# Source code for gemseo.algos.linear_solvers.linear_problem

```
# -*- coding: utf-8 -*-
# Copyright 2021 IRT Saint Exupéry, https://www.irt-saintexupery.com
#
# This program is free software; you can redistribute it and/or
# modify it under the terms of the GNU Lesser General Public
# License version 3 as published by the Free Software Foundation.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
# Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with this program; if not, write to the Free Software Foundation,
# Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
# Contributors:
# INITIAL AUTHORS - API and implementation and/or documentation
# :author: Francois Gallard
# OTHER AUTHORS - MACROSCOPIC CHANGES
"""Linear equations problem."""
import logging
from typing import Optional, Union
import matplotlib.pyplot as plt
from matplotlib.figure import Figure
from numpy import ndarray
from numpy.linalg import norm
from scipy.sparse import spmatrix
from scipy.sparse.linalg import LinearOperator
LOGGER = logging.getLogger(__name__)
[docs]class LinearProblem(object):
"""Represent the linear equations system ``lhs.x = rhs``.
It also contains the solution, and some properties of the system such as the symmetry
or positive definiteness.
Attributes:
rhs (ndarray): The right hand side of the equation.
lhs (ndarray, LinearOperator, sparse): The left hand side of the equation.
If None, the problem can't be solved and the user has to set it after init.
solution (ndarray): The current solution of the problem.
is_converged (bool): If the solution is_converged.
convergence_info (int, str): The information provided by the solver if convergence
occured or not.
is_symmetric (bool): Whether the LHS is symmetric.
is_positive_def (bool): Whether the LHS is positive definite.
is_lhs_linear_operator (bool): Whether the LHS is symmetric. XXX
solver_options (Dict[str, XXX]): The options passed to the solver.
solver_name (str): The solver name.
residuals_history (List[float]): The convergence history of residuals.
"""
def __init__(
self,
lhs, # type: Union[ndarray, spmatrix, LinearOperator]
rhs=None, # type: Optional[ndarray]
solution=None, # type: Optional[ndarray]
is_symmetric=False, # type : bool
is_positive_def=False, # type : bool
is_converged=None, # type : Optional[bool]
): # type: (...) -> None
"""
Args:
lhs: The left hand side (matrix or linear operator) of the problem.
If None, XXX.
rhs: The right hand side (vector) of the problem.
If None, XXX.
solution: The current solution.
is_symmetric: Whether to assume that the LHS is symmetric.
is_positive_def: Whether to assume that the LHS is positive definite.
is_converged: Whether the solution is converged to the specified tolerance.
If False, the algorithm stopped before convergence.
If None, no run was performed.
"""
self.rhs = rhs
self.lhs = lhs
self.solution = solution
self.is_converged = is_converged
self.convergence_info = None
self.is_symmetric = is_symmetric
self.is_positive_def = is_positive_def
if isinstance(lhs, LinearOperator):
self.is_lhs_linear_operator = True
else:
self.is_lhs_linear_operator = False
self.solver_options = None
self.solver_name = None
self.residuals_history = None
[docs] def compute_residuals(
self,
relative_residuals=True, # type : bool
store=False, # type : bool
current_x=None, # type : Optional[ndarray]
): # type: (...) -> ndarray
"""Compute the L2 norm of the residuals of the problem.
Args:
relative_residuals: If True, return norm(lhs.solution-rhs)/norm(rhs),
else return norm(lhs.solution-rhs).
store: Whether to store the residuals value in the residuals_history attribute.
current_x: Compute the residuals associated with current_x,
If None, compute then from the solution attribute.
Returns:
The residuals value.
Raises:
ValueError: If self.solution is None and current_x is None.
"""
if self.rhs is None:
raise ValueError("Missing RHS.")
if current_x is None:
current_x = self.solution
if self.solution is None:
raise ValueError("Missing solution.")
res = norm(self.lhs.dot(current_x) - self.rhs)
if relative_residuals:
res /= norm(self.rhs)
if store:
if self.residuals_history is None:
self.residuals_history = []
self.residuals_history.append(res)
return res
[docs] def plot_residuals(self): # type: (...) -> Figure
"""Plot the residuals convergence in log scale.
Returns:
The matplotlib figure.
Raises:
ValueError: When the residuals history is empty.
"""
if self.residuals_history is None or len(self.residuals_history) == 0:
raise ValueError(
"Residuals history is empty. "
" Use the 'store_residuals' option for the solver."
)
fig = plt.figure(figsize=(11, 6))
plt.plot(self.residuals_history, color="black", lw=2)
ax1 = fig.gca()
ax1.set_yscale("log")
ax1.set_title("Linear solver '{}' convergence".format(self.solver_name))
ax1.set_ylabel("Residuals norm (log)")
ax1.set_xlabel("Iterations")
return fig
[docs] def check(self): # type: (...) -> None
"""Check the consistency of the dimensions of the LHS and RHS.
Raises:
ValueError: When the shapes are inconsistent.
"""
lhs_shape = self.lhs.shape
rhs_shape = self.rhs.shape
if (
(len(lhs_shape) != 2)
or (lhs_shape[0] != rhs_shape[0])
or (len(rhs_shape) != 1 and rhs_shape[-1] != 1)
):
raise ValueError(
"Incompatible dimensions in linear system Ax=b,"
" A shape is %s and b shape is %s",
self.lhs.shape,
self.rhs.shape,
)
```