#!/usr/bin/env python3 """ 单元格裁剪图预处理参数扫描:去水印 / contrast(clahe/gamma/linear/text_restore)/ upscale / det 阈值 / OCR 模式。 支持 contrast 在放大前/后执行两种顺序对比。 默认从 **原图**(`*_raw.png`)出发,与 pipeline 二次 OCR 一致,避免对已预处理 debug 图二次去水印。 用法: python cell_sweep.py cell219_empty_empty_raw.png -o ./out -t "ATM存折取款" python cell_sweep.py /path/to/tablecell_ocr/ -o ./out python cell_sweep.py cell.png --quick --no-save-images python cell_sweep.py cell.png --contrast-orders before_upscale,after_upscale OCR_DET_MODEL_PATH=... OCR_REC_MODEL_PATH=... python cell_sweep.py cell.png # 统计出的最优参数 tag: threshold_t150_cl_1.0_8_ob_u128_det0.5 # 对目录下所有 *_raw.png 验证适配性 python cell_sweep.py /path/to/tablecell_ocr/ -o ./out --best-only # 自定义最优参数 python cell_sweep.py /path/to/tablecell_ocr/ -o ./out --best-only \ --best-config threshold_t150_cl_1.0_8_ob_u128_det0.5 # 指定目标文字,自动统计 HIT 命中率 python cell_sweep.py /path/to/tablecell_ocr/ -o ./out --best-only -t "交易类型" """ from __future__ import annotations import argparse import json import os import sys from itertools import product from pathlib import Path from typing import Any, Dict, List, Optional, Sequence, Tuple import cv2 import numpy as np _repo_root = Path(__file__).resolve().parents[3] if str(_repo_root) not in sys.path: sys.path.insert(0, str(_repo_root)) from ocr_utils.watermark import WatermarkProcessor, merge_watermark_config from ocr_utils.watermark.contrast import enhance_document_contrast _IMAGE_SUFFIXES = {".png", ".jpg", ".jpeg", ".bmp", ".tif", ".tiff", ".webp"} _DEFAULT_MODEL_DIR = Path( "/Users/zhch158/models/modelscope_cache/models/OpenDataLab/" "PDF-Extract-Kit-1___0/models/OCR/paddleocr_torch" ) def _parse_csv_ints(s: str) -> List[Optional[int]]: out: List[Optional[int]] = [] for part in s.split(","): part = part.strip() if not part or part.lower() in ("none", "d", "default"): out.append(None) else: out.append(int(part)) return out def _parse_csv_floats(s: str) -> List[float]: return [float(x.strip()) for x in s.split(",") if x.strip()] def _parse_csv_bools(s: str) -> List[bool]: out: List[bool] = [] for part in s.split(","): p = part.strip().lower() if p in ("1", "true", "yes", "on"): out.append(True) elif p in ("0", "false", "no", "off"): out.append(False) else: raise ValueError(f"无效的 bool 值: {part!r}") return out def _default_model_dir() -> Path: det = os.environ.get("OCR_DET_MODEL_PATH") if det: return Path(det).parent return _DEFAULT_MODEL_DIR def _upscale(img: np.ndarray, min_side: int) -> np.ndarray: h, w = img.shape[:2] if h >= min_side and w >= min_side: return img s = max(min_side / max(h, 1), min_side / max(w, 1), 1.0) return cv2.resize(img, None, fx=s, fy=s, interpolation=cv2.INTER_CUBIC) # ── 对比度增强方法(clahe / gamma / linear / text_restore / none)── def _apply_contrast( gray: np.ndarray, *, method: str, clip_limit: float = 1.0, tile_grid_size: int = 8, gamma: float = 0.85, black_percentile: float = 2.0, white_percentile: float = 98.0, text_black_target: int = 85, background_threshold: int = 248, ) -> np.ndarray: """对灰度图应用对比度增强;method="none" 时原样返回。""" if method == "none": return gray if method == "text_restore": return enhance_document_contrast( gray, method="text_restore", text_black_target=text_black_target, background_threshold=background_threshold, ) if method == "clahe": return