392 lines
13 KiB
Python
392 lines
13 KiB
Python
"""Betweenness centrality measures."""
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from heapq import heappush, heappop
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from itertools import count
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import warnings
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from networkx.utils import py_random_state
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from networkx.utils.decorators import not_implemented_for
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__all__ = ["betweenness_centrality", "edge_betweenness_centrality", "edge_betweenness"]
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@py_random_state(5)
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@not_implemented_for("multigraph")
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def betweenness_centrality(
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G, k=None, normalized=True, weight=None, endpoints=False, seed=None
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):
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r"""Compute the shortest-path betweenness centrality for nodes.
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Betweenness centrality of a node $v$ is the sum of the
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fraction of all-pairs shortest paths that pass through $v$
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.. math::
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c_B(v) =\sum_{s,t \in V} \frac{\sigma(s, t|v)}{\sigma(s, t)}
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where $V$ is the set of nodes, $\sigma(s, t)$ is the number of
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shortest $(s, t)$-paths, and $\sigma(s, t|v)$ is the number of
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those paths passing through some node $v$ other than $s, t$.
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If $s = t$, $\sigma(s, t) = 1$, and if $v \in {s, t}$,
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$\sigma(s, t|v) = 0$ [2]_.
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Parameters
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----------
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G : graph
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A NetworkX graph.
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k : int, optional (default=None)
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If k is not None use k node samples to estimate betweenness.
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The value of k <= n where n is the number of nodes in the graph.
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Higher values give better approximation.
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normalized : bool, optional
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If True the betweenness values are normalized by `2/((n-1)(n-2))`
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for graphs, and `1/((n-1)(n-2))` for directed graphs where `n`
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is the number of nodes in G.
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weight : None or string, optional (default=None)
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If None, all edge weights are considered equal.
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Otherwise holds the name of the edge attribute used as weight.
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endpoints : bool, optional
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If True include the endpoints in the shortest path counts.
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seed : integer, random_state, or None (default)
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Indicator of random number generation state.
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See :ref:`Randomness<randomness>`.
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Note that this is only used if k is not None.
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Returns
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-------
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nodes : dictionary
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Dictionary of nodes with betweenness centrality as the value.
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See Also
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--------
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edge_betweenness_centrality
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load_centrality
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Notes
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-----
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The algorithm is from Ulrik Brandes [1]_.
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See [4]_ for the original first published version and [2]_ for details on
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algorithms for variations and related metrics.
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For approximate betweenness calculations set k=#samples to use
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k nodes ("pivots") to estimate the betweenness values. For an estimate
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of the number of pivots needed see [3]_.
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For weighted graphs the edge weights must be greater than zero.
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Zero edge weights can produce an infinite number of equal length
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paths between pairs of nodes.
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The total number of paths between source and target is counted
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differently for directed and undirected graphs. Directed paths
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are easy to count. Undirected paths are tricky: should a path
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from "u" to "v" count as 1 undirected path or as 2 directed paths?
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For betweenness_centrality we report the number of undirected
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paths when G is undirected.
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For betweenness_centrality_subset the reporting is different.
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If the source and target subsets are the same, then we want
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to count undirected paths. But if the source and target subsets
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differ -- for example, if sources is {0} and targets is {1},
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then we are only counting the paths in one direction. They are
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undirected paths but we are counting them in a directed way.
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To count them as undirected paths, each should count as half a path.
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References
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----------
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.. [1] Ulrik Brandes:
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A Faster Algorithm for Betweenness Centrality.
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Journal of Mathematical Sociology 25(2):163-177, 2001.
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http://www.inf.uni-konstanz.de/algo/publications/b-fabc-01.pdf
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.. [2] Ulrik Brandes:
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On Variants of Shortest-Path Betweenness
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Centrality and their Generic Computation.
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Social Networks 30(2):136-145, 2008.
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http://www.inf.uni-konstanz.de/algo/publications/b-vspbc-08.pdf
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.. [3] Ulrik Brandes and Christian Pich:
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Centrality Estimation in Large Networks.
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International Journal of Bifurcation and Chaos 17(7):2303-2318, 2007.
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http://www.inf.uni-konstanz.de/algo/publications/bp-celn-06.pdf
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.. [4] Linton C. Freeman:
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A set of measures of centrality based on betweenness.
