1516 lines
61 KiB
Python
1516 lines
61 KiB
Python
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"""
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Method agnostic utility functions for linear progamming
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"""
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import numpy as np
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import scipy.sparse as sps
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from warnings import warn
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from ._optimize import OptimizeWarning
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from scipy.optimize._remove_redundancy import (
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_remove_redundancy_svd, _remove_redundancy_pivot_sparse,
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_remove_redundancy_pivot_dense, _remove_redundancy_id
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)
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from collections import namedtuple
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_LPProblem = namedtuple('_LPProblem',
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'c A_ub b_ub A_eq b_eq bounds x0 integrality')
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_LPProblem.__new__.__defaults__ = (None,) * 7 # make c the only required arg
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_LPProblem.__doc__ = \
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""" Represents a linear-programming problem.
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Attributes
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----------
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c : 1D array
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The coefficients of the linear objective function to be minimized.
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A_ub : 2D array, optional
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The inequality constraint matrix. Each row of ``A_ub`` specifies the
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coefficients of a linear inequality constraint on ``x``.
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b_ub : 1D array, optional
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The inequality constraint vector. Each element represents an
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upper bound on the corresponding value of ``A_ub @ x``.
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A_eq : 2D array, optional
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The equality constraint matrix. Each row of ``A_eq`` specifies the
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coefficients of a linear equality constraint on ``x``.
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b_eq : 1D array, optional
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The equality constraint vector. Each element of ``A_eq @ x`` must equal
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the corresponding element of ``b_eq``.
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bounds : various valid formats, optional
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The bounds of ``x``, as ``min`` and ``max`` pairs.
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If bounds are specified for all N variables separately, valid formats
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are:
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* a 2D array (N x 2);
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* a sequence of N sequences, each with 2 values.
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If all variables have the same bounds, the bounds can be specified as
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a 1-D or 2-D array or sequence with 2 scalar values.
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If all variables have a lower bound of 0 and no upper bound, the bounds
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parameter can be omitted (or given as None).
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Absent lower and/or upper bounds can be specified as -numpy.inf (no
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lower bound), numpy.inf (no upper bound) or None (both).
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x0 : 1D array, optional
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Guess values of the decision variables, which will be refined by
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the optimization algorithm. This argument is currently used only by the
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'revised simplex' method, and can only be used if `x0` represents a
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basic feasible solution.
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integrality : 1-D array or int, optional
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Indicates the type of integrality constraint on each decision variable.
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``0`` : Continuous variable; no integrality constraint.
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``1`` : Integer variable; decision variable must be an integer
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within `bounds`.
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``2`` : Semi-continuous variable; decision variable must be within
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`bounds` or take value ``0``.
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``3`` : Semi-integer variable; decision variable must be an integer
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within `bounds` or take value ``0``.
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By default, all variables are continuous.
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For mixed integrality constraints, supply an array of shape `c.shape`.
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To infer a constraint on each decision variable from shorter inputs,
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the argument will be broadcasted to `c.shape` using `np.broadcast_to`.
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This argument is currently used only by the ``'highs'`` method and
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ignored otherwise.
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Notes
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-----
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This namedtuple supports 2 ways of initialization:
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>>> lp1 = _LPProblem(c=[-1, 4], A_ub=[[-3, 1], [1, 2]], b_ub=[6, 4])
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>>> lp2 = _LPProblem([-1, 4], [[-3, 1], [1, 2]], [6, 4])
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Note that only ``c`` is a required argument here, whereas all other arguments
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``A_ub``, ``b_ub``, ``A_eq``, ``b_eq``, ``bounds``, ``x0`` are optional with
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default values of None.
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For example, ``A_eq`` and ``b_eq`` can be set without ``A_ub`` or ``b_ub``:
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>>> lp3 = _LPProblem(c=[-1, 4], A_eq=[[2, 1]], b_eq=[10])
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"""
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def _check_sparse_inputs(options, meth, A_ub, A_eq):
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"""
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Check the provided ``A_ub`` and ``A_eq`` matrices conform to the specified
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optional sparsity variables.
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Parameters
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----------
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A_ub : 2-D array, optional
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2-D array such that ``A_ub @ x`` gives the values of the upper-bound
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inequality constraints at ``x``.
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A_eq : 2-D array, optional
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2-D array such that ``A_eq @ x`` gives the values of the equality
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constraints at ``x``.
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options : dict
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A dictionary of solver options. All methods accept the following
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generic options:
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maxiter : int
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Maximum number of iterations to perform.
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disp : bool
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Set to True to print convergence messages.
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For method-specific options, see :func:`show_options('linprog')`.
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method : str, optional
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The algorithm used to solve the standard form problem.
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Returns
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-------
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A_ub : 2-D array, optional
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2-D array such that ``A_ub @ x`` gives the values of the upper-bound
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inequality constraints at ``x``.
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A_eq : 2-D array, optional
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2-D array such that ``A_eq @ x`` gives the values of the equality
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constraints at ``x``.
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options : dict
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A dictionary of solver options. All methods accept the following
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generic options:
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maxiter : int
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Maximum number of iterations to perform.
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disp : bool
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Set to True to print convergence messages.
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For method-specific options, see :func:`show_options('linprog')`.
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"""
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# This is an undocumented option for unit testing sparse presolve
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_sparse_presolve = options.pop('_sparse_presolve', False)
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if _sparse_presolve and A_eq is not None:
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A_eq = sps.coo_matrix(A_eq)
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if _sparse_presolve and A_ub is not None:
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A_ub = sps.coo_matrix(A_ub)
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sparse_constraint = sps.issparse(A_eq) or sps.issparse(A_ub)
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preferred_methods = {"highs", "highs-ds", "highs-ipm"}
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dense_methods = {"simplex", "revised simplex"}
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if meth in dense_methods and sparse_constraint:
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raise ValueError(f"Method '{meth}' does not support sparse "
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"constraint matrices. Please consider using one of "
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f"{preferred_methods}.")
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sparse = options.get('sparse', False)
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if not sparse and sparse_constraint and meth == 'interior-point':
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options['sparse'] = True
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warn("Sparse constraint matrix detected; setting 'sparse':True.",
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OptimizeWarning, stacklevel=4)
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return options, A_ub, A_eq
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def _format_A_constraints(A, n_x, sparse_lhs=False):
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"""Format the left hand side of the constraints to a 2-D array
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Parameters
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----------
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A : 2-D array
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2-D array such that ``A @ x`` gives the values of the upper-bound
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(in)equality constraints at ``x``.
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n_x : int
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The number of variables in the linear programming problem.
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sparse_lhs : bool
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Whether either of `A_ub` or `A_eq` are sparse. If true return a
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coo_matrix instead of a numpy array.
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Returns
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-------
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np.ndarray or sparse.coo_matrix
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2-D array such that ``A @ x`` gives the values of the upper-bound
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(in)equality constraints at ``x``.
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"""
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if sparse_lhs:
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return sps.coo_matrix(
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(0, n_x) if A is None else A, dtype=float, copy=True
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)
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elif A is None:
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return np.zeros((0, n_x), dtype=float)
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else:
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return np.array(A, dtype=float, copy=True)
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def _format_b_constraints(b):
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"""Format the upper bounds of the constraints to a 1-D array
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Parameters
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----------
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b : 1-D array
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1-D array of values representing the upper-bound of each (in)equality
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constraint (row) in ``A``.
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Returns
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-------
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1-D np.array
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1-D array of values representing the upper-bound of each (in)equality
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constraint (row) in ``A``.
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"""
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if b is None:
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return np.array([], dtype=float)
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b = np.array(b, dtype=float, copy=True).squeeze()
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return b if b.size != 1 else b.reshape((-1))
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def _clean_inputs(lp):
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"""
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Given user inputs for a linear programming problem, return the
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objective vector, upper bound constraints, equality constraints,
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and simple bounds in a preferred format.
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Parameters
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----------
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lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
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c : 1D array
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The coefficients of the linear objective function to be minimized.
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A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
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|
b_ub : 1D array, optional
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|
The inequality constraint vector. Each element represents an
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upper bound on the corresponding value of ``A_ub @ x``.
