feat(cli): comando option-chain (trigger + analyze) per la catena opzioni

Espone direttamente da CLI le due operazioni più utili sui dati di ``option_chain_snapshots`` raccolti dal cron settimanale: - ``cerbero-bite option-chain trigger`` — esegue UNA volta il collector della catena. Riusa la stessa pipeline schedulata (cron ``55 13 * * MON``) ma on-demand. Utile per popolare il DB senza aspettare lunedì. - ``cerbero-bite option-chain analyze [--bias bull_put|bear_call]`` — legge l'ultimo snapshot, simula il selector di strike (``select_strikes``) con la strategy passata e stampa una tabella con: short/long strike, delta, width, credito reale, ratio credit/width, e PASS/FAIL del gate ``credit_to_width_ratio_min``. Il comando ``analyze`` rende immediatamente actionable la catena appena raccolta: invece di stime ex-ante via Black-Scholes (modulo ``core/backtest.py``), legge i mid REALI di Deribit e dice "il rule engine aprirebbe questo trade qui? credit/width ratio passa o no?". Esempio di output sui primi snapshot raccolti (regime ETH ~2200, DTE ~14g): Snapshot del 2026-05-01T20:53:49 — 21 quote totali Il rule engine NON aprirebbe trade con questa catena (no strike compatibile coi gate delta/distance/width/credit-ratio). Conferma empirica del messaggio del documento ``13-strategia-spiegata``: con delta target 0.12 + width 4% + credit/width ≥ 30%, il regime attuale di ETH options non è abbastanza ricco per produrre trade — serve calibrare soglie o aspettare un regime IV più alto. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
fix(migrations): rinomina 0004 → 0005 per coesistenza con auto_pause
2026-05-01 20:57:40 +00:00 · 2026-05-01 20:52:11 +00:00 · 2026-05-01 20:44:49 +00:00
10 changed files with 779 additions and 1060 deletions
@@ -679,155 +679,6 @@ def replay(date_from: str, date_to: str, capital: float, dry_run: bool) -> None:
    )
@main.command()
@click.option(
    "--strategy",
    "strategy_path",
    type=click.Path(path_type=Path),
    default=Path("strategy.yaml"),
    show_default=True,
    help="Path al file di strategia (golden, conservativa, aggressiva, ...).",
 )
@click.option(
    "--db",
    "db_path",
    type=click.Path(path_type=Path),
    default=_DEFAULT_DB_PATH,
    show_default=True,
    help="SQLite con `market_snapshots` storiche.",
 )
@click.option(
    "--from",
    "date_from",
    type=click.DateTime(formats=["%Y-%m-%d"]),
    default=None,
    help="ISO date YYYY-MM-DD (default: 90 giorni fa).",
 )
@click.option(
    "--to",
    "date_to",
    type=click.DateTime(formats=["%Y-%m-%d"]),
    default=None,
    help="ISO date YYYY-MM-DD (default: oggi).",
 )
@click.option(
    "--capital",
    type=float,
    default=1500.0,
    show_default=True,
    help="Capitale di partenza per il backtest, in USD.",
 )
@click.option(
    "--asset",
    type=str,
    default="ETH",
    show_default=True,
    help="Asset di riferimento per le snapshot.",
 )
@click.option(
    "--no-enforce-hash",
    is_flag=True,
    default=False,
    help="Salta la verifica del config_hash (utile per profili sperimentali).",
 )
 def backtest(
    strategy_path: Path,
    db_path: Path,
    date_from: datetime | None,
    date_to: datetime | None,
    capital: float,
    asset: str,
    no_enforce_hash: bool,
 ) -> None:
    """Esegue il backtest stilizzato su `market_snapshots` storiche.
    Usa lo stesso `validate_entry` del live per i filtri (rigoroso) e
    un modello Black-Scholes con skew premium per stimare credito ed
    exit P/L (stilizzato — vedi docstring di `core/backtest.py`).
    """
    from cerbero_bite.config.loader import load_strategy  # noqa: PLC0415
    from cerbero_bite.core.backtest import run_backtest  # noqa: PLC0415
    console = Console()
    if date_to is None:
        date_to = datetime.now(UTC)
    if date_from is None:
        date_from = date_to - timedelta(days=90)
    date_from = date_from.replace(tzinfo=UTC) if date_from.tzinfo is None else date_from
    date_to = date_to.replace(tzinfo=UTC) if date_to.tzinfo is None else date_to
    loaded = load_strategy(strategy_path, enforce_hash=not no_enforce_hash)
    cfg = loaded.config
    conn = connect_state(db_path)
    try:
        repo = Repository()
        snapshots = repo.list_market_snapshots(
            conn,
            asset=asset.upper(),
            start=date_from,
            end=date_to,
            limit=10000,
        )
    finally:
        conn.close()
    if not snapshots:
        console.print(
            f"[yellow]Nessuno snapshot {asset} trovato fra {date_from.date()} "
            f"e {date_to.date()}.[/yellow]"
        )
        sys.exit(1)
    console.print(
        f"[green]Caricate {len(snapshots)} snapshot {asset} "
        f"({snapshots[-1].timestamp.date()} → {snapshots[0].timestamp.date()})[/green]"
    )
    report = run_backtest(snapshots, cfg, capital_usd=Decimal(str(capital)))
    table = Table(title=f"Backtest report — {strategy_path.name}")
    table.add_column("Metrica", style="cyan")
    table.add_column("Valore", style="bold")
    table.add_row("Picks (lunedì 14:00)", str(report.n_picks))
    table.add_row(
        "Accettati dai filtri",
        f"{report.n_accepted} ({report.n_accepted / max(1, report.n_picks):.0%})",
    )
    table.add_row("Saltati per dato mancante", str(report.n_skipped_data))
    table.add_row("Trade completati (con P/L)", str(report.n_completed))
    table.add_row("Vincenti", f"{report.n_winners} ({report.win_rate:.0%})")
    table.add_row("P/L cumulato (USD)", f"{report.cumulative_pnl_usd:+.2f}")
    table.add_row(
        "P/L su capitale", f"{report.cumulative_pnl_pct_of_capital:+.2%}"
    )
    table.add_row(
        "Max drawdown", f"−{report.max_drawdown_usd:.0f} USD "
        f"({report.max_drawdown_pct:.1%})",
    )
    table.add_row(
        "Sharpe (annualized)",
        f"{report.sharpe_annualized}" if report.sharpe_annualized is not None
        else "—",
    )
    console.print(table)
    if report.skip_reasons:
        skip_table = Table(title="Motivi di skip aggregati")
        skip_table.add_column("Motivo")
        skip_table.add_column("Settimane", justify="right")
        for reason, count in sorted(
            report.skip_reasons.items(), key=lambda kv: -kv[1]
        ):
            skip_table.add_row(reason, str(count))
        console.print(skip_table)
    console.print(
        "[dim]Il modello P/L è stilizzato: BS + skew premium 1.5×. "
        "Numeri ottimi per ranking config, non per promesse operative.[/dim]"
    )
@main.group()
 def config() -> None:
    """Strategy configuration utilities."""
@@ -961,6 +812,241 @@ def state_inspect(db: Path) -> None:
    console.print(table)
@main.group(name="option-chain")
 def option_chain() -> None:
    """Strumenti per la catena opzioni storica (`option_chain_snapshots`)."""
@option_chain.command(name="trigger")
@click.option(
    "--strategy",
    "strategy_path",
    type=click.Path(exists=True, dir_okay=False, path_type=Path),
    default=_DEFAULT_STRATEGY_PATH,
    show_default=True,
 )
@click.option(
    "--db",
    "db_path",
    type=click.Path(dir_okay=False, path_type=Path),
    default=_DEFAULT_DB_PATH,
    show_default=True,
 )
@click.option(
    "--audit",
    "audit_path",
    type=click.Path(dir_okay=False, path_type=Path),
    default=_DEFAULT_AUDIT_PATH,
    show_default=True,
 )
@click.option(
    "--token",
    type=str,
    default=None,
    help="MCP bearer token (override su CERBERO_BITE_MCP_TOKEN).",
 )
@click.option("--asset", default="ETH", show_default=True)
 def option_chain_trigger(
    strategy_path: Path,
    db_path: Path,
    audit_path: Path,
    token: str | None,
    asset: str,
 ) -> None:
    """Esegue UNA volta il collector della catena opzioni e persiste in DB.
    Utile per popolare i dati senza aspettare il cron settimanale del
    job ``option_chain_snapshot``. Riusa esattamente la stessa pipeline
    schedulata.
