forked from 170010011/fr
861 lines
26 KiB
Python
861 lines
26 KiB
Python
"""Functions to construct sparse matrices
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"""
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__docformat__ = "restructuredtext en"
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__all__ = ['spdiags', 'eye', 'identity', 'kron', 'kronsum',
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'hstack', 'vstack', 'bmat', 'rand', 'random', 'diags', 'block_diag']
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import numbers
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from functools import partial
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import numpy as np
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from scipy._lib._util import check_random_state, rng_integers
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from .sputils import upcast, get_index_dtype, isscalarlike
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from .csr import csr_matrix
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from .csc import csc_matrix
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from .bsr import bsr_matrix
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from .coo import coo_matrix
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from .dia import dia_matrix
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from .base import issparse
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def spdiags(data, diags, m, n, format=None):
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"""
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Return a sparse matrix from diagonals.
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Parameters
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----------
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data : array_like
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matrix diagonals stored row-wise
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diags : diagonals to set
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- k = 0 the main diagonal
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- k > 0 the k-th upper diagonal
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- k < 0 the k-th lower diagonal
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m, n : int
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shape of the result
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format : str, optional
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Format of the result. By default (format=None) an appropriate sparse
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matrix format is returned. This choice is subject to change.
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See Also
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--------
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diags : more convenient form of this function
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dia_matrix : the sparse DIAgonal format.
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Examples
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--------
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>>> from scipy.sparse import spdiags
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>>> data = np.array([[1, 2, 3, 4], [1, 2, 3, 4], [1, 2, 3, 4]])
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>>> diags = np.array([0, -1, 2])
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>>> spdiags(data, diags, 4, 4).toarray()
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array([[1, 0, 3, 0],
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[1, 2, 0, 4],
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[0, 2, 3, 0],
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[0, 0, 3, 4]])
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"""
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return dia_matrix((data, diags), shape=(m,n)).asformat(format)
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def diags(diagonals, offsets=0, shape=None, format=None, dtype=None):
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"""
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Construct a sparse matrix from diagonals.
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Parameters
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----------
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diagonals : sequence of array_like
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Sequence of arrays containing the matrix diagonals,
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corresponding to `offsets`.
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offsets : sequence of int or an int, optional
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Diagonals to set:
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- k = 0 the main diagonal (default)
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- k > 0 the kth upper diagonal
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- k < 0 the kth lower diagonal
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shape : tuple of int, optional
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Shape of the result. If omitted, a square matrix large enough
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to contain the diagonals is returned.
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format : {"dia", "csr", "csc", "lil", ...}, optional
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Matrix format of the result. By default (format=None) an
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appropriate sparse matrix format is returned. This choice is
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subject to change.
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dtype : dtype, optional
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Data type of the matrix.
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See Also
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--------
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spdiags : construct matrix from diagonals
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Notes
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-----
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This function differs from `spdiags` in the way it handles
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off-diagonals.
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The result from `diags` is the sparse equivalent of::
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np.diag(diagonals[0], offsets[0])
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+ ...
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+ np.diag(diagonals[k], offsets[k])
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Repeated diagonal offsets are disallowed.
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.. versionadded:: 0.11
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Examples
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--------
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>>> from scipy.sparse import diags
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>>> diagonals = [[1, 2, 3, 4], [1, 2, 3], [1, 2]]
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>>> diags(diagonals, [0, -1, 2]).toarray()
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array([[1, 0, 1, 0],
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[1, 2, 0, 2],
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[0, 2, 3, 0],
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[0, 0, 3, 4]])
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Broadcasting of scalars is supported (but shape needs to be
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specified):
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>>> diags([1, -2, 1], [-1, 0, 1], shape=(4, 4)).toarray()
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array([[-2., 1., 0., 0.],
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[ 1., -2., 1., 0.],
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[ 0., 1., -2., 1.],
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[ 0., 0., 1., -2.]])
