perf: Fase 1 speed+precision (V1 V11 P1 P5)

V1 Coarse-to-fine angolare: - Al top-level valuta solo 1 variante ogni coarse_angle_factor (default 2) - Espande ai vicini nel full-res per preservare accuracy - Safe anche per template allungati (factor=2 non perde match) V11 Cache matcher in-memory (LRU, capacita 8): - Key = md5(ROI bytes + params tecnici che influenzano il training) - Re-match con stessi parametri: train_time = 0s (era 0.5-1.5s) - OrderedDict LRU con _cache_get_matcher / _cache_put_matcher P1 Fit parabolico 2D bivariato: - In _subpixel_peak ora usa stencil 3x3 completo: f(dx,dy) = a + b*dx + c*dy + d*dx^2 + e*dy^2 + f*dx*dy - Argmax analytic solve di sistema 2x2; fallback separabile se det~0 - Precisione attesa: 0.1-0.3 px (era 0.5 px separabile) P5 Golden-section angle search: - Sostituisce 5 sample equispaziati con convergenza log(n) - Tol 0.1 gradi, 8 iterazioni max - Helper _score_at_angle interno per valutare score a offset arbitrario P2 Weighted centroid plateau: - Peso = (score - (max-0.01))^2 per enfatizzare top del plateau Benchmark suite 16 casi (4 immagini x full/part x fast/preciso): prima Fase 1: totale find 27.3s dopo Fase 1: totale find 25.1s nessuna regressione match count, alcuni casi miglioramenti precisione. ROADMAP.md aggiornato con checklist Fase 1. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
2026-04-24 11:35:40 +02:00
parent b83e577eab
commit 37b718e45e
3 changed files with 213 additions and 79 deletions
@@ -2,6 +2,22 @@
 Lista ragionata di miglioramenti futuri. Priorità = impatto / effort, non urgenza temporale.
 ## Fase 1 COMPLETATA (branch `speedFase1`)
 | ID | Voce | Status | Note |
 |---|---|---|---|
 | V1 | Coarse-to-fine angolare (step coarse al top-level) | ✅ | `coarse_angle_factor=2` default, safe anche su template allungati |
 | V11 | Cache matcher in-memory LRU (capacità 8) | ✅ | Key = hash(ROI bytes + params). Re-match stesse params = train 0s |
 | P1 | Fit parabolico 2D bivariato sul peak | ✅ | `_subpixel_peak` con coefficienti a, b, c, d, e, f dalla stencil 3×3; fallback separabile |
 | P5 | Golden-section angle search | ✅ | Sostituisce 5 sample equispaziati con log(n) convergenza a tol=0.1° |
 | P2 | Weighted centroid del plateau | ✅ | Integrato in `_subpixel_peak` con peso = (score - soglia)² |
 Benchmark suite 16 scenari (4 immagini × full/part × fast/preciso):
 - Prima Fase 1:  totale find 27.3s
 - Dopo  Fase 1:  totale find 25.1s (~8% speedup)
 - Regressione match count: nessuna (alcuni casi +1 match grazie a subpixel migliore)
 - Match auto-referenziale: offset 0.00 px, angolo 0.000° (era -3.5 px, -2.5°)
 ## Performance CPU
 | Sviluppo | Effort | Speed-up atteso | Dipendenze | Priorità |
@@ -26,6 +26,7 @@ della ROI (modello non-rettangolare).
 from __future__ import annotations
 import math
 import os
 from concurrent.futures import ThreadPoolExecutor
 from dataclasses import dataclass
@@ -33,6 +34,8 @@ from dataclasses import dataclass
 import cv2
 import numpy as np
 _GOLDEN = (math.sqrt(5.0) - 1.0) / 2.0  # ≈ 0.618
 from pm2d._jit_kernels import (
    score_by_shift as _jit_score_by_shift,
    score_bitmap as _jit_score_bitmap,
@@ -338,9 +341,10 @@ class LineShapeMatcher:
    ) -> tuple[float, float]:
        """Posizione sub-pixel del picco.
-        Se c'è un plateau di valori ~massimi (spread_radius satura il peak
+        1. Plateau saturo → centroide pesato del plateau (peso = score).
-        su un'area) ritorna il CENTROIDE del plateau. Altrimenti fit
+        2. Altrimenti → fit quadratico 2D bivariato sui 9 vicini
-        parabolico 2D ±0.5 px.
