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1 Commits
| Author | SHA1 | Date | |
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 Adriano
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d9a40952c4 |
+5
-2
@@ -220,8 +220,11 @@ def auto_tune(template_bgr: np.ndarray, mask: np.ndarray | None = None) -> dict:
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else:
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min_score = 0.45
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# angle step: 5° default; se simmetria, mantengo step ma range ridotto
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angle_step = 5.0
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# angle step adattivo (Halcon-style): atan(2/max_side) deg, clampato.
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# Template grande → step fine (rotazione minima visibile su perimetro).
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# Template piccolo → step grosso (over-sampling = sprecato).
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max_side = max(h, w)
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angle_step = float(np.clip(np.degrees(np.arctan2(2.0, max_side)), 1.0, 8.0))
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result = {
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"backend": "line",
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+28
-66
@@ -197,12 +197,31 @@ class LineShapeMatcher:
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n = int(np.floor((s1 - s0) / self.scale_step)) + 1
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return [float(s0 + i * self.scale_step) for i in range(n)]
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def _auto_angle_step(self) -> float:
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"""Step angolare derivato da dimensione template (Halcon-style).
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Formula: step ≈ atan(2 / max_side) gradi. Garantisce che la
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rotazione minima produca uno spostamento di ≥2 px sul perimetro
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del template (sotto sample il matching coarse perde candidati).
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Clampato in [0.5°, 10°].
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"""
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max_side = max(self.template_size) if self.template_size != (0, 0) else 64
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step = math.degrees(math.atan2(2.0, float(max_side)))
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return float(np.clip(step, 0.5, 10.0))
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def _effective_angle_step(self) -> float:
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"""Risolve angle_step_deg gestendo modalità auto (<=0)."""
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if self.angle_step_deg <= 0:
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return self._auto_angle_step()
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return self.angle_step_deg
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def _angle_list(self) -> list[float]:
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a0, a1 = self.angle_range_deg
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if self.angle_step_deg <= 0 or a0 >= a1:
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step = self._effective_angle_step()
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if step <= 0 or a0 >= a1:
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return [float(a0)]
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n = int(np.floor((a1 - a0) / self.angle_step_deg))
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return [float(a0 + i * self.angle_step_deg) for i in range(n)]
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n = int(np.floor((a1 - a0) / step))
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return [float(a0 + i * step) for i in range(n)]
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# --- Training ------------------------------------------------------
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@@ -415,7 +434,7 @@ class LineShapeMatcher:
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if original_score is not None and original_score >= 0.99:
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return (angle_deg, original_score, cx, cy)
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if search_radius is None:
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search_radius = self.angle_step_deg / 2.0
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search_radius = self._effective_angle_step() / 2.0
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h, w = template_gray.shape
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sw = max(16, int(round(w * scale)))
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@@ -574,8 +593,6 @@ class LineShapeMatcher:
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verify_threshold: float = 0.4,
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coarse_angle_factor: int = 2,
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scale_penalty: float = 0.0,
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pyramid_propagate: bool = True,
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propagate_topk: int = 8,
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) -> list[Match]:
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"""
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scale_penalty: se > 0, riduce lo score per match a scala diversa da 1.0:
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@@ -647,12 +664,7 @@ class LineShapeMatcher:
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end = min(n, i + half + 1)
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neighbor_map[vi_c] = vi_sorted[start:end]
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# Pruning varianti via top-level (parallelizzato).
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# Quando pyramid_propagate=True ritorna anche le top-K posizioni
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# del picco (in coord top-level) per restringere la fase full-res
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# a piccoli crop attorno ai candidati (vs intera scena).
