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	# -- coding: utf-8 --
	"""2.7 Code to be deployed 21.02.2025

	Automatically generated by Colab.

	Original file is located at
	https://colab.research.google.com/drive/1RWSQn0GW_KXoHkJLcbYzLAGGyc0tiDWl
	"""

	"""## Imports"""
	import sys
	import math
	import random
	import string
	import zlib
	import base64
	import datetime
	import uuid
	import re
	from io import BytesIO
	from ctypes import sizeof
	from collections import Counter
	from typing import NewType
	import xml.etree.ElementTree as ET
	from xml.etree.ElementTree import Element, SubElement, tostring, ElementTree
	from xml.dom.minidom import parseString

	import numpy as np
	import cv2
	from matplotlib import pyplot as plt
	from matplotlib.patches import Polygon
	from shapely.geometry import Point, Polygon as ShapelyPolygon
	from shapely.ops import unary_union
	from PIL import Image, ImageDraw, ImageFont, ImageColor

	import fitz
	import ezdxf
	from ezdxf import units, bbox
	from ezdxf.colors import aci2rgb
	from ezdxf.math import OCS, Matrix44, Vec3, Vec2

	import pandas as pd
	import google_sheet_Legend
	import tsadropboxretrieval

	from PyPDF2 import PdfReader, PdfWriter
	from PyPDF2.generic import (
	NameObject,
	TextStringObject,
	DictionaryObject,
	ArrayObject,
	FloatObject,
	NumberObject,
	)

	from math import sin, cos, radians, isclose



	def normalize_vertices(vertices):
	"""Sort vertices to ensure consistent order."""
	return tuple(sorted(tuple(v) for v in vertices))

	def areas_are_similar(area1, area2, tolerance=0.2):
	"""Check if two areas are within a given tolerance."""
	return abs(area1 - area2) <= tolerance


	# -- coding: utf-8 --wj
	"""Version to be deployed of 3.2 Calculating area/perimeter

	Automatically generated by Colab.

	Original file is located at
	https://colab.research.google.com/drive/1XPeCoTBgWSNBYZ3aMKBteP4YG3w4bORs
	"""
	import ezdxf
	from ezdxf.bbox import extents

	def detect_scale_from_page(dxf_path, page_pixel_width, m_per_pixel_from_pdf):
	"""
	Detects mm/px scale factor using the bounding box of the entire DXF content.
	"""
	doc = ezdxf.readfile(dxf_path)

	#getting the bounding box from modelspace
	msp = doc.modelspace()
	bbox_msp = extents(msp, fast=True)

	if bbox_msp.has_data: #not empty
	min_x, min_y, max_x, max_y = bbox_msp.extmin.x, bbox_msp.extmin.y, bbox_msp.extmax.x, bbox_msp.extmax.y
	else:
	# Try paperspace as a fallback
	psp = doc.layout("Layout1")
	bbox_psp = extents(psp, fast=True)
	if not bbox_psp.has_data:
	raise ValueError("No bounding box data found in modelspace or paperspace.")
	min_x, min_y, max_x, max_y = bbox_psp.extmin.x, bbox_psp.extmin.y, bbox_psp.extmax.x, bbox_psp.extmax.y

	# DXF width
	dxf_width = max_x - min_x

	# PDF width in m
	pdf_metric_width = page_pixel_width * m_per_pixel_from_pdf

	# Correction factor
	correction_factor = dxf_width / pdf_metric_width
	# final_scale = mm_per_pixel_from_pdf * correction_factor

	return correction_factor


	"""## Notes"""

	#new approach to get width and height of dxf plan
	'''
	This portion is used to convert vertices read from dxf to pixels in order to accurately locate shapes in the image and pdf
	ratio :
	MeasuredMetric* PixelValue/ DxfMetric = MeasuredPixel
	PixelValue: get from pixel conversion code , second number in the bracker represents the perimeter
	DxfMetric: measured perimeter from foxit

	divide pixelvalue by dxfmetric, will give u a ratio , this is ur dxfratio


	'''

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5.928572 1.285714 5.928572 c h 1.285714 8.5 m 1.561857 8.5 1.785714 8.723858 1.785714 9 c 1.785714 9.276142 1.561857 9.5 1.285714 9.5 c 1.009572 9.5 0.7857141 9.276142 0.7857141 9 c 0.7857141 8.723858 1.009572 8.5 1.285714 8.5 c h 1.285714 11.07143 m 1.561857 11.07143 1.785714 11.29529 1.785714 11.57143 c 1.785714 11.84757 1.561857 12.07143 1.285714 12.07143 c 1.009572 12.07143 0.7857141 11.84757 0.7857141 11.57143 c 0.7857141 11.29529 1.009572 11.07143 1.285714 11.07143 c h 1.285714 13.64286 m 1.561857 13.64286 1.785714 13.86672 1.785714 14.14286 c 1.785714 14.419 1.561857 14.64286 1.285714 14.64286 c 1.009572 14.64286 0.7857141 14.419 0.7857141 14.14286 c 0.7857141 13.86672 1.009572 13.64286 1.285714 13.64286 c h 1.285714 16.21429 m 1.561857 16.21429 1.785714 16.43814 1.785714 16.71429 c 1.785714 16.99043 1.561857 17.21429 1.285714 17.21429 c 1.009572 17.21429 0.7857141 16.99043 0.7857141 16.71429 c 0.7857141 16.43814 1.009572 16.21429 1.285714 16.21429 c h 3.857143 0.7857141 m 4.133285 0.7857141 4.357142 1.009572 4.357142 1.285714 c 4.357142 1.561857 4.133285 1.785714 3.857143 1.785714 c 3.581 1.785714 3.357143 1.561857 3.357143 1.285714 c 3.357143 1.009572 3.581 0.7857141 3.857143 0.7857141 c h 3.857143 3.357143 m 4.133285 3.357143 4.357142 3.581 4.357142 3.857143 c 4.357142 4.133285 4.133285 4.357142 3.857143 4.357142 c 3.581 4.357142 3.357143 4.133285 3.357143 3.857143 c 3.357143 3.581 3.581 3.357143 3.857143 3.357143 c h 3.857143 5.928572 m 4.133285 5.928572 4.357142 6.15243 4.357142 6.428572 c 4.357142 6.704715 4.133285 6.928572 3.857143 6.928572 c 3.581 6.928572 3.357143 6.704715 3.357143 6.428572 c 3.357143 6.15243 3.581 5.928572 3.857143 5.928572 c h 3.857143 8.5 m 4.133285 8.5 4.357142 8.723858 4.357142 9 c 4.357142 9.276142 4.133285 9.5 3.857143 9.5 c 3.581 9.5 3.357143 9.276142 3.357143 9 c 3.357143 8.723858 3.581 8.5 3.857143 8.5 c h 3.857143 11.07143 m 4.133285 11.07143 4.357142 11.29529 4.357142 11.57143 c 4.357142 11.84757 4.133285 12.07143 3.857143 12.07143 c 3.581 12.07143 3.357143 11.84757 3.357143 11.57143 c 3.357143 11.29529 3.581 11.07143 3.857143 11.07143 c h 3.857143 13.64286 m 4.133285 13.64286 4.357142 13.86672 4.357142 14.14286 c 4.357142 14.419 4.133285 14.64286 3.857143 14.64286 c 3.581 14.64286 3.357143 14.419 3.357143 14.14286 c 3.357143 13.86672 3.581 13.64286 3.857143 13.64286 c h 3.857143 16.21429 m 4.133285 16.21429 4.357142 16.43814 4.357142 16.71429 c 4.357142 16.99043 4.133285 17.21429 3.857143 17.21429 c 3.581 17.21429 3.357143 16.99043 3.357143 16.71429 c 3.357143 16.43814 3.581 16.21429 3.857143 16.21429 c h 6.428572 0.7857141 m 6.704715 0.7857141 6.928572 1.009572 6.928572 1.285714 c 6.928572 1.561857 6.704715 1.785714 6.428572 1.785714 c 6.15243 1.785714 5.928572 1.561857 5.928572 1.285714 c 5.928572 1.009572 6.15243 0.7857141 6.428572 0.7857141 c h 6.428572 3.357143 m 6.704715 3.357143 6.928572 3.581 6.928572 3.857143 c 6.928572 4.133285 6.704715 4.357142 6.428572 4.357142 c 6.15243 4.357142 5.928572 4.133285 5.928572 3.857143 c 5.928572 3.581 6.15243 3.357143 6.428572 3.357143 c h 6.428572 5.928572 m 6.704715 5.928572 6.928572 6.15243 6.928572 6.428572 c 6.928572 6.704715 6.704715 6.928572 6.428572 6.928572 c 6.15243 6.928572 5.928572 6.704715 5.928572 6.428572 c 5.928572 6.15243 6.15243 5.928572 6.428572 5.928572 c h 6.428572 8.5 m 6.704715 8.5 6.928572 8.723858 6.928572 9 c 6.928572 9.276142 6.704715 9.5 6.428572 9.5 c 6.15243 9.5 5.928572 9.276142 5.928572 9 c 5.928572 8.723858 6.15243 8.5 6.428572 8.5 c h 6.428572 11.07143 m 6.704715 11.07143 6.928572 11.29529 6.928572 11.57143 c 6.928572 11.84757 6.704715 12.07143 6.428572 12.07143 c 6.15243 12.07143 5.928572 11.84757 5.928572 11.57143 c 5.928572 11.29529 6.15243 11.07143 6.428572 11.07143 c h 6.428572 13.64286 m 6.704715 13.64286 6.928572 13.86672 6.928572 14.14286 c 6.928572 14.419 6.704715 14.64286 6.428572 14.64286 c 6.15243 14.64286 5.928572 14.419 5.928572 14.14286 c 5.928572 13.86672 6.15243 13.64286 6.428572 13.64286 c h 6.428572 16.21429 m 6.704715 16.21429 6.928572 16.43814 6.928572 16.71429 c 6.928572 16.99043 6.704715 17.21429 6.428572 17.21429 c 6.15243 17.21429 5.928572 16.99043 5.928572 16.71429 c 5.928572 16.43814 6.15243 16.21429 6.428572 16.21429 c h 9 0.7857141 m 9.276142 0.7857141 9.5 1.009572 9.5 1.285714 c 9.5 1.561857 9.276142 1.785714 9 1.785714 c 8.723858 1.785714 8.5 1.561857 8.5 1.285714 c 8.5 1.009572 8.723858 0.7857141 9 0.7857141 c h 9 3.357143 m 9.276142 3.357143 9.5 3.581 9.5 3.857143 c 9.5 4.133285 9.276142 4.357142 9 4.357142 c 8.723858 4.357142 8.5 4.133285 8.5 3.857143 c 8.5 3.581 8.723858 3.357143 9 3.357143 c h 9 5.928572 m 9.276142 5.928572 9.5 6.15243 9.5 6.428572 c 9.5 6.704715 9.276142 6.928572 9 6.928572 c 8.723858 6.928572 8.5 6.704715 8.5 6.428572 c 8.5 6.15243 8.723858 5.928572 9 5.928572 c h 9 8.5 m 9.276142 8.5 9.5 8.723858 9.5 9 c 9.5 9.276142 9.276142 9.5 9 9.5 c 8.723858 9.5 8.5 9.276142 8.5 9 c 8.5 8.723858 8.723858 8.5 9 8.5 c h 9 11.07143 m 9.276142 11.07143 9.5
	11.29529 9.5 11.57143 c 9.5 11.84757 9.276142 12.07143 9 12.07143 c 8.723858 12.07143 8.5 11.84757 8.5 11.57143 c 8.5 11.29529 8.723858 11.07143 9 11.07143 c h 9 13.64286 m 9.276142 13.64286 9.5 13.86672 9.5 14.14286 c 9.5 14.419 9.276142 14.64286 9 14.64286 c 8.723858 14.64286 8.5 14.419 8.5 14.14286 c 8.5 13.86672 8.723858 13.64286 9 13.64286 c h 9 16.21429 m 9.276142 16.21429 9.5 16.43814 9.5 16.71429 c 9.5 16.99043 9.276142 17.21429 9 17.21429 c 8.723858 17.21429 8.5 16.99043 8.5 16.71429 c 8.5 16.43814 8.723858 16.21429 9 16.21429 c h 11.57143 0.7857141 m 11.84757 0.7857141 12.07143 1.009572 12.07143 1.285714 c 12.07143 1.561857 11.84757 1.785714 11.57143 1.785714 c 11.29529 1.785714 11.07143 1.561857 11.07143 1.285714 c 11.07143 1.009572 11.29529 0.7857141 11.57143 0.7857141 c h 11.57143 3.357143 m 11.84757 3.357143 12.07143 3.581 12.07143 3.857143 c 12.07143 4.133285 11.84757 4.357142 11.57143 4.357142 c 11.29529 4.357142 11.07143 4.133285 11.07143 3.857143 c 11.07143 3.581 11.29529 3.357143 11.57143 3.357143 c h 11.57143 5.928572 m 11.84757 5.928572 12.07143 6.15243 12.07143 6.428572 c 12.07143 6.704715 11.84757 6.928572 11.57143 6.928572 c 11.29529 6.928572 11.07143 6.704715 11.07143 6.428572 c 11.07143 6.15243 11.29529 5.928572 11.57143 5.928572 c h 11.57143 8.5 m 11.84757 8.5 12.07143 8.723858 12.07143 9 c 12.07143 9.276142 11.84757 9.5 11.57143 9.5 c 11.29529 9.5 11.07143 9.276142 11.07143 9 c 11.07143 8.723858 11.29529 8.5 11.57143 8.5 c h 11.57143 11.07143 m 11.84757 11.07143 12.07143 11.29529 12.07143 11.57143 c 12.07143 11.84757 11.84757 12.07143 11.57143 12.07143 c 11.29529 12.07143 11.07143 11.84757 11.07143 11.57143 c 11.07143 11.29529 11.29529 11.07143 11.57143 11.07143 c h 11.57143 13.64286 m 11.84757 13.64286 12.07143 13.86672 12.07143 14.14286 c 12.07143 14.419 11.84757 14.64286 11.57143 14.64286 c 11.29529 14.64286 11.07143 14.419 11.07143 14.14286 c 11.07143 13.86672 11.29529 13.64286 11.57143 13.64286 c h 11.57143 16.21429 m 11.84757 16.21429 12.07143 16.43814 12.07143 16.71429 c 12.07143 16.99043 11.84757 17.21429 11.57143 17.21429 c 11.29529 17.21429 11.07143 16.99043 11.07143 16.71429 c 11.07143 16.43814 11.29529 16.21429 11.57143 16.21429 c h 14.14286 0.7857141 m 14.419 0.7857141 14.64286 1.009572 14.64286 1.285714 c 14.64286 1.561857 14.419 1.785714 14.14286 1.785714 c 13.86672 1.785714 13.64286 1.561857 13.64286 1.285714 c 13.64286 1.009572 13.86672 0.7857141 14.14286 0.7857141 c h 14.14286 3.357143 m 14.419 3.357143 14.64286 3.581 14.64286 3.857143 c 14.64286 4.133285 14.419 4.357142 14.14286 4.357142 c 13.86672 4.357142 13.64286 4.133285 13.64286 3.857143 c 13.64286 3.581 13.86672 3.357143 14.14286 3.357143 c h 14.14286 5.928572 m 14.419 5.928572 14.64286 6.15243 14.64286 6.428572 c 14.64286 6.704715 14.419 6.928572 14.14286 6.928572 c 13.86672 6.928572 13.64286 6.704715 13.64286 6.428572 c 13.64286 6.15243 13.86672 5.928572 14.14286 5.928572 c h 14.14286 8.5 m 14.419 8.5 14.64286 8.723858 14.64286 9 c 14.64286 9.276142 14.419 9.5 14.14286 9.5 c 13.86672 9.5 13.64286 9.276142 13.64286 9 c 13.64286 8.723858 13.86672 8.5 14.14286 8.5 c h 14.14286 11.07143 m 14.419 11.07143 14.64286 11.29529 14.64286 11.57143 c 14.64286 11.84757 14.419 12.07143 14.14286 12.07143 c 13.86672 12.07143 13.64286 11.84757 13.64286 11.57143 c 13.64286 11.29529 13.86672 11.07143 14.14286 11.07143 c h 14.14286 13.64286 m 14.419 13.64286 14.64286 13.86672 14.64286 14.14286 c 14.64286 14.419 14.419 14.64286 14.14286 14.64286 c 13.86672 14.64286 13.64286 14.419 13.64286 14.14286 c 13.64286 13.86672 13.86672 13.64286 14.14286 13.64286 c h 14.14286 16.21429 m 14.419 16.21429 14.64286 16.43814 14.64286 16.71429 c 14.64286 16.99043 14.419 17.21429 14.14286 17.21429 c 13.86672 17.21429 13.64286 16.99043 13.64286 16.71429 c 13.64286 16.43814 13.86672 16.21429 14.14286 16.21429 c h 16.71429 0.7857141 m 16.99043 0.7857141 17.21429 1.009572 17.21429 1.285714 c 17.21429 1.561857 16.99043 1.785714 16.71429 1.785714 c 16.43814 1.785714 16.21429 1.561857 16.21429 1.285714 c 16.21429 1.009572 16.43814 0.7857141 16.71429 0.7857141 c h 16.71429 3.357143 m 16.99043 3.357143 17.21429 3.581 17.21429 3.857143 c 17.21429 4.133285 16.99043 4.357142 16.71429 4.357142 c 16.43814 4.357142 16.21429 4.133285 16.21429 3.857143 c 16.21429 3.581 16.43814 3.357143 16.71429 3.357143 c h 16.71429 5.928572 m 16.99043 5.928572 17.21429 6.15243 17.21429 6.428572 c 17.21429 6.704715 16.99043 6.928572 16.71429 6.928572 c 16.43814 6.928572 16.21429 6.704715 16.21429 6.428572 c 16.21429 6.15243 16.43814 5.928572 16.71429 5.928572 c h 16.71429 8.5 m 16.99043 8.5 17.21429 8.723858 17.21429 9 c 17.21429 9.276142 16.99043 9.5 16.71429 9.5 c 16.43814 9.5 16.21429 9.276142 16.21429 9 c 16.21429 8.723858 16.43814 8.5 16.71429 8.5 c h 16.71429 11.07143 m 16.99043 11.07143 17.21429 11.29529 17.21429 11.57143 c 17.21429 11.84757 16.99043 12.07143 16.71429 12.07143 c 16.43814 12.07143 16.21429 11.84757 16.21429 11.57143 c 16.21429 11.29529 16.43814 11.07143 16.71429 11.07143 c h 16.71429 13.64286 m 16.99043 13.64286 17.21429 13.86672 17.21429 14.14286 c 17.21429 14.419 16.99043 14.64286 16.71429 14.64286 c 16.43814 14.64286 16.21429 14.419 16.21429 14.14286 c 16.21429 13.86672 16.43814 13.64286 16.71429 13.64286 c h 16.71429 16.21429 m 16.99043 16.21429 17.21429 16.43814 17.21429 16.71429 c 17.21429 16.99043 16.99043 17.21429 16.71429 17.21429 c 16.43814 17.21429 16.21429 16.99043 16.21429 16.71429 c 16.21429 16.43814 16.43814 16.21429 16.71429 16.21429 c h
	{strokecolor} rg f
	endstream'''
	}

