Vehicle-Anti-Theft-Face-Rec.../venv/Lib/site-packages/networkx/generators/ego.py

"""
Ego graph.
"""
__all__ = ["ego_graph"]

import networkx as nx


def ego_graph(G, n, radius=1, center=True, undirected=False, distance=None):
    """Returns induced subgraph of neighbors centered at node n within
    a given radius.

    Parameters
    ----------
    G : graph
      A NetworkX Graph or DiGraph

    n : node
      A single node

    radius : number, optional
      Include all neighbors of distance<=radius from n.

    center : bool, optional
      If False, do not include center node in graph

    undirected : bool, optional
      If True use both in- and out-neighbors of directed graphs.

    distance : key, optional
      Use specified edge data key as distance.  For example, setting
      distance='weight' will use the edge weight to measure the
      distance from the node n.

    Notes
    -----
    For directed graphs D this produces the "out" neighborhood
    or successors.  If you want the neighborhood of predecessors
    first reverse the graph with D.reverse().  If you want both
    directions use the keyword argument undirected=True.

    Node, edge, and graph attributes are copied to the returned subgraph.
    """
    if undirected:
        if distance is not None:
            sp, _ = nx.single_source_dijkstra(
                G.to_undirected(), n, cutoff=radius, weight=distance
            )
        else:
            sp = dict(
                nx.single_source_shortest_path_length(
                    G.to_undirected(), n, cutoff=radius
                )
            )
    else:
        if distance is not None:
            sp, _ = nx.single_source_dijkstra(G, n, cutoff=radius, weight=distance)
        else:
            sp = dict(nx.single_source_shortest_path_length(G, n, cutoff=radius))

    H = G.subgraph(sp).copy()
    if not center:
        H.remove_node(n)
    return H
Fixed database typo and removed unnecessary class identifier. 2020-10-14 14:10:37 +00:00			`"""`
			`Ego graph.`
			`"""`
			`__all__ = ["ego_graph"]`

			`import networkx as nx`


			`def ego_graph(G, n, radius=1, center=True, undirected=False, distance=None):`
			`"""Returns induced subgraph of neighbors centered at node n within`
			`a given radius.`

			`Parameters`
			`----------`
			`G : graph`
			`A NetworkX Graph or DiGraph`

			`n : node`
			`A single node`

			`radius : number, optional`
			`Include all neighbors of distance<=radius from n.`

			`center : bool, optional`
			`If False, do not include center node in graph`

			`undirected : bool, optional`
			`If True use both in- and out-neighbors of directed graphs.`

			`distance : key, optional`
			`Use specified edge data key as distance. For example, setting`
			`distance='weight' will use the edge weight to measure the`
			`distance from the node n.`

			`Notes`
			`-----`
			`For directed graphs D this produces the "out" neighborhood`
			`or successors. If you want the neighborhood of predecessors`
			`first reverse the graph with D.reverse(). If you want both`
			`directions use the keyword argument undirected=True.`

			`Node, edge, and graph attributes are copied to the returned subgraph.`
			`"""`
			`if undirected:`
			`if distance is not None:`
			`sp, _ = nx.single_source_dijkstra(`
			`G.to_undirected(), n, cutoff=radius, weight=distance`
			`)`
			`else:`
			`sp = dict(`
			`nx.single_source_shortest_path_length(`
			`G.to_undirected(), n, cutoff=radius`
			`)`
			`)`
			`else:`
			`if distance is not None:`
			`sp, _ = nx.single_source_dijkstra(G, n, cutoff=radius, weight=distance)`
			`else:`
			`sp = dict(nx.single_source_shortest_path_length(G, n, cutoff=radius))`

			`H = G.subgraph(sp).copy()`
			`if not center:`
			`H.remove_node(n)`
			`return H`