forked from s_ranjbar/city_retrofit
239 lines
10 KiB
Python
239 lines
10 KiB
Python
"""
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Geojson module parses geojson files and import the geometry into the city model structure
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SPDX - License - Identifier: LGPL - 3.0 - or -later
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Copyright © 2022 Concordia CERC group
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Project Coder Guillermo Gutierrez Guillermo.GutierrezMorote@concordia.ca
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"""
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import json
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import numpy as np
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import trimesh.creation
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from pyproj import Transformer
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from shapely.geometry import Polygon as ShapelyPolygon
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import hub.helpers.constants as cte
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from hub.helpers.geometry_helper import GeometryHelper
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from hub.imports.geometry.helpers.geometry_helper import GeometryHelper as igh
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from hub.city_model_structure.attributes.polygon import Polygon
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from hub.city_model_structure.building import Building
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from hub.city_model_structure.building_demand.surface import Surface
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from hub.city_model_structure.city import City
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class Geojson:
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"""
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Geojson class
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"""
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X = 0
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Y = 1
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def __init__(self,
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path,
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extrusion_height_field=None,
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year_of_construction_field=None,
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function_field=None,
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function_to_hub=None):
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# todo: destination epsg should change according actual the location
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self._transformer = Transformer.from_crs('epsg:4326', 'epsg:26911')
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self._min_x = cte.MAX_FLOAT
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self._min_y = cte.MAX_FLOAT
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self._max_x = cte.MIN_FLOAT
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self._max_y = cte.MIN_FLOAT
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self._max_z = 0
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self._city = None
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self._extrusion_height_field = extrusion_height_field
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self._year_of_construction_field = year_of_construction_field
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self._function_field = function_field
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self._function_to_hub = function_to_hub
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with open(path) as json_file:
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self._geojson = json.loads(json_file.read())
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def _save_bounds(self, x, y):
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if x > self._max_x:
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self._max_x = x
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if x < self._min_x:
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self._min_x = x
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if y > self._max_y:
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self._max_y = y
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if y < self._min_y:
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self._min_y = y
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@staticmethod
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def _create_buildings_lod0(name, year_of_construction, function, surfaces_coordinates):
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surfaces = []
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buildings = []
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for zone, surface_coordinates in enumerate(surfaces_coordinates):
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points = igh.points_from_string(igh.remove_last_point_from_string(surface_coordinates))
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# geojson provides the roofs, need to be transform into grounds
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points = igh.invert_points(points)
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polygon = Polygon(points)
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surfaces.append(Surface(polygon, polygon))
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buildings.append(Building(f'{name}_zone_{zone}', surfaces, year_of_construction, function))
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return buildings
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@staticmethod
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def _create_buildings_lod1(name, year_of_construction, function, height, surface_coordinates):
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lod0_buildings = Geojson._create_buildings_lod0(name, year_of_construction, function, surface_coordinates)
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surfaces = []
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buildings = []
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for zone, lod0_building in enumerate(lod0_buildings):
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for surface in lod0_building.grounds:
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volume = surface.solid_polygon.area * height
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surfaces.append(surface)
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roof_coordinates = []
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# adding a roof means invert the polygon coordinates and change the Z value
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for coordinate in surface.solid_polygon.coordinates:
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roof_coordinate = np.array([coordinate[0], coordinate[1], height])
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# insert the roof rotated already
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roof_coordinates.insert(0, roof_coordinate)
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polygon = Polygon(roof_coordinates)
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roof = Surface(polygon, polygon)
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surfaces.append(roof)
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# adding a wall means add the point coordinates and the next point coordinates with Z's height and 0
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coordinates_length = len(roof.solid_polygon.coordinates)
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for i, coordinate in enumerate(roof.solid_polygon.coordinates):
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j = i + 1
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if j == coordinates_length:
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j = 0
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next_coordinate = roof.solid_polygon.coordinates[j]
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wall_coordinates = [
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np.array([coordinate[0], coordinate[1], 0.0]),
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np.array([next_coordinate[0], next_coordinate[1], 0.0]),
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np.array([next_coordinate[0], next_coordinate[1], next_coordinate[2]]),
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np.array([coordinate[0], coordinate[1], coordinate[2]])
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]
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polygon = Polygon(wall_coordinates)
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wall = Surface(polygon, polygon)
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surfaces.append(wall)
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building = Building(f'{name}_zone_{zone}', surfaces, year_of_construction, function)
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building.volume = volume
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buildings.append(building)
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return buildings
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def _get_polygons(self, polygons, coordinates):
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if type(coordinates[0][self.X]) != float:
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polygons = []
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for element in coordinates:
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polygons = self._get_polygons(polygons, element)
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return polygons
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else:
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transformed_coordinates = ''
