Pix2Text / pix2text /table_ocr.py

init

2c67080 about 1 month ago

38.1 kB

	# coding: utf-8
	# Adapted from https://github.com/microsoft/table-transformer/blob/main/src/inference.py
	import os
	import shutil
	from collections import defaultdict, OrderedDict
	from itertools import chain
	from pathlib import Path
	from typing import Union, Optional, Dict, Any
	from copy import deepcopy
	import xml.etree.ElementTree as ET

	import torch
	from torchvision import transforms
	from PIL import Image
	from fitz import Rect
	import numpy as np
	import pandas as pd
	from transformers import AutoModelForObjectDetection

	# from transformers import TableTransformerForObjectDetection

	from .consts import MODEL_VERSION
	from .ocr_engine import TextOcrEngine
	from .utils import (
	select_device,
	data_dir,
	read_img,
	rotated_box_to_horizontal,
	is_valid_box,
	list2box,
	box2list,
	sort_boxes,
	merge_line_texts,
	prepare_model_files2,
	)
	from . import table_postprocess as postprocess


	# detection_class_thresholds = {"table": 0.5, "table rotated": 0.5, "no object": 10}
	DEFAULT_STRUCTURE_THRESHOLDS = {
	"table": 0.5,
	"table column": 0.5,
	"table row": 0.5,
	"table column header": 0.5,
	"table projected row header": 0.5,
	"table spanning cell": 0.5,
	"no object": 10,
	}


	DEFAULT_CONFIGS = {
	'model_dir': None,
	'root': data_dir(),
	'structure_thresholds': DEFAULT_STRUCTURE_THRESHOLDS,
	'table_expansion_margin': 10,
	'threshold_percentage': 0.10,
	}


	class TableOCR(object):
	"""
	Represents a table extractor for extracting tables from a document.
	"""

	def __init__(
	self,
	text_ocr: TextOcrEngine,
	spellchecker=None,
	device: str = None,
	model_dir: Optional[Union[str, Path]] = None,
	root: Union[str, Path] = data_dir(),
	structure_thresholds=None,
	table_expansion_margin=10,
	threshold_percentage=0.10,
	**kwargs,
	):
	"""
	Initialize an TableDataExtractor object.
	"""
	self.text_ocr = text_ocr
	self.spellchecker = spellchecker

	self.str_device = select_device(device)
	self.str_class_name2idx = get_class_map('structure')
	self.str_class_idx2name = {v: k for k, v in self.str_class_name2idx.items()}
	self.str_class_thresholds = structure_thresholds or DEFAULT_STRUCTURE_THRESHOLDS

	if model_dir is None:
	model_dir = self._prepare_model_files(root, None)
	# Initialize the model for identifying table structures
	self.str_model = AutoModelForObjectDetection.from_pretrained(model_dir).to(
	self.str_device
	)
	self.str_model.eval()

	# Expand the bounding box slightly for better cropping
	self._table_expansion_margin = table_expansion_margin

	# Use a percentage (e.g., 10%) of the average height as the threshold for a new row
	self._threshold_percentage = threshold_percentage
	self.test = []

	@classmethod
	def from_config(
	cls,
	text_ocr: TextOcrEngine,
	spellchecker=None,
	configs: Optional[dict] = None,
	device: str = None,
	**kwargs,
	):
	configs = configs or {}
	def_configs = deepcopy(DEFAULT_CONFIGS)
	def_configs.update(configs)
	configs = def_configs
	configs['device'] = select_device(device)

	return cls(
	text_ocr=text_ocr,
	spellchecker=spellchecker,
	device=device,
	model_dir=configs['model_dir'],
	root=configs['root'],
	structure_thresholds=configs['structure_thresholds'],
	table_expansion_margin=configs['table_expansion_margin'],
	threshold_percentage=configs['threshold_percentage'],
	**kwargs,
	)

	def _prepare_model_files(self, root, model_info):
	model_root_dir = Path(root) / MODEL_VERSION
	# model_dir = model_root_dir / model_info['local_model_id']
	model_dir = model_root_dir / 'table-rec'
	if model_dir.is_dir() and list(model_dir.glob('*/[!.]')):
	return model_dir
	model_dir = prepare_model_files2(
	model_fp_or_dir=model_dir,
	remote_repo="breezedeus/pix2text-table-rec",
	file_or_dir="dir",
	)
	return model_dir

	def recognize(
	self,
	img,
	tokens=None,
	out_objects=False,
	out_cells=True,
	out_html=False,
	out_csv=False,
	out_markdown=True,
	**kwargs,
	) -> Dict[str, Any]:
	"""