	HatchStyleTemplates={
	'Brick' :'/PatternName(Brick)', #BBObjPtr
	'DiagonalBrick':'/PatternName(Diagonal Brick)',
	'Horizontal':'/PatternName(Horizontal)',
	'Vertical':'/PatternName(Vertical)',
	'DiagonalDown':'/PatternName(Diagonal Down)',
	'DiagonalUp':'/PatternName(Diagonal Up)',
	'Grid':'/PatternName(Grid)',
	'Weave':'/PatternName(Weave)',
	'10Dots':'/PatternName(10% Dots)',
	'20Dots':'/PatternName(20% Dots)',
	'30Dots':'/PatternName(30% Dots)'
	}

	def calculate_bounding_rect(vertices):
	xs = [pt[0] for pt in vertices]
	ys = [pt[1] for pt in vertices]
	min_x = min(xs)
	max_x = max(xs)
	min_y = min(ys)
	max_y = max(ys)
	return [min_x, min_y, max_x, max_y]
	def generate_annotation_xml_block(vertices, area_text, author, custom_data: dict, column_order: list, index: int,
	type_internal: str = 'Bluebeam.PDF.Annotations.AnnotationMeasureArea',
	subject: str = 'Area Measurement',
	label: str = '',opacity:str='',
	color:str='', linestyle:str='',
	hatchstyle:str='',hatchLinescolor:str='',
	bb_objptrMeas:str=''):
	now = datetime.datetime.utcnow()
	mod_date = now.strftime("D:%Y%m%d%H%M%S+00'00'")
	creation_date = now.isoformat() + 'Z'
	id_str = generate_bb_objptr()# "fitz-" + uuid.uuid4().hex[:4].upper()

	vert_str = ' '.join([f'{x:.4f}' for point in vertices for x in point])
	ordered_column_values = [f'({custom_data.get(col, "")})' for col in column_order]
	bsi_column_data = ''.join(ordered_column_values)
	meastype=''
	if subject.startswith('Area'):
	meastype='129'
	polygonpolylineDimension='/PolygonDimension'
	polygonpolyline='/Polygon'
	elif subject.startswith('Perimeter'):
	meastype='130'
	polygonpolylineDimension='/PolyLineDimension'
	polygonpolyline='/PolyLine'
	rectvertices=calculate_bounding_rect(vertices)

	raw_text = f'''<<
	/DS(font: Helvetica 12pt; text-align:center; line-height:13.8pt; color:#FF0000)
	/Cap false
	/AlignOnSegment true
	/MeasurementTypes {meastype}
	/SlopeType 1
	/PitchRun 12
	/IT
	{polygonpolylineDimension}
	/Vertices[{vert_str}]
	/IC[{color}]
	/Pattern/{hatchstyle}/PatternColor[{hatchLinescolor}]
	/FillOpacity {opacity}
	/T({author})
	/CA {opacity}
	/RC(<?xml version="1.0"?><body xmlns:xfa="http://www.xfa.org/schema/xfa-data/1.0/" xfa:contentType="text/html" xfa:APIVersion="BluebeamPDFRevu:2018" xfa:spec="2.2.0" style="font:Helvetica 12pt; text-align:center; line-height:13.8pt; color:#FF0000" xmlns="http://www.w3.org/1999/xhtml"><p>{area_text}</p></body>)
	/Label({label})
	/Subj({subject})
	/Measure/BBObjPtr_{bb_objptrMeas}
	/BSIColumnData[{bsi_column_data}]
	/NM({id_str})
	/Subtype/{polygonpolyline}
	/Rect[{rectvertices[0]} {rectvertices[1]} {rectvertices[2]} {rectvertices[3]}]
	/Contents({area_text})
	/F 4
	/C[{color}]
	/BS{linestyle}
	/M({mod_date})
	>>'''.encode('utf-8')

	compressed = zlib.compress(raw_text)
	base64_raw = base64.b16encode(compressed).lower().decode()

	annotation = Element('Annotation')
	SubElement(annotation, 'Page').text = '1'
	SubElement(annotation, 'Contents').text = area_text
	SubElement(annotation, 'ModDate').text = creation_date
	SubElement(annotation, 'Color').text = '#B7B7E8'
	SubElement(annotation, 'Type').text = 'Polygon'
	SubElement(annotation, 'ID').text = id_str
	SubElement(annotation, 'TypeInternal').text = type_internal
	SubElement(annotation, 'Raw').text = base64_raw
	SubElement(annotation, 'Index').text = str(index)

	custom = SubElement(annotation, 'Custom')
	for key, value in custom_data.items():
	SubElement(custom, key).text = value

	SubElement(annotation, 'Subject').text = subject
	SubElement(annotation, 'CreationDate').text = creation_date
	SubElement(annotation, 'Author').text = author
	SubElement(annotation, 'Label').text = label

	return annotation

	def generate_bb_objptr():
	return ''.join(random.choices(string.ascii_uppercase, k=16))

	def compresslikeBBRaw(textToCompress):
	decompressedX = textToCompress.encode('utf-8')
	print(decompressedX)
	recompressedX = zlib.compress(decompressedX)
	print(recompressedX.hex())
	return recompressedX.hex()

	def setBrickHatch(fillcolor,strokecolor):
	# resourceid='789cf30b0877f2f40cf30f758ff48e0a0df3040029f004fd'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['Brick'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['Brick'],compressedRaw, resourceid

	def setDiagonalBrickHatch(fillcolor,strokecolor):
	# resourceid='789c0b0d8cf47274f60d0df28a740ef4f4f3020029ab04da'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['DiagonalBrick'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['DiagonalBrick'],compressedRaw,resourceid

	def setHorizontalHatch(fillcolor,strokecolor):
	# resourceid='789cf3720b76f6f072f173f58cf071f209f00000273604a3'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['Horizontal'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['Horizontal'],compressedRaw,resourceid

	def setVerticalHatch(fillcolor,strokecolor):
	# resourceid='789cf30d080ef4f609088b74740ff0890a7607002a1904f0'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['Vertical'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['Vertical'],compressedRaw,resourceid

	def setDiagonalDownHatch(fillcolor,strokecolor):
	# resourceid='789cf3f28b74f477f7770b0c7675f68f74f60300288f04c3'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['DiagonalDown'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['DiagonalDown'],compressedRaw,resourceid

	def setDiagonalUpHatch(fillcolor,strokecolor):
	# resourceid='789c0b8a70f30df4f70b09f40cf6f108757606002a2304dc'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['DiagonalUp'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['DiagonalUp'],compressedRaw,resourceid

	def setGridHatch(fillcolor,strokecolor):
	# resourceid='789c730b71738e0a760cf3758972f370740a0300286b04ba'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['Grid'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['Grid'],compressedRaw,resourceid

	def setWeaveHatch(fillcolor,strokecolor):
	# resourceid='789cf30af775f2f1f776720d8972740c8af40500285c04c6'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['Weave'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['Weave'],compressedRaw,resourceid

	def set10DotsHatch(fillcolor,strokecolor):
	# resourceid='789cf3740f71f6770d0e8c0a0f76f50e0df00600291c04e4'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['10Dots'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['10Dots'],compressedRaw,resourceid

	def set20DotsHatch(fillcolor,strokecolor):
	# resourceid='789c738f0cf70bf5f0f0770a0df471760df7000029b004d5'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['20Dots'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['20Dots'],compressedRaw,resourceid

	def set30DotsHatch(fillcolor,strokecolor):
	# resourceid='789cf38c747789f4f68a8c0cf2f6f2f676f2070029b104dc'
	randombb_objptr=generate_bb_objptr()
	resourceid=compresslikeBBRaw(randombb_objptr)
	compressedRaw=compresslikeBBRaw(AllhatchesCodes['30Dots'].format(fillcolor=fillcolor, strokecolor=strokecolor))
	return 'BBObjPtr_'+randombb_objptr+HatchStyleTemplates['30Dots'],compressedRaw,resourceid

	def save_multiple_annotations_bax(annotations, output_path, column_order,pdfWidth,pdfHeight):
	"""
	annotations: list of dicts, each with:
	- vertices: list of [x, y]
	- text: str (label/tooltip)
	- author: str
	- custom_data: dict of custom field values
	- type_internal: str (e.g., Bluebeam.PDF.Annotations.AnnotationMeasurePerimeter)
	- subject: str (e.g., Perimeter Measurement)
	"""
	globalhatches=[]
	scales=[]
	doc = Element('Document', Version='1')
	########## Subelement1 - page ################
	page = SubElement(doc, 'Page', Index='0')
	SubElement(page, 'Label').text = '1'
	SubElement(page, 'Width').text = str(pdfWidth)
	SubElement(page, 'Height').text = str(pdfHeight)

