Example #1
0
def search_nodes(map):
  if len(map.nodeList) > 0:
    valid, lat, lon = parse_gps()
    if not valid:
      return
    dlist = map.generate_dlist(lat, lon)
    dlist_sorted = sorted(dlist)
    show_type = input("Show (1) nodes closer than a certain distance, or (2) given number of closest nodes: ")
    show_num = 0
    if show_type == '1':
      keepTrying = 'y'
      while keepTrying == 'y':
        dist_str = input("Show nodes closer than the following distance (in feet): ")
        try:
          dist_num = int(dist_str)
          show_num = sum([CvtdUtil.coord_to_ft(y) < dist_num for y in dlist])
          show = input(f"Show {show_num} entries (y/n): ")
          if show == 'y':
            print(f"Showing {show_num} nodes within {dist_num} feet of {lat}, {lon}")
            for i in range(show_num):
              dlist_ix = dlist.index(dlist_sorted[i])
              e = round(CvtdUtil.coord_to_ft(dlist_sorted[i]), 3)
              print(f"{i+1}: {map.nodeList[dlist_ix].lat}, {map.nodeList[dlist_ix].lon} ({e} feet)")
            keepTrying = 'n'
          else:
            keepTrying = input("Try again (y/n): ")
        except ValueError:
          keepTrying = input(f"Error: Could not convert ${show_str} to an integer. Try again (y/n): ")
    elif show_type == '2':
      nnodes = len(map.nodeList)
      show_str = input(f"Show how many entries (max {nnodes}): ")
      try:
        show_num = min(int(show_str), nnodes)
        print(f"Showing {show_num} nodes close to {lat}, {lon}")
        for i in range(show_num):
          dlist_ix = dlist.index(dlist_sorted[i])
          e = round(dlist_sorted[i]*70*5280, 3)
          print(f"{i+1}: {map.nodeList[dlist_ix].lat}, {map.nodeList[dlist_ix].lon} ({e} feet)")
      except ValueError:
        print(f"Error: Could not convert ${show_str} to an integer")
  
    # Now, let them choose one of these nodes
    if show_num > 0:
      while True:
        try:
          node_info = int(input(f"Get more info about a node (1-{show_num}) or (n)o: "))
          if 1 <= node_info <= show_num:
            plist = map.get_node_usage(dlist.index(dlist_sorted[node_info - 1]))
            if len(plist) > 0:
              print("The following roads use this node: ")
              for p in plist:
                print(p.addr_repr(map.roadList))
          else:
            break
        except ValueError:
          break
  else:
    print("No nodes have been added, you might want to read roads.txt (key 'r')")
Example #2
0
def add_to_print_list(myMap, locator, print_list, rid, ix):
    try:
        position = locator.pos[rid][ix]
        t = position.timestamp
        lat = position.lat
        lon = position.lon
        dir = position.direction
    except IndexError:
        return

    # Determine route
    try:
        route = myMap.routeDict[rid]
        routeName = route.routeShortName
        # validStreets = route.get_street_list()
    except KeyError:
        routeName = "Unknown Route"
        # validStreets = None
    validStreets = None

    # Compute address
    # roadIx, addr, error = myMap.compute_addr_repr(lat, lon, validStreets)
    roadIx, addr, error = myMap.compute_addr_repr(lat, lon, None)
    if validStreets is not None and error > 250:
        roadIx, addr_off_route, error_off_route = myMap.compute_addr_repr(
            lat, lon, None)
        if error_off_route < 200:
            addr = "!" + addr_off_route
            error = error_off_route
    error = round(error)

    # Determine if direction is actual or if it should be X
    try:
        lat_to_lat_diff = CvtdUtil.coord_to_ft(
            abs(locator.pos[rid][ix - 1].lat - lat))
        lon_to_lon_diff = CvtdUtil.coord_to_ft(
            abs(locator.pos[rid][ix - 1].lon - lon))
        pos_to_pos_diff = math.sqrt(lat_to_lat_diff**2 + lon_to_lon_diff**2)
        if (pos_to_pos_diff < 40):
            dir = Direction.X
        else:
            dir = direction.get_direction(dir)
    except IndexError:
        dir = direction.get_direction(dir)

