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import re
from collections import defaultdict, Counter
import fitz # PyMuPDF
import requests
from io import BytesIO
def normalize_text(text):
if text is None:
return ""
return re.sub(r'\s+', ' ', text.strip().lower())
def get_spaced_text_from_spans(spans):
return normalize_text(" ".join(span["text"].strip() for span in spans))
def is_header(span, most_common_font_size, most_common_color, most_common_font):
fontname = span.get("font", "").lower()
# is_italic = "italic" in fontname or "oblique" in fontname
is_bold = "bold" in fontname or span.get("bold", False)
return (
(
span["size"] > most_common_font_size or
span["font"].lower() != most_common_font.lower() or
is_bold
)
)
def add_span_to_nearest_group(span_y, grouped_dict, pageNum=None, threshold=0.5):
for (p, y) in grouped_dict:
if pageNum is not None and p != pageNum:
continue
if abs(y - span_y) <= threshold:
return (p, y)
return (pageNum, span_y)
def get_regular_font_size_and_color(doc):
font_sizes = []
colors = []
fonts = []
# Loop through all pages
for page_num in range(len(doc)):
page = doc.load_page(page_num)
for span in page.get_text("dict")["blocks"]:
if "lines" in span:
for line in span["lines"]:
for span in line["spans"]:
font_sizes.append(span['size'])
colors.append(span['color'])
fonts.append(span['font'])
# Get the most common font size, color, and font
most_common_font_size = Counter(font_sizes).most_common(1)[0][0] if font_sizes else None
most_common_color = Counter(colors).most_common(1)[0][0] if colors else None
most_common_font = Counter(fonts).most_common(1)[0][0] if fonts else None
return most_common_font_size, most_common_color, most_common_font
def extract_headers(doc, toc_pages, most_common_font_size, most_common_color, most_common_font, top_margin, bottom_margin):
print("Font baseline:", most_common_font_size, most_common_color, most_common_font)
grouped_headers = defaultdict(list)
spans = []
line_merge_threshold = 1.5 # Maximum vertical distance between lines to consider as part of same header
for pageNum in range(len(doc)):
if pageNum in toc_pages:
continue
page = doc.load_page(pageNum)
page_height = page.rect.height
text_instances = page.get_text("dict")
# First pass: collect all potential header spans
potential_header_spans = []
for block in text_instances['blocks']:
if block['type'] != 0:
continue
for line in block['lines']:
for span in line['spans']:
span_y0 = span['bbox'][1]
span_y1 = span['bbox'][3]
if span_y0 < top_margin or span_y1 > (page_height - bottom_margin):
continue
span_text = normalize_text(span.get('text', ''))
if not span_text:
continue
if span_text.startswith('http://www') or span_text.startswith('www'):
continue
if any((
'page' in span_text,
not re.search(r'[a-z0-9]', span_text),
'end of section' in span_text,
re.search(r'page\s+\d+\s+of\s+\d+', span_text),
re.search(r'\b(?:\d{1,2}[/-])?\d{1,2}[/-]\d{2,4}\b', span_text),
# re.search(r'\b(?:jan|feb|mar|apr|may|jun|jul|aug|sep|oct|nov|dec)', span_text),
'specification:' in span_text
)):
continue
cleaned_text = re.sub(r'[.\-]{4,}.*$', '', span_text).strip()
cleaned_text = normalize_text(cleaned_text)
if is_header(span, most_common_font_size, most_common_color, most_common_font):
potential_header_spans.append({
'text': cleaned_text,
'size': span['size'],
'pageNum': pageNum,
'y0': span_y0,
'y1': span_y1,
'x0': span['bbox'][0],
'x1': span['bbox'][2],
'span': span
})
# Sort spans by vertical position (top to bottom)
potential_header_spans.sort(key=lambda s: (s['pageNum'], s['y0']))
# Second pass: group spans that are vertically close and likely part of same header
i = 0
while i < len(potential_header_spans):
current = potential_header_spans[i]
header_text = current['text']
header_size = current['size']
header_page = current['pageNum']
min_y = current['y0']
max_y = current['y1']
spans_group = [current['span']]
# Look ahead to find adjacent lines that might be part of same header
j = i + 1
while j < len(potential_header_spans):
next_span = potential_header_spans[j]
# Check if on same page and vertically close with similar styling
if (next_span['pageNum'] == header_page and
next_span['y0'] - max_y < line_merge_threshold and
abs(next_span['size'] - header_size) < 0.5):
header_text += " " + next_span['text']
max_y = next_span['y1']
spans_group.append(next_span['span'])
j += 1
else:
break
# Add the merged header
grouped_headers[(header_page, min_y)].append({
"text": header_text.strip(),
"size": header_size,