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If only one diagonal is wanted (as in `numpy.diag`), the following
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works as well:
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>>> diags([1, 2, 3], 1).toarray()
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array([[ 0., 1., 0., 0.],
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[ 0., 0., 2., 0.],
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[ 0., 0., 0., 3.],
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[ 0., 0., 0., 0.]])
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"""
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# if offsets is not a sequence, assume that there's only one diagonal
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if isscalarlike(offsets):
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# now check that there's actually only one diagonal
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if len(diagonals) == 0 or isscalarlike(diagonals[0]):
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diagonals = [np.atleast_1d(diagonals)]
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else:
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raise ValueError("Different number of diagonals and offsets.")
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else:
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diagonals = list(map(np.atleast_1d, diagonals))
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offsets = np.atleast_1d(offsets)
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# Basic check
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if len(diagonals) != len(offsets):
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raise ValueError("Different number of diagonals and offsets.")
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# Determine shape, if omitted
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if shape is None:
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m = len(diagonals[0]) + abs(int(offsets[0]))
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shape = (m, m)
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# Determine data type, if omitted
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if dtype is None:
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dtype = np.common_type(*diagonals)
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# Construct data array
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m, n = shape
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M = max([min(m + offset, n - offset) + max(0, offset)
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for offset in offsets])
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M = max(0, M)
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data_arr = np.zeros((len(offsets), M), dtype=dtype)
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K = min(m, n)
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for j, diagonal in enumerate(diagonals):
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offset = offsets[j]
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k = max(0, offset)
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length = min(m + offset, n - offset, K)
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if length < 0:
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raise ValueError("Offset %d (index %d) out of bounds" % (offset, j))
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try:
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data_arr[j, k:k+length] = diagonal[...,:length]
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except ValueError as e:
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if len(diagonal) != length and len(diagonal) != 1:
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raise ValueError(
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"Diagonal length (index %d: %d at offset %d) does not "
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"agree with matrix size (%d, %d)." % (
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j, len(diagonal), offset, m, n)) from e
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raise
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return dia_matrix((data_arr, offsets), shape=(m, n)).asformat(format)
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def identity(n, dtype='d', format=None):
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"""Identity matrix in sparse format
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Returns an identity matrix with shape (n,n) using a given
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sparse format and dtype.
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Parameters
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----------
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n : int
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Shape of the identity matrix.
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dtype : dtype, optional
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Data type of the matrix
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format : str, optional
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Sparse format of the result, e.g., format="csr", etc.
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Examples
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--------
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>>> from scipy.sparse import identity
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>>> identity(3).toarray()
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array([[ 1., 0., 0.],
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[ 0., 1., 0.],
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[ 0., 0., 1.]])
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>>> identity(3, dtype='int8', format='dia')
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<3x3 sparse matrix of type '<class 'numpy.int8'>'
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with 3 stored elements (1 diagonals) in DIAgonal format>
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"""
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return eye(n, n, dtype=dtype, format=format)
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def eye(m, n=None, k=0, dtype=float, format=None):
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"""Sparse matrix with ones on diagonal
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Returns a sparse (m x n) matrix where the kth diagonal
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is all ones and everything else is zeros.
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Parameters
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----------
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m : int
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Number of rows in the matrix.
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n : int, optional
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Number of columns. Default: `m`.
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k : int, optional
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Diagonal to place ones on. Default: 0 (main diagonal).
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dtype : dtype, optional
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Data type of the matrix.
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format : str, optional
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Sparse format of the result, e.g., format="csr", etc.
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Examples
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--------
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>>> from scipy import sparse
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>>> sparse.eye(3).toarray()
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array([[ 1., 0., 0.],
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[ 0., 1., 0.],
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[ 0., 0., 1.]])
