feat: angle_step auto adattivo a dimensione template

Halcon-style: angle_step_deg=0 attiva derivazione automatica step = atan(2/max_side) deg, clampato [0.5, 10]. Template grande ottiene step fine, piccolo step grosso. auto_tune emette il valore calcolato direttamente. _refine_angle ora usa _effective_angle_step() per coerenza con training quando la modalita auto e attiva. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
2026-05-04 15:27:35 +02:00
3 changed files with 30 additions and 142 deletions
@@ -159,63 +159,6 @@ if HAS_NUMBA:
                        acc[y, x] = 0.0
        return acc
    @nb.njit(cache=True, parallel=True, fastmath=True, boundscheck=False)
    def _jit_top_max_per_variant(
        spread: np.ndarray,            # uint8 (H, W)
        dx_flat: np.ndarray,           # int32 (sum_N,)
        dy_flat: np.ndarray,           # int32 (sum_N,)
        bins_flat: np.ndarray,         # int8 (sum_N,)
        offsets: np.ndarray,           # int32 (n_vars+1,) prefix sum
        bit_active: np.uint8,
        bg_per_variant: np.ndarray,    # float32 (n_vars, H, W) - 1 per scala
        scale_idx: np.ndarray,         # int32 (n_vars,) idx in bg_per_variant
    ) -> np.ndarray:
        """Batch: per ogni variante calcola max score (rescored bg), ritorna
        array float32 (n_vars,). Parallelismo prange ESTERNO sulle varianti
        elimina overhead di n_vars chiamate JIT separate (avg ~20us per
        chiamata su template piccoli) + pool thread Python.
        Pensato per fase TOP del pruning quando n_vars >> n_threads.
        """
        n_vars = offsets.shape[0] - 1
        H, W = spread.shape
        out = np.zeros(n_vars, dtype=np.float32)
        for vi in nb.prange(n_vars):
            i0 = offsets[vi]; i1 = offsets[vi + 1]
            N = i1 - i0
            if N == 0:
                out[vi] = -1.0
                continue
            si = scale_idx[vi]
            inv = nb.float32(1.0 / N)
            best = nb.float32(-1.0)
            for y in range(H):
                for x in range(W):
                    s = nb.float32(0.0)
                    for k in range(N):
                        b = bins_flat[i0 + k]
                        mask = np.uint8(1) << b
                        if (bit_active & mask) == 0:
                            continue
                        ddy = dy_flat[i0 + k]
                        yy = y + ddy
                        if yy < 0 or yy >= H:
                            continue
                        ddx = dx_flat[i0 + k]
                        xx = x + ddx
                        if xx < 0 or xx >= W:
                            continue
                        if spread[yy, xx] & mask:
                            s += nb.float32(1.0)
                    s *= inv
                    bgv = bg_per_variant[si, y, x]
                    if bgv < 1.0:
                        r = (s - bgv) / (1.0 - bgv + 1e-6)
                        if r > best:
                            best = r
            out[vi] = best if best > 0.0 else 0.0
        return out
    @nb.njit(cache=True, parallel=True, fastmath=True, boundscheck=False)
    def _jit_popcount_density(spread: np.ndarray) -> np.ndarray:
        """Conta bit set per pixel: ritorna (H, W) float32 in [0..8]."""
