/****************************************************************************** * Project: libspatialindex - A C++ library for spatial indexing * Author: Marios Hadjieleftheriou, mhadji@gmail.com ****************************************************************************** * Copyright (c) 2003, Marios Hadjieleftheriou * * All rights reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. ******************************************************************************/ // NOTE: Please read README.txt before browsing this code. #include // include library header file. #include using namespace SpatialIndex; using namespace std; #define DELETE 0 #define INSERT 1 #define QUERY 2 // example of a Visitor pattern. // findes the index and leaf IO for answering the query and prints // the resulting data IDs to stdout. class MyVisitor : public IVisitor { public: size_t m_indexIO; size_t m_leafIO; public: MyVisitor() : m_indexIO(0), m_leafIO(0) {} void visitNode(const INode& n) { if (n.isLeaf()) m_leafIO++; else m_indexIO++; } void visitData(const IData& d) { //IShape* pS; //d.getShape(&pS); // do something. //delete pS; // data should be an array of characters representing a Region as a string. //byte* pData = 0; //size_t cLen = 0; //d.getData(cLen, &pData); // do something. //string s = reinterpret_cast(pData); //cout << s << endl; //delete[] pData; cout << d.getIdentifier() << endl; // the ID of this data entry is an answer to the query. I will just print it to stdout. } void visitData(std::vector& v) {} }; // example of a Strategy pattern. // traverses the tree by level. class MyQueryStrategy : public SpatialIndex::IQueryStrategy { private: queue ids; public: void getNextEntry(const IEntry& entry, id_type& nextEntry, bool& hasNext) { IShape* ps; entry.getShape(&ps); Region* pr = dynamic_cast(ps); cout << pr->m_pLow[0] << " " << pr->m_pLow[1] << endl; cout << pr->m_pHigh[0] << " " << pr->m_pLow[1] << endl; cout << pr->m_pHigh[0] << " " << pr->m_pHigh[1] << endl; cout << pr->m_pLow[0] << " " << pr->m_pHigh[1] << endl; cout << pr->m_pLow[0] << " " << pr->m_pLow[1] << endl << endl << endl; // print node MBRs gnuplot style! delete ps; const INode* n = dynamic_cast(&entry); // traverse only index nodes at levels 2 and higher. if (n != 0 && n->getLevel() > 1) { for (size_t cChild = 0; cChild < n->getChildrenCount(); cChild++) { ids.push(n->getChildIdentifier(cChild)); } } if (! ids.empty()) { nextEntry = ids.front(); ids.pop(); hasNext = true; } else { hasNext = false; } } }; // example of a Strategy pattern. // find the total indexed space managed by the index (the MBR of the root). class MyQueryStrategy2 : public IQueryStrategy { public: Region m_indexedSpace; public: void getNextEntry(const IEntry& entry, id_type& nextEntry, bool& hasNext) { // the first time we are called, entry points to the root. // stop after the root. hasNext = false; IShape* ps; entry.getShape(&ps); ps->getMBR(m_indexedSpace); delete ps; } }; int main(int argc, char** argv) { try { if (argc != 4) { cerr << "Usage: " << argv[0] << " query_file tree_file query_type [intersection | 10NN]." << endl; return -1; } uint32_t queryType = 0; if (strcmp(argv[3], "intersection") == 0) queryType = 0; else if (strcmp(argv[3], "10NN") == 0) queryType = 1; else { cerr << "Unknown query type." << endl; return -1; } ifstream fin(argv[1]); if (! fin) { cerr << "Cannot open query file " << argv[1] << "." << endl; return -1; } string baseName = argv[2]; IStorageManager* diskfile = StorageManager::loadDiskStorageManager(baseName); // this will try to locate and open an already existing storage manager. StorageManager::IBuffer* file = StorageManager::createNewRandomEvictionsBuffer(*diskfile, 10, false); // applies a main memory random buffer on top of the persistent storage manager // (LRU buffer, etc can be created the same way). // If we need to open an existing tree stored in the storage manager, we only // have to specify the index identifier as follows ISpatialIndex* tree = MVRTree::loadMVRTree(*file, 1); size_t count = 0; size_t indexIO = 0; size_t leafIO = 0; id_type id; uint32_t op; double x1, x2, y1, y2, t; double plow[2], phigh[2]; while (fin) { fin >> t >> op >> id >> x1 >> y1 >> x2 >> y2; if (! fin.good()) continue; // skip newlines, etc. if (op == QUERY) { size_t qt1, qt2; fin >> qt1 >> qt2; if (! fin.good()) continue; plow[0] = x1; plow[1] = y1; phigh[0] = x2; phigh[1] = y2; MyVisitor vis; if (queryType == 0) { TimeRegion r = TimeRegion(plow, phigh, qt1, qt2, 2); tree->intersectsWithQuery(r, vis); // this will find all data that intersect with the query range. } else { //Point p = Point(plow, 2); //tree->nearestNeighborQuery(10, p, vis); // this will find the 10 nearest neighbors. } indexIO += vis.m_indexIO; leafIO += vis.m_leafIO; // example of the Visitor pattern usage, for calculating how many nodes // were visited. } else { cerr << "This is not a query operation." << endl; } if ((count % 1000) == 0) cerr << count << endl; count++; } MyQueryStrategy2 qs; tree->queryStrategy(qs); cerr << "Indexed space: " << qs.m_indexedSpace << endl; cerr << "Operations: " << count << endl; cerr << *tree; cerr << "Index I/O: " << indexIO << endl; cerr << "Leaf I/O: " << leafIO << endl; cerr << "Buffer hits: " << file->getHits() << endl; delete tree; delete file; delete diskfile; // delete the buffer first, then the storage manager // (otherwise the the buffer will fail writting the dirty entries). } catch (Tools::Exception& e) { cerr << "******ERROR******" << endl; std::string s = e.what(); cerr << s << endl; return -1; } catch (...) { cerr << "******ERROR******" << endl; cerr << "other exception" << endl; return -1; } return 0; }