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peaks_by_vi: dict[int, list[tuple[int, int, float]]] = {}
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# Pruning varianti via top-level (parallelizzato) - solo coarse
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def _top_score(vi: int) -> tuple[int, float]:
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var = self.variants[vi]
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lvl = var.levels[min(top, len(var.levels) - 1)]
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@@ -660,23 +672,7 @@ class LineShapeMatcher:
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spread_top, lvl.dx, lvl.dy, lvl.bin, bit_active_top,
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bg_cache_top[var.scale],
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)
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if score.size == 0:
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return vi, -1.0
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best = float(score.max())
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if pyramid_propagate and best > 0:
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# Top-K posizioni > top_thresh (max propagate_topk)
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flat = score.ravel()
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k = min(propagate_topk, flat.size)
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idx = np.argpartition(-flat, k - 1)[:k]
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peaks: list[tuple[int, int, float]] = []
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for i in idx:
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s = float(flat[i])
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if s < top_thresh * 0.7:
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continue
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yt, xt = int(i // score.shape[1]), int(i % score.shape[1])
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peaks.append((xt, yt, s))
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peaks_by_vi[vi] = peaks
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return vi, best
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return vi, float(score.max()) if score.size else -1.0
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kept_coarse: list[tuple[int, float]] = []
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all_top_scores: list[tuple[int, float]] = []
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@@ -736,48 +732,14 @@ class LineShapeMatcher:
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for sc in unique_scales:
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bg_cache_full[sc] = _bg_for_scale(density_full, sc, 1)
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# Margine in full-res attorno ad ogni peak top: copre incertezza
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# downsampling (sf_top px) + spread_radius + slack per NMS.
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propagate_margin = sf_top + self.spread_radius + max(8, nms_radius // 2)
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H_full, W_full = spread0.shape
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def _full_score(vi: int) -> tuple[int, np.ndarray]:
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var = self.variants[vi]
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lvl0 = var.levels[0]
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if not pyramid_propagate or vi not in peaks_by_vi or not peaks_by_vi[vi]:
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# Path legacy: scansiona intera scena
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return vi, _jit_score_bitmap_rescored(
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score = _jit_score_bitmap_rescored(
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spread0, lvl0.dx, lvl0.dy, lvl0.bin, bit_active_full,
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bg_cache_full[var.scale],
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)
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# Path piramide propagata: valuta solo crop locali attorno
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# alle posizioni dei picchi top-level (riproiettati a full-res).
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score_full = np.zeros((H_full, W_full), dtype=np.float32)
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mark = np.zeros((H_full, W_full), dtype=bool)
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bg = bg_cache_full[var.scale]
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for xt, yt, _s in peaks_by_vi[vi]:
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cx0 = xt * sf_top
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cy0 = yt * sf_top
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x_lo = max(0, cx0 - propagate_margin)
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x_hi = min(W_full, cx0 + propagate_margin + 1)
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y_lo = max(0, cy0 - propagate_margin)
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y_hi = min(H_full, cy0 + propagate_margin + 1)
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if x_hi <= x_lo or y_hi <= y_lo:
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continue
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if mark[y_lo:y_hi, x_lo:x_hi].all():
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continue
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# Crop spread + bg, valuta kernel sul crop
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spread_crop = np.ascontiguousarray(spread0[y_lo:y_hi, x_lo:x_hi])
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bg_crop = np.ascontiguousarray(bg[y_lo:y_hi, x_lo:x_hi])
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score_crop = _jit_score_bitmap_rescored(
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spread_crop, lvl0.dx, lvl0.dy, lvl0.bin,
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bit_active_full, bg_crop,
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)
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score_full[y_lo:y_hi, x_lo:x_hi] = np.maximum(
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score_full[y_lo:y_hi, x_lo:x_hi], score_crop,
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)
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mark[y_lo:y_hi, x_lo:x_hi] = True
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return vi, score_full
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return vi, score
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candidates_per_var: list[tuple[int, np.ndarray]] = []
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raw: list[tuple[float, int, int, int]] = []
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@@ -859,7 +821,7 @@ class LineShapeMatcher:
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ang_f, score_f, cx_f, cy_f = self._refine_angle(
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spread0, bit_active_full, self.template_gray, cx_f, cy_f,
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var.angle_deg, var.scale, mask_full,
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search_radius=self.angle_step_deg / 2.0,
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search_radius=self._effective_angle_step() / 2.0,
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original_score=score,
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)
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if verify_ncc:
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