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>>> sparse.eye(3, dtype=np.int8)
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<3x3 sparse matrix of type '<class 'numpy.int8'>'
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with 3 stored elements (1 diagonals) in DIAgonal format>
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"""
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if n is None:
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n = m
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m,n = int(m),int(n)
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if m == n and k == 0:
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# fast branch for special formats
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if format in ['csr', 'csc']:
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idx_dtype = get_index_dtype(maxval=n)
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indptr = np.arange(n+1, dtype=idx_dtype)
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indices = np.arange(n, dtype=idx_dtype)
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data = np.ones(n, dtype=dtype)
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cls = {'csr': csr_matrix, 'csc': csc_matrix}[format]
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return cls((data,indices,indptr),(n,n))
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elif format == 'coo':
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idx_dtype = get_index_dtype(maxval=n)
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row = np.arange(n, dtype=idx_dtype)
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col = np.arange(n, dtype=idx_dtype)
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data = np.ones(n, dtype=dtype)
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return coo_matrix((data,(row,col)),(n,n))
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diags = np.ones((1, max(0, min(m + k, n))), dtype=dtype)
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return spdiags(diags, k, m, n).asformat(format)
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def kron(A, B, format=None):
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"""kronecker product of sparse matrices A and B
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Parameters
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----------
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A : sparse or dense matrix
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first matrix of the product
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B : sparse or dense matrix
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second matrix of the product
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format : str, optional
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format of the result (e.g. "csr")
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Returns
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-------
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kronecker product in a sparse matrix format
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Examples
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--------
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>>> from scipy import sparse
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>>> A = sparse.csr_matrix(np.array([[0, 2], [5, 0]]))
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>>> B = sparse.csr_matrix(np.array([[1, 2], [3, 4]]))
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>>> sparse.kron(A, B).toarray()
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array([[ 0, 0, 2, 4],
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[ 0, 0, 6, 8],
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[ 5, 10, 0, 0],
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[15, 20, 0, 0]])
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>>> sparse.kron(A, [[1, 2], [3, 4]]).toarray()
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array([[ 0, 0, 2, 4],
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[ 0, 0, 6, 8],
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[ 5, 10, 0, 0],
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[15, 20, 0, 0]])
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"""
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B = coo_matrix(B)
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if (format is None or format == "bsr") and 2*B.nnz >= B.shape[0] * B.shape[1]:
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# B is fairly dense, use BSR
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A = csr_matrix(A,copy=True)
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output_shape = (A.shape[0]*B.shape[0], A.shape[1]*B.shape[1])
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if A.nnz == 0 or B.nnz == 0:
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# kronecker product is the zero matrix
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return coo_matrix(output_shape).asformat(format)
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B = B.toarray()
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data = A.data.repeat(B.size).reshape(-1,B.shape[0],B.shape[1])
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data = data * B
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return bsr_matrix((data,A.indices,A.indptr), shape=output_shape)
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else:
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# use COO
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A = coo_matrix(A)
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output_shape = (A.shape[0]*B.shape[0], A.shape[1]*B.shape[1])
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if A.nnz == 0 or B.nnz == 0:
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# kronecker product is the zero matrix
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return coo_matrix(output_shape).asformat(format)
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# expand entries of a into blocks
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row = A.row.repeat(B.nnz)
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col = A.col.repeat(B.nnz)
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data = A.data.repeat(B.nnz)
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if max(A.shape[0]*B.shape[0], A.shape[1]*B.shape[1]) > np.iinfo('int32').max:
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row = row.astype(np.int64)
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col = col.astype(np.int64)
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row *= B.shape[0]
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col *= B.shape[1]
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# increment block indices
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row,col = row.reshape(-1,B.nnz),col.reshape(-1,B.nnz)
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row += B.row
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col += B.col
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row,col = row.reshape(-1),col.reshape(-1)
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# compute block entries
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data = data.reshape(-1,B.nnz) * B.data
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data = data.reshape(-1)
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return coo_matrix((data,(row,col)), shape=output_shape).asformat(format)
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def kronsum(A, B, format=None):
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"""kronecker sum of sparse matrices A and B
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Kronecker sum of two sparse matrices is a sum of two Kronecker
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products kron(I_n,A) + kron(B,I_m) where A has shape (m,m)
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and B has shape (n,n) and I_m and I_n are identity matrices
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of shape (m,m) and (n,n), respectively.