	for i, ann in enumerate(annotations):

	bb_objptrMeas=generate_bb_objptr()
	resourceidComp=compresslikeBBRaw(bb_objptrMeas)
	scales.append(resourceidComp)

	hatchstyle_key = ann.get('hatchstyle') # e.g., 'Brick'
	if hatchstyle_key not in globalhatches and hatchstyle_key:
	globalhatches.append([hatchstyle_key[2],hatchstyle_key[1]]) # id, raw
	hatchstyle=hatchstyle_key[0]
	else:
	hatchstyle='none'

	annotation_xml = generate_annotation_xml_block(
	vertices=ann['vertices'],
	area_text=ann['text'],
	author=ann['author'],
	custom_data=ann['custom_data'],
	column_order=column_order,
	index=i,
	bb_objptrMeas=bb_objptrMeas,
	type_internal=ann.get('type_internal', 'Bluebeam.PDF.Annotations.AnnotationMeasureArea'),
	subject=ann.get('subject', 'Area Measurement'),
	label=ann.get('label', 'label1'),
	opacity=ann.get('opacity', ''),
	color=ann.get('color', ''),
	linestyle=ann.get('linestyle', ''),
	hatchstyle=hatchstyle,
	hatchLinescolor=ann.get('hatchLinescolor',''),
	)
	page.append(annotation_xml)
	################# Subelement 2 - Global resources############
	GlobalResources = SubElement(doc, 'GlobalResources')
	for hatch in globalhatches:
	Resource = SubElement(GlobalResources, 'Resource')
	SubElement(Resource, 'ID').text = hatch[0]
	SubElement(Resource, 'Raw').text = hatch[1]
	for scale in scales:
	Resource = SubElement(GlobalResources, 'Resource')
	SubElement(Resource, 'ID').text = scale
	SubElement(Resource, 'Raw').text = '789c85d04f0b82401005f0af3247bd34bb46d9c11642f15411fe89c03aa80ce161b5d6dda06f9f1e148aace330efc783e779983c6f843bca5ba3086353e8fe8eb618591c4a096be0206d3c6543746f64412a6c94cc35a656f7f381cdd87ce1b8aebbc200386318c7962dc405839f8c7fa43753e9f60e6f200c402b43234ca6e0d959b26ff0d0c1511fa77469fed4e6ea4a3aad2bed37f583545b3575bf051bd610e205c9766776'
	bax_xml= tostring(doc, encoding="unicode", method="xml") #tostring(doc, encoding="utf-8", method="xml").decode("utf-8")

	# print(f" Saved {len(annotations)} annotations to {output_path}")
	return bax_xml

	"""PDF to image"""

	def pdftoimg(datadoc,pdf_content=0):
	if pdf_content:
	doc = fitz.open(stream=pdf_content, filetype="pdf")
	else:
	doc =fitz.open('pdf',datadoc)
	page=doc[0]
	pix = page.get_pixmap() # render page to an image
	pl=Image.frombytes('RGB', [pix.width,pix.height],pix.samples)
	img=np.array(pl)
	img = cv2.cvtColor(img, cv2.COLOR_RGB2BGR)
	print("IMAGE")
	# cv2_imshow(img)
	return img,pix


	# Standard ISO paper sizes in inches
	ISO_SIZES_INCHES = {
	"A0": (33.11, 46.81),
	"A1": (23.39, 33.11),
	"A2": (16.54, 23.39),
	"A3": (11.69, 16.54),
	"A4": (8.27, 11.69),
	"A5": (5.83, 8.27),
	"A6": (4.13, 5.83),
	"A7": (2.91, 4.13),
	"A8": (2.05, 2.91),
	"A9": (1.46, 2.05),
	"A10": (1.02, 1.46)
	}

	def get_paper_size_in_inches(width, height):
	"""Find the closest matching paper size in inches."""
	for size, (w, h) in ISO_SIZES_INCHES.items():
	if (abs(w - width) < 0.1 and abs(h - height) < 0.1) or (abs(w - height) < 0.1 and abs(h - width) < 0.1):
	return size
	return "Unknown Size"

	def analyze_pdf(datadoc,pdf_content=0):
	# Open the PDF file
	if pdf_content:
	pdf_document = fitz.open(stream=pdf_content, filetype="pdf")
	else:
	pdf_document = fitz.open('pdf',datadoc)

	# Iterate through pages and print their sizes
	for page_number in range(len(pdf_document)):
	page = pdf_document[page_number]
	rect = page.rect
	width_points, height_points = rect.width, rect.height

	# Convert points to inches
	width_inches, height_inches = width_points / 72, height_points / 72

	paper_size = get_paper_size_in_inches(width_inches, height_inches)

	print(f"Page {page_number + 1}: {width_inches:.2f} x {height_inches:.2f} inches ({paper_size})")

	pdf_document.close()
	return width_inches , height_inches , paper_size


	def get_dxfSize(dxfpath):

	doc = ezdxf.readfile(dxfpath)
	msp = doc.modelspace()
	# Create a cache for bounding box calculations
	# Get the overall bounding box for all entities in the modelspace
	cache = bbox.Cache()
	overall_bbox = bbox.extents(msp, cache=cache)
	print("Overall Bounding Box:", overall_bbox)
	print(overall_bbox.extmin[0]+overall_bbox.extmax[0], overall_bbox.extmin[1]+overall_bbox.extmax[1])

	return overall_bbox.extmin[0]+overall_bbox.extmax[0], overall_bbox.extmin[1]+overall_bbox.extmax[1]



	def switch_case(argument):
	switcher = {
	"A0": 1.27,
	"A1": 2.54,
	"A2": 5.08,
	"A3": 10.16,
	"A4": 20.32,
	"A5": 40.64,
	"A6": 81.28,
	"A7": 162.56,
	"A8": 325.12,
	"A9": 650.24,
	"A10": 1300.48
	}
	# Get the value from the dictionary; if not found, return a default value
	print("Final Ratio=",switcher.get(argument, 1))
	return switcher.get(argument, 1)




	def RetriveRatio(datadoc,dxfpath,pdf_content=0):
	if pdf_content:
	width,height,paper_size = analyze_pdf (datadoc,pdf_content)
	else:
	width,height,paper_size = analyze_pdf (datadoc)
	if(width > height ):
	bigger=width
	else:
	bigger=height

	width_dxf,height_dxf = get_dxfSize(dxfpath)

	if(width_dxf > height_dxf ):
	bigger_dxf=width_dxf
	else:
	bigger_dxf=height_dxf

	if(0.2 < bigger_dxf/bigger < 1.2):
	print("bigger_dxf/bigger",bigger/bigger_dxf)
	argument = paper_size
	FinalRatio=switch_case(argument)
	else:
	FinalRatio=1
	return FinalRatio,width_dxf


	"""Flips image
	DXF origin is at the bottom left while img origin is top left
	"""

	def flip(img):
	height, width = img.shape[:2]

	# Define the rotation angle (clockwise)
	angle = 180

	# Calculate the rotation matrix
	rotation_matrix = cv2.getRotationMatrix2D((width/2, height/2), angle, 1)

	# Rotate the image
	rotated_image = cv2.warpAffine(img, rotation_matrix, (width, height))
	flipped_horizontal = cv2.flip(rotated_image, 1)
	return flipped_horizontal



	def aci_to_rgb(aci):
	aci_rgb_map = {
	0: (0, 0, 0),
	1: (255, 0, 0),
	2: (255, 255, 0),
	3: (0, 255, 0),
	4: (0, 255, 255),
	5: (0, 0, 255),
	6: (255, 0, 255),
	7: (255, 255, 255),
	8: (65, 65, 65),
	9: (128, 128, 128),
	10: (255, 0, 0),
	11: (255, 170, 170),
	12: (189, 0, 0),
	13: (189, 126, 126),
	14: (129, 0, 0),
	15: (129, 86, 86),
	16: (104, 0, 0),
	17: (104, 69, 69),
	18: (79, 0, 0),
	19: (79, 53, 53),
	20: (255, 63, 0),
	21: (255, 191, 170),
	22: (189, 46, 0),
	23: (189, 141, 126),
	24: (129, 31, 0),
	25: (129, 96, 86),
	26: (104, 25, 0),
	27: (104, 78, 69),
	28: (79, 19, 0),
	29: (79, 59, 53),
	30: (255, 127, 0),
	31: (255, 212, 170),
	32: (189, 94, 0),
	33: (189, 157, 126),
	34: (129, 64, 0),
	35: (129, 107, 86),
	36: (104, 52, 0),
	37: (104, 86, 69),
	38: (79, 39, 0),
	39: (79, 66, 53),
	40: (255, 191, 0),
	41: (255, 234, 170),
	42: (189, 141, 0),
	43: (189, 173, 126),
	44: (129, 96, 0),
	45: (129, 118, 86),
	46: (104, 78, 0),
	47: (104, 95, 69),
	48: (79, 59, 0),
	49: (79, 73, 53),
	50: (255, 255, 0),
	51: (255, 255, 170),
	52: (189, 189, 0),
	53: (189, 189, 126),
	54: (129, 129, 0),
	55: (129, 129, 86),
	56: (104, 104, 0),
	57: (104, 104, 69),
	58: (79, 79, 0),
	59: (79, 79, 53),
	60: (191, 255, 0),
	61: (234, 255, 170),
	62: (141, 189, 0),
	63: (173, 189, 126),
	64: (96, 129, 0),
	65: (118, 129, 86),
	66: (78, 104, 0),
	67: (95, 104, 69),
	68: (59, 79, 0),
	69: (73, 79, 53),
	70: (127, 255, 0),
	71: (212, 255, 170),
	72: (94, 189, 0),
	73: (157, 189, 126),
	74: (64, 129, 0),
	75: (107, 129, 86),
	76: (52, 104, 0),
	77: (86, 104, 69),
	78: (39, 79, 0),
	79: (66, 79, 53),
	80: (63, 255, 0),
	81: (191, 255, 170),
	82: (46, 189, 0),
	83: (141, 189, 126),
	84: (31, 129, 0),
	85: (96, 129, 86),
	86: (25, 104, 0),
	87: (78, 104, 69),
	88: (19, 79, 0),
	89: (59, 79, 53),
	90: (0, 255, 0),
	91: (170, 255, 170),
	92: (0, 189, 0),
	93: (126, 189, 126),
	94: (0, 129, 0),
	95: (86, 129, 86),
	96: (0, 104, 0),
	97: (69, 104, 69),
	98: (0, 79, 0),
	99: (53, 79, 53),
	100: (0, 255, 63),
	101: (170, 255, 191),
	102: (0, 189, 46),
	103: (126, 189, 141),
	104: (0, 129, 31),
	105: (86, 129, 96),
	106: (0, 104, 25),
	107: (69, 104, 78),
	108: (0, 79, 19),
	109: (53, 79, 59),
	110: (0, 255, 127),
	111: (170, 255, 212),
	112: (0, 189, 94),
	113: (126, 189, 157),
	114: (0, 129, 64),
	115: (86, 129, 107),
	116: (0, 104, 52),
	117: (69, 104, 86),
	118: (0, 79, 39),
	119: (53, 79, 66),
	120: (0, 255, 191),
	121: (170, 255, 234),
	122: (0, 189, 141),
	123: (126, 189, 173),
	124: (0, 129, 96),
	125: (86, 129, 118),
	126: (0, 104, 78),
	127: (69, 104, 95),
	128: (0, 79, 59),
	129: (53, 79, 73),
	130: (0, 255, 255),
	131: (170, 255, 255),
	132: (0, 189, 189),
	133: (126, 189, 189),
	134: (0, 129, 129),
	135: (86, 129, 129),
	136: (0, 104, 104),
	137: (69, 104, 104),
	138: (0, 79, 79),
	139: (53, 79, 79),
	140: (0, 191, 255),
	141: (170, 234, 255),
	142: (0, 141, 189),
	143: (126, 173, 189),
	144: (0, 96, 129),
	145: (86, 118, 129),
	146: (0, 78, 104),
	147: (69, 95, 104),
	148: (0, 59, 79),
	149: (53, 73, 79),
	150: (0, 127, 255),
	151: (170, 212, 255),
	152: (0, 94, 189),
	153: (126, 157, 189),
	154: (0, 64, 129),
	155: (86, 107, 129),
	156: (0, 52, 104),
	157: (69, 86, 104),
	158: (0, 39, 79),
	159: (53, 66, 79),
	160: (0, 63, 255),
	161: (170, 191, 255),
	162: (0, 46, 189),
	163: (126, 141, 189),
	164: (0, 31, 129),
	165: (86, 96, 129),
	166: (0, 25, 104),
	167: (69, 78, 104),
	168: (0, 19, 79),
	169: (53, 59, 79),
	170: (0, 0, 255),
	171: (170, 170, 255),
	172: (0, 0, 189),
	173: (126, 126, 189),
	174: (0, 0, 129),
	175: (86, 86, 129),
	176: (0, 0, 104),
	177: (69, 69, 104),
	178: (0, 0, 79),
	179: (53, 53, 79),
	180: (63, 0, 255),
	181: (191, 170, 255),
	182: (46, 0, 189),
	183: (141, 126, 189),
	184: (31, 0, 129),
	185: (96, 86, 129),
	186: (25, 0, 104),
	187: (78, 69, 104),
	188: (19, 0, 79),
	189: (59, 53, 79),
	190: (127, 0, 255),
	191: (212, 170, 255),
	192: (94, 0, 189),
	193: (157, 126, 189),
	194: (64, 0, 129),
	195: (107, 86, 129),
	196: (52, 0, 104),
	197: (86, 69, 104),
	198: (39, 0, 79),
	199: (66, 53, 79),
	200: (191, 0, 255),
	201: (234, 170, 255),
	202: (141, 0, 189),
	203: (173, 126, 189),
	204: (96, 0, 129),
	205: (118, 86, 129),
	206: (78, 0, 104),
	207: (95, 69, 104),
	208: (59, 0, 79),
	209: (73, 53, 79),
	210: (255, 0, 255),
	211: (255, 170, 255),
	212: (189, 0, 189),
	213: (189, 126, 189),
	214: (129, 0, 129),
	215: (129, 86, 129),
	216: (104, 0, 104),
	217: (104, 69, 104),
	218: (79, 0, 79),
	219: (79, 53, 79),
	220: (255, 0, 191),
	221: (255, 170, 234),
	222: (189, 0, 141),
	223: (189, 126, 173),
	224: (129, 0, 96),
	225: (129, 86, 118),
	226: (104, 0, 78),
	227: (104, 69, 95),
	228: (79, 0, 59),
	229: (79, 53, 73),
	230: (255, 0, 127),
	231: (255, 170, 212),
	232: (189, 0, 94),
	233: (189, 126, 157),
	234: (129, 0, 64),
	235: (129, 86, 107),
	236: (104, 0, 52),
	237: (104, 69, 86),
	238: (79, 0, 39),
	239: (79, 53, 66),
	240: (255, 0, 63),
	241: (255, 170, 191),
	242: (189, 0, 46),
	243: (189, 126, 141),
	244: (129, 0, 31),
	245: (129, 86, 96),
	246: (104, 0, 25),
	247: (104, 69, 78),
	248: (79, 0, 19),
	249: (79, 53, 59),
	250: (51, 51, 51),
	251: (80, 80, 80),
	252: (105, 105, 105),
	253: (130, 130, 130),
	254: (190, 190, 190),
	255: (255, 255, 255)
	}