	Args:
	img ():
	tokens ():
	out_objects ():
	out_cells ():
	out_html ():
	out_csv ():
	out_markdown ():
	**kwargs ():

	* save_analysis_res (str): Save the parsed result image in this file; default value is `None`, which means not to save

	Returns:

	"""
	out_formats = {}
	if self.str_model is None:
	print("No structure model loaded.")
	return out_formats

	if not (out_objects or out_cells or out_html or out_csv):
	print("No output format specified")
	return out_formats

	if isinstance(img, (str, Path)):
	img = read_img(img, return_type='Image')
	# Transform the image how the model expects it
	img_tensor = structure_transform(img)

	# Run input image through the model
	with torch.no_grad():
	outputs = self.str_model(img_tensor.unsqueeze(0).to(self.str_device))

	# Post-process detected objects, assign class labels
	objects = outputs_to_objects(outputs, img.size, self.str_class_idx2name)
	if out_objects:
	out_formats['objects'] = objects
	if not (out_cells or out_html or out_csv):
	return out_formats

	# Further process the detected objects so they correspond to a consistent table
	tokens = tokens or []
	tables_structure = objects_to_structures(
	objects, tokens, self.str_class_thresholds
	)

	# Enumerate all table cells: grid cells and spanning cells
	tables_cells = [
	structure_to_cells(structure, tokens)[0] for structure in tables_structure
	]
	for cells in tables_cells:
	self._ocr_texts(img, cells)
	if out_cells:
	out_formats['cells'] = tables_cells
	if kwargs.get('save_analysis_res'):
	visualize_cells(img, tables_cells[0], kwargs['save_analysis_res'])

	if not (out_html or out_csv):
	return out_formats

	# Convert cells to HTML
	if out_html:
	tables_htmls = [cells_to_html(cells) for cells in tables_cells]
	out_formats['html'] = tables_htmls

	# Convert cells to CSV, including flattening multi-row column headers to a single row
	if out_csv:
	tables_csvs = [cells_to_csv(cells) for cells in tables_cells]
	out_formats['csv'] = tables_csvs

	if out_markdown:
	tables_mds = [cells_to_markdown(cells) for cells in tables_cells]
	out_formats['markdown'] = tables_mds

	return out_formats

	def _ocr_texts(self, img: Image.Image, cells):
	text_box_infos = self.text_ocr.detect_only(np.array(img))
	box_infos = []
	for line_box_info in text_box_infos['detected_texts']:
	_text_box = rotated_box_to_horizontal(line_box_info['position'])
	if not is_valid_box(_text_box, min_height=8, min_width=2):
	continue
	box_infos.append({'position': _text_box})
	for t_cell in cells:
	table_box = t_cell['bbox']
	inner_text_boxes = []
	for box_info in box_infos:
	_pos = box_info['position']
	text_box = [_pos[0][0], _pos[0][1], _pos[2][0], _pos[2][1]]
	inner_box = list2box(*cut_bbox(table_box, text_box))
	if is_valid_box(inner_box):
	inner_text_boxes.append({'position': inner_box})
	if inner_text_boxes:
	for _box_info in inner_text_boxes:
	_box = box2list(_box_info['position'])
	ocr_out = self.text_ocr.recognize_only(np.array(img.crop(_box)))
	_box_info['text'] = ocr_out['text']
	_box_info['type'] = 'text'
	outs = sort_boxes(inner_text_boxes, key='position')
	t_cell['text_bboxes'] = outs
	outs = list(chain(*outs))
	t_cell['cell text'] = merge_line_texts(
	outs,
	auto_line_break=True,
	line_sep=' ',
	spellchecker=self.spellchecker,
	)


	def cut_bbox(anchor_box, box2):
	# x1, y1, x2, y2
	x1 = max(anchor_box[0], box2[0])
	y1 = max(anchor_box[1], box2[1])
	x2 = min(anchor_box[2], box2[2])
	y2 = min(anchor_box[3], box2[3])
	return x1, y1, x2, y2


	class MaxResize(object):
	def __init__(self, max_size=800):
	self.max_size = max_size

	def __call__(self, image):
	width, height = image.size
	current_max_size = max(width, height)
	scale = self.max_size / current_max_size
	resized_image = image.resize(
	(int(round(scale * width)), int(round(scale * height)))
	)

	return resized_image


	def get_class_map(data_type):
	class_map = {}
	if data_type == 'structure':
	class_map = {
	'table': 0,
	'table column': 1,
	'table row': 2,
	'table column header': 3,
	'table projected row header': 4,
	'table spanning cell': 5,
	'no object': 6,
	}
	elif data_type == 'detection':
	class_map = {'table': 0, 'table rotated': 1, 'no object': 2}
	return class_map