"pageNum": header_page,
"spans": spans_group
})
spans.extend(spans_group)
i = j # Skip the spans we've already processed
# Prepare final headers list
headers = []
for (pageNum, y), header_groups in sorted(grouped_headers.items()):
for group in header_groups:
headers.append([
group['text'],
group['size'],
group['pageNum'],
y
])
font_sizes = [size for _, size, _, _ in headers]
font_size_counts = Counter(font_sizes)
# Filter font sizes that appear at least 3 times
valid_font_sizes = [size for size, count in font_size_counts.items() if count >= 3]
# Sort in descending order
valid_font_sizes_sorted = sorted(valid_font_sizes, reverse=True)
# If only 2 sizes, repeat the second one
if len(valid_font_sizes_sorted) == 2:
top_3_font_sizes = [valid_font_sizes_sorted[0], valid_font_sizes_sorted[1], valid_font_sizes_sorted[1]]
else:
top_3_font_sizes = valid_font_sizes_sorted[:3]
# Get the smallest font size among valid ones
smallest_font_size = min(valid_font_sizes) if valid_font_sizes else None
print("Smallest font size in headers:", smallest_font_size)
return headers, top_3_font_sizes, smallest_font_size, spans
import re
import difflib
def is_numbered(text):
return bool(re.match(r'^\d', text.strip()))
def is_similar(a, b, threshold=0.85):
return difflib.SequenceMatcher(None, a, b).ratio() > threshold
def normalize(text):
text = text.lower()
text = re.sub(r'\.{2,}', '', text) # remove long dots
text = re.sub(r'\s+', ' ', text) # replace multiple spaces with one
return text.strip()
def clean_toc_entry(toc_text):
"""Remove page numbers and formatting from TOC entries"""
# Remove everything after last sequence of dots/whitespace followed by digits
return re.sub(r'[\.\s]+\d+.*$', '', toc_text).strip('. ')
def build_header_hierarchy(doc, toc_pages, most_common_font_size, most_common_color, most_common_font, top_margin=70, bottom_margin=70):
# Extract headers with margin handling
headers_list, top_3_font_sizes, smallest_font_size, spans = extract_headers(
doc,
toc_pages=toc_pages,
most_common_font_size=most_common_font_size,
most_common_color=most_common_color,
most_common_font=most_common_font,
top_margin=top_margin,
bottom_margin=bottom_margin
)
# Step 1: Collect and filter potential headers
headers = []
seen_headers = set()
# First extract TOC entries to get exact level 0 header texts
toc_entries = {}
for pno in toc_pages:
page = doc.load_page(pno)
toc_text = page.get_text()
for line in toc_text.split('\n'):
clean_line = line.strip()
if clean_line:
norm_line = normalize(clean_line)
toc_entries[norm_line] = clean_line # Store original text
for h in headers_list:
text, size, pageNum, y = h[:4]
page = doc.load_page(pageNum)
page_height = page.rect.height
# Skip margin areas
if y < top_margin or y > (page_height - bottom_margin):
continue
norm_text = normalize(text)
if len(norm_text) > 2 and size >= most_common_font_size:
headers.append({
"text": text,
"page": pageNum,
"y": y,
"size": size,
"bold": h[4] if len(h) > 4 else False,
# "italic": h[5] if len(h) > 5 else False,
"color": h[6] if len(h) > 6 else None,
"font": h[7] if len(h) > 7 else None,
"children": [],
"is_numbered": is_numbered(text),
"original_size": size,
"norm_text": norm_text,
"level": -1 # Initialize as unassigned
})
# Sort by page and vertical position
headers.sort(key=lambda h: (h['page'], h['y']))
# Step 2: Detect consecutive headers and assign levels
i = 0
while i < len(headers) - 1:
current = headers[i]
next_header = headers[i+1]
# Check if they are on the same page and very close vertically (likely consecutive lines)
if (current['page'] == next_header['page'] and
abs(current['y'] - next_header['y']) < 20): # 20pt threshold for "same line"
# Case 1: Both unassigned - make current level 1 and next level 2
if current['level'] == -1 and next_header['level'] == -1:
current['level'] = 1
next_header['level'] = 2
i += 1 # Skip next header since we processed it
# Case 2: Current unassigned, next assigned - make current one level above
elif current['level'] == -1 and next_header['level'] != -1:
current['level'] = max(1, next_header['level'] - 1)
# Case 3: Current assigned, next unassigned - make next one level below
elif current['level'] != -1 and next_header['level'] == -1:
next_header['level'] = current['level'] + 1
i += 1 # Skip next header since we processed it
i += 1
# Step 2: Identify level 0 headers (largest and in TOC)
# max_size = max(h['size'] for h in headers) if headers else 0
max_size,subheaderSize,nbsheadersize=top_3_font_sizes
