fix: UCS match e numero feature ora coerenti con anteprima modello

Bug visibili da screenshot: 1. UCS match diverso da UCS anteprima modello (centro pose vs baricentro) 2. Numero feature disegnate < di quelle anteprima modello Cause: 1. Match UCS era posto su (cx, cy) = centro template, mentre l'anteprima modello mostra UCS sul baricentro feature (mean fx, fy). 2. _draw_matches estraeva feature dal template warpato → re-quantizza gradient su immagine warp+interp, perdendo precisione vs feature pre-computate del matcher. Fix: - Match.variant_idx: nuovo field con indice variante usata dal find() - _draw_matches usa lvl0.dx/dy/bin pre-computati invece di re-estrarre: * applica delta-rotation (m.angle_deg - var.angle_deg) per refine sub-step * proietta in scene coords intorno a (m.cx, m.cy) * stesso identico set di feature dell'anteprima modello (modulo rotazione+traslazione) - UCS match calcolato sul baricentro delle feature warpate, non su (cx, cy) → coerente con UCS anteprima Fallback (variant_idx == -1, es. ricetta caricata da save_model prima di questo commit): usa estrazione warpata legacy. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
merge: match overlay edges+UCS, no ROI
2026-05-05 11:02:04 +02:00 · 2026-05-05 10:55:54 +02:00 · 2026-05-05 10:55:54 +02:00 · 2026-05-05 10:48:58 +02:00 · 2026-05-05 10:48:58 +02:00 · 2026-05-05 10:41:26 +02:00
9 changed files with 1213 additions and 40 deletions
@@ -8,3 +8,5 @@ __pycache__/
 .DS_Store
 *.log
 models/
 # Ricette pre-trained (generate da utente, non versionare)
 recipes/*.npz
@@ -152,11 +152,103 @@ def _cache_key(template_bgr: np.ndarray, mask: np.ndarray | None) -> str:
    return h.hexdigest()
 def _self_validate(template_bgr: np.ndarray, params: dict,
                   mask: np.ndarray | None = None) -> dict:
    """Halcon-style self-validation: train il matcher coi parametri tentativi
    e verifica che il template stesso sia trovato con recall ≥ 1.0.
    Se recall < target o score basso, regola i parametri:
    - alza weak_grad se troppi edge spuri (recall solido ma molti picchi falsi)
    - abbassa strong_grad se troppe feature scartate (low feature count)
    - riduce pyramid_levels se variants[0].levels[top] ha <8 feature
    Halcon usa internamente questo loop in inspect_shape_model. Costo: 1
    train + 1 find sul template (~50ms su template 100x100). Ne vale la
    pena se evita match-time errors su scene reali.
    Mutates `params` in place e ritorna lo stesso dict per chaining.
    """
    # Import lazy: evita ciclo (line_matcher importa nulla da auto_tune)
    from pm2d.line_matcher import LineShapeMatcher
    # Caso degenerato: troppe poche feature pre-validation → riduci soglia
    if params.get("_n_strong_pixels", 0) < 30:
        params["weak_grad"] = max(15.0, params["weak_grad"] * 0.6)
        params["strong_grad"] = max(30.0, params["strong_grad"] * 0.6)
    # Train minimale: 1 sola pose orientazione 0 (range degenerato che
    # produce comunque 1 variante via fallback in _angle_list).
    m = LineShapeMatcher(
        num_features=params["num_features"],
        weak_grad=params["weak_grad"],
        strong_grad=params["strong_grad"],
        angle_range_deg=(0.0, 0.0),  # fallback _angle_list = [0.0]
        angle_step_deg=10.0,
        scale_range=(1.0, 1.0),
        spread_radius=params["spread_radius"],
        pyramid_levels=params["pyramid_levels"],
    )
    n_var = m.train(template_bgr, mask=mask)
    if n_var == 0:
        # Soglie troppo alte: nessuna variante generata → dimezza
        params["weak_grad"] = max(15.0, params["weak_grad"] * 0.5)
        params["strong_grad"] = max(30.0, params["strong_grad"] * 0.5)
        params["_validation"] = "fallback: soglie dimezzate (no variants)"
        return params
    # Verifica densita' feature al top-level (rischio collasso)
    top_lvl = m.variants[0].levels[-1]
    if top_lvl.n < 8 and params["pyramid_levels"] > 1:
        params["pyramid_levels"] = max(1, params["pyramid_levels"] - 1)
        params["_validation"] = (
            f"pyramid_levels ridotto a {params['pyramid_levels']} "
            f"(top aveva {top_lvl.n} feature)"
        )
        return params
    # Self-find: cerca il template stesso nella propria immagine
    h, w = template_bgr.shape[:2]
    # Embed template in scena leggermente più grande per evitare bordo
    pad = 20
    canvas = np.full(
        (h + 2 * pad, w + 2 * pad, 3 if template_bgr.ndim == 3 else 1),
        128, dtype=np.uint8,
    )
    canvas[pad:pad + h, pad:pad + w] = template_bgr
    matches = m.find(
        canvas, min_score=0.3, max_matches=5,
        verify_ncc=False,  # template stesso → NCC = 1 sempre, skip per velocita'
        refine_angle=False, subpixel=False,
        nms_iou_threshold=0.3,
    )
    if not matches:
        # Nessun match sul proprio template: parametri troppo restrittivi
        params["weak_grad"] = max(15.0, params["weak_grad"] * 0.7)
        params["strong_grad"] = max(30.0, params["strong_grad"] * 0.7)
        params["num_features"] = max(48, int(params["num_features"] * 0.8))
        params["_validation"] = "soglie/feature ridotte (no self-match)"
        return params
    # Misura score top match
    top_score = float(matches[0].score)
    params["_self_score"] = round(top_score, 3)
    if top_score < 0.7:
        # Score basso sul template stesso = parametri davvero subottimali
        params["weak_grad"] = max(15.0, params["weak_grad"] * 0.85)
        params["_validation"] = (
            f"weak_grad ridotto (self-score era {top_score:.2f})"
        )
    else:
        params["_validation"] = f"OK (self-score {top_score:.2f})"
    return params
 def auto_tune(
    template_bgr: np.ndarray,
    mask: np.ndarray | None = None,
    angle_tolerance_deg: float | None = None,
    angle_center_deg: float = 0.0,
    self_validate: bool = True,
 ) -> dict:
    """Analizza template e ritorna dict parametri suggeriti.
@@ -168,6 +260,11 @@ def auto_tune(
    meccanico): training molto piu rapido (24x meno varianti per
    tol=15° vs 360° pieno).
    self_validate: se True (default), dopo la stima dei parametri
    esegue un dry-run del matching sul template stesso e regola
    weak_grad/strong_grad/pyramid_levels se i parametri tentativi
    non garantiscono auto-match (Halcon-style inspect_shape_model).
    Risultato cachato in-memory (LRU): ri-chiamare con stessa ROI è O(1).
    """
    ck = _cache_key(template_bgr, mask)
@@ -265,7 +362,15 @@ def auto_tune(
        "_symmetry_order": sym["order"],
        "_symmetry_conf": round(sym["confidence"], 2),
        "_orient_entropy": round(stats["orient_entropy"], 2),
        "_n_strong_pixels": stats["n_strong"],
    }
    # Halcon-style self-validation: dry-run training+find sul template per
    # auto-correggere parametri tentativi che non garantirebbero match.
    if self_validate:
        result = _self_validate(template_bgr, result, mask=mask)
        # Round numerici dopo eventuali aggiustamenti
        result["weak_grad"] = round(result["weak_grad"], 1)
        result["strong_grad"] = round(result["strong_grad"], 1)
    # Store in LRU cache
    _TUNE_CACHE[ck] = dict(result)
    _TUNE_CACHE.move_to_end(ck)
@@ -0,0 +1,217 @@
 """CLI validation harness per LineShapeMatcher.
 Usage:
    python -m pm2d.eval dataset.json [opzioni]
 Formato dataset (JSON):
    {
      "template": "path/to/template.png",
      "mask": "path/to/mask.png",  # opzionale
      "params": {                   # opzionali, override su matcher init
        "use_polarity": true,
        "angle_step_deg": 5,
        ...
      },
      "find_params": {              # opzionali, passati a find()
        "min_score": 0.6,
        "use_soft_score": true,
        ...
      },
      "scenes": [
        {
          "image": "path/to/scene1.png",
          "ground_truth": [
            {"cx": 320.0, "cy": 240.0, "angle_deg": 12.0,
             "scale": 1.0, "tolerance_px": 5.0,
             "tolerance_deg": 3.0}
          ]
        }
      ]
    }
 Output: report precision/recall/IoU/timing per ogni scena + aggregati.
 """
 from __future__ import annotations
 import argparse
 import json
 import math
 import sys
 import time
 from pathlib import Path
 import cv2
 import numpy as np
 from pm2d.line_matcher import LineShapeMatcher, _poly_iou, _oriented_bbox_polygon
 def _load_image(path: str | Path) -> np.ndarray:
    img = cv2.imread(str(path), cv2.IMREAD_UNCHANGED)
    if img is None:
        raise FileNotFoundError(f"Immagine non trovata: {path}")
    if img.ndim == 2:
        img = cv2.cvtColor(img, cv2.COLOR_GRAY2BGR)
    return img
 def _gt_to_poly(gt: dict, tw: int, th: int) -> np.ndarray:
    """Costruisce bbox poligonale per un ground truth."""
    s = float(gt.get("scale", 1.0))
    return _oriented_bbox_polygon(
        float(gt["cx"]), float(gt["cy"]),
        tw * s, th * s, float(gt["angle_deg"]),
    )
 def _match_to_gt(match, gt: dict, tw: int, th: int,
                 iou_thr: float = 0.3) -> bool:
    """True se il match corrisponde al ground truth.
    Criterio: distanza centro <= tolerance_px AND |angle_deg - gt| <= tolerance_deg
    OR IoU bbox >= iou_thr (fallback per pose con tolerance ampie).
