""" Graph summarization finds smaller representations of graphs resulting in faster runtime of algorithms, reduced storage needs, and noise reduction. Summarization has applications in areas such as visualization, pattern mining, clustering and community detection, and more. Core graph summarization techniques are grouping/aggregation, bit-compression, simplification/sparsification, and influence based. Graph summarization algorithms often produce either summary graphs in the form of supergraphs or sparsified graphs, or a list of independent structures. Supergraphs are the most common product, which consist of supernodes and original nodes and are connected by edges and superedges, which represent aggregate edges between nodes and supernodes. Grouping/aggregation based techniques compress graphs by representing close/connected nodes and edges in a graph by a single node/edge in a supergraph. Nodes can be grouped together into supernodes based on their structural similarities or proximity within a graph to reduce the total number of nodes in a graph. Edge-grouping techniques group edges into lossy/lossless nodes called compressor or virtual nodes to reduce the total number of edges in a graph. Edge-grouping techniques can be lossless, meaning that they can be used to re-create the original graph, or techniques can be lossy, requiring less space to store the summary graph, but at the expense of lower reconstruction accuracy of the original graph. Bit-compression techniques minimize the amount of information needed to describe the original graph, while revealing structural patterns in the original graph. The two-part minimum description length (MDL) is often used to represent the model and the original graph in terms of the model. A key difference between graph compression and graph summarization is that graph summarization focuses on finding structural patterns within the original graph, whereas graph compression focuses on compressions the original graph to be as small as possible. **NOTE**: Some bit-compression methods exist solely to compress a graph without creating a summary graph or finding comprehensible structural patterns. Simplification/Sparsification techniques attempt to create a sparse representation of a graph by removing unimportant nodes and edges from the graph. Sparsified graphs differ from supergraphs created by grouping/aggregation by only containing a subset of the original nodes and edges of the original graph. Influence based techniques aim to find a high-level description of influence propagation in a large graph. These methods are scarce and have been mostly applied to social graphs. *dedensification* is a grouping/aggregation based technique to compress the neighborhoods around high-degree nodes in unweighted graphs by adding compressor nodes that summarize multiple edges of the same type to high-degree nodes (nodes with a degree greater than a given threshold). Dedensification was developed for the purpose of increasing performance of query processing around high-degree nodes in graph databases and enables direct operations on the compressed graph. The structural patterns surrounding high-degree nodes in the original is preserved while using fewer edges and adding a small number of compressor nodes. The degree of nodes present in the original graph is also preserved. The current implementation of dedensification supports graphs with one edge type. For more information on graph summarization, see `Graph Summarization Methods and Applications: A Survey `_ """ from collections import Counter, defaultdict import networkx as nx __all__ = ["dedensify", "snap_aggregation"] @nx._dispatch def dedensify(G, threshold, prefix=None, copy=True): """Compresses neighborhoods around high-degree nodes Reduces the number of edges to high-degree nodes by adding compressor nodes that summarize multiple edges of the same type to high-degree nodes (nodes with a degree greater than a given threshold). Dedensification also has the added benefit of reducing the number of edges around high-degree nodes. The implementation currently supports graphs with a single edge type. Parameters ---------- G: graph A networkx graph threshold: int Minimum degree threshold of a node to be considered a high degree node. The threshold must be greater than or equal to 2. prefix: str or None, optional (default: None) An optional prefix for denoting compressor nodes copy: bool, optional (default: True) Indicates if dedensification should be done inplace Returns ------- dedensified networkx graph : (graph, set) 2-tuple of the dedensified graph and set of compressor nodes Notes ----- According to the algorithm in [1]_, removes edges in a graph by compressing/decompressing the neighborhoods around high degree nodes by adding compressor nodes that summarize multiple edges of the same type to high-degree nodes. Dedensification will only add a compressor node when doing so will reduce the total