	# Default to white if index is invalid or not found
	return aci_rgb_map.get(aci, (255, 255, 255))


	def int_to_rgb(color_int):
	"""Convert an integer to an (R, G, B) tuple."""
	r = (color_int >> 16) & 255
	g = (color_int >> 8) & 255
	b = color_int & 255
	return (r, g, b)


	def get_hatch_color(entity):
	"""Extract hatch color with detailed debugging."""
	if not entity:
	# print("No entity provided for color extraction.")
	return (255, 255, 255)

	# Check for true color
	if entity.dxf.hasattr('true_color'):
	true_color = entity.dxf.true_color
	rgb_color = int_to_rgb(true_color) # Convert integer to (R, G, B)
	# print(f"True color detected (RGB): {rgb_color}")
	return rgb_color

	# Check for color index
	color_index = entity.dxf.color
	# print(f"Entity color index: {color_index}")
	if 1 <= color_index <= 255:
	rgb_color = aci_to_rgb(color_index) # Convert ACI to RGB
	# print(f"Converted ACI to RGB: {rgb_color}")
	return rgb_color

	# Handle ByLayer or ByBlock
	if color_index == 0: # ByLayer
	layer_name = entity.dxf.layer
	layer = entity.doc.layers.get(layer_name)
	# print(f"ByLayer detected for layer '{layer_name}'.")
	if layer:
	layer_color_index = layer.dxf.color
	# print(layer_color_index)
	rgb_color = aci_to_rgb(layer_color_index)
	# print(f"Layer '{layer_name}' color index {layer_color_index} converted to RGB: {rgb_color}")
	return rgb_color
	else:
	# print(f"Layer '{layer_name}' not found. Defaulting to white.")
	return (255, 255, 255)

	# Default
	# print("Unhandled color case. Defaulting to white.")
	return (255, 255, 255)



	def point_in_rectangle(point, rect_coords):
	x, y = point
	(x1, y1), (x2, y2) = rect_coords
	return x1 <= x <= x2 and y1 <= y <= y2

	from math import sqrt

	def euclidean_distance(point1, point2):
	x1, y1 = point1
	x2, y2 = point2
	return sqrt((x2 - x1)2 + (y2 - y1)2)

	def compute_hatch_centroid(hatch):
	x_coords = []
	y_coords = []
	for path in hatch.paths:
	if path.PATH_TYPE == "PolylinePath":
	for vertex in path.vertices:
	x_coords.append(vertex[0])
	y_coords.append(vertex[1])
	elif path.PATH_TYPE == "EdgePath":
	for edge in path.edges:
	if hasattr(edge, "start"):
	x_coords.append(edge.start[0])
	y_coords.append(edge.start[1])
	if hasattr(edge, "end"):
	x_coords.append(edge.end[0])
	y_coords.append(edge.end[1])
	if x_coords and y_coords:
	return (sum(x_coords) / len(x_coords), sum(y_coords) / len(y_coords))
	return None

	"""### Hatched areas"""
	def get_hatched_areas(datadoc,filename,FinalRatio,rotationangle,SearchArray,CollectedColors):

	coloredarray = [tuple(x) for x in CollectedColors]

	# coloredarray = [list(c) if isinstance(c, (tuple, list)) else [c] for c in CollectedColors]

	print("CollectedColors = ",CollectedColors)
	# print("coloredarray = ",coloredarray)

	print("SearchArray = ",SearchArray)

	doc = ezdxf.readfile(filename)
	doc.header['$MEASUREMENT'] = 1
	msp = doc.modelspace()
	trial=0
	hatched_areas = []
	threshold=0.001
	TextFound = 0
	j=0
	unique_shapes = []


	text_with_positions = []
	text_color_mapping = {}
	color_palette = [
	(255, 0, 0), (0, 0, 255), (0, 255, 255), (0, 64, 0), (255, 204, 0),
	(255, 128, 64), (255, 0, 128), (255, 128, 192), (128, 128, 255),
	(128, 64, 0), (0, 255, 0), (0, 200, 0), (255, 128, 255), (128, 0, 255),
	(0, 128, 192), (128, 0, 128), (128, 0, 0), (0, 128, 255), (149, 1, 70),
	(255, 182, 128), (222, 48, 71), (240, 0, 112), (255, 0, 255),
	(192, 46, 65), (0, 0, 128), (0, 128, 64), (255, 255, 0), (128, 0, 80),
	(255, 255, 128), (90, 255, 140), (255, 200, 20), (91, 16, 51),
	(90, 105, 138), (114, 10, 138), (36, 82, 78), (225, 105, 190),
	(108, 150, 170), (11, 35, 75), (42, 176, 170), (255, 176, 170),
	(209, 151, 15), (81, 27, 85), (226, 106, 122), (67, 119, 149),
	(159, 179, 140), (159, 179, 30), (255, 85, 198), (255, 27, 85),
	(188, 158, 8), (140, 188, 120), (59, 61, 52), (65, 81, 21),
	(212, 255, 174), (15, 164, 90), (41, 217, 245), (213, 23, 182),
	(11, 85, 169), (78, 153, 239), (0, 66, 141), (64, 98, 232),
	(140, 112, 255), (57, 33, 154), (194, 117, 252), (116, 92, 135),
	(74, 43, 98), (188, 13, 123), (129, 58, 91), (255, 128, 100),
	(171, 122, 145), (255, 98, 98), (222, 48, 77)
	]
	import re

	text_with_positions = []
	# SearchArray=[["","Wall Type","",""],["","","",""]]

	# print("SearchArray=",len(SearchArray))
	# print("SearchArray=",len(SearchArray[0]))
	# print("SearchArray=",SearchArray[0][0])

	if(SearchArray):
	for i in range(len(SearchArray)):

	if (SearchArray[i][0] and SearchArray[i][1] and SearchArray[i][2]):
	for text_entity in doc.modelspace().query('TEXT MTEXT'):
	text = text_entity.text.strip() if hasattr(text_entity, 'text') else ""
	# if (text.startswith("P") and len(text) == 3) or (text.startswith("I") and len(text) == 3): # Filter for "Wall"
	if(text.startswith(SearchArray[i][0]) and len(text)==int(SearchArray[i][2])):
	position = text_entity.dxf.insert # Extract text position
	x, y = position.x, position.y

	for text_entity in doc.modelspace().query('TEXT MTEXT'):
	NBS = text_entity.text.strip() if hasattr(text_entity, 'text') else ""
	if (NBS.startswith(SearchArray[i][1])):
	positionNBS = text_entity.dxf.insert # Extract text position
	xNBS, yNBS = positionNBS.x, positionNBS.y

	if(x == xNBS or y == yNBS):
	textNBS=NBS
	break

	else:
	textNBS = None



	nearest_hatch = None
	min_distance = float('inf') # Initialize with a very large value
	detected_color = (255, 255, 255) # Default to white

	# Search for the nearest hatch
	for hatch in doc.modelspace().query('HATCH'): # Query only hatches
	if hatch.paths:
	for path in hatch.paths:
	if path.type == 1: # PolylinePath
	vertices = [v[:2] for v in path.vertices]
	# Calculate the centroid of the hatch
	centroid_x = sum(v[0] for v in vertices) / len(vertices)
	centroid_y = sum(v[1] for v in vertices) / len(vertices)
	centroid = (centroid_x, centroid_y)

	# Calculate the distance between the text and the hatch centroid
	distance = calculate_distance((x, y), centroid)

	# Update the nearest hatch if a closer one is found
	if distance < min_distance:
	min_distance = distance
	nearest_hatch = hatch

	# Get the color of this hatch
	current_color = get_hatch_color(hatch)
	if current_color != (255, 255, 255): # Valid color found
	detected_color = current_color
	break # Stop checking further paths for this hatch


	# Append the detected result only once
	text_with_positions.append([text, textNBS, (x, y), detected_color])
	print("text_with_positions=",text_with_positions)

	elif (SearchArray[i][0] and SearchArray[i][2]):
	for text_entity in doc.modelspace().query('TEXT MTEXT'):
	text = text_entity.text.strip() if hasattr(text_entity, 'text') else ""
	# if (text.startswith("P") and len(text) == 3) or (text.startswith("I") and len(text) == 3): # Filter for "Wall"
	if(text.startswith(SearchArray[i][0]) and len(text)==int(SearchArray[i][2])):
	position = text_entity.dxf.insert # Extract text position
	x, y = position.x, position.y
	textNBS = None
	nearest_hatch = None
	min_distance = float('inf') # Initialize with a very large value
	detected_color = (255, 255, 255) # Default to white

	# Search for the nearest hatch
	for hatch in doc.modelspace().query('HATCH'): # Query only hatches
	if hatch.paths:
	for path in hatch.paths:
	if path.type == 1: # PolylinePath
	vertices = [v[:2] for v in path.vertices]
	# Calculate the centroid of the hatch
	centroid_x = sum(v[0] for v in vertices) / len(vertices)
	centroid_y = sum(v[1] for v in vertices) / len(vertices)
	centroid = (centroid_x, centroid_y)

	# Calculate the distance between the text and the hatch centroid
	distance = calculate_distance((x, y), centroid)

	# Update the nearest hatch if a closer one is found
	if distance < min_distance:
	min_distance = distance
	nearest_hatch = hatch

	# Get the color of this hatch
	current_color = get_hatch_color(hatch)
	if current_color != (255, 255, 255): # Valid color found
	detected_color = current_color
	break # Stop checking further paths for this hatch


	# Append the detected result only once
	text_with_positions.append([text, textNBS, (x, y), detected_color])
	print("text_with_positions=",text_with_positions)

	elif(SearchArray[i][0]):
	for text_entity in doc.modelspace().query('TEXT MTEXT'):
	text = text_entity.text.strip() if hasattr(text_entity, 'text') else ""
	# if (text.startswith("P") and len(text) == 3) or (text.startswith("I") and len(text) == 3): # Filter for "Wall"
	if(text.startswith(SearchArray[i][0])):
	position = text_entity.dxf.insert # Extract text position
	x, y = position.x, position.y
	textNBS = None
	nearest_hatch = None
	min_distance = float('inf') # Initialize with a very large value
	detected_color = (255, 255, 255) # Default to white

	# Search for the nearest hatch
	for hatch in doc.modelspace().query('HATCH'): # Query only hatches
	if hatch.paths:
	for path in hatch.paths:
	if path.type == 1: # PolylinePath
	vertices = [v[:2] for v in path.vertices]
	# Calculate the centroid of the hatch
	centroid_x = sum(v[0] for v in vertices) / len(vertices)
	centroid_y = sum(v[1] for v in vertices) / len(vertices)
	centroid = (centroid_x, centroid_y)

	# Calculate the distance between the text and the hatch centroid
	distance = calculate_distance((x, y), centroid)

	# Update the nearest hatch if a closer one is found
	if distance < min_distance:
	min_distance = distance
	nearest_hatch = hatch

	# Get the color of this hatch
	current_color = get_hatch_color(hatch)
	if current_color != (255, 255, 255): # Valid color found
	detected_color = current_color
	break # Stop checking further paths for this hatch


	# Append the detected result only once
	text_with_positions.append([text, textNBS, (x, y), detected_color])
	print("text_with_positions=",text_with_positions)








	grouped = {}
	for entry in text_with_positions:
	key = entry[0]
	grouped.setdefault(key, []).append(entry)

	# Filter the groups: if any entry in a group has a non-None Text Nbs, keep only one of those
	filtered_results = []
	for key, entries in grouped.items():
	# Find the first entry with a valid textNBS (non-None)
	complete = next((entry for entry in entries if entry[1] is not None), None)
	if complete:
	filtered_results.append(complete)
	else:
	# If none are complete, you can choose to keep just one entry
	filtered_results.append(entries[0])

	text_with_positions=filtered_results

	for entity in msp:
	if entity.dxftype() == 'HATCH':

	cntPoints=[]
	for path in entity.paths:

