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#!/usr/bin/env python
from __future__ import annotations

import argparse
import hashlib
import json
import math
import subprocess
import sys
from collections import defaultdict
from pathlib import Path
from typing import Any

PROJECT_ROOT = Path(__file__).resolve().parents[1]
if str(PROJECT_ROOT) not in sys.path:
    sys.path.insert(0, str(PROJECT_ROOT))

import numpy as np  # noqa: E402
from sklearn.ensemble import (  # noqa: E402
    HistGradientBoostingClassifier,
    HistGradientBoostingRegressor,
    RandomForestRegressor,
)

from cil.chart_features import CHART_FEATURE_MODES  # noqa: E402
from cil.metrics import macro_micro_summary  # noqa: E402
from scripts.eval_dominance_selector import (  # noqa: E402
    _DominanceScorer,
    _chart_map,
    _first_train_seed,
    _rows,
)
from scripts.eval_learned_dominance_selector import (  # noqa: E402
    FEATURE_SET_CHOICES,
    _candidate_dataset,
    _evaluate_predictions,
    _feature_names,
    _group_means,
    _pairwise_calibration_global,
    _pairwise_calibration_summary,
    _resolve_index_path,
    _selector_chart_map,
    _simple_summary,
    _source_evidence_map,
    _summary_with_pairwise,
    _uses_chart_compat,
    _uses_source_evidence,
)


def main(argv: list[str] | None = None) -> int:
    parser = argparse.ArgumentParser(
        description=(
            "Train a nonlinear train-only dominance selector on measured CTT "
            "calibration rollouts and evaluate it on held-out measured rollouts."
        )
    )
    parser.add_argument("--calibration-input", type=Path, required=True)
    parser.add_argument("--calibration-target-index", type=Path, required=True)
    parser.add_argument("--eval-input", type=Path, required=True)
    parser.add_argument("--eval-target-index", type=Path, required=True)
    parser.add_argument(
        "--source-index",
        type=Path,
        default=None,
        help=(
            "Train split chart index used for source-evidence features. "
            "Defaults to --calibration-target-index."
        ),
    )
    parser.add_argument(
        "--checkpoint-template",
        default="runs/ctt_residual_full_seed{seed}/model.pt",
    )
    parser.add_argument(
        "--out-dir",
        type=Path,
        default=Path("runs/ctt_nonlinear_dominance_train_to_test"),
    )
    parser.add_argument("--k", type=int, default=8)
    parser.add_argument(
        "--feature-set",
        choices=FEATURE_SET_CHOICES,
        default="context_tangent",
    )
    parser.add_argument(
        "--selector-chart-feature-mode",
        choices=CHART_FEATURE_MODES,
        default="base_context_obs_obj",
        help=(
            "Chart feature mode used only for selector chart-compatibility "
            "features. These maps are loaded without hidden outcomes."
        ),
    )
    parser.add_argument(
        "--target",
        choices=("utility_margin", "success", "success_weighted_margin", "positive_margin"),
        default="positive_margin",
    )
    parser.add_argument(
        "--model-types",
        default="hgb_classifier,hgb_regressor,rf_regressor",
        help="Comma-separated candidates from hgb_classifier,hgb_regressor,rf_regressor.",
    )
    parser.add_argument("--selection-frac", type=float, default=0.35)
    parser.add_argument("--seed", type=int, default=0)
    parser.add_argument("--bootstrap-samples", type=int, default=1000)
    parser.add_argument(
        "--no-markdown-report",
        action="store_true",
        help="Do not write report.md; useful when the workspace is kept README-only.",
    )
    args = parser.parse_args(argv)

    if args.k <= 0:
        parser.error("--k must be positive")
    if not 0.05 <= args.selection_frac <= 0.75:
        parser.error("--selection-frac must be in [0.05, 0.75]")
    model_types = [item.strip() for item in args.model_types.split(",") if item.strip()]
    allowed = {"hgb_classifier", "hgb_regressor", "rf_regressor"}
    if not model_types or any(item not in allowed for item in model_types):
        parser.error(f"--model-types must be comma-separated values from {sorted(allowed)}")