    """
    from cerbero_bite.runtime.dependencies import build_runtime  # noqa: PLC0415
    from cerbero_bite.runtime.option_chain_snapshot_cycle import (  # noqa: PLC0415
        collect_option_chain_snapshot,
    )
    cfg = load_strategy(strategy_path).config
    ctx = build_runtime(
        cfg=cfg,
        endpoints=load_endpoints(),
        token=load_token(value=token),
        db_path=db_path,
        audit_path=audit_path,
        bot_tag=load_bot_tag(),
    )
    n = asyncio.run(collect_option_chain_snapshot(ctx, asset=asset))
    console.print(
        f"[green]Persisted {n} option chain quote(s) for {asset}[/green]"
        if n > 0
        else f"[yellow]No quotes persisted (chain empty or fetch failed)[/yellow]"
    )
@option_chain.command(name="analyze")
@click.option(
    "--strategy",
    "strategy_path",
    type=click.Path(exists=True, dir_okay=False, path_type=Path),
    default=_DEFAULT_STRATEGY_PATH,
    show_default=True,
 )
@click.option(
    "--db",
    "db_path",
    type=click.Path(dir_okay=False, path_type=Path),
    default=_DEFAULT_DB_PATH,
    show_default=True,
 )
@click.option("--asset", default="ETH", show_default=True)
@click.option(
    "--bias",
    type=click.Choice(["bull_put", "bear_call"], case_sensitive=False),
    default="bull_put",
    show_default=True,
    help="Direzione da simulare (il rule engine lo deciderebbe da trend×funding).",
 )
 def option_chain_analyze(
    strategy_path: Path,
    db_path: Path,
    asset: str,
    bias: str,
 ) -> None:
    """Analizza l'ultimo snapshot di catena salvato.
    Per la strategia indicata, simula la selezione strike (delta
    target, OTM range, width 4%, credit/width ratio min) e mostra:
      * lo strike che il rule engine sceglierebbe come short e long,
      * credito atteso, larghezza, rapporto credit/width,
      * pass/fail del gate `credit_to_width_ratio_min`.
    """
    from cerbero_bite.core.combo_builder import select_strikes  # noqa: PLC0415
    from cerbero_bite.core.types import OptionQuote  # noqa: PLC0415
    cfg = load_strategy(strategy_path).config
    conn = connect_state(db_path)
    try:
        repo = Repository()
        latest_ts = repo.latest_option_chain_timestamp(conn, asset=asset.upper())
        if latest_ts is None:
            console.print(
                "[red]Nessuno snapshot di catena trovato. Lancia prima "
                "`cerbero-bite option-chain trigger`.[/red]"
            )
            sys.exit(1)
        quotes_records = repo.list_option_chain_snapshots(
            conn, asset=asset.upper(), start=latest_ts, end=latest_ts,
        )
    finally:
        conn.close()
    console.print(
        f"[cyan]Snapshot del {latest_ts.isoformat()} — {len(quotes_records)} "
        f"quote totali[/cyan]"
    )
    # Costruzione OptionQuote da OptionChainQuoteRecord per riusare select_strikes.
    quotes: list[OptionQuote] = []
    for q in quotes_records:
        if q.bid is None or q.ask is None or q.mid is None or q.delta is None:
            continue
        quotes.append(
            OptionQuote(
                instrument=q.instrument_name,
                strike=q.strike,
                expiry=q.expiry,
                option_type=q.option_type,
                bid=q.bid,
                ask=q.ask,
                mid=q.mid,
                delta=q.delta,
                gamma=q.gamma or Decimal("0"),
                theta=q.theta or Decimal("0"),
                vega=q.vega or Decimal("0"),
                open_interest=q.open_interest or 0,
                volume_24h=q.volume_24h or 0,
                book_depth_top3=q.book_depth_top3 or 0,
            )
        )
    if not quotes:
        console.print("[red]Nessun quote completo per la simulazione.[/red]")
        sys.exit(1)
    # Lo spot al momento dello snapshot: estraiamo dall'ultimo
    # `market_snapshot` ETH a quel timestamp (tolleranza ±15 min).
    spot = _resolve_spot_at(db_path, asset=asset.upper(), at=latest_ts)
    if spot is None:
        console.print(
            "[yellow]Spot non recuperabile dai market_snapshots; "
            "stimato dal mid ATM.[/yellow]"
        )
        spot = _atm_spot_proxy(quotes)
    selection = select_strikes(
        chain=quotes,
        bias=bias,  # type: ignore[arg-type]
        spot=spot,
        now=latest_ts,
        cfg=cfg,
    )
    if selection is None:
        console.print(
            "[red]Il rule engine NON aprirebbe trade con questa catena[/red] "
            "(no strike compatibile coi gate delta/distance/width/credit-ratio)."
        )
        sys.exit(0)
    short, long_ = selection
    width_usd = (short.strike - long_.strike).copy_abs()
    credit_eth = short.mid - long_.mid
    credit_usd = credit_eth * spot
    ratio = credit_usd / width_usd if width_usd > 0 else Decimal("0")
    ratio_target = cfg.structure.credit_to_width_ratio_min
    table = Table(title=f"Simulazione picker — bias={bias}, spot={spot:.0f}")
    table.add_column("Campo", style="cyan")
    table.add_column("Valore", style="bold")
    table.add_row("Short strike", f"{short.strike} ({short.delta:+.3f}δ)")
    table.add_row("Long strike", f"{long_.strike} ({long_.delta:+.3f}δ)")
    table.add_row("Width", f"{width_usd:.0f} USD")
    table.add_row("Credit", f"{credit_eth:.4f} ETH ≈ {credit_usd:.2f} USD")
    table.add_row(
        "Credit/width ratio",
        f"{ratio:.2%}  (gate ≥ {float(ratio_target):.0%})",
    )
    pass_str = (
        "[green]PASS — entry possibile[/green]"
        if ratio >= ratio_target
        else "[red]FAIL — premio troppo magro[/red]"
    )
    table.add_row("Verdetto gate ratio", pass_str)
    console.print(table)
 def _resolve_spot_at(db_path: Path, *, asset: str, at: datetime) -> Decimal | None:
    """Best-effort lookup dello spot al timestamp ``at`` ± 15 min."""
    conn = connect_state(db_path)
    try:
        rows = Repository().list_market_snapshots(
            conn,
            asset=asset,
            start=at - timedelta(minutes=15),
            end=at + timedelta(minutes=15),
            limit=1,
        )
    finally:
        conn.close()
    if not rows:
        return None
    return rows[0].spot
 def _atm_spot_proxy(quotes: list[Any]) -> Decimal:
    """Stima dello spot prendendo lo strike il cui delta è più vicino a 0.5."""
    quote = min(quotes, key=lambda q: abs(abs(q.delta) - Decimal("0.5")))
    return quote.strike
 def _entrypoint() -> None:
    """Wrapper used by ``cerbero-bite`` console script."""
    try:
@@ -1,652 +0,0 @@
 """Stylized backtest engine over ``market_snapshots`` (§13).
 Two layers, both pure functions:
 1. **Entry-filter simulation** — for each Monday 14:00 UTC tick in the
   recorded snapshots, evaluate which §2 gates would have passed,
   reconstructing :class:`EntryContext` from the snapshot.  This part
   is **rigorous**: it uses the same :func:`validate_entry` the live
   engine uses, so the output is exactly "what the bot would have
   decided".
 2. **P/L estimation per accepted entry** — since ``market_snapshots``
   does NOT record the option chain (we only collect spot, DVOL,
   funding, etc.), credit and exit P/L are estimated via a stylized
   Black-Scholes model: given ``spot``, ``DVOL`` (as IV), and the
   strategy's delta target, we solve for the short strike, the long
   strike at ``width_pct`` distance, and the combo mid-price.  Future
   ticks are then re-priced under the same model to detect the first
   exit trigger from §7.
 The stylized layer is **intentionally approximate**: it captures the
 geometry of the strategy (DVOL band sets credit, ETH path drives
 exit triggers) but not the second-order effects (chain liquidity,
 borrow rates, exchange fees beyond the 0.03% notional cap, dealer
 hedging skew).  Numbers are good for ranking and tuning, not for
 operational P/L promises.
 The engine is deterministic and side-effect-free: it does **not**
 write to SQLite, does not call MCP, does not place orders.  It
 operates entirely on a list of :class:`MarketSnapshotRecord` rows
 the caller has already loaded.
 """
 from __future__ import annotations
 import math
 from dataclasses import dataclass
 from datetime import UTC, datetime, timedelta
 from decimal import Decimal
 from typing import Literal
 from pydantic import BaseModel, ConfigDict
 from cerbero_bite.config.schema import StrategyConfig
 from cerbero_bite.core.entry_validator import EntryContext, validate_entry
 from cerbero_bite.state.models import MarketSnapshotRecord
 __all__ = [
    "BacktestEntry",
    "BacktestExit",
    "BacktestReport",
    "MondayPick",
    "bs_put_delta",
    "bs_put_price",
    "estimate_credit_eth",
    "find_strike_for_delta",
    "monday_picks",
    "normal_cdf",
    "run_backtest",
    "simulate_entry_filters",
    "simulate_position_outcome",
 ]
 _ANNUAL_DAYS = Decimal("365")
 _DEFAULT_RISK_FREE = Decimal("0")
 _NUM_SLIPPAGE_PCT_OF_CREDIT = Decimal("0.03")
 _NUM_FEE_PCT_OF_NOTIONAL = Decimal("0.0003")
 # ---------------------------------------------------------------------------
 # Black-Scholes helpers (stdlib-only)
 # ---------------------------------------------------------------------------
 def normal_cdf(x: float) -> float:
    """Standard normal CDF, no scipy dependency."""
    return 0.5 * (1.0 + math.erf(x / math.sqrt(2.0)))
 def bs_put_price(*, spot: float, strike: float, t_years: float, sigma: float) -> float:
    """European put price under r=0, q=0 Black-Scholes.
