/********************************************************************** * * GEOS - Geometry Engine Open Source * http://geos.osgeo.org * * Copyright (C) 2006 Refractions Research Inc. * * This is free software; you can redistribute and/or modify it under * the terms of the GNU Lesser General Public Licence as published * by the Free Software Foundation. * See the COPYING file for more information. * ********************************************************************** * * Last port: operation/overlay/PolygonBuilder.java rev. 1.20 (JTS-1.10) * **********************************************************************/ #pragma once #include #include #include #ifdef _MSC_VER #pragma warning(push) #pragma warning(disable: 4251) // warning C4251: needs to have dll-interface to be used by clients of class #endif // Forward declarations namespace geos { namespace geom { class Geometry; class Coordinate; class GeometryFactory; } namespace geomgraph { class EdgeRing; class Node; class PlanarGraph; class DirectedEdge; } namespace operation { namespace overlay { class MaximalEdgeRing; class MinimalEdgeRing; } } } namespace geos { namespace operation { // geos::operation namespace overlay { // geos::operation::overlay /** \brief * Forms Polygon out of a graph of geomgraph::DirectedEdge. * * The edges to use are marked as being in the result Area. */ class GEOS_DLL PolygonBuilder { public: PolygonBuilder(const geom::GeometryFactory* newGeometryFactory); ~PolygonBuilder(); /** * Add a complete graph. * The graph is assumed to contain one or more polygons, * possibly with holes. */ void add(geomgraph::PlanarGraph* graph); // throw(const TopologyException &) /** * Add a set of edges and nodes, which form a graph. * The graph is assumed to contain one or more polygons, * possibly with holes. */ void add(const std::vector* dirEdges, const std::vector* nodes); // throw(const TopologyException &) std::vector> getPolygons(); private: const geom::GeometryFactory* geometryFactory; std::vector shellList; /** * For all DirectedEdges in result, form them into MaximalEdgeRings * * @param maxEdgeRings * Formed MaximalEdgeRings will be pushed to this vector. * Ownership of the elements is transferred to caller. */ void buildMaximalEdgeRings( const std::vector* dirEdges, std::vector& maxEdgeRings); // throw(const TopologyException &) void buildMinimalEdgeRings( std::vector& maxEdgeRings, std::vector& newShellList, std::vector& freeHoleList, std::vector& edgeRings); /** * This method takes a list of MinimalEdgeRings derived from a * MaximalEdgeRing, and tests whether they form a Polygon. * This is the case if there is a single shell * in the list. In this case the shell is returned. * The other possibility is that they are a series of connected * holes, in which case no shell is returned. * * @return the shell geomgraph::EdgeRing, if there is one * @return NULL, if all the rings are holes */ geomgraph::EdgeRing* findShell(std::vector* minEdgeRings); /** * This method assigns the holes for a Polygon (formed from a list of * MinimalEdgeRings) to its shell. * Determining the holes for a MinimalEdgeRing polygon serves two * purposes: * * - it is faster than using a point-in-polygon check later on. * - it ensures correctness, since if the PIP test was used the point * chosen might lie on the shell, which might return an incorrect * result from the PIP test */ void placePolygonHoles(geomgraph::EdgeRing* shell, std::vector* minEdgeRings); /** * For all rings in the input list, * determine whether the ring is a shell or a hole * and add it to the appropriate list. * Due to the way the DirectedEdges were linked, * a ring is a shell if it is oriented CW, a hole otherwise. */ void sortShellsAndHoles(std::vector& edgeRings, std::vector& newShellList, std::vector& freeHoleList); struct FastPIPRing { geomgraph::EdgeRing* edgeRing; algorithm::locate::IndexedPointInAreaLocator* pipLocator; }; /** \brief * This method determines finds a containing shell for all holes * which have not yet been assigned to a shell. * * These "free" holes should all be properly contained in * their parent shells, so it is safe to use the * findEdgeRingContaining method. * This is the case because any holes which are NOT * properly contained (i.e. are connected to their * parent shell) would have formed part of a MaximalEdgeRing * and been handled in a previous step. * * @throws TopologyException if a hole cannot be assigned to a shell */ void placeFreeHoles(std::vector& newShellList, std::vector& freeHoleList); // throw(const TopologyException&) /** \brief * Find the innermost enclosing shell geomgraph::EdgeRing containing the * argument geomgraph::EdgeRing, if any. * * The innermost enclosing ring is the smallest enclosing ring. * The algorithm used depends on the fact that: * * ring A contains ring B iff envelope(ring A) * contains envelope(ring B) * * This routine is only safe to use if the chosen point of the hole * is known to be properly contained in a shell * (which is guaranteed to be the case if the hole does not touch * its shell) * * @return containing geomgraph::EdgeRing, if there is one * @return NULL if no containing geomgraph::EdgeRing is found */ geomgraph::EdgeRing* findEdgeRingContaining(geomgraph::EdgeRing* testEr, std::vector& newShellList); std::vector> computePolygons( std::vector& newShellList); /** * Checks the current set of shells (with their associated holes) to * see if any of them contain the point. */ }; } // namespace geos::operation::overlay } // namespace geos::operation } // namespace geos #ifdef _MSC_VER #pragma warning(pop) #endif