	# path_type = path.type

	# # Resolve the path type to its name
	# path_type_name = BoundaryPathType(path_type).name
	# print(f"Encountered path type: {path_type_name}")

	vertices = [] # Reset vertices for each path

	# print(str(path.type))

	if str(path.type) == 'BoundaryPathType.POLYLINE' or path.type == 1:
	# if path.type == 2: # Polyline path
	# Handle POLYLINE type HATCH
	vertices = [(vertex[0] * FinalRatio, vertex[1] * FinalRatio) for vertex in path.vertices]
	# print("Hatch Vertices = ",vertices)

	if len(vertices) > 3:
	poly = ShapelyPolygon(vertices)
	minx, miny, maxx, maxy = poly.bounds
	width = maxx - minx
	height = maxy - miny




	if (poly.area > 0 and (height > 0 or width > 0)):

	length = height
	if(width > length):
	length = width

	area1 = round(poly.area, 3)
	perimeter = round(poly.length, 3)
	# print("Vertices = ",vertices)
	normalized_vertices = normalize_vertices(vertices)

	rgb_color = get_hatch_color(entity)
	# print("rgb_color = ",rgb_color)

	# if(rgb_color == (255, 255, 255)):
	# if(len(text_with_positions)>0):

	# for text, position, color in text_with_positions:
	# text_position = Point(position[0], position[1])

	# if poly.contains(text_position):
	# rgb_color = color
	# break

	duplicate_found = False
	for existing_vertices, existing_area in unique_shapes:
	if normalized_vertices == existing_vertices and areas_are_similar(area1, existing_area):
	duplicate_found = True
	break

	if not duplicate_found:
	# rgb_color = get_hatch_color(entity) # Assuming this function exists
	unique_shapes.append((normalized_vertices, area1))

	if length > 0.6:
	# rgbconverted = tuple(rgb_color)
	# print("rgb_color = ",type(rgb_color))
	# print("CollectedColors = ",type(CollectedColors))
	# colored_fix = [tuple(map(int, c)) for c in coloredarray]

	if ( len(coloredarray) > 0 and ( rgb_color in coloredarray)):

	print("rgbcolor in 2.7 hatch 1 type = ",type(rgb_color))
	print("coloredarray in 2.7 hatch 1 type = ",type(coloredarray))

	hatched_areas.append([vertices, area1, length, rgb_color])
	elif (len(coloredarray) == 0):
	hatched_areas.append([vertices, area1, length, rgb_color])
	print("rgbcolor = ",rgb_color)
	print("coloredarray =",coloredarray)


	elif str(path.type) == 'BoundaryPathType.EDGE' or path.type == 2:
	# elif path.type == 2: # Edge path
	# Handle EDGE type HATCH
	vert = []
	for edge in path.edges:
	x, y = edge.start
	x1, y1 = edge.end
	vert.append((x * FinalRatio, y * FinalRatio))
	vert.append((x1 * FinalRatio, y1 * FinalRatio))

	poly = ShapelyPolygon(vert)
	minx, miny, maxx, maxy = poly.bounds
	width = maxx - minx
	height = maxy - miny

	if (poly.area > 0 and (height > 0 or width > 0)):

	length = height
	if(width > length):
	length = width

	area1 = round(poly.area, 3)
	perimeter = round(poly.length, 3)
	normalized_vertices = normalize_vertices(vert)
	rgb_color = get_hatch_color(entity)
	# print("rgb_color = ",rgb_color)

	# if(rgb_color == (255, 255, 255)):
	# if(len(text_with_positions)>0):
	# for text, position, color in text_with_positions:
	# text_position = Point(position[0], position[1])

	# if poly.contains(text_position):
	# rgb_color = color
	# break


	duplicate_found = False
	for existing_vertices, existing_area in unique_shapes:
	if normalized_vertices == existing_vertices and areas_are_similar(area1, existing_area):
	duplicate_found = True
	break

	if not duplicate_found:
	# rgb_color = get_hatch_color(entity) # Assuming this function exists
	unique_shapes.append((normalized_vertices, area1))

	if length > 0.6:

	rgbconverted = tuple(rgb_color)
	if ( len(CollectedColors) > 0 and (rgb_color in CollectedColors)):

	print("rgbcolor in 2.7 hatch 2 type = ",type(rgb_color))
	print("CollectedColors in 2.7 hatch 2 type = ",type(CollectedColors))

	hatched_areas.append([vert, area1, length, rgb_color])
	elif (len(CollectedColors) == 0):
	hatched_areas.append([vert, area1, length, rgb_color])
	else:
	print(f"Encountered path type: {path.type}")

	elif entity.dxftype() == 'SOLID':



	vertices = [entity.dxf.vtx0 * (FinalRatio), entity.dxf.vtx1* (FinalRatio), entity.dxf.vtx2* (FinalRatio), entity.dxf.vtx3* (FinalRatio)]
	poly = ShapelyPolygon(vertices)
	minx, miny, maxx, maxy = poly.bounds

	# Calculate the width and height of the bounding box
	width = maxx - minx
	height = maxy - miny

	if (poly.area > 0 and (height > 0 and width > 0)):
	area1 = round(poly.area, 3)
	perimeter = round(poly.length, 3)
	normalized_vertices = normalize_vertices(vertices)

	duplicate_found = False
	for existing_vertices, existing_area in unique_shapes:
	if normalized_vertices == existing_vertices or areas_are_similar(area1, existing_area):
	duplicate_found = True
	break

	if not duplicate_found:
	rgb_color = get_hatch_color(entity) # Assuming this function exists
	unique_shapes.append((normalized_vertices, area1))
	rgbconverted = tuple(rgb_color)
	if ( len(CollectedColors) > 0 and (rgb_color in CollectedColors)):
	print("rgbcolor in 2.7 solid type = ",type(rgb_color))
	print("CollectedColors in 2.7 solid type = ",type(CollectedColors))
	hatched_areas.append([vertices, area1, perimeter, rgb_color])
	elif (len(CollectedColors) == 0):
	hatched_areas.append([vertices, area1, perimeter, rgb_color])




	elif entity.dxftype() == 'LWPOLYLINE':

	vertices = []
	lwpolyline = entity
	points = lwpolyline.get_points()
	flag = 0

	# Collect vertices and apply the FinalRatio
	for i in range(len(points)):
	vertices.append([points[i][0] * FinalRatio, points[i][1] * FinalRatio])

	# # Ensure there are more than 3 vertices
	if len(vertices) > 3:
	# Check if the polyline is closed
	if vertices[0][0] == vertices[-1][0] or vertices[0][1] == vertices[-1][1]:
	poly = ShapelyPolygon(vertices)
	minx, miny, maxx, maxy = poly.bounds

	# Calculate width and height of the bounding box
	width = maxx - minx
	height = maxy - miny

	# Check area and size constraints
	if (poly.area > 0 and (height > 0 and width > 0)):
	area1 = round(poly.area, 3)
	perimeter = round(poly.length, 3)
	normalized_vertices = normalize_vertices(vertices)

	duplicate_found = False
	for existing_vertices, existing_area in unique_shapes:
	if normalized_vertices == existing_vertices or areas_are_similar(area1, existing_area):
	duplicate_found = True
	break

	if not duplicate_found:
	rgb_color = get_hatch_color(entity) # Assuming this function exists
	unique_shapes.append((normalized_vertices, area1))
	hatched_areas.append([vertices, area1, perimeter, rgb_color])



	elif entity.dxftype() == 'POLYLINE':

	flag=0
	vertices = [(v.dxf.location.x * (FinalRatio), v.dxf.location.y * (FinalRatio)) for v in entity.vertices]
	# print('Vertices:', vertices)

	if(len(vertices)>3):

	if(vertices[0][0] == vertices[len(vertices)-1][0] or vertices[0][1] == vertices[len(vertices)-1][1]):

	poly=ShapelyPolygon(vertices)
	minx, miny, maxx, maxy = poly.bounds

	# Calculate the width and height of the bounding box
	width = maxx - minx
	height = maxy - miny

	if (poly.area > 0 and (height > 0 and width > 0)):
	area1 = round(poly.area,3)
	perimeter = round (poly.length,3)
	normalized_vertices = normalize_vertices(vertices)

	duplicate_found = False
	for existing_vertices, existing_area in unique_shapes:
	if normalized_vertices == existing_vertices or areas_are_similar(area1, existing_area):
	duplicate_found = True
	break

	if not duplicate_found:
	rgb_color = get_hatch_color(entity) # Assuming this function exists
	unique_shapes.append((normalized_vertices, area1))
	hatched_areas.append([vertices, area1, perimeter, rgb_color])


	elif entity.dxftype() == 'SPLINE':

	spline_entity = entity
	vertices = []
	control_points = spline_entity.control_points
	if(len(control_points)>3):
	for i in range(len(control_points)):
	vertices.append([control_points[i][0]* (FinalRatio),control_points[i][1]* (FinalRatio)])
	poly=ShapelyPolygon(vertices)

	minx, miny, maxx, maxy = poly.bounds

	# Calculate the width and height of the bounding box
	width = maxx - minx
	height = maxy - miny


	if (poly.area > 0 and (height > 0 and width > 0)):
	area1 = round(poly.area,3)
	perimeter = round (poly.length,3)
	normalized_vertices = normalize_vertices(vertices)

	duplicate_found = False
	for existing_vertices, existing_area in unique_shapes:
	if normalized_vertices == existing_vertices or areas_are_similar(area1, existing_area):
	duplicate_found = True
	break

	if not duplicate_found:
	rgb_color = get_hatch_color(entity) # Assuming this function exists
	unique_shapes.append((normalized_vertices, area1))
	hatched_areas.append([vertices, area1, perimeter, rgb_color])



	sorted_data = sorted(hatched_areas, key=lambda x: x[1])
	return sorted_data,text_with_positions


	"""### Rotate polygon"""



	def rotate_point(point, angle,pdfrotation,width,height, center_point=(0, 0)):
	"""Rotates a point around center_point(origin by default)
	Angle is in degrees.
	Rotation is counter-clockwise
	"""
	angle_rad = radians(angle % 360)
	# Shift the point so that center_point becomes the origin
	new_point = (point[0] - center_point[0], point[1] - center_point[1])
	new_point = (new_point[0] * cos(angle_rad) - new_point[1] * sin(angle_rad),
	new_point[0] * sin(angle_rad) + new_point[1] * cos(angle_rad))
	# Reverse the shifting we have done
	if pdfrotation!=0:

	new_point = (new_point[0]+width + center_point[0], new_point[1] + center_point[1]) #pdfsize[2] is the same as +width
	else:

	new_point = (new_point[0] + center_point[0], new_point[1]+ height + center_point[1]) # pdfsize[3] is the same as +height
	# new_point = (new_point[0] + center_point[0], new_point[1] + center_point[1])
	return new_point


	def rotate_polygon(polygon, angle, pdfrotation,width,height,center_point=(0, 0)):
	"""Rotates the given polygon which consists of corners represented as (x,y)
	around center_point (origin by default)
	Rotation is counter-clockwise
	Angle is in degrees
	"""
	rotated_polygon = []
	for corner in polygon:
	rotated_corner = rotate_point(corner, angle,pdfrotation,width,height, center_point)
	rotated_polygon.append(rotated_corner)
	return rotated_polygon

	#create a dataframe containing color , count(how many times is this object found in the plan), area of 1 of these shapes, total area
	#perimeter, totat perimeter, length, total length
	#import pandas as pd
	#SimilarAreaDictionary= pd.DataFrame(columns=['Guess','Color','Occurences','Area','Total Area','Perimeter','Total Perimeter','Length','Total Length','R','G','B'])
	#loop 3la hatched areas and count the occurences of each shape w create a table bl hagat di



	def Create_DF(dxfpath,datadoc,hatched_areas,pdf_content=0):

	if pdf_content:
	FinalRatio,width_dxf= RetriveRatio(datadoc,dxfpath,pdf_content)
	else:
	FinalRatio,width_dxf= RetriveRatio(datadoc,dxfpath)
	# hatched_areas = get_hatched_areas(datadoc,dxfpath,FinalRatio)

	# hatched_areas=remove_duplicate_shapes(new_hatched_areas)

	# SimilarAreaDictionary= pd.DataFrame(columns=['Area', 'Total Area', 'Perimeter', 'Total Perimeter', 'Occurences', 'Color'])
	SimilarAreaDictionary= pd.DataFrame(columns=['Guess','Color','Occurences','Area','Total Area','Perimeter','Total Perimeter','Length','Total Length','Texts','Comments'])

	# colorRanges2=generate_color_array(30000)
	# colorRanges = [[255, 0, 0], [0, 0, 255], [0, 255, 255], [0, 64, 0], [255, 204, 0], [255, 128, 64], [255, 0, 128], [255, 128, 192], [128, 128, 255], [128, 64, 0],[0, 255, 0],[0, 200, 0],[255, 128, 255], [128, 0, 255], [0, 128, 192], [128, 0, 128],[128, 0, 0], [0, 128, 255], [149, 1, 70], [255, 182, 128], [222, 48, 71], [240, 0, 112], [255, 0, 255], [192, 46, 65], [0, 0, 128],[0, 128, 64],[255, 255, 0], [128, 0, 80], [255, 255, 128], [90, 255, 140],[255, 200, 20],[91, 16, 51], [90, 105, 138], [114, 10, 138], [36, 82, 78], [225, 105, 190], [108, 150, 170], [11, 35, 75], [42, 176, 170], [255, 176, 170], [209, 151, 15],[81, 27, 85], [226, 106, 122], [67, 119, 149], [159, 179, 140], [159, 179, 30],[255, 85, 198], [255, 27, 85], [188, 158, 8],[140, 188, 120], [59, 61, 52], [65, 81, 21], [212, 255, 174], [15, 164, 90],[41, 217, 245], [213, 23, 182], [11, 85, 169], [78, 153, 239], [0, 66, 141],[64, 98, 232], [140, 112, 255], [57, 33, 154], [194, 117, 252], [116, 92, 135], [74, 43, 98], [188, 13, 123], [129, 58, 91], [255, 128, 100], [171, 122, 145], [255, 98, 98], [222, 48, 77]]
	# colorUsed=[]
	TotalArea=0
	TotalPerimeter=0
	for shape in hatched_areas:
	area = shape[1] # area
	perimeter = shape[2] # perimeter
	# if(i < len(colorRanges)):
	# color = colorRanges[i]
	# colorUsed.append(color)
	# else:
	# color = colorRanges2[i]
	# colorUsed.append(color)
	TotalArea = area
	TotalPerimeter = perimeter
	tol=0
	condition1 = (SimilarAreaDictionary['Area'] >= area - tol) & (SimilarAreaDictionary['Area'] <= area +tol)
	condition2 = (SimilarAreaDictionary['Perimeter'] >= perimeter -tol) & (SimilarAreaDictionary['Perimeter'] <= perimeter +tol)
	combined_condition = condition1 & condition2

	if any(combined_condition):
	index = np.where(combined_condition)[0][0]
	SimilarAreaDictionary.at[index, 'Occurences'] += 1
	SimilarAreaDictionary.at[index, 'Total Area'] = SimilarAreaDictionary.at[index, 'Area'] * SimilarAreaDictionary.at[index, 'Occurences']
	SimilarAreaDictionary.at[index, 'Total Perimeter'] = SimilarAreaDictionary.at[index, 'Perimeter'] * SimilarAreaDictionary.at[index, 'Occurences']
	else:
	TotalArea=area
	TotalPerimeter=perimeter
	# print("Shape[3]",shape[3])
	new_data = {'Area': area, 'Total Area': TotalArea ,'Perimeter': perimeter, 'Total Perimeter': TotalPerimeter, 'Occurences': 1, 'Color':shape[3],'Comments':''} #add color here and read color to insert in
	SimilarAreaDictionary = pd.concat([SimilarAreaDictionary, pd.DataFrame([new_data])], ignore_index=True)

