#!/usr/bin/env python3
from __future__ import annotations
import argparse
import html
import json
import os
import time
from dataclasses import dataclass
from pathlib import Path
from typing import Any, Dict, Iterable, List, Optional, Sequence, Tuple
import fitz
import numpy as np
from PIL import Image, ImageDraw
MIN_NATIVE_SPAN_COUNT = 24
@dataclass
class StyledFragment:
text: str
bbox: Tuple[float, float, float, float]
font: str
flags: int
size: float
bold: bool
italic: bool
underline: bool
def to_payload(self) -> Dict[str, Any]:
return {
"text": self.text,
"bbox": [round(value, 2) for value in self.bbox],
"font": self.font,
"flags": int(self.flags),
"size": round(float(self.size), 2),
"bold": bool(self.bold),
"italic": bool(self.italic),
"underline": bool(self.underline),
}
@dataclass
class RowGroup:
cy: float
items: List[StyledFragment]
@property
def bbox(self) -> Tuple[float, float, float, float]:
return union_bbox(item.bbox for item in self.items)
def to_payload(self) -> Dict[str, Any]:
return {
"bbox": [round(value, 2) for value in self.bbox],
"text": " | ".join(item.text for item in self.items),
"fragments": [item.to_payload() for item in self.items],
}
@dataclass
class TableCandidate:
rect: Tuple[float, float, float, float]
source: str
score: float
rows: List[RowGroup]
def to_payload(self) -> Dict[str, Any]:
return {
"bbox": [round(value, 2) for value in self.rect],
"source": self.source,
"score": round(float(self.score), 2),
"row_count": len(self.rows),
"fragment_count": sum(len(row.items) for row in self.rows),
"rows": [row.to_payload() for row in self.rows],
}
@dataclass
class TableCellCandidate:
row: int
col: int
rowspan: int
colspan: int
bbox: Tuple[float, float, float, float]
text: str
html: str
header: bool
bold: bool
italic: bool
underline: bool
def to_payload(self) -> Dict[str, Any]:
return {
"row": int(self.row),
"col": int(self.col),
"rowspan": int(self.rowspan),
"colspan": int(self.colspan),
"bbox": [round(value, 2) for value in self.bbox],
"text": self.text,
"html": self.html,
"header": bool(self.header),
"bold": bool(self.bold),
"italic": bool(self.italic),
"underline": bool(self.underline),
}
@dataclass
class RasterCandidate:
rect: Tuple[float, float, float, float]
score: float
row_count: int
avg_components_per_row: float
text_density: float
line_density: float
def to_payload(self) -> Dict[str, Any]:
return {
"bbox": [round(value, 2) for value in self.rect],
"score": round(float(self.score), 2),
"row_count": int(self.row_count),
"avg_components_per_row": round(float(self.avg_components_per_row), 2),
"text_density": round(float(self.text_density), 4),
"line_density": round(float(self.line_density), 4),
}
def union_bbox(boxes: Iterable[Sequence[float]]) -> Tuple[float, float, float, float]:
points = [tuple(float(value) for value in box) for box in boxes]
if not points:
return (0.0, 0.0, 0.0, 0.0)
return (
min(box[0] for box in points),
min(box[1] for box in points),
max(box[2] for box in points),
max(box[3] for box in points),
)
def bbox_iou(box_a: Sequence[float], box_b: Sequence[float]) -> float:
left = max(float(box_a[0]), float(box_b[0]))
top = max(float(box_a[1]), float(box_b[1]))
right = min(float(box_a[2]), float(box_b[2]))
bottom = min(float(box_a[3]), float(box_b[3]))
inter_w = max(0.0, right - left)
inter_h = max(0.0, bottom - top)
inter_area = inter_w * inter_h
area_a = max(0.0, float(box_a[2]) - float(box_a[0])) * max(0.0, float(box_a[3]) - float(box_a[1]))
area_b = max(0.0, float(box_b[2]) - float(box_b[0])) * max(0.0, float(box_b[3]) - float(box_b[1]))
union = max(1e-6, area_a + area_b - inter_area)
return inter_area / union
def width(box: Sequence[float]) -> float:
return max(0.0, float(box[2]) - float(box[0]))
def height(box: Sequence[float]) -> float:
return max(0.0, float(box[3]) - float(box[1]))
def center_y(box: Sequence[float]) -> float:
return (float(box[1]) + float(box[3])) / 2.0
def center_x(box: Sequence[float]) -> float:
return (float(box[0]) + float(box[2])) / 2.0
def is_numeric_like(text: str) -> bool:
normalized = str(text or "").strip()
if not normalized:
return False
return any(char.isdigit() for char in normalized)
def is_bold(font_name: str, flags: int) -> bool:
font_name = str(font_name or "").lower()
return "bold" in font_name or bool(int(flags or 0) & 16)
def is_italic(font_name: str, flags: int) -> bool:
font_name = str(font_name or "").lower()
return "italic" in font_name or "oblique" in font_name or bool(int(flags or 0) & 2)
def extract_horizontal_line_boxes(page: fitz.Page) -> List[Tuple[float, float, float, float]]:
line_boxes: List[Tuple[float, float, float, float]] = []