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A_eq : 2D array, optional
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The equality constraint matrix. Each row of ``A_eq`` specifies the
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coefficients of a linear equality constraint on ``x``.
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b_eq : 1D array, optional
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|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
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|
the corresponding element of ``b_eq``.
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|
bounds : various valid formats, optional
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|
The bounds of ``x``, as ``min`` and ``max`` pairs.
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|
If bounds are specified for all N variables separately, valid formats are:
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* a 2D array (2 x N or N x 2);
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* a sequence of N sequences, each with 2 values.
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If all variables have the same bounds, a single pair of values can
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be specified. Valid formats are:
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* a sequence with 2 scalar values;
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* a sequence with a single element containing 2 scalar values.
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If all variables have a lower bound of 0 and no upper bound, the bounds
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parameter can be omitted (or given as None).
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x0 : 1D array, optional
|
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|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
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|
'revised simplex' method, and can only be used if `x0` represents a
|
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|
basic feasible solution.
|
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|
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Returns
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-------
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lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
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c : 1D array
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|
The coefficients of the linear objective function to be minimized.
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||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
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|
A_eq : 2D array, optional
|
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|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
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|
coefficients of a linear equality constraint on ``x``.
|
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|
b_eq : 1D array, optional
|
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|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
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|
the corresponding element of ``b_eq``.
|
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bounds : 2D array
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The bounds of ``x``, as ``min`` and ``max`` pairs, one for each of the N
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elements of ``x``. The N x 2 array contains lower bounds in the first
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column and upper bounds in the 2nd. Unbounded variables have lower
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bound -np.inf and/or upper bound np.inf.
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x0 : 1D array, optional
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Guess values of the decision variables, which will be refined by
|
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|
the optimization algorithm. This argument is currently used only by the
|
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|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
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|
|
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"""
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c, A_ub, b_ub, A_eq, b_eq, bounds, x0, integrality = lp
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if c is None:
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raise TypeError
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try:
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c = np.array(c, dtype=np.float64, copy=True).squeeze()
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except ValueError as e:
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raise TypeError(
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"Invalid input for linprog: c must be a 1-D array of numerical "
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"coefficients") from e
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else:
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# If c is a single value, convert it to a 1-D array.
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if c.size == 1:
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c = c.reshape((-1))
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n_x = len(c)
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if n_x == 0 or len(c.shape) != 1:
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raise ValueError(
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"Invalid input for linprog: c must be a 1-D array and must "
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"not have more than one non-singleton dimension")
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if not np.isfinite(c).all():
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raise ValueError(
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"Invalid input for linprog: c must not contain values "
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"inf, nan, or None")
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sparse_lhs = sps.issparse(A_eq) or sps.issparse(A_ub)
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try:
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A_ub = _format_A_constraints(A_ub, n_x, sparse_lhs=sparse_lhs)
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except ValueError as e:
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raise TypeError(
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"Invalid input for linprog: A_ub must be a 2-D array "
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"of numerical values") from e
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else:
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n_ub = A_ub.shape[0]
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if len(A_ub.shape) != 2 or A_ub.shape[1] != n_x:
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raise ValueError(
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"Invalid input for linprog: A_ub must have exactly two "
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"dimensions, and the number of columns in A_ub must be "
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"equal to the size of c")
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if (sps.issparse(A_ub) and not np.isfinite(A_ub.data).all()
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or not sps.issparse(A_ub) and not np.isfinite(A_ub).all()):
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raise ValueError(
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"Invalid input for linprog: A_ub must not contain values "
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"inf, nan, or None")
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|
|
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try:
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b_ub = _format_b_constraints(b_ub)
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except ValueError as e:
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raise TypeError(
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|
"Invalid input for linprog: b_ub must be a 1-D array of "
|
||
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"numerical values, each representing the upper bound of an "
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"inequality constraint (row) in A_ub") from e
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else:
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if b_ub.shape != (n_ub,):
|
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raise ValueError(
|
||
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"Invalid input for linprog: b_ub must be a 1-D array; b_ub "
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"must not have more than one non-singleton dimension and "
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"the number of rows in A_ub must equal the number of values "
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"in b_ub")
|
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if not np.isfinite(b_ub).all():
|
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raise ValueError(
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"Invalid input for linprog: b_ub must not contain values "
|
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"inf, nan, or None")
|
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|
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try:
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A_eq = _format_A_constraints(A_eq, n_x, sparse_lhs=sparse_lhs)
|
||
|
except ValueError as e:
|
||
|
raise TypeError(
|
||
|
"Invalid input for linprog: A_eq must be a 2-D array "
|
||
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"of numerical values") from e
|
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else:
|
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n_eq = A_eq.shape[0]
|
||
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if len(A_eq.shape) != 2 or A_eq.shape[1] != n_x:
|
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|
raise ValueError(
|
||
|
"Invalid input for linprog: A_eq must have exactly two "
|
||
|
"dimensions, and the number of columns in A_eq must be "
|
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|
"equal to the size of c")
|
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|
|
||
|
if (sps.issparse(A_eq) and not np.isfinite(A_eq.data).all()
|
||
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or not sps.issparse(A_eq) and not np.isfinite(A_eq).all()):
|
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|
raise ValueError(
|
||
|
"Invalid input for linprog: A_eq must not contain values "
|
||
|
"inf, nan, or None")
|
||
|
|
||
|
try:
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b_eq = _format_b_constraints(b_eq)
|
||
|
except ValueError as e:
|
||
|
raise TypeError(
|
||
|
"Invalid input for linprog: b_eq must be a dense, 1-D array of "
|
||
|
"numerical values, each representing the right hand side of an "
|
||
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"equality constraint (row) in A_eq") from e
|
||
|
else:
|
||
|
if b_eq.shape != (n_eq,):
|
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|
raise ValueError(
|
||
|
"Invalid input for linprog: b_eq must be a 1-D array; b_eq "
|
||
|
"must not have more than one non-singleton dimension and "
|
||
|
"the number of rows in A_eq must equal the number of values "
|
||
|
"in b_eq")
|
||
|
if not np.isfinite(b_eq).all():
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: b_eq must not contain values "
|
||
|
"inf, nan, or None")
|
||
|
|
||
|
# x0 gives a (optional) starting solution to the solver. If x0 is None,
|
||
|
# skip the checks. Initial solution will be generated automatically.
|
||
|
if x0 is not None:
|
||
|
try:
|
||
|
x0 = np.array(x0, dtype=float, copy=True).squeeze()
|
||
|
except ValueError as e:
|
||
|
raise TypeError(
|
||
|
"Invalid input for linprog: x0 must be a 1-D array of "
|
||
|
"numerical coefficients") from e
|
||
|
if x0.ndim == 0:
|
||
|
x0 = x0.reshape((-1))
|
||
|
if len(x0) == 0 or x0.ndim != 1:
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: x0 should be a 1-D array; it "
|
||
|
"must not have more than one non-singleton dimension")
|
||
|
if not x0.size == c.size:
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: x0 and c should contain the "
|
||
|
"same number of elements")
|
||
|
if not np.isfinite(x0).all():
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: x0 must not contain values "
|
||
|
"inf, nan, or None")
|
||
|
|
||
|
# Bounds can be one of these formats:
|
||
|
# (1) a 2-D array or sequence, with shape N x 2
|
||
|
# (2) a 1-D or 2-D sequence or array with 2 scalars
|
||
|
# (3) None (or an empty sequence or array)
|
||
|
# Unspecified bounds can be represented by None or (-)np.inf.
|
||
|
# All formats are converted into a N x 2 np.array with (-)np.inf where
|
||
|
# bounds are unspecified.
|
||
|
|
||
|
# Prepare clean bounds array
|
||
|
bounds_clean = np.zeros((n_x, 2), dtype=float)
|
||
|
|
||
|
# Convert to a numpy array.
|
||
|
# np.array(..,dtype=float) raises an error if dimensions are inconsistent
|
||
|
# or if there are invalid data types in bounds. Just add a linprog prefix
|
||
|
# to the error and re-raise.
|
||
|
# Creating at least a 2-D array simplifies the cases to distinguish below.
|
||
|
if bounds is None or np.array_equal(bounds, []) or np.array_equal(bounds, [[]]):
|
||
|
bounds = (0, np.inf)
|
||
|
try:
|
||
|
bounds_conv = np.atleast_2d(np.array(bounds, dtype=float))
|
||
|
except ValueError as e:
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: unable to interpret bounds, "
|
||
|
"check values and dimensions: " + e.args[0]) from e
|
||
|
except TypeError as e:
|
||
|
raise TypeError(
|
||
|
"Invalid input for linprog: unable to interpret bounds, "
|
||
|
"check values and dimensions: " + e.args[0]) from e
|
||
|
|
||
|
# Check bounds options
|
||
|
bsh = bounds_conv.shape
|
||
|
if len(bsh) > 2:
|
||
|
# Do not try to handle multidimensional bounds input
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: provide a 2-D array for bounds, "
|
||
|
"not a {:d}-D array.".format(len(bsh)))
|
||
|
elif np.all(bsh == (n_x, 2)):
|
||
|
# Regular N x 2 array
|
||
|
bounds_clean = bounds_conv
|
||
|
elif (np.all(bsh == (2, 1)) or np.all(bsh == (1, 2))):
|
||
|
# 2 values: interpret as overall lower and upper bound
|
||
|
bounds_flat = bounds_conv.flatten()
|
||
|
bounds_clean[:, 0] = bounds_flat[0]
|
||
|
bounds_clean[:, 1] = bounds_flat[1]
|
||
|
elif np.all(bsh == (2, n_x)):
|
||
|
# Reject a 2 x N array
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: provide a {:d} x 2 array for bounds, "
|
||
|
"not a 2 x {:d} array.".format(n_x, n_x))
|
||
|
else:
|
||
|
raise ValueError(
|
||
|
"Invalid input for linprog: unable to interpret bounds with this "
|
||
|
"dimension tuple: {0}.".format(bsh))
|
||
|
|
||
|
# The process above creates nan-s where the input specified None
|
||
|
# Convert the nan-s in the 1st column to -np.inf and in the 2nd column
|
||
|
# to np.inf
|
||
|
i_none = np.isnan(bounds_clean[:, 0])
|
||
|
bounds_clean[i_none, 0] = -np.inf
|
||
|
i_none = np.isnan(bounds_clean[:, 1])
|
||
|
bounds_clean[i_none, 1] = np.inf
|
||
|
|
||
|
return _LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds_clean, x0, integrality)
|
||
|
|
||
|
|
||
|
def _presolve(lp, rr, rr_method, tol=1e-9):
|
||
|
"""
|
||
|
Given inputs for a linear programming problem in preferred format,
|
||
|
presolve the problem: identify trivial infeasibilities, redundancies,
|
||
|
and unboundedness, tighten bounds where possible, and eliminate fixed
|
||
|
variables.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
|
||
|
|
||
|
c : 1D array
|
||
|
The coefficients of the linear objective function to be minimized.
|
||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
||
|
A_eq : 2D array, optional
|
||
|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
||
|
coefficients of a linear equality constraint on ``x``.
|
||
|
b_eq : 1D array, optional
|
||
|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
||
|
the corresponding element of ``b_eq``.
|
||
|
bounds : 2D array
|
||
|
The bounds of ``x``, as ``min`` and ``max`` pairs, one for each of the N
|
||
|
elements of ``x``. The N x 2 array contains lower bounds in the first
|
||
|
column and upper bounds in the 2nd. Unbounded variables have lower
|
||
|
bound -np.inf and/or upper bound np.inf.
|
||
|
x0 : 1D array, optional
|
||
|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
||
|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
||
|
|
||
|
rr : bool
|
||
|
If ``True`` attempts to eliminate any redundant rows in ``A_eq``.
|
||
|
Set False if ``A_eq`` is known to be of full row rank, or if you are
|
||
|
looking for a potential speedup (at the expense of reliability).
|
||
|
rr_method : string
|
||
|
Method used to identify and remove redundant rows from the
|
||
|
equality constraint matrix after presolve.
|
||
|
tol : float
|
||
|
The tolerance which determines when a solution is "close enough" to
|
||
|
zero in Phase 1 to be considered a basic feasible solution or close
|
||
|
enough to positive to serve as an optimal solution.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
|
||
|
|
||
|
c : 1D array
|
||
|
The coefficients of the linear objective function to be minimized.
|
||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
||
|
A_eq : 2D array, optional
|
||
|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
||
|
coefficients of a linear equality constraint on ``x``.
|
||
|
b_eq : 1D array, optional
|
||
|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
||
|
the corresponding element of ``b_eq``.
|
||
|
bounds : 2D array
|
||
|
The bounds of ``x``, as ``min`` and ``max`` pairs, possibly tightened.
|
||
|
x0 : 1D array, optional
|
||
|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
||
|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
||
|
|
||
|
c0 : 1D array
|
||
|
Constant term in objective function due to fixed (and eliminated)
|
||
|
variables.
|
||
|
x : 1D array
|
||
|
Solution vector (when the solution is trivial and can be determined
|
||
|
in presolve)
|
||
|
revstack: list of functions
|
||
|
the functions in the list reverse the operations of _presolve()
|
||
|
the function signature is x_org = f(x_mod), where x_mod is the result
|
||
|
of a presolve step and x_org the value at the start of the step
|
||
|
(currently, the revstack contains only one function)
|
||
|
complete: bool
|
||
|
Whether the solution is complete (solved or determined to be infeasible
|
||
|
or unbounded in presolve)
|
||
|
status : int
|
||
|
An integer representing the exit status of the optimization::
|
||
|
|
||
|
0 : Optimization terminated successfully
|
||
|
1 : Iteration limit reached
|
||
|
2 : Problem appears to be infeasible
|
||
|
3 : Problem appears to be unbounded
|
||
|
4 : Serious numerical difficulties encountered
|
||
|
|
||
|
message : str
|
||
|
A string descriptor of the exit status of the optimization.
|
||
|
|
||
|
References
|
||
|
----------
|
||
|
.. [5] Andersen, Erling D. "Finding all linearly dependent rows in
|
||
|
large-scale linear programming." Optimization Methods and Software
|
||
|
6.3 (1995): 219-227.
|
||
|
.. [8] Andersen, Erling D., and Knud D. Andersen. "Presolving in linear
|
||
|
programming." Mathematical Programming 71.2 (1995): 221-245.
|
||
|
|
||
|
"""
|
||
|
# ideas from Reference [5] by Andersen and Andersen
|
||
|
# however, unlike the reference, this is performed before converting
|
||
|
# problem to standard form
|
||
|
# There are a few advantages:
|
||
|
# * artificial variables have not been added, so matrices are smaller
|
||
|
# * bounds have not been converted to constraints yet. (It is better to
|
||
|
# do that after presolve because presolve may adjust the simple bounds.)
|
||
|
# There are many improvements that can be made, namely:
|
||
|
# * implement remaining checks from [5]
|
||
|
# * loop presolve until no additional changes are made
|
||
|
# * implement additional efficiency improvements in redundancy removal [2]
|
||
|
|
||
|
c, A_ub, b_ub, A_eq, b_eq, bounds, x0, _ = lp
|
||
|
|
||
|
revstack = [] # record of variables eliminated from problem
|
||
|
# constant term in cost function may be added if variables are eliminated
|
||
|
c0 = 0
|
||
|
complete = False # complete is True if detected infeasible/unbounded
|
||
|
x = np.zeros(c.shape) # this is solution vector if completed in presolve
|
||
|
|
||
|
status = 0 # all OK unless determined otherwise
|
||
|
message = ""
|
||
|
|
||
|
# Lower and upper bounds. Copy to prevent feedback.
|
||
|
lb = bounds[:, 0].copy()
|
||
|
ub = bounds[:, 1].copy()
|
||
|
|
||
|
m_eq, n = A_eq.shape
|
||
|
m_ub, n = A_ub.shape
|
||
|
|
||
|
if (rr_method is not None
|
||
|
and rr_method.lower() not in {"svd", "pivot", "id"}):
|
||
|
message = ("'" + str(rr_method) + "' is not a valid option "
|
||
|
"for redundancy removal. Valid options are 'SVD', "
|
||
|
"'pivot', and 'ID'.")
|
||
|
raise ValueError(message)
|
||
|
|
||
|
if sps.issparse(A_eq):
|
||
|
A_eq = A_eq.tocsr()
|
||
|
A_ub = A_ub.tocsr()
|
||
|
|
||
|
def where(A):
|
||
|
return A.nonzero()
|
||
|
|
||
|
vstack = sps.vstack
|
||
|
else:
|
||
|
where = np.where
|
||
|
vstack = np.vstack
|
||
|
|
||
|
# upper bounds > lower bounds
|
||
|
if np.any(ub < lb) or np.any(lb == np.inf) or np.any(ub == -np.inf):
|
||
|
status = 2
|
||
|
message = ("The problem is (trivially) infeasible since one "
|
||
|
"or more upper bounds are smaller than the corresponding "
|
||
|
"lower bounds, a lower bound is np.inf or an upper bound "
|
||
|
"is -np.inf.")