	detection_transform = transforms.Compose(
	[
	MaxResize(800),
	transforms.ToTensor(),
	transforms.Normalize([0.485, 0.456, 0.406], [0.229, 0.224, 0.225]),
	]
	)

	structure_transform = transforms.Compose(
	[
	MaxResize(1000),
	transforms.ToTensor(),
	transforms.Normalize([0.485, 0.456, 0.406], [0.229, 0.224, 0.225]),
	]
	)


	def box_cxcywh_to_xyxy(x):
	x_c, y_c, w, h = x.unbind(-1)
	b = [(x_c - 0.5 * w), (y_c - 0.5 * h), (x_c + 0.5 * w), (y_c + 0.5 * h)]
	return torch.stack(b, dim=1)


	def rescale_bboxes(out_bbox, size):
	img_w, img_h = size
	b = box_cxcywh_to_xyxy(out_bbox)
	b = b * torch.tensor([img_w, img_h, img_w, img_h], dtype=torch.float32)
	return b


	def iob(bbox1, bbox2):
	"""
	Compute the intersection area over box area, for bbox1.
	"""
	intersection = Rect(bbox1).intersect(bbox2)

	bbox1_area = Rect(bbox1).get_area()
	if bbox1_area > 0:
	return intersection.get_area() / bbox1_area

	return 0


	def align_headers(headers, rows):
	"""
	Adjust the header boundary to be the convex hull of the rows it intersects
	at least 50% of the height of.

	For now, we are not supporting tables with multiple headers, so we need to
	eliminate anything besides the top-most header.
	"""

	aligned_headers = []

	for row in rows:
	row['column header'] = False

	header_row_nums = []
	for header in headers:
	for row_num, row in enumerate(rows):
	row_height = row['bbox'][3] - row['bbox'][1]
	min_row_overlap = max(row['bbox'][1], header['bbox'][1])
	max_row_overlap = min(row['bbox'][3], header['bbox'][3])
	overlap_height = max_row_overlap - min_row_overlap
	if overlap_height / row_height >= 0.5:
	header_row_nums.append(row_num)

	if len(header_row_nums) == 0:
	return aligned_headers

	header_rect = Rect()
	if header_row_nums[0] > 0:
	header_row_nums = list(range(header_row_nums[0] + 1)) + header_row_nums

	last_row_num = -1
	for row_num in header_row_nums:
	if row_num == last_row_num + 1:
	row = rows[row_num]
	row['column header'] = True
	header_rect = header_rect.include_rect(row['bbox'])
	last_row_num = row_num
	else:
	# Break as soon as a non-header row is encountered.
	# This ignores any subsequent rows in the table labeled as a header.
	# Having more than 1 header is not supported currently.
	break

	header = {'bbox': list(header_rect)}
	aligned_headers.append(header)

	return aligned_headers


	def refine_table_structure(table_structure, class_thresholds):
	"""
	Apply operations to the detected table structure objects such as
	thresholding, NMS, and alignment.
	"""
	rows = table_structure["rows"]
	columns = table_structure['columns']

	# Process the headers
	column_headers = table_structure['column headers']
	column_headers = postprocess.apply_threshold(
	column_headers, class_thresholds["table column header"]
	)
	column_headers = postprocess.nms(column_headers)
	column_headers = align_headers(column_headers, rows)

	# Process spanning cells
	spanning_cells = [
	elem
	for elem in table_structure['spanning cells']
	if not elem['projected row header']
	]
	projected_row_headers = [
	elem
	for elem in table_structure['spanning cells']
	if elem['projected row header']
	]
	spanning_cells = postprocess.apply_threshold(
	spanning_cells, class_thresholds["table spanning cell"]
	)
	projected_row_headers = postprocess.apply_threshold(
	projected_row_headers, class_thresholds["table projected row header"]
	)
	spanning_cells += projected_row_headers
	# Align before NMS for spanning cells because alignment brings them into agreement
	# with rows and columns first; if spanning cells still overlap after this operation,
	# the threshold for NMS can basically be lowered to just above 0
	spanning_cells = postprocess.align_supercells(spanning_cells, rows, columns)
	spanning_cells = postprocess.nms_supercells(spanning_cells)

	postprocess.header_supercell_tree(spanning_cells)

	table_structure['columns'] = columns
	table_structure['rows'] = rows
	table_structure['spanning cells'] = spanning_cells
	table_structure['column headers'] = column_headers