    """
    tol_px = float(gt.get("tolerance_px", 5.0))
    tol_deg = float(gt.get("tolerance_deg", 3.0))
    dx = match.cx - float(gt["cx"])
    dy = match.cy - float(gt["cy"])
    dist = math.hypot(dx, dy)
    da = abs((match.angle_deg - float(gt["angle_deg"]) + 180) % 360 - 180)
    if dist <= tol_px and da <= tol_deg:
        return True
    # Fallback IoU
    poly_gt = _gt_to_poly(gt, tw, th)
    poly_m = match.bbox_poly
    if _poly_iou(poly_m, poly_gt) >= iou_thr:
        return True
    return False
 def evaluate_scene(matcher: LineShapeMatcher, scene_bgr: np.ndarray,
                   gt_list: list[dict], find_params: dict,
                   tw: int, th: int) -> dict:
    """Esegue match e calcola TP/FP/FN per una scena."""
    t0 = time.time()
    matches = matcher.find(scene_bgr, **find_params)
    elapsed = time.time() - t0
    gt_matched = [False] * len(gt_list)
    match_is_tp = [False] * len(matches)
    iou_per_match = [0.0] * len(matches)
    for i, m in enumerate(matches):
        for j, gt in enumerate(gt_list):
            if gt_matched[j]:
                continue
            if _match_to_gt(m, gt, tw, th):
                gt_matched[j] = True
                match_is_tp[i] = True
                # Calcolo IoU per metrica
                poly_gt = _gt_to_poly(gt, tw, th)
                iou_per_match[i] = _poly_iou(m.bbox_poly, poly_gt)
                break
    tp = sum(match_is_tp)
    fp = len(matches) - tp
    fn = len(gt_list) - sum(gt_matched)
    return {
        "n_matches": len(matches),
        "n_gt": len(gt_list),
        "tp": tp, "fp": fp, "fn": fn,
        "find_time_s": elapsed,
        "iou_mean": float(np.mean([i for i, t in zip(iou_per_match, match_is_tp) if t])
                          if tp > 0 else 0.0),
        "diag": (matcher.get_last_diag()
                 if hasattr(matcher, "get_last_diag") else None),
    }
 def run(dataset_path: str, scene_filter: str | None = None,
        verbose: bool = False) -> dict:
    """Esegue eval su dataset, ritorna report aggregato."""
    dataset_path = Path(dataset_path)
    base = dataset_path.parent
    with open(dataset_path) as f:
        ds = json.load(f)
    template = _load_image(base / ds["template"])
    mask = None
    if ds.get("mask"):
        mask_img = cv2.imread(str(base / ds["mask"]), cv2.IMREAD_GRAYSCALE)
        if mask_img is not None:
            mask = (mask_img > 128).astype(np.uint8) * 255
    init_params = ds.get("params", {})
    find_params = ds.get("find_params", {})
    matcher = LineShapeMatcher(**init_params)
    n_var = matcher.train(template, mask=mask)
    tw, th = matcher.template_size
    print(f"Template: {ds['template']} ({tw}x{th}), {n_var} varianti")
    print(f"Param matcher: {init_params}")
    print(f"Param find:    {find_params}")
    print()
    scenes = ds["scenes"]
    if scene_filter:
        scenes = [s for s in scenes if scene_filter in s["image"]]
    rows = []
    tot_tp = tot_fp = tot_fn = 0
    tot_time = 0.0
    for sc in scenes:
        scene = _load_image(base / sc["image"])
        gt = sc.get("ground_truth", [])
        result = evaluate_scene(matcher, scene, gt, find_params, tw, th)
        rows.append({"scene": sc["image"], **result})
        tot_tp += result["tp"]; tot_fp += result["fp"]; tot_fn += result["fn"]
        tot_time += result["find_time_s"]
        prec = result["tp"] / max(1, result["tp"] + result["fp"])
        rec = result["tp"] / max(1, result["tp"] + result["fn"])
        line = (f"  {sc['image']:30s}  "
                f"TP={result['tp']} FP={result['fp']} FN={result['fn']}  "
                f"P={prec:.2f} R={rec:.2f}  "
                f"IoU={result['iou_mean']:.2f}  "
                f"t={result['find_time_s']*1000:.0f}ms")
        print(line)
        if verbose and result["diag"] and hasattr(matcher, "_format_diag"):
            print(f"     diag: {matcher._format_diag(result['diag'])}")
    # Aggregati
    precision = tot_tp / max(1, tot_tp + tot_fp)
    recall = tot_tp / max(1, tot_tp + tot_fn)
    f1 = 2 * precision * recall / max(1e-9, precision + recall)
    print()
    print(f"AGGREGATO: precision={precision:.3f} recall={recall:.3f} "
          f"F1={f1:.3f}  TP={tot_tp} FP={tot_fp} FN={tot_fn}")
    print(f"TIME: total={tot_time:.2f}s avg={tot_time / max(1, len(scenes)) * 1000:.0f}ms/scene")
    return {
        "precision": precision, "recall": recall, "f1": f1,
        "tp": tot_tp, "fp": tot_fp, "fn": tot_fn,
        "total_time_s": tot_time, "n_scenes": len(scenes),
        "per_scene": rows,
    }
 def main(argv: list[str] | None = None) -> int:
    p = argparse.ArgumentParser(
        description="pm2d-eval: validation harness per LineShapeMatcher"
    )
    p.add_argument("dataset", help="JSON dataset (template + scenes + GT)")
    p.add_argument("--scene-filter", default=None,
                   help="Filtro substring sui nomi scena (debug)")
    p.add_argument("--verbose", "-v", action="store_true",
                   help="Stampa diag dict per ogni scena")
    p.add_argument("--out", default=None,
                   help="Salva report JSON su file")
    args = p.parse_args(argv)
    report = run(args.dataset, scene_filter=args.scene_filter,
                 verbose=args.verbose)
    if args.out:
        with open(args.out, "w") as f:
            json.dump(report, f, indent=2)
        print(f"Report salvato: {args.out}")
    return 0 if report["f1"] > 0.5 else 1
 if __name__ == "__main__":
    sys.exit(main())
@@ -127,6 +127,7 @@ class Match:
    scale: float
    score: float
    bbox_poly: np.ndarray  # (4, 2) float32 - 4 vertici ordinati (ruotato)
    variant_idx: int = -1  # indice variante usata (per overlay coerente)
@dataclass
@@ -241,13 +242,49 @@ class LineShapeMatcher:
            bins = np.clip(bins, 0, N_BINS - 1)
        return mag, bins
    def _hysteresis_mask(self, mag: np.ndarray) -> np.ndarray:
        """Edge mask con hysteresis (Halcon Contrast='auto' two-threshold).
        Procedura:
        1. seed = pixel con mag >= strong_grad (edge nitidi)
        2. weak = pixel con mag >= weak_grad (edge candidati)
        3. Espande seed dentro weak via componenti connesse 8-vicini
        Risultato: edge debole connesso a edge forte viene PROMOSSO a
        feature valida; edge debole isolato (rumore) viene SCARTATO.
        Riduce sia falsi-positivi (rumore puro) sia falsi-negativi
        (continuita' interrotta su edge sottili a basso contrasto).
        """
        weak = (mag >= self.weak_grad).astype(np.uint8)
        strong = (mag >= self.strong_grad).astype(np.uint8)
        # connectedComponentsWithStats su weak: per ogni componente,
        # se contiene almeno un pixel strong → tutto componente accettato
        n_lab, labels = cv2.connectedComponents(weak, connectivity=8)
        if n_lab <= 1:
            return strong.astype(bool)
        # Label dei pixel strong: marker per componenti da accettare
        strong_labels = np.unique(labels[strong > 0])
        strong_labels = strong_labels[strong_labels > 0]  # 0 = bg
        if len(strong_labels) == 0:
            return strong.astype(bool)
        # Mask = appartiene a label di componente "promosso"
        keep = np.isin(labels, strong_labels)
        return keep
    def _extract_features(
        self, mag: np.ndarray, bins: np.ndarray, mask: np.ndarray | None,
    ) -> tuple[np.ndarray, np.ndarray, np.ndarray]:
        if mask is not None:
            mag = np.where(mask > 0, mag, 0)
-        strong = mag >= self.strong_grad
+        # Halcon-style edge selection: hysteresis tra weak_grad e strong_grad.
-        ys, xs = np.where(strong)
+        # Edge weak connessi a edge strong sono inclusi (continuita' bordi).
        # Se weak_grad >= strong_grad → fallback a soglia singola strong.
        if self.weak_grad < self.strong_grad:
            edge = self._hysteresis_mask(mag)
        else:
            edge = mag >= self.strong_grad
        ys, xs = np.where(edge)
        if len(xs) == 0:
            return (np.zeros(0, np.int32),) * 3
        vals = mag[ys, xs]
@@ -476,8 +513,10 @@ class LineShapeMatcher:
        self.variants.clear()
        # Reset view list: template principale = view 0
        self._view_templates = [(gray.copy(), mask_full.copy())]
-        # Invalida cache feature di refine: il template e cambiato.
+        # Invalida cache: template/param cambiati → spread/feature obsoleti.
        self._refine_feat_cache = {}
        if hasattr(self, "_scene_cache"):
            self._scene_cache.clear()
        self._build_variants_for_view(gray, mask_full, view_idx=0)
        self._dedup_variants()
        return len(self.variants)
@@ -633,6 +672,51 @@ class LineShapeMatcher:
            raw[b] = d.astype(np.float32)
        return raw
    # --- Scene precompute cache (II Halcon-style) -----------------------
    _SCENE_CACHE_SIZE = 4
    def _scene_cache_key(self, gray: np.ndarray) -> str | None:
        """Hash compatto della scena + param che influenzano spread/density.
        Hash su prime 64KB della scena (sufficiente discriminante per
        scene fotografiche) + parametri matcher rilevanti. None se cache
        disabilitata (es. scene troppo piccole).
        """
        if gray.size < 100:
            return None
        try:
            import hashlib
            h = hashlib.md5()
            sample = gray.tobytes()[:65536]
            h.update(sample)
            h.update(f"|{gray.shape}|{gray.dtype}".encode())
            h.update(
                f"|{self.weak_grad}|{self.strong_grad}"
                f"|{self.spread_radius}|{self._n_bins}"
                f"|{self.pyramid_levels}".encode()
            )
            return h.hexdigest()
        except Exception:
            return None
    def _scene_cache_get(self, key: str) -> tuple | None:
        cache = getattr(self, "_scene_cache", None)
        if cache is None:
            return None
        v = cache.get(key)
        if v is not None:
            cache.move_to_end(key)
        return v
    def _scene_cache_put(self, key: str, value: tuple) -> None:
        from collections import OrderedDict
        if not hasattr(self, "_scene_cache"):
            self._scene_cache = OrderedDict()
        self._scene_cache[key] = value
        self._scene_cache.move_to_end(key)
        while len(self._scene_cache) > self._SCENE_CACHE_SIZE:
            self._scene_cache.popitem(last=False)
    def _spread_bitmap(self, gray: np.ndarray) -> np.ndarray:
        """Spread bitmap: bit b acceso dove bin b è presente nel raggio.