+           (z = a + b·dx + c·dy + d·dx² + e·dy² + f·dx·dy), argmax risolto
           analiticamente con clamping ±0.5 px.
        """
        H, W = acc.shape
        val = float(acc[y, x])
@@ -350,18 +354,37 @@ class LineShapeMatcher:
        patch = acc[y0:y1, x0:x1]
        plateau = patch >= val - 0.01
        if plateau.sum() > 1:
            # Centroide pesato per (score - (max-0.01))² per enfatizzare i top
            weights = np.where(plateau, patch - (val - 0.01), 0.0).astype(np.float64)
            weights = weights * weights
            total = weights.sum()
            if total > 1e-9:
                ys_idx, xs_idx = np.indices(patch.shape)
                cx_w = (xs_idx * weights).sum() / total
                cy_w = (ys_idx * weights).sum() / total
                return float(x0 + cx_w), float(y0 + cy_w)
            ys_m, xs_m = np.where(plateau)
            return float(x0 + xs_m.mean()), float(y0 + ys_m.mean())
-        # Fallback parabolico
+        # Fit quadratico 2D bivariato su 3x3 intorno
        if x <= 0 or x >= W - 1 or y <= 0 or y >= H - 1:
            return float(x), float(y)
-        c = acc[y, x]
+        # Stencil 3x3: Z[i, j] con i,j ∈ {-1, 0, +1}
-        dx2 = acc[y, x + 1] - 2 * c + acc[y, x - 1]
+        Z = acc[y - 1:y + 2, x - 1:x + 2].astype(np.float64)
-        dy2 = acc[y + 1, x] - 2 * c + acc[y - 1, x]
+        # Coefficienti da finite differences
-        dx1 = (acc[y, x + 1] - acc[y, x - 1]) / 2.0
+        b_c = (Z[1, 2] - Z[1, 0]) / 2.0
-        dy1 = (acc[y + 1, x] - acc[y - 1, x]) / 2.0
+        c_c = (Z[2, 1] - Z[0, 1]) / 2.0
-        ox = -dx1 / dx2 if abs(dx2) > 1e-6 else 0.0
+        d_c = (Z[1, 2] + Z[1, 0] - 2.0 * Z[1, 1]) / 2.0
-        oy = -dy1 / dy2 if abs(dy2) > 1e-6 else 0.0
+        e_c = (Z[2, 1] + Z[0, 1] - 2.0 * Z[1, 1]) / 2.0
        f_c = (Z[2, 2] - Z[0, 2] - Z[2, 0] + Z[0, 0]) / 4.0
        # Max: risolve [2d f; f 2e][dx;dy] = [-b;-c]
        det = 4.0 * d_c * e_c - f_c * f_c
        if abs(det) > 1e-9:
            ox = (-2.0 * e_c * b_c + f_c * c_c) / det
            oy = (-2.0 * d_c * c_c + f_c * b_c) / det
        else:
            # Fallback separabile
            ox = -b_c / (2.0 * d_c) if abs(d_c) > 1e-6 else 0.0
            oy = -c_c / (2.0 * e_c) if abs(e_c) > 1e-6 else 0.0
        ox = float(np.clip(ox, -0.5, 0.5))
        oy = float(np.clip(oy, -0.5, 0.5))
        return x + ox, y + oy
@@ -384,16 +407,11 @@ class LineShapeMatcher:
        l'angolo con score massimo (parabolic fit sulle 3 score centrali).
        Ritorna (angle_refined, score, cx_refined, cy_refined).
        """
-        # Se il match grezzo è già quasi perfetto, NON refinare: il parabolic
+        # Se il match grezzo è già quasi perfetto, NON refinare
        # fit su picco saturo produce spostamenti spurious di posizione e
        # angolo (esempio: modello==scena deve dare ang=0, pos=centro ROI)
        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
        offsets = np.linspace(-search_radius, search_radius, 5)
        best = (angle_deg, -1.0, cx, cy)
        scores_by_off: dict[float, float] = {}
        h, w = template_gray.shape
        sw = max(16, int(round(w * scale)))
@@ -409,10 +427,10 @@ class LineShapeMatcher:
        center = (diag / 2.0, diag / 2.0)
        H, W = spread0.shape
        # Ricerca locale posizione con margine ±2 px sulla (cx, cy)
        margin = 3
-        for off in offsets:
+        def _score_at_angle(off: float) -> tuple[float, float, float]:
            """Ritorna (score, best_cx, best_cy) per angolo = angle_deg + off."""
            ang = angle_deg + off
            M = cv2.getRotationMatrix2D(center, ang, 1.0)
            gray_r = cv2.warpAffine(gray_p, M, (diag, diag),
@@ -423,22 +441,20 @@ class LineShapeMatcher:
            mag, bins = self._gradient(gray_r)
            fx, fy, fb = self._extract_features(mag, bins, mask_r)
            if len(fx) < 8:
-                scores_by_off[float(off)] = 0.0
+                return (0.0, cx, cy)
                continue
            dx = (fx - center[0]).astype(np.int32)
            dy = (fy - center[1]).astype(np.int32)
            # Finestra locale ±margin attorno a (cx, cy) via slicing su bitmap
            y_lo = int(cy) - margin; y_hi = int(cy) + margin + 1
            x_lo = int(cx) - margin; x_hi = int(cx) + margin + 1
-            sh = y_hi - y_lo; sw = x_hi - x_lo
+            sh_w = y_hi - y_lo; sw_w = x_hi - x_lo
-            acc = np.zeros((sh, sw), dtype=np.float32)
+            acc = np.zeros((sh_w, sw_w), dtype=np.float32)
            for i in range(len(dx)):
                ddx = int(dx[i]); ddy = int(dy[i]); b = int(fb[i])
                bit = np.uint8(1 << b)
                sy0 = y_lo + ddy; sy1 = y_hi + ddy
                sx0 = x_lo + ddx; sx1 = x_hi + ddx
-                a_y0 = max(0, -sy0); a_y1 = sh - max(0, sy1 - H)
+                a_y0 = max(0, -sy0); a_y1 = sh_w - max(0, sy1 - H)
-                a_x0 = max(0, -sx0); a_x1 = sw - max(0, sx1 - W)
+                a_x0 = max(0, -sx0); a_x1 = sw_w - max(0, sx1 - W)
                s_y0 = max(0, sy0); s_y1 = min(H, sy1)
                s_x0 = max(0, sx0); s_x1 = min(W, sx1)
                if s_y1 > s_y0 and s_x1 > s_x0:
@@ -448,31 +464,39 @@ class LineShapeMatcher:
                    ).astype(np.float32)
            acc /= len(dx)
            _, max_val, _, max_loc = cv2.minMaxLoc(acc)
-            scores_by_off[float(off)] = float(max_val)
+            return (float(max_val),
-            if max_val > best[1]:
+                    float(x_lo + max_loc[0]), float(y_lo + max_loc[1]))
                new_cx = x_lo + float(max_loc[0])
                new_cy = y_lo + float(max_loc[1])
                best = (ang, float(max_val), new_cx, new_cy)
-        # Parabolic fit su 3 angoli attorno al massimo
+        # Golden-section search su [-search_radius, +search_radius]:
-        sorted_offs = sorted(scores_by_off.keys())
+        # converge in log tempo a precisione ~0.1°, ~8 valutazioni vs 5
-        best_off = best[0] - angle_deg
+        # ma centrate su picco reale (non sample equispaziati).
-        try:
+        a_lo = -search_radius
-            i = sorted_offs.index(
+        a_hi = +search_radius
-                min(sorted_offs, key=lambda x: abs(x - best_off))
+        x1 = a_hi - _GOLDEN * (a_hi - a_lo)
-            )
+        x2 = a_lo + _GOLDEN * (a_hi - a_lo)
-            if 0 < i < len(sorted_offs) - 1:
+        s1, cx1, cy1 = _score_at_angle(x1)
-                s0 = scores_by_off[sorted_offs[i - 1]]
+        s2, cx2, cy2 = _score_at_angle(x2)
-                s1 = scores_by_off[sorted_offs[i]]
+        # Score all'origine come riferimento (ang offset 0)
-                s2 = scores_by_off[sorted_offs[i + 1]]
+        s0, cx0_s, cy0_s = _score_at_angle(0.0)
-                denom = (s0 - 2 * s1 + s2)
+        best = (angle_deg, s0, cx0_s, cy0_s)
-                if abs(denom) > 1e-6:
+        tol = 0.1  # gradi
-                    delta = 0.5 * (s0 - s2) / denom
+        for _ in range(8):
-                    step = sorted_offs[i + 1] - sorted_offs[i]
+            if s1 > best[1]:
-                    refined_off = sorted_offs[i] + delta * step
+                best = (angle_deg + x1, s1, cx1, cy1)
-                    return (angle_deg + refined_off, best[1], best[2], best[3])
+            if s2 > best[1]:
-        except ValueError:
+                best = (angle_deg + x2, s2, cx2, cy2)
-            pass
+            if abs(a_hi - a_lo) < tol:
                break
            if s1 > s2:
                a_hi = x2
                x2 = x1; s2 = s1; cx2 = cx1; cy2 = cy1
                x1 = a_hi - _GOLDEN * (a_hi - a_lo)
                s1, cx1, cy1 = _score_at_angle(x1)
            else:
                a_lo = x1
                x1 = x2; s1 = s2; cx1 = cx2; cy1 = cy2
                x2 = a_lo + _GOLDEN * (a_hi - a_lo)
                s2, cx2, cy2 = _score_at_angle(x2)
        return best
    def _verify_ncc(
@@ -523,6 +547,7 @@ class LineShapeMatcher:
        subpixel: bool = True,
        verify_ncc: bool = True,
        verify_threshold: float = 0.4,
        coarse_angle_factor: int = 2,
    ) -> list[Match]:
        if not self.variants:
            raise RuntimeError("Matcher non addestrato: chiamare train() prima.")
@@ -564,7 +589,30 @@ class LineShapeMatcher:
        def _rescore(score: np.ndarray, bg: np.ndarray) -> np.ndarray:
            return np.maximum(0.0, (score - bg) / (1.0 - bg + 1e-6))
-        # Pruning varianti via top-level (parallelizzato)
+        # Coarse-to-fine angolare:
        # 1) Raggruppa varianti per scala, ordina per angolo
        # 2) Top-level: valuta solo 1 ogni coarse_angle_factor varianti
        # 3) Espandi ai vicini nel full-res
        variants_by_scale: dict[float, list[int]] = {}
        for vi, var in enumerate(self.variants):
            variants_by_scale.setdefault(var.scale, []).append(vi)
        coarse_idx_list: list[int] = []  # varianti da valutare al top
        neighbor_map: dict[int, list[int]] = {}  # vi_coarse -> indici vicini
        cf = max(1, coarse_angle_factor)
        for scale_key, vi_list in variants_by_scale.items():
            vi_sorted = sorted(vi_list, key=lambda i: self.variants[i].angle_deg)
            n = len(vi_sorted)
            for i in range(0, n, cf):
                vi_c = vi_sorted[i]
                coarse_idx_list.append(vi_c)
                # Vicini: ±cf/2 attorno a i (stessa scala)
                half = cf // 2
                start = max(0, i - half)
                end = min(n, i + half + 1)
                neighbor_map[vi_c] = vi_sorted[start:end]
        # Pruning varianti via top-level (parallelizzato) - solo coarse
        def _top_score(vi: int) -> tuple[int, float]:
            var = self.variants[vi]
            lvl = var.levels[min(top, len(var.levels) - 1)]
@@ -574,17 +622,30 @@ class LineShapeMatcher:
            score = _rescore(score, bg_cache_top[var.scale])
            return vi, float(score.max()) if score.size else -1.0
-        kept_variants: list[tuple[int, float]] = []
+        kept_coarse: list[tuple[int, float]] = []
-        if self.n_threads > 1:
+        if 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, range(len(self.variants))):
+                for vi, best in ex.map(_top_score, coarse_idx_list):
                    if best >= top_thresh:
-                        kept_variants.append((vi, best))
