444 lines
21 KiB
Python
444 lines
21 KiB
Python
"""
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Graph data model for DNSRecon using NetworkX.
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Manages in-memory graph storage with confidence scoring and forensic metadata.
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"""
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import re
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from datetime import datetime, timezone
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from enum import Enum
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from typing import Dict, List, Any, Optional, Tuple
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import networkx as nx
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class NodeType(Enum):
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"""Enumeration of supported node types."""
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DOMAIN = "domain"
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IP = "ip"
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ASN = "asn"
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LARGE_ENTITY = "large_entity"
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CORRELATION_OBJECT = "correlation_object"
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def __repr__(self):
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return self.value
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class GraphManager:
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"""
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Thread-safe graph manager for DNSRecon infrastructure mapping.
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Uses NetworkX for in-memory graph storage with confidence scoring.
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"""
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def __init__(self):
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"""Initialize empty directed graph."""
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self.graph = nx.DiGraph()
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self.creation_time = datetime.now(timezone.utc).isoformat()
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self.last_modified = self.creation_time
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self.correlation_index = {}
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# Compile regex for date filtering for efficiency
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self.date_pattern = re.compile(r'^\d{4}-\d{2}-\d{2}[ T]\d{2}:\d{2}:\d{2}')
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def __getstate__(self):
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"""Prepare GraphManager for pickling, excluding compiled regex."""
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state = self.__dict__.copy()
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# Compiled regex patterns are not always picklable
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if 'date_pattern' in state:
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del state['date_pattern']
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return state
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def __setstate__(self, state):
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"""Restore GraphManager state and recompile regex."""
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self.__dict__.update(state)
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self.date_pattern = re.compile(r'^\d{4}-\d{2}-\d{2}[ T]\d{2}:\d{2}:\d{2}')
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def _update_correlation_index(self, node_id: str, data: Any, path: List[str] = []):
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"""Recursively traverse metadata and add hashable values to the index."""
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if path is None:
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path = []
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if isinstance(data, dict):
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for key, value in data.items():
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self._update_correlation_index(node_id, value, path + [key])
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elif isinstance(data, list):
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for i, item in enumerate(data):
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self._update_correlation_index(node_id, item, path + [f"[{i}]"])
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else:
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self._add_to_correlation_index(node_id, data, ".".join(path))
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def _add_to_correlation_index(self, node_id: str, value: Any, path_str: str):
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"""Add a hashable value to the correlation index, filtering out noise."""
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if not isinstance(value, (str, int, float, bool)) or value is None:
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return
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# Ignore certain paths that contain noisy, non-unique identifiers
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if any(keyword in path_str.lower() for keyword in ['count', 'total', 'timestamp', 'date']):
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return
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# Filter out common low-entropy values and date-like strings
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if isinstance(value, str):
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# FIXED: Prevent correlation on date/time strings.
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if self.date_pattern.match(value):
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return
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if len(value) < 4 or value.lower() in ['true', 'false', 'unknown', 'none', 'crt.sh']:
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return
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elif isinstance(value, int) and (abs(value) < 1024 or abs(value) > 65535):
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return # Ignore small integers and common port numbers
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elif isinstance(value, bool):
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return # Ignore boolean values
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# Add the valuable correlation data to the index
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if value not in self.correlation_index:
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self.correlation_index[value] = {}
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if node_id not in self.correlation_index[value]:
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self.correlation_index[value][node_id] = []
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if path_str not in self.correlation_index[value][node_id]:
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self.correlation_index[value][node_id].append(path_str)
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def _check_for_correlations(self, new_node_id: str, data: Any, path: List[str] = []) -> List[Dict]:
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"""Recursively traverse metadata to find correlations with existing data."""
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if path is None:
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path = []
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all_correlations = []
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if isinstance(data, dict):
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for key, value in data.items():
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if key == 'source': # Avoid correlating on the provider name
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continue
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all_correlations.extend(self._check_for_correlations(new_node_id, value, path + [key]))
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elif isinstance(data, list):
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for i, item in enumerate(data):
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all_correlations.extend(self._check_for_correlations(new_node_id, item, path + [f"[{i}]"]))
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else:
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value = data
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if value in self.correlation_index:
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existing_nodes_with_paths = self.correlation_index[value]
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unique_nodes = set(existing_nodes_with_paths.keys())
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unique_nodes.add(new_node_id)
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if len(unique_nodes) < 2:
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return all_correlations # Correlation must involve at least two distinct nodes
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new_source = {'node_id': new_node_id, 'path': ".".join(path)}
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all_sources = [new_source]
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for node_id, paths in existing_nodes_with_paths.items():
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for p_str in paths:
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all_sources.append({'node_id': node_id, 'path': p_str})
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all_correlations.append({
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'value': value,
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'sources': all_sources,
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'nodes': list(unique_nodes)
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})
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return all_correlations
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def add_node(self, node_id: str, node_type: NodeType, attributes: Optional[Dict[str, Any]] = None,
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description: str = "", metadata: Optional[Dict[str, Any]] = None) -> bool:
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"""Add a node to the graph, update attributes, and process correlations."""