	# print(SimilarAreaDictionary)
	return SimilarAreaDictionary
	"""### Draw on Image and PDF"""

	# from sklearn.cluster import KMeans

	def color_distance(color1, color2):
	print("color1 = ",color1)
	print("color2 = ",color2)
	print("abs(color1[0] - color2[0]) = ",abs(color1[0] - color2[0]))
	print("abs(color1[1] - color2[1]) = ",abs(color1[1] - color2[1]))
	print("abs(color1[2] - color2[2]) = ",abs(color1[2] - color2[2]))
	if(abs(color1[0] - color2[0]) < 20 and
	abs(color1[1] - color2[1]) < 20 and
	abs(color1[2] - color2[2]) < 20):
	return 1
	else:
	return 100
	# return np.sqrt(sum((a - b) ** 2 for a, b in zip(color1, color2)))

	# Unify colors within a distance threshold
	def unify_colors(df, threshold=20):
	# Convert colors to tuple if they are not already in tuple format
	df['Color'] = df['Color'].apply(lambda x: tuple(x) if isinstance(x, list) else x)

	# Iterate through the DataFrame and compare each color with the next one
	for i in range(len(df) - 1): # We don't need to compare the last color with anything
	current_color = df.at[i, 'Color']
	next_color = df.at[i + 1, 'Color']

	# If the distance between current color and the next color is smaller than the threshold
	if color_distance(current_color, next_color) <= threshold:
	# Make both the same color (unify them to the current color)
	df.at[i + 1, 'Color'] = current_color # Change the next color to the current color

	return df

	def normalize_color(color):
	"""Convert PDF color (range 0-1) to RGB (range 0-255)."""
	return tuple(min(max(round(c * 255), 0), 255) for c in color)


	def color_close_enough(c1, c2, threshold=10):
	return all(abs(a - b) <= threshold for a, b in zip(c1, c2))

	def adjustannotations(OutputPdfStage1,text_with_positions,CollectedColors):
	input_pdf_path = OutputPdfStage1
	output_pdf_path = "Final-WallsAdjusted.pdf"
	annotations_data = []

	paired_colors = []
	for i in range(0, len(CollectedColors), 2):
	name = CollectedColors[i] # take the current name
	color_list = CollectedColors[i+1] # take the next item as color list
	# convert each component to int
	color = tuple(int(c) for c in color_list)
	paired_colors.append([name, color])

	CollectedColors = paired_colors

	# Load the input PDF
	pdf_bytes_io = BytesIO(OutputPdfStage1)

	reader = PdfReader(pdf_bytes_io)
	writer = PdfWriter()

	# Append all pages to the writer
	writer.append_pages_from_reader(reader)

	# Add metadata (optional)
	metadata = reader.metadata
	writer.add_metadata(metadata)

	for page_index, page in enumerate(writer.pages):
	if "/Annots" not in page:
	continue

	for annot in page["/Annots"]:
	obj = annot.get_object()
	subtype = obj.get("/Subtype")

	# Group vertices for metadata
	if subtype == "/Line":
	raw_vertices = obj.get("/L", [])
	else:
	raw_vertices = obj.get("/Vertices", [])
	vertices = group_vertices(raw_vertices)

	# Normalize color
	raw_color = obj.get("/C")
	try:
	annot_color = normalize_color(raw_color)
	except:
	annot_color = raw_color

	# Extract measurement from annotation content
	measurement = extract_measurement(obj)
	# Assign to area or perimeter based on subtype
	area = measurement if subtype == "/Polygon" else None
	perimeter = measurement if subtype in ["/Line", "/PolyLine"] else None

	# Match text and NBS
	matched_text = None
	matched_nbs = None
	if subtype in ["/Line", "/PolyLine", "/Polygon"] and raw_color:
	matched_entry = next(
	((t, n) for t, n, _, c in text_with_positions if color_close_enough(annot_color, c)),
	(None, None)
	)
	matched_text, matched_nbs = matched_entry
	print("1st entry nbs: " ,type(matched_nbs))
	print("1st entry text: ",type(matched_text))
	combined = ""
	if matched_text and matched_nbs:
	combined = f"{matched_text} - {matched_nbs}"
	elif matched_text:
	combined = matched_text
	elif matched_nbs:
	combined = matched_nbs
	if combined:
	obj.update({NameObject("/T"): TextStringObject(combined)})




	if subtype in ["/Line", "/PolyLine", "/Polygon"] and raw_color:
	matched_entry2 = next(
	((name,color) for name,color in CollectedColors if color_close_enough(annot_color,color)),
	(None, None)
	)
	matched_text2, matched_nbs2 = matched_entry2
	# print("2nd entry nbs: " ,type(matched_nbs2))
	# print("2nd entry text: ",type(matched_text2))
	combined2 = ""
	if matched_text2 and matched_nbs2:
	combined2 = f"{matched_text2} - {matched_nbs2}"
	elif matched_text:
	combined2 = str(matched_text2)
	elif matched_nbs:
	combined2 = str(matched_nbs2)
	if combined2:
	obj.update({NameObject("/T"): TextStringObject(combined2)})

	# Update annotation dictionaries for measurement type
	if subtype == "/Line" and obj.get("/Subj", "") == "Perimeter Measurement":
	obj.update({
	NameObject("/Measure"): DictionaryObject({
	NameObject("/Type"): NameObject("/Measure"),
	NameObject("/L"): DictionaryObject({
	NameObject("/G"): FloatObject(1),
	NameObject("/U"): TextStringObject("m"),
	}),
	}),
	NameObject("/IT"): NameObject("/LineDimension"),
	NameObject("/Subj"): TextStringObject("Length Measurement"),
	})
	if subtype == "/Polygon" and obj.get("/Subj", "") == "Area Measurement":
	obj.update({
	NameObject("/Measure"): DictionaryObject({
	NameObject("/Type"): NameObject("/Measure"),
	NameObject("/Area"): DictionaryObject({
	NameObject("/G"): FloatObject(1),
	NameObject("/U"): TextStringObject("sq m"),
	}),
	}),
	NameObject("/IT"): NameObject("/Area_Annotation"),
	NameObject("/Subj"): TextStringObject("Area Measurement"),
	})

	# Append metadata
	annotations_data.append([
	vertices,
	area,
	perimeter,
	annot_color,
	matched_text,
	matched_nbs,
	matched_text2,
	matched_nbs2,
	])



	output_pdf_io = BytesIO()
	writer.write(output_pdf_io)
	output_pdf_io.seek(0)

	print(f"Annotations updated and saved to {output_pdf_path}")
	return output_pdf_io.read() , annotations_data

	def distance(rect1, rect2):
	"""Calculate the Euclidean distance between two annotation centers."""
	x1, y1 = (float(rect1[0]) + float(rect1[2])) / 2, (float(rect1[1]) + float(rect1[3])) / 2
	x2, y2 = (float(rect2[0]) + float(rect2[2])) / 2, (float(rect2[1]) + float(rect2[3])) / 2
	return math.sqrt((x2 - x1) 2 + (y2 - y1) 2)

	def group_vertices(raw):
	"""Convert flat list [x1,y1,x2,y2,...] into [[x1,y1],[x2,y2],...]"""
	if not raw or len(raw) < 2:
	return []
	return [[float(raw[i]), float(raw[i+1])] for i in range(0, len(raw), 2)]

	def group_rect(verts):
	"""Convert list of [x,y] vertices into a bounding rect [x_min, y_min, x_max, y_max]."""
	xs = [v[0] for v in verts]
	ys = [v[1] for v in verts]
	return [min(xs), min(ys), max(xs), max(ys)] if verts else None

	def extract_measurement(obj):
	"""Extract first numeric measurement from an annotation's /Contents."""
	contents = obj.get("/Contents")
	if not contents:
	return None
	match = re.search(r"([0-9]*\.?[0-9]+)", str(contents))
	return float(match.group(1)) if match else None

	def remove_duplicate_annotations(pdf_path, threshold):
	"""Remove one of the duplicate annotations if they are close and have the same color."""

	input_pdf_path = pdf_path
	output_pdf_path = "Filtered-Walls.pdf"

	# Load the input PDF
	pdf_bytes_io = BytesIO(pdf_path)

	reader = PdfReader(pdf_bytes_io)
	writer = PdfWriter()

	# Append all pages to the writer
	# writer.append_pages_from_reader(reader)

	# Add metadata (optional)
	metadata = reader.metadata
	writer.add_metadata(metadata)

	for page_index in range(len(reader.pages)):
	page = reader.pages[page_index]

	if "/Annots" in page:
	annotations = page["/Annots"]
	annots_data = []
	to_delete = set()

	# Extract annotation positions and colors
	# for annot_index, annot_ref in enumerate(annotations):
	# annot = annot_ref.get_object()

	# if "/Rect" in annot and "/C" in annot:
	# rect = annot["/Rect"]
	# if isinstance(rect, ArrayObject): # Ensure rect is a list
	# rect = list(rect)

	# color = normalize_color(annot["/C"])
	# annots_data.append((annot_index, rect, color))

	for i, annot_ref in enumerate(annotations):
	annot = annot_ref.get_object()
	rect = annot.get("/Rect")
	color = annot.get("/C")

	if rect and color and isinstance(rect, ArrayObject) and len(rect) == 4:
	norm_color = normalize_color(color)
	annots_data.append((i, list(rect), norm_color))


	for i, (idx1, rect1, color1) in enumerate(annots_data):
	if idx1 in to_delete:
	continue
	for j in range(i + 1, len(annots_data)):
	idx2, rect2, color2 = annots_data[j]
	if idx2 in to_delete:
	continue
	if color_close_enough(color1, color2) and distance(rect1, rect2) < threshold:
	to_delete.add(idx2)

	# Keep only non-duplicates
	new_annots = [annotations[i] for i in range(len(annotations)) if i not in to_delete]
	page[NameObject("/Annots")] = ArrayObject(new_annots)
	# Compare distances and mark duplicates
	# for i, (idx1, rect1, color1) in enumerate(annots_data):
	# if idx1 in to_delete:
	# continue
	# for j, (idx2, rect2, color2) in enumerate(annots_data[i+1:], start=i+1):
	# if idx2 in to_delete:
	# continue
	# if color1 == color2 and distance(rect1, rect2) < threshold:
	# to_delete.add(idx2) # Mark second annotation for deletion

	# # Remove duplicates
	# new_annotations = [annotations[i] for i in range(len(annotations)) if i not in to_delete]
	# page[NameObject("/Annots")] = ArrayObject(new_annotations)

	writer.add_page(page)

	output_pdf_io = BytesIO()
	writer.write(output_pdf_io)
	output_pdf_io.seek(0)

	return output_pdf_io.read()


	def rect_distance(r1, r2):
	"""Euclidean distance between rect centers."""
	if not r1 or not r2:
	return float('inf')
	cx1, cy1 = (r1[0]+r1[2])/2, (r1[1]+r1[3])/2
	cx2, cy2 = (r2[0]+r2[2])/2, (r2[1]+r2[3])/2
	return math.hypot(cx2-cx1, cy2-cy1)

	def group_rect(verts):
	"""Turn [[x,y],…] into (x_min, y_min, x_max, y_max)."""
	xs = [x for x,_ in verts]
	ys = [y for _,y in verts]
	return (min(xs), min(ys), max(xs), max(ys)) if verts else None

	def clean_annotations(annotations_data, threshold):
	"""
	Remove “nearby” duplicates from annotations_data,
	where each entry is EITHER a dict with a 'vertices' key
	OR a list/tuple whose first element is the vertices list.
	"""
	# 1) Extract a parallel list of bounding rects
	rects = []
	for item in annotations_data:
	if isinstance(item, dict):
	verts = item.get('vertices', [])
	elif isinstance(item, (list, tuple)) and item:
	# heuristically assume the first element is vertices
	verts = item[0] if isinstance(item[0], list) else []
	else:
	verts = []
	rects.append(group_rect(verts))

	# 2) Mark duplicates
	to_delete = set()
	for i, r1 in enumerate(rects):
	if i in to_delete:
	continue
	for j in range(i+1, len(rects)):
	if j in to_delete:
	continue
	if rect_distance(r1, rects[j]) < threshold:
	to_delete.add(j)

