Shape_Model_2D/pm2d/web/server.py

"""FastAPI webapp standalone per PM2D.

Endpoint:
  GET  /                    → HTML UI
  POST /upload              → upload immagine (multipart)
  POST /match               → JSON params + ids → results
  GET  /image/{id}/raw      → PNG originale
  GET  /image/{id}/annotated → PNG con overlay match
"""
from __future__ import annotations

import hashlib
import os
import tempfile
import time
import uuid
from collections import OrderedDict
from pathlib import Path

import cv2
import numpy as np
from fastapi import FastAPI, File, HTTPException, UploadFile
from fastapi.responses import HTMLResponse, Response
from fastapi.staticfiles import StaticFiles
from pydantic import BaseModel


def _load_env(root: Path) -> None:
    """Legge .env in root e popola os.environ (no override se già set)."""
    f = root / ".env"
    if not f.exists():
        return
    for line in f.read_text(encoding="utf-8").splitlines():
        line = line.strip()
        if not line or line.startswith("#") or "=" not in line:
            continue
        k, v = line.split("=", 1)
        k = k.strip(); v = v.strip().strip('"').strip("'")
        os.environ.setdefault(k, v)


# Root progetto (parent di pm2d/)
PROJECT_ROOT = Path(__file__).resolve().parents[2]
_load_env(PROJECT_ROOT)

_images_dir_raw = os.environ.get("IMAGES_DIR", "Test")
IMAGES_DIR = Path(_images_dir_raw)
if not IMAGES_DIR.is_absolute():
    IMAGES_DIR = PROJECT_ROOT / IMAGES_DIR

# Cartella ricette pre-trained (V feature: save/load matcher)
RECIPES_DIR = PROJECT_ROOT / "recipes"
RECIPES_DIR.mkdir(exist_ok=True)

from pm2d.line_matcher import LineShapeMatcher, Match
from pm2d.auto_tune import auto_tune


WEB_DIR = Path(__file__).parent
STATIC_DIR = WEB_DIR / "static"
STATIC_DIR.mkdir(exist_ok=True)

# Persistenza immagini su disco (sopravvive a restart server)
CACHE_DIR = Path(tempfile.gettempdir()) / "pm2d_cache"
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]
    cv2.imwrite(str(CACHE_DIR / f"{iid}.png"), img)
    _IMG_CACHE[iid] = img
    return iid


def _load_image(iid: str) -> np.ndarray | None:
    cached = _IMG_CACHE.get(iid)
    if cached is not None:
        return cached
    p = CACHE_DIR / f"{iid}.png"
    if not p.exists():
        return None
    img = cv2.imread(str(p))
    if img is not None:
        _IMG_CACHE[iid] = img
    return img

app = FastAPI(title="PM2D Webapp", version="1.0.0")


def _encode_png(img: np.ndarray) -> bytes:
    ok, buf = cv2.imencode(".png", img)
    if not ok:
        raise RuntimeError("PNG encode failed")
    return buf.tobytes()


def _draw_matches(scene: np.ndarray, matches: list[Match],
                   template_gray: np.ndarray | None) -> np.ndarray:
    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),
    ]
    for i, m in enumerate(matches):
        color = palette[i % len(palette)]
        if template_gray 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
            warped = cv2.warpAffine(edge, M, (W, H),
                                     flags=cv2.INTER_NEAREST, borderValue=0)
            mask = warped > 0
            if mask.any():
                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)
        cv2.polylines(out, [poly], True, color, 2, cv2.LINE_AA)
        p0 = tuple(m.bbox_poly[0].astype(int))
        p1 = tuple(m.bbox_poly[1].astype(int))
        cv2.line(out, p0, p1, color, 4, cv2.LINE_AA)
        cx, cy = int(round(m.cx)), int(round(m.cy))
        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)
        cv2.arrowedLine(out, (cx, cy),
                        (int(cx + L * np.cos(a)), int(cy - L * np.sin(a))),
                        color, 2, cv2.LINE_AA, tipLength=0.2)
        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.FONT_HERSHEY_SIMPLEX, 0.5, color, 2, cv2.LINE_AA)
    return out