for drawing in page.get_drawings():
rect = drawing.get("rect")
if rect is None:
continue
if rect.width <= 0 or rect.height > 2.5:
continue
line_boxes.append((rect.x0, rect.y0, rect.x1, rect.y1))
return line_boxes
def span_has_underline(
bbox: Sequence[float],
*,
line_boxes: Sequence[Sequence[float]],
) -> bool:
span_left, _span_top, span_right, span_bottom = (float(value) for value in bbox)
span_width = max(1.0, span_right - span_left)
for line_box in line_boxes:
line_left, line_top, line_right, line_bottom = (float(value) for value in line_box)
overlap = max(0.0, min(span_right, line_right) - max(span_left, line_left))
if overlap < (0.60 * span_width):
continue
if abs(line_top - span_bottom) <= 2.5 or abs(line_bottom - span_bottom) <= 2.5:
return True
return False
def extract_styled_fragments(page: fitz.Page) -> List[StyledFragment]:
rawdict = page.get_text("rawdict")
line_boxes = extract_horizontal_line_boxes(page)
fragments: List[StyledFragment] = []
for block in rawdict.get("blocks", []):
for line in block.get("lines", []):
for span in line.get("spans", []):
text = "".join(char.get("c", "") for char in span.get("chars", [])).strip()
if not text:
continue
bbox = tuple(float(value) for value in span.get("bbox", (0, 0, 0, 0)))
font = str(span.get("font") or "")
flags = int(span.get("flags") or 0)
fragments.append(
StyledFragment(
text=text,
bbox=bbox,
font=font,
flags=flags,
size=float(span.get("size") or 0.0),
bold=is_bold(font, flags),
italic=is_italic(font, flags),
underline=span_has_underline(bbox, line_boxes=line_boxes),
)
)
return fragments
def extract_layout_fragments(page: fitz.Page) -> List[StyledFragment]:
words = page.get_text("words", sort=True)
grouped_words: Dict[Tuple[int, int], List[Tuple[float, float, float, float, str]]] = {}
for word in words:
if len(word) < 8:
continue
x0, y0, x1, y1, text, block_no, line_no, _word_no = word[:8]
normalized_text = str(text or "").strip()
if not normalized_text:
continue
grouped_words.setdefault((int(block_no), int(line_no)), []).append(
(float(x0), float(y0), float(x1), float(y1), normalized_text)
)
fragments: List[StyledFragment] = []
for _line_key, line_words in sorted(grouped_words.items(), key=lambda item: (item[0][0], item[0][1])):
current_texts: List[str] = []
current_boxes: List[Tuple[float, float, float, float]] = []
previous_right: Optional[float] = None
current_height = 0.0
for x0, y0, x1, y1, text in sorted(line_words, key=lambda item: item[0]):
box = (x0, y0, x1, y1)
box_height = height(box)
gap = float("inf") if previous_right is None else max(0.0, x0 - previous_right)
merge_gap = max(8.0, current_height * 0.45, box_height * 0.45)
if current_texts and gap > merge_gap:
merged_box = union_bbox(current_boxes)
fragments.append(
StyledFragment(
text=" ".join(current_texts),
bbox=merged_box,
font="",
flags=0,
size=max(current_height, 0.0),
bold=False,
italic=False,
underline=False,
)
)
current_texts = []
current_boxes = []
current_height = 0.0
current_texts.append(text)
current_boxes.append(box)
current_height = max(current_height, box_height)
previous_right = x1
if current_texts:
merged_box = union_bbox(current_boxes)
fragments.append(
StyledFragment(
text=" ".join(current_texts),
bbox=merged_box,
font="",
flags=0,
size=max(current_height, 0.0),
bold=False,
italic=False,
underline=False,
)
)
return fragments
def group_rows(items: Sequence[StyledFragment], *, y_tolerance: float = 3.5) -> List[RowGroup]:
rows: List[RowGroup] = []
for item in sorted(items, key=lambda fragment: (center_y(fragment.bbox), fragment.bbox[0])):
item_cy = center_y(item.bbox)
if rows and abs(rows[-1].cy - item_cy) <= y_tolerance:
rows[-1].items.append(item)
rows[-1].cy = float(np.mean([center_y(existing.bbox) for existing in rows[-1].items]))
continue
rows.append(RowGroup(cy=item_cy, items=[item]))
return rows
def is_headerish_row(row: RowGroup, *, page_width: float) -> bool:
bbox = row.bbox
text = " ".join(item.text for item in row.items)
centered = bbox[0] > (page_width * 0.25) and bbox[2] < (page_width * 0.85)
short_text = len(text) <= 80
return centered or short_text or row.items[0].italic
def _fragment_style_weight(fragment: StyledFragment) -> float:
normalized_text = "".join(char for char in str(fragment.text or "") if not char.isspace())
if normalized_text:
return float(len(normalized_text))
return max(1.0, width(fragment.bbox))
def _fragment_style_fraction(
fragments: Sequence[StyledFragment],
*,
attr_name: str,
) -> float:
total_weight = 0.0
styled_weight = 0.0
for fragment in fragments:
weight = _fragment_style_weight(fragment)
total_weight += weight
if bool(getattr(fragment, attr_name, False)):