    # Add to list to print later
    try:
        print_list[rid].append([t, addr, error, dir])
    except KeyError:
        print_list[rid] = [routeName]
        print_list[rid].append([t, addr, error, dir])
Example #3
0
def choose_gps(map):
  valid, lat, lon = parse_gps()
  if not valid:
    return False
  node_ix = len(map.nodeList)
  dlist = map.generate_dlist(lat, lon)
  dlist_sorted = sorted(dlist)
  node_count = sum([CvtdUtil.coord_to_ft(y) < 150 for y in dlist])
  if node_count > 0:
    print(f"The following {node_count} nodes already exist close to the location you entered:")
    for i in range(node_count):
      dlist_ix = dlist.index(dlist_sorted[i])
      print(f"{i+1}: {map.nodeList[dlist_ix].lat}, {map.nodeList[dlist_ix].lon} ({CvtdUtil.coord_to_ft(dlist_sorted[i])} feet)")
    usenode = input("Use instead any of these nodes? Enter 'n' or number: ")
    try:
      usenode = int(usenode)
      if 1 <= usenode <= node_count:
        plist = map.get_node_usage(dlist_ix)
        if len(plist) > 0:
          print("The following roads use this node: ")
          for point in plist:
            print(p.addr_repr(map.roadList))
          okay = input("Okay (y/n): ")
          if okay.lower() != 'y':
            return None
        else:
          lat = map.nodeList[dlist_ix].lat
          lon = map.nodeList[dlist_ix].lon
          node_ix = dlist_ix
    except ValueError:
      # node_ix, lat and lot already have their desired values
      pass
  return node_ix, lat, lon
Example #4
0
    def compute_addr(self, lat, lon, nodeDict):
        point_ix, proj_ratio, error = self.compute_proj_ratio(
            lat, lon, nodeDict)

        vaddr_begin = self.points[point_ix].addr
        vaddr_end = self.points[point_ix + 1].addr

        address = round(proj_ratio * (vaddr_end - vaddr_begin) + vaddr_begin)
        addrRepr = CvtdUtil.addr_repr(address, self.dir, self.name)

        return addrRepr, CvtdUtil.coord_to_ft(error)
Example #5
0
    def compute_addr(self, lat, lon, valid_streets):
        ix, seg_ix, proj_ratio, error = self.compute_proj_ratio(
            lat, lon, valid_streets)

        if ix != -1:
            vaddr_begin = self.roadList[ix].points[seg_ix].addr
            vaddr_end = self.roadList[ix].points[seg_ix + 1].addr

            address = round(proj_ratio * (vaddr_end - vaddr_begin) +
                            vaddr_begin)
        else:
            address = 0

        return ix, address, CvtdUtil.coord_to_ft(error)
Example #6
0
  def get_min_point_error(self, lat, lon):
    min_pos_to_proj = 0x7FFFFFFF
    
    for point_ix, point in enumerate(self.pointList[:-1]):
      blon = point.lon
      blat = point.lat
      elon = self.pointList[point_ix + 1].lon
      elat = self.pointList[point_ix + 1].lat
      street_sc, pos_sc, projection_sc, begin_or_end = CvtdUtil.sub_proj_ratio(lat, lon, blat, blon, elat, elon)

      if projection_sc != 0.0:
        proj_sc_fixed = min(projection_sc, street_sc)
        try:
          pos_to_proj = math.sqrt((pos_sc * pos_sc) - (proj_sc_fixed * proj_sc_fixed))
        except ValueError:
          pos_to_proj = 0

        if pos_to_proj < min_pos_to_proj:
          min_pos_to_proj = pos_to_proj
      else:
        print(f"Error [get_min_point_error] on shape: two adjacent points with same node")
      
    return CvtdUtil.coord_to_ft(min_pos_to_proj)
Example #7
0
 def test_coord_to_ft(self):
     self.assertEqual(CvtdUtil.coord_to_ft(1), 369600)