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Parameters
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----------
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A
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square matrix
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B
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square matrix
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format : str
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format of the result (e.g. "csr")
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Returns
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-------
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kronecker sum in a sparse matrix format
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Examples
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--------
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"""
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A = coo_matrix(A)
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B = coo_matrix(B)
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if A.shape[0] != A.shape[1]:
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raise ValueError('A is not square')
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if B.shape[0] != B.shape[1]:
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raise ValueError('B is not square')
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dtype = upcast(A.dtype, B.dtype)
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L = kron(eye(B.shape[0],dtype=dtype), A, format=format)
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R = kron(B, eye(A.shape[0],dtype=dtype), format=format)
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return (L+R).asformat(format) # since L + R is not always same format
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def _compressed_sparse_stack(blocks, axis):
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"""
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Stacking fast path for CSR/CSC matrices
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(i) vstack for CSR, (ii) hstack for CSC.
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"""
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other_axis = 1 if axis == 0 else 0
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data = np.concatenate([b.data for b in blocks])
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constant_dim = blocks[0].shape[other_axis]
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idx_dtype = get_index_dtype(arrays=[b.indptr for b in blocks],
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maxval=max(data.size, constant_dim))
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indices = np.empty(data.size, dtype=idx_dtype)
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indptr = np.empty(sum(b.shape[axis] for b in blocks) + 1, dtype=idx_dtype)
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last_indptr = idx_dtype(0)
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sum_dim = 0
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sum_indices = 0
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for b in blocks:
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if b.shape[other_axis] != constant_dim:
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raise ValueError('incompatible dimensions for axis %d' % other_axis)
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indices[sum_indices:sum_indices+b.indices.size] = b.indices
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sum_indices += b.indices.size
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idxs = slice(sum_dim, sum_dim + b.shape[axis])
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indptr[idxs] = b.indptr[:-1]
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indptr[idxs] += last_indptr
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sum_dim += b.shape[axis]
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last_indptr += b.indptr[-1]
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indptr[-1] = last_indptr
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if axis == 0:
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return csr_matrix((data, indices, indptr),
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shape=(sum_dim, constant_dim))
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else:
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return csc_matrix((data, indices, indptr),
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shape=(constant_dim, sum_dim))
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def hstack(blocks, format=None, dtype=None):
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"""
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Stack sparse matrices horizontally (column wise)
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Parameters
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----------
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blocks
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sequence of sparse matrices with compatible shapes
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format : str
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sparse format of the result (e.g., "csr")
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by default an appropriate sparse matrix format is returned.
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This choice is subject to change.
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dtype : dtype, optional
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The data-type of the output matrix. If not given, the dtype is
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determined from that of `blocks`.
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See Also
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--------
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vstack : stack sparse matrices vertically (row wise)
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Examples
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--------
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>>> from scipy.sparse import coo_matrix, hstack
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>>> A = coo_matrix([[1, 2], [3, 4]])
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>>> B = coo_matrix([[5], [6]])
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>>> hstack([A,B]).toarray()
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array([[1, 2, 5],
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[3, 4, 6]])
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"""
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return bmat([blocks], format=format, dtype=dtype)
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def vstack(blocks, format=None, dtype=None):
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"""
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Stack sparse matrices vertically (row wise)
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Parameters
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----------
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blocks
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sequence of sparse matrices with compatible shapes
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format : str, optional
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sparse format of the result (e.g., "csr")
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by default an appropriate sparse matrix format is returned.
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This choice is subject to change.
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dtype : dtype, optional
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The data-type of the output matrix. If not given, the dtype is
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determined from that of `blocks`.
