/* Copyright 2008 Intel Corporation Use, modification and distribution are subject to the Boost Software License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt). */ #ifndef BOOST_POLYGON_MAX_COVER_HPP #define BOOST_POLYGON_MAX_COVER_HPP namespace boost { namespace polygon{ template struct MaxCover { typedef interval_data Interval; typedef rectangle_data Rectangle; class Node { private: std::vector children_; std::set tracedPaths_; public: Rectangle rect; Node() : children_(), tracedPaths_(), rect() {} Node(const Rectangle rectIn) : children_(), tracedPaths_(), rect(rectIn) {} typedef typename std::vector::iterator iterator; inline iterator begin() { return children_.begin(); } inline iterator end() { return children_.end(); } inline void add(Node* child) { children_.push_back(child); } inline bool tracedPath(const Interval& ivl) const { return tracedPaths_.find(ivl) != tracedPaths_.end(); } inline void addPath(const Interval& ivl) { tracedPaths_.insert(tracedPaths_.end(), ivl); } }; typedef std::pair, Node* > EdgeAssociation; class lessEdgeAssociation : public std::binary_function { public: inline lessEdgeAssociation() {} inline bool operator () (const EdgeAssociation& elem1, const EdgeAssociation& elem2) const { if(elem1.first.first < elem2.first.first) return true; if(elem1.first.first > elem2.first.first) return false; return elem1.first.second < elem2.first.second; } }; template static inline void getMaxCover(cT& outputContainer, Node* node, orientation_2d orient) { Interval rectIvl = node->rect.get(orient); if(node->tracedPath(rectIvl)) { return; } node->addPath(rectIvl); if(node->begin() == node->end()) { //std::cout << "WRITE OUT 3: " << node->rect << std::endl; outputContainer.push_back(copy_construct(node->rect)); return; } bool writeOut = true; for(typename Node::iterator itr = node->begin(); itr != node->end(); ++itr) { getMaxCover(outputContainer, *itr, orient, node->rect); //get rectangles down path Interval nodeIvl = (*itr)->rect.get(orient); if(contains(nodeIvl, rectIvl, true)) writeOut = false; } if(writeOut) { //std::cout << "WRITE OUT 2: " << node->rect << std::endl; outputContainer.push_back(copy_construct(node->rect)); } } struct stack_element { inline stack_element() : node(), rect(), itr() {} inline stack_element(Node* n, const Rectangle& r, typename Node::iterator i) : node(n), rect(r), itr(i) {} Node* node; Rectangle rect; typename Node::iterator itr; }; template static inline void getMaxCover(cT& outputContainer, Node* node, orientation_2d orient, Rectangle rect) { //std::cout << "New Root\n"; std::vector stack; typename Node::iterator itr = node->begin(); do { //std::cout << "LOOP\n"; //std::cout << node->rect << std::endl; Interval rectIvl = rect.get(orient); Interval nodeIvl = node->rect.get(orient); bool iresult = intersect(rectIvl, nodeIvl, false); bool tresult = !node->tracedPath(rectIvl); //std::cout << (itr != node->end()) << " " << iresult << " " << tresult << std::endl; Rectangle nextRect1 = Rectangle(rectIvl, rectIvl); Unit low = rect.get(orient.get_perpendicular()).low(); Unit high = node->rect.get(orient.get_perpendicular()).high(); nextRect1.set(orient.get_perpendicular(), Interval(low, high)); if(iresult && tresult) { node->addPath(rectIvl); bool writeOut = true; //check further visibility beyond this node for(typename Node::iterator itr2 = node->begin(); itr2 != node->end(); ++itr2) { Interval nodeIvl3 = (*itr2)->rect.get(orient); //if a child of this node can contain the interval then we can extend through if(contains(nodeIvl3, rectIvl, true)) writeOut = false; //std::cout << "child " << (*itr2)->rect << std::endl; } Rectangle nextRect2 = Rectangle(rectIvl, rectIvl); Unit low2 = rect.get(orient.get_perpendicular()).low(); Unit high2 = node->rect.get(orient.get_perpendicular()).high(); nextRect2.set(orient.get_perpendicular(), Interval(low2, high2)); if(writeOut) { //std::cout << "write out " << nextRect << std::endl; outputContainer.push_back(copy_construct(nextRect2)); } else { //std::cout << "suppress " << nextRect << std::endl; } } if(itr != node->end() && iresult && tresult) { //std::cout << "recurse into child\n"; stack.push_back(stack_element(node, rect, itr)); rect = nextRect1; node = *itr; itr = node->begin(); } else { if(!stack.empty()) { //std::cout << "recurse out of child\n"; node = stack.back().node; rect = stack.back().rect; itr = stack.back().itr; stack.pop_back(); } else { //std::cout << "empty stack\n"; //if there were no children of the root node // Rectangle nextRect = Rectangle(rectIvl, rectIvl); // Unit low = rect.get(orient.get_perpendicular()).low(); // Unit high = node->rect.get(orient.get_perpendicular()).high(); // nextRect.set(orient.get_perpendicular(), Interval(low, high)); // outputContainer.push_back(copy_construct(nextRect)); } //std::cout << "increment " << (itr != node->end()) << std::endl; if(itr != node->end()) { ++itr; if(itr != node->end()) { //std::cout << "recurse into next child.