Old engine for Continuous Time Bayesian Networks. Superseded by reCTBN. 🐍
https://github.com/madlabunimib/PyCTBN
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191 lines
5.8 KiB
191 lines
5.8 KiB
"""
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=========
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Antigraph
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=========
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Complement graph class for small footprint when working on dense graphs.
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This class allows you to add the edges that *do not exist* in the dense
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graph. However, when applying algorithms to this complement graph data
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structure, it behaves as if it were the dense version. So it can be used
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directly in several NetworkX algorithms.
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This subclass has only been tested for k-core, connected_components,
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and biconnected_components algorithms but might also work for other
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algorithms.
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"""
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import networkx as nx
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from networkx.exception import NetworkXError
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import matplotlib.pyplot as plt
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class AntiGraph(nx.Graph):
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"""
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Class for complement graphs.
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The main goal is to be able to work with big and dense graphs with
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a low memory footprint.
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In this class you add the edges that *do not exist* in the dense graph,
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the report methods of the class return the neighbors, the edges and
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the degree as if it was the dense graph. Thus it's possible to use
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an instance of this class with some of NetworkX functions.
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"""
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all_edge_dict = {"weight": 1}
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def single_edge_dict(self):
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return self.all_edge_dict
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edge_attr_dict_factory = single_edge_dict
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def __getitem__(self, n):
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"""Return a dict of neighbors of node n in the dense graph.
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Parameters
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----------
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n : node
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A node in the graph.
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Returns
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-------
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adj_dict : dictionary
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The adjacency dictionary for nodes connected to n.
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"""
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return {
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node: self.all_edge_dict for node in set(self.adj) - set(self.adj[n]) - {n}
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}
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def neighbors(self, n):
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"""Return an iterator over all neighbors of node n in the
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dense graph.
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"""
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try:
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return iter(set(self.adj) - set(self.adj[n]) - {n})
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except KeyError as e:
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raise NetworkXError(f"The node {n} is not in the graph.") from e
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def degree(self, nbunch=None, weight=None):
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"""Return an iterator for (node, degree) in the dense graph.
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The node degree is the number of edges adjacent to the node.
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Parameters
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----------
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nbunch : iterable container, optional (default=all nodes)
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A container of nodes. The container will be iterated
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through once.
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weight : string or None, optional (default=None)
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The edge attribute that holds the numerical value used
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as a weight. If None, then each edge has weight 1.
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The degree is the sum of the edge weights adjacent to the node.
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Returns
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-------
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nd_iter : iterator
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The iterator returns two-tuples of (node, degree).
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See Also
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--------
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degree
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Examples
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--------
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>>> G = nx.path_graph(4) # or DiGraph, MultiGraph, MultiDiGraph, etc
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>>> list(G.degree(0)) # node 0 with degree 1
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[(0, 1)]
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>>> list(G.degree([0, 1]))
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[(0, 1), (1, 2)]
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"""
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if nbunch is None:
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nodes_nbrs = (
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(
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n,
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{
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v: self.all_edge_dict
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for v in set(self.adj) - set(self.adj[n]) - {n}
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},
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)
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for n in self.nodes()
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)
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elif nbunch in self:
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nbrs = set(self.nodes()) - set(self.adj[nbunch]) - {nbunch}
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return len(nbrs)
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else:
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nodes_nbrs = (
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(
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n,
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{
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v: self.all_edge_dict
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for v in set(self.nodes()) - set(self.adj[n]) - {n}
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},
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)
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for n in self.nbunch_iter(nbunch)
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)
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if weight is None:
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return ((n, len(nbrs)) for n, nbrs in nodes_nbrs)
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else:
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# AntiGraph is a ThinGraph so all edges have weight 1
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return (
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(n, sum((nbrs[nbr].get(weight, 1)) for nbr in nbrs))
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for n, nbrs in nodes_nbrs
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)
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def adjacency_iter(self):
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"""Return an iterator of (node, adjacency set) tuples for all nodes
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in the dense graph.
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This is the fastest way to look at every edge.
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For directed graphs, only outgoing adjacencies are included.
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Returns
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-------
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adj_iter : iterator
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An iterator of (node, adjacency set) for all nodes in
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the graph.
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"""
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for n in self.adj:
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yield (n, set(self.adj) - set(self.adj[n]) - {n})
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# Build several pairs of graphs, a regular graph
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# and the AntiGraph of it's complement, which behaves
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# as if it were the original graph.
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Gnp = nx.gnp_random_graph(20, 0.8, seed=42)
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Anp = AntiGraph(nx.complement(Gnp))
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Gd = nx.davis_southern_women_graph()
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Ad = AntiGraph(nx.complement(Gd))
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Gk = nx.karate_club_graph()
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Ak = AntiGraph(nx.complement(Gk))
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pairs = [(Gnp, Anp), (Gd, Ad), (Gk, Ak)]
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# test connected components
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for G, A in pairs:
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gc = [set(c) for c in nx.connected_components(G)]
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ac = [set(c) for c in nx.connected_components(A)]
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for comp in ac:
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assert comp in gc
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# test biconnected components
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for G, A in pairs:
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gc = [set(c) for c in nx.biconnected_components(G)]
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ac = [set(c) for c in nx.biconnected_components(A)]
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for comp in ac:
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assert comp in gc
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# test degree
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for G, A in pairs:
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node = list(G.nodes())[0]
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nodes = list(G.nodes())[1:4]
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assert G.degree(node) == A.degree(node)
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assert sum(d for n, d in G.degree()) == sum(d for n, d in A.degree())
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# AntiGraph is a ThinGraph, so all the weights are 1
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assert sum(d for n, d in A.degree()) == sum(d for n, d in A.degree(weight="weight"))
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assert sum(d for n, d in G.degree(nodes)) == sum(d for n, d in A.degree(nodes))
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nx.draw(Gnp)
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plt.show()
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