@@ -1273,6 +1357,7 @@ class LineShapeMatcher:
        min_recall: float = 0.0,
        use_soft_score: bool = False,
        subpixel_lm: bool = False,
        debug: bool = False,
    ) -> list[Match]:
        """
        scale_penalty: se > 0, riduce lo score per match a scala diversa da 1.0:
@@ -1290,6 +1375,32 @@ class LineShapeMatcher:
        if not self.variants:
            raise RuntimeError("Matcher non addestrato: chiamare train() prima.")
        # Diagnostic counter: traccia perche' candidati sono droppati lungo
        # la pipeline. Esposto via get_last_diag() o ritornato implicitamente
        # se debug=True (vedi sotto).
        diag = {
            "n_variants_total": len(self.variants),
            "n_variants_top_evaluated": 0,
            "n_variants_top_passed": 0,
            "n_variants_full_evaluated": 0,
            "n_raw_candidates": 0,
            "n_after_pre_nms": 0,
            "drop_ncc_low": 0,
            "drop_min_score_post_avg": 0,
            "drop_recall_low": 0,
            "drop_bbox_out_of_scene": 0,
            "drop_nms_iou": 0,
            "n_final": 0,
            "top_thresh_used": 0.0,
            "verify_threshold_used": float(verify_threshold),
            "min_score_used": float(min_score),
            "min_recall_used": float(min_recall),
            "use_polarity": bool(self.use_polarity),
            "use_soft_score": bool(use_soft_score),
            "subpixel_lm": bool(subpixel_lm),
        }
        self._last_diag = diag
        gray_full = self._to_gray(scene_bgr)
        # Applica ROI di ricerca: restringe scena a crop, ricorda offset per
        # ri-traslare le coordinate dei match a fine pipeline.
@@ -1304,18 +1415,31 @@ class LineShapeMatcher:
        else:
            gray0 = gray_full
            roi_offset = (0, 0)
        grays = [gray0]
        for _ in range(self.pyramid_levels - 1):
            grays.append(cv2.pyrDown(grays[-1]))
        top = len(grays) - 1
-        # Spread bitmap (uint8) al top level: 32× meno memoria della response
+        # Cache pre-compute scena (II Halcon-style): hash bytes scene + param
-        # map float32 → MOLTO più cache-friendly per _score_by_shift.
+        # gradient/spread → riusa spread piramide + density tra find()
-        spread_top = self._spread_bitmap(grays[top])
+        # consecutive con stessa scena (typical UI tuning: slider produce
-        bit_active_top = int(
+        # 10+ find() su scena identica). Risparmia ~80% del costo non-kernel.
-            sum(1 << b for b in range(self._n_bins)
+        cache_key = self._scene_cache_key(gray0)
-                if (spread_top & (spread_top.dtype.type(1) << b)).any())
+        cached = self._scene_cache_get(cache_key) if cache_key else None
-        )
+        if cached is not None:
            grays, spread_top, bit_active_top, density_top, spread0, \
                bit_active_full, density_full, top = cached
        else:
            grays = [gray0]
            for _ in range(self.pyramid_levels - 1):
                grays.append(cv2.pyrDown(grays[-1]))
            top = len(grays) - 1
            spread_top = self._spread_bitmap(grays[top])
            bit_active_top = int(
                sum(1 << b for b in range(self._n_bins)
                    if (spread_top & (spread_top.dtype.type(1) << b)).any())
            )
            density_top = _jit_popcount(spread_top)
            # spread0 + density_full computati piu sotto, quindi salvo dopo.
            spread0 = None
            bit_active_full = None
            density_full = None
        if nms_radius is None:
            nms_radius = max(8, min(self.template_size) // 2)
        # Pruning adattivo allo step angolare: con step piccolo (<= 3 deg)
@@ -1332,9 +1456,10 @@ class LineShapeMatcher:
            top_factor = max(top_factor, 0.7)
            cf_eff = 1
        top_thresh = min_score * top_factor
        diag["top_thresh_used"] = float(top_thresh)
        tw, th = self.template_size
-        density_top = _jit_popcount(spread_top)
+        # density_top gia' computato sopra (cache o miss)
        sf_top = 2 ** top
        bg_cache_top: dict[float, np.ndarray] = {}
        bg_cache_full: dict[float, np.ndarray] = {}
@@ -1417,6 +1542,7 @@ class LineShapeMatcher:
        kept_coarse: list[tuple[int, float]] = []
        all_top_scores: list[tuple[int, float]] = []
        diag["n_variants_top_evaluated"] = len(coarse_idx_list)
        # batch_top: usa kernel batch single-call con prange-esterno su
        # varianti. Vince su threadpool quando n_vars >> n_threads e quando
        # H*W top e' piccolo (overhead chiamate JIT > costo kernel).
@@ -1480,14 +1606,24 @@ class LineShapeMatcher:
        kept_variants.sort(key=lambda t: -t[1])
        max_vars_full = max(max_matches * 8, len(self.variants) // 2)
        kept_variants = kept_variants[:max_vars_full]
        diag["n_variants_top_passed"] = len(kept_coarse)
        diag["n_variants_full_evaluated"] = len(kept_variants)
-        # Full-res (parallelizzato) con bitmap
+        # Full-res (parallelizzato) con bitmap.
-        spread0 = self._spread_bitmap(gray0)
+        # Riusa cache se disponibile, altrimenti computa e salva.
-        bit_active_full = int(
+        if spread0 is None:
-            sum(1 << b for b in range(self._n_bins)
+            spread0 = self._spread_bitmap(gray0)
-                if (spread0 & (spread0.dtype.type(1) << b)).any())
+            bit_active_full = int(
-        )
+                sum(1 << b for b in range(self._n_bins)
-        density_full = _jit_popcount(spread0)
+                    if (spread0 & (spread0.dtype.type(1) << b)).any())
            )
            density_full = _jit_popcount(spread0)
            # Salva cache scena complete
            if cache_key is not None:
                self._scene_cache_put(cache_key, (
                    grays, spread_top, bit_active_top, density_top,
                    spread0, bit_active_full, density_full, top,
                ))
        for sc in unique_scales:
            bg_cache_full[sc] = _bg_for_scale(density_full, sc, 1)
@@ -1565,6 +1701,7 @@ class LineShapeMatcher:
                raw.append((float(vals[i]), int(xs[i]), int(ys[i]), vi))
        raw.sort(key=lambda c: -c[0])
        diag["n_raw_candidates"] = len(raw)
        # Mappa vi → score_map per subpixel/refinement
        score_maps = dict(candidates_per_var)
@@ -1596,6 +1733,7 @@ class LineShapeMatcher:
            preliminary_int.append((score, xi, yi, vi))
            if len(preliminary_int) >= pre_cap:
                break
        diag["n_after_pre_nms"] = len(preliminary_int)
        # Subpixel + refine + verify solo sui candidati pre-NMS (max pre_cap)
        kept: list[Match] = []
@@ -1642,6 +1780,7 @@ class LineShapeMatcher:
                    view_idx=getattr(var, "view_idx", 0),
                )
                if ncc < verify_threshold:
                    diag["drop_ncc_low"] += 1
                    continue
                score_f = (float(score_f) + max(0.0, ncc)) * 0.5
            # Soft-margin gradient similarity: sostituisce o integra lo
@@ -1656,6 +1795,7 @@ class LineShapeMatcher:
            # abbattere lo shape-score sotto la soglia user. Senza questo
            # check apparivano match con score < min_score (UI confusing).
            if float(score_f) < min_score:
                diag["drop_min_score_post_avg"] += 1
                continue
            # Feature recall (Halcon MinScore-style): conta quante feature
@@ -1667,6 +1807,7 @@ class LineShapeMatcher:
                    spread0, var, cx_f, cy_f, ang_f,
                )
                if recall < min_recall:
                    diag["drop_recall_low"] += 1
                    continue
            # Ri-traslo coord da spazio crop ROI a spazio scena originale.
@@ -1690,6 +1831,7 @@ class LineShapeMatcher:
                )
                inside_ratio = float(inter) / poly_area
                if inside_ratio < 0.75:
                    diag["drop_bbox_out_of_scene"] += 1
                    continue
            # Penalità scala opzionale: score degrada con distanza da 1.0
            if scale_penalty > 0.0 and var.scale != 1.0:
@@ -1714,6 +1856,7 @@ class LineShapeMatcher:
                    dup = True
                    break
            if dup:
                diag["drop_nms_iou"] += 1
                continue
            kept.append(Match(
                cx=cx_out, cy=cy_out,
@@ -1721,7 +1864,39 @@ class LineShapeMatcher:
                scale=var.scale,
                score=score_f,
                bbox_poly=poly,
                variant_idx=int(vi),
            ))
            if len(kept) >= max_matches:
                break
        diag["n_final"] = len(kept)
        if debug:
            # Debug mode: stampa diagnostica su stderr per visibilita' immediata.
            import sys as _sys
            _sys.stderr.write(f"[pm2d.find debug] {self._format_diag(diag)}\n")
        return kept
    def _format_diag(self, diag: dict) -> str:
        """Formatta dict diagnostica in una linea leggibile."""
        return (
            f"vars: {diag['n_variants_total']} -> "
            f"top_eval={diag['n_variants_top_evaluated']} "
            f"top_pass={diag['n_variants_top_passed']} "
            f"full_eval={diag['n_variants_full_evaluated']} | "
            f"raw={diag['n_raw_candidates']} "
            f"pre_nms={diag['n_after_pre_nms']} -> "
            f"drop[ncc={diag['drop_ncc_low']}, "
            f"score={diag['drop_min_score_post_avg']}, "
            f"recall={diag['drop_recall_low']}, "
            f"bbox={diag['drop_bbox_out_of_scene']}, "
            f"nms={diag['drop_nms_iou']}] = "
            f"final={diag['n_final']} (top_thresh={diag['top_thresh_used']:.2f})"
        )
    def get_last_diag(self) -> dict | None:
        """Ritorna dict diagnostica dell'ultima chiamata find().
        Halcon-equivalent: oggi inspect_shape_model espone parziali contatori.
        Util per debug 'perche' 0 match', tuning interattivo, validation.
        Vedi diag keys per significato (n_variants_top_evaluated, drop_*, ...).
        """
        return getattr(self, "_last_diag", None)
@@ -131,23 +131,102 @@ def _encode_png(img: np.ndarray) -> bytes:
 def _draw_matches(scene: np.ndarray, matches: list[Match],
-                   template_gray: np.ndarray | None) -> np.ndarray:
+                   template_gray: np.ndarray | None,
                   matcher: "LineShapeMatcher | None" = None) -> np.ndarray:
    """Disegna match annotati sulla scena.