# ---------------- Models ----------------

class UploadResp(BaseModel):
    id: str
    width: int
    height: int


class MatchParams(BaseModel):
    model_id: str
    scene_id: str
    roi: list[int]  # [x, y, w, h] nell'immagine modello
    angle_min: float = 0.0
    angle_max: float = 360.0
    angle_step: float = 5.0
    scale_min: float = 1.0
    scale_max: float = 1.0
    scale_step: float = 0.1
    min_score: float = 0.55
    max_matches: int = 25
    nms_radius: int = 0
    num_features: int = 96
    weak_grad: float = 30.0
    strong_grad: float = 60.0
    spread_radius: int = 5
    pyramid_levels: int = 3
    verify_threshold: float = 0.4


class MatchResult(BaseModel):
    cx: float
    cy: float
    angle_deg: float
    scale: float
    score: float
    bbox_poly: list[list[float]]


class MatchResp(BaseModel):
    matches: list[MatchResult]
    train_time: float
    find_time: float
    num_variants: int
    annotated_id: str


class TuneParams(BaseModel):
    model_id: str
    roi: list[int]


# ---------- User-facing (simple) params ----------

SYMMETRY_TO_ANGLE_MAX = {
    "invariante": 0.0,   # oggetto simmetrico a rotazione totale (cerchi): 1 variante
    "nessuna": 360.0,
    "bilaterale": 180.0,
    "rot_3": 120.0,
    "rot_4": 90.0,
    "rot_6": 60.0,
    "rot_8": 45.0,
}

SCALE_PRESETS = {
    "fissa":  (1.0, 1.0, 0.1),
    "mini":   (0.9, 1.1, 0.05),    # ±10%
    "medio":  (0.75, 1.25, 0.05),  # ±25%
    "max":    (0.5, 1.5, 0.05),    # ±50%
}

PRECISION_ANGLE_STEP = {
    "veloce": 10.0,
    "normale": 5.0,
    "preciso": 2.0,
}

# "Filtro falsi positivi" = mapping semantico del verify NCC threshold.
# Un operatore sceglie il livello di rigore, non un numero astratto.
FILTRO_FP_MAP = {
    "off":      0.0,   # disabilitato: mantieni tutti i match shape-based
    "leggero":  0.30,  # tollera variazioni intensità/illuminazione forti
    "medio":    0.50,  # default bilanciato (consigliato)
    "forte":    0.70,  # scarta match con intensità molto diversa dal template
}


class SimpleMatchParams(BaseModel):
    model_id: str
    scene_id: str
    roi: list[int]
    tipo: str = "intero"              # "intero" | "parziale"
    simmetria: str = "nessuna"        # chiave SYMMETRY_TO_ANGLE_MAX
    scala: str = "fissa"              # chiave SCALE_PRESETS
    precisione: str = "normale"       # chiave PRECISION_ANGLE_STEP
    filtro_fp: str = "medio"          # chiave FILTRO_FP_MAP
    penalita_scala: float = 0.0       # 0 = score shape invariante, >0 = penalizza scala != 1
    min_score: float = 0.65
    max_matches: int = 25
    # --- Halcon-mode flags (default off = backward compat) ---
    # Init-time (richiede ri-train se cambiato)
    use_polarity: bool = False        # F: 16 bin orientation mod 2pi
    use_gpu: bool = False             # R: OpenCL UMat (silent fallback)
    # Find-time (no retrain)
    min_recall: float = 0.0           # M: filtra match con poche feature combaciate
    use_soft_score: bool = False      # Y: cosine sim continua dei gradients
    subpixel_lm: bool = False         # Z: precisione 0.05 px
    nms_iou_threshold: float = 0.3    # A: IoU bbox poligonale
    coarse_stride: int = 1            # sub-sampling top-level (>=1)
    pyramid_propagate: bool = False   # propagazione candidati top->full
    greediness: float = 0.0           # early-exit kernel (0..1)
    refine_pose_joint: bool = False   # Nelder-Mead 3D (cx, cy, angle)
    search_roi: list[int] | None = None  # [x, y, w, h] limita area


def _simple_to_technical(
    p: SimpleMatchParams, roi_img: np.ndarray,
) -> dict:
    """Converti parametri user-facing → tecnici usando analisi della ROI."""
    from pm2d.auto_tune import auto_tune as _auto

    tune = _auto(roi_img)
    h, w = roi_img.shape[:2]
    min_side = min(h, w)

    # Feature count: parziale = meno feature (area minore)
    nf = tune["num_features"]
    if p.tipo == "parziale":
        nf = max(32, int(nf * 0.6))

    # Piramide derivata da dimensione ROI
    if min_side < 60:
        pyr = 1
    elif min_side < 150:
        pyr = 2
    elif min_side < 400:
        pyr = 3
    else:
        pyr = 4

    # Spread radius ~2-3% del lato minimo
    spread = max(3, min(10, int(round(min_side * 0.03))))

    angle_max = SYMMETRY_TO_ANGLE_MAX.get(p.simmetria, 360.0)
    smin, smax, sstep = SCALE_PRESETS.get(p.scala, (1.0, 1.0, 0.1))
    ang_step = PRECISION_ANGLE_STEP.get(p.precisione, 5.0)

    return {
        "num_features": nf,
        "weak_grad": tune["weak_grad"],
        "strong_grad": tune["strong_grad"],
        "spread_radius": spread,
        "pyramid_levels": pyr,
        "angle_min": 0.0,
        "angle_max": angle_max,
        "angle_step": ang_step,
        "scale_min": smin,
        "scale_max": smax,
        "scale_step": sstep,
        "min_score": p.min_score,
        "max_matches": p.max_matches,
        "nms_radius": 0,
        "verify_threshold": FILTRO_FP_MAP.get(p.filtro_fp, 0.35),
        "scale_penalty": p.penalita_scala,
    }


# ---------------- Endpoints ----------------

@app.get("/", response_class=HTMLResponse)
def index():
    html_path = STATIC_DIR / "index.html"
    return HTMLResponse(html_path.read_text(encoding="utf-8"))


@app.post("/upload_to_folder")
async def upload_to_folder(file: UploadFile = File(...)):
    """Salva file caricato nella cartella IMAGES_DIR. Ritorna lista aggiornata."""
    if not IMAGES_DIR.is_dir():
        raise HTTPException(500, f"IMAGES_DIR non esiste: {IMAGES_DIR}")
    # Sanitizza nome file (no traversal)
    name = Path(file.filename or "upload.png").name
    if not name:
        raise HTTPException(400, "nome file vuoto")
    ext = Path(name).suffix.lower()
    allowed = {".png", ".jpg", ".jpeg", ".bmp", ".tif", ".tiff"}
    if ext not in allowed:
        raise HTTPException(400, f"estensione non supportata: {ext}")
    # Leggi contenuto e valida come immagine
    data = await file.read()
    arr = np.frombuffer(data, dtype=np.uint8)
    img = cv2.imdecode(arr, cv2.IMREAD_COLOR)
    if img is None:
        raise HTTPException(400, "file non è un'immagine valida")
    # Evita overwrite: se esiste, aggiungi suffisso numerico
    target = IMAGES_DIR / name
    if target.exists():
        stem = target.stem; suffix = target.suffix
        i = 1
        while True:
            alt = IMAGES_DIR / f"{stem}_{i}{suffix}"
            if not alt.exists():
                target = alt; break
            i += 1
    # Scrivi su disco
    with open(target, "wb") as f:
        f.write(data)
    # Ritorna lista aggiornata
    return {
        "saved_as": target.name,
        "dir": str(IMAGES_DIR),
        "files": sorted(
            p.name for p in IMAGES_DIR.iterdir()
            if p.is_file() and p.suffix.lower() in allowed
        ),
    }


@app.get("/folder_image/{filename}")
def folder_image(filename: str, w: int = 120):
    """Serve thumbnail PNG dell'immagine IMAGES_DIR (scalata a width w)."""
    if "/" in filename or ".." in filename:
        raise HTTPException(400, "nome non valido")
    path = IMAGES_DIR / filename
    if not path.is_file():
        raise HTTPException(404, "non trovato")
    img = cv2.imread(str(path), cv2.IMREAD_COLOR)
    if img is None:
        raise HTTPException(400, "non leggibile")
    h0, w0 = img.shape[:2]
    if w0 > w:
        sc = w / w0
        img = cv2.resize(img, (w, int(h0 * sc)), interpolation=cv2.INTER_AREA)
    return Response(_encode_png(img), media_type="image/png",
                    headers={"Cache-Control": "public, max-age=3600"})