@@ -242,12 +185,6 @@ if HAS_NUMBA:
        _jit_score_bitmap(spread, dx, dy, b, np.uint8(0xFF))
        bg = np.zeros((32, 32), dtype=np.float32)
        _jit_score_bitmap_rescored(spread, dx, dy, b, np.uint8(0xFF), bg)
        offsets = np.array([0, 1], dtype=np.int32)
        scale_idx = np.zeros(1, dtype=np.int32)
        bg_pv = np.zeros((1, 32, 32), dtype=np.float32)
        _jit_top_max_per_variant(
            spread, dx, dy, b, offsets, np.uint8(0xFF), bg_pv, scale_idx,
        )
        _jit_popcount_density(spread)
 else:  # pragma: no cover
@@ -261,12 +198,6 @@ else:  # pragma: no cover
    def _jit_score_bitmap_rescored(spread, dx, dy, bins, bit_active, bg):
        raise RuntimeError("numba non disponibile")
    def _jit_top_max_per_variant(
        spread, dx_flat, dy_flat, bins_flat, offsets, bit_active,
        bg_per_variant, scale_idx,
    ):
        raise RuntimeError("numba non disponibile")
    def _jit_popcount_density(spread):
        raise RuntimeError("numba non disponibile")
@@ -315,51 +246,6 @@ def score_bitmap_rescored(
    return np.maximum(0.0, out).astype(np.float32)
 def top_max_per_variant(
    spread: np.ndarray,
    dx_list: list, dy_list: list, bin_list: list,
    bg_per_scale: dict,
    variant_scales: list,
    bit_active: int,
 ) -> np.ndarray:
    """Wrapper: prepara buffer flat e chiama kernel batch su tutte le varianti.
    Parallelismo Numba prange-esterno sulle varianti (n_vars >> n_threads
    tipicamente per top-pruning) → meglio del thread-pool Python che paga
    overhead di n_vars chiamate JIT separate.
    """
    if not HAS_NUMBA or len(dx_list) == 0:
        return np.array([], dtype=np.float32)
    n_vars = len(dx_list)
    sizes = [len(d) for d in dx_list]
    offsets = np.zeros(n_vars + 1, dtype=np.int32)
    offsets[1:] = np.cumsum(sizes)
    total = int(offsets[-1])
    dx_flat = np.empty(total, dtype=np.int32)
    dy_flat = np.empty(total, dtype=np.int32)
    bins_flat = np.empty(total, dtype=np.int8)
    for vi, (dx, dy, bn) in enumerate(zip(dx_list, dy_list, bin_list)):
        i0 = int(offsets[vi]); i1 = int(offsets[vi + 1])
        dx_flat[i0:i1] = dx
        dy_flat[i0:i1] = dy
        bins_flat[i0:i1] = bn
    # bg per variante: indicizzato per scala
    scales_unique = sorted(bg_per_scale.keys())
    scale_to_idx = {s: i for i, s in enumerate(scales_unique)}
    H, W = spread.shape
    bg_pv = np.empty((len(scales_unique), H, W), dtype=np.float32)
    for s, idx in scale_to_idx.items():
        bg_pv[idx] = bg_per_scale[s]
    scale_idx = np.array(
        [scale_to_idx[s] for s in variant_scales], dtype=np.int32,
    )
    return _jit_top_max_per_variant(
        np.ascontiguousarray(spread, dtype=np.uint8),
        dx_flat, dy_flat, bins_flat, offsets, np.uint8(bit_active),
        bg_pv, scale_idx,
    )
 def popcount_density(spread: np.ndarray) -> np.ndarray:
    if HAS_NUMBA:
        return _jit_popcount_density(np.ascontiguousarray(spread, dtype=np.uint8))
@@ -220,8 +220,11 @@ def auto_tune(template_bgr: np.ndarray, mask: np.ndarray | None = None) -> dict:
    else:
        min_score = 0.45
-    # angle step: 5° default; se simmetria, mantengo step ma range ridotto
+    # angle step adattivo (Halcon-style): atan(2/max_side) deg, clampato.
-    angle_step = 5.0
+    # Template grande → step fine (rotazione minima visibile su perimetro).
    # Template piccolo → step grosso (over-sampling = sprecato).
    max_side = max(h, w)
    angle_step = float(np.clip(np.degrees(np.arctan2(2.0, max_side)), 1.0, 8.0))
    result = {
        "backend": "line",
@@ -40,7 +40,6 @@ from pm2d._jit_kernels import (
    score_by_shift as _jit_score_by_shift,
    score_bitmap as _jit_score_bitmap,
    score_bitmap_rescored as _jit_score_bitmap_rescored,
    top_max_per_variant as _jit_top_max_per_variant,
    popcount_density as _jit_popcount,
    HAS_NUMBA,
 )
@@ -198,12 +197,31 @@ class LineShapeMatcher:
        n = int(np.floor((s1 - s0) / self.scale_step)) + 1
        return [float(s0 + i * self.scale_step) for i in range(n)]
    def _auto_angle_step(self) -> float:
        """Step angolare derivato da dimensione template (Halcon-style).
