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704 lines
21 KiB
Python
704 lines
21 KiB
Python
"""Abstract linear algebra library.
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This module defines a class hierarchy that implements a kind of "lazy"
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matrix representation, called the ``LinearOperator``. It can be used to do
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linear algebra with extremely large sparse or structured matrices, without
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representing those explicitly in memory. Such matrices can be added,
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multiplied, transposed, etc.
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As a motivating example, suppose you want have a matrix where almost all of
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the elements have the value one. The standard sparse matrix representation
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skips the storage of zeros, but not ones. By contrast, a LinearOperator is
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able to represent such matrices efficiently. First, we need a compact way to
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represent an all-ones matrix::
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>>> import numpy as np
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>>> class Ones(LinearOperator):
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... def __init__(self, shape):
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... super(Ones, self).__init__(dtype=None, shape=shape)
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... def _matvec(self, x):
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... return np.repeat(x.sum(), self.shape[0])
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Instances of this class emulate ``np.ones(shape)``, but using a constant
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amount of storage, independent of ``shape``. The ``_matvec`` method specifies
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how this linear operator multiplies with (operates on) a vector. We can now
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add this operator to a sparse matrix that stores only offsets from one::
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>>> from scipy.sparse import csr_matrix
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>>> offsets = csr_matrix([[1, 0, 2], [0, -1, 0], [0, 0, 3]])
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>>> A = aslinearoperator(offsets) + Ones(offsets.shape)
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>>> A.dot([1, 2, 3])
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array([13, 4, 15])
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The result is the same as that given by its dense, explicitly-stored
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counterpart::
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>>> (np.ones(A.shape, A.dtype) + offsets.toarray()).dot([1, 2, 3])
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array([13, 4, 15])
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Several algorithms in the ``scipy.sparse`` library are able to operate on
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``LinearOperator`` instances.
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"""
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from __future__ import division, print_function, absolute_import
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import warnings
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import numpy as np
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from scipy.sparse import isspmatrix
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from scipy.sparse.sputils import isshape, isintlike
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__all__ = ['LinearOperator', 'aslinearoperator']
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class LinearOperator(object):
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"""Common interface for performing matrix vector products
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Many iterative methods (e.g. cg, gmres) do not need to know the
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individual entries of a matrix to solve a linear system A*x=b.
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Such solvers only require the computation of matrix vector
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products, A*v where v is a dense vector. This class serves as
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an abstract interface between iterative solvers and matrix-like
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objects.
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To construct a concrete LinearOperator, either pass appropriate
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callables to the constructor of this class, or subclass it.
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A subclass must implement either one of the methods ``_matvec``
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and ``_matmat``, and the attributes/properties ``shape`` (pair of
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integers) and ``dtype`` (may be None). It may call the ``__init__``
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on this class to have these attributes validated. Implementing
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``_matvec`` automatically implements ``_matmat`` (using a naive
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algorithm) and vice-versa.
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Optionally, a subclass may implement ``_rmatvec`` or ``_adjoint``
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to implement the Hermitian adjoint (conjugate transpose). As with
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``_matvec`` and ``_matmat``, implementing either ``_rmatvec`` or
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``_adjoint`` implements the other automatically. Implementing
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``_adjoint`` is preferable; ``_rmatvec`` is mostly there for
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backwards compatibility.
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Parameters
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----------
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shape : tuple
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Matrix dimensions (M,N).
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matvec : callable f(v)
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Returns returns A * v.
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rmatvec : callable f(v)
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Returns A^H * v, where A^H is the conjugate transpose of A.
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matmat : callable f(V)
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Returns A * V, where V is a dense matrix with dimensions (N,K).
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dtype : dtype
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Data type of the matrix.
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Attributes
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----------
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args : tuple
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For linear operators describing products etc. of other linear
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operators, the operands of the binary operation.
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See Also
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--------
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aslinearoperator : Construct LinearOperators
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Notes
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-----
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The user-defined matvec() function must properly handle the case
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where v has shape (N,) as well as the (N,1) case. The shape of
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the return type is handled internally by LinearOperator.
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LinearOperator instances can also be multiplied, added with each
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other and exponentiated, all lazily: the result of these operations
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is always a new, composite LinearOperator, that defers linear
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operations to the original operators and combines the results.