number of edges in the given graph. This implementation currently supports graphs with a single edge type. Examples -------- Dedensification will only add compressor nodes when doing so would result in fewer edges:: >>> original_graph = nx.DiGraph() >>> original_graph.add_nodes_from( ... ["1", "2", "3", "4", "5", "6", "A", "B", "C"] ... ) >>> original_graph.add_edges_from( ... [ ... ("1", "C"), ("1", "B"), ... ("2", "C"), ("2", "B"), ("2", "A"), ... ("3", "B"), ("3", "A"), ("3", "6"), ... ("4", "C"), ("4", "B"), ("4", "A"), ... ("5", "B"), ("5", "A"), ... ("6", "5"), ... ("A", "6") ... ] ... ) >>> c_graph, c_nodes = nx.dedensify(original_graph, threshold=2) >>> original_graph.number_of_edges() 15 >>> c_graph.number_of_edges() 14 A dedensified, directed graph can be "densified" to reconstruct the original graph:: >>> original_graph = nx.DiGraph() >>> original_graph.add_nodes_from( ... ["1", "2", "3", "4", "5", "6", "A", "B", "C"] ... ) >>> original_graph.add_edges_from( ... [ ... ("1", "C"), ("1", "B"), ... ("2", "C"), ("2", "B"), ("2", "A"), ... ("3", "B"), ("3", "A"), ("3", "6"), ... ("4", "C"), ("4", "B"), ("4", "A"), ... ("5", "B"), ("5", "A"), ... ("6", "5"), ... ("A", "6") ... ] ... ) >>> c_graph, c_nodes = nx.dedensify(original_graph, threshold=2) >>> # re-densifies the compressed graph into the original graph >>> for c_node in c_nodes: ... all_neighbors = set(nx.all_neighbors(c_graph, c_node)) ... out_neighbors = set(c_graph.neighbors(c_node)) ... for out_neighbor in out_neighbors: ... c_graph.remove_edge(c_node, out_neighbor) ... in_neighbors = all_neighbors - out_neighbors ... for in_neighbor in in_neighbors: ... c_graph.remove_edge(in_neighbor, c_node) ... for out_neighbor in out_neighbors: ... c_graph.add_edge(in_neighbor, out_neighbor) ... c_graph.remove_node(c_node) ... >>> nx.is_isomorphic(original_graph, c_graph) True References ---------- .. [1] Maccioni, A., & Abadi, D. J. (2016, August). Scalable pattern matching over compressed graphs via dedensification. In Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining (pp. 1755-1764). http://www.cs.umd.edu/~abadi/papers/graph-dedense.pdf """ if threshold < 2: raise nx.NetworkXError("The degree threshold must be >= 2") degrees = G.in_degree if G.is_directed() else G.degree # Group nodes based on degree threshold high_degree_nodes = {n for n, d in degrees if d > threshold} low_degree_nodes = G.nodes() - high_degree_nodes auxiliary = {} for node in G: high_degree_neighbors = frozenset(high_degree_nodes & set(G[node])) if high_degree_neighbors: if high_degree_neighbors in auxiliary: auxiliary[high_degree_neighbors].add(node) else: auxiliary[high_degree_neighbors] = {node} if copy: G = G.copy() compressor_nodes = set() for index, (high_degree_nodes, low_degree_nodes) in enumerate(auxiliary.items()): low_degree_node_count = len(low_degree_nodes) high_degree_node_count = len(high_degree_nodes) old_edges = high_degree_node_count * low_degree_node_count new_edges = high_degree_node_count + low_degree_node_count if old_edges <= new_edges: continue compression_node = "".join(str(node) for node in high_degree_nodes) if prefix: compression_node = str(prefix) + compression_node for node in low_degree_nodes: for high_node in high_degree_nodes: if G.has_edge(node, high_node): G.remove_edge(node, high_node) G.add_edge(node, compression_node) for node in high_degree_nodes: G.add_edge(compression_node, node) compressor_nodes.add(compression_node) return G, compressor_nodes def _snap_build_graph( G, groups, node_attributes, edge_attributes, neighbor_info, edge_types, prefix, supernode_attribute, superedge_attribute, ): """ Build the summary graph from the data structures produced in the SNAP aggregation algorithm Used in the SNAP aggregation algorithm to build the output summary graph and supernode lookup dictionary. This process uses the original graph and the data structures to create the supernodes with the correct node attributes, and the superedges with the correct edge attributes Parameters ---------- G: networkx.Graph the original graph to be summarized groups: dict A dictionary of unique group IDs and their corresponding node groups node_attributes: iterable An iterable of the node attributes considered in the summarization process edge_attributes: iterable An iterable of the edge attributes considered in the summarization process neighbor_info: dict A data structure indicating the number of edges a node has with the groups in the current summarization of each edge type edge_types: dict dictionary of edges in the graph and their corresponding attributes recognized in the summarization prefix: string The prefix to be added to all supernodes supernode_attribute: str The node attribute for recording the supernode groupings of nodes superedge_attribute: str The edge attribute for recording the edge types represented by superedges Returns ------- summary graph: Networkx graph """ output = G.