styled_weight += weight
if total_weight <= 0:
return 0.0
return styled_weight / total_weight
def _native_cell_bold_min_fraction() -> float:
raw_value = str(os.getenv("PDF_NATIVE_CELL_BOLD_MIN_FRACTION", "0.60")).strip()
try:
return min(1.0, max(0.0, float(raw_value)))
except ValueError:
return 0.60
def drawing_based_candidates(page: fitz.Page) -> List[Tuple[float, float, float, float]]:
candidate_boxes: List[Tuple[float, float, float, float]] = []
page_width = float(page.rect.width)
for drawing in page.get_drawings():
rect = drawing.get("rect")
if rect is None:
continue
candidate = (float(rect.x0), float(rect.y0), float(rect.x1), float(rect.y1))
if width(candidate) < (page_width * 0.35):
continue
draw_type = str(drawing.get("type") or "")
if draw_type in {"f", "fs"} and height(candidate) <= 30.0:
candidate_boxes.append(candidate)
continue
if draw_type in {"s", "fs"} and height(candidate) <= 2.0:
candidate_boxes.append(candidate)
candidate_boxes.sort(key=lambda box: (box[1], box[0]))
merged: List[Tuple[float, float, float, float]] = []
for candidate in candidate_boxes:
if (
merged
and candidate[1] - merged[-1][3] <= 18.0
and min(candidate[2], merged[-1][2]) - max(candidate[0], merged[-1][0]) > (page_width * 0.20)
):
merged[-1] = (
min(merged[-1][0], candidate[0]),
min(merged[-1][1], candidate[1]),
max(merged[-1][2], candidate[2]),
max(merged[-1][3], candidate[3]),
)
continue
merged.append(candidate)
return merged
def row_is_tabular_core(row: RowGroup) -> bool:
numeric_count = sum(is_numeric_like(item.text) for item in row.items)
if len(row.items) >= 4:
return True
if len(row.items) >= 3 and numeric_count >= 1:
return True
if len(row.items) >= 2 and numeric_count >= 2:
return True
return False
def row_is_tabular_support(row: RowGroup) -> bool:
numeric_count = sum(is_numeric_like(item.text) for item in row.items)
if row_is_tabular_core(row):
return True
if len(row.items) >= 2 and numeric_count >= 1:
return True
return False
def alignment_based_candidates(
rows: Sequence[RowGroup],
*,
page_width: float,
) -> List[Tuple[float, float, float, float]]:
candidates: List[Tuple[float, float, float, float]] = []
index = 0
while index < len(rows):
row = rows[index]
if not row_is_tabular_core(row):
index += 1
continue
start = index
end = index + 1
while end < len(rows):
row_gap = rows[end].bbox[1] - rows[end - 1].bbox[3]
if row_gap > 22.0 or not row_is_tabular_support(rows[end]):
break
end += 1
run = list(rows[start:end])
core_count = sum(row_is_tabular_core(candidate_row) for candidate_row in run)
avg_items = float(np.mean([len(candidate_row.items) for candidate_row in run])) if run else 0.0
if core_count >= 3 and avg_items >= 2.8:
expanded_start = start
for _ in range(3):
if expanded_start <= 0:
break
previous_row = rows[expanded_start - 1]
gap = rows[expanded_start].bbox[1] - previous_row.bbox[3]
if gap > 18.0 or not is_headerish_row(previous_row, page_width=page_width):
break
expanded_start -= 1
expanded_end = end
while expanded_end < len(rows):
next_row = rows[expanded_end]
if rows[expanded_end].bbox[1] - rows[expanded_end - 1].bbox[3] > 18.0:
break
if len(next_row.items) > 2:
break
next_text = " ".join(item.text for item in next_row.items).strip()
if not next_text.startswith("("):
break
expanded_end += 1
run_rows = rows[expanded_start:expanded_end]
candidate_box = union_bbox(row_group.bbox for row_group in run_rows)
if width(candidate_box) >= (page_width * 0.35):
candidates.append(candidate_box)
index = max(end, index + 1)
return candidates
def filter_fragments_in_rect(
rect: Sequence[float],
*,
fragments: Sequence[StyledFragment],
) -> List[StyledFragment]:
left, top, right, bottom = (float(value) for value in rect)
kept: List[StyledFragment] = []
for fragment in fragments:
x0, y0, x1, y1 = fragment.bbox
cx = (x0 + x1) / 2.0
cy = (y0 + y1) / 2.0
if left <= cx <= right and top <= cy <= bottom:
kept.append(fragment)
return kept
def score_candidate(
rect: Sequence[float],
*,
fragments: Sequence[StyledFragment],
) -> Optional[TableCandidate]:
inside_fragments = filter_fragments_in_rect(rect, fragments=fragments)
if len(inside_fragments) < 6:
return None
rows = group_rows(inside_fragments)
dense_rows = [row for row in rows if len(row.items) >= 2]
if len(dense_rows) < 3:
return None
numeric_fragments = sum(is_numeric_like(fragment.text) for fragment in inside_fragments)
bold_fragments = sum(bool(fragment.bold) for fragment in inside_fragments)
score = (len(dense_rows) * 5.0) + min(20.0, float(numeric_fragments)) + min(10.0, float(bold_fragments))
return TableCandidate(
rect=tuple(float(value) for value in rect),
source="scored",
score=score,
rows=rows,
)
