566 lines
15 KiB
Python
566 lines
15 KiB
Python
# See https://github.com/networkx/networkx/pull/1474
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# Copyright 2011 Reya Group <http://www.reyagroup.com>
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# Copyright 2011 Alex Levenson <alex@isnotinvain.com>
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# Copyright 2011 Diederik van Liere <diederik.vanliere@rotman.utoronto.ca>
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"""Functions for analyzing triads of a graph."""
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from collections import defaultdict
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from itertools import combinations, permutations
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import networkx as nx
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from networkx.utils import not_implemented_for, py_random_state
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__all__ = [
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"triadic_census",
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"is_triad",
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"all_triplets",
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"all_triads",
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"triads_by_type",
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"triad_type",
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"random_triad",
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]
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#: The integer codes representing each type of triad.
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#:
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#: Triads that are the same up to symmetry have the same code.
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TRICODES = (
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1,
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2,
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2,
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3,
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2,
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4,
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6,
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8,
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2,
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6,
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5,
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7,
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3,
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8,
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7,
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11,
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2,
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6,
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4,
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8,
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5,
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9,
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9,
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13,
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6,
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10,
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9,
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14,
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7,
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14,
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12,
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15,
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2,
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5,
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6,
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7,
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6,
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9,
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10,
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14,
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4,
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9,
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9,
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12,
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8,
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13,
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14,
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15,
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3,
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7,
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8,
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11,
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7,
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12,
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14,
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15,
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8,
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14,
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13,
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15,
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11,
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15,
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15,
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16,
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)
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#: The names of each type of triad. The order of the elements is
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#: important: it corresponds to the tricodes given in :data:`TRICODES`.
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TRIAD_NAMES = (
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"003",
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"012",
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"102",
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"021D",
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"021U",
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"021C",
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"111D",
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"111U",
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"030T",
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"030C",
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"201",
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"120D",
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"120U",
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"120C",
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"210",
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"300",
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)
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#: A dictionary mapping triad code to triad name.
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TRICODE_TO_NAME = {i: TRIAD_NAMES[code - 1] for i, code in enumerate(TRICODES)}
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def _tricode(G, v, u, w):
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"""Returns the integer code of the given triad.
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This is some fancy magic that comes from Batagelj and Mrvar's paper. It
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treats each edge joining a pair of `v`, `u`, and `w` as a bit in
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the binary representation of an integer.
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"""
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combos = ((v, u, 1), (u, v, 2), (v, w, 4), (w, v, 8), (u, w, 16), (w, u, 32))
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return sum(x for u, v, x in combos if v in G[u])
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@not_implemented_for("undirected")
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@nx._dispatch
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def triadic_census(G, nodelist=None):
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"""Determines the triadic census of a directed graph.
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The triadic census is a count of how many of the 16 possible types of
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triads are present in a directed graph. If a list of nodes is passed, then
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only those triads are taken into account which have elements of nodelist in them.
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Parameters
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----------
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G : digraph
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A NetworkX DiGraph
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nodelist : list
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List of nodes for which you want to calculate triadic census
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Returns
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-------
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census : dict
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Dictionary with triad type as keys and number of occurrences as values.
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Examples
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--------
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>>> G = nx.DiGraph([(1, 2), (2, 3), (3, 1), (3, 4), (4, 1), (4, 2)])
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>>> triadic_census = nx.triadic_census(G)
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>>> for key, value in triadic_census.items():
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... print(f"{key}: {value}")
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...
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003: 0
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012: 0
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102: 0
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021D: 0
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021U: 0
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021C: 0
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111D: 0
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111U: 0
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030T: 2
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030C: 2
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201: 0
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120D: 0
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120U: 0
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120C: 0
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210: 0
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300: 0
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Notes
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-----
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This algorithm has complexity $O(m)$ where $m$ is the number of edges in
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the graph.
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Raises
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------
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ValueError
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If `nodelist` contains duplicate nodes or nodes not in `G`.