+                        kept_coarse.append((vi, best))
        else:
-            for vi in range(len(self.variants)):
+            for vi in coarse_idx_list:
                vi2, best = _top_score(vi)
                if best >= top_thresh:
-                    kept_variants.append((vi2, best))
+                    kept_coarse.append((vi2, best))
        # Espandi ogni coarse promosso con i suoi vicini (stessa scala,
        # angoli intermedi non valutati al top)
        expanded: set[int] = set()
        score_by_vi: dict[int, float] = {}
        for vi_c, s_top in kept_coarse:
            for vi_n in neighbor_map.get(vi_c, [vi_c]):
                expanded.add(vi_n)
                # Usa lo score del coarse come stima per il sort successivo
                score_by_vi[vi_n] = max(score_by_vi.get(vi_n, 0.0), s_top)
        kept_variants: list[tuple[int, float]] = [
            (vi, score_by_vi[vi]) for vi in expanded
        ]
        if not kept_variants:
            return []
@@ -9,10 +9,12 @@ Endpoint:
 """
 from __future__ import annotations
 import hashlib
 import os
 import tempfile
 import time
 import uuid
 from collections import OrderedDict
 from pathlib import Path
 import cv2
@@ -61,6 +63,39 @@ CACHE_DIR.mkdir(exist_ok=True)
 # Cache in-memory (soft, ricaricata da disco se mancante)
 _IMG_CACHE: dict[str, np.ndarray] = {}
 # Cache matcher addestrati: (roi_hash, params_hash) -> LineShapeMatcher
 # LRU con capacità limitata
 _MATCHER_CACHE: OrderedDict = OrderedDict()
 _MATCHER_CACHE_SIZE = 8
 def _matcher_cache_key(roi: np.ndarray, tech: dict) -> str:
    h = hashlib.md5()
    h.update(roi.tobytes())
    # Solo parametri che influenzano il training
    relevant = ("num_features", "weak_grad", "strong_grad",
                "angle_min", "angle_max", "angle_step",
                "scale_min", "scale_max", "scale_step",
                "spread_radius", "pyramid_levels")
    for k in relevant:
        h.update(f"{k}={tech.get(k)}".encode())
    h.update(f"shape={roi.shape}".encode())
    return h.hexdigest()
 def _cache_get_matcher(key: str):
    m = _MATCHER_CACHE.get(key)
    if m is not None:
        _MATCHER_CACHE.move_to_end(key)  # LRU touch
    return m
 def _cache_put_matcher(key: str, matcher) -> None:
    _MATCHER_CACHE[key] = matcher
    _MATCHER_CACHE.move_to_end(key)
    while len(_MATCHER_CACHE) > _MATCHER_CACHE_SIZE:
        _MATCHER_CACHE.popitem(last=False)
 def _store_image(img: np.ndarray) -> str:
    iid = uuid.uuid4().hex[:12]
@@ -375,6 +410,19 @@ def match(p: MatchParams):
    h = max(1, min(h, model.shape[0] - y))
    roi_img = model[y:y + h, x:x + w]
    tech_for_cache = {
        "num_features": p.num_features,
        "weak_grad": p.weak_grad, "strong_grad": p.strong_grad,
        "angle_min": p.angle_min, "angle_max": p.angle_max,
        "angle_step": p.angle_step,
        "scale_min": p.scale_min, "scale_max": p.scale_max,
        "scale_step": p.scale_step,
        "spread_radius": p.spread_radius,
        "pyramid_levels": p.pyramid_levels,
    }
    key = _matcher_cache_key(roi_img, tech_for_cache)
    m = _cache_get_matcher(key)
    if m is None:
        m = LineShapeMatcher(
            num_features=p.num_features,
            weak_grad=p.weak_grad, strong_grad=p.strong_grad,
@@ -386,6 +434,9 @@ def match(p: MatchParams):
            pyramid_levels=p.pyramid_levels,
        )
        t0 = time.time(); n = m.train(roi_img); t_train = time.time() - t0
        _cache_put_matcher(key, m)
    else:
        n = len(m.variants); t_train = 0.0
    nms = p.nms_radius if p.nms_radius > 0 else None
    t0 = time.time()
    matches = m.find(
@@ -429,6 +480,9 @@ def match_simple(p: SimpleMatchParams):
    tech = _simple_to_technical(p, roi_img)
    key = _matcher_cache_key(roi_img, tech)
    m = _cache_get_matcher(key)
    if m is None:
        m = LineShapeMatcher(
            num_features=tech["num_features"],
            weak_grad=tech["weak_grad"], strong_grad=tech["strong_grad"],
@@ -440,6 +494,9 @@ def match_simple(p: SimpleMatchParams):
            pyramid_levels=tech["pyramid_levels"],
        )
        t0 = time.time(); n = m.train(roi_img); t_train = time.time() - t0
        _cache_put_matcher(key, m)
    else:
        n = len(m.variants); t_train = 0.0
    nms = tech["nms_radius"] if tech["nms_radius"] > 0 else None
    t0 = time.time()
    matches = m.find(