def dedupe_candidates(candidates: Sequence[TableCandidate]) -> List[TableCandidate]:
kept: List[TableCandidate] = []
for candidate in sorted(candidates, key=lambda item: (item.score, width(item.rect) * height(item.rect)), reverse=True):
if any(bbox_iou(candidate.rect, existing.rect) >= 0.85 for existing in kept):
continue
kept.append(candidate)
return kept
def render_fragment_html(fragment: StyledFragment) -> str:
rendered = html.escape(fragment.text, quote=False)
if fragment.bold:
rendered = f"{rendered}"
if fragment.italic:
rendered = f"{rendered}"
if fragment.underline:
rendered = f"{rendered}"
return rendered
def column_anchor_x(fragment: StyledFragment) -> float:
if is_numeric_like(fragment.text):
return float(fragment.bbox[2])
return float(fragment.bbox[0])
def infer_column_centers(
rows: Sequence[RowGroup],
*,
table_rect: Sequence[float],
) -> List[float]:
table_width = width(table_rect)
tolerance = max(14.0, table_width * 0.03)
centers: List[float] = []
counts: List[int] = []
dense_rows = [row for row in rows if len(row.items) >= 2]
for row in dense_rows:
for item in sorted(row.items, key=lambda fragment: fragment.bbox[0]):
item_center = column_anchor_x(item)
matched_index: Optional[int] = None
for index, existing_center in enumerate(centers):
if abs(existing_center - item_center) <= tolerance:
matched_index = index
break
if matched_index is None:
centers.append(item_center)
counts.append(1)
continue
counts[matched_index] += 1
centers[matched_index] = (
(centers[matched_index] * float(counts[matched_index] - 1)) + item_center
) / float(counts[matched_index])
ranked_pairs = sorted(
zip(centers, counts),
key=lambda pair: pair[0],
)
filtered = [center for center, count in ranked_pairs if count >= 2]
if filtered:
return filtered
if dense_rows:
widest_row = max(dense_rows, key=lambda row: len(row.items))
return [column_anchor_x(item) for item in sorted(widest_row.items, key=lambda fragment: fragment.bbox[0])]
return []
def build_column_boundaries(
column_centers: Sequence[float],
*,
table_rect: Sequence[float],
) -> List[float]:
if not column_centers:
return [float(table_rect[0]), float(table_rect[2])]
boundaries = [float(table_rect[0])]
sorted_centers = sorted(float(value) for value in column_centers)
for index in range(len(sorted_centers) - 1):
boundaries.append((sorted_centers[index] + sorted_centers[index + 1]) / 2.0)
boundaries.append(float(table_rect[2]))
return boundaries
def build_row_boundaries(
rows: Sequence[RowGroup],
*,
table_rect: Sequence[float],
) -> List[float]:
if not rows:
return [float(table_rect[1]), float(table_rect[3])]
boundaries = [float(table_rect[1])]
for index in range(len(rows) - 1):
boundaries.append((float(rows[index].bbox[3]) + float(rows[index + 1].bbox[1])) / 2.0)
boundaries.append(float(table_rect[3]))
return boundaries
def infer_header_row_count(rows: Sequence[RowGroup]) -> int:
header_row_count = 0
for row in rows[:3]:
numeric_count = sum(is_numeric_like(item.text) for item in row.items)
bold_count = sum(bool(item.bold) for item in row.items)
if header_row_count == 0 and (numeric_count == 0 or len(row.items) <= 2):
header_row_count += 1
continue
if numeric_count == 0 and len(row.items) >= 2:
header_row_count += 1
continue
if bold_count >= max(1, len(row.items) - 1) and numeric_count <= 2:
header_row_count += 1
continue
break
return header_row_count
def assign_fragment_to_columns(
fragment: StyledFragment,
*,
column_centers: Sequence[float],
boundaries: Sequence[float],
allow_spans: bool,
) -> Tuple[int, int]:
if len(boundaries) < 2:
return 0, 0
item_left, _item_top, item_right, _item_bottom = fragment.bbox
item_width = max(1.0, item_right - item_left)
overlapping_columns: List[int] = []
for index in range(len(boundaries) - 1):
boundary_left = float(boundaries[index])
boundary_right = float(boundaries[index + 1])
overlap = max(0.0, min(item_right, boundary_right) - max(item_left, boundary_left))
if overlap >= max(4.0, item_width * 0.12):
overlapping_columns.append(index)
if overlapping_columns:
if not allow_spans:
nearest_index = min(
overlapping_columns,
key=lambda index: abs(column_anchor_x(fragment) - float(column_centers[index])),
)
return nearest_index, nearest_index
return overlapping_columns[0], overlapping_columns[-1]
if not column_centers:
return 0, 0
nearest_index = min(
range(len(column_centers)),
key=lambda index: abs(column_anchor_x(fragment) - float(column_centers[index])),
)
return nearest_index, nearest_index
def infer_table_candidate_cells(candidate: TableCandidate) -> List[TableCellCandidate]:
rows = [RowGroup(cy=row.cy, items=sorted(row.items, key=lambda fragment: fragment.bbox[0])) for row in candidate.rows]