@app.get("/images")
def list_images():
    """Lista file immagine nella cartella configurata in IMAGES_DIR."""
    if not IMAGES_DIR.is_dir():
        return {"dir": str(IMAGES_DIR), "files": []}
    exts = {".png", ".jpg", ".jpeg", ".bmp", ".tif", ".tiff"}
    files = sorted(
        p.name for p in IMAGES_DIR.iterdir()
        if p.is_file() and p.suffix.lower() in exts
    )
    return {"dir": str(IMAGES_DIR), "files": files}


class LoadFolderReq(BaseModel):
    filename: str


@app.post("/load_from_folder", response_model=UploadResp)
def load_from_folder(req: LoadFolderReq):
    """Carica immagine dalla cartella IMAGES_DIR per nome file."""
    name = req.filename
    if "/" in name or ".." in name:
        raise HTTPException(400, "nome file non valido")
    path = IMAGES_DIR / name
    if not path.is_file():
        raise HTTPException(404, f"file non trovato: {name}")
    img = cv2.imread(str(path), cv2.IMREAD_COLOR)
    if img is None:
        raise HTTPException(400, "immagine non leggibile")
    iid = _store_image(img)
    return UploadResp(id=iid, width=img.shape[1], height=img.shape[0])


@app.post("/upload", response_model=UploadResp)
async def upload(file: UploadFile = File(...)):
    data = await file.read()
    arr = np.frombuffer(data, dtype=np.uint8)
    img = cv2.imdecode(arr, cv2.IMREAD_COLOR)
    if img is None:
        raise HTTPException(400, "Immagine non valida")
    iid = _store_image(img)
    return UploadResp(id=iid, width=img.shape[1], height=img.shape[0])


@app.get("/image/{iid}/raw")
def image_raw(iid: str):
    img = _load_image(iid)
    if img is None:
        raise HTTPException(404, "Image not found")
    return Response(_encode_png(img), media_type="image/png")


@app.post("/match", response_model=MatchResp)
def match(p: MatchParams):
    model = _load_image(p.model_id)
    scene = _load_image(p.scene_id)
    if model is None or scene is None:
        raise HTTPException(404, "Immagini non trovate")
    x, y, w, h = p.roi
    x = max(0, x); y = max(0, y)
    w = max(1, min(w, model.shape[1] - x))
    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,
            angle_range_deg=(p.angle_min, p.angle_max),
            angle_step_deg=p.angle_step,
            scale_range=(p.scale_min, p.scale_max),
            scale_step=p.scale_step,
            spread_radius=p.spread_radius,
            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(
        scene, min_score=p.min_score, max_matches=p.max_matches,
        nms_radius=nms, verify_threshold=p.verify_threshold,
    )
    t_find = time.time() - t0

    # Render annotated image
    tg = cv2.cvtColor(roi_img, cv2.COLOR_BGR2GRAY)
    annotated = _draw_matches(scene, matches, tg)
    ann_id = _store_image(annotated)

    return MatchResp(
        matches=[MatchResult(
            cx=m_.cx, cy=m_.cy, angle_deg=m_.angle_deg, scale=m_.scale,
            score=m_.score,
            bbox_poly=m_.bbox_poly.tolist(),
        ) for m_ in matches],
        train_time=t_train, find_time=t_find,
        num_variants=n, annotated_id=ann_id,
    )


@app.post("/match_simple", response_model=MatchResp)
def match_simple(p: SimpleMatchParams):
    """Match con parametri user-facing (tipo/simmetria/scala/precisione).

    Il server deriva i parametri tecnici (num_features, soglie gradiente,
    piramide, ecc.) dall'analisi automatica della ROI.
    """
    model = _load_image(p.model_id)
    scene = _load_image(p.scene_id)
    if model is None or scene is None:
        raise HTTPException(404, "Immagini non trovate")
    x, y, w, h = p.roi
    x = max(0, x); y = max(0, y)
    w = max(1, min(w, model.shape[1] - x))
    h = max(1, min(h, model.shape[0] - y))
    roi_img = model[y:y + h, x:x + w]

    tech = _simple_to_technical(p, roi_img)