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See Also
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--------
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hstack : stack sparse matrices horizontally (column wise)
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Examples
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--------
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>>> from scipy.sparse import coo_matrix, vstack
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>>> A = coo_matrix([[1, 2], [3, 4]])
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>>> B = coo_matrix([[5, 6]])
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>>> vstack([A, B]).toarray()
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array([[1, 2],
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[3, 4],
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[5, 6]])
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"""
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return bmat([[b] for b in blocks], format=format, dtype=dtype)
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def bmat(blocks, format=None, dtype=None):
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"""
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Build a sparse matrix from sparse sub-blocks
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Parameters
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----------
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blocks : array_like
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Grid of sparse matrices with compatible shapes.
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An entry of None implies an all-zero matrix.
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format : {'bsr', 'coo', 'csc', 'csr', 'dia', 'dok', 'lil'}, optional
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The sparse format of the result (e.g. "csr"). By default an
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appropriate sparse matrix format is returned.
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This choice is subject to change.
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dtype : dtype, optional
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The data-type of the output matrix. If not given, the dtype is
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determined from that of `blocks`.
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Returns
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-------
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bmat : sparse matrix
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See Also
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--------
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block_diag, diags
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Examples
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--------
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>>> from scipy.sparse import coo_matrix, bmat
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>>> A = coo_matrix([[1, 2], [3, 4]])
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>>> B = coo_matrix([[5], [6]])
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>>> C = coo_matrix([[7]])
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>>> bmat([[A, B], [None, C]]).toarray()
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array([[1, 2, 5],
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[3, 4, 6],
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[0, 0, 7]])
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>>> bmat([[A, None], [None, C]]).toarray()
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array([[1, 2, 0],
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[3, 4, 0],
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[0, 0, 7]])
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"""
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blocks = np.asarray(blocks, dtype='object')
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if blocks.ndim != 2:
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raise ValueError('blocks must be 2-D')
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M,N = blocks.shape
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# check for fast path cases
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if (N == 1 and format in (None, 'csr') and all(isinstance(b, csr_matrix)
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for b in blocks.flat)):
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A = _compressed_sparse_stack(blocks[:,0], 0)
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if dtype is not None:
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A = A.astype(dtype)
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return A
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elif (M == 1 and format in (None, 'csc')
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and all(isinstance(b, csc_matrix) for b in blocks.flat)):
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A = _compressed_sparse_stack(blocks[0,:], 1)
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if dtype is not None:
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A = A.astype(dtype)
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return A
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block_mask = np.zeros(blocks.shape, dtype=bool)
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brow_lengths = np.zeros(M, dtype=np.int64)
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bcol_lengths = np.zeros(N, dtype=np.int64)
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# convert everything to COO format
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for i in range(M):
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for j in range(N):
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if blocks[i,j] is not None:
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A = coo_matrix(blocks[i,j])
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blocks[i,j] = A
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block_mask[i,j] = True
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if brow_lengths[i] == 0:
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brow_lengths[i] = A.shape[0]
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elif brow_lengths[i] != A.shape[0]:
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msg = ('blocks[{i},:] has incompatible row dimensions. '
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'Got blocks[{i},{j}].shape[0] == {got}, '
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'expected {exp}.'.format(i=i, j=j,
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exp=brow_lengths[i],
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got=A.shape[0]))
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raise ValueError(msg)
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if bcol_lengths[j] == 0:
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bcol_lengths[j] = A.shape[1]
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elif bcol_lengths[j] != A.shape[1]:
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msg = ('blocks[:,{j}] has incompatible row dimensions. '
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'Got blocks[{i},{j}].shape[1] == {got}, '
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'expected {exp}.'.format(i=i, j=j,
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exp=bcol_lengths[j],
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got=A.shape[1]))
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raise ValueError(msg)
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nnz = sum(block.nnz for block in blocks[block_mask])
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if dtype is None:
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all_dtypes = [blk.dtype for blk in blocks[block_mask]]
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dtype = upcast(*all_dtypes) if all_dtypes else None
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row_offsets = np.append(0, np.cumsum(brow_lengths))
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col_offsets = np.append(0, np.cumsum(bcol_lengths))
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shape = (row_offsets[-1], col_offsets[-1])
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data = np.empty(nnz, dtype=dtype)
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idx_dtype = get_index_dtype(maxval=max(shape))
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row = np.empty(nnz, dtype=idx_dtype)
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col = np.empty(nnz, dtype=idx_dtype)
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nnz = 0
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ii, jj = np.nonzero(block_mask)
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for i, j in zip(ii, jj):
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B = blocks[i, j]
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idx = slice(nnz, nnz + B.nnz)
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data[idx] = B.data
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row[idx] = B.row + row_offsets[i]
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col[idx] = B.col + col_offsets[j]
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nnz += B.nnz
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return coo_matrix((data, (row, col)), shape=shape).asformat(format)
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def block_diag(mats, format=None, dtype=None):
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"""
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Build a block diagonal sparse matrix from provided matrices.