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is_new_node = not self.graph.has_node(node_id)
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if is_new_node:
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self.graph.add_node(node_id, type=node_type.value,
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added_timestamp=datetime.now(timezone.utc).isoformat(),
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attributes=attributes or {},
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description=description,
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metadata=metadata or {})
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else:
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# Safely merge new attributes into existing attributes
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if attributes:
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existing_attributes = self.graph.nodes[node_id].get('attributes', {})
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existing_attributes.update(attributes)
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self.graph.nodes[node_id]['attributes'] = existing_attributes
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if description:
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self.graph.nodes[node_id]['description'] = description
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if metadata:
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existing_metadata = self.graph.nodes[node_id].get('metadata', {})
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existing_metadata.update(metadata)
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self.graph.nodes[node_id]['metadata'] = existing_metadata
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if attributes and node_type != NodeType.CORRELATION_OBJECT:
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correlations = self._check_for_correlations(node_id, attributes)
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for corr in correlations:
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value = corr['value']
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# STEP 1: Substring check against all existing nodes
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if self._correlation_value_matches_existing_node(value):
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# Skip creating correlation node - would be redundant
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continue
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# *** CHANGE START ***
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# The overly aggressive filtering logic has been removed.
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# All nodes involved in the correlation will now be used.
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eligible_nodes = set(corr['nodes'])
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# *** CHANGE END ***
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if len(eligible_nodes) < 2:
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# Need at least 2 nodes to create a correlation
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continue
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# STEP 3: Check for existing correlation node with same connection pattern
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correlation_nodes_with_pattern = self._find_correlation_nodes_with_same_pattern(eligible_nodes)
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if correlation_nodes_with_pattern:
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# STEP 4: Merge with existing correlation node
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target_correlation_node = correlation_nodes_with_pattern[0]
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self._merge_correlation_values(target_correlation_node, value, corr)
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else:
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# STEP 5: Create new correlation node for eligible nodes only
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correlation_node_id = f"corr_{abs(hash(str(sorted(eligible_nodes))))}"
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self.add_node(correlation_node_id, NodeType.CORRELATION_OBJECT,
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metadata={'values': [value], 'sources': corr['sources'],
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'correlated_nodes': list(eligible_nodes)})
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# Create edges from eligible nodes to this correlation node
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for c_node_id in eligible_nodes:
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if self.graph.has_node(c_node_id):
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attribute = corr['sources'][0]['path'].split('.')[-1]
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relationship_type = f"c_{attribute}"
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self.add_edge(c_node_id, correlation_node_id, relationship_type, confidence_score=0.9)
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self._update_correlation_index(node_id, attributes)
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self.last_modified = datetime.now(timezone.utc).isoformat()
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return is_new_node
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# *** CHANGE START ***
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# The following function is no longer needed and has been removed to avoid confusion.
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# def _filter_nodes_without_direct_edges(self, node_set: set) -> set:
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# *** CHANGE END ***
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def _has_direct_edge_bidirectional(self, node_a: str, node_b: str) -> bool:
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"""
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Check if there's a direct edge between two nodes in either direction.
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Returns True if node_a→node_b OR node_b→node_a exists.
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"""
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return (self.graph.has_edge(node_a, node_b) or
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self.graph.has_edge(node_b, node_a))
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def _correlation_value_matches_existing_node(self, correlation_value: str) -> bool:
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"""
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Check if correlation value contains any existing node ID as substring.
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Returns True if match found (correlation node should NOT be created).
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"""
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correlation_str = str(correlation_value).lower()
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# Check against all existing nodes
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for existing_node_id in self.graph.nodes():
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if existing_node_id.lower() in correlation_str:
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return True
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return False
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def _find_correlation_nodes_with_same_pattern(self, node_set: set) -> List[str]:
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"""
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Find existing correlation nodes that have the exact same pattern of connected nodes.