if not rows:
return []
column_centers = infer_column_centers(rows, table_rect=candidate.rect)
if not column_centers:
return []
boundaries = build_column_boundaries(column_centers, table_rect=candidate.rect)
row_boundaries = build_row_boundaries(rows, table_rect=candidate.rect)
header_row_count = infer_header_row_count(rows)
cells: List[TableCellCandidate] = []
for row_index, row in enumerate(rows):
assigned_cells: List[Dict[str, Any]] = []
for fragment in row.items:
start_column, end_column = assign_fragment_to_columns(
fragment,
column_centers=column_centers,
boundaries=boundaries,
allow_spans=(len(row.items) == 1),
)
fragment_html = render_fragment_html(fragment)
if assigned_cells and start_column <= int(assigned_cells[-1]["end_column"]):
assigned_cells[-1]["end_column"] = max(int(assigned_cells[-1]["end_column"]), end_column)
assigned_cells[-1]["html"] += "
" + fragment_html
assigned_cells[-1]["texts"].append(fragment.text)
assigned_cells[-1]["fragments"].append(fragment)
continue
assigned_cells.append(
{
"start_column": start_column,
"end_column": end_column,
"html": fragment_html,
"texts": [fragment.text],
"fragments": [fragment],
}
)
cursor = 0
for cell in assigned_cells:
start_column = max(cursor, int(cell["start_column"]))
end_column = max(start_column, int(cell["end_column"]))
cursor = end_column + 1
left = float(boundaries[start_column])
right = float(boundaries[end_column + 1])
top = float(row_boundaries[row_index])
bottom = float(row_boundaries[row_index + 1])
fragments = list(cell["fragments"])
cells.append(
TableCellCandidate(
row=row_index,
col=start_column,
rowspan=1,
colspan=max(1, end_column - start_column + 1),
bbox=(left, top, right, bottom),
text="\n".join(str(piece) for piece in cell["texts"] if str(piece).strip()),
html=str(cell["html"]),
header=(row_index < header_row_count),
bold=(
_fragment_style_fraction(fragments, attr_name="bold")
>= _native_cell_bold_min_fraction()
),
italic=any(bool(fragment.italic) for fragment in fragments),
underline=any(bool(fragment.underline) for fragment in fragments),
)
)
return cells
def render_table_candidate_html(candidate: TableCandidate) -> str:
cells = infer_table_candidate_cells(candidate)
if not cells:
return ""
row_count = max(int(cell.row + cell.rowspan) for cell in cells)
column_count = max(int(cell.col + cell.colspan) for cell in cells)
cells_by_row: Dict[int, List[TableCellCandidate]] = {}
for cell in cells:
cells_by_row.setdefault(int(cell.row), []).append(cell)
parts: List[str] = [""]
for row_index in range(row_count):
row_cells = sorted(cells_by_row.get(row_index, []), key=lambda cell: (cell.col, cell.colspan))
default_tag_name = "th" if any(bool(cell.header) for cell in row_cells) else "td"
parts.append("")
cursor = 0
for cell in row_cells:
start_column = max(cursor, int(cell.col))
end_column = max(start_column, int(cell.col + cell.colspan - 1))
while cursor < start_column:
parts.append(f"<{default_tag_name}>")
cursor += 1
colspan = max(1, end_column - start_column + 1)
colspan_attr = f' colspan="{colspan}"' if colspan > 1 else ""
tag_name = "th" if cell.header else "td"
parts.append(f"<{tag_name}{colspan_attr}>{cell.html}")
cursor = end_column + 1
while cursor < column_count:
parts.append(f"<{default_tag_name}>")
cursor += 1
parts.append("
")
parts.append("
")
return "".join(parts)
def detect_native_tables(page: fitz.Page) -> Dict[str, Any]:
timings: Dict[str, float] = {}
started_at = time.perf_counter()
layout_started_at = time.perf_counter()
layout_fragments = extract_layout_fragments(page)
timings["layout_extraction_ms"] = (time.perf_counter() - layout_started_at) * 1000.0
page_width = float(page.rect.width)
grouped_rows = group_rows(layout_fragments)
alignment_started_at = time.perf_counter()
alignment_rects = alignment_based_candidates(grouped_rows, page_width=page_width)
timings["alignment_candidate_ms"] = (time.perf_counter() - alignment_started_at) * 1000.0
if not alignment_rects:
timings["total_detection_ms"] = (time.perf_counter() - started_at) * 1000.0
return {
"mode": "pdf_native",
"fragments": layout_fragments,
"tables": [],
"timings_ms": timings,
"row_count": len(grouped_rows),
}
spans_started_at = time.perf_counter()
fragments = extract_styled_fragments(page)
timings["span_extraction_ms"] = (time.perf_counter() - spans_started_at) * 1000.0
drawing_started_at = time.perf_counter()
drawing_rects = drawing_based_candidates(page)
timings["drawing_candidate_ms"] = (time.perf_counter() - drawing_started_at) * 1000.0
scored_candidates: List[TableCandidate] = []
for rect in [*drawing_rects, *alignment_rects]:
candidate = score_candidate(rect, fragments=fragments)
if candidate is None:
continue
candidate.source = "drawing" if rect in drawing_rects else "alignment"
scored_candidates.append(candidate)
deduped_candidates = dedupe_candidates(scored_candidates)
timings["total_detection_ms"] = (time.perf_counter() - started_at) * 1000.0
return {
"mode": "pdf_native",
"fragments": fragments,
"tables": deduped_candidates,
"timings_ms": timings,
"row_count": len(grouped_rows),
}
def render_page_image(page: fitz.Page, *, zoom: float = 2.0) -> Image.Image:
pix = page.get_pixmap(matrix=fitz.Matrix(zoom, zoom), alpha=False)
return Image.frombytes("RGB", [pix.width, pix.height], pix.samples)
def group_component_boxes_into_rows(
component_boxes: Sequence[Sequence[int]],
*,
y_tolerance: float,
) -> List[List[Tuple[int, int, int, int]]]:
rows: List[List[Tuple[int, int, int, int]]] = []
row_centers: List[float] = []
for box in sorted(
((int(box[0]), int(box[1]), int(box[2]), int(box[3])) for box in component_boxes),
key=lambda item: (((item[1] + item[3]) / 2.0), item[0]),
):
cy = (box[1] + box[3]) / 2.0
if rows and abs(row_centers[-1] - cy) <= y_tolerance:
rows[-1].append(box)
row_centers[-1] = float(np.mean([(item[1] + item[3]) / 2.0 for item in rows[-1]]))
continue
rows.append([box])
row_centers.append(cy)
return rows
def analyze_raster_candidate(
*,
text_mask: np.ndarray,
line_mask: np.ndarray,
x: int,
y: int,
width_px_box: int,
height_px_box: int,
scale_x: float,
scale_y: float,
page_height: float,
) -> Optional[RasterCandidate]:
try:
import cv2 # type: ignore
except ImportError as exc: # pragma: no cover - depends on environment
raise RuntimeError("Raster fallback requires cv2 (opencv-python-headless).") from exc
crop_text = text_mask[y : y + height_px_box, x : x + width_px_box]
crop_lines = line_mask[y : y + height_px_box, x : x + width_px_box]
if crop_text.size == 0:
return None
cc_kernel = cv2.getStructuringElement(
cv2.MORPH_RECT,
(max(4, width_px_box // 120), max(2, height_px_box // 160)),
)
grouped_components = cv2.dilate(crop_text, cc_kernel, iterations=1)
component_count, _labels, stats, _centroids = cv2.connectedComponentsWithStats(grouped_components, connectivity=8)
component_boxes: List[Tuple[int, int, int, int]] = []
for component_index in range(1, component_count):
comp_x, comp_y, comp_w, comp_h, comp_area = stats[component_index]
if comp_area < 20 or comp_w < 4 or comp_h < 4:
continue
component_boxes.append((comp_x, comp_y, comp_x + comp_w, comp_y + comp_h))
row_groups = group_component_boxes_into_rows(
component_boxes,
y_tolerance=max(8.0, height_px_box * 0.01),
)
populated_rows = [row for row in row_groups if row]
row_count = len(populated_rows)
avg_components_per_row = (
float(np.mean([len(row) for row in populated_rows])) if populated_rows else 0.0
)
line_density = float((crop_lines > 0).mean())
text_density = float((crop_text > 0).mean())
# Narrative paragraphs tend to have dense full-width text and fewer disconnected
# column clusters per row than real tables.
if line_density < 0.003 and avg_components_per_row < 2.4:
return None
if text_density > 0.09 and line_density < 0.003:
return None
if line_density > 0.12:
return None
if row_count < 4:
return None
left = x * scale_x
top = y * scale_y
right = (x + width_px_box) * scale_x
bottom = (y + height_px_box) * scale_y
candidate_box = (left, top, right, bottom)
score = (
(avg_components_per_row * 8.0)
+ (line_density * 220.0)
+ (text_density * 35.0)
+ (height(candidate_box) / max(1.0, page_height) * 8.0)
)
return RasterCandidate(
rect=candidate_box,
score=score,
row_count=row_count,
avg_components_per_row=avg_components_per_row,
text_density=text_density,
line_density=line_density,
)
def detect_raster_table_regions(page: fitz.Page) -> Dict[str, Any]:
try:
import cv2 # type: ignore
except ImportError as exc: # pragma: no cover - depends on environment
raise RuntimeError("Raster fallback requires cv2 (opencv-python-headless).") from exc
timings: Dict[str, float] = {}
started_at = time.perf_counter()
render_started_at = time.perf_counter()
image = render_page_image(page, zoom=2.0)
timings["render_ms"] = (time.perf_counter() - render_started_at) * 1000.0
grayscale_started_at = time.perf_counter()
rgb = np.asarray(image, dtype=np.uint8)
gray = cv2.cvtColor(rgb, cv2.COLOR_RGB2GRAY)
_threshold, binary = cv2.threshold(gray, 0, 255, cv2.THRESH_BINARY_INV + cv2.THRESH_OTSU)
timings["binarize_ms"] = (time.perf_counter() - grayscale_started_at) * 1000.0
morphology_started_at = time.perf_counter()
height_px, width_px = gray.shape[:2]
horizontal_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (max(40, width_px // 25), 1))