    out_dir = args.out_dir
    out_dir.mkdir(parents=True, exist_ok=True)
    _write_provenance(out_dir, args)

    scorer = _DominanceScorer(args.checkpoint_template)
    calibration_rows = _rows(json.loads(args.calibration_input.read_text()))
    eval_rows = _rows(json.loads(args.eval_input.read_text()))
    chart_feature_mode = scorer.chart_feature_mode(_first_train_seed(calibration_rows + eval_rows))
    calibration_charts, calibration_index = _chart_map(
        args.calibration_target_index,
        chart_feature_mode=chart_feature_mode,
    )
    eval_charts, eval_index = _chart_map(
        args.eval_target_index,
        chart_feature_mode=chart_feature_mode,
    )
    source_index_path = _resolve_index_path(args.source_index or args.calibration_target_index)
    source_evidence, source_index = (
        _source_evidence_map(source_index_path) if _uses_source_evidence(args.feature_set) else ({}, {})
    )
    selector_source_charts: dict[str, Any] = {}
    selector_source_index: dict[str, Any] = {}
    selector_calibration_charts: dict[str, Any] = {}
    selector_eval_charts: dict[str, Any] = {}
    selector_calibration_index: dict[str, Any] = {}
    selector_eval_index: dict[str, Any] = {}
    if _uses_chart_compat(args.feature_set):
        selector_calibration_charts, selector_calibration_index = _selector_chart_map(
            args.calibration_target_index,
            chart_feature_mode=args.selector_chart_feature_mode,
        )
        selector_eval_charts, selector_eval_index = _selector_chart_map(
            args.eval_target_index,
            chart_feature_mode=args.selector_chart_feature_mode,
        )
        selector_source_charts, selector_source_index = _selector_chart_map(
            source_index_path,
            chart_feature_mode=args.selector_chart_feature_mode,
        )
    dataset_target = (
        "utility_margin" if args.target == "positive_margin" else args.target
    )
    calibration_dataset = _candidate_dataset(
        calibration_rows,
        calibration_charts,
        scorer=scorer,
        k=args.k,
        feature_set=args.feature_set,
        target=dataset_target,
        source_evidence=source_evidence,
        selector_target_charts=selector_calibration_charts,
        selector_source_charts=selector_source_charts,
        selector_chart_feature_mode=args.selector_chart_feature_mode,
    )
    eval_dataset = _candidate_dataset(
        eval_rows,
        eval_charts,
        scorer=scorer,
        k=args.k,
        feature_set=args.feature_set,
        target=dataset_target,
        source_evidence=source_evidence,
        selector_target_charts=selector_eval_charts,
        selector_source_charts=selector_source_charts,
        selector_chart_feature_mode=args.selector_chart_feature_mode,
    )
    fit_rows, select_rows = _split_rows(
        calibration_dataset,
        selection_frac=args.selection_frac,
        seed=args.seed,
    )
    fit_dataset = _subset_dataset(calibration_dataset, fit_rows)
    select_dataset = _subset_dataset(calibration_dataset, select_rows)
    if not fit_dataset["samples"] or not select_dataset["samples"]:
        raise SystemExit("calibration split produced an empty fit or selection set")

    best = _fit_select_model(
        fit_dataset,
        select_dataset,
        model_types=model_types,
        target=args.target,
        seed=args.seed,
    )
    eval_predictions = _predict(best["model"], eval_dataset, model_type=best["model_type"])
    fit_predictions = _predict(best["model"], fit_dataset, model_type=best["model_type"])
    select_predictions = _predict(best["model"], select_dataset, model_type=best["model_type"])
    eval_pairwise = _pairwise_calibration_summary(eval_dataset, eval_predictions)
    fit_pairwise = _pairwise_calibration_summary(fit_dataset, fit_predictions)
    select_pairwise = _pairwise_calibration_summary(select_dataset, select_predictions)
    eval_cases = _evaluate_predictions(
        eval_dataset,
        eval_predictions,
        tau=best["tau"],
        include_pairwise_calibration=True,
        pairwise_calibration=eval_pairwise,
    )
    fit_cases = _evaluate_predictions(
        fit_dataset,
        fit_predictions,
        tau=best["tau"],
        include_pairwise_calibration=True,
        pairwise_calibration=fit_pairwise,
    )
    select_cases = _evaluate_predictions(
        select_dataset,
        select_predictions,
        tau=best["tau"],
        include_pairwise_calibration=True,
        pairwise_calibration=select_pairwise,
    )