        Formula: step ≈ atan(2 / max_side) gradi. Garantisce che la
        rotazione minima produca uno spostamento di ≥2 px sul perimetro
        del template (sotto sample il matching coarse perde candidati).
        Clampato in [0.5°, 10°].
        """
        max_side = max(self.template_size) if self.template_size != (0, 0) else 64
        step = math.degrees(math.atan2(2.0, float(max_side)))
        return float(np.clip(step, 0.5, 10.0))
    def _effective_angle_step(self) -> float:
        """Risolve angle_step_deg gestendo modalità auto (<=0)."""
        if self.angle_step_deg <= 0:
            return self._auto_angle_step()
        return self.angle_step_deg
    def _angle_list(self) -> list[float]:
        a0, a1 = self.angle_range_deg
-        if self.angle_step_deg <= 0 or a0 >= a1:
+        step = self._effective_angle_step()
        if step <= 0 or a0 >= a1:
            return [float(a0)]
-        n = int(np.floor((a1 - a0) / self.angle_step_deg))
+        n = int(np.floor((a1 - a0) / step))
-        return [float(a0 + i * self.angle_step_deg) for i in range(n)]
+        return [float(a0 + i * step) for i in range(n)]
    # --- Training ------------------------------------------------------
@@ -416,7 +434,7 @@ class LineShapeMatcher:
        if original_score is not None and original_score >= 0.99:
            return (angle_deg, original_score, cx, cy)
        if search_radius is None:
-            search_radius = self.angle_step_deg / 2.0
+            search_radius = self._effective_angle_step() / 2.0
        h, w = template_gray.shape
        sw = max(16, int(round(w * scale)))
@@ -575,7 +593,6 @@ class LineShapeMatcher:
        verify_threshold: float = 0.4,
        coarse_angle_factor: int = 2,
        scale_penalty: float = 0.0,
        batch_top: bool = False,
    ) -> list[Match]:
        """
        scale_penalty: se > 0, riduce lo score per match a scala diversa da 1.0:
@@ -659,25 +676,7 @@ class LineShapeMatcher:
        kept_coarse: list[tuple[int, float]] = []
        all_top_scores: list[tuple[int, float]] = []
-        # batch_top: usa kernel batch single-call con prange-esterno su
+        if self.n_threads > 1 and len(coarse_idx_list) > 1:
        # varianti. Vince su threadpool quando n_vars >> n_threads e quando
        # H*W top e' piccolo (overhead chiamate JIT > costo kernel).
        if (batch_top and HAS_NUMBA and len(coarse_idx_list) > 4):
            dx_l = []; dy_l = []; bn_l = []; vs_l = []
            for vi in coarse_idx_list:
                var = self.variants[vi]
                lvl = var.levels[min(top, len(var.levels) - 1)]
                dx_l.append(lvl.dx); dy_l.append(lvl.dy); bn_l.append(lvl.bin)
                vs_l.append(var.scale)
            scores_arr = _jit_top_max_per_variant(
                spread_top, dx_l, dy_l, bn_l, bg_cache_top, vs_l,
                bit_active_top,
            )
            for vi, best in zip(coarse_idx_list, scores_arr.tolist()):
                all_top_scores.append((vi, best))
                if best >= top_thresh:
                    kept_coarse.append((vi, best))
        elif self.n_threads > 1 and len(coarse_idx_list) > 1:
            with ThreadPoolExecutor(max_workers=self.n_threads) as ex:
                for vi, best in ex.map(_top_score, coarse_idx_list):
                    all_top_scores.append((vi, best))
@@ -822,7 +821,7 @@ class LineShapeMatcher:
                ang_f, score_f, cx_f, cy_f = self._refine_angle(
                    spread0, bit_active_full, self.template_gray, cx_f, cy_f,
                    var.angle_deg, var.scale, mask_full,
-                    search_radius=self.angle_step_deg / 2.0,
+                    search_radius=self._effective_angle_step() / 2.0,
                    original_score=score,
                )
            if verify_ncc: