EVOLUTION-MANAGER

Edit File: SIRtree.cpp

/********************************************************************** * * GEOS - Geometry Engine Open Source * http://geos.osgeo.org * * Copyright (C) 2006 Refractions Research Inc. * Copyright (C) 2001-2002 Vivid Solutions 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. * **********************************************************************/ #include <geos/index/strtree/SIRtree.h> #include <geos/index/strtree/AbstractNode.h> //#include <geos/util.h> #include <memory> #include <vector> #include <cassert> #include <algorithm> using namespace std; namespace geos { namespace index { // geos.index namespace strtree { // geos.index.strtree static bool compareSIRBoundables(Boundable* a, Boundable* b) { return AbstractSTRtree::compareDoubles(((Interval*)a->getBounds())->getCentre(), ((Interval*)b->getBounds())->getCentre()); } /*protected*/ std::unique_ptr<BoundableList> SIRtree::createParentBoundables(BoundableList* childBoundables, int newLevel) { assert(!childBoundables->empty()); std::unique_ptr<BoundableList> parentBoundables(new BoundableList()); parentBoundables->push_back(createNode(newLevel)); std::unique_ptr<BoundableList> sortedChildBoundables(sortBoundables(childBoundables)); //for(unsigned int i=0;i<sortedChildBoundables->size();i++) for(BoundableList::iterator i = sortedChildBoundables->begin(), e = sortedChildBoundables->end(); i != e; ++i) { //Boundable *childBoundable=(AbstractNode*)(*sortedChildBoundables)[i]; Boundable* childBoundable = *i; AbstractNode* lNode = lastNode(parentBoundables.get()); if(lNode->getChildBoundables()->size() == nodeCapacity) { parentBoundables->push_back(createNode(newLevel)); } lNode->addChildBoundable(childBoundable); } return parentBoundables; } bool SIRtree::SIRIntersectsOp::intersects(const void* aBounds, const void* bBounds) { return ((Interval*)aBounds)->intersects((Interval*)bBounds); } /*public*/ SIRtree::SIRtree(): AbstractSTRtree(10), intersectsOp(new SIRIntersectsOp()) { } /*public*/ SIRtree::SIRtree(size_t p_nodeCapacity): AbstractSTRtree(p_nodeCapacity), intersectsOp(new SIRIntersectsOp()) { } SIRtree::~SIRtree() { delete intersectsOp; } class SIRAbstractNode: public AbstractNode { public: SIRAbstractNode(int p_level, size_t capacity) : AbstractNode(p_level, capacity) {} ~SIRAbstractNode() override { delete(Interval*)bounds; } protected: void* computeBounds() const override { Interval* p_bounds = nullptr; const BoundableList& b = *getChildBoundables(); for(unsigned int i = 0; i < b.size(); ++i) { const Boundable* childBoundable = b[i]; if(p_bounds == nullptr) { p_bounds = new Interval(*((Interval*)childBoundable->getBounds())); } else { p_bounds->expandToInclude((Interval*)childBoundable->getBounds()); } } return p_bounds; } }; AbstractNode* SIRtree::createNode(int level) { AbstractNode* an = new SIRAbstractNode(level, nodeCapacity); nodes->push_back(an); return an; } /** * Inserts an item having the given bounds into the tree. */ void SIRtree::insert(double x1, double x2, void* item) { std::unique_ptr<Interval> i{new Interval(std::min(x1, x2), std::max(x1, x2))}; AbstractSTRtree::insert(i.get(), item); intervals.push_back(std::move(i)); } std::unique_ptr<BoundableList> SIRtree::sortBoundables(const BoundableList* input) { std::unique_ptr<BoundableList> output(new BoundableList(*input)); sort(output->begin(), output->end(), compareSIRBoundables); //output->sort(compareSIRBoundables); return output; } } // namespace geos.index.strtree } // namespace geos.index } // namespace geos