    Returns price in spot units (so for an ETH option, dividing by spot
    gives the price in ETH).
    """
    if t_years <= 0 or sigma <= 0 or spot <= 0 or strike <= 0:
        return max(0.0, strike - spot)
    sqrt_t = math.sqrt(t_years)
    d1 = (math.log(spot / strike) + 0.5 * sigma * sigma * t_years) / (sigma * sqrt_t)
    d2 = d1 - sigma * sqrt_t
    return strike * normal_cdf(-d2) - spot * normal_cdf(-d1)
 def bs_put_delta(*, spot: float, strike: float, t_years: float, sigma: float) -> float:
    """Put delta under r=0, q=0 Black-Scholes (negative number for put).
    Returns 0 for expired options.
    """
    if t_years <= 0 or sigma <= 0 or spot <= 0 or strike <= 0:
        return 0.0
    sqrt_t = math.sqrt(t_years)
    d1 = (math.log(spot / strike) + 0.5 * sigma * sigma * t_years) / (sigma * sqrt_t)
    return normal_cdf(d1) - 1.0  # = -N(-d1)
 def find_strike_for_delta(
    *,
    spot: float,
    dvol_pct: float,
    dte_days: int,
    target_delta_abs: float,
 ) -> float:
    """Solve for the put strike whose |delta| matches ``target_delta_abs``.
    Bisection on a monotone-decreasing |delta(strike)| relationship.
    Returns the strike in absolute USD terms.
    """
    sigma = max(0.01, dvol_pct / 100.0)
    t_years = max(1e-6, dte_days / 365.0)
    # Bracket: from 50% of spot (deep OTM, small |delta|) up to spot
    # (ATM, |delta| ≈ 0.5).
    low = max(1.0, spot * 0.30)
    high = spot
    for _ in range(64):
        mid = 0.5 * (low + high)
        delta_abs = abs(bs_put_delta(spot=spot, strike=mid, t_years=t_years, sigma=sigma))
        if delta_abs > target_delta_abs:
            high = mid
        else:
            low = mid
        if abs(high - low) < 1e-3:
            break
    return 0.5 * (low + high)
 def estimate_credit_eth(
    *,
    spot: float,
    dvol_pct: float,
    dte_days: int,
    width_pct: float,
    delta_target_abs: float,
    skew_premium: float = 1.5,
 ) -> tuple[float, float, float]:
    """Estimate credit (ETH), short_strike, long_strike for a bull-put-style
    credit spread under Black-Scholes.
    ``skew_premium`` è il moltiplicatore applicato al credito BS per
    approssimare la **vol smile** dell'ETH options market (le put OTM
    trattano a IV più alta della IV ATM, quindi un BS pulito sottostima
    sistematicamente il premio del venditore di vol).  Il default 1.5
    è una stima conservativa dei dati Deribit storici (smile slope
    tipica 5-10 vol points per 100δ); valori sensati: 1.3 (smile
    blanda) … 1.8 (regime "stress IV"). Va calibrato sui dati reali
    quando avremo abbastanza chain history da farlo.
    Returns ``(credit_eth, short_strike, long_strike)``.  Credit è
    già moltiplicato per ``skew_premium``.
    """
    short_strike = find_strike_for_delta(
        spot=spot, dvol_pct=dvol_pct, dte_days=dte_days,
        target_delta_abs=delta_target_abs,
    )
    width_usd = width_pct * spot
    long_strike = max(1.0, short_strike - width_usd)
    sigma = max(0.01, dvol_pct / 100.0)
    t_years = max(1e-6, dte_days / 365.0)
    short_mid_usd = bs_put_price(
        spot=spot, strike=short_strike, t_years=t_years, sigma=sigma,
    )
    long_mid_usd = bs_put_price(
        spot=spot, strike=long_strike, t_years=t_years, sigma=sigma,
    )
    short_mid_eth = short_mid_usd / spot
    long_mid_eth = long_mid_usd / spot
    credit_eth = (short_mid_eth - long_mid_eth) * skew_premium
    return credit_eth, short_strike, long_strike
 # ---------------------------------------------------------------------------
 # Entry filter simulation — rigorous (uses validate_entry exactly)
 # ---------------------------------------------------------------------------
@dataclass(frozen=True)
 class MondayPick:
    """Indice di un tick "Monday 14:00 UTC" nella time-series."""
    timestamp: datetime
    snapshot: MarketSnapshotRecord
 def monday_picks(
    snapshots: list[MarketSnapshotRecord],
    *,
    weekday: int = 0,  # Monday
    hour_utc: int = 14,
    asset: str = "ETH",
 ) -> list[MondayPick]:
    """Estrae i tick più vicini a "Monday h:00 UTC" per ogni settimana.
    ``snapshots`` deve essere ordinato per timestamp ascending.  Per ogni
    occorrenza di ``weekday + hour_utc`` (es. lun 14:00) presa l'unica
    riga ETH che la copre.  Settimane senza tick a quell'ora vengono
    saltate.
    """
    picks: list[MondayPick] = []
    seen_dates: set[tuple[int, int]] = set()  # (iso_year, iso_week)
    for snap in snapshots:
        if snap.asset.upper() != asset.upper():
            continue
        ts = snap.timestamp.astimezone(UTC)
        if ts.weekday() != weekday or ts.hour != hour_utc:
            continue
        iso_y, iso_w, _ = ts.isocalendar()
        key = (iso_y, iso_w)
        if key in seen_dates:
            continue
        seen_dates.add(key)
        picks.append(MondayPick(timestamp=ts, snapshot=snap))
    return picks
 def _entry_context_from_snapshot(
    snap: MarketSnapshotRecord,
    *,
    capital_usd: Decimal,
    eth_holdings_pct: Decimal = Decimal("0"),
 ) -> EntryContext | None:
    """Costruisce :class:`EntryContext` dal tick storico.
    ``None`` quando la riga non ha i campi minimi (spot, dvol, funding).
    Nel filtro questo si traduce in "skip della settimana" — è la
    stessa logica del live: un tick incompleto è meglio di un'entry
    al buio.
    """
    if snap.dvol is None or snap.funding_perp_annualized is None:
        return None
    return EntryContext(
        capital_usd=capital_usd,
        dvol_now=snap.dvol,
        funding_perp_annualized=snap.funding_perp_annualized,
        eth_holdings_pct_of_portfolio=eth_holdings_pct,
        next_macro_event_in_days=snap.macro_days_to_event,
        has_open_position=False,
        dealer_net_gamma=snap.dealer_net_gamma,
        liquidation_squeeze_risk_high=(
            snap.liquidation_long_risk == "high"
            or snap.liquidation_short_risk == "high"
        ),
    )
@dataclass(frozen=True)
 class EntryFilterResult:
    """Esito del check filtri per una singola Monday pick."""
    pick: MondayPick
    accepted: bool
    reasons: list[str]
    skipped_for_data: bool  # True se il tick non aveva i campi minimi
 def simulate_entry_filters(
    picks: list[MondayPick],
    cfg: StrategyConfig,
    *,
    capital_usd: Decimal,
 ) -> list[EntryFilterResult]:
    """Per ogni Monday pick, valuta validate_entry come farebbe il live.
    Rigoroso: usa esattamente :func:`validate_entry` e :class:`EntryContext`.
    Restituisce la lista degli esiti, una entry per pick.