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If you want to ignore this you can preprocess with `set(nodelist) & G.nodes`
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See also
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--------
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triad_graph
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References
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----------
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.. [1] Vladimir Batagelj and Andrej Mrvar, A subquadratic triad census
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algorithm for large sparse networks with small maximum degree,
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University of Ljubljana,
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http://vlado.fmf.uni-lj.si/pub/networks/doc/triads/triads.pdf
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"""
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nodeset = set(G.nbunch_iter(nodelist))
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if nodelist is not None and len(nodelist) != len(nodeset):
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raise ValueError("nodelist includes duplicate nodes or nodes not in G")
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N = len(G)
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Nnot = N - len(nodeset) # can signal special counting for subset of nodes
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# create an ordering of nodes with nodeset nodes first
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m = {n: i for i, n in enumerate(nodeset)}
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if Nnot:
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# add non-nodeset nodes later in the ordering
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not_nodeset = G.nodes - nodeset
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m.update((n, i + N) for i, n in enumerate(not_nodeset))
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# build all_neighbor dicts for easy counting
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# After Python 3.8 can leave off these keys(). Speedup also using G._pred
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# nbrs = {n: G._pred[n].keys() | G._succ[n].keys() for n in G}
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nbrs = {n: G.pred[n].keys() | G.succ[n].keys() for n in G}
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dbl_nbrs = {n: G.pred[n].keys() & G.succ[n].keys() for n in G}
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if Nnot:
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sgl_nbrs = {n: G.pred[n].keys() ^ G.succ[n].keys() for n in not_nodeset}
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# find number of edges not incident to nodes in nodeset
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sgl = sum(1 for n in not_nodeset for nbr in sgl_nbrs[n] if nbr not in nodeset)
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sgl_edges_outside = sgl // 2
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dbl = sum(1 for n in not_nodeset for nbr in dbl_nbrs[n] if nbr not in nodeset)
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dbl_edges_outside = dbl // 2
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# Initialize the count for each triad to be zero.
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census = {name: 0 for name in TRIAD_NAMES}
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# Main loop over nodes
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for v in nodeset:
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vnbrs = nbrs[v]
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dbl_vnbrs = dbl_nbrs[v]
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if Nnot:
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# set up counts of edges attached to v.
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sgl_unbrs_bdy = sgl_unbrs_out = dbl_unbrs_bdy = dbl_unbrs_out = 0
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for u in vnbrs:
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if m[u] <= m[v]:
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continue
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unbrs = nbrs[u]
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neighbors = (vnbrs | unbrs) - {u, v}
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# Count connected triads.
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for w in neighbors:
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if m[u] < m[w] or (m[v] < m[w] < m[u] and v not in nbrs[w]):
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code = _tricode(G, v, u, w)
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census[TRICODE_TO_NAME[code]] += 1
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# Use a formula for dyadic triads with edge incident to v
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if u in dbl_vnbrs:
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census["102"] += N - len(neighbors) - 2
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else:
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census["012"] += N - len(neighbors) - 2
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# Count edges attached to v. Subtract later to get triads with v isolated
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# _out are (u,unbr) for unbrs outside boundary of nodeset
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# _bdy are (u,unbr) for unbrs on boundary of nodeset (get double counted)
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if Nnot and u not in nodeset:
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sgl_unbrs = sgl_nbrs[u]
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sgl_unbrs_bdy += len(sgl_unbrs & vnbrs - nodeset)
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sgl_unbrs_out += len(sgl_unbrs - vnbrs - nodeset)
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dbl_unbrs = dbl_nbrs[u]
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dbl_unbrs_bdy += len(dbl_unbrs & vnbrs - nodeset)
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dbl_unbrs_out += len(dbl_unbrs - vnbrs - nodeset)
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# if nodeset == G.nodes, skip this b/c we will find the edge later.
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if Nnot:
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# Count edges outside nodeset not connected with v (v isolated triads)
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census["012"] += sgl_edges_outside - (sgl_unbrs_out + sgl_unbrs_bdy // 2)
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census["102"] += dbl_edges_outside - (dbl_unbrs_out + dbl_unbrs_bdy // 2)
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# calculate null triads: "003"
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# null triads = total number of possible triads - all found triads
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total_triangles = (N * (N - 1) * (N - 2)) // 6
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triangles_without_nodeset = (Nnot * (Nnot - 1) * (Nnot - 2)) // 6
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total_census = total_triangles - triangles_without_nodeset
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census["003"] = total_census - sum(census.values())
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return census
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@nx._dispatch
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def is_triad(G):
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"""Returns True if the graph G is a triad, else False.
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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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Returns
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-------
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istriad : boolean
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Whether G is a valid triad
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Examples
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--------
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>>> G = nx.DiGraph([(1, 2), (2, 3), (3, 1)])
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>>> nx.is_triad(G)
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True
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>>> G.add_edge(0, 1)
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>>> nx.is_triad(G)
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False
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"""
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if isinstance(G, nx.Graph):
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if G.order() == 3 and nx.is_directed(G):
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if not any((n, n) in G.edges() for n in G.nodes()):
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return True
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return False
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@not_implemented_for("undirected")
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@nx._dispatch
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def all_triplets(G):
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"""Returns a generator of all possible sets of 3 nodes in a DiGraph.
