Two doctrine-aligned CLAUDE.md items closed together. Part 1 — vault indexing + batching (item #4): - VaultStore lazy _matrix_cache (invalidated on store / reproject / eviction); vault_recall(prebuilt_matrix=...) skips deque→ndarray rebuild on hot path - New vault_recall_batch + VaultStore.recall_batch — B queries scored in one component-serial sweep, bit-identical to per-query vault_recall (3 seeds × 7 queries × N=137 parity test) - No approximation, no hot-path repair, scoring arithmetic unchanged Part 2 — holdout split wired: - LaneInfo.holdout_cases_path resolves plaintext holdouts in fixed priority; sealed (.age) holdouts stay in holdout_runner - framework.run_lane(split="holdout") + argparse --split choices - First official cognition holdout numbers: 19 cases, intent 100%, surface 94.7%, term_capture 70.8%, versor 100% — single miss is predicted correction_truth_040 (ADR-0053 scope-limit) Tests: 21 new vault tests + 10 new framework tests. Lanes: smoke 67, cognition 121, runtime 19, teaching 17, packs 6, algebra 132 — all green. versor_condition < 1e-6 invariant preserved.
266 lines
10 KiB
Python
266 lines
10 KiB
Python
"""
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VaultStore — exact memory via CGA inner product scan.
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No HNSW. No approximate nearest neighbor. No index rebuild.
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Recall is exact and deterministic over stored versors. When the query is the
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same point that was stored, exact self-match is promoted ahead of metric ties
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or CGA-sign artifacts.
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Exact self-match uses a hash index (versor bytes -> stored indices) instead of
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O(N) np.array_equal scans.
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"""
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from __future__ import annotations
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from collections import deque
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import numpy as np
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from algebra.backend import vault_recall, vault_recall_batch
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from algebra.cga import null_project
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from teaching.epistemic import ADMISSIBLE_AS_EVIDENCE, EpistemicStatus
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def _versor_key(F: np.ndarray) -> bytes:
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return np.asarray(F, dtype=np.float32).tobytes()
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def _status_admits(entry_status: EpistemicStatus, min_status: EpistemicStatus) -> bool:
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"""Return True iff `entry_status` is admissible at the `min_status` tier.
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Today the only meaningful tier-filter is `min_status=COHERENT`, which
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means "must be in ADMISSIBLE_AS_EVIDENCE." CONTESTED, SPECULATIVE,
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and FALSIFIED entries are excluded. If the admissibility set grows
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in the future (it should not, per ADR-0021), only this helper changes.
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"""
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if min_status is EpistemicStatus.COHERENT:
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return entry_status in ADMISSIBLE_AS_EVIDENCE
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return entry_status is min_status
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class VaultStore:
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def __init__(
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self,
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reproject_interval: int = 100,
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max_entries: int | None = None,
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):
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self._versors: deque[np.ndarray] = deque(maxlen=max_entries)
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self._metadata: deque[dict] = deque(maxlen=max_entries)
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self._store_count: int = 0
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self._reproject_interval = reproject_interval
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self._max_entries = max_entries
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self._exact_index: dict[bytes, list[int]] = {}
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# ADR-0054: cached (N, D) f32 matrix view of the deque, rebuilt
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# lazily on the first recall after any mutation. Indexing
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# optimisation only — scoring arithmetic is unchanged.
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self._matrix_cache: np.ndarray | None = None
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def store(
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self,
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F: np.ndarray,
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metadata: dict | None = None,
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*,
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epistemic_status: EpistemicStatus = EpistemicStatus.SPECULATIVE,
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) -> int:
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"""Store a versor. Returns its index. Auto-reprojects every N stores.
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Every stored entry carries an EpistemicStatus stamped into its
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metadata under the ``epistemic_status`` key. The default is
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SPECULATIVE — the safe choice per ADR-0021 §3: when in doubt,
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the entry is not admissible as evidence. Callers that have
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actually performed a coherence judgment must declare it
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(``epistemic_status=EpistemicStatus.COHERENT``); pack authority
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and source provenance alone are not coherence judgments.
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"""
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arr = np.asarray(F, dtype=np.float32).copy()
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stamped: dict = dict(metadata) if metadata else {}
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stamped["epistemic_status"] = epistemic_status.value
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will_evict = self._max_entries is not None and len(self._versors) >= self._max_entries
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self._versors.append(arr)
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self._metadata.append(stamped)
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if will_evict:
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self._rebuild_index()
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else:
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idx = len(self._versors) - 1
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key = _versor_key(arr)
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self._exact_index.setdefault(key, []).append(idx)
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self._matrix_cache = None
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self._store_count += 1
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if self._reproject_interval > 0 and self._store_count % self._reproject_interval == 0:
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self.reproject()
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return len(self._versors) - 1
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def recall(
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self,
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query: np.ndarray,
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top_k: int = 5,
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*,
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min_status: EpistemicStatus | None = None,
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) -> list:
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"""
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Return top_k closest stored versors by CGA inner product.
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Each result: {versor, score, metadata, index}.
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When ``min_status`` is None (default), no filter is applied —
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every stored entry is eligible. This preserves raw session
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lookup behavior: the session needs to see its own turns
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regardless of epistemic tier.
