Intelegentny_Pszczelarz/.venv/Lib/site-packages/scipy/sparse/__init__.py

"""
=====================================
Sparse matrices (:mod:`scipy.sparse`)
=====================================

.. currentmodule:: scipy.sparse

SciPy 2-D sparse array package for numeric data.

.. note::

   This package is switching to an array interface, compatible with
   NumPy arrays, from the older matrix interface.  We recommend that
   you use the array objects (`bsr_array`, `coo_array`, etc.) for
   all new work.

   When using the array interface, please note that:

   - ``x * y`` no longer performs matrix multiplication, but
     element-wise multiplication (just like with NumPy arrays).  To
     make code work with both arrays and matrices, use ``x @ y`` for
     matrix multiplication.
   - Operations such as `sum`, that used to produce dense matrices, now
     produce arrays, whose multiplication behavior differs similarly.
   - Sparse arrays currently must be two-dimensional.  This also means
     that all *slicing* operations on these objects must produce
     two-dimensional results, or they will result in an error. This
     will be addressed in a future version.

   The construction utilities (`eye`, `kron`, `random`, `diags`, etc.)
   have not yet been ported, but their results can be wrapped into arrays::

     A = csr_array(eye(3))

Contents
========

Sparse array classes
--------------------

.. autosummary::
   :toctree: generated/

   bsr_array - Block Sparse Row array
   coo_array - A sparse array in COOrdinate format
   csc_array - Compressed Sparse Column array
   csr_array - Compressed Sparse Row array
   dia_array - Sparse array with DIAgonal storage
   dok_array - Dictionary Of Keys based sparse array
   lil_array - Row-based list of lists sparse array

Sparse matrix classes
---------------------

.. autosummary::
   :toctree: generated/

   bsr_matrix - Block Sparse Row matrix
   coo_matrix - A sparse matrix in COOrdinate format
   csc_matrix - Compressed Sparse Column matrix
   csr_matrix - Compressed Sparse Row matrix
   dia_matrix - Sparse matrix with DIAgonal storage
   dok_matrix - Dictionary Of Keys based sparse matrix
   lil_matrix - Row-based list of lists sparse matrix
   spmatrix - Sparse matrix base class

Functions
---------

Building sparse matrices:

.. autosummary::
   :toctree: generated/

   eye - Sparse MxN matrix whose k-th diagonal is all ones
   identity - Identity matrix in sparse format
   kron - kronecker product of two sparse matrices
   kronsum - kronecker sum of sparse matrices
   diags - Return a sparse matrix from diagonals
   spdiags - Return a sparse matrix from diagonals
   block_diag - Build a block diagonal sparse matrix
   tril - Lower triangular portion of a matrix in sparse format
   triu - Upper triangular portion of a matrix in sparse format
   bmat - Build a sparse matrix from sparse sub-blocks
   hstack - Stack sparse matrices horizontally (column wise)
   vstack - Stack sparse matrices vertically (row wise)
   rand - Random values in a given shape
   random - Random values in a given shape

Save and load sparse matrices:

.. autosummary::
   :toctree: generated/

   save_npz - Save a sparse matrix to a file using ``.npz`` format.
   load_npz - Load a sparse matrix from a file using ``.npz`` format.

Sparse matrix tools:

.. autosummary::
   :toctree: generated/

   find

Identifying sparse matrices:

.. autosummary::
   :toctree: generated/

   issparse
   isspmatrix
   isspmatrix_csc
   isspmatrix_csr
   isspmatrix_bsr
   isspmatrix_lil
   isspmatrix_dok
   isspmatrix_coo
   isspmatrix_dia

Submodules
----------

.. autosummary::

   csgraph - Compressed sparse graph routines
   linalg - sparse linear algebra routines

Exceptions
----------

.. autosummary::
   :toctree: generated/

   SparseEfficiencyWarning
   SparseWarning


Usage information
=================

There are seven available sparse matrix types:

    1. csc_matrix: Compressed Sparse Column format
    2. csr_matrix: Compressed Sparse Row format
    3. bsr_matrix: Block Sparse Row format
    4. lil_matrix: List of Lists format
    5. dok_matrix: Dictionary of Keys format
    6. coo_matrix: COOrdinate format (aka IJV, triplet format)
    7. dia_matrix: DIAgonal format

To construct a matrix efficiently, use either dok_matrix or lil_matrix.
The lil_matrix class supports basic slicing and fancy indexing with a
similar syntax to NumPy arrays. As illustrated below, the COO format
may also be used to efficiently construct matrices. Despite their
similarity to NumPy arrays, it is **strongly discouraged** to use NumPy
functions directly on these matrices because NumPy may not properly convert
them for computations, leading to unexpected (and incorrect) results. If you
do want to apply a NumPy function to these matrices, first check if SciPy has
its own implementation for the given sparse matrix class, or **convert the
sparse matrix to a NumPy array** (e.g., using the `toarray()` method of the
class) first before applying the method.