    metric_names = sorted(
        {
            key
            for row in eval_cases
            for key, value in row.items()
            if key not in {"chart_id", "task_id", "seed", "train_seed"}
            and isinstance(value, (int, float))
            and math.isfinite(float(value))
        }
    )
    summary = {
        name: macro_micro_summary(
            eval_cases,
            name,
            bootstrap_samples=args.bootstrap_samples,
            confidence=0.95,
        )
        for name in metric_names
    }
    metrics = {
        "report_type": "nonlinear_dominance_selector_eval",
        "schema_version": 1,
        "k": args.k,
        "feature_set": args.feature_set,
        "feature_names": _feature_names(args.feature_set),
        "target": args.target,
        "model_types": model_types,
        "selected_model_type": best["model_type"],
        "selected_model_params": best["params"],
        "tau": best["tau"],
        "selection_frac": args.selection_frac,
        "seed": args.seed,
        "chart_feature_mode": chart_feature_mode,
        "selector_chart_feature_mode": (
            args.selector_chart_feature_mode if _uses_chart_compat(args.feature_set) else None
        ),
        "calibration_input": str(args.calibration_input),
        "eval_input": str(args.eval_input),
        "source_index": str(source_index_path) if _uses_source_evidence(args.feature_set) else None,
        "data_hash": eval_index.get("content_hash"),
        "split_hash": eval_index.get("split_hash"),
        "calibration_target_content_hash": calibration_index.get("content_hash"),
        "calibration_target_split_hash": calibration_index.get("split_hash"),
        "eval_target_content_hash": eval_index.get("content_hash"),
        "eval_target_split_hash": eval_index.get("split_hash"),
        "source_content_hash": source_index.get("content_hash"),
        "source_split_hash": source_index.get("split_hash"),
        "selector_source_content_hash": selector_source_index.get("content_hash"),
        "selector_source_split_hash": selector_source_index.get("split_hash"),
        "selector_calibration_target_content_hash": selector_calibration_index.get("content_hash"),
        "selector_calibration_target_split_hash": selector_calibration_index.get("split_hash"),
        "selector_eval_target_content_hash": selector_eval_index.get("content_hash"),
        "selector_eval_target_split_hash": selector_eval_index.get("split_hash"),
        "num_calibration_rows": len(calibration_rows),
        "num_fit_rows": fit_dataset["num_rows"],
        "num_selection_rows": select_dataset["num_rows"],
        "num_eval_rows": len(eval_rows),
        "num_fit_candidates": len(fit_dataset["samples"]),
        "num_selection_candidates": len(select_dataset["samples"]),
        "num_eval_candidates": len(eval_dataset["samples"]),
        "model_selection": best["selection"],
        "fit_summary": _summary_with_pairwise(fit_cases, fit_pairwise),
        "selection_summary": _summary_with_pairwise(select_cases, select_pairwise),
        "eval_summary": _summary_with_pairwise(eval_cases, eval_pairwise),
        "pairwise_causal_calibration": {
            "fit": _pairwise_calibration_global(fit_pairwise),
            "selection": _pairwise_calibration_global(select_pairwise),
            "eval": _pairwise_calibration_global(eval_pairwise),
        },
        "summary": summary,
        "rows": eval_cases,
    }
    (out_dir / "metrics.json").write_text(json.dumps(metrics, indent=2, sort_keys=True) + "\n")
    (out_dir / "metrics_by_task.json").write_text(
        json.dumps(_group_means(eval_cases, "task_id", metric_names), indent=2, sort_keys=True)
        + "\n"
    )
    (out_dir / "metrics_by_seed.json").write_text(
        json.dumps(_group_means(eval_cases, "seed", metric_names), indent=2, sort_keys=True)
        + "\n"
    )
    (out_dir / "table.tex").write_text(_table(metrics) + "\n")
    _write_report_artifact(out_dir, metrics, no_markdown_report=args.no_markdown_report)
    (out_dir / "train.log").write_text(
        "trained nonlinear dominance selector on calibration-fit rows only\n"
        f"selected_model_type={best['model_type']}\n"
        f"selected_model_params={json.dumps(best['params'], sort_keys=True)}\n"
        f"tau={best['tau']:.6f}\n"
        f"calibration_input={args.calibration_input}\n"
    )
    (out_dir / "eval.log").write_text(
        "selected model/tau on held-out calibration-selection rows; evaluated on held-out measured rollout rows\n"
        f"eval_input={args.eval_input}\n"
        f"num_eval_rows={len(eval_rows)}\n"
    )
    print(
        json.dumps(
            {
                "out_dir": str(out_dir),
                "model_type": best["model_type"],
                "tau": best["tau"],
                "selected_success": metrics["eval_summary"]["selected_success"],
            },
            indent=2,
        )
    )
    return 0