\n"; stack.push_back(stack_element(node, rect, itr)); Interval rectIvl2 = rect.get(orient); Interval nodeIvl2 = node->rect.get(orient); /*bool iresult =*/ intersect(rectIvl2, nodeIvl2, false); Rectangle nextRect2 = Rectangle(rectIvl2, rectIvl2); Unit low2 = rect.get(orient.get_perpendicular()).low(); Unit high2 = node->rect.get(orient.get_perpendicular()).high(); nextRect2.set(orient.get_perpendicular(), Interval(low2, high2)); rect = nextRect2; //std::cout << "rect for next child" << rect << std::endl; node = *itr; itr = node->begin(); } } } } while(!stack.empty() || itr != node->end()); } /* Function recursive version of getMaxCover Because the code is so much simpler than the loop algorithm I retain it for clarity template static inline void getMaxCover(cT& outputContainer, Node* node, orientation_2d orient, const Rectangle& rect) { Interval rectIvl = rect.get(orient); Interval nodeIvl = node->rect.get(orient); if(!intersect(rectIvl, nodeIvl, false)) { return; } if(node->tracedPath(rectIvl)) { return; } node->addPath(rectIvl); Rectangle nextRect(rectIvl, rectIvl); Unit low = rect.get(orient.get_perpendicular()).low(); Unit high = node->rect.get(orient.get_perpendicular()).high(); nextRect.set(orient.get_perpendicular(), Interval(low, high)); bool writeOut = true; rectIvl = nextRect.get(orient); for(typename Node::iterator itr = node->begin(); itr != node->end(); ++itr) { nodeIvl = (*itr)->rect.get(orient); if(contains(nodeIvl, rectIvl, true)) writeOut = false; } if(writeOut) { outputContainer.push_back(copy_construct(nextRect)); } for(typename Node::iterator itr = node->begin(); itr != node->end(); ++itr) { getMaxCover(outputContainer, *itr, orient, nextRect); } } */ //iterator range is assummed to be in topological order meaning all node's trailing //edges are in sorted order template static inline void computeDag(iT beginNode, iT endNode, orientation_2d orient, std::size_t size) { std::vector leadingEdges; leadingEdges.reserve(size); for(iT iter = beginNode; iter != endNode; ++iter) { Node* nodep = &(*iter); Unit leading = nodep->rect.get(orient.get_perpendicular()).low(); Interval rectIvl = nodep->rect.get(orient); leadingEdges.push_back(EdgeAssociation(std::pair(leading, rectIvl), nodep)); } polygon_sort(leadingEdges.begin(), leadingEdges.end(), lessEdgeAssociation()); typename std::vector::iterator leadingBegin = leadingEdges.begin(); iT trailingBegin = beginNode; while(leadingBegin != leadingEdges.end()) { EdgeAssociation& leadingSegment = (*leadingBegin); Unit trailing = (*trailingBegin).rect.get(orient.get_perpendicular()).high(); Interval ivl = (*trailingBegin).rect.get(orient); std::pair trailingSegment(trailing, ivl); if(leadingSegment.first.first < trailingSegment.first) { ++leadingBegin; continue; } if(leadingSegment.first.first > trailingSegment.first) { ++trailingBegin; continue; } if(leadingSegment.first.second.high() <= trailingSegment.second.low()) { ++leadingBegin; continue; } if(trailingSegment.second.high() <= leadingSegment.first.second.low()) { ++trailingBegin; continue; } //leading segment intersects trailing segment (*trailingBegin).add((*leadingBegin).second); if(leadingSegment.first.second.high() > trailingSegment.second.high()) { ++trailingBegin; continue; } if(trailingSegment.second.high() > leadingSegment.first.second.high()) { ++leadingBegin; continue; } ++leadingBegin; ++trailingBegin; } } template static inline void getMaxCover(cT& outputContainer, const std::vector& rects, orientation_2d orient) { if(rects.empty()) return; std::vector nodes; { if(rects.size() == 1) { outputContainer.push_back(copy_construct(rects[0])); return; } nodes.reserve(rects.size()); for(std::size_t i = 0; i < rects.size(); ++i) { nodes.push_back(Node(rects[i])); } } computeDag(nodes.begin(), nodes.end(), orient, nodes.size()); for(std::size_t i = 0; i < nodes.size(); ++i) { getMaxCover(outputContainer, &(nodes[i]), orient); } } }; } } #endif