enhance_document_contrast( gray, method="clahe", clip_limit=clip_limit, tile_grid_size=tile_grid_size, ) if method == "gamma": return enhance_document_contrast(gray, method="gamma", gamma=gamma) if method == "linear": return enhance_document_contrast( gray, method="linear", black_percentile=black_percentile, white_percentile=white_percentile, ) return gray def _contrast_tag(cfg: Dict[str, Any]) -> str: """生成 contrast 配置的短标签。""" m = cfg.get("method", "none") if m == "none": return "c0" if m == "text_restore": return f"tr_{cfg.get('text_black_target', 85)}" if m == "clahe": return f"cl_{cfg.get('clip_limit', 1.0)}_{cfg.get('tile_grid_size', 8)}" if m == "gamma": return f"gm_{cfg.get('gamma', 0.85)}" if m == "linear": return f"ln_{cfg.get('black_percentile', 2.0)}_{cfg.get('white_percentile', 98.0)}" return m def _build_contrast_grid(quick: bool = False) -> List[Dict[str, Any]]: """构建 contrast 参数网格(对齐 contrast_sweep.py 的设计)。 返回列表,每个元素是一个 Dict,至少包含 "method" 字段。 """ grid: List[Dict[str, Any]] = [{"method": "none"}] # 对照组:不增强 # text_restore if quick: tbt = [60, 85] bts = [240, 248] else: tbt = [60, 85, 100, 120] bts = [240, 248, 252] for target, bg_th in product(tbt, bts): grid.append({"method": "text_restore", "text_black_target": target, "background_threshold": bg_th}) # clahe if quick: cl = [1.0, 2.0] ts = [4, 8] else: cl = [0.5, 1.0, 2.0, 3.0, 5.0] ts = [4, 8] for clip, tile in product(cl, ts): grid.append({"method": "clahe", "clip_limit": clip, "tile_grid_size": tile}) # # gamma # if quick: # gvs = [0.5, 0.85] # else: # gvs = [0.4, 0.55, 0.7, 0.85] # for g in gvs: # grid.append({"method": "gamma", "gamma": g}) # # linear # if quick: # bps = [2.0, 5.0] # wps = [95.0, 98.0] # else: # bps = [2.0, 5.0, 8.0] # wps = [95.0, 98.0] # for bp, wp in product(bps, wps): # grid.append({"method": "linear", "black_percentile": bp, "white_percentile": wp}) return grid def _preprocess( raw: np.ndarray, *, method: str, thresh: Optional[int], contrast_cfg: Dict[str, Any], upscale: int, contrast_order: str = "before_upscale", ) -> np.ndarray: """预处理管线:去水印 → [contrast] → 放大(或去水印 → 放大 → contrast)。 method="none" 时跳过去水印,直接从原图开始处理。 """ if method == "none": img = raw.copy() # 不处理水印,直接使用原图 else: user: Dict[str, Any] = {"enabled": True, "method": method} if method == "threshold" and thresh is not None: user["threshold"] = thresh cfg = merge_watermark_config("cell", user) img, _ = WatermarkProcessor(cfg, scope="cell").process(raw, force=True) contrast_method = contrast_cfg.get("method", "none") if contrast_method != "none" and contrast_order == "before_upscale": gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY) gray = _apply_contrast(gray, **contrast_cfg) img = cv2.cvtColor(gray, cv2.COLOR_GRAY2BGR) img = _upscale(img, upscale) if contrast_method != "none" and contrast_order == "after_upscale": gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY) gray = _apply_contrast(gray, **contrast_cfg) img = cv2.cvtColor(gray, cv2.COLOR_GRAY2BGR) return img def _parse_rec_pair(rec_part: Any) -> Tuple[str, float]: """从 OCR 返回的 (text, score) 或嵌套结构中解析识别结果。""" if rec_part is None: return "", 0.0 if isinstance(rec_part, (list, tuple)) and len(rec_part) >= 2: if isinstance(rec_part[0], (list, tuple, dict)): return "", 0.0 txt = str(rec_part[0] or "").strip() try: sc = float(rec_part[1] or 0.0) except (TypeError, ValueError): sc = 0.0 