    """
    results: list[EntryFilterResult] = []
    for pick in picks:
        ctx = _entry_context_from_snapshot(pick.snapshot, capital_usd=capital_usd)
        if ctx is None:
            results.append(
                EntryFilterResult(
                    pick=pick,
                    accepted=False,
                    reasons=["incomplete_snapshot"],
                    skipped_for_data=True,
                )
            )
            continue
        decision = validate_entry(ctx, cfg)
        results.append(
            EntryFilterResult(
                pick=pick,
                accepted=decision.accepted,
                reasons=list(decision.reasons),
                skipped_for_data=False,
            )
        )
    return results
 # ---------------------------------------------------------------------------
 # Position outcome simulation — stylized (Black-Scholes re-pricing)
 # ---------------------------------------------------------------------------
 class BacktestEntry(BaseModel):
    """Trade aperto nel backtest (snapshot al momento dell'entry)."""
    model_config = ConfigDict(frozen=True)
    timestamp: datetime
    spread_type: Literal["bull_put"]  # MVP: solo bull_put nel backtest
    spot_at_entry: Decimal
    dvol_at_entry: Decimal
    short_strike: Decimal
    long_strike: Decimal
    expiry: datetime
    credit_received_eth: Decimal
    credit_received_usd: Decimal
    n_contracts: int
 class BacktestExit(BaseModel):
    """Esito di un trade nel backtest."""
    model_config = ConfigDict(frozen=True)
    timestamp: datetime
    action: Literal[
        "CLOSE_PROFIT", "CLOSE_STOP", "CLOSE_VOL", "CLOSE_TIME",
        "CLOSE_DELTA", "CLOSE_AVERSE", "EXPIRED",
    ]
    reason: str
    spot_at_exit: Decimal
    dvol_at_exit: Decimal
    debit_paid_eth: Decimal
    pnl_eth: Decimal
    pnl_usd: Decimal
 def _combo_mid_eth(
    *, spot: float, dvol_pct: float, dte_days: int,
    short_strike: float, long_strike: float,
    skew_premium: float = 1.5,
 ) -> float:
    """Re-prezza il combo bull-put usando BS sul nuovo spot/dvol/dte."""
    sigma = max(0.01, dvol_pct / 100.0)
    t_years = max(1e-6, dte_days / 365.0)
    short_mid_usd = bs_put_price(
        spot=spot, strike=short_strike, t_years=t_years, sigma=sigma,
    )
    long_mid_usd = bs_put_price(
        spot=spot, strike=long_strike, t_years=t_years, sigma=sigma,
    )
    return (short_mid_usd - long_mid_usd) / spot * skew_premium
 def simulate_position_outcome(
    entry: BacktestEntry,
    future_snapshots: list[MarketSnapshotRecord],
    cfg: StrategyConfig,
 ) -> BacktestExit:
    """Re-prezza il combo a ogni tick futuro fino al primo exit trigger.
    Triggers in ordine §7:
      1. profit_take (debit ≤ 0.5×credit)
      2. stop_loss (debit ≥ 2.5×credit)
      3. vol_stop (DVOL salita di ≥10 pt rispetto entry)
      4. time_stop (DTE ≤ 7 e debit > 0.7×credit)
      5. expiry (uscita per scadenza, P/L = credit − intrinsic)
    """
    ec = cfg.exit
    credit = float(entry.credit_received_eth)
    short = float(entry.short_strike)
    long_ = float(entry.long_strike)
    profit_thresh = float(ec.profit_take_pct_of_credit) * credit
    stop_thresh = float(ec.stop_loss_mark_x_credit) * credit
    skip_time_thresh = float(ec.time_stop_skip_if_close_to_profit_pct) * credit
    for snap in future_snapshots:
        if snap.timestamp <= entry.timestamp:
            continue
        if snap.timestamp >= entry.expiry:
            break
        if snap.dvol is None or snap.spot is None:
            continue
        spot_now = float(snap.spot)
        dvol_now = float(snap.dvol)
        dte = max(0, (entry.expiry - snap.timestamp).days)
        debit = _combo_mid_eth(
            spot=spot_now, dvol_pct=dvol_now, dte_days=dte,
            short_strike=short, long_strike=long_,
        )
        if debit <= profit_thresh:
            return _exit(
                snap, entry, debit,
                action="CLOSE_PROFIT",
                reason=f"debit {debit:.4f} ≤ {profit_thresh:.4f}",
            )
        if debit >= stop_thresh:
            return _exit(
                snap, entry, debit,
                action="CLOSE_STOP",
                reason=f"debit {debit:.4f} ≥ {stop_thresh:.4f}",
            )
        if dvol_now >= float(entry.dvol_at_entry) + float(ec.vol_stop_dvol_increase):
            return _exit(
                snap, entry, debit,
                action="CLOSE_VOL",
                reason=f"DVOL {dvol_now:.1f} ≥ entry+{ec.vol_stop_dvol_increase}",
            )
        if dte <= ec.time_stop_dte_remaining and debit > skip_time_thresh:
            return _exit(
                snap, entry, debit,
                action="CLOSE_TIME",
                reason=f"DTE {dte} ≤ {ec.time_stop_dte_remaining}",
            )
    # Tick passati senza trigger: scadenza naturale.
    last = future_snapshots[-1] if future_snapshots else None
    intrinsic = max(0.0, short - float(last.spot if last and last.spot else 0))
    intrinsic_capped = min(intrinsic, short - long_)
    debit_at_expiry_eth = (
        intrinsic_capped / float(last.spot)
        if last is not None and last.spot is not None and float(last.spot) > 0
        else 0.0
    )
    return _exit(
        last or _synthetic_expiry_snapshot(entry),
        entry,
        debit_at_expiry_eth,
        action="EXPIRED",
        reason="held to expiry",
    )
 def _synthetic_expiry_snapshot(entry: BacktestEntry) -> MarketSnapshotRecord:
    return MarketSnapshotRecord(
        timestamp=entry.expiry,
        asset="ETH",
        spot=entry.spot_at_entry,
        dvol=entry.dvol_at_entry,
        fetch_ok=False,
    )
 def _exit(
    snap: MarketSnapshotRecord,
    entry: BacktestEntry,
    debit_eth: float,
    *,
    action: str,
    reason: str,
 ) -> BacktestExit:
    pnl_eth = float(entry.credit_received_eth) - debit_eth
    spot = float(snap.spot) if snap.spot is not None else float(entry.spot_at_entry)
    dvol = float(snap.dvol) if snap.dvol is not None else float(entry.dvol_at_entry)
    return BacktestExit(
        timestamp=snap.timestamp,
        action=action,  # type: ignore[arg-type]
        reason=reason,
        spot_at_exit=Decimal(str(spot)),
        dvol_at_exit=Decimal(str(dvol)),
        debit_paid_eth=Decimal(str(debit_eth)),
        pnl_eth=Decimal(str(pnl_eth)),
        pnl_usd=Decimal(str(pnl_eth * spot * entry.n_contracts)),
    )
 # ---------------------------------------------------------------------------
 # Full pipeline
 # ---------------------------------------------------------------------------
@dataclass(frozen=True)
 class CompletedTrade:
    entry: BacktestEntry
    exit: BacktestExit
 class BacktestReport(BaseModel):
    """Aggregato del backtest. Tutti i numeri sono **stime**."""
    model_config = ConfigDict(frozen=True)
    n_picks: int
    n_accepted: int
    n_skipped_data: int
    n_completed: int
    n_winners: int
    win_rate: Decimal
    cumulative_pnl_usd: Decimal
    cumulative_pnl_pct_of_capital: Decimal
    max_drawdown_usd: Decimal
    max_drawdown_pct: Decimal
    sharpe_annualized: Decimal | None
    skip_reasons: dict[str, int]
    trades: list[CompletedTrade]
 def _build_entry_from_pick(
    pick: MondayPick,
    cfg: StrategyConfig,
    *,
    capital_usd: Decimal,
    eur_to_usd: Decimal,
 ) -> BacktestEntry | None:
    snap = pick.snapshot
    if snap.spot is None or snap.dvol is None:
        return None
    spot = float(snap.spot)
    dvol = float(snap.dvol)
    width_pct = float(cfg.structure.spread_width.target_pct_of_spot)
    delta_target = float(cfg.structure.short_strike.delta_target)
    dte = cfg.structure.dte_target
    credit_eth, short_strike, long_strike = estimate_credit_eth(
        spot=spot, dvol_pct=dvol, dte_days=dte,
        width_pct=width_pct, delta_target_abs=delta_target,
    )
    width_usd = float(cfg.structure.spread_width.target_pct_of_spot) * spot
    credit_usd = credit_eth * spot
    if width_usd <= 0 or credit_usd / width_usd < float(
        cfg.structure.credit_to_width_ratio_min
    ):
        return None  # ratio gate fallisce → no entry
    cap_pertrade_usd = float(cfg.sizing.cap_per_trade_eur) * float(eur_to_usd)
    risk_target = min(float(cfg.sizing.kelly_fraction) * float(capital_usd), cap_pertrade_usd)
    n_contracts = max(0, min(int(risk_target // width_usd), cfg.sizing.max_contracts_per_trade))
    if n_contracts == 0:
        return None
    expiry = pick.timestamp + timedelta(days=dte)
    return BacktestEntry(
        timestamp=pick.timestamp,
        spread_type="bull_put",
        spot_at_entry=Decimal(str(spot)),
        dvol_at_entry=Decimal(str(dvol)),
        short_strike=Decimal(str(round(short_strike, 2))),
        long_strike=Decimal(str(round(long_strike, 2))),
        expiry=expiry,
        credit_received_eth=Decimal(str(credit_eth)),
        credit_received_usd=Decimal(str(credit_usd * n_contracts)),
        n_contracts=n_contracts,
    )
 def _max_drawdown_usd(equity: list[Decimal]) -> tuple[Decimal, Decimal]:
    """Return ``(max_dd_usd, max_dd_pct_of_peak)`` over an equity curve."""
    if not equity:
        return Decimal("0"), Decimal("0")
    peak = equity[0]
    max_dd_usd = Decimal("0")
    max_dd_pct = Decimal("0")
    for v in equity:
        if v > peak:
            peak = v
        dd = peak - v
        if dd > max_dd_usd:
            max_dd_usd = dd
        if peak > 0 and (dd / peak) > max_dd_pct:
            max_dd_pct = dd / peak
    return max_dd_usd, max_dd_pct
 def _sharpe_annualized(pnls_usd: list[Decimal], capital_usd: Decimal) -> Decimal | None:
    """Annualized Sharpe approximation: 52 trade/anno (settimanali).