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
|
||
|
# zero row in equality constraints
|
||
|
zero_row = np.array(np.sum(A_eq != 0, axis=1) == 0).flatten()
|
||
|
if np.any(zero_row):
|
||
|
if np.any(
|
||
|
np.logical_and(
|
||
|
zero_row,
|
||
|
np.abs(b_eq) > tol)): # test_zero_row_1
|
||
|
# infeasible if RHS is not zero
|
||
|
status = 2
|
||
|
message = ("The problem is (trivially) infeasible due to a row "
|
||
|
"of zeros in the equality constraint matrix with a "
|
||
|
"nonzero corresponding constraint value.")
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
else: # test_zero_row_2
|
||
|
# if RHS is zero, we can eliminate this equation entirely
|
||
|
A_eq = A_eq[np.logical_not(zero_row), :]
|
||
|
b_eq = b_eq[np.logical_not(zero_row)]
|
||
|
|
||
|
# zero row in inequality constraints
|
||
|
zero_row = np.array(np.sum(A_ub != 0, axis=1) == 0).flatten()
|
||
|
if np.any(zero_row):
|
||
|
if np.any(np.logical_and(zero_row, b_ub < -tol)): # test_zero_row_1
|
||
|
# infeasible if RHS is less than zero (because LHS is zero)
|
||
|
status = 2
|
||
|
message = ("The problem is (trivially) infeasible due to a row "
|
||
|
"of zeros in the equality constraint matrix with a "
|
||
|
"nonzero corresponding constraint value.")
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
else: # test_zero_row_2
|
||
|
# if LHS is >= 0, we can eliminate this constraint entirely
|
||
|
A_ub = A_ub[np.logical_not(zero_row), :]
|
||
|
b_ub = b_ub[np.logical_not(zero_row)]
|
||
|
|
||
|
# zero column in (both) constraints
|
||
|
# this indicates that a variable isn't constrained and can be removed
|
||
|
A = vstack((A_eq, A_ub))
|
||
|
if A.shape[0] > 0:
|
||
|
zero_col = np.array(np.sum(A != 0, axis=0) == 0).flatten()
|
||
|
# variable will be at upper or lower bound, depending on objective
|
||
|
x[np.logical_and(zero_col, c < 0)] = ub[
|
||
|
np.logical_and(zero_col, c < 0)]
|
||
|
x[np.logical_and(zero_col, c > 0)] = lb[
|
||
|
np.logical_and(zero_col, c > 0)]
|
||
|
if np.any(np.isinf(x)): # if an unconstrained variable has no bound
|
||
|
status = 3
|
||
|
message = ("If feasible, the problem is (trivially) unbounded "
|
||
|
"due to a zero column in the constraint matrices. If "
|
||
|
"you wish to check whether the problem is infeasible, "
|
||
|
"turn presolve off.")
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
# variables will equal upper/lower bounds will be removed later
|
||
|
lb[np.logical_and(zero_col, c < 0)] = ub[
|
||
|
np.logical_and(zero_col, c < 0)]
|
||
|
ub[np.logical_and(zero_col, c > 0)] = lb[
|
||
|
np.logical_and(zero_col, c > 0)]
|
||
|
|
||
|
# row singleton in equality constraints
|
||
|
# this fixes a variable and removes the constraint
|
||
|
singleton_row = np.array(np.sum(A_eq != 0, axis=1) == 1).flatten()
|
||
|
rows = where(singleton_row)[0]
|
||
|
cols = where(A_eq[rows, :])[1]
|
||
|
if len(rows) > 0:
|
||
|
for row, col in zip(rows, cols):
|
||
|
val = b_eq[row] / A_eq[row, col]
|
||
|
if not lb[col] - tol <= val <= ub[col] + tol:
|
||
|
# infeasible if fixed value is not within bounds
|
||
|
status = 2
|
||
|
message = ("The problem is (trivially) infeasible because a "
|
||
|
"singleton row in the equality constraints is "
|
||
|
"inconsistent with the bounds.")
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
else:
|
||
|
# sets upper and lower bounds at that fixed value - variable
|
||
|
# will be removed later
|
||
|
lb[col] = val
|
||
|
ub[col] = val
|
||
|
A_eq = A_eq[np.logical_not(singleton_row), :]
|
||
|
b_eq = b_eq[np.logical_not(singleton_row)]
|
||
|
|
||
|
# row singleton in inequality constraints
|
||
|
# this indicates a simple bound and the constraint can be removed
|
||
|
# simple bounds may be adjusted here
|
||
|
# After all of the simple bound information is combined here, get_Abc will
|
||
|
# turn the simple bounds into constraints
|
||
|
singleton_row = np.array(np.sum(A_ub != 0, axis=1) == 1).flatten()
|
||
|
cols = where(A_ub[singleton_row, :])[1]
|
||
|
rows = where(singleton_row)[0]
|
||
|
if len(rows) > 0:
|
||
|
for row, col in zip(rows, cols):
|
||
|
val = b_ub[row] / A_ub[row, col]
|
||
|
if A_ub[row, col] > 0: # upper bound
|
||
|
if val < lb[col] - tol: # infeasible
|
||
|
complete = True
|
||
|
elif val < ub[col]: # new upper bound
|
||
|
ub[col] = val
|
||
|
else: # lower bound
|
||
|
if val > ub[col] + tol: # infeasible
|
||
|
complete = True
|
||
|
elif val > lb[col]: # new lower bound
|
||
|
lb[col] = val
|
||
|
if complete:
|
||
|
status = 2
|
||
|
message = ("The problem is (trivially) infeasible because a "
|
||
|
"singleton row in the upper bound constraints is "
|
||
|
"inconsistent with the bounds.")
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
A_ub = A_ub[np.logical_not(singleton_row), :]
|
||
|
b_ub = b_ub[np.logical_not(singleton_row)]
|
||
|
|
||
|
# identical bounds indicate that variable can be removed
|
||
|
i_f = np.abs(lb - ub) < tol # indices of "fixed" variables
|
||
|
i_nf = np.logical_not(i_f) # indices of "not fixed" variables
|
||
|
|
||
|
# test_bounds_equal_but_infeasible
|
||
|
if np.all(i_f): # if bounds define solution, check for consistency
|
||
|
residual = b_eq - A_eq.dot(lb)
|
||
|
slack = b_ub - A_ub.dot(lb)
|
||
|
if ((A_ub.size > 0 and np.any(slack < 0)) or
|
||
|
(A_eq.size > 0 and not np.allclose(residual, 0))):
|
||
|
status = 2
|
||
|
message = ("The problem is (trivially) infeasible because the "
|
||
|
"bounds fix all variables to values inconsistent with "
|
||
|
"the constraints")
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
|
||
|
ub_mod = ub
|
||
|
lb_mod = lb
|
||
|
if np.any(i_f):
|
||
|
c0 += c[i_f].dot(lb[i_f])
|
||
|
b_eq = b_eq - A_eq[:, i_f].dot(lb[i_f])
|
||
|
b_ub = b_ub - A_ub[:, i_f].dot(lb[i_f])
|
||
|
c = c[i_nf]
|
||
|
x_undo = lb[i_f] # not x[i_f], x is just zeroes
|
||
|
x = x[i_nf]
|
||
|
# user guess x0 stays separate from presolve solution x
|
||
|
if x0 is not None:
|
||
|
x0 = x0[i_nf]
|
||
|
A_eq = A_eq[:, i_nf]
|
||
|
A_ub = A_ub[:, i_nf]
|
||
|
# modify bounds
|
||
|
lb_mod = lb[i_nf]
|
||
|
ub_mod = ub[i_nf]
|
||
|
|
||
|
def rev(x_mod):
