| """Evaluate the safety supervisor on the labelled eval set, with real numbers. |
| |
| Calibrates the supervisor on the real DROID calibration actions, then: |
| |
| - sweeps the drift threshold over the normal-vs-drift rows to get an ROC and |
| AUC, and picks a data-driven operating point at a target false-positive |
| rate, so the threshold is justified instead of a magic 4.0; |
| - replays every eval row through the real supervisor (the genuine step() code |
| path) and reports precision / recall / false-positive rate at both the |
| default and the chosen threshold, plus the catch rate per fault type. |
| |
| Needs only numpy + the eval set built by make_eval_set.py. |
| Run: python3 safety/evaluate.py (add --json safety/data/eval_report.json to save) |
| """ |
| from __future__ import annotations |
|
|
| import argparse |
| import json |
| import os |
|
|
| import numpy as np |
|
|
| from supervisor import Supervisor, SupervisorConfig |
|
|
| DATA = os.path.join(os.path.dirname(__file__), "data", "supervisor_eval.npz") |
| TARGET_FPR = 0.01 |
| CODE_NAME = {0: "normal", 1: "nonfinite", 2: "out_of_bounds", 3: "drift", 4: "jerk"} |
|
|
|
|
| def roc(scores_neg, scores_pos): |
| """ROC + AUC for a score where higher = more anomalous. Returns (fpr, tpr, thr, auc).""" |
| thr = np.unique(np.concatenate([scores_neg, scores_pos])) |
| thr = np.concatenate([[-np.inf], thr, [np.inf]]) |
| tpr = np.array([(scores_pos >= t).mean() for t in thr]) |
| fpr = np.array([(scores_neg >= t).mean() for t in thr]) |
| order = np.argsort(fpr) |
| fo, to = fpr[order], tpr[order] |
| auc = float(np.sum((fo[1:] - fo[:-1]) * (to[1:] + to[:-1]) / 2.0)) |
| return fpr, tpr, thr, auc |
|
|
|
|
| def confusion(pred_fault, label): |
| tp = int(((pred_fault == 1) & (label == 1)).sum()) |
| fp = int(((pred_fault == 1) & (label == 0)).sum()) |
| tn = int(((pred_fault == 0) & (label == 0)).sum()) |
| fn = int(((pred_fault == 0) & (label == 1)).sum()) |
| prec = tp / (tp + fp) if tp + fp else 0.0 |
| rec = tp / (tp + fn) if tp + fn else 0.0 |
| fpr = fp / (fp + tn) if fp + tn else 0.0 |
| f1 = 2 * prec * rec / (prec + rec) if prec + rec else 0.0 |
| return dict(tp=tp, fp=fp, tn=tn, fn=fn, precision=prec, recall=rec, fpr=fpr, f1=f1) |
|
|
|
|
| def replay(sup, acts, prevs, drift_thresh): |
| """Run every row through the real step() at a given drift threshold; return predicted-fault mask.""" |
| sup.cfg.drift_thresh = drift_thresh |
| pred = np.zeros(len(acts), dtype=np.int64) |
| for i in range(len(acts)): |
| sup._last_safe = prevs[i].astype(np.float64).copy() |
| _, iv = sup.step(acts[i]) |
| pred[i] = 0 if iv is None else 1 |
| return pred |
|
|
|
|
| def main(): |
| ap = argparse.ArgumentParser() |
| ap.add_argument("--json", default=None, help="optional path to save the report as JSON") |
| args = ap.parse_args() |
|
|
| d = np.load(DATA, allow_pickle=False) |
| calib = d["calib_actions"].astype(np.float64) |
| low, high = d["action_low"].astype(np.float64), d["action_high"].astype(np.float64) |
| acts, prevs = d["eval_action"].astype(np.float64), d["eval_prev"].astype(np.float64) |
| label, ftype = d["eval_label"], d["eval_ftype"] |
| A = calib.shape[1] |
|
|
| cfg = SupervisorConfig(action_low=low, action_high=high) |
| sup = Supervisor(cfg).calibrate(calib) |
|
|
| |
| drift_score = np.array([sup.drift_score(a) for a in acts]) |
| is_norm, is_drift = (ftype == 0), (ftype == 3) |
| fpr, tpr, thr, auc = roc(drift_score[is_norm], drift_score[is_drift]) |
|
|
| |
| ok = np.where(fpr <= TARGET_FPR)[0] |
| op_thr = float(thr[ok[np.argmax(tpr[ok])]]) if len(ok) else float(thr[-1]) |
| op_tpr = float(tpr[thr == op_thr][0]); op_fpr = float(fpr[thr == op_thr][0]) |
|
|
| |
| res = {} |
| for name, t in [("default(4.0)", 4.0), (f"tuned({op_thr:.2f})", op_thr)]: |
| pred = replay(sup, acts, prevs, t) |
| c = confusion(pred, label) |
| per_type = {CODE_NAME[ct]: round(float(pred[ftype == ct].mean()), 4) |
| for ct in sorted(set(ftype.tolist()))} |
| res[name] = {"threshold": t, **c, "catch_rate_by_type": per_type} |
|
|
| |
| print("=" * 64) |
| print("Safety supervisor — evaluation on real DROID actions + labelled faults") |
| print("=" * 64) |
| print(f"calibration frames : {len(calib)} action_dim : {A}") |
| print(f"eval rows : {len(acts)} ({int(is_norm.sum())} normal, {int((label==1).sum())} fault)") |
| print() |
| print(f"Drift (OOD) detector ROC, normal vs drift: AUC = {auc:.3f}") |
| print(f" operating point at <= {TARGET_FPR*100:.0f}% false positives:") |
| print(f" threshold {op_thr:.2f} -> detection {op_tpr*100:.1f}% at FPR {op_fpr*100:.2f}%") |
| print(f" (shipped default threshold is 4.0)") |
| print() |
| for name, r in res.items(): |
| print(f"All faults, threshold = {name}") |
| print(f" precision {r['precision']*100:5.1f}% recall {r['recall']*100:5.1f}% " |
| f"FPR {r['fpr']*100:4.1f}% F1 {r['f1']:.3f}") |
| print(" catch rate by type: " + |
| " ".join(f"{k} {v*100:.0f}%" for k, v in r["catch_rate_by_type"].items())) |
| print() |
|
|
| if args.json: |
| out = {"calibration_frames": len(calib), "action_dim": A, "eval_rows": len(acts), |
| "drift_auc": round(auc, 4), |
| "operating_point": {"target_fpr": TARGET_FPR, "threshold": round(op_thr, 4), |
| "detection": round(op_tpr, 4), "fpr": round(op_fpr, 4)}, |
| "at_thresholds": res} |
| with open(args.json, "w") as f: |
| json.dump(out, f, indent=2) |
| print(f"saved {args.json}") |
|
|
|
|
| if __name__ == "__main__": |
| main() |
|
|