	# 3) Build cleaned list
	cleaned = []
	for idx, item in enumerate(annotations_data):
	if idx not in to_delete:
	cleaned.append(item)

	return cleaned


	def calculate_distance(p1, p2):
	return math.sqrt((p1[0] - p2[0])2 + (p1[1] - p2[1])2)

	def ROI_boundingBoxCoor(img):
	# Threshold (invert: walls are white)
	imgGray= cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
	_, thresh = cv2.threshold(imgGray, 250, 255, cv2.THRESH_BINARY_INV)

	# Morphological cleanup
	kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (5,5))
	walls = cv2.morphologyEx(thresh, cv2.MORPH_CLOSE, kernel)

	# --- Connected components ---
	num_labels, labels, stats, centroids = cv2.connectedComponentsWithStats(walls, connectivity=8)

	best_idx = None
	best_score = -1
	h, w = walls.shape
	cx_img, cy_img = w//2, h//2 # image center

	for i in range(1, num_labels): # ignore background (0)
	x, y, bw, bh, area = stats[i]
	cx, cy = centroids[i]

	# Score = area minus distance penalty
	#prefer large area AND closeness to image center
	dist = np.hypot(cx - cx_img, cy - cy_img)
	score = area - 0.5 * dist #tune 0.5

	if score > best_score:
	best_score = score
	best_idx = i

	# --- Get bounding box of best region ---
	bbox = None
	if best_idx is not None:
	x, y, bw, bh, _ = stats[best_idx]
	margin = 50
	x = int(max(x - margin, 0))
	y = int(max(y - margin, 0))
	bw = int(min(bw + 2*margin, w-x))
	bh = int(min(bh + 2*margin, h-y))

	# Define bounding box as (x_min, y_min, x_max, y_max)
	bbox = (x, y, x+bw, y+bh)

	# Draw ROI
	imgcopy = img.copy()
	cv2.rectangle(imgcopy, (bbox[0], bbox[1]), (bbox[2], bbox[3]), (0,255,0), 2)

	mask = np.zeros_like(img)
	cv2.rectangle(mask, (bbox[0], bbox[1]), (bbox[2], bbox[3]), (255,255,255), -1)
	main_zone = cv2.bitwise_and(img, mask)

	return imgcopy, main_zone, bbox

	return img, img, bbox

	def draw_bb_onPDF(doc,bbox):
	page = doc[0]
	x1, y1 = bbox[0],bbox[1]
	x2, y2 = bbox[2],bbox[3]

	p1 = fitz.Point(x1,y1)
	p2 = fitz.Point(x2,y2)

	p1=p1*page.derotation_matrix
	p2=p2*page.derotation_matrix

	rect = fitz.Rect(p1, p2).normalize()
	x0, y0, x1, y1 = rect.x0, rect.y0, rect.x1, rect.y1
	pdf_bbox=[x0, y0, x1, y1]

	page.draw_rect(rect) #for visualization only
	doc.save('kk.pdf') #ffor visualization only
	return pdf_bbox

	def mainFunctionDrawImgPdf(datadoc,dxfpath, dxfratio,SearchArray,CorrectionRatio,CollectedColors,points_Of_drawing_Canvas,Thickness,pdfpath=0,pdfname=0,pdf_content=0):
	# print("points_Of_drawing_Canvas in 2.7 = ",points_Of_drawing_Canvas)
	# print("CollectedColors in 2.7 = ",CollectedColors)
	OutputPdfStage1='BB Trial.pdf'
	if pdf_content:
	FinalRatio,width_dxf= RetriveRatio(datadoc,dxfpath,pdf_content)
	else:
	FinalRatio,width_dxf= RetriveRatio(datadoc,dxfpath)

	# hatched_areas = get_hatched_areas(datadoc,dxfpath,FinalRatio)
	# hatched_areas=remove_duplicate_shapes(new_hatched_areas)
	if pdf_content:
	img,pix2=pdftoimg(datadoc,pdf_content)
	else:
	img,pix2=pdftoimg(datadoc)
	flipped_horizontal=flip(img)
	allcnts = []
	imgg = flipped_horizontal
	# imgtransparent1=imgg.copy()
	if pdf_content:
	doc = fitz.open(stream=pdf_content, filetype="pdf")
	else:
	doc = fitz.open('pdf',datadoc)
	page2 = doc[0]
	rotationOld=page2.rotation
	derotationMatrix=page2.derotation_matrix
	# print("Derotation Matrix = ",derotationMatrix)
	pix=page2.get_pixmap()
	width=abs(page2.mediabox[2])+abs(page2.mediabox[0])
	height=abs(page2.mediabox[3])+abs(page2.mediabox[1])
	print('mediabox', width , height)

	Correction = CorrectionRatio / width_dxf
	print("Correction Factor = ",round((Correction/FinalRatio),1))
	dxfratio = dxfratio * round((Correction/FinalRatio),1)
	print("new omar dxfRatio = ",dxfratio)

	imgcopy, main_zone, bbox = ROI_boundingBoxCoor(img) #send here bgr img not gray
	pdf_bbox=draw_bb_onPDF(doc,bbox)
	bxmin, bymin, bxmax, bymax = pdf_bbox


	# print('olddxfratio',dxfratio)
	# correction_factor= detect_scale_from_page(dxfpath,width,dxfratio/1000)

	# factor=1
	# print('corr_factor',correction_factor)
	# if correction_factor <0.26: #if less than 0.25 then the dxf ratio is correeect, if greater then *2
	# factor=1
	# print('Ratio working: keep as it is')
	# else:
	# factor =2
	# print('Ratio was adjusted to be ur input ratio x2')

	# dxfratio=dxfratio*factor
	# print('new dxfratio', dxfratio)

	if page2.rotation!=0:

	rotationangle = page2.rotation
	page2.set_rotation(0)
	ratio = pix.width/ img.shape[0]
	else:
	ratio = pix.width/ img.shape[1]
	rotationangle = 270

	hatched_areas,text_with_positions = get_hatched_areas(datadoc,dxfpath,FinalRatio,rotationangle,SearchArray,CollectedColors)
	allshapes=[]
	# Iterate through each polygon in metric units
	NewColors = []
	if pdf_content:
	SimilarAreaDictionary=Create_DF(dxfpath,datadoc,hatched_areas,pdf_content)
	else:
	SimilarAreaDictionary=Create_DF(dxfpath,datadoc,hatched_areas)
	i=0
	flagcolor = 0
	ColorCounter = 0
	ColorCheck=[]
	deleterows = []


	# def color_distance(color1, color2):
	# return np.sqrt(sum((a - b) ** 2 for a, b in zip(color1, color2)))

	color_margin = 2 # Define margin threshold

	for polygon in hatched_areas:
	cntPoints = []
	cntPoints1 = []
	shapeePerimeter = []
	shapeeArea = []
	Text_Detected = 0

	blackImgShapes = np.zeros(imgg.shape[:2], dtype="uint8")
	blackImgShapes= cv2.cvtColor(blackImgShapes, cv2.COLOR_GRAY2BGR)

	# Convert each vertex from metric to pixel coordinates
	for vertex in polygon[0]:
	x = (vertex[0]) *dxfratio
	y = (vertex[1]) *dxfratio
	if rotationangle==0:
	if y<0:
	y=y*-1
	cntPoints.append([int(x), int(y)])
	cntPoints1.append([x, y])

	cv2.drawContours(blackImgShapes, [np.array(cntPoints)], -1, ([255,255,255]), thickness=-1)
	x, y, w, h = cv2.boundingRect(np.array(cntPoints))
	firstpoint = 0
	for poi in np.array(cntPoints1):
	if firstpoint == 0:
	x2, y2 = poi
	p2 = fitz.Point(x2,y2)
	# p1 = fitz.Point(x1,y1)
	p2=p2*derotationMatrix
	shapeePerimeter.append([p2[0],p2[1]])
	firstpoint = 1
	else:
	x1, y1 = poi
	p1 = fitz.Point(x1,y1)
	# p1 = fitz.Point(x1,y1)
	p1=p1*derotationMatrix
	# print("P1 = ",p1)
	shapeePerimeter.append([p1[0],p1[1]])

	shapeePerimeter.append([p2[0],p2[1]])
	shapeePerimeter=np.flip(shapeePerimeter,1)
	shapeePerimeter=rotate_polygon(shapeePerimeter,rotationangle,rotationOld,width,height)

	for poi in np.array(cntPoints1):
	x1, y1 = poi
	p1 = fitz.Point(x1,y1)
	# p1 = fitz.Point(x1,y1)
	p1=p1*derotationMatrix
	# print("P1 = ",p1)
	shapeeArea.append([p1[0],p1[1]])

	shapeeArea.append([p2[0],p2[1]])
	shapeeArea=np.flip(shapeeArea,1)
	shapeeArea=rotate_polygon(shapeeArea,rotationangle,rotationOld,width,height)

	tol=0
	condition1 = (SimilarAreaDictionary['Area'] >= polygon[1] - tol) & (SimilarAreaDictionary['Area'] <= polygon[1] +tol)
	condition2 = (SimilarAreaDictionary['Perimeter'] >= polygon[2] -tol) & (SimilarAreaDictionary['Perimeter'] <= polygon[2] +tol)
	combined_condition = condition1 & condition2
	# print("combined_condition = ",combined_condition)

	if any(combined_condition):

	flagcolor = 1
	index = np.where(combined_condition)[0][0]
	# print(SimilarAreaDictionary.at[index, 'Color'])
	NewColors=SimilarAreaDictionary.at[index, 'Color']

	else:
	flagcolor = 2
	NewColors=SimilarAreaDictionary.at[i, 'Color']
	# flagcolor = 2

	# cv2.drawContours(imgg, [np.array(cntPoints)], -1, (NewColors), thickness=2)
	# print("new color = ",NewColors)
	# print("New Colors = ",NewColors)
	# if img is not None or img.shape[0] != 0 or img.shape[1] != 0:
	if(int(NewColors[0])==255 and int(NewColors[1])==255 and int(NewColors[2])==255):

	WhiteImgFinal = cv2.bitwise_and(blackImgShapes,imgg)
	# print("length = ",WhiteImgFinal.shape[0])
	# print("width = ",WhiteImgFinal.shape[1])
	flipped=flip(WhiteImgFinal)
	# print("Flipped")
	# cv2_imshow(flipped)

	imgslice = WhiteImgFinal[y:y+h, x:x+w]
	# print("length slice = ",imgslice.shape[0])
	# print("width slice = ",imgslice.shape[1])
	if(imgslice.shape[0] != 0 and imgslice.shape[1] != 0):
	flippedSlice=flip(imgslice)
	# print("Sliced & Flipped")
	# cv2_imshow(flippedSlice)

	# Convert flippedSlice to PIL for color extraction
	flippedSlice_pil = Image.fromarray(flippedSlice)

	# Define patch size for color sampling (e.g., 10x10 pixels)
	patch_size = 100
	patch_colors = []

	# Loop through patches in the image
	for i in range(0, flippedSlice_pil.width, patch_size):
	for j in range(0, flippedSlice_pil.height, patch_size):
	# Crop a patch from the original image
	patch = flippedSlice_pil.crop((i, j, i + patch_size, j + patch_size))
	patch_colors += patch.getcolors(patch_size * patch_size)

	# Calculate the dominant color from all patches
	max_count = 0
	dominant_color = None
	tolerance = 5
	black_threshold = 30 # Max RGB value for a color to be considered "black"
	white_threshold = 225 # Min RGB value for a color to be considered "white"

	for count, color in patch_colors:
	# Exclude colors within the black and white ranges
	if not (all(c <= black_threshold for c in color) or all(c >= white_threshold for c in color)):
	# Update if the current color has a higher count than previous max
	if count > max_count:
	max_count = count
	dominant_color = color

	# print("Dominant Color =", dominant_color)

	# Append dominant color to ColorCheck and update NewColors
	if dominant_color is not None:
	ColorCheck.append(dominant_color)

	NewColors = None # Initialize NewColors

	for color in ColorCheck:
	# Check if the current color is within the tolerance
	# print("color = ",color)
	# print("dominant_color = ",dominant_color)
	if (abs(color[0] - dominant_color[0]) < 20 and
	abs(color[1] - dominant_color[1]) < 20 and
	abs(color[2] - dominant_color[2]) < 20):
	NewColors = (color[2], color[1], color[0]) # Set the new color
	break
	else:
	# If no color in ColorCheck meets the tolerance, use the dominant color
	NewColors = (dominant_color[2], dominant_color[1], dominant_color[0])
	# break

	# Avoid appending `dominant_color` again unnecessarily
	if NewColors not in ColorCheck:
	ColorCheck.append(NewColors)

	if flagcolor == 1:
	SimilarAreaDictionary.at[index, 'Color'] = NewColors
	# # print(f"Updated Color at index {index} with {NewColors}.")
	elif flagcolor == 2:
	SimilarAreaDictionary.at[i, 'Color'] = NewColors
	# print("New Colors = ",NewColors)
	cv2.drawContours(imgg, [np.array(cntPoints)], -1, ([NewColors[2],NewColors[1],NewColors[0]]), thickness=3)




	start_point1 = shapeePerimeter[0]
	end_point1 = shapeePerimeter[1]
	start_point2 = shapeePerimeter[0]
	end_point2 = shapeePerimeter[-2]

	distance1 = calculate_distance(start_point1, end_point1)
	distance2 = calculate_distance(start_point2, end_point2)



	# Divide the shapePerimeter into two halves
	half_index = len(shapeePerimeter) // 2
	half1 = shapeePerimeter[1:half_index+1]
	half2 = shapeePerimeter[half_index:]
	# half1 = shapeePerimeter[1:half_index]
	# half2 = shapeePerimeter[half_index:-1]



