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REMB / src /geometry /plot_generator.py

Cuong2004

Initial commit: REMB - AI-Powered Industrial Estate Master Plan Optimization Engine

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	"""
	Plot Generator - Industrial Plot Layout Generation
	Generates optimal plot layouts within buildable area
	"""
	import numpy as np
	from shapely.geometry import Polygon, MultiPolygon, box, LineString
	from shapely.ops import unary_union
	from shapely.affinity import rotate, translate
	from typing import List, Tuple, Optional, Dict
	import logging
	import yaml
	from pathlib import Path
	import uuid

	from src.models.domain import SiteBoundary, Plot, PlotType, RoadNetwork

	logger = logging.getLogger(__name__)


	class PlotGenerator:
	"""
	Industrial plot generator

	Responsibilities:
	- Generate plot subdivisions within buildable area
	- Optimize plot orientation for efficiency
	- Ensure road access for all plots
	- Handle varied plot sizes
	"""

	def __init__(self, regulations_path: str = "config/regulations.yaml"):
	"""
	Initialize plot generator

	Args:
	regulations_path: Path to regulations YAML
	"""
	self.regulations_path = Path(regulations_path)
	self.regulations = self._load_regulations()
	self.logger = logging.getLogger(__name__)

	# Load plot requirements
	plot_config = self.regulations.get('plot', {})
	self.min_area = plot_config.get('minimum_area_sqm', 1000)
	self.max_area = plot_config.get('maximum_area_sqm', 50000)
	self.min_width = plot_config.get('minimum_width_m', 20)
	self.min_frontage = plot_config.get('minimum_frontage_m', 15)

	def _load_regulations(self) -> dict:
	"""Load regulations from YAML"""
	if not self.regulations_path.exists():
	return {}
	with open(self.regulations_path, 'r', encoding='utf-8') as f:
	return yaml.safe_load(f)

	def generate_grid_plots(
	self,
	site: SiteBoundary,
	road_network: RoadNetwork,
	plot_width: float = 100,
	plot_depth: float = 100,
	road_setback: float = 5
	) -> List[Plot]:
	"""
	Generate plots in a regular grid pattern

	Args:
	site: Site boundary
	road_network: Road network for access checking
	plot_width: Standard plot width
	plot_depth: Standard plot depth
	road_setback: Setback from roads

	Returns:
	List of Plot objects
	"""
	self.logger.info(f"Generating grid plots: {plot_width}m x {plot_depth}m")

	# Get buildable area (after boundary setback)
	setback = self.regulations.get('setbacks', {}).get('boundary_minimum', 50)
	buildable = site.geometry.buffer(-setback)

	if buildable.is_empty:
	self.logger.warning("No buildable area after setback")
	return []

	# Get road polygons to avoid
	road_polygons = self._get_road_polygons(road_network)
	if road_polygons:
	road_union = unary_union(road_polygons)
	buildable = buildable.difference(road_union.buffer(road_setback))

	if buildable.is_empty:
	self.logger.warning("No buildable area after road subtraction")
	return []

	# Get bounds
	minx, miny, maxx, maxy = buildable.bounds

	plots = []
	plot_id = 0

	# Generate grid of plots
	y = miny
	while y + plot_depth <= maxy:
	x = minx
	while x + plot_width <= maxx:
	plot_geom = box(x, y, x + plot_width, y + plot_depth)

	# Check if plot fits in buildable area
	if buildable.contains(plot_geom):
	# Check if plot area meets minimum
	if plot_geom.area >= self.min_area:
	plot = Plot(
	id=f"plot_{plot_id:03d}",
	geometry=plot_geom,
	area_sqm=plot_geom.area,
	type=PlotType.INDUSTRIAL,
	width_m=plot_width,
	depth_m=plot_depth,
	frontage_m=plot_width,
	has_road_access=self._check_road_access(plot_geom, road_network),
	orientation_degrees=0
	)
	plots.append(plot)
	plot_id += 1
	elif buildable.intersects(plot_geom):
	# Try to fit partial plot
	intersection = buildable.intersection(plot_geom)
	if isinstance(intersection, Polygon) and intersection.area >= self.min_area:
	plot = Plot(
	id=f"plot_{plot_id:03d}",
	geometry=intersection,
	area_sqm=intersection.area,
	type=PlotType.INDUSTRIAL,
	width_m=self._estimate_width(intersection),
	depth_m=self._estimate_depth(intersection),
	frontage_m=self._estimate_width(intersection),
	has_road_access=self._check_road_access(intersection, road_network),
	orientation_degrees=0
	)
	plots.append(plot)
	plot_id += 1

	x += plot_width
	y += plot_depth

	self.logger.info(f"Generated {len(plots)} grid plots")
	return plots

	def generate_varied_plots(
	self,
	site: SiteBoundary,
	road_network: RoadNetwork,
	size_distribution: Dict[str, float] = None
	) -> List[Plot]:
	"""
	Generate plots with varied sizes