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Examples
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--------
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>>> import numpy as np
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>>> from scipy.sparse.linalg import LinearOperator
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>>> def mv(v):
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... return np.array([2*v[0], 3*v[1]])
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...
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>>> A = LinearOperator((2,2), matvec=mv)
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>>> A
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<2x2 _CustomLinearOperator with dtype=float64>
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>>> A.matvec(np.ones(2))
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array([ 2., 3.])
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>>> A * np.ones(2)
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array([ 2., 3.])
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"""
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def __new__(cls, *args, **kwargs):
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if cls is LinearOperator:
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# Operate as _CustomLinearOperator factory.
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return super(LinearOperator, cls).__new__(_CustomLinearOperator)
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else:
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obj = super(LinearOperator, cls).__new__(cls)
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if (type(obj)._matvec == LinearOperator._matvec
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and type(obj)._matmat == LinearOperator._matmat):
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warnings.warn("LinearOperator subclass should implement"
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" at least one of _matvec and _matmat.",
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category=RuntimeWarning, stacklevel=2)
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return obj
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def __init__(self, dtype, shape):
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"""Initialize this LinearOperator.
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To be called by subclasses. ``dtype`` may be None; ``shape`` should
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be convertible to a length-2 tuple.
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"""
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if dtype is not None:
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dtype = np.dtype(dtype)
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shape = tuple(shape)
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if not isshape(shape):
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raise ValueError("invalid shape %r (must be 2-d)" % (shape,))
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self.dtype = dtype
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self.shape = shape
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def _init_dtype(self):
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"""Called from subclasses at the end of the __init__ routine.
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"""
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if self.dtype is None:
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v = np.zeros(self.shape[-1])
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self.dtype = np.asarray(self.matvec(v)).dtype
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def _matmat(self, X):
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"""Default matrix-matrix multiplication handler.
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Falls back on the user-defined _matvec method, so defining that will
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define matrix multiplication (though in a very suboptimal way).
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"""
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return np.hstack([self.matvec(col.reshape(-1,1)) for col in X.T])
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def _matvec(self, x):
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"""Default matrix-vector multiplication handler.
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If self is a linear operator of shape (M, N), then this method will
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be called on a shape (N,) or (N, 1) ndarray, and should return a
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shape (M,) or (M, 1) ndarray.
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This default implementation falls back on _matmat, so defining that
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will define matrix-vector multiplication as well.
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"""
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return self.matmat(x.reshape(-1, 1))
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def matvec(self, x):
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"""Matrix-vector multiplication.
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Performs the operation y=A*x where A is an MxN linear
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operator and x is a column vector or 1-d array.
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Parameters
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----------
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x : {matrix, ndarray}
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An array with shape (N,) or (N,1).
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Returns
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-------
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y : {matrix, ndarray}
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A matrix or ndarray with shape (M,) or (M,1) depending
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on the type and shape of the x argument.
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Notes
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-----
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This matvec wraps the user-specified matvec routine or overridden
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_matvec method to ensure that y has the correct shape and type.
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"""
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x = np.asanyarray(x)
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M,N = self.shape
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if x.shape != (N,) and x.shape != (N,1):
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raise ValueError('dimension mismatch')
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y = self._matvec(x)
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if isinstance(x, np.matrix):
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y = np.asmatrix(y)
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else:
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y = np.asarray(y)
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if x.ndim == 1:
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y = y.reshape(M)
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elif x.ndim == 2:
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y = y.reshape(M,1)
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else:
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raise ValueError('invalid shape returned by user-defined matvec()')
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return y
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def rmatvec(self, x):
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"""Adjoint matrix-vector multiplication.
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Performs the operation y = A^H * x where A is an MxN linear
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operator and x is a column vector or 1-d array.
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Parameters
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----------
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x : {matrix, ndarray}
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An array with shape (M,) or (M,1).
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Returns
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-------
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y : {matrix, ndarray}
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A matrix or ndarray with shape (N,) or (N,1) depending
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on the type and shape of the x argument.
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Notes
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-----
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This rmatvec wraps the user-specified rmatvec routine or overridden
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_rmatvec method to ensure that y has the correct shape and type.