vertical_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (1, max(40, height_px // 25)))
horizontal = cv2.morphologyEx(binary, cv2.MORPH_OPEN, horizontal_kernel)
vertical = cv2.morphologyEx(binary, cv2.MORPH_OPEN, vertical_kernel)
line_mask = cv2.bitwise_or(horizontal, vertical)
text_mask = cv2.subtract(binary, line_mask)
text_kernel = cv2.getStructuringElement(cv2.MORPH_RECT, (max(8, width_px // 180), max(6, height_px // 180)))
grouped_text = cv2.dilate(text_mask, text_kernel, iterations=1)
candidate_mask = cv2.dilate(
cv2.bitwise_or(grouped_text, line_mask),
cv2.getStructuringElement(cv2.MORPH_RECT, (max(20, width_px // 80), max(20, height_px // 80))),
iterations=1,
)
contours, _hierarchy = cv2.findContours(candidate_mask, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)
timings["morphology_ms"] = (time.perf_counter() - morphology_started_at) * 1000.0
scale_x = float(page.rect.width) / float(width_px)
scale_y = float(page.rect.height) / float(height_px)
candidates: List[RasterCandidate] = []
for contour in contours:
x, y, width_px_box, height_px_box = cv2.boundingRect(contour)
if width_px_box < (width_px * 0.20) or height_px_box < (height_px * 0.05):
continue
candidate = analyze_raster_candidate(
text_mask=text_mask,
line_mask=line_mask,
x=x,
y=y,
width_px_box=width_px_box,
height_px_box=height_px_box,
scale_x=scale_x,
scale_y=scale_y,
page_height=float(page.rect.height),
)
if candidate is not None:
candidates.append(candidate)
kept: List[RasterCandidate] = []
for candidate in sorted(candidates, key=lambda item: item.score, reverse=True):
if any(bbox_iou(candidate.rect, existing.rect) >= 0.85 for existing in kept):
continue
kept.append(candidate)
timings["total_detection_ms"] = (time.perf_counter() - started_at) * 1000.0
return {
"mode": "image_morphology",
"tables": kept[:6],
"timings_ms": timings,
}
def detect_tables_on_page(page: fitz.Page) -> Dict[str, Any]:
native_result = detect_native_tables(page)
native_fragment_count = len(native_result["fragments"])
if native_fragment_count >= MIN_NATIVE_SPAN_COUNT:
return native_result
raster_result = detect_raster_table_regions(page)
if native_result["tables"]:
return native_result
return raster_result
def build_table_payload(candidate: TableCandidate) -> Dict[str, Any]:
payload = candidate.to_payload()
payload["cells"] = [cell.to_payload() for cell in infer_table_candidate_cells(candidate)]
html_fragment = render_table_candidate_html(candidate)
if html_fragment:
payload["html"] = html_fragment
return payload
def save_overlay(
page: fitz.Page,
*,
detection_payload: Dict[str, Any],
output_path: Path,
) -> None:
image = render_page_image(page, zoom=2.0)
draw = ImageDraw.Draw(image)
scale_x = float(image.width) / float(page.rect.width)
scale_y = float(image.height) / float(page.rect.height)
def scale_box(box: Sequence[float]) -> Tuple[float, float, float, float]:
return (
float(box[0]) * scale_x,
float(box[1]) * scale_y,
float(box[2]) * scale_x,
float(box[3]) * scale_y,
)
if detection_payload.get("mode") == "pdf_native":
for table in detection_payload.get("tables", []):
draw.rectangle(scale_box(table.rect), outline=(220, 40, 40), width=5)
for row in table.rows:
draw.rectangle(scale_box(row.bbox), outline=(255, 140, 0), width=2)
for fragment in row.items:
outline_color = (40, 170, 40) if fragment.bold else (40, 120, 220)
draw.rectangle(scale_box(fragment.bbox), outline=outline_color, width=1)
else:
for table in detection_payload.get("tables", []):
box = table.rect if isinstance(table, RasterCandidate) else table["bbox"]
draw.rectangle(scale_box(box), outline=(220, 40, 40), width=5)
output_path.parent.mkdir(parents=True, exist_ok=True)
image.save(output_path)
def build_payload(
pdf_path: Path,
*,
page_number: int,
detection_payload: Dict[str, Any],
) -> Dict[str, Any]:
payload: Dict[str, Any] = {
"pdf_path": str(pdf_path),
"page_number": int(page_number),
"mode": detection_payload.get("mode"),
"timings_ms": {
key: round(float(value), 2)
for key, value in dict(detection_payload.get("timings_ms") or {}).items()
},
}
if detection_payload.get("mode") == "pdf_native":
payload["native_fragment_count"] = len(detection_payload.get("fragments") or [])
payload["tables"] = [build_table_payload(table) for table in detection_payload.get("tables") or []]
payload["html_fragments"] = [
str(table_payload["html"])
for table_payload in payload["tables"]
if isinstance(table_payload, dict) and isinstance(table_payload.get("html"), str) and table_payload.get("html")
]
else:
payload["tables"] = [table.to_payload() for table in detection_payload.get("tables") or []]
payload["html_fragments"] = []
return payload
