GDMC-2024/networks/roads_2/Road.py

import json
from typing import List
from networks.geometry.Polyline import Polyline

from networks.geometry.Point3D import Point3D
from networks.geometry.Point2D import Point2D
from networks.geometry.Segment2D import Segment2D
from networks.geometry.Segment3D import Segment3D
from networks.geometry.Circle import Circle
from Enums import LINE_THICKNESS_MODE
from gdpc import Block, Editor


class Road:
    def __init__(self, coordinates: List[Point3D], width: int):
        self.coordinates = self._remove_collinear_points(coordinates)
        self.output_block = []
        # with open(road_configuration) as f:
        #     self.road_configuration = json.load(f)
        #     self.width = self.road_configuration["width"]
        self.width = width
        self.polyline_height = None
        self.polyline_total_line_output = None
        self.segment_total_line_output = None
        self.index_factor = 0

        if len(self._remove_collinear_points(self.coordinates)) >= 4:
            self.polyline = Polyline(Point3D.to_2d(coordinates, 'y'))
            self.polyline_total_line_output = [
                [] for _ in range(len(self.polyline.total_line_output))]

            self._projection_polyline()

        if len(self.coordinates) == 2:
            self.segment_total_line_output = Segment2D(
                Point3D.to_2d([self.coordinates[0]], 'y')[0], Point3D.to_2d([self.coordinates[1]], 'y')[0]).segment_thick(self.width, LINE_THICKNESS_MODE.MIDDLE)
            self._projection_segment()
            self.place()

    @staticmethod
    def _remove_collinear_points(points):
        output_points = [points[0]]

        for i in range(1, len(points) - 1):
            if isinstance(points[0], Point3D):
                if not Point2D.collinear(
                        Point3D.to_2d([points[i-1]], 'y')[0], Point3D.to_2d([points[i]], 'y')[0], Point3D.to_2d([points[i+1]], 'y')[0]):
                    output_points.append(points[i])
            else:
                if not Point2D.collinear(points[i-1], points[i], points[i+1]):
                    output_points.append(points[i])

        output_points.append(points[-1])
        return output_points

    def _surface(self):
        # Segments

        for i in range(1, len(self.polyline.segments)):
            if len(self.polyline.segments[i].segment()) > 2:
                for j in range(len(self.polyline.segments[i].segment_thick(self.width, LINE_THICKNESS_MODE.MIDDLE))):
                    # Get nearest in x,z projection
                    nearest = self.polyline.segments[i].points_thick[j].nearest(
                        Point3D.to_2d(self.polyline_total_line_output, removed_axis='y'), True)
                    # self.output_block.append(
                    #     (Point3D.insert_3d([self.polyline.segments[i].points_thick[j]], 'y', [self.polyline_total_line_output[nearest[0]].y])[0].coordinates, Block("stone")))
                for k in range(len(self.polyline.segments[i].points_thick_by_line)):
                    match k:
                        case 0:
                            blob = 'black_concrete'
                        case 1:
                            blob = 'red_concrete'
                        case 2:
                            blob = 'orange_concrete'
                        case 3:
                            blob = 'yellow_concrete'
                        case 4:
                            blob = 'green_concrete'
                        case 5:
                            blob = 'blue_concrete'
                        case 6:
                            blob = 'purple_concrete'

                    for m in range(len(self.polyline.segments[i].points_thick_by_line[k])):
                        nearest = self.polyline.segments[i].points_thick_by_line[k][m].nearest(
                            Point3D.to_2d(self.polyline_total_line_output, removed_axis='y'), True)
                        self.output_block.append(
                            (Point3D.insert_3d([self.polyline.segments[i].points_thick_by_line[k][m]], 'y', [self.polyline_total_line_output[nearest[0]].y])[0].coordinates, Block(blob)))

        for i in range(1, len(self.polyline.centers)-1):
            # Circle

            circle = Circle(self.polyline.centers[i])
            circle.circle_thick(int(
                (self.polyline.radii[i]-self.width/2)), int((self.polyline.radii[i]+self.width/2)-1))

            # Better to do here than drawing circle arc inside big triangle!
            double_point_a = Point2D.from_arrays(Point2D.to_arrays(self.polyline.acrs_intersections[i][0]) + 5 * (Point2D.to_arrays(
                self.polyline.acrs_intersections[i][0]) - Point2D.to_arrays(self.polyline.centers[i])))
            double_point_b = Point2D.from_arrays(Point2D.to_arrays(self.polyline.acrs_intersections[i][2]) + 5 * (Point2D.to_arrays(
                self.polyline.acrs_intersections[i][2]) - Point2D.to_arrays(self.polyline.centers[i])))

            for j in range(len(circle.points_thick)):
                if circle.points_thick[j].is_in_triangle(double_point_a, self.polyline.centers[i], double_point_b):
                    nearest = circle.points_thick[j].nearest(
                        Point3D.to_2d(self.polyline_total_line_output, removed_axis='y'), True)
                    self.output_block.append(
                        (Point3D.insert_3d([circle.points_thick[j]], 'y', [
                            self.polyline_total_line_output[nearest[0]].y])[0].coordinates, Block("white_concrete")))

    def _projection_polyline(self):
        nearest_points_to_reference = []
        for i in range(len(self.coordinates)):
            # nearest_points_to_reference.append(Point3D.insert_3d([Point3D.to_2d([self.coordinates[i]], 'y')[0].nearest(
            #     self.polyline.total_line_output, return_index=True)], 'y', [self.coordinates[i].y])[0])
            index, point = Point3D.to_2d([self.coordinates[i]], 'y')[0].nearest(
                self.polyline.total_line_output, return_index=True)
            nearest_points_to_reference.append(
                Point2D(index, self.coordinates[i].y))

        if len(self._remove_collinear_points(nearest_points_to_reference)) >= 4:
            self.polyline_height = Polyline(nearest_points_to_reference)

            self.index_factor = len(
                self.polyline_height.total_line_output)/len(self.polyline.total_line_output)

            for i in range(len(self.polyline.total_line_output)):
                self.polyline_total_line_output[i] = Point3D(
                    self.polyline.total_line_output[i].x, self.polyline_height.total_line_output[round(i*self.index_factor)].y, self.polyline.total_line_output[i].y)

            self._surface()
            self.place()
        # self.polyline_total_line_output = self.polyline_total_line_output[0].optimized_path(
        #     self.polyline_total_line_output)

    def _projection_segment(self):
        s = Segment3D(
            self.coordinates[0], self.coordinates[1])

        reference = s.segment()

        for i in range(len(self.segment_total_line_output)):
            self.output_block.append(((
                self.segment_total_line_output[i].x, reference[self.segment_total_line_output[i].nearest(Point3D.to_2d(reference, 'y'), True)[0]].y, self.segment_total_line_output[i].y), Block("black_concrete")))

    def place(self):
        editor = Editor(buffering=True)
        for i in range(len(self.output_block)):
            editor.placeBlock(self.output_block[i][0],
                              self.output_block[i][1])