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Returns list of correlation node IDs with matching patterns.
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"""
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correlation_nodes = self.get_nodes_by_type(NodeType.CORRELATION_OBJECT)
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matching_nodes = []
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for corr_node_id in correlation_nodes:
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# Get all nodes connected to this correlation node
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connected_nodes = set()
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# Add all predecessors (nodes pointing TO the correlation node)
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connected_nodes.update(self.graph.predecessors(corr_node_id))
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# Add all successors (nodes pointed TO by the correlation node)
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connected_nodes.update(self.graph.successors(corr_node_id))
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# Check if the pattern matches exactly
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if connected_nodes == node_set:
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matching_nodes.append(corr_node_id)
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return matching_nodes
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def _merge_correlation_values(self, target_node_id: str, new_value: Any, corr_data: Dict) -> None:
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"""
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Merge a new correlation value into an existing correlation node.
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Uses same logic as large entity merging.
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"""
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if not self.graph.has_node(target_node_id):
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return
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target_metadata = self.graph.nodes[target_node_id]['metadata']
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# Get existing values (ensure it's a list)
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existing_values = target_metadata.get('values', [])
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if not isinstance(existing_values, list):
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existing_values = [existing_values]
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# Add new value if not already present
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if new_value not in existing_values:
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existing_values.append(new_value)
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# Merge sources
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existing_sources = target_metadata.get('sources', [])
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new_sources = corr_data.get('sources', [])
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# Create set of unique sources based on (node_id, path) tuples
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source_set = set()
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for source in existing_sources + new_sources:
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source_tuple = (source['node_id'], source['path'])
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source_set.add(source_tuple)
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# Convert back to list of dictionaries
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merged_sources = [{'node_id': nid, 'path': path} for nid, path in source_set]
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# Update metadata
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target_metadata.update({
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'values': existing_values,
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'sources': merged_sources,
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'correlated_nodes': list(set(target_metadata.get('correlated_nodes', []) + corr_data.get('nodes', []))),
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'merge_count': len(existing_values),
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'last_merge_timestamp': datetime.now(timezone.utc).isoformat()
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})
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# Update description to reflect merged nature
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value_count = len(existing_values)
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node_count = len(target_metadata['correlated_nodes'])
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self.graph.nodes[target_node_id]['description'] = (
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f"Correlation container with {value_count} merged values "
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f"across {node_count} nodes"
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)
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def add_edge(self, source_id: str, target_id: str, relationship_type: str,
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confidence_score: float = 0.5, source_provider: str = "unknown",
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raw_data: Optional[Dict[str, Any]] = None) -> bool:
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"""Add or update an edge between two nodes, ensuring nodes exist."""
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if not self.graph.has_node(source_id) or not self.graph.has_node(target_id):
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return False
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new_confidence = confidence_score
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if relationship_type.startswith("c_"):
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edge_label = relationship_type
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else:
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edge_label = f"{source_provider}_{relationship_type}"
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if self.graph.has_edge(source_id, target_id):
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# If edge exists, update confidence if the new score is higher.
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if new_confidence > self.graph.edges[source_id, target_id].get('confidence_score', 0):
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self.graph.edges[source_id, target_id]['confidence_score'] = new_confidence
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self.graph.edges[source_id, target_id]['updated_timestamp'] = datetime.now(timezone.utc).isoformat()
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self.graph.edges[source_id, target_id]['updated_by'] = source_provider
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return False
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# Add a new edge with all attributes.
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self.graph.add_edge(source_id, target_id,
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relationship_type=edge_label,
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confidence_score=new_confidence,
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source_provider=source_provider,
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discovery_timestamp=datetime.now(timezone.utc).isoformat(),
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raw_data=raw_data or {})
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self.last_modified = datetime.now(timezone.utc).isoformat()
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return True
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def get_node_count(self) -> int:
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"""Get total number of nodes in the graph."""
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return self.graph.number_of_nodes()
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def get_edge_count(self) -> int:
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"""Get total number of edges in the graph."""
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return self.graph.number_of_edges()
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def get_nodes_by_type(self, node_type: NodeType) -> List[str]:
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"""Get all nodes of a specific type."""
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return [n for n, d in self.graph.nodes(data=True) if d.get('type') == node_type.value]
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def get_neighbors(self, node_id: str) -> List[str]:
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"""Get all unique neighbors (predecessors and successors) for a node."""