	return table_structure


	def outputs_to_objects(outputs, img_size, class_idx2name):
	m = outputs['logits'].softmax(-1).max(-1)
	pred_labels = list(m.indices.detach().cpu().numpy())[0]
	pred_scores = list(m.values.detach().cpu().numpy())[0]
	pred_bboxes = outputs['pred_boxes'].detach().cpu()[0]
	pred_bboxes = [elem.tolist() for elem in rescale_bboxes(pred_bboxes, img_size)]

	objects = []
	for label, score, bbox in zip(pred_labels, pred_scores, pred_bboxes):
	class_label = class_idx2name[int(label)]
	if not class_label == 'no object':
	objects.append(
	{
	'label': class_label,
	'score': float(score),
	'bbox': [float(elem) for elem in bbox],
	}
	)

	return objects


	def objects_to_crops(img, tokens, objects, class_thresholds, padding=10):
	"""
	Process the bounding boxes produced by the table detection model into
	cropped table images and cropped tokens.
	"""

	table_crops = []
	for obj in objects:
	if obj['score'] < class_thresholds[obj['label']]:
	continue

	cropped_table = {}

	bbox = obj['bbox']
	bbox = [
	bbox[0] - padding,
	bbox[1] - padding,
	bbox[2] + padding,
	bbox[3] + padding,
	]

	cropped_img = img.crop(bbox)

	table_tokens = [token for token in tokens if iob(token['bbox'], bbox) >= 0.5]
	for token in table_tokens:
	token['bbox'] = [
	token['bbox'][0] - bbox[0],
	token['bbox'][1] - bbox[1],
	token['bbox'][2] - bbox[0],
	token['bbox'][3] - bbox[1],
	]

	# If table is predicted to be rotated, rotate cropped image and tokens/words:
	if obj['label'] == 'table rotated':
	cropped_img = cropped_img.rotate(270, expand=True)
	for token in table_tokens:
	bbox = token['bbox']
	bbox = [
	cropped_img.size[0] - bbox[3] - 1,
	bbox[0],
	cropped_img.size[0] - bbox[1] - 1,
	bbox[2],
	]
	token['bbox'] = bbox

	cropped_table['image'] = cropped_img
	cropped_table['tokens'] = table_tokens

	table_crops.append(cropped_table)

	return table_crops


	def objects_to_structures(objects, tokens, class_thresholds):
	"""
	Process the bounding boxes produced by the table structure recognition model into
	a consistent set of table structures (rows, columns, spanning cells, headers).
	This entails resolving conflicts/overlaps, and ensuring the boxes meet certain alignment
	conditions (for example: rows should all have the same width, etc.).
	"""

	tables = [obj for obj in objects if obj['label'] == 'table']
	table_structures = []

	for table in tables:
	table_objects = [
	obj for obj in objects if iob(obj['bbox'], table['bbox']) >= 0.5
	]
	table_tokens = [
	token for token in tokens if iob(token['bbox'], table['bbox']) >= 0.5
	]

	structure = {}

	columns = [obj for obj in table_objects if obj['label'] == 'table column']
	rows = [obj for obj in table_objects if obj['label'] == 'table row']
	column_headers = [
	obj for obj in table_objects if obj['label'] == 'table column header'
	]
	spanning_cells = [
	obj for obj in table_objects if obj['label'] == 'table spanning cell'
	]
	for obj in spanning_cells:
	obj['projected row header'] = False
	projected_row_headers = [
	obj for obj in table_objects if obj['label'] == 'table projected row header'
	]
	for obj in projected_row_headers:
	obj['projected row header'] = True
	spanning_cells += projected_row_headers
	for obj in rows:
	obj['column header'] = False
	for header_obj in column_headers:
	if iob(obj['bbox'], header_obj['bbox']) >= 0.5:
	obj['column header'] = True

	# Refine table structures
	rows = postprocess.refine_rows(
	rows, table_tokens, class_thresholds['table row']
	)
	columns = postprocess.refine_columns(
	columns, table_tokens, class_thresholds['table column']
	)

	# Shrink table bbox to just the total height of the rows
	# and the total width of the columns
	row_rect = Rect()
	for obj in rows:
	row_rect.include_rect(obj['bbox'])
	column_rect = Rect()
	for obj in columns:
	column_rect.include_rect(obj['bbox'])
	table['row_column_bbox'] = [
	column_rect[0],
	row_rect[1],
	column_rect[2],
	row_rect[3],
	]
	table['bbox'] = table['row_column_bbox']