    Restituisce ``None`` se ci sono <5 trade o stdev = 0.
    """
    if len(pnls_usd) < 5 or capital_usd <= 0:
        return None
    rets = [float(p / capital_usd) for p in pnls_usd]
    mean = sum(rets) / len(rets)
    var = sum((r - mean) ** 2 for r in rets) / max(1, (len(rets) - 1))
    std = math.sqrt(var)
    if std == 0:
        return None
    sharpe = mean / std * math.sqrt(52)
    return Decimal(str(round(sharpe, 3)))
 def run_backtest(
    snapshots: list[MarketSnapshotRecord],
    cfg: StrategyConfig,
    *,
    capital_usd: Decimal,
    eur_to_usd: Decimal = Decimal("1.075"),
    asset: str = "ETH",
 ) -> BacktestReport:
    """Esegue il backtest end-to-end sui ``snapshots`` ETH ordinati per ts."""
    snapshots = sorted(snapshots, key=lambda s: s.timestamp)
    eth_snapshots = [s for s in snapshots if s.asset.upper() == asset.upper()]
    picks = monday_picks(eth_snapshots, asset=asset)
    filter_results = simulate_entry_filters(picks, cfg, capital_usd=capital_usd)
    # Tally skip reasons
    skip_reasons: dict[str, int] = {}
    for r in filter_results:
        if r.accepted:
            continue
        for reason in r.reasons:
            skip_reasons[reason] = skip_reasons.get(reason, 0) + 1
    trades: list[CompletedTrade] = []
    for r in filter_results:
        if not r.accepted:
            continue
        entry = _build_entry_from_pick(
            r.pick, cfg, capital_usd=capital_usd, eur_to_usd=eur_to_usd,
        )
        if entry is None:
            skip_reasons["sizing_or_ratio"] = skip_reasons.get("sizing_or_ratio", 0) + 1
            continue
        future = [s for s in eth_snapshots if s.timestamp > r.pick.timestamp]
        exit_ = simulate_position_outcome(entry, future, cfg)
        trades.append(CompletedTrade(entry=entry, exit=exit_))
    pnls = [t.exit.pnl_usd for t in trades]
    cumulative = sum(pnls, start=Decimal("0"))
    n_winners = sum(1 for p in pnls if p > 0)
    win_rate = (
        Decimal(n_winners) / Decimal(len(pnls))
        if pnls
        else Decimal("0")
    )
    # Equity curve in USD assoluti
    equity = [capital_usd]
    for p in pnls:
        equity.append(equity[-1] + p)
    max_dd_usd, max_dd_pct = _max_drawdown_usd(equity)
    return BacktestReport(
        n_picks=len(picks),
        n_accepted=sum(1 for r in filter_results if r.accepted),
        n_skipped_data=sum(1 for r in filter_results if r.skipped_for_data),
        n_completed=len(trades),
        n_winners=n_winners,
        win_rate=win_rate,
        cumulative_pnl_usd=cumulative,
        cumulative_pnl_pct_of_capital=(
            cumulative / capital_usd if capital_usd > 0 else Decimal("0")
        ),
        max_drawdown_usd=max_dd_usd,
        max_drawdown_pct=max_dd_pct,
        sharpe_annualized=_sharpe_annualized(pnls, capital_usd),
        skip_reasons=skip_reasons,
        trades=trades,
    )
@@ -0,0 +1,185 @@
 """Periodic option-chain snapshot collector (§13).
 Fetches the Deribit option chain for every strike entro la finestra
 DTE configurata, prima del trigger entry settimanale (cron
 ``55 13 * * MON`` di default). Persiste un quote per ogni strumento
 in ``option_chain_snapshots`` con un timestamp condiviso, che diventa
 il dato di base per:
 * il backtest non-stilizzato (vedi ``core/backtest.py``),
 * la calibrazione empirica dello skew premium e del credit/width
  ratio sui regimi reali,
 * l'analisi ex-post degli strike picker.
 Il collector è **best-effort**: se ``get_tickers`` fallisce per un
 batch, gli altri batch passano comunque; se manca completamente la
 chain, il job ritorna 0 senza alzare eccezioni e logga il problema.
 Non chiama l'order book per ogni strike (sarebbe troppo costoso) —
 ``book_depth_top3`` resta NULL nel quote, il liquidity gate del live
 lo legge al volo solo per gli strike che gli interessano.
 """
 from __future__ import annotations
 import asyncio
 import logging
 from datetime import UTC, datetime, timedelta
 from decimal import Decimal
 from typing import TYPE_CHECKING, Any
 from cerbero_bite.state import connect, transaction
 from cerbero_bite.state.models import OptionChainQuoteRecord
 if TYPE_CHECKING:
    from cerbero_bite.runtime.dependencies import RuntimeContext
 __all__ = ["DEFAULT_BATCH_SIZE", "collect_option_chain_snapshot"]
 _log = logging.getLogger("cerbero_bite.runtime.option_chain_snapshot")
 DEFAULT_BATCH_SIZE = 20  # Deribit get_ticker_batch limit
 def _to_decimal_or_none(value: Any) -> Decimal | None:
    if value is None:
        return None
    try:
        return Decimal(str(value))
    except Exception:
        return None
 async def _fetch_tickers_in_batches(
    ctx: RuntimeContext, names: list[str], *, batch_size: int = DEFAULT_BATCH_SIZE
 ) -> dict[str, dict[str, Any]]:
    """Best-effort fetch dei ticker per tutti i nomi richiesti."""
    out: dict[str, dict[str, Any]] = {}
    for i in range(0, len(names), batch_size):
        batch = names[i : i + batch_size]
        try:
            tickers = await ctx.deribit.get_tickers(batch)
        except Exception as exc:
            _log.warning(
                "get_tickers failed for batch starting %s: %s",
                batch[0] if batch else "<empty>", exc,
            )
            continue
        for t in tickers:
            name = t.get("instrument_name") or t.get("instrument")
            if isinstance(name, str):
                out[name] = t
    return out
 async def collect_option_chain_snapshot(
    ctx: RuntimeContext,
    *,
    asset: str = "ETH",
    now: datetime | None = None,
    batch_size: int = DEFAULT_BATCH_SIZE,
 ) -> int:
    """Collect + persist a single chain snapshot for ``asset``. Returns
    the number of quotes persisted (0 on best-effort failure).
    Filtra le scadenze nella finestra ``[dte_min, dte_max]`` di
    ``cfg.structure`` per non sprecare richieste su scadenze che il
    rule engine non userebbe mai.
    """
    when = (now or datetime.now(UTC)).astimezone(UTC)
    cfg = ctx.cfg
    expiry_from = when + timedelta(days=cfg.structure.dte_min)
    expiry_to = when + timedelta(days=cfg.structure.dte_max)
    try:
        chain = await ctx.deribit.options_chain(
            currency=asset.upper(),
            expiry_from=expiry_from,
            expiry_to=expiry_to,
            min_open_interest=int(cfg.liquidity.open_interest_min),
        )
    except Exception:
        _log.exception("option chain fetch failed")
        return 0
    if not chain:
        _log.info("option chain empty for %s in window", asset)
        return 0
    names = [meta.name for meta in chain]
    tickers = await _fetch_tickers_in_batches(ctx, names, batch_size=batch_size)
    quotes: list[OptionChainQuoteRecord] = []
    for meta in chain:
        ticker = tickers.get(meta.name)
        if ticker is None:
            # Lasciamo comunque la riga senza quote: utile sapere
            # che lo strumento esisteva.
            quotes.append(
                OptionChainQuoteRecord(
                    timestamp=when,
                    asset=asset.upper(),
                    instrument_name=meta.name,
                    strike=meta.strike,
                    expiry=meta.expiry,
                    option_type=meta.option_type,
                    open_interest=int(meta.open_interest)
                    if meta.open_interest is not None
                    else None,
                )
            )
            continue
        greeks = ticker.get("greeks") or {}
        quotes.append(
            OptionChainQuoteRecord(
                timestamp=when,
                asset=asset.upper(),
                instrument_name=meta.name,
                strike=meta.strike,
                expiry=meta.expiry,
                option_type=meta.option_type,
                bid=_to_decimal_or_none(ticker.get("bid")),
                ask=_to_decimal_or_none(ticker.get("ask")),
                mid=_to_decimal_or_none(ticker.get("mark_price")),
                iv=_to_decimal_or_none(ticker.get("mark_iv")),
                delta=_to_decimal_or_none(greeks.get("delta")),
                gamma=_to_decimal_or_none(greeks.get("gamma")),
                theta=_to_decimal_or_none(greeks.get("theta")),
                vega=_to_decimal_or_none(greeks.get("vega")),
                open_interest=int(meta.open_interest)
                if meta.open_interest is not None
                else None,
                volume_24h=(
                    int(ticker["volume_24h"])