To perform manipulations such as multiplication or inversion, first
convert the matrix to either CSC or CSR format. The lil_matrix format is
row-based, so conversion to CSR is efficient, whereas conversion to CSC
is less so.

All conversions among the CSR, CSC, and COO formats are efficient,
linear-time operations.

Matrix vector product
---------------------
To do a vector product between a sparse matrix and a vector simply use
the matrix `dot` method, as described in its docstring:

>>> import numpy as np
>>> from scipy.sparse import csr_matrix
>>> A = csr_matrix([[1, 2, 0], [0, 0, 3], [4, 0, 5]])
>>> v = np.array([1, 0, -1])
>>> A.dot(v)
array([ 1, -3, -1], dtype=int64)

.. warning:: As of NumPy 1.7, `np.dot` is not aware of sparse matrices,
  therefore using it will result on unexpected results or errors.
  The corresponding dense array should be obtained first instead:

  >>> np.dot(A.toarray(), v)
  array([ 1, -3, -1], dtype=int64)

  but then all the performance advantages would be lost.

The CSR format is specially suitable for fast matrix vector products.

Example 1
---------
Construct a 1000x1000 lil_matrix and add some values to it:

>>> from scipy.sparse import lil_matrix
>>> from scipy.sparse.linalg import spsolve
>>> from numpy.linalg import solve, norm
>>> from numpy.random import rand

>>> A = lil_matrix((1000, 1000))
>>> A[0, :100] = rand(100)
>>> A[1, 100:200] = A[0, :100]
>>> A.setdiag(rand(1000))

Now convert it to CSR format and solve A x = b for x:

>>> A = A.tocsr()
>>> b = rand(1000)
>>> x = spsolve(A, b)

Convert it to a dense matrix and solve, and check that the result
is the same:

>>> x_ = solve(A.toarray(), b)

Now we can compute norm of the error with:

>>> err = norm(x-x_)
>>> err < 1e-10
True

It should be small :)


Example 2
---------

Construct a matrix in COO format:

>>> from scipy import sparse
>>> from numpy import array
>>> I = array([0,3,1,0])
>>> J = array([0,3,1,2])
>>> V = array([4,5,7,9])
>>> A = sparse.coo_matrix((V,(I,J)),shape=(4,4))

Notice that the indices do not need to be sorted.

Duplicate (i,j) entries are summed when converting to CSR or CSC.

>>> I = array([0,0,1,3,1,0,0])
>>> J = array([0,2,1,3,1,0,0])
>>> V = array([1,1,1,1,1,1,1])
>>> B = sparse.coo_matrix((V,(I,J)),shape=(4,4)).tocsr()

This is useful for constructing finite-element stiffness and mass matrices.

Further details
---------------

CSR column indices are not necessarily sorted. Likewise for CSC row
indices. Use the .sorted_indices() and .sort_indices() methods when
sorted indices are required (e.g., when passing data to other libraries).

"""

# Original code by Travis Oliphant.
# Modified and extended by Ed Schofield, Robert Cimrman,
# Nathan Bell, and Jake Vanderplas.

import warnings as _warnings

from ._base import *
from ._csr import *
from ._csc import *
from ._lil import *
from ._dok import *
from ._coo import *
from ._dia import *
from ._bsr import *
from ._construct import *
from ._extract import *
from ._matrix_io import *

from ._arrays import (
    csr_array, csc_array, lil_array, dok_array, coo_array, dia_array, bsr_array
)

# For backward compatibility with v0.19.
from . import csgraph

# Deprecated namespaces, to be removed in v2.0.0
from . import (
    base, bsr, compressed, construct, coo, csc, csr, data, dia, dok, extract,
    lil, sparsetools, sputils
)

__all__ = [s for s in dir() if not s.startswith('_')]

# Filter PendingDeprecationWarning for np.matrix introduced with numpy 1.15
_warnings.filterwarnings('ignore', message='the matrix subclass is not the recommended way')

from scipy._lib._testutils import PytestTester
test = PytestTester(__name__)
del PytestTester
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`"""`
			`=====================================`
			Sparse matrices (:mod:`scipy.sparse`)
			`=====================================`

			`.. currentmodule:: scipy.sparse`

			`SciPy 2-D sparse array package for numeric data.`

			`.. note::`

			`This package is switching to an array interface, compatible with`
			`NumPy arrays, from the older matrix interface. We recommend that`
			you use the array objects (`bsr_array`, `coo_array`, etc.) for
			`all new work.`