	# Process the rows and columns into a complete segmented table
	columns = postprocess.align_columns(columns, table['row_column_bbox'])
	rows = postprocess.align_rows(rows, table['row_column_bbox'])

	structure['rows'] = rows
	structure['columns'] = columns
	structure['column headers'] = column_headers
	structure['spanning cells'] = spanning_cells

	if len(rows) > 0 and len(columns) > 1:
	structure = refine_table_structure(structure, class_thresholds)

	table_structures.append(structure)

	return table_structures


	def structure_to_cells(table_structure, tokens):
	"""
	Assuming the row, column, spanning cell, and header bounding boxes have
	been refined into a set of consistent table structures, process these
	table structures into table cells. This is a universal representation
	format for the table, which can later be exported to Pandas or CSV formats.
	Classify the cells as header/access cells or data cells
	based on if they intersect with the header bounding box.
	"""
	columns = table_structure['columns']
	rows = table_structure['rows']
	spanning_cells = table_structure['spanning cells']
	cells = []
	subcells = []

	# Identify complete cells and subcells
	for column_num, column in enumerate(columns):
	for row_num, row in enumerate(rows):
	column_rect = Rect(list(column['bbox']))
	row_rect = Rect(list(row['bbox']))
	cell_rect = row_rect.intersect(column_rect)
	header = 'column header' in row and row['column header']
	cell = {
	'bbox': list(cell_rect),
	'column_nums': [column_num],
	'row_nums': [row_num],
	'column header': header,
	}

	cell['subcell'] = False
	for spanning_cell in spanning_cells:
	spanning_cell_rect = Rect(list(spanning_cell['bbox']))
	if (
	spanning_cell_rect.intersect(cell_rect).get_area()
	/ cell_rect.get_area()
	) > 0.5:
	cell['subcell'] = True
	break

	if cell['subcell']:
	subcells.append(cell)
	else:
	# cell text = extract_text_inside_bbox(table_spans, cell['bbox'])
	# cell['cell text'] = cell text
	cell['projected row header'] = False
	cells.append(cell)

	for spanning_cell in spanning_cells:
	spanning_cell_rect = Rect(list(spanning_cell['bbox']))
	cell_columns = set()
	cell_rows = set()
	cell_rect = None
	header = True
	for subcell in subcells:
	subcell_rect = Rect(list(subcell['bbox']))
	subcell_rect_area = subcell_rect.get_area()
	if (
	subcell_rect.intersect(spanning_cell_rect).get_area()
	/ subcell_rect_area
	) > 0.5:
	if cell_rect is None:
	cell_rect = Rect(list(subcell['bbox']))
	else:
	cell_rect.include_rect(Rect(list(subcell['bbox'])))
	cell_rows = cell_rows.union(set(subcell['row_nums']))
	cell_columns = cell_columns.union(set(subcell['column_nums']))
	# By convention here, all subcells must be classified
	# as header cells for a spanning cell to be classified as a header cell;
	# otherwise, this could lead to a non-rectangular header region
	header = (
	header and 'column header' in subcell and subcell['column header']
	)
	if len(cell_rows) > 0 and len(cell_columns) > 0:
	cell = {
	'bbox': list(cell_rect),
	'column_nums': list(cell_columns),
	'row_nums': list(cell_rows),
	'column header': header,
	'projected row header': spanning_cell['projected row header'],
	}
	cells.append(cell)

	# Compute a confidence score based on how well the page tokens
	# slot into the cells reported by the model
	_, _, cell_match_scores = postprocess.slot_into_containers(cells, tokens)
	try:
	mean_match_score = sum(cell_match_scores) / len(cell_match_scores)
	min_match_score = min(cell_match_scores)
	confidence_score = (mean_match_score + min_match_score) / 2
	except:
	confidence_score = 0

	# Dilate rows and columns before final extraction
	# dilated_columns = fill_column_gaps(columns, table_bbox)
	dilated_columns = columns
	# dilated_rows = fill_row_gaps(rows, table_bbox)
	dilated_rows = rows
	for cell in cells:
	column_rect = Rect()
	for column_num in cell['column_nums']:
	column_rect.include_rect(list(dilated_columns[column_num]['bbox']))
	row_rect = Rect()
	for row_num in cell['row_nums']:
	row_rect.include_rect(list(dilated_rows[row_num]['bbox']))
	cell_rect = column_rect.intersect(row_rect)
	cell['bbox'] = list(cell_rect)

	span_nums_by_cell, _, _ = postprocess.slot_into_containers(
	cells,
	tokens,
	overlap_threshold=0.001,
	unique_assignment=True,
	forced_assignment=False,
	)

	for cell, cell_span_nums in zip(cells, span_nums_by_cell):
	cell_spans = [tokens[num] for num in cell_span_nums]
	# TODO: Refine how text is extracted; should be character-based, not span-based;
	# but need to associate
	cell['cell text'] = postprocess.extract_text_from_spans(
	cell_spans, remove_integer_superscripts=False
	)
	cell['spans'] = cell_spans