                    if ticker.get("volume_24h") is not None
                    else None
                ),
                # book_depth_top3: NULL — non lo prendiamo per ogni
                # strike per non saturare l'API. Il liquidity gate
                # del live lo chiede on-the-fly per gli strike
                # candidati al picker.
            )
        )
    persisted = 0
    try:
        conn = connect(ctx.db_path)
        try:
            with transaction(conn):
                persisted = ctx.repository.record_option_chain_snapshot(
                    conn, quotes
                )
        finally:
            conn.close()
    except Exception:
        _log.exception("persist option chain snapshot failed")
        return 0
    _log.info("option_chain_snapshot persisted %d quote(s)", persisted)
    return persisted
 # Avoid unused import warning for asyncio in lint when only used as type
 _ = asyncio
@@ -34,6 +34,9 @@ from cerbero_bite.runtime.market_snapshot_cycle import (
    DEFAULT_ASSETS,
    collect_market_snapshot,
 )
 from cerbero_bite.runtime.option_chain_snapshot_cycle import (
    collect_option_chain_snapshot,
 )
 from cerbero_bite.runtime.monitor_cycle import MonitorCycleResult, run_monitor_cycle
 from cerbero_bite.runtime.recovery import recover_state
 from cerbero_bite.runtime.scheduler import JobSpec, build_scheduler
@@ -53,6 +56,7 @@ _CRON_HEALTH = "*/5 * * * *"
 _CRON_BACKUP = "0 * * * *"
 _CRON_MANUAL_ACTIONS = "*/1 * * * *"
 _CRON_MARKET_SNAPSHOT = "*/15 * * * *"
 _CRON_OPTION_CHAIN_SNAPSHOT = "55 13 * * MON"  # 5 min prima del trigger entry
 _BACKUP_RETENTION_DAYS = 30
@@ -217,6 +221,8 @@ class Orchestrator:
        manual_actions_cron: str = _CRON_MANUAL_ACTIONS,
        market_snapshot_cron: str = _CRON_MARKET_SNAPSHOT,
        market_snapshot_assets: tuple[str, ...] = DEFAULT_ASSETS,
        option_chain_cron: str = _CRON_OPTION_CHAIN_SNAPSHOT,
        option_chain_asset: str = "ETH",
        backup_dir: Path | None = None,
        backup_retention_days: int = _BACKUP_RETENTION_DAYS,
    ) -> AsyncIOScheduler:
@@ -282,6 +288,14 @@ class Orchestrator:
            await _safe("market_snapshot", _do)
        async def _option_chain_snapshot() -> None:
            async def _do() -> None:
                await collect_option_chain_snapshot(
                    self._ctx, asset=option_chain_asset
                )
            await _safe("option_chain_snapshot", _do)
        jobs: list[JobSpec] = [
            JobSpec(name="health", cron=health_cron, coro_factory=_health),
            JobSpec(name="backup", cron=backup_cron, coro_factory=_backup),
@@ -309,6 +323,13 @@ class Orchestrator:
                    coro_factory=_market_snapshot,
                )
            )
            jobs.append(
                JobSpec(
                    name="option_chain_snapshot",
                    cron=option_chain_cron,
                    coro_factory=_option_chain_snapshot,
                )
            )
        else:
            _log.warning(
                "data analysis disabled (CERBERO_BITE_ENABLE_DATA_ANALYSIS="
@@ -0,0 +1,42 @@
 -- 0004_option_chain_snapshots.sql — catena opzioni storica
 --
 -- Snapshot della option chain Deribit, prelevata settimanalmente (cron
 -- 55 13 * * MON, appena prima del trigger entry alle 14:00 UTC) per
 -- ogni strike entro ±30% dallo spot e per ogni scadenza in finestra
 -- 14-28 DTE. Dato di base per il backtest non-stilizzato e per
 -- calibrare empiricamente lo skew premium del modello BS.
 --
 -- Granularità: una riga per (snapshot_ts, instrument). Lo
 -- snapshot_ts è il timestamp del cron tick — TUTTI i quote raccolti
 -- in quello stesso tick condividono il timestamp, così filtrare per
 -- "lo snapshot del 2026-05-04 alle 13:55" è una semplice
 -- WHERE timestamp = X.
 CREATE TABLE option_chain_snapshots (
    timestamp        TEXT    NOT NULL,
    asset            TEXT    NOT NULL,
    instrument_name  TEXT    NOT NULL,
    strike           TEXT    NOT NULL,
    expiry           TEXT    NOT NULL,
    option_type      TEXT    NOT NULL CHECK (option_type IN ('C','P')),
    bid              TEXT,
    ask              TEXT,
    mid              TEXT,
    iv               TEXT,
    delta            TEXT,
    gamma            TEXT,
    theta            TEXT,
    vega             TEXT,
    open_interest    INTEGER,
    volume_24h       INTEGER,
    book_depth_top3  INTEGER,
    PRIMARY KEY (timestamp, instrument_name)
 ) WITHOUT ROWID;
 CREATE INDEX idx_option_chain_asset_ts
    ON option_chain_snapshots(asset, timestamp DESC);
 CREATE INDEX idx_option_chain_expiry
    ON option_chain_snapshots(asset, expiry);
 PRAGMA user_version = 5;
@@ -22,6 +22,7 @@ __all__ = [
    "InstructionRecord",
    "ManualAction",
    "MarketSnapshotRecord",
    "OptionChainQuoteRecord",
    "PositionRecord",
    "PositionStatus",
    "SystemStateRecord",
@@ -148,6 +149,36 @@ class MarketSnapshotRecord(BaseModel):
    fetch_errors_json: str | None = None
 class OptionChainQuoteRecord(BaseModel):
    """Row of the ``option_chain_snapshots`` table.
    One row per (snapshot_ts, instrument) — the same ``timestamp`` is
    shared by every quote prelevato nello stesso tick del cron.  Tutti
    i campi numerici sono opzionali perché il collector è
    best-effort: un ticker mancante non invalida il resto della chain.
    """
    model_config = ConfigDict(extra="forbid")
    timestamp: datetime
    asset: str
    instrument_name: str
    strike: Decimal
    expiry: datetime
    option_type: Literal["C", "P"]
    bid: Decimal | None = None
    ask: Decimal | None = None
    mid: Decimal | None = None
    iv: Decimal | None = None
    delta: Decimal | None = None
    gamma: Decimal | None = None
    theta: Decimal | None = None
    vega: Decimal | None = None
    open_interest: int | None = None
    volume_24h: int | None = None
    book_depth_top3: int | None = None
 class ManualAction(BaseModel):
    """Row of the ``manual_actions`` table."""
@@ -24,6 +24,7 @@ from cerbero_bite.state.models import (
    InstructionRecord,
    ManualAction,
    MarketSnapshotRecord,
    OptionChainQuoteRecord,
    PositionRecord,
    PositionStatus,
    SystemStateRecord,
@@ -407,6 +408,103 @@ class Repository:
        ).fetchall()
        return [_row_to_market_snapshot(r) for r in rows]
    # ------------------------------------------------------------------
    # option_chain_snapshots
    # ------------------------------------------------------------------
    def record_option_chain_snapshot(
        self,
        conn: sqlite3.Connection,
        quotes: list[OptionChainQuoteRecord],
    ) -> int:
        """Bulk-insert dei quote di un singolo tick. Tutti i quote
        condividono lo stesso ``timestamp``. Idempotente per
        (timestamp, instrument_name)."""
        if not quotes:
            return 0
        rows = [
            (
                _enc_dt(q.timestamp),
                q.asset,
                q.instrument_name,
                _enc_dec(q.strike),
                _enc_dt(q.expiry),
                q.option_type,
                _enc_dec(q.bid),
                _enc_dec(q.ask),
                _enc_dec(q.mid),
                _enc_dec(q.iv),
                _enc_dec(q.delta),
                _enc_dec(q.gamma),
                _enc_dec(q.theta),
                _enc_dec(q.vega),
                q.open_interest,
                q.volume_24h,
                q.book_depth_top3,
            )
            for q in quotes
        ]
        conn.executemany(
            "INSERT OR REPLACE INTO option_chain_snapshots("
            "timestamp, asset, instrument_name, strike, expiry, option_type, "
            "bid, ask, mid, iv, delta, gamma, theta, vega, "
            "open_interest, volume_24h, book_depth_top3) "
            "VALUES (?,?,?,?,?,?,?,?,?,?,?,?,?,?,?,?,?)",
            rows,
        )
        return len(rows)
    def list_option_chain_snapshots(
        self,
        conn: sqlite3.Connection,
        *,
        asset: str,
        start: datetime | None = None,
        end: datetime | None = None,
        expiry_from: datetime | None = None,
        expiry_to: datetime | None = None,
        limit: int = 50000,
    ) -> list[OptionChainQuoteRecord]:
        clauses: list[str] = ["asset = ?"]
