""" Direct Extraction Engine using PyMuPDF Handles direct text and structure extraction from editable PDFs without OCR. This provides much faster processing and perfect accuracy for documents with extractable text. """ import os import logging import fitz # PyMuPDF import uuid from pathlib import Path from typing import Dict, List, Optional, Tuple, Any, Union from datetime import datetime import re from ..models.unified_document import ( UnifiedDocument, DocumentElement, Page, DocumentMetadata, BoundingBox, StyleInfo, TableData, TableCell, Dimensions, ElementType, ProcessingTrack ) logger = logging.getLogger(__name__) class DirectExtractionEngine: """ Engine for direct text extraction from editable PDFs using PyMuPDF. This engine provides: - Fast text extraction with exact positioning - Font and style information preservation - Table structure detection - Image extraction with coordinates - Hyperlink and annotation extraction """ def __init__(self, enable_table_detection: bool = True, enable_image_extraction: bool = True, min_table_rows: int = 2, min_table_cols: int = 2): """ Initialize the extraction engine. Args: enable_table_detection: Whether to detect and extract tables enable_image_extraction: Whether to extract images min_table_rows: Minimum rows for table detection min_table_cols: Minimum columns for table detection """ self.enable_table_detection = enable_table_detection self.enable_image_extraction = enable_image_extraction self.min_table_rows = min_table_rows self.min_table_cols = min_table_cols def extract(self, file_path: Path, output_dir: Optional[Path] = None) -> UnifiedDocument: """ Extract content from PDF file to UnifiedDocument format. Args: file_path: Path to PDF file output_dir: Optional directory to save extracted images. If not provided, creates a temporary directory in storage/results/{document_id}/ Returns: UnifiedDocument with extracted content """ start_time = datetime.now() document_id = str(uuid.uuid4())[:8] # Short ID for cleaner paths try: doc = fitz.open(str(file_path)) # If no output_dir provided, create default directory for image extraction if output_dir is None and self.enable_image_extraction: # Create temporary directory in storage/results default_output_dir = Path("storage/results") / document_id default_output_dir.mkdir(parents=True, exist_ok=True) output_dir = default_output_dir logger.debug(f"Created default output directory: {output_dir}") # Extract document metadata metadata = self._extract_metadata(file_path, doc, start_time) # Extract pages pages = [] for page_num in range(len(doc)): logger.info(f"Extracting page {page_num + 1}/{len(doc)}") page = self._extract_page( doc[page_num], page_num + 1, document_id, output_dir ) pages.append(page) doc.close() # Calculate processing time processing_time = (datetime.now() - start_time).total_seconds() metadata.processing_time = processing_time logger.info(f"Direct extraction completed in {processing_time:.2f}s") return UnifiedDocument( document_id=document_id, metadata=metadata, pages=pages ) except Exception as e: logger.error(f"Error during direct extraction: {e}") # Return partial result with error information processing_time = (datetime.now() - start_time).total_seconds() if 'metadata' not in locals(): metadata = DocumentMetadata( filename=file_path.name, file_type="pdf", file_size=file_path.stat().st_size if file_path.exists() else 0, created_at=datetime.now(), processing_track=ProcessingTrack.DIRECT, processing_time=processing_time ) return UnifiedDocument( document_id=document_id, metadata=metadata, pages=pages if 'pages' in locals() else [], processing_errors=[{ "error": str(e), "type": type(e).__name__ }] ) def _extract_metadata(self, file_path: Path, doc: fitz.Document, start_time: datetime) -> DocumentMetadata: """Extract document metadata""" pdf_metadata = doc.metadata return DocumentMetadata( filename=file_path.name, file_type="pdf", file_size=file_path.stat().st_size, created_at=start_time, processing_track=ProcessingTrack.DIRECT, processing_time=0.0, # Will be updated later title=pdf_metadata.get("title"), author=pdf_metadata.get("author"), subject=pdf_metadata.get("subject"), keywords=pdf_metadata.get("keywords", "").split(",") if pdf_metadata.get("keywords") else None, producer=pdf_metadata.get("producer"), creator=pdf_metadata.get("creator"), creation_date=self._parse_pdf_date(pdf_metadata.get("creationDate")), modification_date=self._parse_pdf_date(pdf_metadata.get("modDate")) ) def _parse_pdf_date(self, date_str: str) -> Optional[datetime]: """Parse PDF date string to datetime""" if not date_str: return None try: # PDF date format: D:YYYYMMDDHHmmSSOHH'mm # Example: D:20240101120000+09'00 if date_str.startswith("D:"): date_str = date_str[2:] # Extract just the date/time part (first 14 characters) if len(date_str) >= 14: date_part = date_str[:14] return datetime.strptime(date_part, "%Y%m%d%H%M%S") except: pass return None def _extract_page(self, page: fitz.Page, page_num: int, document_id: str, output_dir: Optional[Path]) -> Page: """Extract content from a single page""" elements = [] element_counter = 0 # Get page-level metadata (for final Page metadata) drawings = page.get_drawings() links = page.get_links() # Get page dimensions rect = page.rect dimensions = Dimensions( width=rect.width, height=rect.height, dpi=72 # PDF standard DPI ) # Extract tables first (if enabled) to get table regions table_bboxes = [] if self.enable_table_detection: try: # Try native table detection (PyMuPDF 1.23.0+) tables = page.find_tables() for table_idx, table in enumerate(tables): element = self._process_native_table( table, page_num, element_counter ) if element and element.bbox: elements.append(element) table_bboxes.append(element.bbox) element_counter += 1 except AttributeError: # Fallback to positional table detection logger.debug("Native table detection not available, using positional detection") table_elements = self._detect_tables_by_position(page, page_num, element_counter) for elem in table_elements: if elem.bbox: table_bboxes.append(elem.bbox) elements.extend(table_elements) element_counter += len(table_elements) # Extract text blocks with formatting (sort=True for reading order) # Filter out lines that overlap with table regions text_dict = page.get_text("dict", sort=True) for block_idx, block in enumerate(text_dict.get("blocks", [])): if block.get("type") == 0: # Text block element = self._process_text_block( block, page_num, element_counter, table_bboxes ) if element: elements.append(element) element_counter += 1 # Extract images (if enabled) if self.enable_image_extraction: image_elements = self._extract_images( page, page_num, document_id, element_counter, output_dir ) elements.extend(image_elements) element_counter += len(image_elements) # Extract vector graphics (charts, diagrams) from drawing commands # Pass table_bboxes to filter out table border drawings before clustering if self.enable_image_extraction: vector_elements = self._extract_vector_graphics( page, page_num, document_id, element_counter, output_dir, table_bboxes=table_bboxes ) elements.extend(vector_elements) element_counter += len(vector_elements) # Extract hyperlinks links = page.get_links() for link_idx, link in enumerate(links): # Create link annotation element if it has URI if link.get("uri"): from_rect = link.get("from") if from_rect: element = DocumentElement( element_id=f"link_{page_num}_{element_counter}", type=ElementType.REFERENCE, content={"uri": link["uri"], "type": "hyperlink"}, bbox=BoundingBox( x0=from_rect.x0, y0=from_rect.y0, x1=from_rect.x1, y1=from_rect.y1 ), metadata={"link_type": "external" if link["uri"].startswith("http") else "internal"} ) elements.append(element) element_counter += 1 # PyMuPDF's sort=True already provides good reading order for multi-column layouts # (top-to-bottom, left-to-right within each row). We don't need to re-sort. # NOTE: If sort=True is not used in get_text(), uncomment the line below: # elements = self._sort_elements_for_reading_order(elements, dimensions) # Deduplicate: Remove CHART elements that overlap with TABLE elements # (Tables have structured data, so they take priority over vector graphics) elements = self._deduplicate_table_chart_overlap(elements) # Post-process elements for header/footer detection and structure elements = self._detect_headers_footers(elements, dimensions) elements = self._build_section_hierarchy(elements) elements = self._build_nested_lists(elements) return Page( page_number=page_num, elements=elements, dimensions=dimensions, metadata={ "has_drawings": len(drawings) > 0, "drawing_count": len(drawings), "link_count": len(links) } ) def _sort_elements_for_reading_order(self, elements: List[DocumentElement], dimensions: Dimensions) -> List[DocumentElement]: """ Sort elements by reading order, handling multi-column layouts. For multi-column layouts (e.g., two-column documents), this ensures elements are ordered correctly: top-to-bottom, then left-to-right within each row. Args: elements: List of document elements dimensions: Page dimensions Returns: Sorted list of elements in reading order """ if not elements: return elements # Detect if page has multi-column layout text_elements = [e for e in elements if e.bbox and e.is_text] if len(text_elements) < 3: # Too few elements to determine layout, just sort by Y position return sorted(elements, key=lambda e: (e.bbox.y0 if e.bbox else 0, e.bbox.x0 if e.bbox else 0)) # Cluster x-positions to detect columns x_positions = [e.bbox.x0 for e in text_elements] columns = self._detect_columns(x_positions, dimensions.width) if len(columns) <= 1: # Single column layout - simple top-to-bottom sort logger.debug(f"Detected single-column layout") return sorted(elements, key=lambda e: (e.bbox.y0 if e.bbox else 0, e.bbox.x0 if e.bbox else 0)) logger.debug(f"Detected {len(columns)}-column layout at x positions: {[f'{x:.1f}' for x in columns]}") # Multi-column layout - use newspaper-style reading order # (complete left column, then right column, etc.) # This is more appropriate for technical documents and data sheets element_data = [] for elem in elements: if not elem.bbox: element_data.append((elem, 0, 0)) continue # Find which column this element belongs to col_idx = 0 min_dist = float('inf') for i, col_x in enumerate(columns): dist = abs(elem.bbox.x0 - col_x) if dist < min_dist: min_dist = dist col_idx = i element_data.append((elem, col_idx, elem.bbox.y0)) # Sort by: column first, then Y position within column # This gives newspaper-style reading: complete column 1, then column 2, etc. element_data.sort(key=lambda x: (x[1], x[2])) logger.debug(f"Using newspaper-style column reading order (column by column, top to bottom)") return [e[0] for e in element_data] def _detect_columns(self, x_positions: List[float], page_width: float) -> List[float]: """ Detect column positions from x-coordinates of text elements. Args: x_positions: List of x-coordinates (left edges of text) page_width: Page width in points Returns: List of column x-positions (sorted left to right) """ if not x_positions: return [] # Cluster x-positions to find column starts # Use k-means-like approach: find groups of x-positions threshold = page_width * 0.15 # 15% of page width as clustering threshold sorted_x = sorted(set(x_positions)) if not sorted_x: return [] clusters = [[sorted_x[0]]] for x in sorted_x[1:]: # Check if x belongs to current cluster cluster_center = sum(clusters[-1]) / len(clusters[-1]) if abs(x - cluster_center) < threshold: clusters[-1].append(x) else: # Start new cluster clusters.append([x]) # Return average x position of each cluster (column start) column_positions = [sum(cluster) / len(cluster) for cluster in clusters] # Filter out columns that are too close to each other min_column_width = page_width * 0.2 # Columns must be at least 20% of page width apart filtered_columns = [column_positions[0]] for col_x in column_positions[1:]: if col_x - filtered_columns[-1] >= min_column_width: filtered_columns.append(col_x) return filtered_columns def _detect_headers_footers(self, elements: List[DocumentElement], dimensions: Dimensions) -> List[DocumentElement]: """Detect