# -*- coding: utf-8 -*- """ Flow Hierarchy. """ # Copyright (C) 2004-2018 by # Aric Hagberg # Dan Schult # Pieter Swart # All rights reserved. # BSD license. import networkx as nx __authors__ = "\n".join(['Ben Edwards (bedwards@cs.unm.edu)']) __all__ = ['flow_hierarchy'] def flow_hierarchy(G, weight=None): """Returns the flow hierarchy of a directed network. Flow hierarchy is defined as the fraction of edges not participating in cycles in a directed graph [1]_. Parameters ---------- G : DiGraph or MultiDiGraph A directed graph weight : key,optional (default=None) Attribute to use for node weights. If None the weight defaults to 1. Returns ------- h : float Flow hierarchy value Notes ----- The algorithm described in [1]_ computes the flow hierarchy through exponentiation of the adjacency matrix. This function implements an alternative approach that finds strongly connected components. An edge is in a cycle if and only if it is in a strongly connected component, which can be found in $O(m)$ time using Tarjan's algorithm. References ---------- .. [1] Luo, J.; Magee, C.L. (2011), Detecting evolving patterns of self-organizing networks by flow hierarchy measurement, Complexity, Volume 16 Issue 6 53-61. DOI: 10.1002/cplx.20368 http://web.mit.edu/~cmagee/www/documents/28-DetectingEvolvingPatterns_FlowHierarchy.pdf """ if not G.is_directed(): raise nx.NetworkXError("G must be a digraph in flow_heirarchy") scc = nx.strongly_connected_components(G) return 1. - sum(G.subgraph(c).size(weight) for c in scc) / float(G.size(weight))