        params: list[Any] = [asset]
        if start is not None:
            clauses.append("timestamp >= ?")
            params.append(_enc_dt(start))
        if end is not None:
            clauses.append("timestamp <= ?")
            params.append(_enc_dt(end))
        if expiry_from is not None:
            clauses.append("expiry >= ?")
            params.append(_enc_dt(expiry_from))
        if expiry_to is not None:
            clauses.append("expiry <= ?")
            params.append(_enc_dt(expiry_to))
        params.append(int(limit))
        rows = conn.execute(
            f"SELECT * FROM option_chain_snapshots "
            f"WHERE {' AND '.join(clauses)} "
            f"ORDER BY timestamp DESC, instrument_name ASC LIMIT ?",
            params,
        ).fetchall()
        return [_row_to_option_chain_quote(r) for r in rows]
    def latest_option_chain_timestamp(
        self,
        conn: sqlite3.Connection,
        *,
        asset: str,
    ) -> datetime | None:
        """Timestamp dell'ultimo snapshot raccolto per ``asset``,
        utile per stimare la freschezza del dato dalla GUI."""
        row = conn.execute(
            "SELECT timestamp FROM option_chain_snapshots "
            "WHERE asset = ? ORDER BY timestamp DESC LIMIT 1",
            (asset,),
        ).fetchone()
        if row is None:
            return None
        return _dec_dt(row["timestamp"])
    # ------------------------------------------------------------------
    # manual_actions
    # ------------------------------------------------------------------
@@ -645,6 +743,38 @@ def _row_to_market_snapshot(row: sqlite3.Row) -> MarketSnapshotRecord:
    )
 def _row_to_option_chain_quote(row: sqlite3.Row) -> OptionChainQuoteRecord:
    return OptionChainQuoteRecord(
        timestamp=_dec_dt_required(row["timestamp"]),
        asset=row["asset"],
        instrument_name=row["instrument_name"],
        strike=_dec_dec_required(row["strike"]),
        expiry=_dec_dt_required(row["expiry"]),
        option_type=row["option_type"],
        bid=_dec_dec(row["bid"]),
        ask=_dec_dec(row["ask"]),
        mid=_dec_dec(row["mid"]),
        iv=_dec_dec(row["iv"]),
        delta=_dec_dec(row["delta"]),
        gamma=_dec_dec(row["gamma"]),
        theta=_dec_dec(row["theta"]),
        vega=_dec_dec(row["vega"]),
        open_interest=(
            int(row["open_interest"])
            if row["open_interest"] is not None
            else None
        ),
        volume_24h=(
            int(row["volume_24h"]) if row["volume_24h"] is not None else None
        ),
        book_depth_top3=(
            int(row["book_depth_top3"])
            if row["book_depth_top3"] is not None
            else None
        ),
    )
 def _dec_dec_required(value: Any) -> Decimal:
    out = _dec_dec(value)
    if out is None:
@@ -129,6 +129,7 @@ def test_install_scheduler_registers_canonical_jobs(tmp_path: Path) -> None:
        "backup",
        "manual_actions",
        "market_snapshot",
        "option_chain_snapshot",
    }
@@ -1,259 +0,0 @@
 """TDD per :mod:`cerbero_bite.core.backtest`."""
 from __future__ import annotations
 from datetime import UTC, datetime, timedelta
 from decimal import Decimal
 import pytest
 from cerbero_bite.config import StrategyConfig, golden_config
 from cerbero_bite.core.backtest import (
    bs_put_delta,
    bs_put_price,
    estimate_credit_eth,
    find_strike_for_delta,
    monday_picks,
    normal_cdf,
    run_backtest,
    simulate_entry_filters,
 )
 from cerbero_bite.state.models import MarketSnapshotRecord
 # ---------------------------------------------------------------------------
 # Black-Scholes helpers
 # ---------------------------------------------------------------------------
 def test_normal_cdf_known_values() -> None:
    assert normal_cdf(0.0) == pytest.approx(0.5, abs=1e-6)
    assert normal_cdf(1.0) == pytest.approx(0.8413, abs=1e-3)
    assert normal_cdf(-1.0) == pytest.approx(0.1587, abs=1e-3)
    assert normal_cdf(2.0) == pytest.approx(0.9772, abs=1e-3)
 def test_bs_put_price_atm_positive_and_less_than_strike() -> None:
    p = bs_put_price(spot=3000, strike=3000, t_years=18 / 365, sigma=0.50)
    assert p > 0
    assert p < 3000  # cap
 def test_bs_put_price_far_otm_close_to_zero() -> None:
    p = bs_put_price(spot=3000, strike=1500, t_years=18 / 365, sigma=0.50)
    assert 0 <= p < 5  # essentially zero
 def test_bs_put_delta_atm_around_minus_half() -> None:
    d = bs_put_delta(spot=3000, strike=3000, t_years=18 / 365, sigma=0.50)
    assert d == pytest.approx(-0.475, abs=0.05)
 def test_bs_put_delta_far_otm_close_to_zero() -> None:
    d = bs_put_delta(spot=3000, strike=1500, t_years=18 / 365, sigma=0.50)
    assert -0.05 < d <= 0
 def test_find_strike_for_delta_monotone() -> None:
    spot = 3000.0
    dvol = 50.0
    dte = 18
    s_010 = find_strike_for_delta(
        spot=spot, dvol_pct=dvol, dte_days=dte, target_delta_abs=0.10,
    )
    s_020 = find_strike_for_delta(
        spot=spot, dvol_pct=dvol, dte_days=dte, target_delta_abs=0.20,
    )
    # |Δ|=0.20 (più ITM) ⇒ strike più alto di |Δ|=0.10 (più OTM).
    assert s_020 > s_010
    # Verifica che il delta corrisponda a target ± tolleranza.
    achieved = abs(
        bs_put_delta(
            spot=spot, strike=s_020, t_years=dte / 365, sigma=dvol / 100,
        )
    )
    assert achieved == pytest.approx(0.20, abs=0.02)
 def test_estimate_credit_returns_positive_credit_in_normal_regime() -> None:
    credit_eth, short_k, long_k = estimate_credit_eth(
        spot=3000, dvol_pct=50, dte_days=18, width_pct=0.04, delta_target_abs=0.12,
    )
    # Sanity: credit > 0, short_k < spot, long_k = short_k - 4%×spot
    assert credit_eth > 0
    assert short_k < 3000
    assert long_k < short_k
    assert short_k - long_k == pytest.approx(0.04 * 3000, abs=1.0)
 # ---------------------------------------------------------------------------
 # Monday picks + entry filter simulation
 # ---------------------------------------------------------------------------
 def _snap(
    *, ts: datetime,
    spot: float = 3000,
    dvol: float = 50,
    funding: float = 0.0,
    macro_d: int | None = None,
    asset: str = "ETH",
 ) -> MarketSnapshotRecord:
    return MarketSnapshotRecord(
        timestamp=ts,
        asset=asset,
        spot=Decimal(str(spot)),
        dvol=Decimal(str(dvol)),
        funding_perp_annualized=Decimal(str(funding)),
        funding_cross_annualized=Decimal("0"),
        dealer_net_gamma=Decimal("100"),
        liquidation_long_risk="low",
        liquidation_short_risk="low",
        macro_days_to_event=macro_d,
        fetch_ok=True,
    )
 def test_monday_picks_extracts_one_per_iso_week() -> None:
    monday_2026_05_04 = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    monday_2026_05_11 = datetime(2026, 5, 11, 14, 0, tzinfo=UTC)
    snapshots = [
        _snap(ts=monday_2026_05_04),
        _snap(ts=monday_2026_05_04 + timedelta(minutes=15)),  # not picked
        _snap(ts=monday_2026_05_11),
    ]
    picks = monday_picks(snapshots)
    assert len(picks) == 2
    assert picks[0].timestamp == monday_2026_05_04
    assert picks[1].timestamp == monday_2026_05_11
 def test_monday_picks_skips_other_days_and_hours() -> None:
    snapshots = [
        _snap(ts=datetime(2026, 5, 4, 13, 0, tzinfo=UTC)),  # Monday 13:00
        _snap(ts=datetime(2026, 5, 5, 14, 0, tzinfo=UTC)),  # Tuesday 14:00
    ]
    assert monday_picks(snapshots) == []
 def test_monday_picks_filters_by_asset() -> None:
    monday = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    snapshots = [
        _snap(ts=monday, asset="BTC"),
        _snap(ts=monday, asset="ETH"),
    ]
    picks = monday_picks(snapshots, asset="ETH")
    assert len(picks) == 1
    assert picks[0].snapshot.asset == "ETH"
 def test_simulate_entry_filters_accepts_clean_snapshot(
 ) -> None:
    cfg: StrategyConfig = golden_config()
    monday = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    snap = _snap(ts=monday, dvol=50, funding=0.10)
    picks = [
        type("MP", (), {"timestamp": monday, "snapshot": snap})()  # type: ignore[arg-type]
    ]
    # Hack: build via real dataclass
    from cerbero_bite.core.backtest import MondayPick
    picks = [MondayPick(timestamp=monday, snapshot=snap)]
    results = simulate_entry_filters(picks, cfg, capital_usd=Decimal("1500"))
    assert len(results) == 1
    assert results[0].accepted is True
 def test_simulate_entry_filters_rejects_dvol_out_of_band() -> None:
    cfg = golden_config()
    monday = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    snap = _snap(ts=monday, dvol=20, funding=0.10)  # below 35
    from cerbero_bite.core.backtest import MondayPick
    picks = [MondayPick(timestamp=monday, snapshot=snap)]
    results = simulate_entry_filters(picks, cfg, capital_usd=Decimal("1500"))
    assert results[0].accepted is False
    assert any("dvol" in r.lower() for r in results[0].reasons)
 def test_simulate_entry_filters_skips_incomplete_snapshot() -> None:
    cfg = golden_config()
    monday = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    incomplete = MarketSnapshotRecord(
        timestamp=monday, asset="ETH", spot=Decimal("3000"),
        # dvol=None ⇒ skipped
        fetch_ok=False,
    )
    from cerbero_bite.core.backtest import MondayPick
    picks = [MondayPick(timestamp=monday, snapshot=incomplete)]
    results = simulate_entry_filters(picks, cfg, capital_usd=Decimal("1500"))
    assert results[0].accepted is False
    assert results[0].skipped_for_data is True
 # ---------------------------------------------------------------------------
 # Full pipeline (sintetico)
 # ---------------------------------------------------------------------------
 def _synthetic_year_of_snapshots(
    *,
    n_weeks: int = 8,
    spot: float = 3000,
    dvol: float = 60,  # con skew_premium 1.5 ⇒ credit/width ≈ 35% (sopra soglia 30%)
    funding: float = 0.10,
 ) -> list[MarketSnapshotRecord]:
    """Genera N settimane di snapshot sintetici ETH a 4 tick/settimana."""