return txt, sc if txt else 0.0 if isinstance(rec_part, (list, tuple)) and len(rec_part) == 1: txt = str(rec_part[0] or "").strip() return txt, 0.0 return "", 0.0 def _aggregate_rec_score(boxes: List[Dict[str, Any]]) -> float: """按字符数加权平均识别分(与 pipeline aggregate_line_ocr 一致)。""" total_len = sum(len(b.get("text") or "") for b in boxes) if total_len <= 0: return 0.0 weighted = sum( len(b.get("text") or "") * float(b.get("score") or 0.0) for b in boxes ) return weighted / total_len def _ocr(engine: Any, img: np.ndarray, *, det: bool, rec: bool) -> Dict[str, Any]: empty: Dict[str, Any] = { "text": "", "score": 0.0, "boxes": [], "det": det, "rec": rec, "n_boxes": 0, } try: res = engine.ocr(img, det=det, rec=rec) items = res[0] if res and res[0] is not None else [] boxes_out: List[Dict[str, Any]] = [] if det: for item in items: if not item or len(item) < 2: continue text, score = _parse_rec_pair(item[1]) bbox = item[0] if hasattr(bbox, "tolist"): bbox = bbox.tolist() entry: Dict[str, Any] = { "text": text, "score": round(score, 6), } if bbox is not None: entry["det_bbox"] = bbox boxes_out.append(entry) else: for item in items: text, score = _parse_rec_pair(item) if not text and isinstance(item, (list, tuple)) and len(item) >= 1: text, score = _parse_rec_pair(item[0]) boxes_out.append({"text": text, "score": round(score, 6)}) text = "".join(b["text"] for b in boxes_out if b.get("text")).strip() agg_score = _aggregate_rec_score(boxes_out) return { "text": text, "score": round(agg_score, 6), "boxes": boxes_out, "det": det, "rec": rec, "n_boxes": len(boxes_out), } except Exception as e: out = dict(empty) out["error"] = str(e) return out def _make_engine(det_thresh: float, model_dir: Path) -> Any: from ocr_tools.pytorch_models.pytorch_paddle import PytorchPaddleOCR det_path = os.environ.get("OCR_DET_MODEL_PATH") or str( model_dir / "ch_PP-OCRv5_det_infer.pth" ) rec_path = os.environ.get("OCR_REC_MODEL_PATH") or str( model_dir / "ch_PP-OCRv4_rec_server_doc_infer.pth" ) return PytorchPaddleOCR( lang="ch", det_model_path=det_path, rec_model_path=rec_path, det_db_box_thresh=det_thresh, ) def resolve_input_image(path: Path, *, prefer_raw: bool) -> Path: """优先使用与 pipeline debug 配套的 *_raw.png。""" if not prefer_raw or path.stem.endswith("_raw"): return path raw_path = path.parent / f"{path.stem}_raw{path.suffix}" if raw_path.is_file(): print(f" 使用原图: {raw_path.name}(跳过 {path.name})") return raw_path return path def collect_inputs(path: Path, *, prefer_raw: bool) -> List[Path]: if path.is_file(): if path.suffix.lower() not in _IMAGE_SUFFIXES: raise ValueError(f"不支持的图像格式: {path}") return [resolve_input_image(path, prefer_raw=prefer_raw)] if not path.is_dir(): raise FileNotFoundError(path) all_images = sorted( p for p in path.iterdir() if p.is_file() and p.suffix.lower() in _IMAGE_SUFFIXES ) if not all_images: raise FileNotFoundError(f"目录内无图像: {path}") if prefer_raw: raws = [p for p in all_images if p.stem.endswith("_raw")] if raws: return raws chosen: List[Path] = [] for p in all_images: if p.stem.endswith("_raw"): continue raw_sibling = p.parent / f"{p.stem}_raw{p.suffix}" if prefer_raw and raw_sibling.is_file(): continue chosen.append(p) return chosen or all_images def _match_hit(text: str, target: Optional[str]) -> Optional[str]: if not text: return None if not target: return "nonempty" if target in text: return "full" if len(target) >= 6 and target.isdigit() and len(text) >= 6 and text.isdigit(): return "partial" return None def run_sweep( input_path: Path, out_dir: Path, *, prefer_raw: bool, target: Optional[str], model_dir: Path, methods: Sequence[str], thresholds: Sequence[Optional[int]], contrast_grid: List[Dict[str, Any]], contrast_orders: Sequence[str], upscales: Sequence[int], det_threshs: Sequence[float], save_images: bool, run_baseline: bool, baseline_upscale: int, ) -> Dict[str, Any]: resolved = resolve_input_image(input_path, prefer_raw=prefer_raw) raw = cv2.imread(str(resolved)) if raw is None: raise RuntimeError(f"无法读取图像: {resolved}") stem = resolved.stem.removesuffix("_raw") if resolved.stem.endswith("_raw") else resolved.stem cell_out = out_dir / stem cell_out.mkdir(parents=True, exist_ok=True) ocr_modes: List[Tuple[str, bool, bool]] = [ ("det_rec", True, True), ("whole_rec", False, True), ] results: List[Dict[str, Any]] = [] hits: List[Dict[str, Any]] = [] engines: Dict[float, Any] = {} total = 0 for method, thresh, contrast_cfg, c_order, upscale, det_th in product( methods, thresholds, contrast_grid, contrast_orders, upscales, det_threshs ): # 过滤无效组合:非 threshold 方法不需要阈值 if method not in ("threshold",): if thresh is not None: continue if det_th not in engines: print(f" [{stem}] 加载 OCR det_db_box_thresh={det_th} ...") engines[det_th] = _make_engine(det_th, model_dir) img = _preprocess( raw, method=method, thresh=thresh, contrast_cfg=contrast_cfg, upscale=upscale, contrast_order=c_order, ) c_tag = _contrast_tag(contrast_cfg) o_tag = "b" if c_order == "before_upscale" else "a" tag = f"{method}_t{thresh or 'd'}_{c_tag}_o{o_tag}_u{upscale}_det{det_th}" if save_images: cv2.imwrite(str(cell_out / f"{tag}.png"), img) for mode_name, det, rec in ocr_modes: total += 1 ocr = _ocr(engines[det_th], img, det=det, rec=rec) row: Dict[str, Any] = { "tag": tag, "method": method, "threshold": thresh, "contrast_method": contrast_cfg.get("method", "none"), "contrast_order": c_order, "contrast_cfg": contrast_cfg, "upscale": upscale, "det_db_box_thresh": det_th, "ocr_mode": mode_name, **ocr, } results.append(row) m = _match_hit(row.get("text", ""), target) if m: row["match"] = m hits.append(row) print( f" HIT [{m}] {mode_name} {tag} " f"score={row.get('score')} -> {row.get('text')!r}" ) if run_baseline: for det_th in det_threshs: if det_th not in engines: engines[det_th] = _make_engine(det_th, model_dir) base_img = _upscale(raw, baseline_upscale) if save_images: cv2.imwrite(str(cell_out / f"baseline_upscale{baseline_upscale}.png"), base_img) for mode_name, det, rec in ocr_modes: ocr = _ocr(engines[det_th], base_img, det=det, rec=rec) row = { "tag": f"baseline_upscale{baseline_upscale}", "det_db_box_thresh": det_th, "ocr_mode": mode_name, **ocr, } results.append(row) m = _match_hit(row.get("text", ""), target) if m: row["match"] = m hits.append(row) report = { "input": str(resolved), "input_requested": str(input_path), "output_dir": str(cell_out), "target": target, "total_trials": total, "hits": hits, "all_results": results, } report_path = cell_out / "sweep_report.json" report_path.write_text( json.dumps(report, ensure_ascii=False, indent=2), encoding="utf-8" ) # ── 结论报告:按 OCR score 排序,分组对比 ── _print_conclusions(stem, results, target) return