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Sociometry 40: 35–41, 1977
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http://moreno.ss.uci.edu/23.pdf
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"""
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betweenness = dict.fromkeys(G, 0.0) # b[v]=0 for v in G
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if k is None:
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nodes = G
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else:
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nodes = seed.sample(G.nodes(), k)
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for s in nodes:
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# single source shortest paths
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if weight is None: # use BFS
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S, P, sigma = _single_source_shortest_path_basic(G, s)
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else: # use Dijkstra's algorithm
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S, P, sigma = _single_source_dijkstra_path_basic(G, s, weight)
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# accumulation
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if endpoints:
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betweenness = _accumulate_endpoints(betweenness, S, P, sigma, s)
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else:
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betweenness = _accumulate_basic(betweenness, S, P, sigma, s)
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# rescaling
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betweenness = _rescale(
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betweenness,
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len(G),
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normalized=normalized,
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directed=G.is_directed(),
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k=k,
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endpoints=endpoints,
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)
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return betweenness
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@py_random_state(4)
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def edge_betweenness_centrality(G, k=None, normalized=True, weight=None, seed=None):
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r"""Compute betweenness centrality for edges.
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Betweenness centrality of an edge $e$ is the sum of the
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fraction of all-pairs shortest paths that pass through $e$
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.. math::
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c_B(e) =\sum_{s,t \in V} \frac{\sigma(s, t|e)}{\sigma(s, t)}
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where $V$ is the set of nodes, $\sigma(s, t)$ is the number of
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shortest $(s, t)$-paths, and $\sigma(s, t|e)$ is the number of
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those paths passing through edge $e$ [2]_.
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Parameters
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----------
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G : graph
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A NetworkX graph.
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k : int, optional (default=None)
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If k is not None use k node samples to estimate betweenness.
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The value of k <= n where n is the number of nodes in the graph.
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Higher values give better approximation.
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normalized : bool, optional
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If True the betweenness values are normalized by $2/(n(n-1))$
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for graphs, and $1/(n(n-1))$ for directed graphs where $n$
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is the number of nodes in G.
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weight : None or string, optional (default=None)
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If None, all edge weights are considered equal.
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Otherwise holds the name of the edge attribute used as weight.
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seed : integer, random_state, or None (default)
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Indicator of random number generation state.
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See :ref:`Randomness<randomness>`.
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Note that this is only used if k is not None.
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Returns
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-------
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edges : dictionary
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Dictionary of edges with betweenness centrality as the value.
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See Also
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--------
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betweenness_centrality
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edge_load
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Notes
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-----
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The algorithm is from Ulrik Brandes [1]_.
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For weighted graphs the edge weights must be greater than zero.
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Zero edge weights can produce an infinite number of equal length
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paths between pairs of nodes.
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References
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----------
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.. [1] A Faster Algorithm for Betweenness Centrality. Ulrik Brandes,
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Journal of Mathematical Sociology 25(2):163-177, 2001.
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http://www.inf.uni-konstanz.de/algo/publications/b-fabc-01.pdf
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.. [2] Ulrik Brandes: On Variants of Shortest-Path Betweenness
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Centrality and their Generic Computation.
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Social Networks 30(2):136-145, 2008.