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if not self.graph.has_node(node_id):
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return []
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return list(set(self.graph.predecessors(node_id)) | set(self.graph.successors(node_id)))
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def get_high_confidence_edges(self, min_confidence: float = 0.8) -> List[Tuple[str, str, Dict]]:
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"""Get edges with confidence score above a given threshold."""
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return [(u, v, d) for u, v, d in self.graph.edges(data=True)
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if d.get('confidence_score', 0) >= min_confidence]
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def get_graph_data(self) -> Dict[str, Any]:
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"""Export graph data formatted for frontend visualization."""
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nodes = []
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for node_id, attrs in self.graph.nodes(data=True):
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node_data = {'id': node_id, 'label': node_id, 'type': attrs.get('type', 'unknown'),
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'attributes': attrs.get('attributes', {}),
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'description': attrs.get('description', ''),
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'metadata': attrs.get('metadata', {}),
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'added_timestamp': attrs.get('added_timestamp')}
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# Customize node appearance based on type and attributes
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node_type = node_data['type']
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attributes = node_data['attributes']
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if node_type == 'domain' and attributes.get('certificates', {}).get('has_valid_cert') is False:
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node_data['color'] = {'background': '#c7c7c7', 'border': '#999'} # Gray for invalid cert
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# Add incoming and outgoing edges to node data
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if self.graph.has_node(node_id):
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node_data['incoming_edges'] = [{'from': u, 'data': d} for u, _, d in self.graph.in_edges(node_id, data=True)]
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node_data['outgoing_edges'] = [{'to': v, 'data': d} for _, v, d in self.graph.out_edges(node_id, data=True)]
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nodes.append(node_data)
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edges = []
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for source, target, attrs in self.graph.edges(data=True):
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edges.append({'from': source, 'to': target,
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'label': attrs.get('relationship_type', ''),
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'confidence_score': attrs.get('confidence_score', 0),
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'source_provider': attrs.get('source_provider', ''),
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'discovery_timestamp': attrs.get('discovery_timestamp')})
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return {
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'nodes': nodes, 'edges': edges,
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'statistics': self.get_statistics()['basic_metrics']
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}
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def export_json(self) -> Dict[str, Any]:
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"""Export complete graph data as a JSON-serializable dictionary."""
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graph_data = nx.node_link_data(self.graph) # Use NetworkX's built-in robust serializer
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return {
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'export_metadata': {
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'export_timestamp': datetime.now(timezone.utc).isoformat(),
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'graph_creation_time': self.creation_time,
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'last_modified': self.last_modified,
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'total_nodes': self.get_node_count(),
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'total_edges': self.get_edge_count(),
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'graph_format': 'dnsrecon_v1_nodeling'
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},
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'graph': graph_data,
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'statistics': self.get_statistics()
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}
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def _get_confidence_distribution(self) -> Dict[str, int]:
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"""Get distribution of edge confidence scores."""
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distribution = {'high': 0, 'medium': 0, 'low': 0}
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for _, _, data in self.graph.edges(data=True):
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confidence = data.get('confidence_score', 0)
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if confidence >= 0.8:
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distribution['high'] += 1
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elif confidence >= 0.6:
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distribution['medium'] += 1
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else:
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distribution['low'] += 1
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return distribution
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def get_statistics(self) -> Dict[str, Any]:
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"""Get comprehensive statistics about the graph."""
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stats = {'basic_metrics': {'total_nodes': self.get_node_count(),
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'total_edges': self.get_edge_count(),
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'creation_time': self.creation_time,
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'last_modified': self.last_modified},
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'node_type_distribution': {}, 'relationship_type_distribution': {},
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'confidence_distribution': self._get_confidence_distribution(),
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'provider_distribution': {}}
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# Calculate distributions
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for node_type in NodeType:
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stats['node_type_distribution'][node_type.value] = self.get_nodes_by_type(node_type).__len__()
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for _, _, data in self.graph.edges(data=True):
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rel_type = data.get('relationship_type', 'unknown')
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stats['relationship_type_distribution'][rel_type] = stats['relationship_type_distribution'].get(rel_type, 0) + 1
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provider = data.get('source_provider', 'unknown')
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stats['provider_distribution'][provider] = stats['provider_distribution'].get(provider, 0) + 1
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return stats
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def clear(self) -> None:
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"""Clear all nodes, edges, and indices from the graph."""
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self.graph.clear()
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self.correlation_index.clear()
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self.creation_time = datetime.now(timezone.utc).isoformat()
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self.last_modified = self.creation_time |