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"""
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x = np.asanyarray(x)
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M,N = self.shape
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if x.shape != (M,) and x.shape != (M,1):
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raise ValueError('dimension mismatch')
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y = self._rmatvec(x)
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if isinstance(x, np.matrix):
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y = np.asmatrix(y)
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else:
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y = np.asarray(y)
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if x.ndim == 1:
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y = y.reshape(N)
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elif x.ndim == 2:
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y = y.reshape(N,1)
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else:
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raise ValueError('invalid shape returned by user-defined rmatvec()')
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return y
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def _rmatvec(self, x):
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"""Default implementation of _rmatvec; defers to adjoint."""
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if type(self)._adjoint == LinearOperator._adjoint:
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# _adjoint not overridden, prevent infinite recursion
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raise NotImplementedError
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else:
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return self.H.matvec(x)
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def matmat(self, X):
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"""Matrix-matrix multiplication.
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Performs the operation y=A*X where A is an MxN linear
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operator and X dense N*K matrix or ndarray.
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Parameters
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----------
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X : {matrix, ndarray}
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An array with shape (N,K).
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Returns
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-------
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Y : {matrix, ndarray}
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A matrix or ndarray with shape (M,K) depending on
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the type of the X argument.
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Notes
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-----
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This matmat wraps any user-specified matmat routine or overridden
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_matmat method to ensure that y has the correct type.
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"""
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X = np.asanyarray(X)
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if X.ndim != 2:
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raise ValueError('expected 2-d ndarray or matrix, not %d-d'
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% X.ndim)
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M,N = self.shape
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if X.shape[0] != N:
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raise ValueError('dimension mismatch: %r, %r'
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% (self.shape, X.shape))
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Y = self._matmat(X)
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if isinstance(Y, np.matrix):
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Y = np.asmatrix(Y)
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return Y
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def __call__(self, x):
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return self*x
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def __mul__(self, x):
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return self.dot(x)
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def dot(self, x):
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"""Matrix-matrix or matrix-vector multiplication.
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Parameters
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----------
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x : array_like
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1-d or 2-d array, representing a vector or matrix.
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Returns
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-------
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Ax : array
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1-d or 2-d array (depending on the shape of x) that represents
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the result of applying this linear operator on x.
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"""
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if isinstance(x, LinearOperator):
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return _ProductLinearOperator(self, x)
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elif np.isscalar(x):
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return _ScaledLinearOperator(self, x)
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else:
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x = np.asarray(x)
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if x.ndim == 1 or x.ndim == 2 and x.shape[1] == 1:
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return self.matvec(x)
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elif x.ndim == 2:
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return self.matmat(x)
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else:
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raise ValueError('expected 1-d or 2-d array or matrix, got %r'
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% x)
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def __matmul__(self, other):
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if np.isscalar(other):
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raise ValueError("Scalar operands are not allowed, "
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"use '*' instead")
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return self.__mul__(other)
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def __rmatmul__(self, other):
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if np.isscalar(other):
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raise ValueError("Scalar operands are not allowed, "
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"use '*' instead")
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return self.__rmul__(other)
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def __rmul__(self, x):
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if np.isscalar(x):
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return _ScaledLinearOperator(self, x)
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else:
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return NotImplemented
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def __pow__(self, p):
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if np.isscalar(p):
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return _PowerLinearOperator(self, p)
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else:
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return NotImplemented
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def __add__(self, x):
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if isinstance(x, LinearOperator):
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return _SumLinearOperator(self, x)
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else:
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return NotImplemented
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def __neg__(self):
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return _ScaledLinearOperator(self, -1)
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def __sub__(self, x):
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return self.__add__(-x)
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def __repr__(self):
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M,N = self.shape
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if self.dtype is None:
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dt = 'unspecified dtype'
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else:
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dt = 'dtype=' + str(self.dtype)
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return '<%dx%d %s with %s>' % (M, N, self.__class__.__name__, dt)
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def adjoint(self):
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"""Hermitian adjoint.
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Returns the Hermitian adjoint of self, aka the Hermitian
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conjugate or Hermitian transpose. For a complex matrix, the
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Hermitian adjoint is equal to the conjugate transpose.
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Can be abbreviated self.H instead of self.adjoint().
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Returns
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-------
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A_H : LinearOperator
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Hermitian adjoint of self.