def _split_rows(
    dataset: dict[str, Any],
    *,
    selection_frac: float,
    seed: int,
) -> tuple[list[int], list[int]]:
    row_indices = sorted(dataset["by_row"])
    scored = []
    for row_index in row_indices:
        sample = dataset["samples"][dataset["by_row"][row_index][0]]
        key = f"{sample['chart_id']}|{sample['seed']}|{seed}"
        digest = hashlib.sha256(key.encode("utf-8")).digest()
        value = int.from_bytes(digest[:8], "big") / float(2**64 - 1)
        scored.append((value, row_index))
    selection = [row for value, row in scored if value < selection_frac]
    fit = [row for value, row in scored if value >= selection_frac]
    if not selection or not fit:
        cutoff = max(1, min(len(scored) - 1, int(round(len(scored) * selection_frac))))
        selection = [row for _value, row in scored[:cutoff]]
        fit = [row for _value, row in scored[cutoff:]]
    return fit, selection


def _subset_dataset(dataset: dict[str, Any], row_indices: list[int]) -> dict[str, Any]:
    wanted = set(int(row) for row in row_indices)
    samples = []
    by_row: dict[int, list[int]] = {}
    row_map: dict[int, int] = {}
    for old_row in sorted(wanted):
        if old_row not in dataset["by_row"]:
            continue
        new_row = len(row_map)
        row_map[old_row] = new_row
        by_row[new_row] = []
        for old_sample_index in dataset["by_row"][old_row]:
            sample = dict(dataset["samples"][old_sample_index])
            sample["row_index"] = new_row
            by_row[new_row].append(len(samples))
            samples.append(sample)
    return {"samples": samples, "by_row": by_row, "num_rows": len(by_row)}


def _fit_select_model(
    fit_dataset: dict[str, Any],
    select_dataset: dict[str, Any],
    *,
    model_types: list[str],
    target: str,
    seed: int,
) -> dict[str, Any]:
    x_fit = np.stack([sample["feature"] for sample in fit_dataset["samples"]], axis=0)
    best: dict[str, Any] | None = None
    for model_type, params in _model_grid(model_types, seed=seed):
        y_fit = _target_array(fit_dataset, target=target, model_type=model_type)
        if model_type == "hgb_classifier" and len(set(int(value) for value in y_fit)) < 2:
            continue
        model = _make_model(model_type, params)
        model.fit(x_fit, y_fit)
        predictions = _predict(model, select_dataset, model_type=model_type)
        tau, selection = _choose_tau(select_dataset, predictions)
        key = (
            float(selection.get("selected_success") or 0.0),
            float(selection.get("selected_utility") or 0.0),
            float(selection.get("coverage") or 0.0),
            -float(_model_complexity(model_type, params)),
        )
        if best is None or key > best["key"]:
            best = {
                "key": key,
                "model": model,
                "model_type": model_type,
                "params": params,
                "tau": tau,
                "selection": selection,
            }
    if best is None:
        raise ValueError("could not fit any nonlinear dominance model")
    return best