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Parameters
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----------
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G : digraph
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A NetworkX DiGraph
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Returns
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-------
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triplets : generator of 3-tuples
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Generator of tuples of 3 nodes
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Examples
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--------
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>>> G = nx.DiGraph([(1, 2), (2, 3), (3, 4)])
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>>> list(nx.all_triplets(G))
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[(1, 2, 3), (1, 2, 4), (1, 3, 4), (2, 3, 4)]
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"""
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triplets = combinations(G.nodes(), 3)
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return triplets
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@not_implemented_for("undirected")
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@nx._dispatch
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def all_triads(G):
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"""A generator of all possible triads in G.
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Parameters
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----------
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G : digraph
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A NetworkX DiGraph
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Returns
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-------
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all_triads : generator of DiGraphs
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Generator of triads (order-3 DiGraphs)
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Examples
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--------
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>>> G = nx.DiGraph([(1, 2), (2, 3), (3, 1), (3, 4), (4, 1), (4, 2)])
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>>> for triad in nx.all_triads(G):
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... print(triad.edges)
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[(1, 2), (2, 3), (3, 1)]
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[(1, 2), (4, 1), (4, 2)]
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[(3, 1), (3, 4), (4, 1)]
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[(2, 3), (3, 4), (4, 2)]
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"""
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triplets = combinations(G.nodes(), 3)
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for triplet in triplets:
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yield G.subgraph(triplet).copy()
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@not_implemented_for("undirected")
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@nx._dispatch
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def triads_by_type(G):
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"""Returns a list of all triads for each triad type in a directed graph.
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There are exactly 16 different types of triads possible. Suppose 1, 2, 3 are three
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nodes, they will be classified as a particular triad type if their connections
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are as follows:
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- 003: 1, 2, 3
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- 012: 1 -> 2, 3
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- 102: 1 <-> 2, 3
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- 021D: 1 <- 2 -> 3
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- 021U: 1 -> 2 <- 3
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- 021C: 1 -> 2 -> 3
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- 111D: 1 <-> 2 <- 3
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- 111U: 1 <-> 2 -> 3
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- 030T: 1 -> 2 -> 3, 1 -> 3
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- 030C: 1 <- 2 <- 3, 1 -> 3
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- 201: 1 <-> 2 <-> 3
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- 120D: 1 <- 2 -> 3, 1 <-> 3
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- 120U: 1 -> 2 <- 3, 1 <-> 3
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- 120C: 1 -> 2 -> 3, 1 <-> 3
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- 210: 1 -> 2 <-> 3, 1 <-> 3
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- 300: 1 <-> 2 <-> 3, 1 <-> 3
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Refer to the :doc:`example gallery </auto_examples/graph/plot_triad_types>`
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for visual examples of the triad types.
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Parameters
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----------
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G : digraph
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A NetworkX DiGraph
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Returns
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-------
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tri_by_type : dict
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Dictionary with triad types as keys and lists of triads as values.
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Examples
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--------
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>>> G = nx.DiGraph([(1, 2), (1, 3), (2, 3), (3, 1), (5, 6), (5, 4), (6, 7)])
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>>> dict = nx.triads_by_type(G)
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>>> dict['120C'][0].edges()
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OutEdgeView([(1, 2), (1, 3), (2, 3), (3, 1)])
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>>> dict['012'][0].edges()
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OutEdgeView([(1, 2)])
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References
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----------
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.. [1] Snijders, T. (2012). "Transitivity and triads." University of
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Oxford.
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https://web.archive.org/web/20170830032057/http://www.stats.ox.ac.uk/~snijders/Trans_Triads_ha.pdf
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"""
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# num_triads = o * (o - 1) * (o - 2) // 6
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# if num_triads > TRIAD_LIMIT: print(WARNING)
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all_tri = all_triads(G)
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tri_by_type = defaultdict(list)
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for triad in all_tri:
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name = triad_type(triad)
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tri_by_type[name].append(triad)
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return tri_by_type
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@not_implemented_for("undirected")
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@nx._dispatch
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def triad_type(G):
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"""Returns the sociological triad type for a triad.