and mark header/footer elements based on page position""" page_height = dimensions.height header_threshold = page_height * 0.1 # Top 10% of page footer_threshold = page_height * 0.9 # Bottom 10% of page for elem in elements: # Skip non-text elements if not elem.is_text: continue # Check if element is in header region if elem.bbox.y1 <= header_threshold: # Only mark as header if it's short text if isinstance(elem.content, str) and len(elem.content) < 200: elem.type = ElementType.HEADER elem.metadata['is_page_header'] = True # Check if element is in footer region elif elem.bbox.y0 >= footer_threshold: # Short text in footer region if isinstance(elem.content, str) and len(elem.content) < 200: elem.type = ElementType.FOOTER elem.metadata['is_page_footer'] = True return elements def _build_section_hierarchy(self, elements: List[DocumentElement]) -> List[DocumentElement]: """Build hierarchical section structure based on font sizes""" # Collect all headers with their font sizes headers = [] for elem in elements: if elem.type in [ElementType.TITLE, ElementType.HEADER]: # Get average font size from style font_size = 12.0 # Default if elem.style and elem.style.font_size: font_size = elem.style.font_size headers.append((elem, font_size)) if not headers: return elements # Sort headers by font size to determine hierarchy levels font_sizes = sorted(set(size for _, size in headers), reverse=True) size_to_level = {size: level for level, size in enumerate(font_sizes, 1)} # Assign section levels to headers for elem, font_size in headers: level = size_to_level.get(font_size, 1) elem.metadata['section_level'] = level elem.metadata['font_size'] = font_size # Build parent-child relationships between headers header_stack = [] # Stack of (element, level) for elem, font_size in headers: level = elem.metadata['section_level'] # Pop headers that are at same or lower level (larger font) while header_stack and header_stack[-1][1] >= level: header_stack.pop() # Set parent header if header_stack: parent = header_stack[-1][0] elem.metadata['parent_section'] = parent.element_id if 'child_sections' not in parent.metadata: parent.metadata['child_sections'] = [] parent.metadata['child_sections'].append(elem.element_id) header_stack.append((elem, level)) # Link content to nearest preceding header at same or higher level current_header = None for elem in elements: if elem.type in [ElementType.TITLE, ElementType.HEADER]: current_header = elem elif current_header and elem.type not in [ElementType.HEADER, ElementType.FOOTER]: elem.metadata['section_id'] = current_header.element_id return elements def _build_nested_lists(self, elements: List[DocumentElement]) -> List[DocumentElement]: """Build nested list structure from flat list items""" # Group list items list_items = [e for e in elements if e.type == ElementType.LIST_ITEM] if not list_items: return elements # Sort by position (top to bottom) list_items.sort(key=lambda e: (e.bbox.y0, e.bbox.x0)) # Detect indentation levels based on x position x_positions = [item.bbox.x0 for item in list_items] if not x_positions: return elements min_x = min(x_positions) indent_unit = 20 # Typical indent size in points # Assign nesting levels for item in list_items: indent = item.bbox.x0 - min_x level = int(indent / indent_unit) item.metadata['list_level'] = level # Build parent-child relationships item_stack = [] # Stack of (element, level) for item in list_items: level = item.metadata.get('list_level', 0) # Pop items at same or deeper level while item_stack and item_stack[-1][1] >= level: item_stack.pop() # Set parent if item_stack: parent = item_stack[-1][0] item.metadata['parent_item'] = parent.element_id if 'children' not in parent.metadata: parent.metadata['children'] = [] parent.metadata['children'].append(item.element_id) # Also add to actual children list parent.children.append(item) item_stack.append((item, level)) return elements def _process_text_block(self, block: Dict, page_num: int, counter: int, table_bboxes: List[BoundingBox] = None) -> Optional[DocumentElement]: """ Process a text block into a DocumentElement. Args: block: Text block from PyMuPDF page_num: Page number counter: Element counter table_bboxes: List of table bounding boxes to filter overlapping lines Returns: DocumentElement or None if all lines overlap with tables """ if table_bboxes is None: table_bboxes = [] # Extract text content and span information # Filter out lines that significantly overlap with table regions text_parts = [] styles = [] span_children = [] # Store span-level children for inline styling span_counter = 0 valid_line_bboxes = [] # Track bboxes of valid lines for overall bbox calculation for line in block.get("lines", []): line_bbox_data = line.get("bbox", [0, 0, 0, 0]) # Check if this line overlaps with any table region line_overlaps_table = False for table_bbox in table_bboxes: overlap_x0 = max(line_bbox_data[0], table_bbox.x0) overlap_y0 = max(line_bbox_data[1], table_bbox.y0) overlap_x1 = min(line_bbox_data[2], table_bbox.x1) overlap_y1 = min(line_bbox_data[3], table_bbox.y1) if overlap_x0 < overlap_x1 and overlap_y0 < overlap_y1: # Calculate overlap ratio line_height = line_bbox_data[3] - line_bbox_data[1] overlap_height = overlap_y1 - overlap_y0 if line_height > 0: overlap_ratio = overlap_height / line_height if overlap_ratio >= 0.5: # Line significantly overlaps with table line_overlaps_table = True break if line_overlaps_table: continue # Skip this line # Process valid line valid_line_bboxes.append(line_bbox_data) for span in line.get("spans", []): text = span.get("text", "") if text: text_parts.append(text) # Extract style information style = StyleInfo( font_name=span.get("font"), font_size=span.get("size"), font_weight="bold" if span.get("flags", 0) & 2**4 else "normal", font_style="italic" if span.get("flags", 0) & 2**1 else "normal", text_color=span.get("color") ) styles.append(style) # Create span child element for inline styling span_bbox_data = span.get("bbox", [0, 0, 0, 0]) span_bbox = BoundingBox( x0=span_bbox_data[0], y0=span_bbox_data[1], x1=span_bbox_data[2], y1=span_bbox_data[3] ) span_element = DocumentElement( element_id=f"span_{page_num}_{counter}_{span_counter}", type=ElementType.TEXT, # Spans are always text content=text, bbox=span_bbox, style=style, confidence=1.0, metadata={"span_index": span_counter} ) span_children.append(span_element) span_counter += 1 if not text_parts: return None # All lines overlapped with tables full_text = "".join(text_parts) # Calculate bbox from valid lines only if valid_line_bboxes: min_x0 = min(b[0] for b in valid_line_bboxes) min_y0 = min(b[1] for b in valid_line_bboxes) max_x1 = max(b[2] for b in valid_line_bboxes) max_y1 = max(b[3] for b in valid_line_bboxes) bbox = BoundingBox(x0=min_x0, y0=min_y0, x1=max_x1, y1=max_y1) else: # Fallback to original bbox if no valid lines found bbox_data = block.get("bbox", [0, 0, 0, 0]) bbox = BoundingBox(x0=bbox_data[0], y0=bbox_data[1], x1=bbox_data[2], y1=bbox_data[3]) # Determine element type based on content and style element_type = self._infer_element_type(full_text, styles) # Use the most common style for the block if styles: block_style = styles[0] # Could be improved with style merging else: block_style = None return DocumentElement( element_id=f"text_{page_num}_{counter}", type=element_type, content=full_text, bbox=bbox, style=block_style, confidence=1.0, # Direct extraction has perfect confidence children=span_children # Store span children for inline styling ) def _infer_element_type(self, text: str, styles: List[StyleInfo]) -> ElementType: """Infer element type based on text content and styling""" text_lower = text.lower().strip() # Check for common patterns if len(text_lower) < 100 and styles: # Short text with large font might be title/header avg_size = sum(s.font_size or 12 for s in styles) / len(styles) if avg_size > 16: return ElementType.TITLE elif avg_size > 14: return ElementType.HEADER # Check for list patterns if re.match(r'^[\d•·▪▫◦‣⁃]\s', text_lower): return ElementType.LIST_ITEM # Check for page numbers if re.match(r'^page\s+\d+|^\d+\s*$|^-\s*\d+\s*-$', text_lower): return ElementType.PAGE_NUMBER # Check for footnote patterns if re.match(r'^[\[\d+\]]|^\d+\)', text_lower): return ElementType.FOOTNOTE # Default to paragraph for longer text, text for shorter return ElementType.PARAGRAPH if len(text) > 150 else ElementType.TEXT def _process_native_table(self, table, page_num: int, counter: int) -> Optional[DocumentElement]: """Process a natively detected table""" try: # Extract table data data = table.extract() if not data or len(data) < self.min_table_rows: return None # Get table bounding box bbox_data = table.bbox bbox = BoundingBox( x0=bbox_data[0], y0=bbox_data[1], x1=bbox_data[2], y1=bbox_data[3] ) # Extract column widths from table cells by analyzing X boundaries column_widths = [] if hasattr(table, 'cells') and table.cells: # Collect all unique X boundaries (both left and right edges) x_boundaries = set() for cell in table.cells: x_boundaries.add(round(cell[0], 1)) # x0 (left edge) x_boundaries.add(round(cell[2], 1)) # x1 (right edge) # Sort boundaries to get column edges sorted_x = sorted(x_boundaries) # Calculate column widths from adjacent boundaries if len(sorted_x) >= 2: column_widths = [sorted_x[i+1] - sorted_x[i] for i in range(len(sorted_x)-1)] logger.debug(f"Calculated column widths from {len(sorted_x)} boundaries: {column_widths}") # Extract row heights from table cells by analyzing Y boundaries row_heights = [] if hasattr(table, 'cells') and table.cells: # Collect all unique Y boundaries (both top and bottom edges) y_boundaries = set() for cell in table.cells: y_boundaries.add(round(cell[1], 1)) # y0 (top edge) y_boundaries.add(round(cell[3], 1)) # y1 (bottom edge) # Sort boundaries to get row edges sorted_y = sorted(y_boundaries) # Calculate row heights from adjacent boundaries if len(sorted_y) >= 2: row_heights = [sorted_y[i+1] - sorted_y[i] for i in range(len(sorted_y)-1)] logger.debug(f"Calculated row heights from {len(sorted_y)} boundaries: {row_heights}") # Create table cells # Note: Include ALL cells (even empty ones) to preserve table structure # This is critical for correct HTML generation and PDF rendering cells = [] for row_idx, row in enumerate(data): for col_idx, cell_text in enumerate(row): # Always add cell, even if empty, to maintain table structure cells.append(TableCell( row=row_idx, col=col_idx, content=str(cell_text) if cell_text else "" )) # Create table data table_data = TableData( rows=len(data), cols=max(len(row) for row in data) if data else 0, cells=cells, headers=data[0] if data else None # Assume first row is header ) # Store column widths and row heights in metadata metadata = {} if column_widths: metadata["column_widths"] = column_widths if row_heights: metadata["row_heights"] = row_heights metadata = metadata if metadata else None return DocumentElement( element_id=f"table_{page_num}_{counter}", type=ElementType.TABLE, content=table_data, bbox=bbox, confidence=1.0, metadata=metadata ) except Exception as e: logger.error(f"Error processing native table: {e}") return None def _detect_tables_by_position(self, page: fitz.Page, page_num: int, counter: int) -> List[DocumentElement]: """Detect tables by analyzing text positioning""" tables = [] # Get all words with positions words = page.get_text("words") # Returns (x0, y0, x1, y1, "word", block_no, line_no, word_no) if not words: return tables # Group words by approximate row (y-coordinate) rows = {} for word in words: y = round(word[1] / 5) * 5 # Round to nearest 5 points if y not in rows: rows[y] = [] rows[y].append({ 'x0': word[0], 'y0': word[1], 'x1': word[2], 'y1': word[3], 'text': word[4], 'block': word[5] if len(word) > 5 else 0 }) # Sort rows by y-coordinate sorted_rows = sorted(rows.items(), key=lambda x: x[0]) # Find potential tables (consecutive rows with multiple columns) current_table_rows = [] tables_found = [] for y, words_in_row in sorted_rows: words_in_row.sort(key=lambda w: w['x0']) if len(words_in_row) >= self.min_table_cols: # Check if this could be a table row x_positions = [w['x0'] for w in