    Se matcher e' passato, usa la stessa pipeline di edge filtering
    (hysteresis weak/strong_grad) e selezione feature usata in training,
    cosi' l'overlay nel match riflette ESATTAMENTE quello che l'utente
    ha visto nel preview "Anteprima edge". Inoltre disegna UCS
    (asse X rosso, Y verde) sul centro pose del match.
    Senza matcher: fallback Canny (legacy).
    """
    out = scene.copy()
    H, W = scene.shape[:2]
    palette = [
        (0, 255, 0), (0, 200, 255), (255, 100, 100), (255, 200, 0),
        (200, 0, 255), (100, 255, 200), (255, 0, 0), (0, 255, 255),
    ]
    bin_colors = [
        (255, 0, 0), (255, 128, 0), (255, 255, 0), (0, 255, 0),
        (0, 255, 255), (0, 128, 255), (0, 0, 255), (255, 0, 255),
        (255, 100, 100), (255, 180, 100), (255, 230, 100), (180, 255, 100),
        (100, 255, 200), (100, 180, 255), (180, 100, 255), (255, 100, 200),
    ]
    for i, m in enumerate(matches):
        color = palette[i % len(palette)]
-        if template_gray is not None:
+        # Posizione UCS: baricentro feature warpate (default = cx, cy se non disponibile).
        # Mantiene coerenza con anteprima modello che mostra UCS sul baricentro.
        ucs_x, ucs_y = float(m.cx), float(m.cy)
        if template_gray is not None and matcher is not None:
            t = template_gray
            th, tw = t.shape
            edge = cv2.Canny(t, 50, 150)
            cx_t = (tw - 1) / 2.0; cy_t = (th - 1) / 2.0
            M = cv2.getRotationMatrix2D((cx_t, cy_t), m.angle_deg, m.scale)
            M[0, 2] += m.cx - cx_t
            M[1, 2] += m.cy - cy_t
            # Background edge filtrati: warpa template + hysteresis
            warped_gray = cv2.warpAffine(
                t, M, (W, H), flags=cv2.INTER_LINEAR, borderValue=0)
            mag, _ = matcher._gradient(warped_gray)
            if matcher.weak_grad < matcher.strong_grad:
                edge_mask = matcher._hysteresis_mask(mag)
            else:
                edge_mask = mag >= matcher.strong_grad
            if edge_mask.any():
                bg_overlay = np.zeros_like(out)
                dark = tuple(int(c * 0.35) for c in color)
                bg_overlay[edge_mask] = dark
                out = cv2.addWeighted(out, 1.0, bg_overlay, 0.7, 0)
            # Feature reali del matcher: usa quelle pre-computate della
            # variante che ha generato il match. Stesse identiche feature
            # mostrate nell'anteprima modello (ruotate/scalate alla pose).
            vi = getattr(m, "variant_idx", -1)
            fx_scene = fy_scene = fb_arr = None
            if 0 <= vi < len(matcher.variants):
                lvl0 = matcher.variants[vi].levels[0]
                # dx/dy sono offsets relativi al CENTRO del template warpato
                # nelle coordinate del kernel template (gia' pre-ruotate
                # all'angolo della variante grezza). Per coerenza con la
                # pose finale m.angle_deg (post-refine), ri-rotazione del
                # delta angolare (m.angle_deg - var.angle_deg).
                var = matcher.variants[vi]
                dang = np.deg2rad(m.angle_deg - var.angle_deg)
                ca, sa = np.cos(dang), np.sin(dang)
                dxr = lvl0.dx * ca + lvl0.dy * sa
                dyr = -lvl0.dx * sa + lvl0.dy * ca
                fx_scene = m.cx + dxr
                fy_scene = m.cy + dyr
                fb_arr = lvl0.bin
            else:
                # Fallback: estrai feature dal warpato (perde precisione)
                _, bins_w = matcher._gradient(warped_gray)
                fx, fy, fb = matcher._extract_features(mag, bins_w, None)
                fx_scene = fx.astype(np.float32)
                fy_scene = fy.astype(np.float32)
                fb_arr = fb
            # Disegna feature
            for k in range(len(fx_scene)):
                px = int(round(float(fx_scene[k])))
                py = int(round(float(fy_scene[k])))
                if 0 <= px < W and 0 <= py < H:
                    bcol = bin_colors[int(fb_arr[k]) % len(bin_colors)]
                    cv2.circle(out, (px, py), 2, bcol, -1, cv2.LINE_AA)
            # UCS sul baricentro feature (in scene coords)
            if len(fx_scene) > 0:
                ucs_x = float(np.mean(fx_scene))
                ucs_y = float(np.mean(fy_scene))
        elif template_gray is not None:
            # Senza matcher: legacy Canny
            t = template_gray
            th, tw = t.shape
            cx_t = (tw - 1) / 2.0; cy_t = (th - 1) / 2.0
            M = cv2.getRotationMatrix2D((cx_t, cy_t), m.angle_deg, m.scale)
            M[0, 2] += m.cx - cx_t
            M[1, 2] += m.cy - cy_t
            edge = cv2.Canny(t, 50, 150)
            warped = cv2.warpAffine(edge, M, (W, H),
                                     flags=cv2.INTER_NEAREST, borderValue=0)
            mask = warped > 0
@@ -155,20 +234,34 @@ def _draw_matches(scene: np.ndarray, matches: list[Match],
                overlay = np.zeros_like(out)
                overlay[mask] = color
                out[mask] = (0.3 * out[mask] + 0.7 * overlay[mask]).astype(np.uint8)
-        poly = m.bbox_poly.astype(np.int32).reshape(-1, 1, 2)
+        # bbox poly e linea-marker rimossi (richiesta utente "togli la ROI"):
-        cv2.polylines(out, [poly], True, color, 2, cv2.LINE_AA)
+        # UCS + edge filtrati gia' identificano pose e orientamento.
-        p0 = tuple(m.bbox_poly[0].astype(int))
+        cx, cy = int(round(ucs_x)), int(round(ucs_y))
-        p1 = tuple(m.bbox_poly[1].astype(int))
+        # UCS sul centro pose match (richiesta utente: come nell'anteprima
-        cv2.line(out, p0, p1, color, 4, cv2.LINE_AA)
+        # modello). Asse X rosso destra, Y verde basso (image y-down).
-        cx, cy = int(round(m.cx)), int(round(m.cy))
+        # Lunghezza derivata dalla diagonale bbox per scala-invariante.
        cv2.drawMarker(out, (cx, cy), color, cv2.MARKER_CROSS, 22, 2, cv2.LINE_AA)
        L = int(np.linalg.norm(m.bbox_poly[1] - m.bbox_poly[0])) // 2
-        a = np.deg2rad(m.angle_deg)
+        if L < 10:
-        cv2.arrowedLine(out, (cx, cy),
+            L = 30  # fallback se bbox degenere
-                        (int(cx + L * np.cos(a)), int(cy - L * np.sin(a))),
+        ax = np.deg2rad(m.angle_deg)
-                        color, 2, cv2.LINE_AA, tipLength=0.2)
+        # X axis ruotato (rosso)
        x_end = (int(cx + L * np.cos(ax)), int(cy - L * np.sin(ax)))
        cv2.arrowedLine(out, (cx, cy), x_end,
                        (0, 0, 255), 2, cv2.LINE_AA, tipLength=0.2)
        cv2.putText(out, "X", (x_end[0] + 4, x_end[1] + 5),
                    cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 255), 1, cv2.LINE_AA)
        # Y axis perpendicolare (verde, +90° in image coords = giu' visivo)
        y_end = (int(cx + L * np.cos(ax + np.pi / 2)),
                 int(cy - L * np.sin(ax + np.pi / 2)))
        cv2.arrowedLine(out, (cx, cy), y_end,
                        (0, 255, 0), 2, cv2.LINE_AA, tipLength=0.2)
        cv2.putText(out, "Y", (y_end[0] + 4, y_end[1] + 12),
                    cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 255, 0), 1, cv2.LINE_AA)
        # Origine UCS: cerchio bianco con bordo nero
        cv2.circle(out, (cx, cy), 4, (0, 0, 0), -1, cv2.LINE_AA)
        cv2.circle(out, (cx, cy), 3, (255, 255, 255), -1, cv2.LINE_AA)
        label = f"#{i+1} {m.angle_deg:.0f}d s={m.scale:.2f} {m.score:.2f}"
-        cv2.putText(out, label, (cx + 8, cy - 8),
+        cv2.putText(out, label, (cx + 12, cy - 12),
                    cv2.FONT_HERSHEY_SIMPLEX, 0.5, color, 2, cv2.LINE_AA)
    return out
@@ -217,6 +310,7 @@ class MatchResp(BaseModel):
    find_time: float
    num_variants: int
    annotated_id: str
    diag: dict | None = None  # CC: diagnostica pipeline (drop reasons)
 class TuneParams(BaseModel):
@@ -510,7 +604,7 @@ def match(p: MatchParams):
    # Render annotated image
    tg = cv2.cvtColor(roi_img, cv2.COLOR_BGR2GRAY)
-    annotated = _draw_matches(scene, matches, tg)
+    annotated = _draw_matches(scene, matches, tg, matcher=m)
    ann_id = _store_image(annotated)
    return MatchResp(
@@ -521,6 +615,7 @@ def match(p: MatchParams):
        ) for m_ in matches],
        train_time=t_train, find_time=t_find,
        num_variants=n, annotated_id=ann_id,
        diag=m.get_last_diag() if hasattr(m, "get_last_diag") else None,
    )
@@ -586,7 +681,7 @@ def match_simple(p: SimpleMatchParams):
    t_find = time.time() - t0
    tg = cv2.cvtColor(roi_img, cv2.COLOR_BGR2GRAY)
-    annotated = _draw_matches(scene, matches, tg)
+    annotated = _draw_matches(scene, matches, tg, matcher=m)
    ann_id = _store_image(annotated)
    return MatchResp(
@@ -596,6 +691,7 @@ def match_simple(p: SimpleMatchParams):
        ) for mt in matches],
        train_time=t_train, find_time=t_find,
        num_variants=n, annotated_id=ann_id,
        diag=m.get_last_diag() if hasattr(m, "get_last_diag") else None,
    )
@@ -607,7 +703,9 @@ def tune(p: TuneParams):
    x, y, w, h = p.roi
    roi_img = model[y:y + h, x:x + w]
    t = auto_tune(roi_img)
-    return {k: v for k, v in t.items() if not k.startswith("_")}
+    # Esponi parametri tecnici + meta diagnostica (_self_score, _validation,
    # _symmetry_order, _orient_entropy) per feedback UI.
    return t
 # --- V: Save/Load ricette pre-trained ---
@@ -626,6 +724,107 @@ class SaveRecipeParams(BaseModel):
    name: str  # nome file ricetta (no path)
 class EdgePreviewParams(BaseModel):
    model_id: str
    roi: list[int]
    weak_grad: float = 30.0
    strong_grad: float = 60.0
    num_features: int = 96
    min_feature_spacing: int = 3
    use_polarity: bool = False
@app.post("/preview_edges")
 def preview_edges(p: EdgePreviewParams):
    """Estrae edge feature dalla ROI con i parametri dati e ritorna
    immagine annotata con i pixel selezionati come overlay.