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for coordinate in coordinates:
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transformed = self._transformer.transform(coordinate[self.Y], coordinate[self.X])
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self._save_bounds(transformed[self.X], transformed[self.Y])
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transformed_coordinates = f'{transformed_coordinates} {transformed[self.X]} {transformed[self.Y]} 0.0'
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polygons.append(transformed_coordinates.lstrip(' '))
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return polygons
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@staticmethod
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def _find_wall(line_1, line_2):
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for i in range(0, 2):
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point_1 = line_1[i]
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point_2 = line_2[i]
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distance = GeometryHelper.distance_between_points(point_1, point_2)
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if distance > 1e-2:
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return False
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return True
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def _store_shared_percentage_to_walls(self, city, city_mapped):
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for building in city.buildings:
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if building.name not in city_mapped.keys():
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continue
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building_mapped = city_mapped[building.name]
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for wall in building.walls:
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percentage = 0
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ground_line = []
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for point in wall.perimeter_polygon.coordinates:
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if point[2] < 0.5:
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ground_line.append(point)
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# todo: erase when we have no triangulation
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if len(ground_line) < 2:
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continue
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# todo: erase down to here
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for entry in building_mapped:
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if building_mapped[entry]['shared_points'] <= 5:
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continue
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line = [building_mapped[entry]['line_start'], building_mapped[entry]['line_end']]
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neighbour_line = [building_mapped[entry]['neighbour_line_start'],
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building_mapped[entry]['neighbour_line_end']]
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neighbour_height = city.city_object(building_mapped[entry]['neighbour_name']).max_height
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if self._find_wall(line, ground_line):
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line_shared = (GeometryHelper.distance_between_points(line[0], line[1]) +
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GeometryHelper.distance_between_points(neighbour_line[0], neighbour_line[1]) -
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GeometryHelper.distance_between_points(line[1], neighbour_line[0]) -
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GeometryHelper.distance_between_points(line[0], neighbour_line[1])) / 2
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percentage_ground = line_shared / GeometryHelper.distance_between_points(line[0], line[1])
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percentage_height = neighbour_height / building.max_height
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if percentage_height > 1:
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percentage_height = 1
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percentage += percentage_ground * percentage_height
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wall.percentage_shared = percentage
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@property
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def city(self) -> City:
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"""
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Get city out of a Geojson file
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"""
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if self._city is None:
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missing_functions = []
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buildings = []
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building_id = 0
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lod = 1
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for feature in self._geojson['features']:
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extrusion_height = 0
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if self._extrusion_height_field is not None:
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extrusion_height = float(feature['properties'][self._extrusion_height_field])
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year_of_construction = None
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if self._year_of_construction_field is not None:
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year_of_construction = int(feature['properties'][self._year_of_construction_field])
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function = None
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if self._function_field is not None:
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function = feature['properties'][self._function_field]
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if self._function_to_hub is not None:
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# use the transformation dictionary to retrieve the proper function
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if function in self._function_to_hub:
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function = self._function_to_hub[function]
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else:
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if function not in missing_functions:
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missing_functions.append(function)
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function = function
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geometry = feature['geometry']
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if 'id' in feature:
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building_name = feature['id']
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else:
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building_name = f'building_{building_id}'
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building_id += 1
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polygons = []
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for part, coordinates in enumerate(geometry['coordinates']):
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polygons = self._get_polygons(polygons, coordinates)
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for zone, polygon in enumerate(polygons):
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if extrusion_height == 0:
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buildings = buildings + Geojson._create_buildings_lod0(f'{building_name}_part_{part}',
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year_of_construction,
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function,
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[polygon])
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lod = 0
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else:
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if self._max_z < extrusion_height:
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self._max_z = extrusion_height
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buildings = buildings + Geojson._create_buildings_lod1(f'{building_name}_part_{part}',
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year_of_construction,
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function,
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extrusion_height,
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[polygon])
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self._city = City([self._min_x, self._min_y, 0.0], [self._max_x, self._max_y, self._max_z], 'epsg:26911')
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for building in buildings:
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self._city.add_city_object(building)
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self._city.level_of_detail.geometry = lod
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if lod == 1:
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lines_information = GeometryHelper.city_mapping(self._city, plot=True)
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self._store_shared_percentage_to_walls(self._city, lines_information)
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if len(missing_functions) > 0:
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print(f'There are unknown functions {missing_functions}')
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return self._city
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