words_in_row] # Check for somewhat regular spacing if self._has_regular_spacing(x_positions): current_table_rows.append((y, words_in_row)) else: # End current table if exists if len(current_table_rows) >= self.min_table_rows: tables_found.append(current_table_rows) current_table_rows = [] else: # End current table if exists if len(current_table_rows) >= self.min_table_rows: tables_found.append(current_table_rows) current_table_rows = [] # Don't forget the last table if len(current_table_rows) >= self.min_table_rows: tables_found.append(current_table_rows) # Convert detected tables to DocumentElements for table_idx, table_rows in enumerate(tables_found): if not table_rows: continue # Calculate table bounding box all_words = [] for _, words in table_rows: all_words.extend(words) min_x = min(w['x0'] for w in all_words) min_y = min(w['y0'] for w in all_words) max_x = max(w['x1'] for w in all_words) max_y = max(w['y1'] for w in all_words) bbox = BoundingBox(x0=min_x, y0=min_y, x1=max_x, y1=max_y) # Create table cells cells = [] for row_idx, (y, words) in enumerate(table_rows): # Group words into columns columns = self._group_into_columns(words, table_rows) for col_idx, col_text in enumerate(columns): if col_text: cells.append(TableCell( row=row_idx, col=col_idx, content=col_text )) # Create table data table_data = TableData( rows=len(table_rows), cols=max(len(self._group_into_columns(words, table_rows)) for _, words in table_rows), cells=cells ) element = DocumentElement( element_id=f"table_{page_num}_{counter + table_idx}", type=ElementType.TABLE, content=table_data, bbox=bbox, confidence=0.8, # Lower confidence for positional detection metadata={"detection_method": "positional"} ) tables.append(element) return tables def _has_regular_spacing(self, x_positions: List[float], tolerance: float = 0.3) -> bool: """Check if x positions have somewhat regular spacing""" if len(x_positions) < 3: return False spacings = [x_positions[i+1] - x_positions[i] for i in range(len(x_positions)-1)] avg_spacing = sum(spacings) / len(spacings) # Check if spacings are within tolerance of average for spacing in spacings: if abs(spacing - avg_spacing) > avg_spacing * tolerance: return False return True def _group_into_columns(self, words: List[Dict], all_rows: List) -> List[str]: """Group words into columns based on x-position""" if not words: return [] # Find common column positions across all rows all_x_positions = [] for _, row_words in all_rows: all_x_positions.extend([w['x0'] for w in row_words]) # Cluster x-positions to find columns column_positions = self._cluster_positions(all_x_positions) # Assign words to columns columns = [""] * len(column_positions) for word in words: # Find closest column closest_col = 0 min_dist = float('inf') for col_idx, col_x in enumerate(column_positions): dist = abs(word['x0'] - col_x) if dist < min_dist: min_dist = dist closest_col = col_idx if columns[closest_col]: columns[closest_col] += " " + word['text'] else: columns[closest_col] = word['text'] return columns def _cluster_positions(self, positions: List[float], threshold: float = 20) -> List[float]: """Cluster positions to find common columns""" if not positions: return [] sorted_pos = sorted(positions) clusters = [[sorted_pos[0]]] for pos in sorted_pos[1:]: # Check if position belongs to current cluster if pos - clusters[-1][-1] < threshold: clusters[-1].append(pos) else: clusters.append([pos]) # Return average position of each cluster return [sum(cluster) / len(cluster) for cluster in clusters] def _extract_images(self, page: fitz.Page, page_num: int, document_id: str, counter: int, output_dir: Optional[Path]) -> List[DocumentElement]: """Extract images from page""" elements = [] image_list = page.get_images() for img_idx, img in enumerate(image_list): try: xref = img[0] # Get image position(s) img_rects = page.get_image_rects(xref) if not img_rects: continue rect = img_rects[0] # Use first occurrence bbox = BoundingBox( x0=rect.x0, y0=rect.y0, x1=rect.x1, y1=rect.y1 ) # Extract image data pix = fitz.Pixmap(page.parent, xref) image_data = { "width": pix.width, "height": pix.height, "colorspace": pix.colorspace.name if pix.colorspace else "unknown", "xref": xref } # Save image if output directory provided if output_dir: output_dir.mkdir(parents=True, exist_ok=True) image_filename = f"{document_id}_p{page_num}_img{img_idx}.png" image_path = output_dir / image_filename pix.save(str(image_path)) # Store relative filename only (consistent with OCR track) # PDF generator will join with result_dir to get full path image_data["saved_path"] = image_filename logger.debug(f"Saved image to {image_path}") element = DocumentElement( element_id=f"image_{page_num}_{counter + img_idx}", type=ElementType.IMAGE, content=image_data, bbox=bbox, confidence=1.0, metadata={ "image_index": img_idx, "xref": xref } ) elements.append(element) pix = None # Free memory except Exception as e: logger.error(f"Error extracting image {img_idx}: {e}") return elements def has_missing_images(self, page: fitz.Page) -> bool: """ Detect if a page likely has images that weren't extracted. This checks for inline image blocks (type=1 in text dict) which indicate graphics composed of many small image blocks (like logos) that page.get_images() cannot detect. Args: page: PyMuPDF page object Returns: True if there are likely missing images that need OCR extraction """ try: # Check if get_images found anything standard_images = page.get_images() if standard_images: return False # Standard images were found, no need for fallback # Check for inline image blocks (type=1) text_dict = page.get_text("dict", sort=True) blocks = text_dict.get("blocks", []) image_block_count = sum(1 for b in blocks if b.get("type") == 1) # If there are many inline image blocks, likely there's a logo or graphic if image_block_count >= 10: logger.info(f"Detected {image_block_count} inline image blocks - may need OCR for image extraction") return True return False except Exception as e: logger.warning(f"Error checking for missing images: {e}") return False def