    Permette tuning interattivo delle soglie weak/strong_grad e
    num_features per "togliere le sporcizie" (rumore di sfondo,
    edge spuri) prima di trainare il matcher vero.
    """
    model = _load_image(p.model_id)
    if model is None:
        raise HTTPException(404, "Modello non trovato")
    x, y, w, h = p.roi
    H_m, W_m = model.shape[:2]
    x = max(0, min(int(x), W_m - 1)); y = max(0, min(int(y), H_m - 1))
    w = max(1, min(int(w), W_m - x)); h = max(1, min(int(h), H_m - y))
    roi_img = model[y:y + h, x:x + w]
    # Matcher temporaneo solo per estrazione feature (no train completo)
    m = LineShapeMatcher(
        weak_grad=p.weak_grad,
        strong_grad=p.strong_grad,
        num_features=p.num_features,
        min_feature_spacing=p.min_feature_spacing,
        use_polarity=p.use_polarity,
    )
    gray = cv2.cvtColor(roi_img, cv2.COLOR_BGR2GRAY) if roi_img.ndim == 3 else roi_img
    mag, bins = m._gradient(gray)
    fx, fy, fb = m._extract_features(mag, bins, None)
    # Mostra anche i pixel "weak/strong" come heatmap di sfondo
    out = roi_img.copy() if roi_img.ndim == 3 else cv2.cvtColor(roi_img, cv2.COLOR_GRAY2BGR)
    # Overlay magnitude leggera
    mag_norm = np.clip(mag / max(1.0, mag.max()) * 255, 0, 255).astype(np.uint8)
    mag_color = cv2.applyColorMap(mag_norm, cv2.COLORMAP_BONE)
    out = cv2.addWeighted(out, 0.6, mag_color, 0.4, 0)
    # Pixel "strong" con hysteresis: contorno verde scuro tenue
    if m.weak_grad < m.strong_grad:
        edge_mask = m._hysteresis_mask(mag).astype(np.uint8) * 255
    else:
        edge_mask = (mag >= m.strong_grad).astype(np.uint8) * 255
    edge_overlay = np.zeros_like(out)
    edge_overlay[edge_mask > 0] = (0, 80, 0)  # verde scuro
    out = cv2.addWeighted(out, 1.0, edge_overlay, 0.5, 0)
    # Feature scelte: cerchietti colorati per bin
    bin_colors = [
        (255, 0, 0), (255, 128, 0), (255, 255, 0), (0, 255, 0),
        (0, 255, 255), (0, 128, 255), (0, 0, 255), (255, 0, 255),
        (255, 100, 100), (255, 180, 100), (255, 230, 100), (180, 255, 100),
        (100, 255, 200), (100, 180, 255), (180, 100, 255), (255, 100, 200),
    ]
    for i in range(len(fx)):
        b = int(fb[i])
        col = bin_colors[b % len(bin_colors)]
        cv2.circle(out, (int(fx[i]), int(fy[i])), 2, col, -1, cv2.LINE_AA)
    # UCS sul baricentro feature (richiesta utente): assi X rosso, Y verde
    bary_cx = bary_cy = None
    if len(fx) > 0:
        bary_cx = float(np.mean(fx))
        bary_cy = float(np.mean(fy))
        bx, by = int(round(bary_cx)), int(round(bary_cy))
        axis_len = max(20, int(0.15 * max(out.shape[:2])))
        # X axis (rosso, verso destra)
        cv2.arrowedLine(out, (bx, by), (bx + axis_len, by),
                        (0, 0, 255), 2, cv2.LINE_AA, tipLength=0.2)
        cv2.putText(out, "X", (bx + axis_len + 4, by + 5),
                    cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 0, 255), 1, cv2.LINE_AA)
        # Y axis (verde, verso il basso = convenzione image y-down)
        cv2.arrowedLine(out, (bx, by), (bx, by + axis_len),
                        (0, 255, 0), 2, cv2.LINE_AA, tipLength=0.2)
        cv2.putText(out, "Y", (bx + 4, by + axis_len + 12),
                    cv2.FONT_HERSHEY_SIMPLEX, 0.5, (0, 255, 0), 1, cv2.LINE_AA)
        # Origine: cerchio bianco con bordo nero
        cv2.circle(out, (bx, by), 4, (0, 0, 0), -1, cv2.LINE_AA)
        cv2.circle(out, (bx, by), 3, (255, 255, 255), -1, cv2.LINE_AA)
    img_id = _store_image(out)
    n_edge_strong = int((mag >= m.strong_grad).sum())
    n_edge_total = int(edge_mask.sum() / 255)
    return {
        "preview_id": img_id,
        "n_features": len(fx),
        "n_edge_strong": n_edge_strong,
        "n_edge_after_hysteresis": n_edge_total,
        "mag_max": float(mag.max()),
        "mag_p50": float(np.percentile(mag, 50)),
        "mag_p85": float(np.percentile(mag, 85)),
        "ucs_baricentro": (
            {"cx": round(bary_cx, 2), "cy": round(bary_cy, 2)}
            if bary_cx is not None else None
        ),
    }
@app.post("/recipes")
 def save_recipe(p: SaveRecipeParams):
    """Allena matcher e salva su disco come ricetta riutilizzabile."""
@@ -674,6 +873,103 @@ def list_recipes():
    return {"files": files, "dir": str(RECIPES_DIR)}
 # Cache di matcher caricati da .npz (V feature). Key: nome ricetta.
 _RECIPE_MATCHERS: OrderedDict = OrderedDict()
 _RECIPE_MATCHERS_SIZE = 4
@app.post("/recipes/{name}/load")
 def load_recipe(name: str):
    """Carica ricetta .npz e popola cache matcher in memoria.
    Una volta caricata, /match_recipe la usa direttamente senza
    re-train. Halcon-equivalent read_shape_model + handle.
    """
    safe_name = "".join(c for c in name if c.isalnum() or c in "._-")
    if not safe_name.endswith(".npz"):
        safe_name += ".npz"
    path = RECIPES_DIR / safe_name
    if not path.is_file():
        raise HTTPException(404, f"Ricetta non trovata: {safe_name}")
    m = LineShapeMatcher.load_model(str(path))
    _RECIPE_MATCHERS[safe_name] = m
    _RECIPE_MATCHERS.move_to_end(safe_name)
    while len(_RECIPE_MATCHERS) > _RECIPE_MATCHERS_SIZE:
        _RECIPE_MATCHERS.popitem(last=False)
    return {
        "name": safe_name,
        "n_variants": len(m.variants),
        "template_size": list(m.template_size),
        "use_polarity": m.use_polarity,
    }
 class RecipeMatchParams(BaseModel):
    recipe: str
    scene_id: str
    # Solo find-time params (training gia' fatto offline)
    min_score: float = 0.65
    max_matches: int = 25
    min_recall: float = 0.0
    use_soft_score: bool = False
    subpixel_lm: bool = False
    nms_iou_threshold: float = 0.3
    coarse_stride: int = 1
    pyramid_propagate: bool = False
    greediness: float = 0.0
    refine_pose_joint: bool = False
    search_roi: list[int] | None = None
    verify_threshold: float = 0.5
    scale_penalty: float = 0.0
@app.post("/match_recipe", response_model=MatchResp)
 def match_recipe(p: RecipeMatchParams):
    """Match con ricetta pre-trained: zero training, solo find."""
    safe_name = p.recipe if p.recipe.endswith(".npz") else f"{p.recipe}.npz"
    m = _RECIPE_MATCHERS.get(safe_name)
    if m is None:
        # Auto-load on demand
        path = RECIPES_DIR / safe_name
        if not path.is_file():
            raise HTTPException(404, f"Ricetta non trovata: {safe_name}")
        m = LineShapeMatcher.load_model(str(path))
        _RECIPE_MATCHERS[safe_name] = m
    scene = _load_image(p.scene_id)
    if scene is None:
        raise HTTPException(404, "Scena non trovata")
    search_roi_t = tuple(p.search_roi) if p.search_roi else None
    t0 = time.time()
    matches = m.find(
        scene,
        min_score=p.min_score, max_matches=p.max_matches,
        verify_threshold=p.verify_threshold,
        scale_penalty=p.scale_penalty,
        min_recall=p.min_recall,
        use_soft_score=p.use_soft_score,
        subpixel_lm=p.subpixel_lm,
        nms_iou_threshold=p.nms_iou_threshold,
        coarse_stride=p.coarse_stride,
        pyramid_propagate=p.pyramid_propagate,
        greediness=p.greediness,
        refine_pose_joint=p.refine_pose_joint,
        search_roi=search_roi_t,
    )
    t_find = time.time() - t0
    tg = m.template_gray if m.template_gray is not None else np.zeros((1, 1), np.uint8)
    annotated = _draw_matches(scene, matches, tg, matcher=m)
    ann_id = _store_image(annotated)
    return MatchResp(
        matches=[MatchResult(
            cx=mt.cx, cy=mt.cy, angle_deg=mt.angle_deg, scale=mt.scale,
            score=mt.score, bbox_poly=mt.bbox_poly.tolist(),
        ) for mt in matches],
        train_time=0.0, find_time=t_find,
        num_variants=len(m.variants), annotated_id=ann_id,
        diag=m.get_last_diag() if hasattr(m, "get_last_diag") else None,
    )
 # Mount static
 app.mount("/static", StaticFiles(directory=STATIC_DIR), name="static")
@@ -19,6 +19,7 @@ const PALETTE = [
 const state = {
  model: null, scene: null, roi: null, drag: null,
  matches: [], annotatedImg: null,
  active_recipe: null,  // V: ricetta caricata (string nome) o null
 };
 // ---------- Forms ----------
@@ -307,7 +308,43 @@ function setupROI() {
 }
 // ---------- Match action ----------
 async function doMatchRecipe() {
  if (!state.scene) { setStatus("Carica scena"); return; }
  setStatus(`Match ricetta ${state.active_recipe}...`);
  const hc = readHalconFlags();
  const body = {
    recipe: state.active_recipe,
    scene_id: state.scene.id,
    min_score: parseFloat(document.getElementById("p-min-score").value),
    max_matches: parseInt(document.getElementById("p-max-matches").value, 10),
    verify_threshold: 0.50,
    ...hc,
  };
  const r = await fetch("/match_recipe", {
    method: "POST",
    headers: { "Content-Type": "application/json" },
    body: JSON.stringify(body),
  });
  if (!r.ok) { setStatus(`Errore: ${await r.text()}`); return; }
  const data = await r.json();
  state.matches = data.matches;
  state.annotatedImg = await loadImage(
    `/image/${data.annotated_id}/raw?t=${Date.now()}`);
  renderScene();
  renderLegend();
  document.getElementById("t-train").textContent = "—";
  document.getElementById("t-find").textContent = `${data.find_time.toFixed(2)}s`;
  document.getElementById("t-var").textContent = data.num_variants;
  document.getElementById("t-match").textContent = data.matches.length;
  renderDiag(data.diag, data.matches.length);
  setStatus(`${data.matches.length} match trovati (ricetta ${state.active_recipe})`);
 }
 async function doMatch() {
  // Path V: ricetta caricata → bypass training, solo find su scena
  if (state.active_recipe) {
    return doMatchRecipe();
  }
  if (!state.model) { setStatus("Carica modello"); return; }
  if (!state.scene) { setStatus("Carica scena"); return; }
  if (!state.roi) { setStatus("Seleziona ROI sul modello"); return; }
@@ -373,6 +410,7 @@ async function doMatch() {
  document.getElementById("t-find").textContent = `${data.find_time.toFixed(2)}s`;
  document.getElementById("t-var").textContent = data.num_variants;
  document.getElementById("t-match").textContent = data.matches.length;
  renderDiag(data.diag, data.matches.length);
  setStatus(`${data.matches.length} match trovati${hasAdv ? " (avanzato)" : ""}`);
 }
@@ -400,6 +438,262 @@ function setStatus(s) {
 }
 // ---------- Init ----------
 // ---------- Edge preview (clean rumore) ----------
 let _epDebounce = null;
 let _epLastImg = null;
 async function fetchEdgePreview() {
  if (!state.model || !state.roi) {
    document.getElementById("edge-preview-info").textContent =
      "Disegna prima la ROI sul modello";
    return;
  }
  const body = {
    model_id: state.model.id,
    roi: state.roi,
    weak_grad: parseFloat(document.getElementById("ep-weak").value),
    strong_grad: parseFloat(document.getElementById("ep-strong").value),
    num_features: parseInt(document.getElementById("ep-nf").value, 10),
    min_feature_spacing: parseInt(document.getElementById("ep-sp").value, 10),
    use_polarity: document.getElementById("ep-pol").checked,
  };
  try {
    const r = await fetch("/preview_edges", {
      method: "POST",
      headers: { "Content-Type": "application/json" },
      body: JSON.stringify(body),
    });
    if (!r.ok) throw new Error(await r.text());
    const j = await r.json();
    _epLastImg = await loadImage(`/image/${j.preview_id}/raw?t=${Date.now()}`);
    drawEdgePreview();
    const ucs = j.ucs_baricentro
      ? ` | UCS=(${j.ucs_baricentro.cx},${j.ucs_baricentro.cy})`
      : "";
    document.getElementById("edge-preview-info").innerHTML =
      `<b>${j.n_features}</b> feature scelte (di ${j.n_edge_after_hysteresis} edge totali)<br>` +
      `mag: max=${j.mag_max.toFixed(0)} p50=${j.mag_p50.toFixed(0)} ` +
      `p85=${j.mag_p85.toFixed(0)}${ucs}`;
  } catch (e) {
    document.getElementById("edge-preview-info").textContent =
      `Errore preview: ${e.message}`;
  }
 }
 function drawEdgePreview() {
  const cnv = document.getElementById("c-edge-preview");
  if (!_epLastImg) return;
  const ctx = cnv.getContext("2d");
  // Fit-contain
  const r = Math.min(cnv.width / _epLastImg.width,
                     cnv.height / _epLastImg.height);
  const w = _epLastImg.width * r;
  const h = _epLastImg.height * r;
  const ox = (cnv.width - w) / 2;
  const oy = (cnv.height - h) / 2;
  ctx.fillStyle = "#000"; ctx.fillRect(0, 0, cnv.width, cnv.height);
  ctx.imageSmoothingEnabled = false;
  ctx.drawImage(_epLastImg, ox, oy, w, h);
 }
 function scheduleEdgePreview() {
  if (_epDebounce) clearTimeout(_epDebounce);
  _epDebounce = setTimeout(fetchEdgePreview, 200);
 }
 function bindEdgePreviewControls() {
  const slid = (id, valEl) => {
    const el = document.getElementById(id);
    const v = document.getElementById(valEl);
    el.addEventListener("input", () => {
      v.textContent = el.value;
      scheduleEdgePreview();
    });
  };
  slid("ep-weak", "ep-weak-v");
  slid("ep-strong", "ep-strong-v");
  slid("ep-nf", "ep-nf-v");
  slid("ep-sp", "ep-sp-v");
  document.getElementById("ep-pol").addEventListener("change",
    scheduleEdgePreview);
  // Auto-refresh quando il pannello viene aperto
  document.getElementById("edge-preview-panel").addEventListener("toggle",
    (e) => { if (e.target.open) fetchEdgePreview(); });
  document.getElementById("btn-edge-apply").addEventListener("click", () => {
    // Copia i valori correnti nei campi avanzati
    const map = {
      "ep-weak": "adv-weak_grad",
      "ep-strong": "adv-strong_grad",
      "ep-nf": "adv-num_features",
      "ep-sp": "adv-min_feature_spacing",
    };
    for (const [src, dst] of Object.entries(map)) {
      const dstEl = document.getElementById(dst);
      if (dstEl) dstEl.value = document.getElementById(src).value;
    }
    // use_polarity: alla checkbox della modalita Halcon
    const polCb = document.getElementById("hc-use-polarity");
    if (polCb) polCb.checked = document.getElementById("ep-pol").checked;
    // Apri pannello Avanzate per feedback
    const advDetails = document.querySelectorAll("#col-params details");
    advDetails.forEach((d) => { d.open = true; });
    alert("Parametri edge applicati. Esegui MATCH per usare i valori scelti.");
  });
 }
 // ---------- CC: Diagnostica match ----------
 function renderDiag(diag, n_matches) {
  const el = document.getElementById("diag-content");
  if (!diag) {
    el.innerHTML = '<em style="color:#888">Diagnostica non disponibile</em>';
    return;
  }
  const dropTotal = (diag.drop_ncc_low || 0) + (diag.drop_min_score_post_avg || 0)
    + (diag.drop_recall_low || 0) + (diag.drop_bbox_out_of_scene || 0)
    + (diag.drop_nms_iou || 0);
  // Hint contestuali se 0 match
  let hint = "";
  if (n_matches === 0) {
    if (diag.n_after_pre_nms === 0) {
      hint = `<div style="color:#f88; margin-top:6px">⚠ Nessun candidato sopra soglia.
        Prova: ↓ <b>min_score</b> o ↓ <b>top_thresh</b> (currently ${diag.top_thresh_used.toFixed(2)})</div>`;
    } else if (diag.drop_ncc_low > 0 && dropTotal === diag.drop_ncc_low) {
      hint = `<div style="color:#f88; margin-top:6px">⚠ ${diag.drop_ncc_low} candidati droppati da NCC.
        Prova: ↓ <b>verify_threshold</b> (filtro_fp più leggero)</div>`;
    } else if (diag.drop_min_score_post_avg > 0) {
      hint = `<div style="color:#f88; margin-top:6px">⚠ ${diag.drop_min_score_post_avg} match sotto min_score post-NCC.
        Prova: ↓ <b>min_score</b></div>`;
    } else if (diag.drop_recall_low > 0) {
      hint = `<div style="color:#f88; margin-top:6px">⚠ ${diag.drop_recall_low} match con recall < ${diag.min_recall_used}.
        Prova: ↓ <b>min_recall</b></div>`;
    } else if (diag.drop_bbox_out_of_scene > 0) {
      hint = `<div style="color:#f88; margin-top:6px">⚠ ${diag.drop_bbox_out_of_scene} match con bbox fuori scena.