	Args:
	site: Site boundary
	road_network: Road network for access checking
	size_distribution: Dict of size:percentage, e.g., {'small': 0.3, 'medium': 0.5, 'large': 0.2}

	Returns:
	List of Plot objects
	"""
	if size_distribution is None:
	size_distribution = {
	'small': 0.3, # 1000-2000 sqm
	'medium': 0.5, # 2000-5000 sqm
	'large': 0.2 # 5000-10000 sqm
	}

	size_specs = {
	'small': {'width': 40, 'depth': 50},
	'medium': {'width': 70, 'depth': 70},
	'large': {'width': 100, 'depth': 100}
	}

	self.logger.info("Generating varied size plots")

	setback = self.regulations.get('setbacks', {}).get('boundary_minimum', 50)
	buildable = site.geometry.buffer(-setback)

	road_polygons = self._get_road_polygons(road_network)
	if road_polygons:
	road_union = unary_union(road_polygons)
	buildable = buildable.difference(road_union.buffer(5))

	if buildable.is_empty:
	return []

	plots = []
	remaining_area = buildable
	plot_id = 0

	# Target area for each size category
	total_buildable = buildable.area
	target_areas = {
	size: total_buildable * pct for size, pct in size_distribution.items()
	}

	for size, target_area in target_areas.items():
	generated_area = 0
	specs = size_specs[size]

	while generated_area < target_area and not remaining_area.is_empty:
	# Find valid placement
	plot = self._place_plot(
	remaining_area,
	specs['width'],
	specs['depth'],
	road_network,
	f"plot_{plot_id:03d}"
	)

	if plot:
	plots.append(plot)
	remaining_area = remaining_area.difference(plot.geometry.buffer(5))
	generated_area += plot.area_sqm
	plot_id += 1
	else:
	break

	self.logger.info(f"Generated {len(plots)} varied plots")
	return plots

	def _place_plot(
	self,
	available_area: Polygon,
	width: float,
	depth: float,
	road_network: RoadNetwork,
	plot_id: str
	) -> Optional[Plot]:
	"""
	Try to place a single plot in available area
	"""
	if available_area.is_empty:
	return None

	minx, miny, maxx, maxy = available_area.bounds

	# Try different positions
	for _ in range(50): # Max attempts
	x = np.random.uniform(minx, maxx - width)
	y = np.random.uniform(miny, maxy - depth)

	plot_geom = box(x, y, x + width, y + depth)

	if available_area.contains(plot_geom):
	return Plot(
	id=plot_id,
	geometry=plot_geom,
	area_sqm=plot_geom.area,
	type=PlotType.INDUSTRIAL,
	width_m=width,
	depth_m=depth,
	frontage_m=width,
	has_road_access=self._check_road_access(plot_geom, road_network)
	)

	return None

	def generate_green_spaces(
	self,
	site: SiteBoundary,
	industrial_plots: List[Plot],
	road_network: RoadNetwork,
	target_ratio: float = 0.15
	) -> List[Plot]:
	"""
	Generate green space plots to meet minimum requirement

	Args:
	site: Site boundary
	industrial_plots: Existing industrial plots
	road_network: Road network
	target_ratio: Target green space ratio (default 15%)

	Returns:
	List of green space Plot objects
	"""
	self.logger.info(f"Generating green spaces (target: {target_ratio*100}%)")

	target_area = site.buildable_area_sqm * target_ratio

	# Get used area
	used_polys = [p.geometry for p in industrial_plots]
	road_polys = self._get_road_polygons(road_network)

	all_used = unary_union(used_polys + road_polys)

	# Remaining area for green
	setback = self.regulations.get('setbacks', {}).get('boundary_minimum', 50)
	buildable = site.geometry.buffer(-setback)
	remaining = buildable.difference(all_used.buffer(2))

	green_plots = []

	if remaining.is_empty:
	self.logger.warning("No remaining area for green space")
	return green_plots

