157 lines
4.9 KiB
Python
157 lines
4.9 KiB
Python
"""
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Adjacency matrix and incidence matrix of graphs.
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"""
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import networkx as nx
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__all__ = ["incidence_matrix", "adj_matrix", "adjacency_matrix"]
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def incidence_matrix(G, nodelist=None, edgelist=None, oriented=False, weight=None):
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"""Returns incidence matrix of G.
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The incidence matrix assigns each row to a node and each column to an edge.
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For a standard incidence matrix a 1 appears wherever a row's node is
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incident on the column's edge. For an oriented incidence matrix each
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edge is assigned an orientation (arbitrarily for undirected and aligning to
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direction for directed). A -1 appears for the source (tail) of an edge and
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1 for the destination (head) of the edge. The elements are zero otherwise.
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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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nodelist : list, optional (default= all nodes in G)
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The rows are ordered according to the nodes in nodelist.
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If nodelist is None, then the ordering is produced by G.nodes().
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edgelist : list, optional (default= all edges in G)
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The columns are ordered according to the edges in edgelist.
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If edgelist is None, then the ordering is produced by G.edges().
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oriented: bool, optional (default=False)
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If True, matrix elements are +1 or -1 for the head or tail node
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respectively of each edge. If False, +1 occurs at both nodes.
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weight : string or None, optional (default=None)
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The edge data key used to provide each value in the matrix.
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If None, then each edge has weight 1. Edge weights, if used,
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should be positive so that the orientation can provide the sign.
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Returns
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-------
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A : SciPy sparse matrix
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The incidence matrix of G.
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Notes
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-----
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For MultiGraph/MultiDiGraph, the edges in edgelist should be
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(u,v,key) 3-tuples.
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"Networks are the best discrete model for so many problems in
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applied mathematics" [1]_.
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References
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----------
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.. [1] Gil Strang, Network applications: A = incidence matrix,
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http://academicearth.org/lectures/network-applications-incidence-matrix
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"""
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import scipy.sparse
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if nodelist is None:
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nodelist = list(G)
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if edgelist is None:
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if G.is_multigraph():
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edgelist = list(G.edges(keys=True))
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else:
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edgelist = list(G.edges())
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A = scipy.sparse.lil_matrix((len(nodelist), len(edgelist)))
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node_index = {node: i for i, node in enumerate(nodelist)}
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for ei, e in enumerate(edgelist):
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(u, v) = e[:2]
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if u == v:
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continue # self loops give zero column
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try:
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ui = node_index[u]
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vi = node_index[v]
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except KeyError as e:
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raise nx.NetworkXError(
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f"node {u} or {v} in edgelist " f"but not in nodelist"
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) from e
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if weight is None:
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wt = 1
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else:
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if G.is_multigraph():
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ekey = e[2]
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wt = G[u][v][ekey].get(weight, 1)
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else:
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wt = G[u][v].get(weight, 1)
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if oriented:
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A[ui, ei] = -wt
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A[vi, ei] = wt
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else:
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A[ui, ei] = wt
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A[vi, ei] = wt
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return A.asformat("csc")
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def adjacency_matrix(G, nodelist=None, weight="weight"):
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"""Returns adjacency matrix of G.
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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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nodelist : list, optional
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The rows and columns are ordered according to the nodes in nodelist.
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If nodelist is None, then the ordering is produced by G.nodes().
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weight : string or None, optional (default='weight')
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The edge data key used to provide each value in the matrix.
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If None, then each edge has weight 1.
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Returns
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-------
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A : SciPy sparse matrix
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Adjacency matrix representation of G.
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Notes
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-----
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For directed graphs, entry i,j corresponds to an edge from i to j.
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If you want a pure Python adjacency matrix representation try
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networkx.convert.to_dict_of_dicts which will return a
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dictionary-of-dictionaries format that can be addressed as a
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sparse matrix.
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For MultiGraph/MultiDiGraph with parallel edges the weights are summed.
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See `to_numpy_array` for other options.
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The convention used for self-loop edges in graphs is to assign the
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diagonal matrix entry value to the edge weight attribute
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(or the number 1 if the edge has no weight attribute). If the
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alternate convention of doubling the edge weight is desired the
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resulting Scipy sparse matrix can be modified as follows:
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>>> import scipy as sp
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>>> G = nx.Graph([(1, 1)])
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>>> A = nx.adjacency_matrix(G)
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>>> print(A.todense())
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[[1]]
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>>> A.setdiag(A.diagonal() * 2)
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>>> print(A.todense())
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[[2]]
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See Also
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--------
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to_numpy_array
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to_scipy_sparse_matrix
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to_dict_of_dicts
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adjacency_spectrum
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"""
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return nx.to_scipy_sparse_matrix(G, nodelist=nodelist, weight=weight)
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adj_matrix = adjacency_matrix
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