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"""
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return self._adjoint()
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H = property(adjoint)
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def transpose(self):
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"""Transpose this linear operator.
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Returns a LinearOperator that represents the transpose of this one.
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Can be abbreviated self.T instead of self.transpose().
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"""
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return self._transpose()
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T = property(transpose)
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def _adjoint(self):
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"""Default implementation of _adjoint; defers to rmatvec."""
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shape = (self.shape[1], self.shape[0])
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return _CustomLinearOperator(shape, matvec=self.rmatvec,
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rmatvec=self.matvec,
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dtype=self.dtype)
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class _CustomLinearOperator(LinearOperator):
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"""Linear operator defined in terms of user-specified operations."""
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def __init__(self, shape, matvec, rmatvec=None, matmat=None, dtype=None):
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super(_CustomLinearOperator, self).__init__(dtype, shape)
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self.args = ()
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self.__matvec_impl = matvec
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self.__rmatvec_impl = rmatvec
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self.__matmat_impl = matmat
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self._init_dtype()
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def _matmat(self, X):
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if self.__matmat_impl is not None:
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return self.__matmat_impl(X)
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else:
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return super(_CustomLinearOperator, self)._matmat(X)
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def _matvec(self, x):
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return self.__matvec_impl(x)
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def _rmatvec(self, x):
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func = self.__rmatvec_impl
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if func is None:
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raise NotImplementedError("rmatvec is not defined")
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return self.__rmatvec_impl(x)
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def _adjoint(self):
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return _CustomLinearOperator(shape=(self.shape[1], self.shape[0]),
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matvec=self.__rmatvec_impl,
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rmatvec=self.__matvec_impl,
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dtype=self.dtype)
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def _get_dtype(operators, dtypes=None):
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if dtypes is None:
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dtypes = []
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for obj in operators:
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if obj is not None and hasattr(obj, 'dtype'):
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dtypes.append(obj.dtype)
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return np.find_common_type(dtypes, [])
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class _SumLinearOperator(LinearOperator):
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def __init__(self, A, B):
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if not isinstance(A, LinearOperator) or \
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not isinstance(B, LinearOperator):
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raise ValueError('both operands have to be a LinearOperator')
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if A.shape != B.shape:
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raise ValueError('cannot add %r and %r: shape mismatch'
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% (A, B))
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self.args = (A, B)
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super(_SumLinearOperator, self).__init__(_get_dtype([A, B]), A.shape)
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def _matvec(self, x):
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return self.args[0].matvec(x) + self.args[1].matvec(x)
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def _rmatvec(self, x):
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return self.args[0].rmatvec(x) + self.args[1].rmatvec(x)
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def _matmat(self, x):
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return self.args[0].matmat(x) + self.args[1].matmat(x)
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def _adjoint(self):
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A, B = self.args
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return A.H + B.H
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class _ProductLinearOperator(LinearOperator):
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def __init__(self, A, B):
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if not isinstance(A, LinearOperator) or \
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not isinstance(B, LinearOperator):
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raise ValueError('both operands have to be a LinearOperator')
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if A.shape[1] != B.shape[0]:
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raise ValueError('cannot multiply %r and %r: shape mismatch'
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% (A, B))
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super(_ProductLinearOperator, self).__init__(_get_dtype([A, B]),
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(A.shape[0], B.shape[1]))
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self.args = (A, B)
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def _matvec(self, x):
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return self.args[0].matvec(self.args[1].matvec(x))
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def _rmatvec(self, x):
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return self.args[1].rmatvec(self.args[0].rmatvec(x))
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def _matmat(self, x):
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return self.args[0].matmat(self.args[1].matmat(x))
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def _adjoint(self):
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A, B = self.args
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return B.H * A.H
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class _ScaledLinearOperator(LinearOperator):
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def __init__(self, A, alpha):
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if not isinstance(A, LinearOperator):
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raise ValueError('LinearOperator expected as A')
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if not np.isscalar(alpha):
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raise ValueError('scalar expected as alpha')
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dtype = _get_dtype([A], [type(alpha)])