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Parameters
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----------
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G : digraph
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A NetworkX DiGraph with 3 nodes
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Returns
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-------
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triad_type : str
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A string identifying the triad type
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Examples
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--------
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>>> G = nx.DiGraph([(1, 2), (2, 3), (3, 1)])
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>>> nx.triad_type(G)
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'030C'
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>>> G.add_edge(1, 3)
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>>> nx.triad_type(G)
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'120C'
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Notes
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-----
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There can be 6 unique edges in a triad (order-3 DiGraph) (so 2^^6=64 unique
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triads given 3 nodes). These 64 triads each display exactly 1 of 16
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topologies of triads (topologies can be permuted). These topologies are
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identified by the following notation:
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{m}{a}{n}{type} (for example: 111D, 210, 102)
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Here:
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{m} = number of mutual ties (takes 0, 1, 2, 3); a mutual tie is (0,1)
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AND (1,0)
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{a} = number of asymmetric ties (takes 0, 1, 2, 3); an asymmetric tie
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is (0,1) BUT NOT (1,0) or vice versa
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{n} = number of null ties (takes 0, 1, 2, 3); a null tie is NEITHER
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(0,1) NOR (1,0)
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{type} = a letter (takes U, D, C, T) corresponding to up, down, cyclical
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and transitive. This is only used for topologies that can have
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more than one form (eg: 021D and 021U).
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References
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----------
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.. [1] Snijders, T. (2012). "Transitivity and triads." University of
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Oxford.
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https://web.archive.org/web/20170830032057/http://www.stats.ox.ac.uk/~snijders/Trans_Triads_ha.pdf
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"""
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if not is_triad(G):
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raise nx.NetworkXAlgorithmError("G is not a triad (order-3 DiGraph)")
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num_edges = len(G.edges())
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if num_edges == 0:
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return "003"
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elif num_edges == 1:
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return "012"
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elif num_edges == 2:
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e1, e2 = G.edges()
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if set(e1) == set(e2):
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return "102"
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elif e1[0] == e2[0]:
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return "021D"
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elif e1[1] == e2[1]:
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return "021U"
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elif e1[1] == e2[0] or e2[1] == e1[0]:
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return "021C"
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elif num_edges == 3:
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for e1, e2, e3 in permutations(G.edges(), 3):
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if set(e1) == set(e2):
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if e3[0] in e1:
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return "111U"
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# e3[1] in e1:
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return "111D"
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elif set(e1).symmetric_difference(set(e2)) == set(e3):
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if {e1[0], e2[0], e3[0]} == {e1[0], e2[0], e3[0]} == set(G.nodes()):
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return "030C"
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# e3 == (e1[0], e2[1]) and e2 == (e1[1], e3[1]):
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return "030T"
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elif num_edges == 4:
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for e1, e2, e3, e4 in permutations(G.edges(), 4):
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if set(e1) == set(e2):
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# identify pair of symmetric edges (which necessarily exists)
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if set(e3) == set(e4):
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return "201"
|
|
if {e3[0]} == {e4[0]} == set(e3).intersection(set(e4)):
|
|
return "120D"
|
|
if {e3[1]} == {e4[1]} == set(e3).intersection(set(e4)):
|
|
return "120U"
|
|
if e3[1] == e4[0]:
|
|
return "120C"
|
|
elif num_edges == 5:
|
|
return "210"
|
|
elif num_edges == 6:
|
|
return "300"
|
|
|
|
|
|
@not_implemented_for("undirected")
|
|
@py_random_state(1)
|
|
@nx._dispatch
|
|
def random_triad(G, seed=None):
|
|
"""Returns a random triad from a directed graph.
|
|
|
|
Parameters
|
|
----------
|
|
G : digraph
|
|
A NetworkX DiGraph
|
|
seed : integer, random_state, or None (default)
|
|
Indicator of random number generation state.
|
|
See :ref:`Randomness<randomness>`.
|
|
|
|
Returns
|
|
-------
|
|
G2 : subgraph
|
|
A randomly selected triad (order-3 NetworkX DiGraph)
|
|
|
|
Raises
|
|
------
|
|
NetworkXError
|
|
If the input Graph has less than 3 nodes.
|
|
|
|
Examples
|
|
--------
|
|
>>> G = nx.DiGraph([(1, 2), (1, 3), (2, 3), (3, 1), (5, 6), (5, 4), (6, 7)])
|
|
>>> triad = nx.random_triad(G, seed=1)
|
|
>>> triad.edges
|
|
OutEdgeView([(1, 2)])
|
|
|
|
"""
|
|
if len(G) < 3:
|
|
raise nx.NetworkXError(
|
|
f"G needs at least 3 nodes to form a triad; (it has {len(G)} nodes)"
|
|
)
|
|
nodes = seed.sample(list(G.nodes()), 3)
|
|
G2 = G.subgraph(nodes)
|
|
return G2
|