Source code for networkx.algorithms.centrality.harmonic

"""Functions for computing the harmonic centrality of a graph."""

from functools import partial

import networkx as nx

__all__ = ["harmonic_centrality"]




[docs]
@nx._dispatchable(edge_attrs="distance")
def harmonic_centrality(G, nbunch=None, distance=None, sources=None):
    r"""Compute harmonic centrality for nodes.

    Harmonic centrality [1]_ of a node `u` is the sum of the reciprocal
    of the shortest path distances from all other nodes to `u`

    .. math::

        C(u) = \sum_{v \neq u} \frac{1}{d(v, u)}

    where `d(v, u)` is the shortest-path distance between `v` and `u`.

    If `sources` is given as an argument, the returned harmonic centrality
    values are calculated as the sum of the reciprocals of the shortest
    path distances from the nodes specified in `sources` to `u` instead
    of from all nodes to `u`.

    Notice that higher values indicate higher centrality.

    Parameters
    ----------
    G : graph
      A NetworkX graph

    nbunch : container (default: all nodes in G)
      Container of nodes for which harmonic centrality values are calculated.

    sources : container (default: all nodes in G)
      Container of nodes `v` over which reciprocal distances are computed.
      Nodes not in `G` are silently ignored.

    distance : edge attribute key, optional (default=None)
      Use the specified edge attribute as the edge distance in shortest
      path calculations.  If `None`, then each edge will have distance equal to 1.

    Returns
    -------
    nodes : dictionary
      Dictionary of nodes with harmonic centrality as the value.

    See Also
    --------
    betweenness_centrality, load_centrality, eigenvector_centrality,
    degree_centrality, closeness_centrality

    Notes
    -----
    If the 'distance' keyword is set to an edge attribute key then the
    shortest-path length will be computed using Dijkstra's algorithm with
    that edge attribute as the edge weight.

    References
    ----------
    .. [1] Boldi, Paolo, and Sebastiano Vigna. "Axioms for centrality."
           Internet Mathematics 10.3-4 (2014): 222-262.
    """

    nbunch = set(G.nbunch_iter(nbunch) if nbunch is not None else G.nodes)
    sources = set(G.nbunch_iter(sources) if sources is not None else G.nodes)

    centrality = {u: 0 for u in nbunch}

    transposed = False
    if len(nbunch) < len(sources):
        transposed = True
        nbunch, sources = sources, nbunch
        if nx.is_directed(G):
            G = nx.reverse(G, copy=False)

    spl = partial(nx.shortest_path_length, G, weight=distance)
    for v in sources:
        dist = spl(v)
        for u in nbunch.intersection(dist):
            d = dist[u]
            if d == 0:  # handle u == v and edges with 0 weight
                continue
            centrality[v if transposed else u] += 1 / d

    return centrality