	# Convert remaining area to green plots
	if isinstance(remaining, MultiPolygon):
	polygons = list(remaining.geoms)
	else:
	polygons = [remaining]

	for i, poly in enumerate(polygons):
	if poly.area >= 50: # Minimum 50 sqm for green space
	green_plot = Plot(
	id=f"green_{i:03d}",
	geometry=poly,
	area_sqm=poly.area,
	type=PlotType.GREEN_SPACE,
	width_m=self._estimate_width(poly),
	depth_m=self._estimate_depth(poly)
	)
	green_plots.append(green_plot)

	total_green = sum(p.area_sqm for p in green_plots)
	self.logger.info(
	f"Generated {len(green_plots)} green plots, "
	f"total: {total_green:.0f}m² ({total_green/site.buildable_area_sqm*100:.1f}%)"
	)

	return green_plots

	def _get_road_polygons(self, road_network: RoadNetwork) -> List[Polygon]:
	"""Get road polygons from road network"""
	if not road_network:
	return []

	road_config = self.regulations.get('roads', {})
	primary_width = road_config.get('primary_width_m', 24)
	secondary_width = road_config.get('secondary_width_m', 16)

	polygons = []

	if road_network.primary_roads:
	roads = road_network.primary_roads.geoms if hasattr(road_network.primary_roads, 'geoms') else [road_network.primary_roads]
	for road in roads:
	if isinstance(road, LineString):
	polygons.append(road.buffer(primary_width / 2, cap_style=2))

	if road_network.secondary_roads:
	roads = road_network.secondary_roads.geoms if hasattr(road_network.secondary_roads, 'geoms') else [road_network.secondary_roads]
	for road in roads:
	if isinstance(road, LineString):
	polygons.append(road.buffer(secondary_width / 2, cap_style=2))

	return polygons

	def _check_road_access(
	self,
	plot_geom: Polygon,
	road_network: RoadNetwork,
	max_distance: float = 200
	) -> bool:
	"""Check if plot has road access within max distance"""
	if not road_network:
	return False

	all_roads = []
	if road_network.primary_roads:
	roads = road_network.primary_roads.geoms if hasattr(road_network.primary_roads, 'geoms') else [road_network.primary_roads]
	all_roads.extend(roads)
	if road_network.secondary_roads:
	roads = road_network.secondary_roads.geoms if hasattr(road_network.secondary_roads, 'geoms') else [road_network.secondary_roads]
	all_roads.extend(roads)

	for road in all_roads:
	if plot_geom.distance(road) <= max_distance:
	return True

	return False

	def _estimate_width(self, geom: Polygon) -> float:
	"""Estimate plot width from geometry"""
	minx, miny, maxx, maxy = geom.bounds
	return maxx - minx

	def _estimate_depth(self, geom: Polygon) -> float:
	"""Estimate plot depth from geometry"""
	minx, miny, maxx, maxy = geom.bounds
	return maxy - miny


	# Example usage
	if __name__ == "__main__":
	from src.geometry.site_processor import SiteProcessor
	from src.geometry.road_network import RoadNetworkGenerator

	# Create test site
	processor = SiteProcessor()
	coords = [(0, 0), (500, 0), (500, 500), (0, 500), (0, 0)]
	site = processor.import_from_coordinates(coords)

	# Generate road network
	road_gen = RoadNetworkGenerator()
	roads = road_gen.generate_grid_network(site, primary_spacing=150)

	# Generate plots
	plot_gen = PlotGenerator()

	# Grid plots
	grid_plots = plot_gen.generate_grid_plots(
	site, roads,
	plot_width=80,
	plot_depth=100
	)

	print(f"Grid plots: {len(grid_plots)}")
	total_area = sum(p.area_sqm for p in grid_plots)
	print(f"Total industrial area: {total_area:.0f}m²")

	# Green spaces
	green_plots = plot_gen.generate_green_spaces(
	site, grid_plots, roads,
	target_ratio=0.15
	)

	print(f"Green plots: {len(green_plots)}")
	green_area = sum(p.area_sqm for p in green_plots)
	print(f"Total green area: {green_area:.0f}m²")

	# Check road access
	with_access = sum(1 for p in grid_plots if p.has_road_access)
	print(f"Plots with road access: {with_access}/{len(grid_plots)}")