|
||
|
# Function to restore x: insert x_undo into x_mod.
|
||
|
# When elements have been removed at positions k1, k2, k3, ...
|
||
|
# then these must be replaced at (after) positions k1-1, k2-2,
|
||
|
# k3-3, ... in the modified array to recreate the original
|
||
|
i = np.flatnonzero(i_f)
|
||
|
# Number of variables to restore
|
||
|
N = len(i)
|
||
|
index_offset = np.arange(N)
|
||
|
# Create insert indices
|
||
|
insert_indices = i - index_offset
|
||
|
x_rev = np.insert(x_mod.astype(float), insert_indices, x_undo)
|
||
|
return x_rev
|
||
|
|
||
|
# Use revstack as a list of functions, currently just this one.
|
||
|
revstack.append(rev)
|
||
|
|
||
|
# no constraints indicates that problem is trivial
|
||
|
if A_eq.size == 0 and A_ub.size == 0:
|
||
|
b_eq = np.array([])
|
||
|
b_ub = np.array([])
|
||
|
# test_empty_constraint_1
|
||
|
if c.size == 0:
|
||
|
status = 0
|
||
|
message = ("The solution was determined in presolve as there are "
|
||
|
"no non-trivial constraints.")
|
||
|
elif (np.any(np.logical_and(c < 0, ub_mod == np.inf)) or
|
||
|
np.any(np.logical_and(c > 0, lb_mod == -np.inf))):
|
||
|
# test_no_constraints()
|
||
|
# test_unbounded_no_nontrivial_constraints_1
|
||
|
# test_unbounded_no_nontrivial_constraints_2
|
||
|
status = 3
|
||
|
message = ("The problem is (trivially) unbounded "
|
||
|
"because there are no non-trivial constraints and "
|
||
|
"a) at least one decision variable is unbounded "
|
||
|
"above and its corresponding cost is negative, or "
|
||
|
"b) at least one decision variable is unbounded below "
|
||
|
"and its corresponding cost is positive. ")
|
||
|
else: # test_empty_constraint_2
|
||
|
status = 0
|
||
|
message = ("The solution was determined in presolve as there are "
|
||
|
"no non-trivial constraints.")
|
||
|
complete = True
|
||
|
x[c < 0] = ub_mod[c < 0]
|
||
|
x[c > 0] = lb_mod[c > 0]
|
||
|
# where c is zero, set x to a finite bound or zero
|
||
|
x_zero_c = ub_mod[c == 0]
|
||
|
x_zero_c[np.isinf(x_zero_c)] = ub_mod[c == 0][np.isinf(x_zero_c)]
|
||
|
x_zero_c[np.isinf(x_zero_c)] = 0
|
||
|
x[c == 0] = x_zero_c
|
||
|
# if this is not the last step of presolve, should convert bounds back
|
||
|
# to array and return here
|
||
|
|
||
|
# Convert modified lb and ub back into N x 2 bounds
|
||
|
bounds = np.hstack((lb_mod[:, np.newaxis], ub_mod[:, np.newaxis]))
|
||
|
|
||
|
# remove redundant (linearly dependent) rows from equality constraints
|
||
|
n_rows_A = A_eq.shape[0]
|
||
|
redundancy_warning = ("A_eq does not appear to be of full row rank. To "
|
||
|
"improve performance, check the problem formulation "
|
||
|
"for redundant equality constraints.")
|
||
|
if (sps.issparse(A_eq)):
|
||
|
if rr and A_eq.size > 0: # TODO: Fast sparse rank check?
|
||
|
rr_res = _remove_redundancy_pivot_sparse(A_eq, b_eq)
|
||
|
A_eq, b_eq, status, message = rr_res
|
||
|
if A_eq.shape[0] < n_rows_A:
|
||
|
warn(redundancy_warning, OptimizeWarning, stacklevel=1)
|
||
|
if status != 0:
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
|
||
|
# This is a wild guess for which redundancy removal algorithm will be
|
||
|
# faster. More testing would be good.
|
||
|
small_nullspace = 5
|
||
|
if rr and A_eq.size > 0:
|
||
|
try: # TODO: use results of first SVD in _remove_redundancy_svd
|
||
|
rank = np.linalg.matrix_rank(A_eq)
|
||
|
# oh well, we'll have to go with _remove_redundancy_pivot_dense
|
||
|
except Exception:
|
||
|
rank = 0
|
||
|
if rr and A_eq.size > 0 and rank < A_eq.shape[0]:
|
||
|
warn(redundancy_warning, OptimizeWarning, stacklevel=3)
|
||
|
dim_row_nullspace = A_eq.shape[0]-rank
|
||
|
if rr_method is None:
|
||
|
if dim_row_nullspace <= small_nullspace:
|
||
|
rr_res = _remove_redundancy_svd(A_eq, b_eq)
|
||
|
A_eq, b_eq, status, message = rr_res
|
||
|
if dim_row_nullspace > small_nullspace or status == 4:
|
||
|
rr_res = _remove_redundancy_pivot_dense(A_eq, b_eq)
|
||
|
A_eq, b_eq, status, message = rr_res
|
||
|
|
||
|
else:
|
||
|
rr_method = rr_method.lower()
|
||
|
if rr_method == "svd":
|
||
|
rr_res = _remove_redundancy_svd(A_eq, b_eq)
|
||
|
A_eq, b_eq, status, message = rr_res
|
||
|
elif rr_method == "pivot":
|
||
|
rr_res = _remove_redundancy_pivot_dense(A_eq, b_eq)
|
||
|
A_eq, b_eq, status, message = rr_res
|
||
|
elif rr_method == "id":
|
||
|
rr_res = _remove_redundancy_id(A_eq, b_eq, rank)
|
||
|
A_eq, b_eq, status, message = rr_res
|
||
|
else: # shouldn't get here; option validity checked above
|
||
|
pass
|
||
|
if A_eq.shape[0] < rank:
|
||
|
message = ("Due to numerical issues, redundant equality "
|
||
|
"constraints could not be removed automatically. "
|
||
|
"Try providing your constraint matrices as sparse "
|
||
|
"matrices to activate sparse presolve, try turning "
|
||
|
"off redundancy removal, or try turning off presolve "
|
||
|
"altogether.")
|
||
|
status = 4
|
||
|
if status != 0:
|
||
|
complete = True
|
||
|
return (_LPProblem(c, A_ub, b_ub, A_eq, b_eq, bounds, x0),
|
||
|
c0, x, revstack, complete, status, message)
|
||
|
|
||
|
|
||
|
def _parse_linprog(lp, options, meth):
|
||
|
"""
|
||
|
Parse the provided linear programming problem
|
||
|
|
||
|
``_parse_linprog`` employs two main steps ``_check_sparse_inputs`` and
|
||
|
``_clean_inputs``. ``_check_sparse_inputs`` checks for sparsity in the
|
||
|
provided constraints (``A_ub`` and ``A_eq) and if these match the provided
|
||
|
sparsity optional values.
|
||
|
|
||
|
``_clean inputs`` checks of the provided inputs. If no violations are
|
||
|
identified the objective vector, upper bound constraints, equality
|
||
|
constraints, and simple bounds are returned in the expected format.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
|
||
|
|
||
|
c : 1D array
|
||
|
The coefficients of the linear objective function to be minimized.
|
||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
||
|
A_eq : 2D array, optional
|
||
|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
||
|
coefficients of a linear equality constraint on ``x``.