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When ``min_status`` is set, only entries whose stored
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``epistemic_status`` is admissible at that tier are returned.
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Inference paths that treat vault hits as *evidence* should pass
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``min_status=EpistemicStatus.COHERENT`` so SPECULATIVE,
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CONTESTED, and FALSIFIED entries do not silently influence
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downstream reasoning (ADR-0021 §3).
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"""
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if not self._versors or top_k <= 0:
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return []
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query_arr = np.asarray(query, dtype=np.float32)
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# Over-fetch when filtering so the post-filter result still
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# has a chance at top_k entries. 4x is a generous heuristic;
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# vault sizes are bounded by max_entries anyway.
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scan_k = max(top_k * 4, top_k) if min_status is not None else max(top_k, 1)
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matrix = self._get_matrix()
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ranked = vault_recall(
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list(self._versors), query_arr, scan_k,
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prebuilt_matrix=matrix,
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)
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key = _versor_key(query_arr)
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exact_indices = self._exact_index.get(key, [])
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if exact_indices:
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exact_matches = [(i, float("inf")) for i in exact_indices]
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seen = set(exact_indices)
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ranked = exact_matches + [(i, score) for i, score in ranked if i not in seen]
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if min_status is not None:
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filtered: list[tuple[int, float]] = []
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for i, score in ranked:
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raw_status = self._metadata[i].get("epistemic_status", "speculative")
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try:
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entry_status = EpistemicStatus(raw_status)
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except ValueError:
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entry_status = EpistemicStatus.SPECULATIVE
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if _status_admits(entry_status, min_status):
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filtered.append((i, score))
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ranked = filtered
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return [
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{
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"versor": self._versors[i],
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"score": float(score),
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"metadata": self._metadata[i],
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"index": i,
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}
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for i, score in ranked[:top_k]
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]
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def recall_batch(
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self,
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queries: np.ndarray,
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top_k: int = 5,
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*,
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min_status: EpistemicStatus | None = None,
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) -> list[list[dict]]:
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"""Recall B queries against the stored versors in one sweep.
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Returns one ``list[dict]`` per query in the same shape ``recall``
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returns. Exact-self-match promotion, ``min_status`` filtering,
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and the descending-score / ascending-index tiebreak rule are
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applied per query — semantics are identical to looping
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``recall(q, top_k=...)`` over each query, but the underlying
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scoring scan is a single component-serial sweep over the
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cached matrix. ADR-0054.
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"""
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Q = np.asarray(queries, dtype=np.float32)
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if Q.ndim == 1:
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Q = Q[None, :]
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if not self._versors or top_k <= 0:
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return [[] for _ in range(Q.shape[0])]
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matrix = self._get_matrix()
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assert matrix is not None # non-empty deque ⇒ matrix is built
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scan_k = max(top_k * 4, top_k) if min_status is not None else max(top_k, 1)
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batch_ranked = vault_recall_batch(matrix, Q, scan_k)
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results: list[list[dict]] = []
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for b, ranked in enumerate(batch_ranked):
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key = _versor_key(Q[b])
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exact_indices = self._exact_index.get(key, [])
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if exact_indices:
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exact_matches = [(i, float("inf")) for i in exact_indices]
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seen = set(exact_indices)
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ranked = exact_matches + [
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(i, score) for i, score in ranked if i not in seen
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]
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if min_status is not None:
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filtered: list[tuple[int, float]] = []
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for i, score in ranked:
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raw_status = self._metadata[i].get(
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"epistemic_status", "speculative",
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)
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try:
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entry_status = EpistemicStatus(raw_status)
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except ValueError:
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entry_status = EpistemicStatus.SPECULATIVE
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if _status_admits(entry_status, min_status):
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filtered.append((i, score))
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ranked = filtered
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results.append([
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{
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"versor": self._versors[i],
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"score": float(score),
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"metadata": self._metadata[i],
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"index": i,
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}
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for i, score in ranked[:top_k]
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])
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return results
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def reproject(self) -> None:
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"""
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Re-project all stored versors onto the null cone.
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Corrects floating-point drift. Run between turns or asynchronously.
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"""
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reprojected = deque((null_project(v) for v in self._versors), maxlen=self._max_entries)
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self._versors = reprojected
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self._rebuild_index()
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def _rebuild_index(self) -> None:
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self._exact_index = {}
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for i, v in enumerate(self._versors):
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key = _versor_key(v)
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self._exact_index.setdefault(key, []).append(i)
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self._matrix_cache = None
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def _get_matrix(self) -> np.ndarray | None:
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"""Return the cached (N, D) f32 stack of stored versors.
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Rebuilds the cache on first call after any mutation. Returns
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None when the vault is empty so callers can branch without
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constructing a 0-row array. ADR-0054.
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"""
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if not self._versors:
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return None
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if self._matrix_cache is None:
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self._matrix_cache = np.asarray(self._versors, dtype=np.float32)
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return self._matrix_cache
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@property
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def reproject_interval(self) -> int:
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return self._reproject_interval
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@property
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def store_count(self) -> int:
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return self._store_count
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@property
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def max_entries(self) -> int | None:
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return self._max_entries
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def __len__(self) -> int:
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return len(self._versors)
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