Point2f *orgpt=0) const
 Returns the edge origin.
 
int findNearest (Point2f pt, Point2f *nearestPt=0)
 Finds the subdivision vertex closest to the given point.
 
int getEdge (int edge, int nextEdgeType) const
 Returns one of the edges related to the given edge.
 
void getEdgeList (std::vector< Vec4f > &edgeList) const
 Returns a list of all edges.
 
void getLeadingEdgeList (std::vector< int > &leadingEdgeList) const
 Returns a list of the leading edge ID connected to each triangle.
 
void getTriangleList (std::vector< Vec6f > &triangleList) const
 Returns a list of all triangles.
 
Point2f getVertex (int vertex, int *firstEdge=0) const
 Returns vertex location from vertex ID.
 
void getVoronoiFacetList (const std::vector< int > &idx, std::vector< std::vector< Point2f > > &facetList, std::vector< Point2f > &facetCenters)
 Returns a list of all Voronoi facets.
 
void initDelaunay (Rect rect)
 Creates a new empty Delaunay subdivision.
 
void insert (const std::vector< Point2f > &ptvec)
 Insert multiple points into a Delaunay triangulation.
 
int insert (Point2f pt)
 Insert a single point into a Delaunay triangulation.
 
int locate (Point2f pt, int &edge, int &vertex)
 Returns the location of a point within a Delaunay triangulation.
 
int nextEdge (int edge) const
 Returns next edge around the edge origin.
 
int rotateEdge (int edge, int rotate) const
 Returns another edge of the same quad-edge.
 
int symEdge (int edge) const
 

Protected Member Functions

void calcVoronoi ()
 
void checkSubdiv () const
 
void clearVoronoi ()
 
int connectEdges (int edgeA, int edgeB)
 
void deleteEdge (int edge)
 
void deletePoint (int vtx)
 
int isRightOf (Point2f pt, int edge) const
 
int newEdge ()
 
int newPoint (Point2f pt, bool isvirtual, int firstEdge=0)
 
void setEdgePoints (int edge, int orgPt, int dstPt)
 
void splice (int edgeA, int edgeB)
 
void swapEdges (int edge)
 

Protected Attributes

Point2f bottomRight
 Bottom right corner of the bounding rect.
 
int freePoint
 
int freeQEdge
 
std::vector< QuadEdgeqedges
 All of the edges.
 
int recentEdge
 
Point2f topLeft
 Top left corner of the bounding rect.
 
bool validGeometry
 
std::vector< Vertexvtx
 All of the vertices.
 

Member Enumeration Documentation

◆ anonymous enum

anonymous enum

Subdiv2D point location cases

Enumerator
PTLOC_ERROR 

Point location error.

PTLOC_OUTSIDE_RECT 

Point outside the subdivision bounding rect.

PTLOC_INSIDE 

Point inside some facet.

PTLOC_VERTEX 

Point coincides with one of the subdivision vertices.

PTLOC_ON_EDGE 

Point on some edge.

◆ anonymous enum

anonymous enum

Subdiv2D edge type navigation (see: getEdge())

Enumerator
NEXT_AROUND_ORG 
NEXT_AROUND_DST 
PREV_AROUND_ORG 
PREV_AROUND_DST 
NEXT_AROUND_LEFT 
NEXT_AROUND_RIGHT 
PREV_AROUND_LEFT 
PREV_AROUND_RIGHT 

Constructor & Destructor Documentation

◆ Subdiv2D() [1/2]

cv::Subdiv2D::Subdiv2D ( )
Python:
cv.Subdiv2D() -> <Subdiv2D object>
cv.Subdiv2D(rect) -> <Subdiv2D object>

creates an empty Subdiv2D object. To create a new empty Delaunay subdivision you need to use the initDelaunay function.

◆ Subdiv2D() [2/2]

cv::Subdiv2D::Subdiv2D ( Rect rect)
Python:
cv.Subdiv2D() -> <Subdiv2D object>
cv.Subdiv2D(rect) -> <Subdiv2D object>

This is an overloaded member function, provided for convenience. It differs from the above function only in what argument(s) it accepts.

Parameters
rectRectangle that includes all of the 2D points that are to be added to the subdivision.

The function creates an empty Delaunay subdivision where 2D points can be added using the function insert() . All of the points to be added must be within the specified rectangle, otherwise a runtime error is raised.

Member Function Documentation

◆ calcVoronoi()

void cv::Subdiv2D::calcVoronoi ( )
protected

◆ checkSubdiv()

void cv::Subdiv2D::checkSubdiv ( ) const
protected

◆ clearVoronoi()

void cv::Subdiv2D::clearVoronoi ( )
protected

◆ connectEdges()

int cv::Subdiv2D::connectEdges ( int edgeA,
int edgeB )
protected

◆ deleteEdge()

void cv::Subdiv2D::deleteEdge ( int edge)
protected

◆ deletePoint()

void cv::Subdiv2D::deletePoint ( int vtx)
protected

◆ edgeDst()

int cv::Subdiv2D::edgeDst ( int edge,
Point2f * dstpt = 0 ) const
Python:
cv.Subdiv2D.edgeDst(edge) -> retval, dstpt

Returns the edge destination.