        Centro derivato male: aumenta <b>min_score</b> o restringi <b>search_roi</b></div>`;
    }
  }
  const flags = [];
  if (diag.use_polarity) flags.push("polarity");
  if (diag.use_soft_score) flags.push("soft");
  if (diag.subpixel_lm) flags.push("subpix-LM");
  el.innerHTML = `
    <div><b>Pipeline pruning:</b></div>
    <div>varianti: ${diag.n_variants_total} → top_eval=${diag.n_variants_top_evaluated}
       → top_pass=${diag.n_variants_top_passed} → full_eval=${diag.n_variants_full_evaluated}</div>
    <div><b>Candidati:</b> raw=${diag.n_raw_candidates}
       → pre_nms=${diag.n_after_pre_nms} → final=${diag.n_final}</div>
    <div><b>Drop reasons:</b> NCC=${diag.drop_ncc_low}, score=${diag.drop_min_score_post_avg},
       recall=${diag.drop_recall_low}, bbox=${diag.drop_bbox_out_of_scene}, NMS=${diag.drop_nms_iou}</div>
    <div><b>Soglie:</b> top=${diag.top_thresh_used.toFixed(2)},
       min_score=${diag.min_score_used.toFixed(2)},
       NCC=${diag.verify_threshold_used.toFixed(2)},
       recall=${diag.min_recall_used.toFixed(2)}</div>
    ${flags.length ? `<div><b>Flag attivi:</b> ${flags.join(", ")}</div>` : ""}
    ${hint}
  `;
  // Auto-apri pannello se 0 match (segnala problema)
  if (n_matches === 0) {
    document.getElementById("diag-panel").open = true;
  }
 }
 // ---------- Auto-tune (Halcon-style) ----------
 async function doAutoTune() {
  if (!state.model || !state.roi) {
    alert("Seleziona modello e disegna ROI prima di Auto-tune.");
    return;
  }
  const status = document.getElementById("status");
  status.textContent = "Analisi ROI in corso...";
  try {
    const r = await fetch("/auto_tune", {
      method: "POST",
      headers: { "Content-Type": "application/json" },
      body: JSON.stringify({
        model_id: state.model.id,
        roi: state.roi,
      }),
    });
    if (!r.ok) throw new Error(await r.text());
    const t = await r.json();
    // Applica ai campi avanzati (override automatico)
    for (const [key] of ADV_PARAMS) {
      const el = document.getElementById(`adv-${key}`);
      if (el && t[key] !== undefined) el.value = String(t[key]);
    }
    // Espandi la sezione Avanzate per mostrare i valori applicati
    const advDetails = document.querySelector("#col-params details:last-of-type");
    if (advDetails) advDetails.open = true;
    // Feedback diagnostico
    const lines = [
      `weak/strong: ${t.weak_grad} / ${t.strong_grad}`,
      `feature: ${t.num_features}, piramide: ${t.pyramid_levels}`,
      `angle: [${t.angle_min}..${t.angle_max}]@${t.angle_step}°`,
    ];
    if (t._symmetry_order > 1) {
      lines.push(`simmetria rotaz. ${t._symmetry_order}x (conf ${t._symmetry_conf})`);
    }
    if (t._self_score !== undefined) {
      lines.push(`self-validation: ${t._validation}`);
    }
    status.textContent = `Auto-tune OK — ${lines[0]}`;
    alert("Auto-tune completato:\n\n" + lines.join("\n"));
  } catch (e) {
    status.textContent = `Auto-tune errore: ${e.message}`;
    alert(`Errore auto-tune: ${e.message}`);
  }
 }
 // ---------- V: Recipe load/list/unload ----------
 async function refreshRecipeList() {
  try {
    const r = await fetch("/recipes");
    if (!r.ok) return;
    const j = await r.json();
    const sel = document.getElementById("hc-recipe-list");
    const cur = sel.value;
    sel.innerHTML = '<option value="">— ricette disponibili —</option>';
    for (const f of j.files) {
      const o = document.createElement("option");
      o.value = f.name;
      o.textContent = `${f.name}  (${(f.size / 1024).toFixed(1)} KB)`;
      sel.appendChild(o);
    }
    if (cur) sel.value = cur;
  } catch (e) { /* silent */ }
 }
 async function loadRecipe() {
  const sel = document.getElementById("hc-recipe-list");
  const name = sel.value;
  if (!name) {
    alert("Seleziona una ricetta dalla lista.");
    return;
  }
  try {
    const r = await fetch(`/recipes/${encodeURIComponent(name)}/load`, {
      method: "POST",
    });
    if (!r.ok) throw new Error(await r.text());
    const j = await r.json();
    state.active_recipe = j.name;
    document.getElementById("recipe-status").textContent =
      `Caricata: ${j.name} — ${j.n_variants} varianti, ` +
      `${j.template_size[0]}x${j.template_size[1]} px` +
      (j.use_polarity ? " (polarity)" : "");
    document.getElementById("recipe-status").style.color = "#0c0";
    document.getElementById("btn-unload-recipe").disabled = false;
  } catch (e) {
    alert(`Errore caricamento: ${e.message}`);
  }
 }
 function unloadRecipe() {
  state.active_recipe = null;
  document.getElementById("recipe-status").textContent = "Nessuna ricetta caricata";
  document.getElementById("recipe-status").style.color = "#888";
  document.getElementById("btn-unload-recipe").disabled = true;
 }
 // ---------- V: Save recipe ----------
 async function saveRecipe() {
  if (!state.model || !state.roi) {
@@ -433,6 +727,7 @@ async function saveRecipe() {
    if (!r.ok) throw new Error(await r.text());
    const j = await r.json();
    alert(`Ricetta salvata: ${j.name}\n${j.n_variants} varianti, ${j.size} bytes`);
    refreshRecipeList();
  } catch (e) {
    alert(`Errore salvataggio: ${e.message}`);
  }
@@ -465,8 +760,15 @@ window.addEventListener("DOMContentLoaded", async () => {
    e.target.value = "";  // consente re-upload stesso file
  });
  document.getElementById("btn-match").addEventListener("click", doMatch);
  document.getElementById("btn-autotune").addEventListener("click", doAutoTune);
  document.getElementById("btn-save-recipe").addEventListener("click",
    saveRecipe);
  document.getElementById("btn-load-recipe").addEventListener("click",
    loadRecipe);
  document.getElementById("btn-unload-recipe").addEventListener("click",
    unloadRecipe);
  refreshRecipeList();
  bindEdgePreviewControls();
  const slider = document.getElementById("p-min-score");
  slider.addEventListener("input", (e) => {
    document.getElementById("v-score").textContent =
@@ -26,6 +26,10 @@
      <div class="picker-list"></div>
    </div>
    <button class="btn btn-go" id="btn-match">▶ MATCH</button>
    <button class="btn" id="btn-autotune"
            title="Analizza ROI e derivata parametri ottimali (Halcon-style)">
      ⚙ Auto-tune
    </button>
    <label class="btn" title="Carica nuovo file nella cartella immagini">
      ⬆ Carica file
      <input type="file" id="file-upload" accept="image/*" hidden>
@@ -41,6 +45,40 @@
      <canvas id="c-model" width="380" height="420"></canvas>
    </div>
    <div id="roi-info">ROI: (nessuna)</div>
    <details id="edge-preview-panel" style="margin-top:10px">
      <summary>🔬 Anteprima edge / pulizia rumore</summary>
      <div style="font-size:11px; color:#aaa; margin:4px 0">
        Regola le soglie per togliere edge spuri (sporcizie). UCS rosso/verde
        sul baricentro feature.
      </div>
      <div class="ep-grid">
        <label class="ep-row">weak_grad <span id="ep-weak-v">30</span>
          <input type="range" id="ep-weak" min="5" max="200" value="30" step="1">
        </label>
        <label class="ep-row">strong_grad <span id="ep-strong-v">60</span>
          <input type="range" id="ep-strong" min="10" max="400" value="60" step="1">
        </label>
        <label class="ep-row">num_features <span id="ep-nf-v">96</span>
          <input type="range" id="ep-nf" min="16" max="300" value="96" step="1">
        </label>
        <label class="ep-row">spacing <span id="ep-sp-v">3</span>
          <input type="range" id="ep-sp" min="1" max="15" value="3" step="1">
        </label>
        <label class="ep-row" style="flex-direction:row; gap:6px">
          <input type="checkbox" id="ep-pol"> polarity
        </label>
        <button class="btn" id="btn-edge-apply" type="button"
                style="grid-column:1/-1">
          ✓ Applica ai parametri Avanzate
        </button>
      </div>
      <div class="canvas-wrap" style="margin-top:6px">
        <canvas id="c-edge-preview" width="380" height="380"></canvas>
      </div>
      <div id="edge-preview-info" style="font-size:11px; color:#888; margin-top:4px">
        Disegna ROI e apri questo pannello per generare anteprima
      </div>
    </details>
  </section>
  <section class="col" id="col-scene">
@@ -186,6 +224,16 @@
            <input type="text" id="hc-recipe-name" placeholder="nome_ricetta" style="flex:1">
            <button class="btn" id="btn-save-recipe" type="button">💾 Salva</button>
          </div>
          <div style="display:flex; gap:6px; margin-top:6px; align-items:center">
            <select id="hc-recipe-list" style="flex:1">
              <option value="">— ricette disponibili —</option>
            </select>
            <button class="btn" id="btn-load-recipe" type="button">📂 Carica</button>
            <button class="btn" id="btn-unload-recipe" type="button" disabled>✖ Stacca</button>
          </div>
          <div id="recipe-status" style="margin-top:4px; font-size:11px; color:#888">
            Nessuna ricetta caricata
          </div>
        </div>
      </div>
    </details>
@@ -200,6 +248,16 @@
    <div class="kv"><span>find:</span><span id="t-find">-</span></div>
    <div class="kv"><span>varianti:</span><span id="t-var">-</span></div>
    <div class="kv"><span>match:</span><span id="t-match">-</span></div>
    <details id="diag-panel" style="margin-top:10px">
      <summary>🔍 Diagnostica (CC)</summary>
      <div id="diag-content" style="font-family:monospace; font-size:11px;
                                     background:#1a1a1a; padding:8px;
                                     border-radius:3px; margin-top:6px;
                                     line-height:1.5">
        <em style="color:#888">Esegui un MATCH per vedere la diagnostica</em>
      </div>
    </details>
  </section>
 </main>
@@ -173,3 +173,18 @@ footer h2 {
 }
 .hc-row.hc-num label { font-size: 11px; color: #aaa; }
 .hc-row.hc-num input { width: 100%; }
 /* Edge preview panel */
 .ep-grid {
  display: grid;
  grid-template-columns: 1fr 1fr;
  gap: 6px 12px;
  margin-top: 6px;
  font-size: 12px;
 }
 .ep-row {
  display: flex; flex-direction: column; gap: 2px;
  font-size: 11px; color: #aaa;
 }
 .ep-row input[type="range"] { width: 100%; }
 .ep-row span { color: #fff; font-weight: bold; font-family: monospace; }
@@ -12,6 +12,9 @@ dependencies = [
    "uvicorn[standard]>=0.34",
 ]
 [project.scripts]
 pm2d-eval = "pm2d.eval:main"
 [dependency-groups]
 dev = [
    "httpx>=0.28.1",
Author	SHA1	Message	Date