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http://www.inf.uni-konstanz.de/algo/publications/b-vspbc-08.pdf
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"""
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betweenness = dict.fromkeys(G, 0.0) # b[v]=0 for v in G
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# b[e]=0 for e in G.edges()
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betweenness.update(dict.fromkeys(G.edges(), 0.0))
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if k is None:
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nodes = G
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else:
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nodes = seed.sample(G.nodes(), k)
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for s in nodes:
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# single source shortest paths
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if weight is None: # use BFS
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S, P, sigma = _single_source_shortest_path_basic(G, s)
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else: # use Dijkstra's algorithm
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S, P, sigma = _single_source_dijkstra_path_basic(G, s, weight)
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# accumulation
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betweenness = _accumulate_edges(betweenness, S, P, sigma, s)
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# rescaling
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for n in G: # remove nodes to only return edges
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del betweenness[n]
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betweenness = _rescale_e(
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betweenness, len(G), normalized=normalized, directed=G.is_directed()
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)
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return betweenness
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# obsolete name
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def edge_betweenness(G, k=None, normalized=True, weight=None, seed=None):
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warnings.warn(
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"edge_betweeness is replaced by edge_betweenness_centrality", DeprecationWarning
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)
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return edge_betweenness_centrality(G, k, normalized, weight, seed)
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# helpers for betweenness centrality
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def _single_source_shortest_path_basic(G, s):
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S = []
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P = {}
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for v in G:
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P[v] = []
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sigma = dict.fromkeys(G, 0.0) # sigma[v]=0 for v in G
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D = {}
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sigma[s] = 1.0
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D[s] = 0
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Q = [s]
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while Q: # use BFS to find shortest paths
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v = Q.pop(0)
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S.append(v)
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Dv = D[v]
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sigmav = sigma[v]
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for w in G[v]:
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if w not in D:
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Q.append(w)
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D[w] = Dv + 1
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if D[w] == Dv + 1: # this is a shortest path, count paths
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sigma[w] += sigmav
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P[w].append(v) # predecessors
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return S, P, sigma
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def _single_source_dijkstra_path_basic(G, s, weight):
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# modified from Eppstein
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S = []
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P = {}
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for v in G:
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P[v] = []
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sigma = dict.fromkeys(G, 0.0) # sigma[v]=0 for v in G
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D = {}
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sigma[s] = 1.0
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push = heappush
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pop = heappop
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seen = {s: 0}
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c = count()
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Q = [] # use Q as heap with (distance,node id) tuples
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push(Q, (0, next(c), s, s))
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while Q:
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(dist, _, pred, v) = pop(Q)
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if v in D:
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continue # already searched this node.
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sigma[v] += sigma[pred] # count paths
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S.append(v)
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D[v] = dist
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for w, edgedata in G[v].items():
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vw_dist = dist + edgedata.get(weight, 1)
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if w not in D and (w not in seen or vw_dist < seen[w]):
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seen[w] = vw_dist
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push(Q, (vw_dist, next(c), v, w))
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sigma[w] = 0.0
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P[w] = [v]
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elif vw_dist == seen[w]: # handle equal paths
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sigma[w] += sigma[v]
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P[w].append(v)
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return S, P, sigma
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def _accumulate_basic(betweenness, S, P, sigma, s):
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delta = dict.fromkeys(S, 0)
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while S:
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w = S.pop()
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coeff = (1 + delta[w]) / sigma[w]
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for v in P[w]:
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delta[v] += sigma[v] * coeff
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if w != s:
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betweenness[w] += delta[w]
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return betweenness
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def _accumulate_endpoints(betweenness, S, P, sigma, s):
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betweenness[s] += len(S) - 1
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delta = dict.fromkeys(S, 0)
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while S:
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w = S.pop()
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coeff = (1 + delta[w]) / sigma[w]
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for v in P[w]:
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delta[v] += sigma[v] * coeff
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if w != s:
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betweenness[w] += delta[w] + 1
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return betweenness
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def _accumulate_edges(betweenness, S, P, sigma, s):
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delta = dict.fromkeys(S, 0)
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while S:
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w = S.pop()
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coeff = (1 + delta[w]) / sigma[w]
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for v in P[w]:
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c = sigma[v] * coeff
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if (v, w) not in betweenness:
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betweenness[(w, v)] += c
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else:
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betweenness[(v, w)] += c
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delta[v] += c
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if w != s:
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betweenness[w] += delta[w]
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return betweenness
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def _rescale(betweenness, n, normalized, directed=False, k=None, endpoints=False):
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if normalized:
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if endpoints:
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if n < 2:
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scale = None # no normalization
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else:
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# Scale factor should include endpoint nodes
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scale = 1 / (n * (n - 1))
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elif n <= 2:
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scale = None # no normalization b=0 for all nodes
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else:
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scale = 1 / ((n - 1) * (n - 2))
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else: # rescale by 2 for undirected graphs
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if not directed:
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scale = 0.5
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else:
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scale = None
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if scale is not None:
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if k is not None:
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scale = scale * n / k
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for v in betweenness:
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betweenness[v] *= scale
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return betweenness
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def _rescale_e(betweenness, n, normalized, directed=False, k=None):
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if normalized:
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if n <= 1:
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scale = None # no normalization b=0 for all nodes
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else:
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scale = 1 / (n * (n - 1))
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else: # rescale by 2 for undirected graphs
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if not directed:
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scale = 0.5
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else:
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scale = None
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if scale is not None:
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if k is not None:
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scale = scale * n / k
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for v in betweenness:
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betweenness[v] *= scale
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return betweenness
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