report def _print_conclusions( stem: str, results: List[Dict[str, Any]], target: Optional[str], ) -> None: """打印实验结论:按 OCR score 排序,分组展示最优组合。""" if not results: return print(f"\n{'='*70}") print(f" 实验结论: {stem}") if target: print(f" 目标文字: {target}") print(f"{'='*70}") # 取 det_rec 模式的结果(优先用检测+识别完整结果) dr_results = [r for r in results if r.get("ocr_mode") == "det_rec" and r.get("text")] if not dr_results: dr_results = [r for r in results if r.get("text")] if not dr_results: print(" (无有效 OCR 结果)") return # ── 1. 全局 Top-5 ── scored = sorted(dr_results, key=lambda r: -(r.get("score") or 0)) print("\n 全局 OCR 得分 Top-5:") for i, r in enumerate(scored[:5], 1): print(f" {i}. score={r.get('score', 0):.4f} text={r.get('text', '')!r}") print(f" tag={r.get('tag', '')}") # ── 2. 按 contrast 方法分组最佳 ── print("\n 按 contrast 方法分组最优(score 最高):") groups: Dict[str, List[Dict[str, Any]]] = {} for r in scored: cm = r.get("contrast_method", "?") groups.setdefault(cm, []).append(r) for cm in sorted(groups.keys()): best = groups[cm][0] wm = best.get("method", "?") print(f" [{cm}] 最佳: score={best.get('score', 0):.4f} " f"wm={wm} upscale={best.get('upscale')} " f"text={best.get('text', '')!r}") # ── 3. 有 watermark 处理 vs 无 watermark 处理对比 ── print("\n 去水印开关对比(同 contrast 方法,最高 score):") wm_groups: Dict[str, Dict[str, Any]] = {} for r in scored: cm = r.get("contrast_method", "?") wm = r.get("method", "?") if r.get("method") != "none" else "无去水印" key = f"{cm}|{wm}" cur_score = r.get("score") or 0 prev_score = (wm_groups.get(key) or {}).get("score") or 0 if key not in wm_groups or cur_score > prev_score: wm_groups[key] = r for cm in sorted(set(r.get("contrast_method", "?") for r in scored)): wm_rows = [r for k, r in wm_groups.items() if k.startswith(cm + "|")] if wm_rows: best_row = max(wm_rows, key=lambda r: r.get("score") or 0) wm_label = "无去水印" if best_row.get("method") == "none" else best_row.get("method", "?") print(f" [{cm}] 最优: wm={wm_label} score={best_row.get('score', 0):.4f} " f"text={best_row.get('text', '')!r}") # ── 4. 放大顺序对比 ── print("\n 放大前/后对比(同方法,最高 score):") order_data: Dict[str, Dict[str, Any]] = {} for r in scored: cm = r.get("contrast_method", "?") co = r.get("contrast_order", "?") key = f"{cm}|{co}" cur_score = r.get("score") or 0 prev_score = (order_data.get(key) or {}).get("score") or 0 if key not in order_data or cur_score > prev_score: order_data[key] = r for cm in sorted(set(r.get("contrast_method", "?") for r in scored)): b_score = (order_data.get(f"{cm}|before_upscale") or {}).get("score") or 0 a_score = (order_data.get(f"{cm}|after_upscale") or {}).get("score") or 0 better = "放大前" if b_score > a_score else ("放大后" if a_score > b_score else "持平") if b_score or a_score: print(f" [{cm}] 放大前={b_score:.4f} 放大后={a_score:.4f} 更优: {better}") # ── 5. HIT 命中率统计 ── if target: hit_count = sum(1 for r in results if r.get("match")) hit_by_cm: Dict[str, int] = {} for r in results: if r.get("match"): cm = r.get("contrast_method", "?") hit_by_cm[cm] = hit_by_cm.get(cm, 0) + 1 print(f"\n HIT 命中率 (target={target}): {hit_count}/{len(results)}") for cm in sorted(hit_by_cm.keys()): print(f" [{cm}] HIT={hit_by_cm[cm]}") print(f"{'='*70}\n") def _parse_best_config(tag: str) -> Dict[str, Any]: """解析最优参数 tag,如 threshold_t150_cl_1.0_8_ob_u128_det0.5。 