505 lines
18 KiB
Python
505 lines
18 KiB
Python
"""
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This module implements the Sequential Least Squares Programming optimization
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algorithm (SLSQP), originally developed by Dieter Kraft.
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See http://www.netlib.org/toms/733
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Functions
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---------
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.. autosummary::
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:toctree: generated/
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approx_jacobian
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fmin_slsqp
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"""
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__all__ = ['approx_jacobian', 'fmin_slsqp']
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import numpy as np
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from scipy.optimize._slsqp import slsqp
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from numpy import (zeros, array, linalg, append, asfarray, concatenate, finfo,
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sqrt, vstack, isfinite, atleast_1d)
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from ._optimize import (OptimizeResult, _check_unknown_options,
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_prepare_scalar_function, _clip_x_for_func,
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_check_clip_x)
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from ._numdiff import approx_derivative
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from ._constraints import old_bound_to_new, _arr_to_scalar
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__docformat__ = "restructuredtext en"
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_epsilon = sqrt(finfo(float).eps)
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def approx_jacobian(x, func, epsilon, *args):
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"""
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Approximate the Jacobian matrix of a callable function.
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Parameters
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----------
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x : array_like
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The state vector at which to compute the Jacobian matrix.
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func : callable f(x,*args)
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The vector-valued function.
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epsilon : float
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The perturbation used to determine the partial derivatives.
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args : sequence
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Additional arguments passed to func.
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Returns
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-------
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An array of dimensions ``(lenf, lenx)`` where ``lenf`` is the length
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of the outputs of `func`, and ``lenx`` is the number of elements in
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`x`.
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Notes
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-----
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The approximation is done using forward differences.
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"""
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# approx_derivative returns (m, n) == (lenf, lenx)
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jac = approx_derivative(func, x, method='2-point', abs_step=epsilon,
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args=args)
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# if func returns a scalar jac.shape will be (lenx,). Make sure
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# it's at least a 2D array.
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return np.atleast_2d(jac)
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def fmin_slsqp(func, x0, eqcons=(), f_eqcons=None, ieqcons=(), f_ieqcons=None,
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bounds=(), fprime=None, fprime_eqcons=None,
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fprime_ieqcons=None, args=(), iter=100, acc=1.0E-6,
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iprint=1, disp=None, full_output=0, epsilon=_epsilon,
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callback=None):
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"""
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Minimize a function using Sequential Least Squares Programming
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Python interface function for the SLSQP Optimization subroutine
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originally implemented by Dieter Kraft.
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Parameters
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----------
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func : callable f(x,*args)
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Objective function. Must return a scalar.
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x0 : 1-D ndarray of float
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Initial guess for the independent variable(s).
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eqcons : list, optional
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A list of functions of length n such that
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eqcons[j](x,*args) == 0.0 in a successfully optimized
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problem.
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f_eqcons : callable f(x,*args), optional
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Returns a 1-D array in which each element must equal 0.0 in a
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successfully optimized problem. If f_eqcons is specified,
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eqcons is ignored.
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ieqcons : list, optional
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A list of functions of length n such that
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ieqcons[j](x,*args) >= 0.0 in a successfully optimized
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problem.
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f_ieqcons : callable f(x,*args), optional
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Returns a 1-D ndarray in which each element must be greater or
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equal to 0.0 in a successfully optimized problem. If
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f_ieqcons is specified, ieqcons is ignored.
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bounds : list, optional
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A list of tuples specifying the lower and upper bound
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for each independent variable [(xl0, xu0),(xl1, xu1),...]
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Infinite values will be interpreted as large floating values.
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fprime : callable `f(x,*args)`, optional
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A function that evaluates the partial derivatives of func.
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fprime_eqcons : callable `f(x,*args)`, optional
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A function of the form `f(x, *args)` that returns the m by n
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array of equality constraint normals. If not provided,
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the normals will be approximated. The array returned by
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fprime_eqcons should be sized as ( len(eqcons), len(x0) ).
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fprime_ieqcons : callable `f(x,*args)`, optional
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A function of the form `f(x, *args)` that returns the m by n
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array of inequality constraint normals. If not provided,
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the normals will be approximated. The array returned by
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fprime_ieqcons should be sized as ( len(ieqcons), len(x0) ).
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args : sequence, optional
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Additional arguments passed to func and fprime.
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iter : int, optional
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The maximum number of iterations.
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acc : float, optional
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Requested accuracy.
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iprint : int, optional
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The verbosity of fmin_slsqp :
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* iprint <= 0 : Silent operation
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* iprint == 1 : Print summary upon completion (default)
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* iprint >= 2 : Print status of each iterate and summary
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disp : int, optional
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Overrides the iprint interface (preferred).