	# Calculate distances for the halves
	if len(half1) >= 2:
	half1_distance = sum(calculate_distance(half1[i], half1[i + 1]) for i in range(len(half1) - 1))
	else:
	half1_distance = 0

	if len(half2) >= 2:
	half2_distance = sum(calculate_distance(half2[i], half2[i + 1]) for i in range(len(half2) - 1))
	else:
	half2_distance = 0

	max_distance = max(distance1, distance2, half1_distance)

	if max_distance == distance1:
	# Draw the line annotation for distance1
	chosen_start = start_point1
	chosen_end = end_point1
	# annot12 = page2.add_line_annot(chosen_start, chosen_end)
	points=[]
	points.append(chosen_start)
	points.append(chosen_end)
	discard = False
	# if(points_Of_drawing_Canvas):
	# print("Canva points = ",points_Of_drawing_Canvas)
	if(points_Of_drawing_Canvas):
	Boundingpolygon = np.array(
	[(p.x, p.y) for p in points_Of_drawing_Canvas],
	dtype=np.float32
	)

	for x, y in points:
	# Check if the point is outside the polygon
	result = cv2.pointPolygonTest(Boundingpolygon, (x, y), False)
	if result < 0: # < 0 means point is outside
	discard = True
	break
	else:
	for point in points:
	if not (bxmin <= point[0] <= bxmax and bymin <= point[1] <= bymax):
	discard = True
	break
	# for point in points:
	# if not (bxmin <= point[0] <= bxmax and bymin <= point[1] <= bymax):
	# discard = True
	# break
	if not discard:
	annot12 = page2.add_polyline_annot(points)

	elif max_distance == distance2:
	# Draw the line annotation for distance2
	chosen_start = start_point2
	chosen_end = end_point2
	# annot12 = page2.add_line_annot(chosen_start, chosen_end)
	points=[]
	points.append(chosen_start)
	points.append(chosen_end)
	# annot12 = page2.add_polyline_annot(points)
	points=[]
	points.append(chosen_start)
	points.append(chosen_end)
	discard = False
	# print("Canva points = ",points_Of_drawing_Canvas)
	if(points_Of_drawing_Canvas):
	Boundingpolygon = np.array(
	[(p.x, p.y) for p in points_Of_drawing_Canvas],
	dtype=np.float32
	)

	for x, y in points:
	# Check if the point is outside the polygon
	result = cv2.pointPolygonTest(Boundingpolygon, (x, y), False)
	if result < 0: # < 0 means point is outside
	discard = True
	break
	else:
	for point in points:
	if not (bxmin <= point[0] <= bxmax and bymin <= point[1] <= bymax):
	discard = True
	break

	if not discard:
	annot12 = page2.add_polyline_annot(points)

	elif max_distance == half1_distance:
	# annot12 = page2.add_polyline_annot(half1)
	max_pair_distance = 0.0
	max_pair_start = None
	max_pair_end = None

	# 2. Loop through each consecutive pair in half1
	for i in range(len(half1) - 1):
	p_current = half1[i]
	p_next = half1[i + 1]

	# 3. Compute distance between these two points
	dist = calculate_distance(p_current, p_next)

	# 4. Update max if this distance is greater
	if dist > max_pair_distance:
	max_pair_distance = dist
	max_pair_start = p_current
	max_pair_end = p_next

	# 5. After the loop, max_pair_start and max_pair_end represent
	# the two consecutive points with the greatest separation.
	if max_pair_start is not None and max_pair_end is not None:
	# 6. Draw the line annotation using these two points
	# annot12 = page2.add_line_annot(max_pair_start, max_pair_end)
	points=[]
	points.append(max_pair_start)
	points.append(max_pair_end)
	discard = False
	# print("Canva points = ",points_Of_drawing_Canvas)
	if(points_Of_drawing_Canvas):
	Boundingpolygon = np.array(
	[(p.x, p.y) for p in points_Of_drawing_Canvas],
	dtype=np.float32
	)

	for x, y in points:
	# Check if the point is outside the polygon
	result = cv2.pointPolygonTest(Boundingpolygon, (x, y), False)
	if result < 0: # < 0 means point is outside
	discard = True
	break
	else:
	for point in points:
	if not (bxmin <= point[0] <= bxmax and bymin <= point[1] <= bymax):
	discard = True
	break

	if not discard:
	annot12 = page2.add_polyline_annot(points)
	# print(f"Drew line annotation between {max_pair_start} and {max_pair_end}")
	else:
	# This case only occurs if half1 has fewer than 2 points
	print("Not enough points in half1 to compute a line.")


	discard = False
	# print("Canva points = ",points_Of_drawing_Canvas)
	if(points_Of_drawing_Canvas):
	Boundingpolygon = np.array(
	[(p.x, p.y) for p in points_Of_drawing_Canvas],
	dtype=np.float32
	)

	for x, y in points:
	# Check if the point is outside the polygon
	result = cv2.pointPolygonTest(Boundingpolygon, (x, y), False)
	if result < 0: # < 0 means point is outside
	discard = True
	break
	else:
	for point in points:
	if not (bxmin <= point[0] <= bxmax and bymin <= point[1] <= bymax):
	discard = True
	break

	if not discard:
	annot12.set_border(width=0.8)
	annot12.set_colors(stroke=(int(NewColors[0])/255,int(NewColors[1])/255,int(NewColors[2])/255))
	# annot12.set_info(content=str(polygon[2])+' m',subject='Perimeter Measurement', title="ADR Team")
	annot12.set_info(subject='Perimeter Measurement',content=str(polygon[2])+' m')
	annot12.set_opacity(0.8)
	annot12.update()


	i += 1
	alpha = 0.8 # Transparency factor.

	page2.set_rotation(rotationOld)
	Correct_img=flip(imgg)

	image_new1 = cv2.addWeighted(Correct_img, alpha, img, 1 - alpha, 0)
	SimilarAreaDictionary = SimilarAreaDictionary.fillna(' ')

	# Define white color to filter out
	white_color = (255, 255, 255)

	# Delete rows where 'Guess' equals white_color
	SimilarAreaDictionary = SimilarAreaDictionary[SimilarAreaDictionary['Color'] != white_color]

	# Reset the index to update row numbering
	SimilarAreaDictionary.reset_index(drop=True, inplace=True)


	grouped_df = SimilarAreaDictionary.groupby('Color').agg({
	'Guess': 'first',
	'Occurences': 'sum', # Sum of occurrences for each color
	'Area':'first',
	'Total Area': 'sum', # Sum of areas for each color
	'Perimeter':'first',
	'Total Perimeter': 'sum', # Sum of perimeters for each color
	'Length':'first',
	'Total Length': 'sum', # Sum of lengths for each color
	'Texts': 'first', # Keep the first occurrence of 'Texts'
	'Comments': 'first' # Keep the first occurrence of 'Comments'

	}).reset_index()

	# doc.save(OutputPdfStage1)
	# OutputPdfStage2=adjustannotations(OutputPdfStage1,text_with_positions)
	modified_pdf_data = doc.tobytes()
	OutputPdfStage2 , annotations_data=adjustannotations(modified_pdf_data,text_with_positions,CollectedColors)

	if (Thickness):

	threshold = round((float(Thickness) * float(dxfratio) ),1)
	cleaned_list = clean_annotations(annotations_data, threshold)

	else:
	cleaned_list = clean_annotations(annotations_data, threshold=10)

	allvertices = cleaned_list
	# PerimeterVertices = XMLPerimeter
	#Example Color : this is in RGB normalized format as for e.g.: 200/255 for r g b


	hatchcolorR= '0'
	hatchcolorG= '1'
	hatchcolorB= '1'
	# Define templates with placeholder {w} instead of hardcoded LINEWIDTH
	LinestyleTemplates = {
	'Solid': '<</W {w}/S/S/Type/Border>>',
	'Dashed1':'<</W {w}/S/D/D[2 2]/Type/Border>>',
	'Dashed2': '<</W {w}/S/D/D[3 3]/Type/Border>>',
	'Dashed3': '<</W {w}/S/D/D[4 4]/Type/Border>>',
	'Dashed4': '<</W {w}/S/D/D[4 3 2 3]/Type/Border>>',
	'Dashed5': '<</W {w}/S/D/D[4 3 16 3]/Type/Border>>',
	'Dashed6': '<</W {w}/S/D/D[8 4 4 4]/Type/Border>>'
	}
	#/BS<</W 1/S/D/D[4 4]/Type/Border>>

	HatchFunctions = {
	'None':'',
	'Brick': setBrickHatch,
	'DiagonalBrick':setDiagonalBrickHatch,
	'Horizontal':setHorizontalHatch,
	'Vertical':setVerticalHatch,
	'DiagonalDown':setDiagonalDownHatch,
	'DiagonalUp':setDiagonalUpHatch,
	'Grid': setGridHatch,
	'Weave':setWeaveHatch,
	'10Dots':set10DotsHatch,
	'20Dots':set20DotsHatch,
	'30Dots':set30DotsHatch
	}

	#Area and perimeter numbers example
	area = 20
	perimeter = 30

	import colorsys

	annotations=[]
	for shapeinvertices in allvertices:

	rn=shapeinvertices[3][0]/255
	gn=shapeinvertices[3][1]/255
	bn=shapeinvertices[3][2]/255

	h, s, v = colorsys.rgb_to_hsv(rn, gn, bn)

	# snap to full saturation, 50% brightness
	s2, v2 = 0.6, 0.9

	# back to RGB
	r2, g2, b2 = colorsys.hsv_to_rgb(h, s2, v2)

	R=str(r2)
	G=str(g2)
	B=str(b2)
	if shapeinvertices[6]:
	annotations.append(
	{

	'vertices': shapeinvertices[0], # [[x,y],[x1,y1],[....]] position of ur markup
	'text': str(shapeinvertices[2])+' m',
	'author': 'ADR',
	'custom_data': {'Specification':shapeinvertices[5]},#identify custom colums here as( Column name: Text to add )
	'type_internal': 'Bluebeam.PDF.Annotations.AnnotationMeasurePerimeter',
	'subject': 'Perimeter Measurement',
	'label':shapeinvertices[6],
	'opacity': '0.7',#opacity of ur shape fill
	'color': R+ ' '+G + ' '+B,# normalized (RGB --> R/255 G/255 B/255)
	'linestyle': LinestyleTemplates['Dashed6'].format(w=2) # LineStyles as in BB ,this w is the linewidth

	}
	)

	else:
	annotations.append(
	{

	'vertices': shapeinvertices[0], # [[x,y],[x1,y1],[....]] position of ur markup
	'text': str(shapeinvertices[2])+' m',
	'author': 'ADR',
	'custom_data': {'Specification':shapeinvertices[5]},#identify custom colums here as( Column name: Text to add )
	'type_internal': 'Bluebeam.PDF.Annotations.AnnotationMeasurePerimeter',
	'subject': 'Perimeter Measurement',
	'label':shapeinvertices[4],
	'opacity': '0.7',#opacity of ur shape fill
	'color': R+ ' '+G + ' '+B,# normalized (RGB --> R/255 G/255 B/255)
	'linestyle': LinestyleTemplates['Dashed6'].format(w=2) # LineStyles as in BB ,this w is the linewidth

	}
	)


	column_order = ['Specification'] #specify here the custom columns in order
	# print(bax_annotations)

	#replace with ur pdf width and height variables
	pdfWidth=1684
	pdfHeight=2384


	# save_multiple_annotations_bax(
	# bax_annotations, 'Area_Perimeter_OMAR_output.bax', column_order, pdfWidth, pdfHeight
	# )
	bax_xml=save_multiple_annotations_bax(
	annotations, '2552 Page 1.bax', column_order, pdfWidth, pdfHeight
	)

	from xml.etree.ElementTree import Element, SubElement, tostring

	def generate_bluebeam_columns_raw(column_names):
	"""
	Generate BluebeamUserDefinedColumns XML as raw string, without headers or extra fields.
	"""
	root = Element("BluebeamUserDefinedColumns")

	for idx, name in enumerate(column_names):
	item = SubElement(root, "BSIColumnItem", Index=str(idx), Subtype="Text")
	SubElement(item, "Name").text = name
	SubElement(item, "DisplayOrder").text = str(idx)
	SubElement(item, "Deleted").text = "False"
	SubElement(item, "Multiline").text = "False"

	# Convert to string and decode raw bytes
	return tostring(root, encoding="unicode", method="xml")


	column_xml = generate_bluebeam_columns_raw(column_order)

	# with open("2552 Page 1.xml", "w", encoding="utf-8") as f:
	# f.write(column_xml)

	# print(column_xml)


	if pdf_content:
	latestimg,pix=pdftoimg(OutputPdfStage2,pdf_content)
	else:
	latestimg,pix=pdftoimg(OutputPdfStage2)
	doc2 =fitz.open('pdf',OutputPdfStage2)
	if pdf_content:
	gc,spreadsheet_service,spreadsheetId, spreadsheet_url , namepathArr=google_sheet_Legend.legendGoogleSheets(grouped_df , pdfname,pdfpath,pdf_content)
	else:
	gc,spreadsheet_service,spreadsheetId, spreadsheet_url , namepathArr=google_sheet_Legend.legendGoogleSheets(grouped_df , pdfname,pdfpath)
	list1=pd.DataFrame(columns=['content', 'id', 'subject','color'])

	# for page in doc:
	for page in doc2:
	# Iterate through annotations on the page
	for annot in page.annots():
	# Get the color of the annotation
	annot_color = annot.colors
	if annot_color is not None:
	# annot_color is a dictionary with 'stroke' and 'fill' keys
	stroke_color = annot_color.get('stroke') # Border color
	fill_color = annot_color.get('fill') # Fill color
	if fill_color:
	v='fill'
	# print('fill')
	if stroke_color:
	v='stroke'
	x,y,z=int(annot_color.get(v)[0]255),int(annot_color.get(v)[1]255),int(annot_color.get(v)[2]*255)
	list1.loc[len(list1)] =[annot.info['content'],annot.info['id'],annot.info['subject'],[x,y,z]]
	print('LISTTT',list1)
	return doc2,latestimg, SimilarAreaDictionary ,spreadsheetId, spreadsheet_url , namepathArr , list1,hatched_areas, bax_xml, column_xml