system_assignation/city_model_structure/attributes/polygon.py

158 lines
5.2 KiB
Python

"""
Polygon module
SPDX - License - Identifier: LGPL - 3.0 - or -later
Copyright © 2020 Project Author Pilar Monsalvete Álvarez de Uribarri pilar.monsalvete@concordia.ca
"""
import sys
import numpy as np
from helpers.geometry_helper import GeometryHelper as gh
class Polygon:
"""
Polygon class
"""
def __init__(self, points):
self._area = None
self._points = points
self._points_list = None
self._normal = None
@property
def points(self) -> np.ndarray:
return self._points
@property
def points_list(self) -> np.ndarray:
"""
Solid surface point coordinates list [x, y, z, x, y, z,...]
:return: np.ndarray
"""
if self._points_list is None:
s = self.points
self._points_list = np.reshape(s, len(s) * 3)
return self._points_list
@property
def area(self):
"""
Surface area in square meters
:return: float
"""
# New method to calculate area
if self._area is None:
if len(self.points) < 3:
sys.stderr.write('Warning: the area of a line or point cannot be calculated 1. Area = 0\n')
return 0
alpha = 0
vec_1 = self.points[1] - self.points[0]
for i in range(2, len(self.points)):
vec_2 = self.points[i] - self.points[0]
alpha += gh.angle_between_vectors(vec_1, vec_2)
if alpha == 0:
sys.stderr.write('Warning: the area of a line or point cannot be calculated 2. Area = 0\n')
return 0
horizontal_points = self.rotate_surface_to_horizontal
area = 0
for i in range(0, len(horizontal_points)-1):
point = horizontal_points[i]
next_point = horizontal_points[i+1]
area += (next_point[1] + point[1]) / 2 * (next_point[0] - point[0])
next_point = horizontal_points[0]
point = horizontal_points[len(horizontal_points)-1]
area += (next_point[1] + point[1]) / 2 * (next_point[0] - point[0])
self._area = abs(area)
return self._area
@property
def rotate_surface_to_horizontal(self):
z_vector = [0, 0, 1]
normal_vector = self.normal
horizontal_points = []
x = normal_vector[0]
y = normal_vector[1]
if x == 0 and y == 0:
# Already horizontal
for point in self.points:
horizontal_points.append([point[0], point[1], 0])
else:
alpha = gh.angle_between_vectors(normal_vector, z_vector)
rotation_line = np.cross(normal_vector, z_vector)
third_axis = np.cross(normal_vector, rotation_line)
w_1 = rotation_line / np.linalg.norm(rotation_line)
w_2 = normal_vector
w_3 = third_axis / np.linalg.norm(third_axis)
rotation_matrix = np.array([[1, 0, 0],
[0, np.cos(alpha), -np.sin(alpha)],
[0, np.sin(alpha), np.cos(alpha)]])
base_matrix = np.array([w_1, w_2, w_3])
rotation_base_matrix = np.matmul(base_matrix.transpose(), rotation_matrix.transpose())
rotation_base_matrix = np.matmul(rotation_base_matrix, base_matrix)
if rotation_base_matrix is None:
sys.stderr.write('Warning: rotation base matrix returned None\n')
else:
for point in self.points:
new_point = np.matmul(rotation_base_matrix, point)
horizontal_points.append(new_point)
return horizontal_points
@property
def normal(self) -> np.ndarray:
"""
Surface normal vector
:return: np.ndarray
"""
if self._normal is None:
points = self.points
# todo: IF THE FIRST ONE IS 0, START WITH THE NEXT
point_origin = points[len(points)-2]
vector_1 = points[len(points)-1] - point_origin
vector_2 = points[0] - point_origin
vector_3 = points[1] - point_origin
cross_product = np.cross(vector_1, vector_2)
if np.linalg.norm(cross_product) != 0:
cross_product = cross_product / np.linalg.norm(cross_product)
alpha = gh.angle_between_vectors(vector_1, vector_2)
else:
# todo modify here
cross_product = [0, 0, 0]
alpha = 0
if len(points) == 3:
return cross_product
alpha += self._angle(vector_2, vector_3, cross_product)
for i in range(0, len(points)-4):
vector_1 = points[i+1] - point_origin
vector_2 = points[i+2] - point_origin
alpha += self._angle(vector_1, vector_2, cross_product)
vector_1 = points[len(points) - 1] - point_origin
vector_2 = points[0] - point_origin
if alpha < 0:
cross_product = np.cross(vector_2, vector_1)
else:
cross_product = np.cross(vector_1, vector_2)
self._normal = cross_product / np.linalg.norm(cross_product)
return self._normal
@staticmethod
def _angle(vector_1, vector_2, cross_product):
accepted_normal_difference = 0.01
cross_product_next = np.cross(vector_1, vector_2)
if np.linalg.norm(cross_product_next) != 0:
cross_product_next = cross_product_next / np.linalg.norm(cross_product_next)
alpha = gh.angle_between_vectors(vector_1, vector_2)
else:
cross_product_next = [0, 0, 0]
alpha = 0
delta_normals = 0
for j in range(0, 3):
delta_normals += cross_product[j] - cross_product_next[j]
if np.abs(delta_normals) < accepted_normal_difference:
return alpha
else:
return -alpha