	# Adjust the row, column, and cell bounding boxes to reflect the extracted text
	num_rows = len(rows)
	rows = postprocess.sort_objects_top_to_bottom(rows)
	num_columns = len(columns)
	columns = postprocess.sort_objects_left_to_right(columns)
	min_y_values_by_row = defaultdict(list)
	max_y_values_by_row = defaultdict(list)
	min_x_values_by_column = defaultdict(list)
	max_x_values_by_column = defaultdict(list)
	for cell in cells:
	min_row = min(cell["row_nums"])
	max_row = max(cell["row_nums"])
	min_column = min(cell["column_nums"])
	max_column = max(cell["column_nums"])
	for span in cell['spans']:
	min_x_values_by_column[min_column].append(span['bbox'][0])
	min_y_values_by_row[min_row].append(span['bbox'][1])
	max_x_values_by_column[max_column].append(span['bbox'][2])
	max_y_values_by_row[max_row].append(span['bbox'][3])
	for row_num, row in enumerate(rows):
	if len(min_x_values_by_column[0]) > 0:
	row['bbox'][0] = min(min_x_values_by_column[0])
	if len(min_y_values_by_row[row_num]) > 0:
	row['bbox'][1] = min(min_y_values_by_row[row_num])
	if len(max_x_values_by_column[num_columns - 1]) > 0:
	row['bbox'][2] = max(max_x_values_by_column[num_columns - 1])
	if len(max_y_values_by_row[row_num]) > 0:
	row['bbox'][3] = max(max_y_values_by_row[row_num])
	for column_num, column in enumerate(columns):
	if len(min_x_values_by_column[column_num]) > 0:
	column['bbox'][0] = min(min_x_values_by_column[column_num])
	if len(min_y_values_by_row[0]) > 0:
	column['bbox'][1] = min(min_y_values_by_row[0])
	if len(max_x_values_by_column[column_num]) > 0:
	column['bbox'][2] = max(max_x_values_by_column[column_num])
	if len(max_y_values_by_row[num_rows - 1]) > 0:
	column['bbox'][3] = max(max_y_values_by_row[num_rows - 1])
	for cell in cells:
	row_rect = Rect()
	column_rect = Rect()
	for row_num in cell['row_nums']:
	row_rect.include_rect(list(rows[row_num]['bbox']))
	for column_num in cell['column_nums']:
	column_rect.include_rect(list(columns[column_num]['bbox']))
	cell_rect = row_rect.intersect(column_rect)
	if cell_rect.get_area() > 0:
	cell['bbox'] = list(cell_rect)
	pass

	return cells, confidence_score


	def cells_to_csv(cells):
	if len(cells) > 0:
	num_columns = max([max(cell['column_nums']) for cell in cells]) + 1
	num_rows = max([max(cell['row_nums']) for cell in cells]) + 1
	else:
	return

	header_cells = [cell for cell in cells if cell['column header']]
	if len(header_cells) > 0:
	max_header_row = max([max(cell['row_nums']) for cell in header_cells])
	else:
	max_header_row = -1

	table_array = np.empty([num_rows, num_columns], dtype="object")
	if len(cells) > 0:
	for cell in cells:
	for row_num in cell['row_nums']:
	for column_num in cell['column_nums']:
	table_array[row_num, column_num] = cell["cell text"]

	header = table_array[: max_header_row + 1, :]
	flattened_header = []
	for col in header.transpose():
	flattened_header.append(' \| '.join(OrderedDict.fromkeys(col)))
	df = pd.DataFrame(
	table_array[max_header_row + 1 :, :], index=None, columns=flattened_header
	)

	return df.to_csv(index=None)


	def cells_to_ET(cells):
	cells = sorted(cells, key=lambda k: min(k['column_nums']))
	cells = sorted(cells, key=lambda k: min(k['row_nums']))

	table = ET.Element("table")
	current_row = -1

	for cell in cells:
	this_row = min(cell['row_nums'])