tag 格式: {method}_t{thresh}_{c_tag}_o{b|a}_u{upscale}_det{det_th} """ import re cfg: Dict[str, Any] = {} tag = tag.strip() # 解析 method: threshold | masked_adaptive | none m = re.match(r"(threshold|masked_adaptive|none)_t(\w+?)_(.+?)_o([ba])_u(\d+)_det([\d.]+)$", tag) if not m: raise ValueError(f"无法解析 best-config tag: {tag!r}") method, thresh_str, c_part, order_char, upscale, det_th = m.groups() cfg["method"] = method cfg["threshold"] = int(thresh_str) if thresh_str.isdigit() else None cfg["contrast_order"] = "before_upscale" if order_char == "b" else "after_upscale" cfg["upscale"] = int(upscale) cfg["det_db_box_thresh"] = float(det_th) # 解析 contrast 部分: cl_1.0_8 | tr_85 | gm_0.85 | ln_2.0_98.0 | c0 if c_part == "c0": cfg["contrast_cfg"] = {"method": "none"} elif c_part.startswith("cl_"): parts = c_part.split("_") cfg["contrast_cfg"] = {"method": "clahe", "clip_limit": float(parts[1]), "tile_grid_size": int(parts[2])} elif c_part.startswith("tr_"): parts = c_part.split("_") cfg["contrast_cfg"] = {"method": "text_restore", "text_black_target": int(parts[1])} elif c_part.startswith("gm_"): parts = c_part.split("_") cfg["contrast_cfg"] = {"method": "gamma", "gamma": float(parts[1])} elif c_part.startswith("ln_"): parts = c_part.split("_") cfg["contrast_cfg"] = {"method": "linear", "black_percentile": float(parts[1]), "white_percentile": float(parts[2])} else: raise ValueError(f"无法解析 contrast tag: {c_part!r} (in {tag})") return cfg def run_best_config( input_path: Path, out_dir: Path, *, prefer_raw: bool, best_cfg: Dict[str, Any], model_dir: Path, save_images: bool, ) -> Dict[str, Any]: """对单图用指定最优参数跑一次 OCR。""" resolved = resolve_input_image(input_path, prefer_raw=prefer_raw) raw = cv2.imread(str(resolved)) if raw is None: raise RuntimeError(f"无法读取图像: {resolved}") stem = resolved.stem.removesuffix("_raw") if resolved.stem.endswith("_raw") else resolved.stem cell_out = out_dir / stem cell_out.mkdir(parents=True, exist_ok=True) engine = _make_engine(best_cfg["det_db_box_thresh"], model_dir) img = _preprocess( raw, method=best_cfg["method"], thresh=best_cfg.get("threshold"), contrast_cfg=best_cfg["contrast_cfg"], upscale=best_cfg["upscale"], contrast_order=best_cfg["contrast_order"], ) tag = best_cfg.get("_tag", "best") if save_images: cv2.imwrite(str(cell_out / f"{tag}.png"), img) ocr = _ocr(engine, img, det=True, rec=True) row: Dict[str, Any] = { "tag": tag, "method": best_cfg["method"], "threshold": best_cfg.get("threshold"), "contrast_method": best_cfg["contrast_cfg"].get("method", "none"), "contrast_order": best_cfg["contrast_order"], "contrast_cfg": best_cfg["contrast_cfg"], "upscale": best_cfg["upscale"], "det_db_box_thresh": best_cfg["det_db_box_thresh"], "ocr_mode": "det_rec", **ocr, } report = { "input": str(resolved), "input_requested": str(input_path), "output_dir": str(cell_out), "result": row, } report_path = cell_out / "best_result.json" report_path.write_text(json.dumps(report, ensure_ascii=False, indent=2), encoding="utf-8") return report def _build_arg_parser() -> argparse.ArgumentParser: p = argparse.ArgumentParser( description="单元格图预处理 + OCR 参数网格扫描(对齐 pipeline 格级二次 OCR)", ) p.add_argument( "input", type=Path, help="单元格裁剪图路径,或 tablecell_ocr 目录(批量扫描)", ) p.add_argument( "-o", "--output", type=Path, default=None, help="输出目录,默认 /sweep_out/", ) p.add_argument( "-t", "--target", default=None, help="期望 OCR 文本;用于标记 HIT(子串匹配)。