			`When using the array interface, please note that:`

			- ``x * y`` no longer performs matrix multiplication, but
			`element-wise multiplication (just like with NumPy arrays). To`
			make code work with both arrays and matrices, use ``x @ y`` for
			`matrix multiplication.`
			- Operations such as `sum`, that used to produce dense matrices, now
			`produce arrays, whose multiplication behavior differs similarly.`
			`- Sparse arrays currently must be two-dimensional. This also means`
			`that all slicing operations on these objects must produce`
			`two-dimensional results, or they will result in an error. This`
			`will be addressed in a future version.`

			The construction utilities (`eye`, `kron`, `random`, `diags`, etc.)
			`have not yet been ported, but their results can be wrapped into arrays::`

			`A = csr_array(eye(3))`

			`Contents`
			`========`

			`Sparse array classes`
			`--------------------`

			`.. autosummary::`
			`:toctree: generated/`

			`bsr_array - Block Sparse Row array`
			`coo_array - A sparse array in COOrdinate format`
			`csc_array - Compressed Sparse Column array`
			`csr_array - Compressed Sparse Row array`
			`dia_array - Sparse array with DIAgonal storage`
			`dok_array - Dictionary Of Keys based sparse array`
			`lil_array - Row-based list of lists sparse array`

			`Sparse matrix classes`
			`---------------------`

			`.. autosummary::`
			`:toctree: generated/`

			`bsr_matrix - Block Sparse Row matrix`
			`coo_matrix - A sparse matrix in COOrdinate format`
			`csc_matrix - Compressed Sparse Column matrix`
			`csr_matrix - Compressed Sparse Row matrix`
			`dia_matrix - Sparse matrix with DIAgonal storage`
			`dok_matrix - Dictionary Of Keys based sparse matrix`
			`lil_matrix - Row-based list of lists sparse matrix`
			`spmatrix - Sparse matrix base class`

			`Functions`
			`---------`

			`Building sparse matrices:`

			`.. autosummary::`
			`:toctree: generated/`

			`eye - Sparse MxN matrix whose k-th diagonal is all ones`
			`identity - Identity matrix in sparse format`
			`kron - kronecker product of two sparse matrices`
			`kronsum - kronecker sum of sparse matrices`
			`diags - Return a sparse matrix from diagonals`
			`spdiags - Return a sparse matrix from diagonals`
			`block_diag - Build a block diagonal sparse matrix`
			`tril - Lower triangular portion of a matrix in sparse format`
			`triu - Upper triangular portion of a matrix in sparse format`
			`bmat - Build a sparse matrix from sparse sub-blocks`
			`hstack - Stack sparse matrices horizontally (column wise)`
			`vstack - Stack sparse matrices vertically (row wise)`
			`rand - Random values in a given shape`
			`random - Random values in a given shape`

			`Save and load sparse matrices:`

			`.. autosummary::`
			`:toctree: generated/`

			save_npz - Save a sparse matrix to a file using ``.npz`` format.
			load_npz - Load a sparse matrix from a file using ``.npz`` format.

			`Sparse matrix tools:`

			`.. autosummary::`
			`:toctree: generated/`

			`find`

			`Identifying sparse matrices:`

			`.. autosummary::`
			`:toctree: generated/`

			`issparse`
			`isspmatrix`
			`isspmatrix_csc`
			`isspmatrix_csr`
			`isspmatrix_bsr`
			`isspmatrix_lil`
			`isspmatrix_dok`
			`isspmatrix_coo`
			`isspmatrix_dia`

			`Submodules`
			`----------`

			`.. autosummary::`

			`csgraph - Compressed sparse graph routines`
			`linalg - sparse linear algebra routines`

			`Exceptions`
			`----------`

			`.. autosummary::`
			`:toctree: generated/`

			`SparseEfficiencyWarning`
			`SparseWarning`


			`Usage information`
			`=================`

			`There are seven available sparse matrix types:`

			`1. csc_matrix: Compressed Sparse Column format`
			`2. csr_matrix: Compressed Sparse Row format`
			`3. bsr_matrix: Block Sparse Row format`
			`4. lil_matrix: List of Lists format`
			`5. dok_matrix: Dictionary of Keys format`
			`6. coo_matrix: COOrdinate format (aka IJV, triplet format)`
			`7. dia_matrix: DIAgonal format`

			`To construct a matrix efficiently, use either dok_matrix or lil_matrix.`
			`The lil_matrix class supports basic slicing and fancy indexing with a`
			`similar syntax to NumPy arrays. As illustrated below, the COO format`
			`may also be used to efficiently construct matrices. Despite their`
			`similarity to NumPy arrays, it is strongly discouraged to use NumPy`
			`functions directly on these matrices because NumPy may not properly convert`
			`them for computations, leading to unexpected (and incorrect) results. If you`
			`do want to apply a NumPy function to these matrices, first check if SciPy has`
			`its own implementation for the given sparse matrix class, or **convert the`
			sparse matrix to a NumPy array** (e.g., using the `toarray()` method of the
			`class) first before applying the method.`

