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from_numpy_array(A, parallel_edges=False, create_using=None)

The 2D NumPy array is interpreted as an adjacency matrix for the graph.

Notes

For directed graphs, explicitly mention create_using=nx.DiGraph, and entry i,j of A corresponds to an edge from i to j.

If :None:None:`create_using` is networkx.MultiGraph or networkx.MultiDiGraph , :None:None:`parallel_edges` is True, and the entries of A are of type int , then this function returns a multigraph (of the same type as :None:None:`create_using`) with parallel edges.

If :None:None:`create_using` indicates an undirected multigraph, then only the edges indicated by the upper triangle of the array A will be added to the graph.

If the NumPy array has a single data type for each array entry it will be converted to an appropriate Python data type.

If the NumPy array has a user-specified compound data type the names of the data fields will be used as attribute keys in the resulting NetworkX graph.

Parameters

A : a 2D numpy.ndarray

An adjacency matrix representation of a graph

parallel_edges : Boolean

If this is True, :None:None:`create_using` is a multigraph, and A is an integer array, then entry (i, j) in the array is interpreted as the number of parallel edges joining vertices i and j in the graph. If it is False, then the entries in the array are interpreted as the weight of a single edge joining the vertices.

create_using : NetworkX graph constructor, optional (default=nx.Graph)

Graph type to create. If graph instance, then cleared before populated.

Returns a graph from a 2D NumPy array.

See Also

to_numpy_array

Examples

Simple integer weights on edges:

>>> import numpy as np
... A = np.array([[1, 1], [2, 1]])
... G = nx.from_numpy_array(A)
... G.edges(data=True) EdgeDataView([(0, 0, {'weight': 1}), (0, 1, {'weight': 2}), (1, 1, {'weight': 1})])

If :None:None:`create_using` indicates a multigraph and the array has only integer entries and :None:None:`parallel_edges` is False, then the entries will be treated as weights for edges joining the nodes (without creating parallel edges):

>>> A = np.array([[1, 1], [1, 2]])
... G = nx.from_numpy_array(A, create_using=nx.MultiGraph)
... G[1][1] AtlasView({0: {'weight': 2}})

If :None:None:`create_using` indicates a multigraph and the array has only integer entries and :None:None:`parallel_edges` is True, then the entries will be treated as the number of parallel edges joining those two vertices:

>>> A = np.array([[1, 1], [1, 2]])
... temp = nx.MultiGraph()
... G = nx.from_numpy_array(A, parallel_edges=True, create_using=temp)
... G[1][1] AtlasView({0: {'weight': 1}, 1: {'weight': 1}})

User defined compound data type on edges:

>>> dt = [("weight", float), ("cost", int)]
... A = np.array([[(1.0, 2)]], dtype=dt)
... G = nx.from_numpy_array(A)
... G.edges() EdgeView([(0, 0)])
>>> G[0][0]["cost"]
2
>>> G[0][0]["weight"]
1.0
See :

Back References

The following pages refer to to this document either explicitly or contain code examples using this.

networkx.convert_matrix networkx.convert_matrix.to_numpy_array networkx.convert_matrix.from_numpy_array networkx.algorithms.bipartite.matrix.from_biadjacency_matrix

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GitHub : /networkx/convert_matrix.py#1511
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