省略则任意非空为 HIT", ) p.add_argument( "--model-dir", type=Path, default=None, help="PaddleOCR torch 模型目录(含 det/rec .pth),也可用 OCR_*_MODEL_PATH", ) p.add_argument( "--no-prefer-raw", action="store_true", help="不自动选用同名的 *_raw.png", ) p.add_argument( "--quick", action="store_true", help="缩小网格(threshold 155,165 × upscale 128,192 × det 0.5 × contrast 精简)", ) p.add_argument( "--methods", default="threshold,masked_adaptive,none", help="去水印方式,逗号分隔;none=不去水印", ) p.add_argument( "--thresholds", default="155,165,none", help="threshold 法的阈值;none=预设默认", ) p.add_argument( "--contrast-orders", default="before_upscale,after_upscale", help="contrast 执行顺序: before_upscale(放大前), after_upscale(放大后), 逗号组合", ) p.add_argument( "--upscales", default="128,192", help="最短边放大目标,逗号分隔整数", ) p.add_argument( "--det-threshs", # default="0.2,0.3,0.4,0.5", default="0.5", help="det_db_box_thresh,逗号分隔", ) p.add_argument( "--no-save-images", action="store_true", help="不写出中间预处理 png(仅报告)", ) p.add_argument( "--no-baseline", action="store_true", help="跳过「仅放大、不去水印」对照组", ) p.add_argument( "--baseline-upscale", type=int, default=192, help="baseline 对照组的最短边放大", ) p.add_argument( "--best-only", action="store_true", help="不跑参数网格,对目录下所有图用 --best-config 指定参数跑一次,验证适配性", ) p.add_argument( "--best-config", default="threshold_t150_cl_1.0_8_ob_u128_det0.5", help="最优参数 tag,如 threshold_t150_cl_1.0_8_ob_u128_det0.5", ) return p def main(argv: Optional[Sequence[str]] = None) -> None: args = _build_arg_parser().parse_args(argv) inputs = collect_inputs(args.input, prefer_raw=not args.no_prefer_raw) if not inputs: raise SystemExit("未找到可扫描的图像") if args.output is not None: out_root = args.output elif args.input.is_file(): out_root = args.input.parent / "sweep_out" else: out_root = args.input / "sweep_out" out_root.mkdir(parents=True, exist_ok=True) model_dir = args.model_dir or _default_model_dir() if args.best_only: # 验证适配性模式:对目录下所有图用最优参数跑一次 best_cfg = _parse_best_config(args.best_config) best_cfg["_tag"] = args.best_config print(f"最佳参数验证模式: {args.best_config}") print(f" 解析: method={best_cfg['method']} contrast={best_cfg['contrast_cfg'].get('method')} " f"upscale={best_cfg['upscale']} order={best_cfg['contrast_order']}") print(f" 共 {len(inputs)} 张图") all_texts: List[Dict[str, Any]] = [] hit_count = 0 for img_path in inputs: report = run_best_config( img_path, out_root, prefer_raw=not args.no_prefer_raw, best_cfg=best_cfg, model_dir=model_dir, save_images=not args.no_save_images, ) result = report["result"] text = result.get("text", "") score = result.get("score", 0) all_texts.append({ "input": img_path.name, "text": text, "score": score, "report": str(Path(report["output_dir"]) / "best_result.json"), }) m = _match_hit(text, args.target) hit_info = f" [HIT: {m}]" if m else "" print(f" {img_path.name}: score={score:.4f} text={text!r}{hit_info}") if m: hit_count += 1 # 汇总 summary_path = out_root / "best_summary.json" summary_data = { "best_config": args.best_config, "total": len(all_texts), "hits": hit_count, "target": args.target, "results": all_texts, } summary_path.write_text(json.dumps(summary_data, ensure_ascii=False, indent=2), encoding="utf-8") print(f"\n汇总: {hit_count}/{len(all_texts)} HIT -> {summary_path}") return # 正常参数网格扫描模式 methods = [m.strip() for m in args.methods.split(",") if