check_document_for_missing_images(self, pdf_path: Path) -> List[int]: """ Check a PDF document for pages that likely have missing images. This opens the PDF and checks each page for inline image blocks that weren't extracted by get_images(). Args: pdf_path: Path to the PDF file Returns: List of page numbers (1-indexed) that have missing images """ pages_with_missing_images = [] try: doc = fitz.open(str(pdf_path)) for page_num in range(len(doc)): page = doc[page_num] if self.has_missing_images(page): pages_with_missing_images.append(page_num + 1) # 1-indexed doc.close() if pages_with_missing_images: logger.info(f"Document has missing images on pages: {pages_with_missing_images}") except Exception as e: logger.error(f"Error checking document for missing images: {e}") return pages_with_missing_images def render_inline_image_regions( self, pdf_path: Path, unified_doc: 'UnifiedDocument', pages: List[int], output_dir: Optional[Path] = None ) -> int: """ Render inline image regions and add them to the unified document. This is a fallback when OCR doesn't detect images. It clusters inline image blocks (type=1) and renders them as images. Args: pdf_path: Path to the PDF file unified_doc: UnifiedDocument to add images to pages: List of page numbers (1-indexed) to process output_dir: Directory to save rendered images Returns: Number of images added """ images_added = 0 try: doc = fitz.open(str(pdf_path)) for page_num in pages: if page_num < 1 or page_num > len(doc): continue page = doc[page_num - 1] # 0-indexed page_rect = page.rect # Get inline image blocks text_dict = page.get_text("dict", sort=True) blocks = text_dict.get("blocks", []) image_blocks = [] for block in blocks: if block.get("type") == 1: # Image block bbox = block.get("bbox") if bbox: image_blocks.append(fitz.Rect(bbox)) if len(image_blocks) < 5: # Reduced from 10 logger.debug(f"Page {page_num}: Only {len(image_blocks)} inline image blocks, skipping") continue logger.info(f"Page {page_num}: Found {len(image_blocks)} inline image blocks") # Cluster nearby image blocks regions = self._cluster_nearby_rects(image_blocks, tolerance=5.0) logger.info(f"Page {page_num}: Clustered into {len(regions)} regions") # Find the corresponding page in unified_doc target_page = None for p in unified_doc.pages: if p.page_number == page_num: target_page = p break if not target_page: continue for region_idx, region_rect in enumerate(regions): logger.info(f"Page {page_num} region {region_idx}: {region_rect} (w={region_rect.width:.1f}, h={region_rect.height:.1f})") # Skip very small regions if region_rect.width < 30 or region_rect.height < 30: logger.info(f" -> Skipped: too small (min 30x30)") continue # Skip regions that are primarily in the table area (below top 40%) # But allow regions that START in the top portion page_30_pct = page_rect.height * 0.3 page_40_pct = page_rect.height * 0.4 if region_rect.y0 > page_40_pct: logger.info(f" -> Skipped: y0={region_rect.y0:.1f} > 40% of page ({page_40_pct:.1f})") continue logger.info(f"Rendering inline image region {region_idx} on page {page_num}: {region_rect}") try: # Add small padding clip_rect = region_rect + (-2, -2, 2, 2) clip_rect.intersect(page_rect) # Render at 2x resolution mat = fitz.Matrix(2, 2) pix = page.get_pixmap(clip=clip_rect, matrix=mat, alpha=False) # Create bounding box bbox = BoundingBox( x0=clip_rect.x0, y0=clip_rect.y0, x1=clip_rect.x1, y1=clip_rect.y1 ) image_data = { "width": pix.width, "height": pix.height, "colorspace": "rgb", "type": "inline_region" } # Save image if output directory provided if output_dir: output_dir.mkdir(parents=True, exist_ok=True) doc_id = unified_doc.document_id or "unknown" image_filename = f"{doc_id}_p{page_num}_logo{region_idx}.png" image_path = output_dir / image_filename pix.save(str(image_path)) image_data["saved_path"] = image_filename logger.info(f"Saved inline image region to {image_path}") element = DocumentElement( element_id=f"logo_{page_num}_{region_idx}", type=ElementType.LOGO, content=image_data, bbox=bbox, confidence=0.9, metadata={ "region_type": "inline_image_blocks", "block_count": len(image_blocks) } ) target_page.elements.append(element) images_added += 1 pix = None # Free memory except Exception as e: logger.error(f"Error rendering inline image region {region_idx}: {e}") doc.close() if images_added > 0: current_images = unified_doc.metadata.total_images or 0 unified_doc.metadata.total_images = current_images + images_added logger.info(f"Added {images_added} inline image regions to document") except Exception as e: logger.error(f"Error rendering inline image regions: {e}") return images_added def _cluster_nearby_rects(self, rects: List[fitz.Rect], tolerance: float = 5.0) -> List[fitz.Rect]: """Cluster nearby rectangles into regions.""" if not rects: return [] sorted_rects = sorted(rects, key=lambda r: (r.y0, r.x0)) merged = [] for rect in sorted_rects: merged_with_existing = False for i, region in enumerate(merged): expanded = region + (-tolerance, -tolerance, tolerance, tolerance) if expanded.intersects(rect): merged[i] = region | rect merged_with_existing = True break if not merged_with_existing: merged.append(rect) # Second pass: merge any regions that now overlap changed = True while changed: changed = False new_merged = [] skip = set() for i, r1 in enumerate(merged): if i in skip: continue current = r1 for j, r2 in enumerate(merged[i+1:], start=i+1): if j in skip: continue expanded = current + (-tolerance, -tolerance, tolerance, tolerance) if expanded.intersects(r2): current = current | r2 skip.add(j) changed = True new_merged.append(current) merged = new_merged return merged def _extract_vector_graphics(self, page: fitz.Page, page_num: int, document_id: str, counter: int, output_dir: Optional[Path], table_bboxes: Optional[List[BoundingBox]] = None) -> List[DocumentElement]: """ Extract vector graphics (charts, diagrams) from page. This method identifies regions that are composed of vector drawing commands (paths, lines, rectangles) rather than embedded raster images. These are typically charts created in Excel, vector