			`To perform manipulations such as multiplication or inversion, first`
			`convert the matrix to either CSC or CSR format. The lil_matrix format is`
			`row-based, so conversion to CSR is efficient, whereas conversion to CSC`
			`is less so.`

			`All conversions among the CSR, CSC, and COO formats are efficient,`
			`linear-time operations.`

			`Matrix vector product`
			`---------------------`
			`To do a vector product between a sparse matrix and a vector simply use`
			the matrix `dot` method, as described in its docstring:

			`>>> import numpy as np`
			`>>> from scipy.sparse import csr_matrix`
			`>>> A = csr_matrix([[1, 2, 0], [0, 0, 3], [4, 0, 5]])`
			`>>> v = np.array([1, 0, -1])`
			`>>> A.dot(v)`
			`array([ 1, -3, -1], dtype=int64)`

			.. warning:: As of NumPy 1.7, `np.dot` is not aware of sparse matrices,
			`therefore using it will result on unexpected results or errors.`
			`The corresponding dense array should be obtained first instead:`

			`>>> np.dot(A.toarray(), v)`
			`array([ 1, -3, -1], dtype=int64)`

			`but then all the performance advantages would be lost.`

			`The CSR format is specially suitable for fast matrix vector products.`

			`Example 1`
			`---------`
			`Construct a 1000x1000 lil_matrix and add some values to it:`

			`>>> from scipy.sparse import lil_matrix`
			`>>> from scipy.sparse.linalg import spsolve`
			`>>> from numpy.linalg import solve, norm`
			`>>> from numpy.random import rand`

			`>>> A = lil_matrix((1000, 1000))`
			`>>> A[0, :100] = rand(100)`
			`>>> A[1, 100:200] = A[0, :100]`
			`>>> A.setdiag(rand(1000))`

			`Now convert it to CSR format and solve A x = b for x:`

			`>>> A = A.tocsr()`
			`>>> b = rand(1000)`
			`>>> x = spsolve(A, b)`

			`Convert it to a dense matrix and solve, and check that the result`
			`is the same:`

			`>>> x_ = solve(A.toarray(), b)`

			`Now we can compute norm of the error with:`

			`>>> err = norm(x-x_)`
			`>>> err < 1e-10`
			`True`

			`It should be small :)`


			`Example 2`
			`---------`

			`Construct a matrix in COO format:`

			`>>> from scipy import sparse`
			`>>> from numpy import array`
			`>>> I = array([0,3,1,0])`
			`>>> J = array([0,3,1,2])`
			`>>> V = array([4,5,7,9])`
			`>>> A = sparse.coo_matrix((V,(I,J)),shape=(4,4))`

			`Notice that the indices do not need to be sorted.`

			`Duplicate (i,j) entries are summed when converting to CSR or CSC.`

			`>>> I = array([0,0,1,3,1,0,0])`
			`>>> J = array([0,2,1,3,1,0,0])`
			`>>> V = array([1,1,1,1,1,1,1])`
			`>>> B = sparse.coo_matrix((V,(I,J)),shape=(4,4)).tocsr()`

			`This is useful for constructing finite-element stiffness and mass matrices.`

			`Further details`
			`---------------`

			`CSR column indices are not necessarily sorted. Likewise for CSC row`
			`indices. Use the .sorted_indices() and .sort_indices() methods when`
			`sorted indices are required (e.g., when passing data to other libraries).`

			`"""`

			`# Original code by Travis Oliphant.`
			`# Modified and extended by Ed Schofield, Robert Cimrman,`
			`# Nathan Bell, and Jake Vanderplas.`

			`import warnings as _warnings`

			`from ._base import *`
			`from ._csr import *`
			`from ._csc import *`
			`from ._lil import *`
			`from ._dok import *`
			`from ._coo import *`
			`from ._dia import *`
			`from ._bsr import *`
			`from ._construct import *`
			`from ._extract import *`
			`from ._matrix_io import *`

			`from ._arrays import (`
			`csr_array, csc_array, lil_array, dok_array, coo_array, dia_array, bsr_array`
			`)`

			`# For backward compatibility with v0.19.`
			`from . import csgraph`

			`# Deprecated namespaces, to be removed in v2.0.0`
			`from . import (`
			`base, bsr, compressed, construct, coo, csc, csr, data, dia, dok, extract,`
			`lil, sparsetools, sputils`
			`)`

			`__all__ = [s for s in dir() if not s.startswith('_')]`

			`# Filter PendingDeprecationWarning for np.matrix introduced with numpy 1.15`
			`_warnings.filterwarnings('ignore', message='the matrix subclass is not the recommended way')`

			`from scipy._lib._testutils import PytestTester`
			`test = PytestTester(__name__)`
			`del PytestTester`