Exemplo n.º 1
0
int main()
{
  std::ifstream ifs("data/sites.cin");
  assert( ifs );

  Apollonius_graph ag;
  Apollonius_graph::Site_2 site;

  // read the sites and insert them in the Apollonius graph
  while ( ifs >> site ) {
    ag.insert(site);
  }

  // validate the Apollonius graph
  assert( ag.is_valid(true, 1) );
  std::cout << std::endl;

  return 0;
}
Exemplo n.º 2
0
int main()
{
  std::ifstream ifs("../data/sites.cin");
  assert( ifs );

  Apollonius_graph ag;
  Apollonius_graph::Site_2 site;

  int k = 0;
  // read the sites and insert them in the Apollonius graph
  while ( ifs >> site ) {
    std::cout << "inserting: " << ++k << std::endl;
    std::cout << site << std::endl;
    ag.insert(site);
    size_t nof = ag.number_of_faces ();
    std::cout << "number of faces: " << nof << std::endl;
  }

  // validate the Apollonius graph
  assert( ag.is_valid(true, 1) );
  std::cout << std::endl;

  size_t nof = ag.number_of_faces ();
  std::cout << "number of faces: " << nof << std::endl;

  for (All_faces_iterator fiter = ag.all_faces_begin (); fiter != ag.all_faces_end(); ++fiter) { 
    Face face = *fiter;
    Vertex_handle vertex = face.vertex(0);
    Vertex v = *vertex;
    //v.point();
    //std::cout << "face: " << face << std::endl;
    //std::cout << "vertex: " << vertex.point() << std::endl;
    std::cout << "vertex: " << v << std::endl;
  }

  return 0;
}
Exemplo n.º 3
0
int main(int argc , char* argv[])
{
  if (argc < 7) {
    std::cerr << "usage: test <input file> <output folder> "
      "<format (wkt | geojson | sql)> <weight city> <weight town> <weight village>" << std::endl;
    exit(1);
  }

  char* input = argv[1];
  char* outdir = argv[2];
  char* format = argv[3];

  char* swc = argv[4];
  char* swt = argv[5];
  char* swv = argv[6];

  std::ifstream ifs(input);
  assert( ifs );

  double wc, wt, wv;
  std::istringstream stmc, stmt, stmv;
  stmc.str(swc);
  stmc >> wc;
  stmt.str(swt);
  stmt >> wt;
  stmv.str(swv);
  stmv >> wv;

  std::cerr << "using weights: city: " << wc << ", town: " << wt << ", village: " << wv << std::endl;

  /*
   * prepare data
   */

  // we use a ScalingFactor(SF) here to stretch input values at the
  // beginning, and divide by SF in the end. This is used because the
  // point-generation of the hyperbola class is using some arbitrary
  // internal decision thresholds to decide how many points to generate for
  // a certain part of the curve. Rule of thumb is: the higher SF the more
  // detail is used in approximation of the hyperbolas.
  double SF = 4000;

  // read in sites from input file
  SiteList sites = readSites(ifs, SF, wc, wt, wv);

  printSites(sites);

  // calculate bounding box of all input sites (and extend it a little).
  // Extension is important, because we later add artificial sites which are
  // actually mirrored on the bounds of this rectangle. If we did not extend
  // some points would lie on the boundary of the bounding box and so would
  // their artificial clones. This would complicate the whole stuff a lot :)
  Iso_rectangle_2 crect = extend(boundingBox(sites), 0.1*SF);
  std::cerr << "rect: " << crect << std::endl;

  // a number of artificial sites
  SiteList artificialSites = createArtificialSites(sites, crect);

  /*
   * create Apollonius graph
   */

  Apollonius_graph ag;

  SiteList::iterator itr;
  // add all original sites to the apollonius graph
  for (itr = sites.begin(); itr != sites.end(); ++itr) {
    Site_2 site = *itr;
    ag.insert(site);
  }
  // add all artificial sites to the apollonius graph
  for (itr = artificialSites.begin(); itr != artificialSites.end(); ++itr) {
    Site_2 site = *itr;
    ag.insert(site);
  }

  // validate the Apollonius graph
  assert( ag.is_valid(true, 1) );
  std::cerr << std::endl;

  /*
   * create polygons from cells
   */

  // we want an identifier for each vertex within the iteration.
  // this is a loop iteration counter
  int vertexIndex = 0;

  // for each vertex in the apollonius graph (this are the sites)
  for (All_vertices_iterator viter = ag.all_vertices_begin ();
      viter != ag.all_vertices_end(); ++viter) {
    // get the corresponding site
    Site_2 site = viter->site();
    Point_2 point = site.point();
    // ignore artifical sites, detect them by their position
    if (!CGAL::do_intersect(crect, point)) {
      continue;
    }
    std::cerr << "vertex " << ++vertexIndex << std::endl;

    // we than circulate all incident edges. By obtaining the respective
    // dual of each edge, we get access to the objects forming the boundary
    // of each voronoi cell in a proper order.
    Edge_circulator ecirc = ag.incident_edges(viter), done(ecirc);
    // this is where we store the polylines
    std::vector<PointList> polylines;
    // for each incident edge
    do {
      // the program may fail in certain situations without this test.
      // acutally !is_infinite(edge) is a precondition in ag.dual(edge).
      if (ag.is_infinite(*ecirc)) {
        continue;
      }
      // NOTE: for this to work, we had to make public the dual function in ApolloniusGraph
      // change line 542 in "Apollonius_graph_2.h" from "private:" to "public:"
      Object_2 o = ag.dual(*ecirc);
      handleDual(o, crect, polylines);
    } while(++ecirc != done);

    PointList polygon = buildPolygon(site, polylines);
    for (int i = 0; i < polygon.size(); i++) {
      Point_2& p = polygon.at(i);
      p = Point_2(p.x()/SF, p.y()/SF);
    }
    if(std::string(format) == "geojson") {
      writeGeoJSON(site, polygon, outdir);
    } else if(std::string(format) == "sql") {
      writeSQL(site, polygon, outdir);
    } else {
      writeWKT(site, polygon, outdir);
    }

    // check each point
    for (int i = 0; i < polygon.size(); i++) {
      Point_2 p = polygon.at(i);
      if (p.x() > crect.xmax()/SF || p.x() < crect.xmin()/SF || p.y() > crect.ymax()/SF || p.y() < crect.ymin()/SF) {
        std::cerr << "out of bounds" << std::endl;
      }
    }
  }
}