	attrib = {}
	colspan = len(cell['column_nums'])
	if colspan > 1:
	attrib['colspan'] = str(colspan)
	rowspan = len(cell['row_nums'])
	if rowspan > 1:
	attrib['rowspan'] = str(rowspan)
	if this_row > current_row:
	current_row = this_row
	if cell['column header']:
	cell_tag = "th"
	row = ET.SubElement(table, "thead")
	else:
	cell_tag = "td"
	row = ET.SubElement(table, "tr")
	tcell = ET.SubElement(row, cell_tag, attrib=attrib)
	tcell.text = cell['cell text']
	return table


	def cells_to_html(cells):
	table = cells_to_ET(cells)
	return str(ET.tostring(table, encoding="unicode", short_empty_elements=False))


	def cells_to_markdown(cells):
	table = cells_to_ET(cells)
	return etree_to_markdown_table(table)


	def etree_to_markdown_table(etree):
	"""
	将XML ElementTree对象转换为Markdown格式的表格。

	Args:
	etree (xml.etree.ElementTree.Element): XML表格的根元素。

	Returns:
	str: Markdown格式的表格字符串。
	"""
	if etree.tag != 'table':
	return "Invalid XML input: root element is not a table."

	markdown_table = []
	headers = [th.text for th in etree.findall('.//th')]

	if headers:
	markdown_table.append("\| " + " \| ".join(headers) + " \|")
	markdown_table.append("\| " + " \| ".join(["---"] * len(headers)) + " \|")

	rows = etree.findall('.//tr')
	if rows:
	for row in rows:
	cells = [td.text.replace('\n', ' ') for td in row.findall('td')]
	if not cells:
	continue
	markdown_table.append("\| " + " \| ".join(cells) + " \|")
	else:
	return "Invalid XML input: no rows found."

	return "\n".join(markdown_table)


	def visualize_detected_tables(img, det_tables, out_path):
	import matplotlib.pyplot as plt
	import matplotlib.patches as patches
	from matplotlib.patches import Patch

	plt.imshow(img, interpolation="lanczos")
	plt.gcf().set_size_inches(20, 20)
	ax = plt.gca()

	for det_table in det_tables:
	bbox = det_table['bbox']

	if det_table['label'] == 'table':
	facecolor = (1, 0, 0.45)
	edgecolor = (1, 0, 0.45)
	alpha = 0.3
	linewidth = 2
	hatch = '//////'
	elif det_table['label'] == 'table rotated':
	facecolor = (0.95, 0.6, 0.1)
	edgecolor = (0.95, 0.6, 0.1)
	alpha = 0.3
	linewidth = 2
	hatch = '//////'
	else:
	continue

	rect = patches.Rectangle(
	bbox[:2],
	bbox[2] - bbox[0],
	bbox[3] - bbox[1],
	linewidth=linewidth,
	edgecolor='none',
	facecolor=facecolor,
	alpha=0.1,
	)
	ax.add_patch(rect)
	rect = patches.Rectangle(
	bbox[:2],
	bbox[2] - bbox[0],
	bbox[3] - bbox[1],
	linewidth=linewidth,
	edgecolor=edgecolor,
	facecolor='none',
	linestyle='-',
	alpha=alpha,
	)
	ax.add_patch(rect)
	rect = patches.Rectangle(
	bbox[:2],
	bbox[2] - bbox[0],
	bbox[3] - bbox[1],
	linewidth=0,
	edgecolor=edgecolor,
	facecolor='none',
	linestyle='-',
	hatch=hatch,
	alpha=0.2,
	)
	ax.add_patch(rect)

	plt.xticks([], [])
	plt.yticks([], [])

	legend_elements = [
	Patch(
	facecolor=(1, 0, 0.45),
	edgecolor=(1, 0, 0.45),
	label='Table',
	hatch='//////',
	alpha=0.3,
	),
	Patch(
	facecolor=(0.95, 0.6, 0.1),
	edgecolor=(0.95, 0.6, 0.1),
	label='Table (rotated)',
	hatch='//////',
	alpha=0.3,
	),
	]
	plt.legend(
	handles=legend_elements,
	bbox_to_anchor=(0.5, -0.02),
	loc='upper center',
	borderaxespad=0,
	fontsize=10,
	ncol=2,
	)
	plt.gcf().set_size_inches(10, 10)
	plt.axis('off')
	plt.savefig(out_path, bbox_inches='tight', dpi=150)
	plt.close()

	return


	def visualize_cells(img, cells, out_path):
	import matplotlib.pyplot as plt
	import matplotlib.patches as patches
	from matplotlib.patches import Patch

	plt.imshow(img, interpolation="lanczos")
	plt.gcf().set_size_inches(20, 20)
	ax = plt.gca()