def _target_array(dataset: dict[str, Any], *, target: str, model_type: str) -> np.ndarray:
    if model_type == "hgb_classifier":
        if target == "success":
            return np.asarray(
                [float(sample["candidate_success"]) for sample in dataset["samples"]],
                dtype=int,
            )
        return np.asarray(
            [float(sample["measured_utility_margin"] > 0.0) for sample in dataset["samples"]],
            dtype=int,
        )
    if target == "positive_margin":
        return np.asarray(
            [float(sample["measured_utility_margin"] > 0.0) for sample in dataset["samples"]],
            dtype=float,
        )
    if target == "success":
        return np.asarray(
            [float(sample["candidate_success"]) for sample in dataset["samples"]],
            dtype=int,
        )
    return np.asarray([float(sample["target_margin"]) for sample in dataset["samples"]], dtype=float)


def _model_grid(model_types: list[str], *, seed: int) -> list[tuple[str, dict[str, Any]]]:
    grid: list[tuple[str, dict[str, Any]]] = []
    for model_type in model_types:
        if model_type == "hgb_classifier":
            for max_iter in (40, 80):
                for max_leaf_nodes in (7, 15):
                    grid.append(
                        (
                            model_type,
                            {
                                "learning_rate": 0.05,
                                "max_iter": max_iter,
                                "max_leaf_nodes": max_leaf_nodes,
                                "l2_regularization": 0.01,
                                "random_state": seed,
                            },
                        )
                    )
        elif model_type == "hgb_regressor":
            for max_iter in (40, 80):
                for max_leaf_nodes in (7, 15):
                    grid.append(
                        (
                            model_type,
                            {
                                "learning_rate": 0.05,
                                "max_iter": max_iter,
                                "max_leaf_nodes": max_leaf_nodes,
                                "l2_regularization": 0.01,
                                "random_state": seed,
                            },
                        )
                    )
        elif model_type == "rf_regressor":
            for max_depth in (3, 5):
                grid.append(
                    (
                        model_type,
                        {
                            "n_estimators": 128,
                            "max_depth": max_depth,
                            "min_samples_leaf": 8,
                            "random_state": seed,
                            "n_jobs": 1,
                        },
                    )
                )
        else:
            raise ValueError(f"unknown model_type: {model_type}")
    return grid


def _make_model(model_type: str, params: dict[str, Any]) -> Any:
    if model_type == "hgb_classifier":
        return HistGradientBoostingClassifier(**params)
    if model_type == "hgb_regressor":
        return HistGradientBoostingRegressor(**params)
    if model_type == "rf_regressor":
        return RandomForestRegressor(**params)
    raise ValueError(f"unknown model_type: {model_type}")


def _predict(model: Any, dataset: dict[str, Any], *, model_type: str) -> np.ndarray:
    x = np.stack([sample["feature"] for sample in dataset["samples"]], axis=0)
    if model_type == "hgb_classifier":
        return np.asarray(model.predict_proba(x)[:, 1], dtype=float)
    return np.asarray(model.predict(x), dtype=float)


def _choose_tau(dataset: dict[str, Any], predictions: np.ndarray) -> tuple[float, dict[str, float | None]]:
    candidates = sorted(float(value) for value in predictions)
    thresholds = [min(candidates) - 1.0, *candidates, max(candidates) + 1.0]
    best_tau = thresholds[0]
    best_summary: dict[str, float | None] | None = None
    best_key: tuple[float, float, float] | None = None
    for tau in thresholds:
        cases = _evaluate_predictions(dataset, predictions, tau=tau)
        summary = _simple_summary(cases)
        key = (
            float(summary.get("selected_success") or 0.0),
            float(summary.get("selected_utility") or 0.0),
            float(summary.get("coverage") or 0.0),
        )
        if best_key is None or key > best_key:
            best_key = key
            best_tau = float(tau)
            best_summary = summary
    assert best_summary is not None
    return best_tau, best_summary