|
||
|
b_eq : 1D array, optional
|
||
|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
||
|
the corresponding element of ``b_eq``.
|
||
|
bounds : various valid formats, optional
|
||
|
The bounds of ``x``, as ``min`` and ``max`` pairs.
|
||
|
If bounds are specified for all N variables separately, valid formats are:
|
||
|
* a 2D array (2 x N or N x 2);
|
||
|
* a sequence of N sequences, each with 2 values.
|
||
|
If all variables have the same bounds, a single pair of values can
|
||
|
be specified. Valid formats are:
|
||
|
* a sequence with 2 scalar values;
|
||
|
* a sequence with a single element containing 2 scalar values.
|
||
|
If all variables have a lower bound of 0 and no upper bound, the bounds
|
||
|
parameter can be omitted (or given as None).
|
||
|
x0 : 1D array, optional
|
||
|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
||
|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
||
|
|
||
|
options : dict
|
||
|
A dictionary of solver options. All methods accept the following
|
||
|
generic options:
|
||
|
|
||
|
maxiter : int
|
||
|
Maximum number of iterations to perform.
|
||
|
disp : bool
|
||
|
Set to True to print convergence messages.
|
||
|
|
||
|
For method-specific options, see :func:`show_options('linprog')`.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
|
||
|
|
||
|
c : 1D array
|
||
|
The coefficients of the linear objective function to be minimized.
|
||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
||
|
A_eq : 2D array, optional
|
||
|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
||
|
coefficients of a linear equality constraint on ``x``.
|
||
|
b_eq : 1D array, optional
|
||
|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
||
|
the corresponding element of ``b_eq``.
|
||
|
bounds : 2D array
|
||
|
The bounds of ``x``, as ``min`` and ``max`` pairs, one for each of the N
|
||
|
elements of ``x``. The N x 2 array contains lower bounds in the first
|
||
|
column and upper bounds in the 2nd. Unbounded variables have lower
|
||
|
bound -np.inf and/or upper bound np.inf.
|
||
|
x0 : 1D array, optional
|
||
|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
||
|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
||
|
|
||
|
options : dict, optional
|
||
|
A dictionary of solver options. All methods accept the following
|
||
|
generic options:
|
||
|
|
||
|
maxiter : int
|
||
|
Maximum number of iterations to perform.
|
||
|
disp : bool
|
||
|
Set to True to print convergence messages.
|
||
|
|
||
|
For method-specific options, see :func:`show_options('linprog')`.
|
||
|
|
||
|
"""
|
||
|
if options is None:
|
||
|
options = {}
|
||
|
|
||
|
solver_options = {k: v for k, v in options.items()}
|
||
|
solver_options, A_ub, A_eq = _check_sparse_inputs(solver_options, meth,
|
||
|
lp.A_ub, lp.A_eq)
|
||
|
# Convert lists to numpy arrays, etc...
|
||
|
lp = _clean_inputs(lp._replace(A_ub=A_ub, A_eq=A_eq))
|
||
|
return lp, solver_options
|
||
|
|
||
|
|
||
|
def _get_Abc(lp, c0):
|
||
|
"""
|
||
|
Given a linear programming problem of the form:
|
||
|
|
||
|
Minimize::
|
||
|
|
||
|
c @ x
|
||
|
|
||
|
Subject to::
|
||
|
|
||
|
A_ub @ x <= b_ub
|
||
|
A_eq @ x == b_eq
|
||
|
lb <= x <= ub
|
||
|
|
||
|
where ``lb = 0`` and ``ub = None`` unless set in ``bounds``.
|
||
|
|
||
|
Return the problem in standard form:
|
||
|
|
||
|
Minimize::
|
||
|
|
||
|
c @ x
|
||
|
|
||
|
Subject to::
|
||
|
|
||
|
A @ x == b
|
||
|
x >= 0
|
||
|
|
||
|
by adding slack variables and making variable substitutions as necessary.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
|
||
|
|
||
|
c : 1D array
|
||
|
The coefficients of the linear objective function to be minimized.
|
||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
||
|
A_eq : 2D array, optional
|
||
|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
||
|
coefficients of a linear equality constraint on ``x``.
|
||
|
b_eq : 1D array, optional
|
||
|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
||
|
the corresponding element of ``b_eq``.
|
||
|
bounds : 2D array
|
||
|
The bounds of ``x``, lower bounds in the 1st column, upper
|
||
|
bounds in the 2nd column. The bounds are possibly tightened
|
||
|
by the presolve procedure.
|
||
|
x0 : 1D array, optional
|
||
|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
||
|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
||
|
|
||
|
c0 : float
|
||
|
Constant term in objective function due to fixed (and eliminated)
|
||
|
variables.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
A : 2-D array
|
||
|
2-D array such that ``A`` @ ``x``, gives the values of the equality
|
||
|
constraints at ``x``.
|
||
|
b : 1-D array
|
||
|
1-D array of values representing the RHS of each equality constraint
|
||
|
(row) in A (for standard form problem).
|
||
|
c : 1-D array
|
||
|
Coefficients of the linear objective function to be minimized (for
|
||
|
standard form problem).
|
||
|
c0 : float
|
||
|
Constant term in objective function due to fixed (and eliminated)
|
||
|
variables.
|
||
|
x0 : 1-D array
|
||
|
Starting values of the independent variables, which will be refined by
|
||
|
the optimization algorithm
|
||
|
|
||
|
References
|
||
|
----------
|
||
|
.. [9] Bertsimas, Dimitris, and J. Tsitsiklis. "Introduction to linear
|
||
|
programming." Athena Scientific 1 (1997): 997.
|
||
|
|
||
|
"""
|
||
|
c, A_ub, b_ub, A_eq, b_eq, bounds, x0, integrality = lp
|
||
|
|
||
|
if sps.issparse(A_eq):
|
||
|
sparse = True
|
||
|
A_eq = sps.csr_matrix(A_eq)
|
||
|
A_ub = sps.csr_matrix(A_ub)
|
||
|
|
||
|
def hstack(blocks):
|
||
|
return sps.hstack(blocks, format="csr")
|
||
|
|
||
|
def vstack(blocks):
|
||
|
return sps.vstack(blocks, format="csr")
|
||
|
|
||
|
zeros = sps.csr_matrix
|
||
|
eye = sps.eye
|
||
|
else:
