"""
Adjacency matrix and incidence matrix of graphs.
"""
import networkx as nx
__all__ = ["incidence_matrix", "adj_matrix", "adjacency_matrix"]
[docs]def incidence_matrix(G, nodelist=None, edgelist=None, oriented=False, weight=None):
"""Returns incidence matrix of G.
The incidence matrix assigns each row to a node and each column to an edge.
For a standard incidence matrix a 1 appears wherever a row's node is
incident on the column's edge. For an oriented incidence matrix each
edge is assigned an orientation (arbitrarily for undirected and aligning to
direction for directed). A -1 appears for the source (tail) of an edge and
1 for the destination (head) of the edge. The elements are zero otherwise.
Parameters
----------
G : graph
A NetworkX graph
nodelist : list, optional (default= all nodes in G)
The rows are ordered according to the nodes in nodelist.
If nodelist is None, then the ordering is produced by G.nodes().
edgelist : list, optional (default= all edges in G)
The columns are ordered according to the edges in edgelist.
If edgelist is None, then the ordering is produced by G.edges().
oriented: bool, optional (default=False)
If True, matrix elements are +1 or -1 for the head or tail node
respectively of each edge. If False, +1 occurs at both nodes.
weight : string or None, optional (default=None)
The edge data key used to provide each value in the matrix.
If None, then each edge has weight 1. Edge weights, if used,
should be positive so that the orientation can provide the sign.
Returns
-------
A : SciPy sparse matrix
The incidence matrix of G.
Notes
-----
For MultiGraph/MultiDiGraph, the edges in edgelist should be
(u,v,key) 3-tuples.
"Networks are the best discrete model for so many problems in
applied mathematics" [1]_.
References
----------
.. [1] Gil Strang, Network applications: A = incidence matrix,
http://videolectures.net/mit18085f07_strang_lec03/
"""
import scipy as sp
import scipy.sparse # call as sp.sparse
if nodelist is None:
nodelist = list(G)
if edgelist is None:
if G.is_multigraph():
edgelist = list(G.edges(keys=True))
else:
edgelist = list(G.edges())
A = sp.sparse.lil_array((len(nodelist), len(edgelist)))
node_index = {node: i for i, node in enumerate(nodelist)}
for ei, e in enumerate(edgelist):
(u, v) = e[:2]
if u == v:
continue # self loops give zero column
try:
ui = node_index[u]
vi = node_index[v]
except KeyError as err:
raise nx.NetworkXError(
f"node {u} or {v} in edgelist but not in nodelist"
) from err
if weight is None:
wt = 1
else:
if G.is_multigraph():
ekey = e[2]
wt = G[u][v][ekey].get(weight, 1)
else:
wt = G[u][v].get(weight, 1)
if oriented:
A[ui, ei] = -wt
A[vi, ei] = wt
else:
A[ui, ei] = wt
A[vi, ei] = wt
import warnings
warnings.warn(
"incidence_matrix will return a scipy.sparse array instead of a matrix in Networkx 3.0.",
FutureWarning,
stacklevel=2,
)
# TODO: Rm sp.sparse.csc_matrix in Networkx 3.0
return A.asformat("csc")
[docs]def adjacency_matrix(G, nodelist=None, dtype=None, weight="weight"):
"""Returns adjacency matrix of G.
Parameters
----------
G : graph
A NetworkX graph
nodelist : list, optional
The rows and columns are ordered according to the nodes in nodelist.
If nodelist is None, then the ordering is produced by G.nodes().
dtype : NumPy data-type, optional
The desired data-type for the array.
If None, then the NumPy default is used.
weight : string or None, optional (default='weight')
The edge data key used to provide each value in the matrix.
If None, then each edge has weight 1.
Returns
-------
A : SciPy sparse matrix
Adjacency matrix representation of G.
Notes
-----
For directed graphs, entry i,j corresponds to an edge from i to j.
If you want a pure Python adjacency matrix representation try
networkx.convert.to_dict_of_dicts which will return a
dictionary-of-dictionaries format that can be addressed as a
sparse matrix.
For MultiGraph/MultiDiGraph with parallel edges the weights are summed.
See `to_numpy_array` for other options.
The convention used for self-loop edges in graphs is to assign the
diagonal matrix entry value to the edge weight attribute
(or the number 1 if the edge has no weight attribute). If the
alternate convention of doubling the edge weight is desired the
resulting Scipy sparse matrix can be modified as follows:
>>> G = nx.Graph([(1, 1)])
>>> A = nx.adjacency_matrix(G)
>>> print(A.todense())
[[1]]
>>> A.setdiag(A.diagonal() * 2)
>>> print(A.todense())
[[2]]
See Also
--------
to_numpy_array
to_scipy_sparse_array
to_dict_of_dicts
adjacency_spectrum
"""
import warnings
warnings.warn(
"adjacency_matrix will return a scipy.sparse array instead of a matrix in Networkx 3.0.",
FutureWarning,
stacklevel=2,
)
# TODO: Change to `to_scipy_sparse_array` for networkx 3.0
return nx.to_scipy_sparse_matrix(G, nodelist=nodelist, dtype=dtype, weight=weight)
def _adj_matrix_warning(G, nodelist=None, dtype=None, weight="weight"):
import warnings
warnings.warn(
(
"adj_matrix is deprecated and will be removed in version 3.0.\n"
"Use `adjacency_matrix` instead\n"
),
DeprecationWarning,
stacklevel=2,
)
return adjacency_matrix(G, nodelist, dtype, weight)
adj_matrix = _adj_matrix_warning