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super(_ScaledLinearOperator, self).__init__(dtype, A.shape)
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self.args = (A, alpha)
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def _matvec(self, x):
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return self.args[1] * self.args[0].matvec(x)
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def _rmatvec(self, x):
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return np.conj(self.args[1]) * self.args[0].rmatvec(x)
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def _matmat(self, x):
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return self.args[1] * self.args[0].matmat(x)
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def _adjoint(self):
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A, alpha = self.args
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return A.H * np.conj(alpha)
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class _PowerLinearOperator(LinearOperator):
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def __init__(self, A, p):
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if not isinstance(A, LinearOperator):
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raise ValueError('LinearOperator expected as A')
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if A.shape[0] != A.shape[1]:
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raise ValueError('square LinearOperator expected, got %r' % A)
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if not isintlike(p) or p < 0:
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raise ValueError('non-negative integer expected as p')
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super(_PowerLinearOperator, self).__init__(_get_dtype([A]), A.shape)
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self.args = (A, p)
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def _power(self, fun, x):
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res = np.array(x, copy=True)
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for i in range(self.args[1]):
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res = fun(res)
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return res
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def _matvec(self, x):
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return self._power(self.args[0].matvec, x)
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def _rmatvec(self, x):
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return self._power(self.args[0].rmatvec, x)
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def _matmat(self, x):
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return self._power(self.args[0].matmat, x)
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def _adjoint(self):
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A, p = self.args
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return A.H ** p
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class MatrixLinearOperator(LinearOperator):
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def __init__(self, A):
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super(MatrixLinearOperator, self).__init__(A.dtype, A.shape)
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self.A = A
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self.__adj = None
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self.args = (A,)
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def _matmat(self, X):
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return self.A.dot(X)
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def _adjoint(self):
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if self.__adj is None:
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self.__adj = _AdjointMatrixOperator(self)
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return self.__adj
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class _AdjointMatrixOperator(MatrixLinearOperator):
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def __init__(self, adjoint):
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self.A = adjoint.A.T.conj()
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self.__adjoint = adjoint
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self.args = (adjoint,)
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self.shape = adjoint.shape[1], adjoint.shape[0]
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@property
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def dtype(self):
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return self.__adjoint.dtype
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def _adjoint(self):
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return self.__adjoint
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class IdentityOperator(LinearOperator):
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def __init__(self, shape, dtype=None):
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super(IdentityOperator, self).__init__(dtype, shape)
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def _matvec(self, x):
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return x
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def _rmatvec(self, x):
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return x
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def _matmat(self, x):
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return x
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def _adjoint(self):
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return self
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def aslinearoperator(A):
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"""Return A as a LinearOperator.
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'A' may be any of the following types:
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- ndarray
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- matrix
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- sparse matrix (e.g. csr_matrix, lil_matrix, etc.)
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- LinearOperator
|
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- An object with .shape and .matvec attributes
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|
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See the LinearOperator documentation for additional information.
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Notes
|
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-----
|
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If 'A' has no .dtype attribute, the data type is determined by calling
|
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:func:`LinearOperator.matvec()` - set the .dtype attribute to prevent this
|
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call upon the linear operator creation.
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Examples
|
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--------
|
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>>> from scipy.sparse.linalg import aslinearoperator
|
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>>> M = np.array([[1,2,3],[4,5,6]], dtype=np.int32)
|
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>>> aslinearoperator(M)
|
|
<2x3 MatrixLinearOperator with dtype=int32>
|
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"""
|
|
if isinstance(A, LinearOperator):
|
|
return A
|
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|
|
elif isinstance(A, np.ndarray) or isinstance(A, np.matrix):
|
|
if A.ndim > 2:
|
|
raise ValueError('array must have ndim <= 2')
|
|
A = np.atleast_2d(np.asarray(A))
|
|
return MatrixLinearOperator(A)
|
|
|
|
elif isspmatrix(A):
|
|
return MatrixLinearOperator(A)
|
|
|
|
else:
|
|
if hasattr(A, 'shape') and hasattr(A, 'matvec'):
|
|
rmatvec = None
|
|
dtype = None
|
|
|
|
if hasattr(A, 'rmatvec'):
|
|
rmatvec = A.rmatvec
|
|
if hasattr(A, 'dtype'):
|
|
dtype = A.dtype
|
|
return LinearOperator(A.shape, A.matvec,
|
|
rmatvec=rmatvec, dtype=dtype)
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|
|
|
else:
|
|
raise TypeError('type not understood')
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