m.strip()] contrast_orders = [o.strip() for o in args.contrast_orders.split(",") if o.strip()] if args.quick: thresholds = [150, 155] upscales = [128, 192] det_threshs = [0.5] else: thresholds = _parse_csv_ints(args.thresholds) upscales = [int(x) for x in args.upscales.split(",") if x.strip()] det_threshs = _parse_csv_floats(args.det_threshs) contrast_grid = _build_contrast_grid(quick=args.quick) print(f"扫描 {len(inputs)} 张图 -> {out_root}") print(f" methods={methods} thresholds={thresholds} upscales={upscales}") print(f" contrast_methods={len(contrast_grid)} orders={contrast_orders}") if args.target: print(f" target={args.target!r}") summary: List[Dict[str, Any]] = [] for img_path in inputs: print(f"\n=== {img_path.name} ===") report = run_sweep( img_path, out_root, prefer_raw=not args.no_prefer_raw, target=args.target, model_dir=model_dir, methods=methods, thresholds=thresholds, contrast_grid=contrast_grid, contrast_orders=contrast_orders, upscales=upscales, det_threshs=det_threshs, save_images=not args.no_save_images, run_baseline=not args.no_baseline, baseline_upscale=args.baseline_upscale, ) summary.append( { "input": report["input"], "hits": len(report["hits"]), "report": str(Path(report["output_dir"]) / "sweep_report.json"), } ) index_path = out_root / "sweep_index.json" index_path.write_text( json.dumps(summary, ensure_ascii=False, indent=2), encoding="utf-8" ) print(f"\n全部完成,索引: {index_path}") for s in summary: print(f" {s['input']}: {s['hits']} hits -> {s['report']}") if __name__ == "__main__": if len(sys.argv) == 1: print("ℹ️ 未提供命令行参数,使用默认配置运行...") default_config = { # "input": "/Users/zhch158/workspace/data/流水分析/彭_广东兴宁农村商业银行/bank_statement_yusys_local/debug/table_recognition_wired/tablecell_ocr/彭_广东兴宁农村商业银行_page_002_0/cell219_empty_empty_raw.png", # "output": "./output/彭_广东兴宁农村商业银行/cell219_sweep", # "target": "ATM存折取款", # "input": "/Users/zhch158/workspace/data/流水分析/彭_广东兴宁农村商业银行/bank_statement_yusys_local/debug/table_recognition_wired/tablecell_ocr/彭_广东兴宁农村商业银行_page_002_0/cell007_whole_longer_易型交类_raw.png", # "output": "./output/彭_广东兴宁农村商业银行/cell007_sweep", # "target": "交易类型", # "quick": True, # "input": "/Users/zhch158/workspace/data/流水分析/钟_广东陆丰农村商业银行/bank_statement_yusys_local/debug/table_recognition_wired/tablecell_ocr/钟_广东陆丰农村商业银行_page_001_0/cell217_empty_empty_raw.png", # "output": "./output/钟_广东陆丰农村商业银行/cell217_sweep", # "target": "专项资金", # "quick": True, # "input": "/Users/zhch158/workspace/data/流水分析/彭_广东兴宁农村商业银行/bank_statement_yusys_local/debug/table_recognition_wired/tablecell_ocr/彭_广东兴宁农村商业银行_page_002_0", # "output": "./output/彭_广东兴宁农村商业银行", # "best-config": "threshold_t150_cl_1.0_8_ob_u128_det0.5", # "best-only": True, "input": "/Users/zhch158/workspace/data/流水分析/钟_广东陆丰农村商业银行/bank_statement_yusys_local/debug/table_recognition_wired/tablecell_ocr/钟_广东陆丰农村商业银行_page_001_0", "output": "./output/钟_广东陆丰农村商业银行", # "best-config": "threshold_t150_cl_1.0_8_ob_u128_det0.5", "best-config": "threshold_t150_cl_1.0_4_ob_u128_det0.5", "best-only": True, } sys.argv = [sys.argv[0], default_config["input"]] for key, value in default_config.items(): if key == "input": continue flag = f"--{key.replace('_', '-')}" if isinstance(value, bool) and value: sys.argv.append(flag) elif not isinstance(value, bool): sys.argv.extend([flag, str(value)]) sys.exit(main())