build(agent): new-agents#a6e6ec iteration
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@ -114,3 +114,62 @@ class TraceGraph:
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next_level.append(hashlib.sha256((left + right).encode()).hexdigest())
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next_level.append(hashlib.sha256((left + right).encode()).hexdigest())
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level = next_level
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level = next_level
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return level[0]
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return level[0]
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def merkle_proof(self, index: int) -> List[Dict[str, str]]:
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"""Compute a Merkle-like proof for the node at the given index.
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This returns a list of dicts, each describing the sibling hash at a
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particular tree level required to recompute the Merkle root. Each entry
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has:
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- direction: 'left' or 'right' indicating the position of the sibling
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- hash: the hexadecimal digest of the sibling node at that level
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Note: This is a lightweight, deterministic proof suitable for auditing
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provenance in MVP deployments. It relies on a fixed leaf ordering (the
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order of self.nodes) and a deterministic leaf hashing similar to merkle_root.
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"""
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import hashlib
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import json
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def _canonicalize(obj: object) -> Dict[str, object]:
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if hasattr(obj, "__dict__"):
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data = getattr(obj, "__dict__")
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return {k: v for k, v in data.items()}
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return {"repr": str(obj)}
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if index < 0 or index >= len(self.nodes):
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raise IndexError("index out of range for merkle_proof")
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# Build leaf hashes from canonicalized node representations
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leaves: List[str] = []
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for n in self.nodes:
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canon = _canonicalize(n)
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serialized = json.dumps(canon, sort_keys=True, separators=(",", ":"))
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leaves.append(hashlib.sha256(serialized.encode()).hexdigest())
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proof: List[Dict[str, str]] = []
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idx = index
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level = leaves
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while len(level) > 1:
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# Sibling hash for the current index
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if idx % 2 == 0:
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sib_index = idx + 1
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direction = "right"
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else:
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sib_index = idx - 1
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direction = "left"
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if sib_index < len(level):
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proof.append({"direction": direction, "hash": level[sib_index]})
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else:
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# If no true sibling (odd last item), replicate the node itself
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proof.append({"direction": direction, "hash": level[idx]})
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# Compute next level
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next_level: List[str] = []
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for i in range(0, len(level), 2):
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left = level[i]
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right = level[i + 1] if i + 1 < len(level) else level[i]
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next_level.append(hashlib.sha256((left + right).encode()).hexdigest())
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level = next_level
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idx = idx // 2
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return proof
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