Parameters
edgeSubdivision edge ID.
dstptOutput vertex location.
Returns
vertex ID.

◆ edgeOrg()

int cv::Subdiv2D::edgeOrg ( int edge,
Point2f * orgpt = 0 ) const
Python:
cv.Subdiv2D.edgeOrg(edge) -> retval, orgpt

Returns the edge origin.

Parameters
edgeSubdivision edge ID.
orgptOutput vertex location.
Returns
vertex ID.

◆ findNearest()

int cv::Subdiv2D::findNearest ( Point2f pt,
Point2f * nearestPt = 0 )
Python:
cv.Subdiv2D.findNearest(pt) -> retval, nearestPt

Finds the subdivision vertex closest to the given point.

Parameters
ptInput point.
nearestPtOutput subdivision vertex point.

The function is another function that locates the input point within the subdivision. It finds the subdivision vertex that is the closest to the input point. It is not necessarily one of vertices of the facet containing the input point, though the facet (located using locate() ) is used as a starting point.

Returns
vertex ID.

◆ getEdge()

int cv::Subdiv2D::getEdge ( int edge,
int nextEdgeType ) const
Python:
cv.Subdiv2D.getEdge(edge, nextEdgeType) -> retval

Returns one of the edges related to the given edge.

Parameters
edgeSubdivision edge ID.
nextEdgeTypeParameter specifying which of the related edges to return. The following values are possible:
  • NEXT_AROUND_ORG next around the edge origin ( eOnext on the picture below if e is the input edge)
  • NEXT_AROUND_DST next around the edge vertex ( eDnext )
  • PREV_AROUND_ORG previous around the edge origin (reversed eRnext )
  • PREV_AROUND_DST previous around the edge destination (reversed eLnext )
  • NEXT_AROUND_LEFT next around the left facet ( eLnext )
  • NEXT_AROUND_RIGHT next around the right facet ( eRnext )
  • PREV_AROUND_LEFT previous around the left facet (reversed eOnext )
  • PREV_AROUND_RIGHT previous around the right facet (reversed eDnext )
sample output
Returns
edge ID related to the input edge.

◆ getEdgeList()

void cv::Subdiv2D::getEdgeList ( std::vector< Vec4f > & edgeList) const
Python:
cv.Subdiv2D.getEdgeList() -> edgeList

Returns a list of all edges.

Parameters
edgeListOutput vector.

The function gives each edge as a 4 numbers vector, where each two are one of the edge vertices. i.e. org_x = v[0], org_y = v[1], dst_x = v[2], dst_y = v[3].

◆ getLeadingEdgeList()

void cv::Subdiv2D::getLeadingEdgeList ( std::vector< int > & leadingEdgeList) const
Python:
cv.Subdiv2D.getLeadingEdgeList() -> leadingEdgeList

Returns a list of the leading edge ID connected to each triangle.

Parameters
leadingEdgeListOutput vector.

The function gives one edge ID for each triangle.

◆ getTriangleList()

void cv::Subdiv2D::getTriangleList ( std::vector< Vec6f > & triangleList) const
Python:
cv.Subdiv2D.getTriangleList() -> triangleList

Returns a list of all triangles.

Parameters
triangleListOutput vector.

The function gives each triangle as a 6 numbers vector, where each two are one of the triangle vertices. i.e. p1_x = v[0], p1_y = v[1], p2_x = v[2], p2_y = v[3], p3_x = v[4], p3_y = v[5].

◆ getVertex()

Point2f cv::Subdiv2D::getVertex ( int vertex,
int * firstEdge = 0 ) const
Python:
cv.Subdiv2D.getVertex(vertex) -> retval, firstEdge

Returns vertex location from vertex ID.

Parameters
vertexvertex ID.
firstEdgeOptional. The first edge ID which is connected to the vertex.
Returns
vertex (x,y)

◆ getVoronoiFacetList()

void cv::Subdiv2D::getVoronoiFacetList ( const std::vector< int > & idx,
std::vector< std::vector< Point2f > > & facetList,
std::vector< Point2f > & facetCenters )
Python:
cv.Subdiv2D.getVoronoiFacetList(idx) -> facetList, facetCenters

Returns a list of all Voronoi facets.

Parameters
idxVector of vertices IDs to consider. For all vertices you can pass empty vector.
facetListOutput vector of the Voronoi facets.
facetCentersOutput vector of the Voronoi facets center points.

◆ initDelaunay()

void cv::Subdiv2D::initDelaunay ( Rect rect)
Python:
cv.Subdiv2D.initDelaunay(rect) -> None

Creates a new empty Delaunay subdivision.