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Parameters
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----------
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mats : sequence of matrices
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Input matrices.
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format : str, optional
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The sparse format of the result (e.g., "csr"). If not given, the matrix
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is returned in "coo" format.
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dtype : dtype specifier, optional
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The data-type of the output matrix. If not given, the dtype is
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determined from that of `blocks`.
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Returns
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-------
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res : sparse matrix
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Notes
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-----
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.. versionadded:: 0.11.0
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See Also
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--------
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bmat, diags
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Examples
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--------
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>>> from scipy.sparse import coo_matrix, block_diag
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>>> A = coo_matrix([[1, 2], [3, 4]])
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>>> B = coo_matrix([[5], [6]])
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>>> C = coo_matrix([[7]])
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>>> block_diag((A, B, C)).toarray()
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array([[1, 2, 0, 0],
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[3, 4, 0, 0],
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[0, 0, 5, 0],
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[0, 0, 6, 0],
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[0, 0, 0, 7]])
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"""
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row = []
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col = []
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data = []
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r_idx = 0
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c_idx = 0
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for a in mats:
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if isinstance(a, (list, numbers.Number)):
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a = coo_matrix(a)
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nrows, ncols = a.shape
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if issparse(a):
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a = a.tocoo()
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row.append(a.row + r_idx)
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col.append(a.col + c_idx)
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data.append(a.data)
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else:
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a_row, a_col = np.divmod(np.arange(nrows*ncols), ncols)
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row.append(a_row + r_idx)
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col.append(a_col + c_idx)
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data.append(a.ravel())
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r_idx += nrows
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c_idx += ncols
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row = np.concatenate(row)
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col = np.concatenate(col)
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data = np.concatenate(data)
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return coo_matrix((data, (row, col)),
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shape=(r_idx, c_idx),
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dtype=dtype).asformat(format)
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def random(m, n, density=0.01, format='coo', dtype=None,
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random_state=None, data_rvs=None):
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"""Generate a sparse matrix of the given shape and density with randomly
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distributed values.
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Parameters
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----------
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m, n : int
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shape of the matrix
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density : real, optional
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density of the generated matrix: density equal to one means a full
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matrix, density of 0 means a matrix with no non-zero items.
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format : str, optional
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sparse matrix format.
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dtype : dtype, optional
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type of the returned matrix values.
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random_state : {numpy.random.RandomState, int}, optional
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Random number generator or random seed. If not given, the singleton
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numpy.random will be used. This random state will be used
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for sampling the sparsity structure, but not necessarily for sampling
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the values of the structurally nonzero entries of the matrix.
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data_rvs : callable, optional
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Samples a requested number of random values.
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This function should take a single argument specifying the length
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of the ndarray that it will return. The structurally nonzero entries
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of the sparse random matrix will be taken from the array sampled
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by this function. By default, uniform [0, 1) random values will be
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sampled using the same random state as is used for sampling
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the sparsity structure.
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Returns
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-------
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res : sparse matrix
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Notes
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-----
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Only float types are supported for now.