|
||
|
sparse = False
|
||
|
hstack = np.hstack
|
||
|
vstack = np.vstack
|
||
|
zeros = np.zeros
|
||
|
eye = np.eye
|
||
|
|
||
|
# Variables lbs and ubs (see below) may be changed, which feeds back into
|
||
|
# bounds, so copy.
|
||
|
bounds = np.array(bounds, copy=True)
|
||
|
|
||
|
# modify problem such that all variables have only non-negativity bounds
|
||
|
lbs = bounds[:, 0]
|
||
|
ubs = bounds[:, 1]
|
||
|
m_ub, n_ub = A_ub.shape
|
||
|
|
||
|
lb_none = np.equal(lbs, -np.inf)
|
||
|
ub_none = np.equal(ubs, np.inf)
|
||
|
lb_some = np.logical_not(lb_none)
|
||
|
ub_some = np.logical_not(ub_none)
|
||
|
|
||
|
# unbounded below: substitute xi = -xi' (unbounded above)
|
||
|
# if -inf <= xi <= ub, then -ub <= -xi <= inf, so swap and invert bounds
|
||
|
l_nolb_someub = np.logical_and(lb_none, ub_some)
|
||
|
i_nolb = np.nonzero(l_nolb_someub)[0]
|
||
|
lbs[l_nolb_someub], ubs[l_nolb_someub] = (
|
||
|
-ubs[l_nolb_someub], -lbs[l_nolb_someub])
|
||
|
lb_none = np.equal(lbs, -np.inf)
|
||
|
ub_none = np.equal(ubs, np.inf)
|
||
|
lb_some = np.logical_not(lb_none)
|
||
|
ub_some = np.logical_not(ub_none)
|
||
|
c[i_nolb] *= -1
|
||
|
if x0 is not None:
|
||
|
x0[i_nolb] *= -1
|
||
|
if len(i_nolb) > 0:
|
||
|
if A_ub.shape[0] > 0: # sometimes needed for sparse arrays... weird
|
||
|
A_ub[:, i_nolb] *= -1
|
||
|
if A_eq.shape[0] > 0:
|
||
|
A_eq[:, i_nolb] *= -1
|
||
|
|
||
|
# upper bound: add inequality constraint
|
||
|
i_newub, = ub_some.nonzero()
|
||
|
ub_newub = ubs[ub_some]
|
||
|
n_bounds = len(i_newub)
|
||
|
if n_bounds > 0:
|
||
|
shape = (n_bounds, A_ub.shape[1])
|
||
|
if sparse:
|
||
|
idxs = (np.arange(n_bounds), i_newub)
|
||
|
A_ub = vstack((A_ub, sps.csr_matrix((np.ones(n_bounds), idxs),
|
||
|
shape=shape)))
|
||
|
else:
|
||
|
A_ub = vstack((A_ub, np.zeros(shape)))
|
||
|
A_ub[np.arange(m_ub, A_ub.shape[0]), i_newub] = 1
|
||
|
b_ub = np.concatenate((b_ub, np.zeros(n_bounds)))
|
||
|
b_ub[m_ub:] = ub_newub
|
||
|
|
||
|
A1 = vstack((A_ub, A_eq))
|
||
|
b = np.concatenate((b_ub, b_eq))
|
||
|
c = np.concatenate((c, np.zeros((A_ub.shape[0],))))
|
||
|
if x0 is not None:
|
||
|
x0 = np.concatenate((x0, np.zeros((A_ub.shape[0],))))
|
||
|
# unbounded: substitute xi = xi+ + xi-
|
||
|
l_free = np.logical_and(lb_none, ub_none)
|
||
|
i_free = np.nonzero(l_free)[0]
|
||
|
n_free = len(i_free)
|
||
|
c = np.concatenate((c, np.zeros(n_free)))
|
||
|
if x0 is not None:
|
||
|
x0 = np.concatenate((x0, np.zeros(n_free)))
|
||
|
A1 = hstack((A1[:, :n_ub], -A1[:, i_free]))
|
||
|
c[n_ub:n_ub+n_free] = -c[i_free]
|
||
|
if x0 is not None:
|
||
|
i_free_neg = x0[i_free] < 0
|
||
|
x0[np.arange(n_ub, A1.shape[1])[i_free_neg]] = -x0[i_free[i_free_neg]]
|
||
|
x0[i_free[i_free_neg]] = 0
|
||
|
|
||
|
# add slack variables
|
||
|
A2 = vstack([eye(A_ub.shape[0]), zeros((A_eq.shape[0], A_ub.shape[0]))])
|
||
|
|
||
|
A = hstack([A1, A2])
|
||
|
|
||
|
# lower bound: substitute xi = xi' + lb
|
||
|
# now there is a constant term in objective
|
||
|
i_shift = np.nonzero(lb_some)[0]
|
||
|
lb_shift = lbs[lb_some].astype(float)
|
||
|
c0 += np.sum(lb_shift * c[i_shift])
|
||
|
if sparse:
|
||
|
b = b.reshape(-1, 1)
|
||
|
A = A.tocsc()
|
||
|
b -= (A[:, i_shift] * sps.diags(lb_shift)).sum(axis=1)
|
||
|
b = b.ravel()
|
||
|
else:
|
||
|
b -= (A[:, i_shift] * lb_shift).sum(axis=1)
|
||
|
if x0 is not None:
|
||
|
x0[i_shift] -= lb_shift
|
||
|
|
||
|
return A, b, c, c0, x0
|
||
|
|
||
|
|
||
|
def _round_to_power_of_two(x):
|
||
|
"""
|
||
|
Round elements of the array to the nearest power of two.
|
||
|
"""
|
||
|
return 2**np.around(np.log2(x))
|
||
|
|
||
|
|
||
|
def _autoscale(A, b, c, x0):
|
||
|
"""
|
||
|
Scales the problem according to equilibration from [12].
|
||
|
Also normalizes the right hand side vector by its maximum element.
|
||
|
"""
|
||
|
m, n = A.shape
|
||
|
|
||
|
C = 1
|
||
|
R = 1
|
||
|
|
||
|
if A.size > 0:
|
||
|
|
||
|
R = np.max(np.abs(A), axis=1)
|
||
|
if sps.issparse(A):
|
||
|
R = R.toarray().flatten()
|
||
|
R[R == 0] = 1
|
||
|
R = 1/_round_to_power_of_two(R)
|
||
|
A = sps.diags(R)*A if sps.issparse(A) else A*R.reshape(m, 1)
|
||
|
b = b*R
|
||
|
|
||
|
C = np.max(np.abs(A), axis=0)
|
||
|
if sps.issparse(A):
|
||
|
C = C.toarray().flatten()
|
||
|
C[C == 0] = 1
|
||
|
C = 1/_round_to_power_of_two(C)
|
||
|
A = A*sps.diags(C) if sps.issparse(A) else A*C
|
||
|
c = c*C
|
||
|
|
||
|
b_scale = np.max(np.abs(b)) if b.size > 0 else 1
|
||
|
if b_scale == 0:
|
||
|
b_scale = 1.
|
||
|
b = b/b_scale
|
||
|
|
||
|
if x0 is not None:
|
||
|
x0 = x0/b_scale*(1/C)
|
||
|
return A, b, c, x0, C, b_scale
|
||
|
|
||
|
|
||
|
def _unscale(x, C, b_scale):
|
||
|
"""
|
||
|
Converts solution to _autoscale problem -> solution to original problem.
|
||
|
"""
|
||
|
|
||
|
try:
|
||
|
n = len(C)
|
||
|
# fails if sparse or scalar; that's OK.
|
||
|
# this is only needed for original simplex (never sparse)
|
||
|
except TypeError:
|
||
|
n = len(x)
|
||
|
|
||
|
return x[:n]*b_scale*C
|
||
|
|
||
|
|
||
|
def _display_summary(message, status, fun, iteration):
|
||
|
"""
|
||
|
Print the termination summary of the linear program
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
message : str
|
||
|
A string descriptor of the exit status of the optimization.
|
||
|
status : int
|
||
|
An integer representing the exit status of the optimization::
|
||
|
|
||
|
0 : Optimization terminated successfully
|
||
|
1 : Iteration limit reached
|
||
|
2 : Problem appears to be infeasible
|
||
|
3 : Problem appears to be unbounded
|
||
|
4 : Serious numerical difficulties encountered
|
||
|
|
||
|
fun : float
|
||
|
Value of the objective function.
|
||
|
iteration : iteration
|
||
|
The number of iterations performed.
|
||
|
"""
|
||
|
print(message)
|
||
|
if status in (0, 1):
|
||
|
print(" Current function value: {0: <12.6f}".format(fun))
|
||
|
print(" Iterations: {0:d}".format(iteration))
|
||
|
|
||
|
|
||
|
def _postsolve(x, postsolve_args, complete=False):
|
||
|
"""
|
||
|
Given solution x to presolved, standard form linear program x, add
|
||
|
fixed variables back into the problem and undo the variable substitutions
|
||
|
to get solution to original linear program. Also, calculate the objective
|
||
|
function value, slack in original upper bound constraints, and residuals
|
||
|
in original equality constraints.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
x : 1-D array
|
||
|
Solution vector to the standard-form problem.
|
||
|
postsolve_args : tuple
|
||
|
Data needed by _postsolve to convert the solution to the standard-form
|
||
|
problem into the solution to the original problem, including:
|
||
|
|
||
|
lp : A `scipy.optimize._linprog_util._LPProblem` consisting of the following fields:
|
||
|
|
||
|
c : 1D array
|
||
|
The coefficients of the linear objective function to be minimized.
|
||
|
A_ub : 2D array, optional
|
||
|
The inequality constraint matrix. Each row of ``A_ub`` specifies the
|
||
|
coefficients of a linear inequality constraint on ``x``.
|
||
|
b_ub : 1D array, optional
|
||
|
The inequality constraint vector. Each element represents an
|
||
|
upper bound on the corresponding value of ``A_ub @ x``.