	for cell in cells:
	bbox = cell['bbox']

	if cell['column header']:
	facecolor = (1, 0, 0.45)
	edgecolor = (1, 0, 0.45)
	alpha = 0.3
	linewidth = 2
	hatch = '//////'
	elif cell['projected row header']:
	facecolor = (0.95, 0.6, 0.1)
	edgecolor = (0.95, 0.6, 0.1)
	alpha = 0.3
	linewidth = 2
	hatch = '//////'
	else:
	facecolor = (0.3, 0.74, 0.8)
	edgecolor = (0.3, 0.7, 0.6)
	alpha = 0.3
	linewidth = 2
	hatch = '\\\\\\\\\\\\'

	rect = patches.Rectangle(
	bbox[:2],
	bbox[2] - bbox[0],
	bbox[3] - bbox[1],
	linewidth=linewidth,
	edgecolor='none',
	facecolor=facecolor,
	alpha=0.1,
	)
	ax.add_patch(rect)
	rect = patches.Rectangle(
	bbox[:2],
	bbox[2] - bbox[0],
	bbox[3] - bbox[1],
	linewidth=linewidth,
	edgecolor=edgecolor,
	facecolor='none',
	linestyle='-',
	alpha=alpha,
	)
	ax.add_patch(rect)
	rect = patches.Rectangle(
	bbox[:2],
	bbox[2] - bbox[0],
	bbox[3] - bbox[1],
	linewidth=0,
	edgecolor=edgecolor,
	facecolor='none',
	linestyle='-',
	hatch=hatch,
	alpha=0.2,
	)
	ax.add_patch(rect)

	plt.xticks([], [])
	plt.yticks([], [])

	legend_elements = [
	Patch(
	facecolor=(0.3, 0.74, 0.8),
	edgecolor=(0.3, 0.7, 0.6),
	label='Data cell',
	hatch='\\\\\\\\\\\\',
	alpha=0.3,
	),
	Patch(
	facecolor=(1, 0, 0.45),
	edgecolor=(1, 0, 0.45),
	label='Column header cell',
	hatch='//////',
	alpha=0.3,
	),
	Patch(
	facecolor=(0.95, 0.6, 0.1),
	edgecolor=(0.95, 0.6, 0.1),
	label='Projected row header cell',
	hatch='//////',
	alpha=0.3,
	),
	]
	plt.legend(
	handles=legend_elements,
	bbox_to_anchor=(0.5, -0.02),
	loc='upper center',
	borderaxespad=0,
	fontsize=10,
	ncol=3,
	)
	plt.gcf().set_size_inches(10, 10)
	plt.axis('off')
	plt.savefig(out_path, bbox_inches='tight', dpi=150)
	plt.close()

	return


	def output_result(key, val, args, img, img_file):
	import json

	if key == 'objects':
	# if args.verbose:
	# print(val)
	out_file = img_file.replace(".jpg", "_objects.json")
	with open(os.path.join(args.out_dir, out_file), 'w', encoding='utf-8') as f:
	json.dump(val, f)
	# if args.visualize:
	# out_file = img_file.replace(".jpg", "_fig_tables.jpg")
	# out_path = os.path.join(args.out_dir, out_file)
	# visualize_detected_tables(img, val, out_path)
	elif not key == 'image' and not key == 'tokens':
	for idx, elem in enumerate(val):
	if key == 'crops':
	for idx, cropped_table in enumerate(val):
	out_img_file = img_file.replace(".jpg", "_table_{}.jpg".format(idx))
	cropped_table['image'].save(
	os.path.join(args.out_dir, out_img_file)
	)
	out_words_file = out_img_file.replace(".jpg", "_words.json")
	with open(os.path.join(args.out_dir, out_words_file), 'w', encoding='utf-8') as f:
	json.dump(cropped_table['tokens'], f)
	elif key == 'cells':
	out_file = img_file.replace(".jpg", "_{}_objects.json".format(idx))
	with open(os.path.join(args.out_dir, out_file), 'w', encoding='utf-8') as f:
	json.dump(elem, f)
	# if args.verbose:
	# print(elem)
	if True:
	out_file = img_file.replace(".jpg", "_fig_cells.jpg")
	out_path = os.path.join(args.out_dir, out_file)
	visualize_cells(img, elem, out_path)
	else:
	out_file = img_file.replace(".jpg", "_{}.{}".format(idx, key))
	with open(os.path.join(args.out_dir, out_file), 'w', encoding='utf-8') as f:
	f.write(elem)
	if args.verbose:
	print(elem)