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Examples
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--------
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>>> from scipy.sparse import random
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>>> from scipy import stats
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>>> class CustomRandomState(np.random.RandomState):
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... def randint(self, k):
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... i = np.random.randint(k)
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... return i - i % 2
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>>> np.random.seed(12345)
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>>> rs = CustomRandomState()
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>>> rvs = stats.poisson(25, loc=10).rvs
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>>> S = random(3, 4, density=0.25, random_state=rs, data_rvs=rvs)
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>>> S.A
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array([[ 36., 0., 33., 0.], # random
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[ 0., 0., 0., 0.],
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[ 0., 0., 36., 0.]])
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>>> from scipy.sparse import random
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>>> from scipy.stats import rv_continuous
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>>> class CustomDistribution(rv_continuous):
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... def _rvs(self, size=None, random_state=None):
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... return random_state.randn(*size)
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>>> X = CustomDistribution(seed=2906)
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>>> Y = X() # get a frozen version of the distribution
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>>> S = random(3, 4, density=0.25, random_state=2906, data_rvs=Y.rvs)
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>>> S.A
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array([[ 0. , 0. , 0. , 0. ],
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[ 0.13569738, 1.9467163 , -0.81205367, 0. ],
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[ 0. , 0. , 0. , 0. ]])
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"""
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if density < 0 or density > 1:
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raise ValueError("density expected to be 0 <= density <= 1")
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dtype = np.dtype(dtype)
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mn = m * n
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tp = np.intc
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if mn > np.iinfo(tp).max:
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tp = np.int64
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if mn > np.iinfo(tp).max:
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msg = """\
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Trying to generate a random sparse matrix such as the product of dimensions is
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greater than %d - this is not supported on this machine
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"""
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raise ValueError(msg % np.iinfo(tp).max)
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# Number of non zero values
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k = int(round(density * m * n))
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random_state = check_random_state(random_state)
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if data_rvs is None:
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if np.issubdtype(dtype, np.integer):
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def data_rvs(n):
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return rng_integers(random_state,
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np.iinfo(dtype).min,
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np.iinfo(dtype).max,
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n,
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dtype=dtype)
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elif np.issubdtype(dtype, np.complexfloating):
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def data_rvs(n):
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return (random_state.uniform(size=n) +
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random_state.uniform(size=n) * 1j)
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else:
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data_rvs = partial(random_state.uniform, 0., 1.)
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ind = random_state.choice(mn, size=k, replace=False)
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j = np.floor(ind * 1. / m).astype(tp, copy=False)
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i = (ind - j * m).astype(tp, copy=False)
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vals = data_rvs(k).astype(dtype, copy=False)
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return coo_matrix((vals, (i, j)), shape=(m, n)).asformat(format,
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copy=False)
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|
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def rand(m, n, density=0.01, format="coo", dtype=None, random_state=None):
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"""Generate a sparse matrix of the given shape and density with uniformly
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distributed values.
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Parameters
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----------
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m, n : int
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shape of the matrix
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density : real, optional
|
|
density of the generated matrix: density equal to one means a full
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matrix, density of 0 means a matrix with no non-zero items.
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format : str, optional
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sparse matrix format.
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dtype : dtype, optional
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|
type of the returned matrix values.
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random_state : {numpy.random.RandomState, int, np.random.Generator}, optional
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Random number generator or random seed. If not given, the singleton
|
|
numpy.random will be used.
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Returns
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-------
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res : sparse matrix
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Notes
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|
-----
|
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Only float types are supported for now.
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|
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See Also
|
|
--------
|
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scipy.sparse.random : Similar function that allows a user-specified random
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data source.
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Examples
|
|
--------
|
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>>> from scipy.sparse import rand
|
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>>> matrix = rand(3, 4, density=0.25, format="csr", random_state=42)
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>>> matrix
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<3x4 sparse matrix of type '<class 'numpy.float64'>'
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with 3 stored elements in Compressed Sparse Row format>
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>>> matrix.todense()
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matrix([[0.05641158, 0. , 0. , 0.65088847],
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[0. , 0. , 0. , 0.14286682],
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[0. , 0. , 0. , 0. ]])
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"""
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return random(m, n, density, format, dtype, random_state)
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