    key = _matcher_cache_key(roi_img, tech)
    # Halcon-mode init params: incidono sul training, includere in cache key
    halcon_init_key = f"|pol={p.use_polarity}|gpu={p.use_gpu}"
    key = key + halcon_init_key
    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"],
            angle_range_deg=(tech["angle_min"], tech["angle_max"]),
            angle_step_deg=tech["angle_step"],
            scale_range=(tech["scale_min"], tech["scale_max"]),
            scale_step=tech["scale_step"],
            spread_radius=tech["spread_radius"],
            pyramid_levels=tech["pyramid_levels"],
            use_polarity=p.use_polarity,
            use_gpu=p.use_gpu,
        )
        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
    search_roi_t = tuple(p.search_roi) if p.search_roi else None
    t0 = time.time()
    matches = m.find(
        scene, min_score=tech["min_score"], max_matches=tech["max_matches"],
        nms_radius=nms, verify_threshold=tech["verify_threshold"],
        scale_penalty=tech.get("scale_penalty", 0.0),
        # Halcon-mode flags
        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 = cv2.cvtColor(roi_img, cv2.COLOR_BGR2GRAY)
    annotated = _draw_matches(scene, matches, tg)
    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=t_train, find_time=t_find,
        num_variants=n, annotated_id=ann_id,
    )


@app.post("/auto_tune")
def tune(p: TuneParams):
    model = _load_image(p.model_id)
    if model is None:
        raise HTTPException(404, "Immagine non trovata")
    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("_")}


# --- V: Save/Load ricette pre-trained ---

class SaveRecipeParams(BaseModel):
    model_id: str
    scene_id: str | None = None
    roi: list[int]
    # Riusa stessi param simple per training equivalente
    tipo: str = "intero"
    simmetria: str = "nessuna"
    scala: str = "fissa"
    precisione: str = "normale"
    use_polarity: bool = False
    use_gpu: bool = False
    name: str  # nome file ricetta (no path)


@app.post("/recipes")
def save_recipe(p: SaveRecipeParams):
    """Allena matcher e salva su disco come ricetta riutilizzabile."""
    model = _load_image(p.model_id)
    if model is None:
        raise HTTPException(404, "Modello non trovato")
    x, y, w, h = p.roi
    roi_img = model[y:y + h, x:x + w]
    sp = SimpleMatchParams(
        model_id=p.model_id, scene_id=p.scene_id or p.model_id, roi=p.roi,
        tipo=p.tipo, simmetria=p.simmetria, scala=p.scala,
        precisione=p.precisione,
        use_polarity=p.use_polarity, use_gpu=p.use_gpu,
    )
    tech = _simple_to_technical(sp, roi_img)
    m = LineShapeMatcher(
        num_features=tech["num_features"],
        weak_grad=tech["weak_grad"], strong_grad=tech["strong_grad"],
        angle_range_deg=(tech["angle_min"], tech["angle_max"]),
        angle_step_deg=tech["angle_step"],
        scale_range=(tech["scale_min"], tech["scale_max"]),
        scale_step=tech["scale_step"],
        spread_radius=tech["spread_radius"],
        pyramid_levels=tech["pyramid_levels"],
        use_polarity=p.use_polarity,
        use_gpu=p.use_gpu,
    )
    m.train(roi_img)
    safe_name = "".join(c for c in p.name if c.isalnum() or c in "._-")
    if not safe_name:
        raise HTTPException(400, "Nome ricetta non valido")
    if not safe_name.endswith(".npz"):
        safe_name += ".npz"
    target = RECIPES_DIR / safe_name
    m.save_model(str(target))
    return {"name": safe_name, "size": target.stat().st_size,
            "n_variants": len(m.variants)}


@app.get("/recipes")
def list_recipes():
    files = []
    if RECIPES_DIR.is_dir():
        for f in sorted(RECIPES_DIR.glob("*.npz")):
            files.append({"name": f.name, "size": f.stat().st_size})
    return {"files": files, "dir": str(RECIPES_DIR)}


# Mount static
app.mount("/static", StaticFiles(directory=STATIC_DIR), name="static")


def serve(host: str = "127.0.0.1", port: int = 8080):
    import uvicorn
    uvicorn.run(app, host=host, port=port, log_level="info")


if __name__ == "__main__":
    serve()