__class__() node_label_lookup = {} for index, group_id in enumerate(groups): group_set = groups[group_id] supernode = f"{prefix}{index}" node_label_lookup[group_id] = supernode supernode_attributes = { attr: G.nodes[next(iter(group_set))][attr] for attr in node_attributes } supernode_attributes[supernode_attribute] = group_set output.add_node(supernode, **supernode_attributes) for group_id in groups: group_set = groups[group_id] source_supernode = node_label_lookup[group_id] for other_group, group_edge_types in neighbor_info[ next(iter(group_set)) ].items(): if group_edge_types: target_supernode = node_label_lookup[other_group] summary_graph_edge = (source_supernode, target_supernode) edge_types = [ dict(zip(edge_attributes, edge_type)) for edge_type in group_edge_types ] has_edge = output.has_edge(*summary_graph_edge) if output.is_multigraph(): if not has_edge: for edge_type in edge_types: output.add_edge(*summary_graph_edge, **edge_type) elif not output.is_directed(): existing_edge_data = output.get_edge_data(*summary_graph_edge) for edge_type in edge_types: if edge_type not in existing_edge_data.values(): output.add_edge(*summary_graph_edge, **edge_type) else: superedge_attributes = {superedge_attribute: edge_types} output.add_edge(*summary_graph_edge, **superedge_attributes) return output def _snap_eligible_group(G, groups, group_lookup, edge_types): """ Determines if a group is eligible to be split. A group is eligible to be split if all nodes in the group have edges of the same type(s) with the same other groups. Parameters ---------- G: graph graph to be summarized groups: dict A dictionary of unique group IDs and their corresponding node groups group_lookup: dict dictionary of nodes and their current corresponding group ID edge_types: dict dictionary of edges in the graph and their corresponding attributes recognized in the summarization Returns ------- tuple: group ID to split, and neighbor-groups participation_counts data structure """ neighbor_info = {node: {gid: Counter() for gid in groups} for node in group_lookup} for group_id in groups: current_group = groups[group_id] # build neighbor_info for nodes in group for node in current_group: neighbor_info[node] = {group_id: Counter() for group_id in groups} edges = G.edges(node, keys=True) if G.is_multigraph() else G.edges(node) for edge in edges: neighbor = edge[1] edge_type = edge_types[edge] neighbor_group_id = group_lookup[neighbor] neighbor_info[node][neighbor_group_id][edge_type] += 1 # check if group_id is eligible to be split group_size = len(current_group) for other_group_id in groups: edge_counts = Counter() for node in current_group: edge_counts.update(neighbor_info[node][other_group_id].keys()) if not all(count == group_size for count in edge_counts.values()): # only the neighbor_info of the returned group_id is required for handling group splits return group_id, neighbor_info # if no eligible groups, complete neighbor_info is calculated return None, neighbor_info def _snap_split(groups, neighbor_info, group_lookup, group_id): """ Splits a group based on edge types and updates the groups accordingly Splits the group with the given group_id based on the edge types of the nodes so that each new grouping will all have the same edges with other nodes. Parameters ---------- groups: dict A dictionary of unique group IDs and their corresponding node groups neighbor_info: dict A data structure indicating the number of edges a node has with the groups in the current summarization of each edge type edge_types: dict dictionary of edges in the graph and their corresponding attributes recognized in the summarization group_lookup: dict dictionary of nodes and their current corresponding group ID group_id: object ID of group to be split Returns ------- dict The updated groups based on the split """ new_group_mappings = defaultdict(set) for node in groups[group_id]: signature = tuple( frozenset(edge_types) for edge_types in neighbor_info[node].values() ) new_group_mappings[signature].add(node) # leave the biggest new_group as the original group new_groups = sorted(new_group_mappings.values(), key=len) for new_group in new_groups[:-1]: # Assign unused integer as the new_group_id # ids are tuples, so will not interact with the original group_ids new_group_id = len(groups) groups[new_group_id] = new_group groups[group_id] -= new_group for node in new_group: group_lookup[node] = new_group_id return groups @nx._dispatch(node_attrs="[node_attributes]", edge_attrs="[edge_attributes]") def snap_aggregation( G, node_attributes, edge_attributes=(), prefix="Supernode-", supernode_attribute="group", superedge_attribute="types", ): """Creates a summary graph based on attributes and connectivity. This function uses the Summarization by Grouping Nodes on Attributes and Pairwise edges (SNAP) algorithm for summarizing a given graph by grouping nodes by node attributes and their edge attributes into supernodes in a summary graph. This name SNAP should not be confused with the Stanford Network Analysis Project (SNAP). Here is a high-level view of how this algorithm works: 1) Group nodes by node attribute values. 