def _model_complexity(model_type: str, params: dict[str, Any]) -> float:
    if model_type == "rf_regressor":
        return float(params.get("n_estimators", 0) * params.get("max_depth", 1))
    return float(params.get("max_iter", 0) * params.get("max_leaf_nodes", 1))


def _table(metrics: dict[str, Any]) -> str:
    summary = metrics["eval_summary"]
    lines = [
        "% Auto-generated by scripts/eval_nonlinear_dominance_selector.py",
        "\\begin{tabular}{lrrrrrrrrr}",
        "\\toprule",
        "Rows & Coverage & Fallback & Base succ. & Selected succ. & Oracle succ. & OutcomePTR & Succ. support gap & Succ. selector gap & Cal. ECE \\\\",
        "\\midrule",
        f"{metrics['num_eval_rows']} & {_fmt(summary.get('coverage'))} & "
        f"{_fmt(summary.get('fallback_rate'))} & {_fmt(summary.get('base_success'))} & "
        f"{_fmt(summary.get('selected_success'))} & {_fmt(summary.get('proposal_oracle_success'))} & "
        f"{_fmt(summary.get('outcome_ptr'))} & {_fmt(summary.get('success_support_gap'))} & "
        f"{_fmt(summary.get('success_selector_gap'))} & "
        f"{_fmt(summary.get('pairwise_causal_calibration_ece'))} \\\\",
        "\\bottomrule",
        "\\end{tabular}",
    ]
    return "\n".join(lines)


def _report(metrics: dict[str, Any]) -> str:
    fit = metrics["fit_summary"]
    selection = metrics["selection_summary"]
    eval_summary = metrics["eval_summary"]
    lines = [
        "# Nonlinear Train-Calibrated CTT Selector",
        "",
        f"Calibration rows: `{metrics['num_calibration_rows']}`",
        f"Fit rows: `{metrics['num_fit_rows']}`",
        f"Selection rows: `{metrics['num_selection_rows']}`",
        f"Eval rows: `{metrics['num_eval_rows']}`",
        f"Selected model: `{metrics['selected_model_type']}`",
        f"Selected params: `{json.dumps(metrics['selected_model_params'], sort_keys=True)}`",
        f"Tau: `{metrics['tau']:.6f}`",
        f"Feature set: `{metrics['feature_set']}`",
        f"Target: `{metrics['target']}`",
        "",
        "The model is fit on calibration-fit rows, and model/tau are selected on held-out calibration-selection rows only. Eval outcomes are used only for reporting.",
        "",
        "| Split | Coverage | Fallback | Base success | Selected success | Proposal oracle | OutcomePTR | Success support gap | Success selector gap | Calibration ECE |",
        "| --- | ---: | ---: | ---: | ---: | ---: | ---: | ---: | ---: | ---: |",
        f"| fit | {_fmt(fit.get('coverage'))} | {_fmt(fit.get('fallback_rate'))} | "
        f"{_fmt(fit.get('base_success'))} | {_fmt(fit.get('selected_success'))} | "
        f"{_fmt(fit.get('proposal_oracle_success'))} | {_fmt(fit.get('outcome_ptr'))} | "
        f"{_fmt(fit.get('success_support_gap'))} | {_fmt(fit.get('success_selector_gap'))} | "
        f"{_fmt(fit.get('pairwise_causal_calibration_ece'))} |",
        f"| selection | {_fmt(selection.get('coverage'))} | {_fmt(selection.get('fallback_rate'))} | "
        f"{_fmt(selection.get('base_success'))} | {_fmt(selection.get('selected_success'))} | "
        f"{_fmt(selection.get('proposal_oracle_success'))} | {_fmt(selection.get('outcome_ptr'))} | "
        f"{_fmt(selection.get('success_support_gap'))} | {_fmt(selection.get('success_selector_gap'))} | "
        f"{_fmt(selection.get('pairwise_causal_calibration_ece'))} |",
        f"| eval | {_fmt(eval_summary.get('coverage'))} | {_fmt(eval_summary.get('fallback_rate'))} | "
        f"{_fmt(eval_summary.get('base_success'))} | {_fmt(eval_summary.get('selected_success'))} | "
        f"{_fmt(eval_summary.get('proposal_oracle_success'))} | {_fmt(eval_summary.get('outcome_ptr'))} | "
        f"{_fmt(eval_summary.get('success_support_gap'))} | {_fmt(eval_summary.get('success_selector_gap'))} | "
        f"{_fmt(eval_summary.get('pairwise_causal_calibration_ece'))} |",
        "",
        "This is a train-calibrated selector diagnostic over already measured candidates, not a new rollout.",
    ]
    return "\n".join(lines)