print(max_size)
toc_text_match=[]
# Improved TOC matching with exact and substring matching
toc_matches = []
for h in headers:
norm_text = h['norm_text']
matching_toc_texts = []
# Check both exact matches and substring matches
for toc_norm, toc_text in toc_entries.items():
# Exact match case
if norm_text == toc_norm and len(toc_text)>4 and h['size']==max_size:
matching_toc_texts.append(toc_text)
# Substring match case (header is substring of TOC entry)
elif norm_text in toc_norm and len(toc_text)>4 and h['size']==max_size:
matching_toc_texts.append(toc_text)
# Substring match case (TOC entry is substring of header)
elif toc_norm in norm_text and len(toc_text)>4 and h['size']==max_size:
matching_toc_texts.append(toc_text)
if matching_toc_texts and h['size'] >= max_size * 0.9:
best_match = max(matching_toc_texts,
key=lambda x: (len(x), -len(x.replace(norm_text, ''))))
h['text'] = normalize_text(clean_toc_entry(best_match))
h['level'] = 0
if h['text'] not in toc_text_match:
toc_matches.append(h)
toc_text_match.append(h['text'])
elif matching_toc_texts and h['size'] < max_size * 0.9 and h['size'] > nbsheadersize : # h['size'] < max_size * 0.9 and h['size'] > max_size*0.75:
print(h['text'],matching_toc_texts)
headers.remove(h)
continue
# Remove duplicates - keep only first occurrence of each level 0 header
unique_level0 = []
seen_level0 = set()
for h in toc_matches:
# Use the cleaned text for duplicate checking
cleaned_text = clean_toc_entry(h['text'])
norm_cleaned_text = normalize(cleaned_text)
if norm_cleaned_text not in seen_level0:
seen_level0.add(norm_cleaned_text)
# Update the header text with cleaned version
h['text'] = cleaned_text
unique_level0.append(h)
print(f"Added unique header: {cleaned_text} (normalized: {norm_cleaned_text})")
# Step 3: Process headers under each level 0 to identify level 1 format
# First, group headers by their level 0 parent
level0_headers = [h for h in headers if h['level'] == 0]
header_groups = []
for i, level0 in enumerate(level0_headers):
start_idx = headers.index(level0)
end_idx = headers.index(level0_headers[i+1]) if i+1 < len(level0_headers) else len(headers)
group = headers[start_idx:end_idx]
header_groups.append(group)
# Now process each group to identify level 1 format
for group in header_groups:
level0 = group[0]
level1_candidates = [h for h in group[1:] if h['level'] == -1]
if not level1_candidates:
continue
# The first candidate is our reference level 1
first_level1 = level1_candidates[0]
level1_format = {
'font': first_level1['font'],
'color': first_level1['color'],
'starts_with_number': is_numbered(first_level1['text']),
'size': first_level1['size'],
'bold': first_level1['bold']
# 'italic': first_level1['italic']
}
# Assign levels based on the reference format
for h in level1_candidates:
current_format = {
'font': h['font'],
'color': h['color'],
'starts_with_number': is_numbered(h['text']),
'size': h['size'],
'bold': h['bold']
# 'italic': h['italic']
}
# Compare with level1 format
if (current_format['font'] == level1_format['font'] and
current_format['color'] == level1_format['color'] and
current_format['starts_with_number'] == level1_format['starts_with_number'] and
abs(current_format['size'] - level1_format['size']) <= 0.1 and
current_format['bold'] == level1_format['bold'] ): #and
# current_format['italic'] == level1_format['italic']):
h['level'] = 1
else:
h['level'] = 2
# Step 4: Assign levels to remaining unassigned headers
unassigned = [h for h in headers if h['level'] == -1]
if unassigned:
# Cluster by size with tolerance
sizes = sorted({h['size'] for h in unassigned}, reverse=True)
clusters = []
for size in sizes:
found_cluster = False
for cluster in clusters:
if abs(size - cluster['size']) <= max(size, cluster['size']) * 0.1:
cluster['headers'].extend([h for h in unassigned if abs(h['size'] - size) <= size * 0.1])
found_cluster = True
break
if not found_cluster:
clusters.append({
'size': size,
'headers': [h for h in unassigned if abs(h['size'] - size) <= size * 0.1]
})
# Assign levels starting from 1
clusters.sort(key=lambda x: -x['size'])
for i, cluster in enumerate(clusters):
for h in cluster['headers']:
base_level = i + 1
if h['bold']:
base_level = max(1, base_level - 1)
h['level'] = base_level
# Step 5: Build hierarchy
root = []
stack = []
# Create a set of normalized texts from unique_level0 to avoid duplicates
unique_level0_texts = {h['norm_text'] for h in unique_level0}
# Filter out any headers from the original list that match unique_level0 headers
filtered_headers = []