2) Iteratively split groups until all nodes in each group have edges to nodes in the same groups. That is, until all the groups are homogeneous in their member nodes' edges to other groups. For example, if all the nodes in group A only have edge to nodes in group B, then the group is homogeneous and does not need to be split. If all nodes in group B have edges with nodes in groups {A, C}, but some also have edges with other nodes in B, then group B is not homogeneous and needs to be split into groups have edges with {A, C} and a group of nodes having edges with {A, B, C}. This way, viewers of the summary graph can assume that all nodes in the group have the exact same node attributes and the exact same edges. 3) Build the output summary graph, where the groups are represented by super-nodes. Edges represent the edges shared between all the nodes in each respective groups. A SNAP summary graph can be used to visualize graphs that are too large to display or visually analyze, or to efficiently identify sets of similar nodes with similar connectivity patterns to other sets of similar nodes based on specified node and/or edge attributes in a graph. Parameters ---------- G: graph Networkx Graph to be summarized node_attributes: iterable, required An iterable of the node attributes used to group nodes in the summarization process. Nodes with the same values for these attributes will be grouped together in the summary graph. edge_attributes: iterable, optional An iterable of the edge attributes considered in the summarization process. If provided, unique combinations of the attribute values found in the graph are used to determine the edge types in the graph. If not provided, all edges are considered to be of the same type. prefix: str The prefix used to denote supernodes in the summary graph. Defaults to 'Supernode-'. supernode_attribute: str The node attribute for recording the supernode groupings of nodes. Defaults to 'group'. superedge_attribute: str The edge attribute for recording the edge types of multiple edges. Defaults to 'types'. Returns ------- networkx.Graph: summary graph Examples -------- SNAP aggregation takes a graph and summarizes it in the context of user-provided node and edge attributes such that a viewer can more easily extract and analyze the information represented by the graph >>> nodes = { ... "A": dict(color="Red"), ... "B": dict(color="Red"), ... "C": dict(color="Red"), ... "D": dict(color="Red"), ... "E": dict(color="Blue"), ... "F": dict(color="Blue"), ... } >>> edges = [ ... ("A", "E", "Strong"), ... ("B", "F", "Strong"), ... ("C", "E", "Weak"), ... ("D", "F", "Weak"), ... ] >>> G = nx.Graph() >>> for node in nodes: ... attributes = nodes[node] ... G.add_node(node, **attributes) ... >>> for source, target, type in edges: ... G.add_edge(source, target, type=type) ... >>> node_attributes = ('color', ) >>> edge_attributes = ('type', ) >>> summary_graph = nx.snap_aggregation(G, node_attributes=node_attributes, edge_attributes=edge_attributes) Notes ----- The summary graph produced is called a maximum Attribute-edge compatible (AR-compatible) grouping. According to [1]_, an AR-compatible grouping means that all nodes in each group have the same exact node attribute values and the same exact edges and edge types to one or more nodes in the same groups. The maximal AR-compatible grouping is the grouping with the minimal cardinality. The AR-compatible grouping is the most detailed grouping provided by any of the SNAP algorithms. References ---------- .. [1] Y. Tian, R. A. Hankins, and J. M. Patel. Efficient aggregation for graph summarization. In Proc. 2008 ACM-SIGMOD Int. Conf. Management of Data (SIGMOD’08), pages 567–580, Vancouver, Canada, June 2008. """ edge_types = { edge: tuple(attrs.get(attr) for attr in edge_attributes) for edge, attrs in G.edges.items() } if not G.is_directed(): if G.is_multigraph(): # list is needed to avoid mutating while iterating edges = [((v, u, k), etype) for (u, v, k), etype in edge_types.items()] else: # list is needed to avoid mutating while iterating edges = [((v, u), etype) for (u, v), etype in edge_types.items()] edge_types.update(edges) group_lookup = { node: tuple(attrs[attr] for attr in node_attributes) for node, attrs in G.nodes.items() } groups = defaultdict(set) for node, node_type in group_lookup.items(): groups[node_type].add(node) eligible_group_id, neighbor_info = _snap_eligible_group( G, groups, group_lookup, edge_types ) while eligible_group_id: groups = _snap_split(groups, neighbor_info, group_lookup, eligible_group_id) eligible_group_id, neighbor_info = _snap_eligible_group( G, groups, group_lookup, edge_types ) return _snap_build_graph( G, groups, node_attributes, edge_attributes, neighbor_info, edge_types, prefix, supernode_attribute, superedge_attribute, )