def _write_report_artifact(
    out_dir: Path,
    metrics: dict[str, Any],
    *,
    no_markdown_report: bool = False,
) -> None:
    report_path = out_dir / "report.md"
    if no_markdown_report:
        if report_path.exists():
            report_path.unlink()
        return
    report_path.write_text(_report(metrics) + "\n")


def _write_provenance(out_dir: Path, args: argparse.Namespace) -> None:
    (out_dir / "config.yaml").write_text(
        "\n".join(f"{key}: {value}" for key, value in sorted(vars(args).items())) + "\n"
    )
    (out_dir / "command.txt").write_text(
        "python scripts/eval_nonlinear_dominance_selector.py " + " ".join(sys.argv[1:]) + "\n"
    )
    (out_dir / "git_hash.txt").write_text(_run(["git", "rev-parse", "HEAD"]) + "\n")
    hashes = {
        "calibration_input": _sha256(args.calibration_input),
        "calibration_target_index": _sha256(_resolve_index_path(args.calibration_target_index)),
        "eval_input": _sha256(args.eval_input),
        "eval_target_index": _sha256(_resolve_index_path(args.eval_target_index)),
    }
    if (
        getattr(args, "source_index", None) is not None
        or _uses_source_evidence(args.feature_set)
        or _uses_chart_compat(args.feature_set)
    ):
        hashes["source_index"] = _sha256(
            _resolve_index_path(args.source_index or args.calibration_target_index)
        )
    (out_dir / "data_hash.txt").write_text(json.dumps(hashes, indent=2, sort_keys=True) + "\n")
    (out_dir / "split_hash.txt").write_text(
        json.dumps(
            {
                "calibration_target_index": _index_hash(args.calibration_target_index),
                "eval_target_index": _index_hash(args.eval_target_index),
                "source_index": _index_hash(args.source_index or args.calibration_target_index)
                if (
                    getattr(args, "source_index", None) is not None
                    or _uses_source_evidence(args.feature_set)
                    or _uses_chart_compat(args.feature_set)
                )
                else None,
            },
            indent=2,
            sort_keys=True,
        )
        + "\n"
    )


def _index_hash(path: Path) -> dict[str, Any]:
    payload = json.loads(_resolve_index_path(path).read_text())
    return {
        "split": payload.get("split"),
        "content_hash": payload.get("content_hash"),
        "split_hash": payload.get("split_hash"),
        "retrieval_index_allowed": payload.get("retrieval_index_allowed"),
    }


def _sha256(path: Path) -> str:
    h = hashlib.sha256()
    h.update(path.read_bytes())
    return h.hexdigest()


def _fmt(value: Any) -> str:
    if not isinstance(value, (int, float)) or not math.isfinite(float(value)):
        return "n/a"
    return f"{float(value):.4f}"


def _run(command: list[str]) -> str:
    try:
        return subprocess.check_output(command, cwd=PROJECT_ROOT, text=True).strip()
    except (subprocess.CalledProcessError, FileNotFoundError):
        return ""


if __name__ == "__main__":
    raise SystemExit(main())