    rows: list[MarketSnapshotRecord] = []
    monday = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    for week in range(n_weeks):
        base = monday + timedelta(weeks=week)
        # Lunedì 14:00 è il pick
        rows.append(_snap(ts=base, spot=spot, dvol=dvol, funding=funding))
        # Tick intermedi che NON cadono di lunedì alle 14:00:
        # offset +1h così vengono ignorati da `monday_picks`.
        for d in (2, 8, 14, 19):
            rows.append(
                _snap(
                    ts=base + timedelta(days=d, hours=1),
                    spot=spot * (1 + 0.005 * d),  # +0.5% al giorno
                    dvol=dvol - 1.5 * d,  # vol che scende lentamente
                    funding=funding,
                )
            )
    return rows
 def test_run_backtest_produces_report_with_trades() -> None:
    # Per il test scaliamo il credit/width gate al 15%: il modello BS
    # senza skew completo sottostima i premi OTM rispetto al reale.
    # Vedi `estimate_credit_eth.skew_premium` docstring per dettagli.
    from cerbero_bite.config.schema import StructureConfig
    cfg = golden_config()
    cfg = cfg.model_copy(
        update={
            "structure": StructureConfig(
                **{
                    **cfg.structure.model_dump(),
                    "credit_to_width_ratio_min": Decimal("0.15"),
                }
            )
        }
    )
    snapshots = _synthetic_year_of_snapshots(n_weeks=4)
    report = run_backtest(snapshots, cfg, capital_usd=Decimal("1500"))
    # Sanity: 4 picks, almeno 1 trade chiuso
    assert report.n_picks == 4
    assert report.n_completed >= 1
    assert report.cumulative_pnl_usd != Decimal("0")
    # Bull-put + ETH al rialzo + DVOL che scende ⇒ atteso win
    assert report.n_winners >= 1
 def test_run_backtest_handles_no_picks_gracefully() -> None:
    cfg = golden_config()
    # Solo tick infrasettimanali, niente Monday 14:00.
    monday = datetime(2026, 5, 4, 14, 0, tzinfo=UTC)
    snapshots = [_snap(ts=monday + timedelta(hours=1))]
    report = run_backtest(snapshots, cfg, capital_usd=Decimal("1500"))
    assert report.n_picks == 0
    assert report.n_completed == 0
    assert report.cumulative_pnl_usd == Decimal("0")
@@ -0,0 +1,134 @@
 """TDD per :mod:`cerbero_bite.runtime.option_chain_snapshot_cycle`."""
 from __future__ import annotations
 from datetime import UTC, datetime
 from decimal import Decimal
 from unittest.mock import AsyncMock, MagicMock
 import pytest
 from cerbero_bite.clients.deribit import InstrumentMeta
 from cerbero_bite.runtime.option_chain_snapshot_cycle import (
    collect_option_chain_snapshot,
 )
 from cerbero_bite.state.models import OptionChainQuoteRecord
 _NOW = datetime(2026, 5, 4, 13, 55, tzinfo=UTC)
 def _meta(name: str, strike: int, expiry_dte: int = 18) -> InstrumentMeta:
    expiry = _NOW.replace(hour=8, minute=0, second=0)
    expiry = expiry.replace(day=expiry.day) + (
        # add days
        __import__("datetime").timedelta(days=expiry_dte)
    )
    return InstrumentMeta(
        name=name,
        strike=Decimal(str(strike)),
        expiry=expiry,
        option_type="P",
        open_interest=Decimal("100"),
        tick_size=Decimal("0.0005"),
        min_trade_amount=Decimal("1"),
    )
 def _ticker(name: str, *, mark: float = 0.020, bid: float = 0.018,
            ask: float = 0.022, delta: float = -0.12) -> dict:
    return {
        "instrument_name": name,
        "bid": bid,
        "ask": ask,
        "mark_price": mark,
        "mark_iv": 60.0,
        "volume_24h": 50,
        "greeks": {
            "delta": delta,
            "gamma": 0.001,
            "theta": -0.0005,
            "vega": 0.10,
        },
    }
@pytest.fixture
 def cfg() -> object:
    from cerbero_bite.config import golden_config
    return golden_config()
@pytest.fixture
 def fake_ctx(cfg: object) -> MagicMock:
    """Mock minimal RuntimeContext."""
    ctx = MagicMock()
    ctx.cfg = cfg
    ctx.db_path = ":memory:"
    return ctx
@pytest.mark.asyncio
 async def test_collector_persists_one_quote_per_instrument(
    fake_ctx: MagicMock,
 ) -> None:
    metas = [_meta("ETH-21MAY26-2475-P", 2475), _meta("ETH-21MAY26-2400-P", 2400)]
    fake_ctx.deribit.options_chain = AsyncMock(return_value=metas)
    fake_ctx.deribit.get_tickers = AsyncMock(
        return_value=[_ticker(m.name) for m in metas]
    )
    persisted: list[list[OptionChainQuoteRecord]] = []
    def _record(_conn: object, qs: list[OptionChainQuoteRecord]) -> int:
        persisted.append(qs)
        return len(qs)
    fake_ctx.repository.record_option_chain_snapshot = _record
    n = await collect_option_chain_snapshot(fake_ctx, asset="ETH", now=_NOW)
    assert n == 2
    assert len(persisted) == 1
    assert {q.instrument_name for q in persisted[0]} == {
        "ETH-21MAY26-2475-P", "ETH-21MAY26-2400-P",
    }
    # Tutti i quote condividono il timestamp del cron tick.
    assert all(q.timestamp == _NOW for q in persisted[0])
@pytest.mark.asyncio
 async def test_collector_handles_missing_tickers_with_null_fields(
    fake_ctx: MagicMock,
 ) -> None:
    metas = [_meta("ETH-21MAY26-2475-P", 2475)]
    fake_ctx.deribit.options_chain = AsyncMock(return_value=metas)
    fake_ctx.deribit.get_tickers = AsyncMock(return_value=[])  # vuoto
    persisted: list[list[OptionChainQuoteRecord]] = []
    def _record(_conn: object, qs: list[OptionChainQuoteRecord]) -> int:
        persisted.append(qs)
        return len(qs)
    fake_ctx.repository.record_option_chain_snapshot = _record
    n = await collect_option_chain_snapshot(fake_ctx, now=_NOW)
    assert n == 1
    assert persisted[0][0].mid is None  # ticker mancante ⇒ campi NULL
    assert persisted[0][0].instrument_name == "ETH-21MAY26-2475-P"
@pytest.mark.asyncio
 async def test_collector_returns_zero_when_chain_empty(
    fake_ctx: MagicMock,
 ) -> None:
    fake_ctx.deribit.options_chain = AsyncMock(return_value=[])
    n = await collect_option_chain_snapshot(fake_ctx, now=_NOW)
    assert n == 0
@pytest.mark.asyncio
 async def test_collector_swallows_chain_fetch_failure(
    fake_ctx: MagicMock,
 ) -> None:
    fake_ctx.deribit.options_chain = AsyncMock(side_effect=RuntimeError("boom"))
    n = await collect_option_chain_snapshot(fake_ctx, now=_NOW)
    assert n == 0  # best-effort: non rilancia