diagrams, or other graphics. Args: page: PyMuPDF page object page_num: Page number (1-indexed) document_id: Unique document identifier counter: Starting counter for element IDs output_dir: Directory to save rendered graphics table_bboxes: List of table bounding boxes to exclude table border drawings Returns: List of DocumentElement objects representing vector graphics """ elements = [] try: # Get all drawing commands drawings = page.get_drawings() if not drawings: return elements logger.debug(f"Page {page_num} contains {len(drawings)} vector drawing commands") # Filter out drawings that are likely table borders # Table borders are typically thin rectangular lines within table regions non_table_drawings = self._filter_table_border_drawings(drawings, table_bboxes) logger.debug(f"After filtering table borders: {len(non_table_drawings)} drawings remain") if not non_table_drawings: logger.debug("All drawings appear to be table borders, no vector graphics to extract") return elements # Cluster drawings into groups (charts, diagrams, etc.) try: # Use custom clustering that only considers non-table drawings drawing_clusters = self._cluster_non_table_drawings(page, non_table_drawings) logger.debug(f"Clustered into {len(drawing_clusters)} groups") except (AttributeError, TypeError) as e: # cluster_drawings not available or has different signature # Fallback: try to identify charts by analyzing drawing density logger.warning(f"Custom clustering failed ({e}), using fallback method") drawing_clusters = self._cluster_drawings_fallback(page, non_table_drawings) for cluster_idx, bbox in enumerate(drawing_clusters): # Ignore small regions (likely noise or separator lines) if bbox.width < 50 or bbox.height < 50: logger.debug(f"Skipping small cluster {cluster_idx}: {bbox.width:.1f}x{bbox.height:.1f}") continue # Render the region to a raster image # matrix=fitz.Matrix(2, 2) increases resolution to ~200 DPI try: pix = page.get_pixmap(clip=bbox, matrix=fitz.Matrix(2, 2)) # Save image if output directory provided if output_dir: output_dir.mkdir(parents=True, exist_ok=True) filename = f"{document_id}_p{page_num}_chart{cluster_idx}.png" filepath = output_dir / filename pix.save(str(filepath)) # Create DocumentElement image_data = { "saved_path": str(filepath), "width": pix.width, "height": pix.height, "colorspace": pix.colorspace.name if pix.colorspace else "unknown", "source": "vector_graphics" } element = DocumentElement( element_id=f"chart_{page_num}_{counter + cluster_idx}", type=ElementType.CHART, # Use CHART type for vector graphics content=image_data, bbox=BoundingBox( x0=bbox.x0, y0=bbox.y0, x1=bbox.x1, y1=bbox.y1 ), confidence=0.85, # Slightly lower confidence than raster images metadata={ "cluster_index": cluster_idx, "drawing_count": len(drawings) } ) elements.append(element) logger.debug(f"Extracted chart {cluster_idx}: {bbox.width:.1f}x{bbox.height:.1f} -> {filepath}") pix = None # Free memory except Exception as e: logger.error(f"Error rendering vector graphic cluster {cluster_idx}: {e}") continue except Exception as e: logger.error(f"Error extracting vector graphics: {e}") return elements def _cluster_drawings_fallback(self, page: fitz.Page, drawings: list) -> list: """ Fallback method to cluster drawings when cluster_drawings() is not available. This uses a simple spatial clustering approach based on bounding boxes. """ if not drawings: return [] # Collect all drawing bounding boxes bboxes = [] for drawing in drawings: rect = drawing.get('rect') if rect: bboxes.append(fitz.Rect(rect)) if not bboxes: return [] # Simple clustering: merge overlapping or nearby rectangles clusters = [] tolerance = 20 for bbox in bboxes: # Try to merge with existing cluster merged = False for i, cluster in enumerate(clusters): # Check if bbox is close to this cluster expanded_cluster = cluster + (-tolerance, -tolerance, tolerance, tolerance) if expanded_cluster.intersects(bbox): # Merge bbox into cluster clusters[i] = cluster | bbox # Union of rectangles merged = True break if not merged: # Create new cluster clusters.append(bbox) # Filter out very small clusters filtered_clusters = [c for c in clusters if c.width >= 50 and c.height >= 50] logger.debug(f"Fallback clustering: {len(bboxes)} drawings -> {len(clusters)} clusters -> {len(filtered_clusters)} filtered") return filtered_clusters def _filter_table_border_drawings(self, drawings: list, table_bboxes: Optional[List[BoundingBox]]) -> list: """ Filter out drawings that are likely table borders. Table borders are typically: - Thin rectangular lines (height or width < 5pt) - Located within or on the edge of table bounding boxes Args: drawings: List of PyMuPDF drawing objects table_bboxes: List of table bounding boxes Returns: List of drawings that are NOT table borders (likely logos, charts, etc.) """ if not table_bboxes: return drawings non_table_drawings = [] table_border_count = 0 for drawing in drawings: rect = drawing.get('rect') if not rect: continue draw_rect = fitz.Rect(rect) # Check if this drawing is a thin line (potential table border) is_thin_line = draw_rect.width < 5 or draw_rect.height < 5 # Check if drawing overlaps significantly with any table overlaps_table = False for table_bbox in table_bboxes: table_rect = fitz.Rect(table_bbox.x0, table_bbox.y0, table_bbox.x1, table_bbox.y1) # Expand table rect slightly to include border lines on edges expanded_table = table_rect + (-5, -5, 5, 5) if expanded_table.contains(draw_rect) or expanded_table.intersects(draw_rect): # Calculate overlap ratio intersection = draw_rect & expanded_table if not intersection.is_empty: overlap_ratio = intersection.get_area() / draw_rect.get_area() if draw_rect.get_area() > 0 else 0 # If drawing is mostly inside table region, it's likely a border if overlap_ratio > 0.8: overlaps_table = True break # Keep drawing if it's NOT (thin line AND overlapping table) # This keeps: logos (complex shapes), charts outside tables, etc. if is_thin_line and overlaps_table: table_border_count += 1 else: non_table_drawings.append(drawing) if table_border_count > 0: logger.debug(f"Filtered out {table_border_count} table border drawings") return non_table_drawings def _cluster_non_table_drawings(self, page: fitz.Page, drawings: list) -> list: """ Cluster non-table drawings into groups. This method clusters drawings that have been pre-filtered to exclude table borders. It uses a more conservative clustering approach suitable for logos and charts. Args: page: PyMuPDF page object drawings: Pre-filtered list of drawings (excluding table borders) Returns: List of fitz.Rect representing clustered drawing regions """ if not drawings: return [] # Collect all drawing bounding boxes bboxes = [] for drawing in drawings: rect = drawing.get('rect') if rect: bboxes.append(fitz.Rect(rect)) if not bboxes: return [] # More conservative clustering with smaller tolerance # This prevents grouping distant graphics together clusters = [] tolerance = 10 # Smaller tolerance than fallback (was 20) for bbox in bboxes: # Try to merge with existing cluster merged = False for i, cluster in enumerate(clusters): # Check if bbox is close to this cluster expanded_cluster = cluster + (-tolerance, -tolerance, tolerance, tolerance) if expanded_cluster.intersects(bbox): # Merge bbox into cluster clusters[i] = cluster | bbox # Union of rectangles merged = True break if not merged: # Create new cluster clusters.append(bbox) # Filter out very small clusters (noise) # Keep minimum 30x30 for logos (smaller than default 50x50) filtered_clusters = [c for c in clusters if c.width >= 30 and c.height >= 30] logger.debug(f"Non-table clustering: {len(bboxes)} drawings -> {len(clusters)} clusters -> {len(filtered_clusters)} filtered") return filtered_clusters def _deduplicate_table_chart_overlap(self, elements: List[DocumentElement]) -> List[DocumentElement]: """ Intelligently resolve TABLE-CHART overlaps based on table structure completeness. When a region is detected as both TABLE and CHART: - Calculate cell completeness = actual_cells / (rows × cols) - If completeness ≥50% → Real table with complete structure → Keep TABLE - If completeness <50% → False positive (chart detected as table) → Keep CHART Args: elements: List of extracted elements Returns: Filtered list with low-quality overlaps removed """ # Collect all tables and charts tables = [elem for elem in elements if elem.type == ElementType.TABLE] charts = [elem for elem in elements if elem.type == ElementType.CHART] if not tables or not charts: return elements # No potential conflicts # Analyze TABLE structure completeness table_completeness = {} for table in tables: if hasattr(table.content, 'rows') and hasattr(table.content, 'cols') and hasattr(table.content, 'cells'): expected_cells = table.content.rows * table.content.cols actual_cells = len(table.content.cells) if expected_cells > 0: completeness = actual_cells / expected_cells table_completeness[table.element_id] = completeness else: table_completeness[table.element_id] = 0.0 else: table_completeness[table.element_id] = 0.0 # Check overlaps and decide what to keep filtered_elements = [] removed_charts = 0 removed_tables = 0 # Process TABLEs for table in tables: if not table.bbox: filtered_elements.append(table) continue # Check if this TABLE overlaps with any CHART overlaps_chart = False for chart in charts: if not chart.bbox: continue # Calculate overlap overlap_x0 = max(table.bbox.x0, chart.bbox.x0) overlap_y0 = max(table.bbox.y0, chart.bbox.y0) overlap_x1 = min(table.bbox.x1, chart.bbox.x1) overlap_y1 = min(table.bbox.y1, chart.bbox.y1) if overlap_x0 < overlap_x1 and overlap_y0 < overlap_y1: overlap_area = (overlap_x1 - overlap_x0) * (overlap_y1 - overlap_y0) table_area = (table.bbox.x1 - table.bbox.x0) * (table.bbox.y1 - table.bbox.y0) if table_area > 0: overlap_ratio = overlap_area / table_area if overlap_ratio >= 0.8: overlaps_chart = True completeness = table_completeness.get(table.element_id, 0.0) logger.debug( f"TABLE-CHART overlap: {table.element_id} vs {chart.element_id}: " f"{overlap_ratio*100:.1f}% overlap, TABLE cell completeness: {completeness*100:.1f}%" ) # Decision: Keep TABLE only if structure is complete if completeness < 0.5: # <50% cell completeness logger.info( f"Removing incomplete TABLE {table.element_id} " f"({completeness*100:.1f}% completeness, overlaps with CHART {chart.element_id})" ) removed_tables += 1 break else: logger.info( f"Keeping TABLE {table.element_id} with {completeness*100:.1f}% completeness " f"(will remove overlapping CHART {chart.element_id})" ) if not overlaps_chart or table_completeness.get(table.element_id, 0.0) >= 0.5: filtered_elements.append(table) # Process CHARTs for chart in charts: if not chart.bbox: filtered_elements.append(chart) continue # Check if this CHART should be removed due to overlap with high-quality TABLE should_remove = False for table in tables: if not table.bbox: continue # Calculate overlap overlap_x0 = max(chart.bbox.x0, table.bbox.x0) overlap_y0 = max(chart.bbox.y0, table.bbox.y0) overlap_x1 = min(chart.bbox.x1, table.bbox.x1) overlap_y1 = min(chart.bbox.y1, table.bbox.y1) if overlap_x0 < overlap_x1 and overlap_y0 < overlap_y1: overlap_area = (overlap_x1 - overlap_x0) * (overlap_y1 - overlap_y0) chart_area = (chart.bbox.x1 - chart.bbox.x0) * (chart.bbox.y1 - chart.bbox.y0) if chart_area > 0: overlap_ratio = overlap_area / chart_area if overlap_ratio >= 0.8: completeness = table_completeness.get(table.element_id, 0.0) # Remove CHART only if TABLE structure is complete if completeness >= 0.5: should_remove = True logger.info( f"Removing CHART {chart.element_id} " f"({overlap_ratio*100:.1f}% overlap with TABLE {table.element_id} having {completeness*100:.1f}% completeness)" ) removed_charts += 1 break if not should_remove: filtered_elements.append(chart) # Process all other elements for elem in elements: if elem.type not in [ElementType.TABLE, ElementType.CHART]: filtered_elements.append(elem) if removed_charts > 0 or removed_tables > 0: logger.info( f"Deduplication complete: removed {removed_tables} incomplete TABLE(s), " f"{removed_charts} overlapping CHART(s)" ) return filtered_elements