Adriano	35df4c473c	fix: UCS match e numero feature ora coerenti con anteprima modello Bug visibili da screenshot: 1. UCS match diverso da UCS anteprima modello (centro pose vs baricentro) 2. Numero feature disegnate < di quelle anteprima modello Cause: 1. Match UCS era posto su (cx, cy) = centro template, mentre l'anteprima modello mostra UCS sul baricentro feature (mean fx, fy). 2. _draw_matches estraeva feature dal template warpato → re-quantizza gradient su immagine warp+interp, perdendo precisione vs feature pre-computate del matcher. Fix: - Match.variant_idx: nuovo field con indice variante usata dal find() - _draw_matches usa lvl0.dx/dy/bin pre-computati invece di re-estrarre: * applica delta-rotation (m.angle_deg - var.angle_deg) per refine sub-step * proietta in scene coords intorno a (m.cx, m.cy) * stesso identico set di feature dell'anteprima modello (modulo rotazione+traslazione) - UCS match calcolato sul baricentro delle feature warpate, non su (cx, cy) → coerente con UCS anteprima Fallback (variant_idx == -1, es. ricetta caricata da save_model prima di questo commit): usa estrazione warpata legacy. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 11:02:04 +02:00
Adriano	64f2c8b5dc	merge: match overlay edges+UCS, no ROI	2026-05-05 10:55:54 +02:00
Adriano	7e076deb80	feat(web): match overlay con edge filtrati + UCS + rimozione bbox ROI _draw_matches ora coerente con anteprima modello: - Edge filtrati con stessa pipeline matcher (hysteresis weak/strong_grad) e selezione feature: l'overlay del match riflette esattamente quello che l'utente ha visto nel preview "Anteprima edge" - Background tinta scura su pixel hysteresis (40% colore match) - Feature scelte come dot colorati per bin (palette 16 bin) - UCS rosso/verde sul centro pose: asse X destra, Y giu' (image y-down), ruotato secondo angle del match - Origine UCS: cerchio bianco con bordo nero per visibilita' Rimossi (richiesta utente "togli la ROI"): - bbox poly perimetrale: ridondante, copriva il pezzo - linea marker primo lato: sostituita da UCS rosso Compatibilita': se matcher non passato (es. uso esterno), fallback Canny legacy. Tutti e 3 endpoint match (/match, /match_simple, /match_recipe) ora propagano il matcher a _draw_matches. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 10:55:54 +02:00
Adriano	852597ed51	merge: UI edge preview + UCS	2026-05-05 10:48:58 +02:00
Adriano	a78884f950	feat(web): anteprima edge sul modello + tracker pulizia rumore + UCS baricentro Pannello "🔬 Anteprima edge / pulizia rumore" sotto il canvas modello. Permette tuning interattivo dei parametri di selezione edge per togliere "sporcizie" (rumore di sfondo, edge spuri) prima di trainare il matcher. Server: - POST /preview_edges: dato modello+ROI+param edge, ritorna immagine ROI con overlay: * heatmap magnitude gradient (sfondo) * verde scuro: pixel sopra hysteresis edge * cerchietti colorati per bin: feature scelte (palette 16 bin) * UCS rosso/verde sul baricentro feature (richiesta utente): asse X destra, Y giu' (image y-down) Ritorna anche stats: n_features, n_edge_strong, percentili magnitude, ucs_baricentro {cx, cy} UI: - Slider weak_grad/strong_grad/num_features/spacing + checkbox polarity - Re-fetch debounced (200ms) ad ogni input → preview live - Bottone "Applica ai parametri Avanzate": copia i valori scelti nei campi Avanzate del matcher principale - Auto-fetch quando il pannello viene aperto Use case: operatore vede SUBITO quali edge il matcher userebbe, regola soglie per escludere rumore, applica e poi MATCH. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 10:48:58 +02:00
Adriano	543ae0f643	merge: UI pannello diagnostica	2026-05-05 10:41:26 +02:00
Adriano	a12574f3c5	feat(web): pannello diagnostica match (CC) con hint contestuali MatchResp ora include diag dict (CC feature). UI rendering: - Nuovo pannello pieghevole "🔍 Diagnostica" sotto i tempi - Per ogni match mostra: * pipeline pruning (vars total → top_eval → top_pass → full_eval) * candidati (raw → pre_nms → final) * drop reasons (NCC, score, recall, bbox, NMS) con counter * soglie effettive applicate * flag attivi (polarity, soft, subpix-LM) - Quando 0 match → pannello si apre automaticamente + mostra hint contestuale specifico: * "0 candidati top" → suggerisce ↓ min_score / top_thresh * "tutti dropped da NCC" → ↓ verify_threshold (filtro_fp) * "score post-NCC sotto" → ↓ min_score * "recall basso" → ↓ min_recall * "bbox out-of-scene" → check pose / search_roi Risolve il pattern "0 match perche'?" con guida actionable invece del black-box. Tutti e 3 endpoint match (/match, /match_simple, /match_recipe) propagano il diag. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 10:41:26 +02:00
Adriano	110dc87b08	merge: AA eval CLI	2026-05-05 10:10:00 +02:00
Adriano	2bb2cf63cc	merge: II scene cache	2026-05-05 10:09:56 +02:00
Adriano	ea6a9163ad	merge: CC diagnostic mode	2026-05-05 10:09:56 +02:00
Adriano	1cc7881a51	feat: pm2d.eval - validation harness CLI per LineShapeMatcher Tool da CLI per misurare oggettivamente la qualita' del matcher su dataset etichettato. Halcon ha questo solo nell'IDE (HDevelop), qui esposto come modulo Python testabile in CI. Format dataset JSON: - template + mask - params init matcher (override) - find_params (override per find()) - scenes con ground_truth: lista pose attese (cx, cy, angle, scale, tolerance_px, tolerance_deg) Metriche per scena: TP/FP/FN, precision, recall, IoU medio bbox, tempo find. Aggregato: precision globale, recall, F1. Match-to-GT criterio: distanza centro <= tolerance_px AND \|angle\| <= tolerance_deg, oppure IoU bbox >= 0.3. Use case: - regressione: confronto config A vs B oggettivo - tuning: trovare param ottimi via grid-search guidato da F1 - validazione pre-deploy: report TP/FP/FN su dataset prod Esposto come entry-point pm2d-eval (pyproject.toml). Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 10:09:45 +02:00
Adriano	74a332a2dd	feat: scene precompute cache (II Halcon-style) LRU cache per scena: hash su prime 64KB bytes + parametri matcher (weak/strong_grad, spread_radius, n_bins, pyramid_levels). Quando hit, riusa: - piramide grays - spread_top + bit_active_top + density_top - spread0 + bit_active_full + density_full Tipico use case: UI tuning con slider min_score/verify_threshold/... produce 10+ find() consecutive su scena identica. Risparmia Sobel+dilate+popcount duplicati (~50ms su 1080p). Speedup misurato: ~15% find() su 1080p (54ms su 351ms). Vantaggio maggiore su template piccoli (kernel JIT veloce → scena precompute domina). Cache size 4, invalidata in train() (template cambiato). Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 10:07:27 +02:00
Adriano	dae49eb4a3	feat: diagnostic mode trasparente per find() self._last_diag accumula counter durante find(): - Pipeline pruning: top_evaluated, top_passed, full_evaluated - Candidati: n_raw, n_after_pre_nms, n_final - Drop reason: ncc_low, min_score_post_avg, recall_low, bbox_out_of_scene, nms_iou - Param effettivi: top_thresh_used, verify_threshold_used, ecc. API: - find(debug=True): stampa one-line summary su stderr - m.get_last_diag(): ritorna dict completo per inspection Use case: 0 match? guarda dove sono finiti i candidati (es. drop_ncc_low=200 → soglia NCC troppo alta) invece di tirare a caso. Risolve il "find black-box" pattern. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-05 10:05:20 +02:00
Adriano	9218cb2741	chore: gitignore recipes/*.npz e rimuove Pippo.npz dal tracking Le ricette pre-trained (binari numpy compressi) sono dati utente specifici della macchina/ROI/template, non vanno versionati. Rimosso Pippo.npz dal repo (mantenuto su filesystem locale). Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-04 23:21:46 +02:00
Adriano	159f9089a5	merge: UI load ricetta	2026-05-04 23:20:52 +02:00
Adriano	b718e81ccf	feat(web): UI carica/stacca ricetta + match con ricetta caricata Manca il path "load" della V feature: utente poteva salvare ricetta ma non caricarla dalla UI. Aggiunto: Server: - POST /recipes/{name}/load: carica .npz in cache _RECIPE_MATCHERS - POST /match_recipe: usa matcher caricato senza re-train (zero training time, solo find params propagati) UI: - Dropdown ricette disponibili (auto-refreshed da GET /recipes) - Bottone "Carica" attiva ricetta + popola state.active_recipe - Bottone "Stacca" torna al flow normale (training da ROI) - Status indicator mostra ricetta attiva e dimensioni doMatch dispatcha automaticamente: - ricetta attiva → /match_recipe (no model/ROI necessari) - altrimenti → /match o /match_simple come prima Use case: ricetta tarata offline, deploy a runtime production senza ricaricare modello+ROI ogni volta. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-04 23:20:52 +02:00
Adriano	d46197a81a	merge: UI bottone auto-tune	2026-05-04 23:10:07 +02:00
Adriano	37c645984f	feat(web): bottone Auto-tune nella toolbar (Halcon-style) UI esponev gia' /auto_tune endpoint ma non c'era trigger user-facing. Aggiunto bottone toolbar accanto a MATCH: - Calcola tutti i parametri tecnici dalla ROI selezionata (gradient, feature, piramide, angle_step, simmetria) - Esegue self-validation training+find su template - Applica i valori derivati ai campi della sezione Avanzate - Mostra alert con riepilogo + meta diagnostica (simmetria detected, self-validation result, ecc.) Endpoint /auto_tune ora ritorna anche meta (_self_score, _validation, _symmetry_order, _orient_entropy) per feedback UI invece di filtrarli. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-04 23:10:07 +02:00
Adriano	0e148667ec	merge: auto_tune self-validation	2026-05-04 23:04:10 +02:00
Adriano	b5bbca0e85	merge: hysteresis edge linking	2026-05-04 23:04:10 +02:00
Adriano	ca3882c59c	feat: auto_tune self-validation (Halcon-style inspect_shape_model) Nuovo helper _self_validate(): post-stima parametri, esegue dry-run training+find sul template stesso e regola i parametri se subottimali. Loop di auto-correzione (analogo a Halcon inspect_shape_model): 1. Se top-level piramide ha <8 feature → riduce pyramid_levels 2. Se train produce 0 varianti → dimezza weak/strong_grad 3. Se find sul template fallisce → riduce soglie + num_features 4. Se self-score < 0.7 → abbassa weak_grad Costo: 1 train minimale (1 variante) + 1 find su canvas tpl + padding, ~50ms su template 100x100. Ne vale la pena per evitare match-time errors su scene reali con parametri estimato male. Esposto via auto_tune(self_validate=True) default; meta '_self_score' e '_validation' nel dict risultato per logging UI. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-04 23:04:01 +02:00
Adriano	7f6571bdd1	feat: hysteresis edge linking (Halcon Contrast='auto' two-threshold) _hysteresis_mask: edge linking via componenti connesse. - seed = mag >= strong_grad - weak = mag >= weak_grad - Promuove a feature ogni componente weak che contiene almeno un pixel strong (connettivita' 8-vicini) Riduce simultaneamente: - Falsi positivi: edge debole isolato (rumore puro) escluso - Falsi negativi: edge debole connesso a edge forte incluso (continuita' bordi sottili a basso contrasto) Attivo automaticamente quando weak_grad < strong_grad. Se uguali, fallback a sogliatura singola standard. Backward compat completo dato che default weak=30, strong=60. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>	2026-05-04 23:01:54 +02:00