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full_output : bool, optional
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If False, return only the minimizer of func (default).
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Otherwise, output final objective function and summary
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information.
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epsilon : float, optional
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The step size for finite-difference derivative estimates.
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callback : callable, optional
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Called after each iteration, as ``callback(x)``, where ``x`` is the
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current parameter vector.
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Returns
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-------
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out : ndarray of float
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The final minimizer of func.
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fx : ndarray of float, if full_output is true
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The final value of the objective function.
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its : int, if full_output is true
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The number of iterations.
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imode : int, if full_output is true
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The exit mode from the optimizer (see below).
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smode : string, if full_output is true
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Message describing the exit mode from the optimizer.
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See also
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--------
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minimize: Interface to minimization algorithms for multivariate
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functions. See the 'SLSQP' `method` in particular.
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Notes
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-----
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Exit modes are defined as follows ::
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-1 : Gradient evaluation required (g & a)
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0 : Optimization terminated successfully
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1 : Function evaluation required (f & c)
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2 : More equality constraints than independent variables
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3 : More than 3*n iterations in LSQ subproblem
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4 : Inequality constraints incompatible
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5 : Singular matrix E in LSQ subproblem
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6 : Singular matrix C in LSQ subproblem
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7 : Rank-deficient equality constraint subproblem HFTI
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8 : Positive directional derivative for linesearch
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9 : Iteration limit reached
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Examples
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--------
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Examples are given :ref:`in the tutorial <tutorial-sqlsp>`.
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"""
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if disp is not None:
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iprint = disp
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opts = {'maxiter': iter,
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'ftol': acc,
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'iprint': iprint,
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'disp': iprint != 0,
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'eps': epsilon,
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'callback': callback}
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# Build the constraints as a tuple of dictionaries
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cons = ()
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# 1. constraints of the 1st kind (eqcons, ieqcons); no Jacobian; take
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# the same extra arguments as the objective function.
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cons += tuple({'type': 'eq', 'fun': c, 'args': args} for c in eqcons)
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cons += tuple({'type': 'ineq', 'fun': c, 'args': args} for c in ieqcons)
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# 2. constraints of the 2nd kind (f_eqcons, f_ieqcons) and their Jacobian
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# (fprime_eqcons, fprime_ieqcons); also take the same extra arguments
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# as the objective function.
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if f_eqcons:
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cons += ({'type': 'eq', 'fun': f_eqcons, 'jac': fprime_eqcons,
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'args': args}, )
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if f_ieqcons:
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cons += ({'type': 'ineq', 'fun': f_ieqcons, 'jac': fprime_ieqcons,
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'args': args}, )
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res = _minimize_slsqp(func, x0, args, jac=fprime, bounds=bounds,
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constraints=cons, **opts)
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if full_output:
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return res['x'], res['fun'], res['nit'], res['status'], res['message']
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else:
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return res['x']
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def _minimize_slsqp(func, x0, args=(), jac=None, bounds=None,
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constraints=(),
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maxiter=100, ftol=1.0E-6, iprint=1, disp=False,
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eps=_epsilon, callback=None, finite_diff_rel_step=None,
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**unknown_options):
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"""
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Minimize a scalar function of one or more variables using Sequential
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Least Squares Programming (SLSQP).
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Options
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-------
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ftol : float
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Precision goal for the value of f in the stopping criterion.
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eps : float
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Step size used for numerical approximation of the Jacobian.
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disp : bool
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Set to True to print convergence messages. If False,
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`verbosity` is ignored and set to 0.
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maxiter : int
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Maximum number of iterations.
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finite_diff_rel_step : None or array_like, optional
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If `jac in ['2-point', '3-point', 'cs']` the relative step size to
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use for numerical approximation of `jac`. The absolute step
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size is computed as ``h = rel_step * sign(x) * max(1, abs(x))``,
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possibly adjusted to fit into the bounds. For ``method='3-point'``
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the sign of `h` is ignored. If None (default) then step is selected
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automatically.
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"""
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_check_unknown_options(unknown_options)
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iter = maxiter - 1
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acc = ftol
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epsilon = eps
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if not disp:
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iprint = 0
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# Transform x0 into an array.