|
||
|
A_eq : 2D array, optional
|
||
|
The equality constraint matrix. Each row of ``A_eq`` specifies the
|
||
|
coefficients of a linear equality constraint on ``x``.
|
||
|
b_eq : 1D array, optional
|
||
|
The equality constraint vector. Each element of ``A_eq @ x`` must equal
|
||
|
the corresponding element of ``b_eq``.
|
||
|
bounds : 2D array
|
||
|
The bounds of ``x``, lower bounds in the 1st column, upper
|
||
|
bounds in the 2nd column. The bounds are possibly tightened
|
||
|
by the presolve procedure.
|
||
|
x0 : 1D array, optional
|
||
|
Guess values of the decision variables, which will be refined by
|
||
|
the optimization algorithm. This argument is currently used only by the
|
||
|
'revised simplex' method, and can only be used if `x0` represents a
|
||
|
basic feasible solution.
|
||
|
|
||
|
revstack: list of functions
|
||
|
the functions in the list reverse the operations of _presolve()
|
||
|
the function signature is x_org = f(x_mod), where x_mod is the result
|
||
|
of a presolve step and x_org the value at the start of the step
|
||
|
complete : bool
|
||
|
Whether the solution is was determined in presolve (``True`` if so)
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
x : 1-D array
|
||
|
Solution vector to original linear programming problem
|
||
|
fun: float
|
||
|
optimal objective value for original problem
|
||
|
slack : 1-D array
|
||
|
The (non-negative) slack in the upper bound constraints, that is,
|
||
|
``b_ub - A_ub @ x``
|
||
|
con : 1-D array
|
||
|
The (nominally zero) residuals of the equality constraints, that is,
|
||
|
``b - A_eq @ x``
|
||
|
"""
|
||
|
# note that all the inputs are the ORIGINAL, unmodified versions
|
||
|
# no rows, columns have been removed
|
||
|
|
||
|
c, A_ub, b_ub, A_eq, b_eq, bounds, x0, integrality = postsolve_args[0]
|
||
|
revstack, C, b_scale = postsolve_args[1:]
|
||
|
|
||
|
x = _unscale(x, C, b_scale)
|
||
|
|
||
|
# Undo variable substitutions of _get_Abc()
|
||
|
# if "complete", problem was solved in presolve; don't do anything here
|
||
|
n_x = bounds.shape[0]
|
||
|
if not complete and bounds is not None: # bounds are never none, probably
|
||
|
n_unbounded = 0
|
||
|
for i, bi in enumerate(bounds):
|
||
|
lbi = bi[0]
|
||
|
ubi = bi[1]
|
||
|
if lbi == -np.inf and ubi == np.inf:
|
||
|
n_unbounded += 1
|
||
|
x[i] = x[i] - x[n_x + n_unbounded - 1]
|
||
|
else:
|
||
|
if lbi == -np.inf:
|
||
|
x[i] = ubi - x[i]
|
||
|
else:
|
||
|
x[i] += lbi
|
||
|
# all the rest of the variables were artificial
|
||
|
x = x[:n_x]
|
||
|
|
||
|
# If there were variables removed from the problem, add them back into the
|
||
|
# solution vector
|
||
|
# Apply the functions in revstack (reverse direction)
|
||
|
for rev in reversed(revstack):
|
||
|
x = rev(x)
|
||
|
|
||
|
fun = x.dot(c)
|
||
|
slack = b_ub - A_ub.dot(x) # report slack for ORIGINAL UB constraints
|
||
|
# report residuals of ORIGINAL EQ constraints
|
||
|
con = b_eq - A_eq.dot(x)
|
||
|
|
||
|
return x, fun, slack, con
|
||
|
|
||
|
|
||
|
def _check_result(x, fun, status, slack, con, bounds, tol, message):
|
||
|
"""
|
||
|
Check the validity of the provided solution.
|
||
|
|
||
|
A valid (optimal) solution satisfies all bounds, all slack variables are
|
||
|
negative and all equality constraint residuals are strictly non-zero.
|
||
|
Further, the lower-bounds, upper-bounds, slack and residuals contain
|
||
|
no nan values.
|
||
|
|
||
|
Parameters
|
||
|
----------
|
||
|
x : 1-D array
|
||
|
Solution vector to original linear programming problem
|
||
|
fun: float
|
||
|
optimal objective value for original problem
|
||
|
status : int
|
||
|
An integer representing the exit status of the optimization::
|
||
|
|
||
|
0 : Optimization terminated successfully
|
||
|
1 : Iteration limit reached
|
||
|
2 : Problem appears to be infeasible
|
||
|
3 : Problem appears to be unbounded
|
||
|
4 : Serious numerical difficulties encountered
|
||
|
|
||
|
slack : 1-D array
|
||
|
The (non-negative) slack in the upper bound constraints, that is,
|
||
|
``b_ub - A_ub @ x``
|
||
|
con : 1-D array
|
||
|
The (nominally zero) residuals of the equality constraints, that is,
|
||
|
``b - A_eq @ x``
|
||
|
bounds : 2D array
|
||
|
The bounds on the original variables ``x``
|
||
|
message : str
|
||
|
A string descriptor of the exit status of the optimization.
|
||
|
tol : float
|
||
|
Termination tolerance; see [1]_ Section 4.5.
|
||
|
|
||
|
Returns
|
||
|
-------
|
||
|
status : int
|
||
|
An integer representing the exit status of the optimization::
|
||
|
|
||
|
0 : Optimization terminated successfully
|
||
|
1 : Iteration limit reached
|
||
|
2 : Problem appears to be infeasible
|
||
|
3 : Problem appears to be unbounded
|
||
|
4 : Serious numerical difficulties encountered
|
||
|
|
||
|
message : str
|
||
|
A string descriptor of the exit status of the optimization.
|
||
|
"""
|
||
|
# Somewhat arbitrary
|
||
|
tol = np.sqrt(tol) * 10
|
||
|
|
||
|
if x is None:
|
||
|
# HiGHS does not provide x if infeasible/unbounded
|
||
|
if status == 0: # Observed with HiGHS Simplex Primal
|
||
|
status = 4
|
||
|
message = ("The solver did not provide a solution nor did it "
|
||
|
"report a failure. Please submit a bug report.")
|
||
|
return status, message
|
||
|
|
||
|
contains_nans = (
|
||
|
np.isnan(x).any()
|
||
|
or np.isnan(fun)
|
||
|
or np.isnan(slack).any()
|
||
|
or np.isnan(con).any()
|
||
|
)
|
||
|
|
||
|
if contains_nans:
|
||
|
is_feasible = False
|
||
|
else:
|
||
|
invalid_bounds = (x < bounds[:, 0] - tol).any() or (x > bounds[:, 1] + tol).any()
|
||
|
invalid_slack = status != 3 and (slack < -tol).any()
|
||
|
invalid_con = status != 3 and (np.abs(con) > tol).any()
|
||
|
is_feasible = not (invalid_bounds or invalid_slack or invalid_con)
|
||
|
|
||
|
if status == 0 and not is_feasible:
|
||
|
status = 4
|
||
|
message = ("The solution does not satisfy the constraints within the "
|
||
|
"required tolerance of " + "{:.2E}".format(tol) + ", yet "
|
||
|
"no errors were raised and there is no certificate of "
|
||
|
"infeasibility or unboundedness. Check whether "
|
||
|
"the slack and constraint residuals are acceptable; "
|
||
|
"if not, consider enabling presolve, adjusting the "
|
||
|
"tolerance option(s), and/or using a different method. "
|
||
|
"Please consider submitting a bug report.")
|
||
|
elif status == 2 and is_feasible:
|
||
|
# Occurs if the simplex method exits after phase one with a very
|
||
|
# nearly basic feasible solution. Postsolving can make the solution
|
||
|
# basic, however, this solution is NOT optimal
|
||
|
status = 4
|
||
|
message = ("The solution is feasible, but the solver did not report "
|
||
|
"that the solution was optimal. Please try a different "
|
||
|
"method.")
|
||
|
|
||
|
return status, message
|