def detect_tables_for_page_number(document: fitz.Document, *, page_number: int) -> Dict[str, Any]:
opened_at = time.perf_counter()
page = document.load_page(page_number - 1)
detection_payload = detect_tables_on_page(page)
detection_payload.setdefault("timings_ms", {})
detection_payload["timings_ms"]["open_and_dispatch_ms"] = (time.perf_counter() - opened_at) * 1000.0
return detection_payload
def extract_tables_from_pdf_page(
pdf_path: Path | str,
*,
page_number: int,
overlay_path: Optional[Path | str] = None,
) -> Dict[str, Any]:
resolved_pdf_path = Path(pdf_path).resolve()
with fitz.open(str(resolved_pdf_path)) as document:
detection_payload = detect_tables_for_page_number(document, page_number=page_number)
if overlay_path:
overlay_started_at = time.perf_counter()
page = document.load_page(page_number - 1)
save_overlay(page, detection_payload=detection_payload, output_path=Path(overlay_path).resolve())
detection_payload["timings_ms"]["overlay_ms"] = (time.perf_counter() - overlay_started_at) * 1000.0
return build_payload(resolved_pdf_path, page_number=page_number, detection_payload=detection_payload)
def summarize_document_payloads(page_payloads: Sequence[Dict[str, Any]]) -> Dict[str, Any]:
latencies_ms = [
float(page_payload.get("timings_ms", {}).get("open_and_dispatch_ms"))
for page_payload in page_payloads
if isinstance(page_payload.get("timings_ms", {}).get("open_and_dispatch_ms"), (int, float))
]
if latencies_ms:
latency_array = np.asarray(latencies_ms, dtype=float)
latency_summary = {
"median_ms": round(float(np.median(latency_array)), 2),
"p95_ms": round(float(np.percentile(latency_array, 95)), 2),
"max_ms": round(float(np.max(latency_array)), 2),
}
else:
latency_summary = {}
return {
"pages": len(page_payloads),
"pages_with_tables": sum(bool(page_payload.get("tables")) for page_payload in page_payloads),
"native_pages": sum(page_payload.get("mode") == "pdf_native" for page_payload in page_payloads),
"raster_pages": sum(page_payload.get("mode") == "image_morphology" for page_payload in page_payloads),
"latency_ms": latency_summary,
}
def extract_tables_from_pdf_document(
pdf_path: Path | str,
*,
page_numbers: Optional[Sequence[int]] = None,
) -> Dict[str, Any]:
resolved_pdf_path = Path(pdf_path).resolve()
with fitz.open(str(resolved_pdf_path)) as document:
total_pages = int(document.page_count)
selected_pages = (
[page_number for page_number in page_numbers if 1 <= int(page_number) <= total_pages]
if page_numbers is not None
else list(range(1, total_pages + 1))
)
page_payloads = [
build_payload(
resolved_pdf_path,
page_number=page_number,
detection_payload=detect_tables_for_page_number(document, page_number=page_number),
)
for page_number in selected_pages
]
return {
"pdf_path": str(resolved_pdf_path),
"page_count": len(page_payloads),
"pages": page_payloads,
"summary": summarize_document_payloads(page_payloads),
}
def extract_table_html_fragments_from_pdf_page(
pdf_path: Path | str,
*,
page_number: int,
) -> List[str]:
payload = extract_tables_from_pdf_page(pdf_path, page_number=page_number)
return [str(fragment) for fragment in payload.get("html_fragments") or [] if str(fragment).strip()]
def parse_args() -> argparse.Namespace:
parser = argparse.ArgumentParser(
description="Fast table bbox/style extraction for PDF pages using native PDF spans and a lightweight raster fallback."
)
parser.add_argument("--pdf", required=True, help="Path to the input PDF.")
parser.add_argument("--page", type=int, help="1-based page number.")
parser.add_argument("--all-pages", action="store_true", help="Process the full PDF instead of a single page.")
parser.add_argument("--output-json", help="Optional JSON output path.")
parser.add_argument("--overlay-png", help="Optional debug overlay PNG path.")
return parser.parse_args()
def main() -> None:
args = parse_args()
pdf_path = Path(args.pdf).resolve()
if not args.all_pages and args.page is None:
raise SystemExit("Pass --page N for a single page or --all-pages for a full-document run.")
if args.all_pages:
if args.overlay_png:
raise SystemExit("--overlay-png is only supported with single-page mode.")
payload = extract_tables_from_pdf_document(pdf_path)
else:
payload = extract_tables_from_pdf_page(
pdf_path,
page_number=max(1, int(args.page)),
overlay_path=(Path(args.overlay_png).resolve() if args.overlay_png else None),
)
rendered = json.dumps(payload, indent=2, sort_keys=True)
print(rendered)
if args.output_json:
output_path = Path(args.output_json).resolve()
output_path.parent.mkdir(parents=True, exist_ok=True)
output_path.write_text(rendered + "\n", encoding="utf-8")
if __name__ == "__main__":
main()