for h in headers:
if h['norm_text'] in unique_level0_texts and h not in unique_level0:
h['level'] = 0
filtered_headers.append(h)
# Combine all headers - unique_level0 first, then the filtered headers
all_headers = unique_level0 + filtered_headers
all_headers.sort(key=lambda h: (h['page'], h['y']))
# Track which level 0 headers we've already added
added_level0 = set()
for header in all_headers:
if header['level'] < 0:
continue
if header['level'] == 0:
norm_text = header['norm_text']
if norm_text in added_level0:
continue
added_level0.add(norm_text)
# Pop stack until we find a parent
while stack and stack[-1]['level'] >= header['level']:
stack.pop()
current_parent = stack[-1] if stack else None
if current_parent:
current_parent['children'].append(header)
else:
root.append(header)
stack.append(header)
# Step 6: Enforce proper nesting
def enforce_nesting(node_list, parent_level=-1):
for node in node_list:
if node['level'] <= parent_level:
node['level'] = parent_level + 1
enforce_nesting(node['children'], node['level'])
enforce_nesting(root)
root = [h for h in root if not (h['level'] == 0 and not h['children'])]
# NEW: Filter out level 1 headers containing 'installation' and their children
def filter_installation_headers(node_list):
filtered = []
for node in node_list:
# Skip if it's a level 1 header containing 'installation' (case insensitive)
if node['level'] == 1 and ('installation' in node['text'].lower() or 'execution' in node['text'].lower() or 'miscellaneous items' in node['text'].lower() ) :
continue
# Recursively filter children
node['children'] = filter_installation_headers(node['children'])
filtered.append(node)
return filtered
root = filter_installation_headers(root)
return root
def adjust_levels_if_level0_not_in_toc(doc, toc_pages, root):
def normalize(text):
return re.sub(r'\s+', ' ', text.strip().lower())
toc_text = ""
for pno in toc_pages:
page = doc.load_page(pno)
toc_text += page.get_text()
toc_text_normalized = normalize(toc_text)
def is_level0_in_toc_text(header):
return header['level'] == 0 and normalize(header['text']) in toc_text_normalized
if any(is_level0_in_toc_text(h) for h in root):
return # No change needed
def increase_levels(node_list):
for node in node_list:
node['level'] += 1
increase_levels(node['children'])
def assign_numbers_to_headers(headers, prefix=None):
for idx, header in enumerate(headers, 1):
current_number = f"{prefix}.{idx}" if prefix else str(idx)
header["number"] = current_number
assign_numbers_to_headers(header["children"], current_number)
def print_tree_with_numbers(headers, listofheaders, indent=0):
for header in headers:
size_info = f"size:{header['original_size']:.1f}" if 'original_size' in header else ""
line = (
" " * indent +
f"{header.get('number', '?')} {header['text']} " +
f"(Level {header['level']}, p:{header['page']+1}, {size_info})"
)
print(line)
listofheaders.append(line)
print_tree_with_numbers(header["children"], listofheaders, indent + 1)
return listofheaders
def get_toc_page_numbers(doc, max_pages_to_check=15):
# Precompute regex patterns
dot_pattern = re.compile(r'\.{3,}')
url_pattern = re.compile(r'https?://\S+|www\.\S+')
toc_pages = []
for page_num in range(min(len(doc), max_pages_to_check)):
page = doc.load_page(page_num)
blocks = page.get_text("dict")["blocks"]
dot_line_count = 0
for block in blocks:
for line in block.get("lines", []):
line_text = get_spaced_text_from_spans(line["spans"]).strip()
if dot_pattern.search(line_text):
dot_line_count += 1
if dot_line_count >= 3:
toc_pages.append(page_num)
return list(range(0, toc_pages[-1] +1)) if toc_pages else toc_pages
def headersfrompdf(filePath):
pdf_path=filePath
if pdf_path and ('http' in pdf_path or 'dropbox' in pdf_path):
pdf_path = pdf_path.replace('dl=0', 'dl=1')
response = requests.get(pdf_path)
pdf_content = BytesIO(response.content)
if not pdf_content:
raise ValueError("No valid PDF content found.")
doc = fitz.open(stream=pdf_content, filetype="pdf")
most_common_font_size, most_common_color, most_common_font = get_regular_font_size_and_color(doc)
toc_pages = get_toc_page_numbers(doc)
hierarchy = build_header_hierarchy(doc,toc_pages, most_common_font_size, most_common_color, most_common_font)
assign_numbers_to_headers(hierarchy)
listofheaders=print_tree_with_numbers(hierarchy,listofheaders=[])
# print(listofheaders)
full_text = "\n".join(listofheaders)
# print(full_text)
return full_text
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