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x = asfarray(x0).flatten()
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# SLSQP is sent 'old-style' bounds, 'new-style' bounds are required by
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# ScalarFunction
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if bounds is None or len(bounds) == 0:
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new_bounds = (-np.inf, np.inf)
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else:
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new_bounds = old_bound_to_new(bounds)
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# clip the initial guess to bounds, otherwise ScalarFunction doesn't work
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x = np.clip(x, new_bounds[0], new_bounds[1])
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# Constraints are triaged per type into a dictionary of tuples
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if isinstance(constraints, dict):
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constraints = (constraints, )
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cons = {'eq': (), 'ineq': ()}
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for ic, con in enumerate(constraints):
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# check type
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try:
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ctype = con['type'].lower()
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except KeyError as e:
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raise KeyError('Constraint %d has no type defined.' % ic) from e
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except TypeError as e:
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raise TypeError('Constraints must be defined using a '
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'dictionary.') from e
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except AttributeError as e:
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raise TypeError("Constraint's type must be a string.") from e
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else:
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if ctype not in ['eq', 'ineq']:
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raise ValueError("Unknown constraint type '%s'." % con['type'])
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# check function
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if 'fun' not in con:
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raise ValueError('Constraint %d has no function defined.' % ic)
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# check Jacobian
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cjac = con.get('jac')
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if cjac is None:
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# approximate Jacobian function. The factory function is needed
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# to keep a reference to `fun`, see gh-4240.
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def cjac_factory(fun):
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def cjac(x, *args):
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x = _check_clip_x(x, new_bounds)
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if jac in ['2-point', '3-point', 'cs']:
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return approx_derivative(fun, x, method=jac, args=args,
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rel_step=finite_diff_rel_step,
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bounds=new_bounds)
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else:
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return approx_derivative(fun, x, method='2-point',
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abs_step=epsilon, args=args,
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bounds=new_bounds)
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return cjac
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cjac = cjac_factory(con['fun'])
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# update constraints' dictionary
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cons[ctype] += ({'fun': con['fun'],
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'jac': cjac,
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'args': con.get('args', ())}, )
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exit_modes = {-1: "Gradient evaluation required (g & a)",
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0: "Optimization terminated successfully",
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1: "Function evaluation required (f & c)",
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2: "More equality constraints than independent variables",
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3: "More than 3*n iterations in LSQ subproblem",
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4: "Inequality constraints incompatible",
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5: "Singular matrix E in LSQ subproblem",
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6: "Singular matrix C in LSQ subproblem",
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7: "Rank-deficient equality constraint subproblem HFTI",
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8: "Positive directional derivative for linesearch",
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9: "Iteration limit reached"}
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# Set the parameters that SLSQP will need
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# meq, mieq: number of equality and inequality constraints
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meq = sum(map(len, [atleast_1d(c['fun'](x, *c['args']))
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for c in cons['eq']]))
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mieq = sum(map(len, [atleast_1d(c['fun'](x, *c['args']))
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for c in cons['ineq']]))
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# m = The total number of constraints
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m = meq + mieq
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# la = The number of constraints, or 1 if there are no constraints
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la = array([1, m]).max()
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# n = The number of independent variables
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n = len(x)
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# Define the workspaces for SLSQP
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n1 = n + 1
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mineq = m - meq + n1 + n1
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len_w = (3*n1+m)*(n1+1)+(n1-meq+1)*(mineq+2) + 2*mineq+(n1+mineq)*(n1-meq) \
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+ 2*meq + n1 + ((n+1)*n)//2 + 2*m + 3*n + 3*n1 + 1
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len_jw = mineq
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w = zeros(len_w)
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jw = zeros(len_jw)
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# Decompose bounds into xl and xu
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if bounds is None or len(bounds) == 0:
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xl = np.empty(n, dtype=float)
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xu = np.empty(n, dtype=float)
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xl.fill(np.nan)
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xu.fill(np.nan)
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else:
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bnds = array([(_arr_to_scalar(l), _arr_to_scalar(u))
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for (l, u) in bounds], float)
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if bnds.shape[0] != n:
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raise IndexError('SLSQP Error: the length of bounds is not '
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'compatible with that of x0.')
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with np.errstate(invalid='ignore'):
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bnderr = bnds[:, 0] > bnds[:, 1]
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if bnderr.any():
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raise ValueError('SLSQP Error: lb > ub in bounds %s.' %
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', '.join(str(b) for b in bnderr))
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xl, xu = bnds[:, 0], bnds[:, 1]
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# Mark infinite bounds with nans; the Fortran code understands this
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infbnd = ~isfinite(bnds)
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xl[infbnd[:, 0]] = np.nan
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xu[infbnd[:, 1]] = np.nan
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# ScalarFunction provides function and gradient evaluation
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sf = _prepare_scalar_function(func, x, jac=jac, args=args, epsilon=eps,
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finite_diff_rel_step=finite_diff_rel_step,
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bounds=new_bounds)
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# gh11403 SLSQP sometimes exceeds bounds by 1 or 2 ULP, make sure this
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# doesn't get sent to the func/grad evaluator.
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wrapped_fun = _clip_x_for_func(sf.fun, new_bounds)
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wrapped_grad = _clip_x_for_func(sf.grad, new_bounds)
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# Initialize the iteration counter and the mode value
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mode = array(0, int)
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acc = array(acc, float)
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majiter = array(iter, int)
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majiter_prev = 0
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# Initialize internal SLSQP state variables
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alpha = array(0, float)
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f0 = array(0, float)
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gs = array(0, float)
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h1 = array(0, float)
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h2 = array(0, float)
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h3 = array(0, float)
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h4 = array(0, float)
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t = array(0, float)
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t0 = array(0, float)
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tol = array(0, float)
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iexact = array(0, int)
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incons = array(0, int)
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ireset = array(0, int)
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itermx = array(0, int)
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line = array(0, int)
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n1 = array(0, int)
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n2 = array(0, int)
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n3 = array(0, int)
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# Print the header if iprint >= 2
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if iprint >= 2:
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print("%5s %5s %16s %16s" % ("NIT", "FC", "OBJFUN", "GNORM"))
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# mode is zero on entry, so call objective, constraints and gradients
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# there should be no func evaluations here because it's cached from
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# ScalarFunction
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fx = wrapped_fun(x)
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g = append(wrapped_grad(x), 0.0)
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c = _eval_constraint(x, cons)
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a = _eval_con_normals(x, cons, la, n, m, meq, mieq)
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while 1:
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# Call SLSQP
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slsqp(m, meq, x, xl, xu, fx, c, g, a, acc, majiter, mode, w, jw,
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alpha, f0, gs, h1, h2, h3, h4, t, t0, tol,
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iexact, incons, ireset, itermx, line,
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n1, n2, n3)
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if mode == 1: # objective and constraint evaluation required
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fx = wrapped_fun(x)
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c = _eval_constraint(x, cons)
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if mode == -1: # gradient evaluation required
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g = append(wrapped_grad(x), 0.0)
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a = _eval_con_normals(x, cons, la, n, m, meq, mieq)
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if majiter > majiter_prev:
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# call callback if major iteration has incremented
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if callback is not None:
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callback(np.copy(x))
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# Print the status of the current iterate if iprint > 2
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if iprint >= 2:
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print("%5i %5i % 16.6E % 16.6E" % (majiter, sf.nfev,
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fx, linalg.norm(g)))
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# If exit mode is not -1 or 1, slsqp has completed
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if abs(mode) != 1:
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break
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majiter_prev = int(majiter)
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# Optimization loop complete. Print status if requested
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if iprint >= 1:
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print(exit_modes[int(mode)] + " (Exit mode " + str(mode) + ')')
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print(" Current function value:", fx)
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print(" Iterations:", majiter)
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print(" Function evaluations:", sf.nfev)
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print(" Gradient evaluations:", sf.ngev)
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return OptimizeResult(x=x, fun=fx, jac=g[:-1], nit=int(majiter),
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nfev=sf.nfev, njev=sf.ngev, status=int(mode),
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message=exit_modes[int(mode)], success=(mode == 0))
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def _eval_constraint(x, cons):
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# Compute constraints
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if cons['eq']:
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c_eq = concatenate([atleast_1d(con['fun'](x, *con['args']))
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for con in cons['eq']])
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else:
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c_eq = zeros(0)
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if cons['ineq']:
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c_ieq = concatenate([atleast_1d(con['fun'](x, *con['args']))
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for con in cons['ineq']])
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else:
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c_ieq = zeros(0)
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# Now combine c_eq and c_ieq into a single matrix
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c = concatenate((c_eq, c_ieq))
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return c
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|
|
|
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def _eval_con_normals(x, cons, la, n, m, meq, mieq):
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# Compute the normals of the constraints
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if cons['eq']:
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a_eq = vstack([con['jac'](x, *con['args'])
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for con in cons['eq']])
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else: # no equality constraint
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|
a_eq = zeros((meq, n))
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|
|
|
if cons['ineq']:
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|
a_ieq = vstack([con['jac'](x, *con['args'])
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|
for con in cons['ineq']])
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|
else: # no inequality constraint
|
|
a_ieq = zeros((mieq, n))
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|
|
|
# Now combine a_eq and a_ieq into a single a matrix
|
|
if m == 0: # no constraints
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|
a = zeros((la, n))
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|
else:
|
|
a = vstack((a_eq, a_ieq))
|
|
a = concatenate((a, zeros([la, 1])), 1)
|
|
|
|
return a
|