Parameters
rectRectangle that includes all of the 2D points that are to be added to the subdivision.

◆ insert() [1/2]

void cv::Subdiv2D::insert ( const std::vector< Point2f > & ptvec)
Python:
cv.Subdiv2D.insert(pt) -> retval
cv.Subdiv2D.insert(ptvec) -> None

Insert multiple points into a Delaunay triangulation.

Parameters
ptvecPoints to insert.

The function inserts a vector of points into a subdivision and modifies the subdivision topology appropriately.

◆ insert() [2/2]

int cv::Subdiv2D::insert ( Point2f pt)
Python:
cv.Subdiv2D.insert(pt) -> retval
cv.Subdiv2D.insert(ptvec) -> None

Insert a single point into a Delaunay triangulation.

Parameters
ptPoint to insert.

The function inserts a single point into a subdivision and modifies the subdivision topology appropriately. If a point with the same coordinates exists already, no new point is added.

Returns
the ID of the point.
Note
If the point is outside of the triangulation specified rect a runtime error is raised.

◆ isRightOf()

int cv::Subdiv2D::isRightOf ( Point2f pt,
int edge ) const
protected

◆ locate()

int cv::Subdiv2D::locate ( Point2f pt,
int & edge,
int & vertex )
Python:
cv.Subdiv2D.locate(pt) -> retval, edge, vertex

Returns the location of a point within a Delaunay triangulation.

Parameters
ptPoint to locate.
edgeOutput edge that the point belongs to or is located to the right of it.
vertexOptional output vertex the input point coincides with.

The function locates the input point within the subdivision and gives one of the triangle edges or vertices.

Returns
an integer which specify one of the following five cases for point location:
  • The point falls into some facet. The function returns PTLOC_INSIDE and edge will contain one of edges of the facet.
  • The point falls onto the edge. The function returns PTLOC_ON_EDGE and edge will contain this edge.
  • The point coincides with one of the subdivision vertices. The function returns PTLOC_VERTEX and vertex will contain a pointer to the vertex.
  • The point is outside the subdivision reference rectangle. The function returns PTLOC_OUTSIDE_RECT and no pointers are filled.
  • One of input arguments is invalid. A runtime error is raised or, if silent or "parent" error processing mode is selected, PTLOC_ERROR is returned.

◆ newEdge()

int cv::Subdiv2D::newEdge ( )
protected

◆ newPoint()

int cv::Subdiv2D::newPoint ( Point2f pt,
bool isvirtual,
int firstEdge = 0 )
protected

◆ nextEdge()

int cv::Subdiv2D::nextEdge ( int edge) const
Python:
cv.Subdiv2D.nextEdge(edge) -> retval

Returns next edge around the edge origin.

Parameters
edgeSubdivision edge ID.
Returns
an integer which is next edge ID around the edge origin: eOnext on the picture above if e is the input edge).

◆ rotateEdge()

int cv::Subdiv2D::rotateEdge ( int edge,
int rotate ) const
Python:
cv.Subdiv2D.rotateEdge(edge, rotate) -> retval

Returns another edge of the same quad-edge.

Parameters
edgeSubdivision edge ID.
rotateParameter specifying which of the edges of the same quad-edge as the input one to return. The following values are possible:
  • 0 - the input edge ( e on the picture below if e is the input edge)
  • 1 - the rotated edge ( eRot )
  • 2 - the reversed edge (reversed e (in green))
  • 3 - the reversed rotated edge (reversed eRot (in green))
Returns
one of the edges ID of the same quad-edge as the input edge.

◆ setEdgePoints()

void cv::Subdiv2D::setEdgePoints ( int edge,
int orgPt,
int dstPt )
protected

◆ splice()

void cv::Subdiv2D::splice ( int edgeA,
int edgeB )
protected

◆ swapEdges()

void cv::Subdiv2D::swapEdges ( int edge)
protected

◆ symEdge()

int cv::Subdiv2D::symEdge ( int edge) const
Python:
cv.Subdiv2D.symEdge(edge) -> retval

Member Data Documentation

◆ bottomRight

Point2f cv::Subdiv2D::bottomRight
protected

Bottom right corner of the bounding rect.

◆ freePoint

int cv::Subdiv2D::freePoint
protected

◆ freeQEdge

int cv::Subdiv2D::freeQEdge
protected

◆ qedges

std::vector<QuadEdge> cv::Subdiv2D::qedges
protected

All of the edges.

◆ recentEdge

int cv::Subdiv2D::recentEdge
protected

◆ topLeft

Point2f cv::Subdiv2D::topLeft
protected

Top left corner of the bounding rect.

◆ validGeometry

bool cv::Subdiv2D::validGeometry
protected

◆ vtx

std::vector<Vertex> cv::Subdiv2D::vtx
protected

All of the vertices.


The documentation for this class was generated from the following file: