eaiaiaiaoi/venv/lib/python2.7/site-packages/scipy/optimize/_lsq/common.py

"""Functions used by least-squares algorithms."""
from __future__ import division, print_function, absolute_import

from math import copysign

import numpy as np
from numpy.linalg import norm

from scipy.linalg import cho_factor, cho_solve, LinAlgError
from scipy.sparse import issparse
from scipy.sparse.linalg import LinearOperator, aslinearoperator


EPS = np.finfo(float).eps


# Functions related to a trust-region problem.


def intersect_trust_region(x, s, Delta):
    """Find the intersection of a line with the boundary of a trust region.
    
    This function solves the quadratic equation with respect to t
    ||(x + s*t)||**2 = Delta**2.
    
    Returns
    -------
    t_neg, t_pos : tuple of float
        Negative and positive roots.
    
    Raises
    ------
    ValueError
        If `s` is zero or `x` is not within the trust region.
    """
    a = np.dot(s, s)
    if a == 0:
        raise ValueError("`s` is zero.")

    b = np.dot(x, s)

    c = np.dot(x, x) - Delta**2
    if c > 0:
        raise ValueError("`x` is not within the trust region.")

    d = np.sqrt(b*b - a*c)  # Root from one fourth of the discriminant.

    # Computations below avoid loss of significance, see "Numerical Recipes".
    q = -(b + copysign(d, b))
    t1 = q / a
    t2 = c / q

    if t1 < t2:
        return t1, t2
    else:
        return t2, t1


def solve_lsq_trust_region(n, m, uf, s, V, Delta, initial_alpha=None,
                           rtol=0.01, max_iter=10):
    """Solve a trust-region problem arising in least-squares minimization.
    
    This function implements a method described by J. J. More [1]_ and used
    in MINPACK, but it relies on a single SVD of Jacobian instead of series
    of Cholesky decompositions. Before running this function, compute:
    ``U, s, VT = svd(J, full_matrices=False)``.
    
    Parameters
    ----------
    n : int
        Number of variables.
    m : int
        Number of residuals.
    uf : ndarray
        Computed as U.T.dot(f).
    s : ndarray
        Singular values of J.
    V : ndarray
        Transpose of VT.
    Delta : float
        Radius of a trust region.
    initial_alpha : float, optional
        Initial guess for alpha, which might be available from a previous
        iteration. If None, determined automatically.
    rtol : float, optional
        Stopping tolerance for the root-finding procedure. Namely, the
        solution ``p`` will satisfy ``abs(norm(p) - Delta) < rtol * Delta``.
    max_iter : int, optional
        Maximum allowed number of iterations for the root-finding procedure.
    
    Returns
    -------
    p : ndarray, shape (n,)
        Found solution of a trust-region problem.
    alpha : float
        Positive value such that (J.T*J + alpha*I)*p = -J.T*f.
        Sometimes called Levenberg-Marquardt parameter.
    n_iter : int
        Number of iterations made by root-finding procedure. Zero means
        that Gauss-Newton step was selected as the solution.
    
    References
    ----------
    .. [1] More, J. J., "The Levenberg-Marquardt Algorithm: Implementation
           and Theory," Numerical Analysis, ed. G. A. Watson, Lecture Notes
           in Mathematics 630, Springer Verlag, pp. 105-116, 1977.
    """
    def phi_and_derivative(alpha, suf, s, Delta):
        """Function of which to find zero.
        
        It is defined as "norm of regularized (by alpha) least-squares
        solution minus `Delta`". Refer to [1]_.
        """
        denom = s**2 + alpha
        p_norm = norm(suf / denom)
        phi = p_norm - Delta
        phi_prime = -np.sum(suf ** 2 / denom**3) / p_norm
        return phi, phi_prime

    suf = s * uf

    # Check if J has full rank and try Gauss-Newton step.
    if m >= n:
        threshold = EPS * m * s[0]
        full_rank = s[-1] > threshold
    else:
        full_rank = False

    if full_rank:
        p = -V.dot(uf / s)
        if norm(p) <= Delta:
            return p, 0.0, 0

    alpha_upper = norm(suf) / Delta

    if full_rank:
        phi, phi_prime = phi_and_derivative(0.0, suf, s, Delta)
        alpha_lower = -phi / phi_prime
    else:
        alpha_lower = 0.0

    if initial_alpha is None or not full_rank and initial_alpha == 0:
        alpha = max(0.001 * alpha_upper, (alpha_lower * alpha_upper)**0.5)
    else:
        alpha = initial_alpha

    for it in range(max_iter):
        if alpha < alpha_lower or alpha > alpha_upper:
            alpha = max(0.001 * alpha_upper, (alpha_lower * alpha_upper)**0.5)

        phi, phi_prime = phi_and_derivative(alpha, suf, s, Delta)

        if phi < 0:
            alpha_upper = alpha

        ratio = phi / phi_prime
        alpha_lower = max(alpha_lower, alpha - ratio)
        alpha -= (phi + Delta) * ratio / Delta

        if np.abs(phi) < rtol * Delta:
            break

    p = -V.dot(suf / (s**2 + alpha))

    # Make the norm of p equal to Delta, p is changed only slightly during
    # this. It is done to prevent p lie outside the trust region (which can
    # cause problems later).
    p *= Delta / norm(p)

    return p, alpha, it + 1


def solve_trust_region_2d(B, g, Delta):
    """Solve a general trust-region problem in 2 dimensions.
    
    The problem is reformulated as a 4-th order algebraic equation,
    the solution of which is found by numpy.roots.
    
    Parameters
    ----------
    B : ndarray, shape (2, 2)
        Symmetric matrix, defines a quadratic term of the function.
    g : ndarray, shape (2,)
        Defines a linear term of the function.
    Delta : float
        Radius of a trust region.
    
    Returns
    -------
    p : ndarray, shape (2,)
        Found solution.
    newton_step : bool
        Whether the returned solution is the Newton step which lies within
        the trust region.
    """
    try:
        R, lower = cho_factor(B)
        p = -cho_solve((R, lower), g)
        if np.dot(p, p) <= Delta**2:
            return p, True
    except LinAlgError:
        pass

    a = B[0, 0] * Delta**2
    b = B[0, 1] * Delta**2
    c = B[1, 1] * Delta**2

    d = g[0] * Delta
    f = g[1] * Delta

    coeffs = np.array(
        [-b + d, 2 * (a - c + f), 6 * b, 2 * (-a + c + f), -b - d])
    t = np.roots(coeffs)  # Can handle leading zeros.
    t = np.real(t[np.isreal(t)])

    p = Delta * np.vstack((2 * t / (1 + t**2), (1 - t**2) / (1 + t**2)))
    value = 0.5 * np.sum(p * B.dot(p), axis=0) + np.dot(g, p)
    i = np.argmin(value)
    p = p[:, i]

    return p, False


def update_tr_radius(Delta, actual_reduction, predicted_reduction,
                     step_norm, bound_hit):
    """Update the radius of a trust region based on the cost reduction.

    Returns
    -------
    Delta : float
        New radius.
    ratio : float
        Ratio between actual and predicted reductions. Zero if predicted
        reduction is zero.
    """
    if predicted_reduction > 0:
        ratio = actual_reduction / predicted_reduction
    else:
        ratio = 0

    if ratio < 0.25:
        Delta = 0.25 * step_norm
    elif ratio > 0.75 and bound_hit:
        Delta *= 2.0

    return Delta, ratio


# Construction and minimization of quadratic functions.


def build_quadratic_1d(J, g, s, diag=None, s0=None):
    """Parameterize a multivariate quadratic function along a line.
    
    The resulting univariate quadratic function is given as follows:
    ::
        f(t) = 0.5 * (s0 + s*t).T * (J.T*J + diag) * (s0 + s*t) +
               g.T * (s0 + s*t)
    
    Parameters
    ----------
    J : ndarray, sparse matrix or LinearOperator shape (m, n)
        Jacobian matrix, affects the quadratic term.
    g : ndarray, shape (n,)
        Gradient, defines the linear term.
    s : ndarray, shape (n,)
        Direction vector of a line.
    diag : None or ndarray with shape (n,), optional
        Addition diagonal part, affects the quadratic term.
        If None, assumed to be 0.
    s0 : None or ndarray with shape (n,), optional
        Initial point. If None, assumed to be 0.
    
    Returns
    -------
    a : float
        Coefficient for t**2.
    b : float
        Coefficient for t.
    c : float
        Free term. Returned only if `s0` is provided.
    """
    v = J.dot(s)
    a = np.dot(v, v)
    if diag is not None:
        a += np.dot(s * diag, s)
    a *= 0.5

    b = np.dot(g, s)

    if s0 is not None:
        u = J.dot(s0)
        b += np.dot(u, v)
        c = 0.5 * np.dot(u, u) + np.dot(g, s0)
        if diag is not None:
            b += np.dot(s0 * diag, s)
            c += 0.5 * np.dot(s0 * diag, s0)
        return a, b, c
    else:
        return a, b


def minimize_quadratic_1d(a, b, lb, ub, c=0):
    """Minimize a 1-d quadratic function subject to bounds.
    
    The free term `c` is 0 by default. Bounds must be finite.
    
    Returns
    -------
    t : float
        Minimum point.
    y : float
        Minimum value.
    """
    t = [lb, ub]
    if a != 0:
        extremum = -0.5 * b / a
        if lb < extremum < ub:
            t.append(extremum)
    t = np.asarray(t)
    y = a * t**2 + b * t + c
    min_index = np.argmin(y)
    return t[min_index], y[min_index]


def evaluate_quadratic(J, g, s, diag=None):
    """Compute values of a quadratic function arising in least squares.
    
    The function is 0.5 * s.T * (J.T * J + diag) * s + g.T * s.
    
    Parameters
    ----------
    J : ndarray, sparse matrix or LinearOperator, shape (m, n)
        Jacobian matrix, affects the quadratic term.
    g : ndarray, shape (n,)
        Gradient, defines the linear term.
    s : ndarray, shape (k, n) or (n,)
        Array containing steps as rows.
    diag : ndarray, shape (n,), optional
        Addition diagonal part, affects the quadratic term.
        If None, assumed to be 0.
    
    Returns
    -------
    values : ndarray with shape (k,) or float
        Values of the function. If `s` was 2-dimensional then ndarray is
        returned, otherwise float is returned.
    """
    if s.ndim == 1:
        Js = J.dot(s)
        q = np.dot(Js, Js)
        if diag is not None:
            q += np.dot(s * diag, s)
    else:
        Js = J.dot(s.T)
        q = np.sum(Js**2, axis=0)
        if diag is not None:
            q += np.sum(diag * s**2, axis=1)

    l = np.dot(s, g)

    return 0.5 * q + l


# Utility functions to work with bound constraints.


def in_bounds(x, lb, ub):
    """Check if a point lies within bounds."""
    return np.all((x >= lb) & (x <= ub))


def step_size_to_bound(x, s, lb, ub):
    """Compute a min_step size required to reach a bound.
    
    The function computes a positive scalar t, such that x + s * t is on
    the bound.
    
    Returns
    -------
    step : float
        Computed step. Non-negative value.
    hits : ndarray of int with shape of x
        Each element indicates whether a corresponding variable reaches the
        bound:
             
             *  0 - the bound was not hit.
             * -1 - the lower bound was hit.
             *  1 - the upper bound was hit.
    """
    non_zero = np.nonzero(s)
    s_non_zero = s[non_zero]
    steps = np.empty_like(x)
    steps.fill(np.inf)
    with np.errstate(over='ignore'):
        steps[non_zero] = np.maximum((lb - x)[non_zero] / s_non_zero,
                                     (ub - x)[non_zero] / s_non_zero)
    min_step = np.min(steps)
    return min_step, np.equal(steps, min_step) * np.sign(s).astype(int)


def find_active_constraints(x, lb, ub, rtol=1e-10):
    """Determine which constraints are active in a given point.
    
    The threshold is computed using `rtol` and the absolute value of the
    closest bound.
    
    Returns
    -------
    active : ndarray of int with shape of x
        Each component shows whether the corresponding constraint is active:
             
             *  0 - a constraint is not active.
             * -1 - a lower bound is active.
             *  1 - a upper bound is active.
    """
    active = np.zeros_like(x, dtype=int)

    if rtol == 0:
        active[x <= lb] = -1
        active[x >= ub] = 1
        return active

    lower_dist = x - lb
    upper_dist = ub - x

    lower_threshold = rtol * np.maximum(1, np.abs(lb))
    upper_threshold = rtol * np.maximum(1, np.abs(ub))

    lower_active = (np.isfinite(lb) &
                    (lower_dist <= np.minimum(upper_dist, lower_threshold)))
    active[lower_active] = -1

    upper_active = (np.isfinite(ub) &
                    (upper_dist <= np.minimum(lower_dist, upper_threshold)))
    active[upper_active] = 1

    return active


def make_strictly_feasible(x, lb, ub, rstep=1e-10):
    """Shift a point to the interior of a feasible region.
    
    Each element of the returned vector is at least at a relative distance
    `rstep` from the closest bound. If ``rstep=0`` then `np.nextafter` is used.
    """
    x_new = x.copy()

    active = find_active_constraints(x, lb, ub, rstep)
    lower_mask = np.equal(active, -1)
    upper_mask = np.equal(active, 1)

    if rstep == 0:
        x_new[lower_mask] = np.nextafter(lb[lower_mask], ub[lower_mask])
        x_new[upper_mask] = np.nextafter(ub[upper_mask], lb[upper_mask])
    else:
        x_new[lower_mask] = (lb[lower_mask] +
                             rstep * np.maximum(1, np.abs(lb[lower_mask])))
        x_new[upper_mask] = (ub[upper_mask] -
                             rstep * np.maximum(1, np.abs(ub[upper_mask])))

    tight_bounds = (x_new < lb) | (x_new > ub)
    x_new[tight_bounds] = 0.5 * (lb[tight_bounds] + ub[tight_bounds])

    return x_new

 
def CL_scaling_vector(x, g, lb, ub):
    """Compute Coleman-Li scaling vector and its derivatives.
    
    Components of a vector v are defined as follows:
    ::
               | ub[i] - x[i], if g[i] < 0 and ub[i] < np.inf
        v[i] = | x[i] - lb[i], if g[i] > 0 and lb[i] > -np.inf
               | 1,           otherwise
    
    According to this definition v[i] >= 0 for all i. It differs from the
    definition in paper [1]_ (eq. (2.2)), where the absolute value of v is
    used. Both definitions are equivalent down the line.
    Derivatives of v with respect to x take value 1, -1 or 0 depending on a
    case.
    
    Returns
    -------
    v : ndarray with shape of x
        Scaling vector.
    dv : ndarray with shape of x
        Derivatives of v[i] with respect to x[i], diagonal elements of v's
        Jacobian.
    
    References
    ----------
    .. [1] M.A. Branch, T.F. Coleman, and Y. Li, "A Subspace, Interior,
           and Conjugate Gradient Method for Large-Scale Bound-Constrained
           Minimization Problems," SIAM Journal on Scientific Computing,
           Vol. 21, Number 1, pp 1-23, 1999.
    """
    v = np.ones_like(x)
    dv = np.zeros_like(x)

    mask = (g < 0) & np.isfinite(ub)
    v[mask] = ub[mask] - x[mask]
    dv[mask] = -1

    mask = (g > 0) & np.isfinite(lb)
    v[mask] = x[mask] - lb[mask]
    dv[mask] = 1

    return v, dv


def reflective_transformation(y, lb, ub):
    """Compute reflective transformation and its gradient."""
    if in_bounds(y, lb, ub):
        return y, np.ones_like(y)

    lb_finite = np.isfinite(lb)
    ub_finite = np.isfinite(ub)

    x = y.copy()
    g_negative = np.zeros_like(y, dtype=bool)

    mask = lb_finite & ~ub_finite
    x[mask] = np.maximum(y[mask], 2 * lb[mask] - y[mask])
    g_negative[mask] = y[mask] < lb[mask]

    mask = ~lb_finite & ub_finite
    x[mask] = np.minimum(y[mask], 2 * ub[mask] - y[mask])
    g_negative[mask] = y[mask] > ub[mask]

    mask = lb_finite & ub_finite
    d = ub - lb
    t = np.remainder(y[mask] - lb[mask], 2 * d[mask])
    x[mask] = lb[mask] + np.minimum(t, 2 * d[mask] - t)
    g_negative[mask] = t > d[mask]

    g = np.ones_like(y)
    g[g_negative] = -1

    return x, g


# Functions to display algorithm's progress.


def print_header_nonlinear():
    print("{0:^15}{1:^15}{2:^15}{3:^15}{4:^15}{5:^15}"
          .format("Iteration", "Total nfev", "Cost", "Cost reduction",
                  "Step norm", "Optimality"))


def print_iteration_nonlinear(iteration, nfev, cost, cost_reduction,
                              step_norm, optimality):
    if cost_reduction is None:
        cost_reduction = " " * 15
    else:
        cost_reduction = "{0:^15.2e}".format(cost_reduction)

    if step_norm is None:
        step_norm = " " * 15
    else:
        step_norm = "{0:^15.2e}".format(step_norm)

    print("{0:^15}{1:^15}{2:^15.4e}{3}{4}{5:^15.2e}"
          .format(iteration, nfev, cost, cost_reduction,
                  step_norm, optimality))


def print_header_linear():
    print("{0:^15}{1:^15}{2:^15}{3:^15}{4:^15}"
          .format("Iteration", "Cost", "Cost reduction", "Step norm",
                  "Optimality"))


def print_iteration_linear(iteration, cost, cost_reduction, step_norm,
                           optimality):
    if cost_reduction is None:
        cost_reduction = " " * 15
    else:
        cost_reduction = "{0:^15.2e}".format(cost_reduction)

    if step_norm is None:
        step_norm = " " * 15
    else:
        step_norm = "{0:^15.2e}".format(step_norm)

    print("{0:^15}{1:^15.4e}{2}{3}{4:^15.2e}".format(
        iteration, cost, cost_reduction, step_norm, optimality))


# Simple helper functions.


def compute_grad(J, f):
    """Compute gradient of the least-squares cost function."""
    if isinstance(J, LinearOperator):
        return J.rmatvec(f)
    else:
        return J.T.dot(f)


def compute_jac_scale(J, scale_inv_old=None):
    """Compute variables scale based on the Jacobian matrix."""
    if issparse(J):
        scale_inv = np.asarray(J.power(2).sum(axis=0)).ravel()**0.5
    else:
        scale_inv = np.sum(J**2, axis=0)**0.5

    if scale_inv_old is None:
        scale_inv[scale_inv == 0] = 1
    else:
        scale_inv = np.maximum(scale_inv, scale_inv_old)

    return 1 / scale_inv, scale_inv


def left_multiplied_operator(J, d):
    """Return diag(d) J as LinearOperator."""
    J = aslinearoperator(J)

    def matvec(x):
        return d * J.matvec(x)

    def matmat(X):
        return d[:, np.newaxis] * J.matmat(X)

    def rmatvec(x):
        return J.rmatvec(x.ravel() * d)

    return LinearOperator(J.shape, matvec=matvec, matmat=matmat,
                          rmatvec=rmatvec)


def right_multiplied_operator(J, d):
    """Return J diag(d) as LinearOperator."""
    J = aslinearoperator(J)

    def matvec(x):
        return J.matvec(np.ravel(x) * d)

    def matmat(X):
        return J.matmat(X * d[:, np.newaxis])

    def rmatvec(x):
        return d * J.rmatvec(x)

    return LinearOperator(J.shape, matvec=matvec, matmat=matmat,
                          rmatvec=rmatvec)


def regularized_lsq_operator(J, diag):
    """Return a matrix arising in regularized least squares as LinearOperator.
    
    The matrix is
        [ J ]
        [ D ]
    where D is diagonal matrix with elements from `diag`.
    """
    J = aslinearoperator(J)
    m, n = J.shape

    def matvec(x):
        return np.hstack((J.matvec(x), diag * x))

    def rmatvec(x):
        x1 = x[:m]
        x2 = x[m:]
        return J.rmatvec(x1) + diag * x2

    return LinearOperator((m + n, n), matvec=matvec, rmatvec=rmatvec)


def right_multiply(J, d, copy=True):
    """Compute J diag(d).
    
    If `copy` is False, `J` is modified in place (unless being LinearOperator).
    """
    if copy and not isinstance(J, LinearOperator):
        J = J.copy()

    if issparse(J):
        J.data *= d.take(J.indices, mode='clip')  # scikit-learn recipe.
    elif isinstance(J, LinearOperator):
        J = right_multiplied_operator(J, d)
    else:
        J *= d

    return J


def left_multiply(J, d, copy=True):
    """Compute diag(d) J.
    
    If `copy` is False, `J` is modified in place (unless being LinearOperator).
    """
    if copy and not isinstance(J, LinearOperator):
        J = J.copy()

    if issparse(J):
        J.data *= np.repeat(d, np.diff(J.indptr))  # scikit-learn recipe.
    elif isinstance(J, LinearOperator):
        J = left_multiplied_operator(J, d)
    else:
        J *= d[:, np.newaxis]

    return J


def check_termination(dF, F, dx_norm, x_norm, ratio, ftol, xtol):
    """Check termination condition for nonlinear least squares."""
    ftol_satisfied = dF < ftol * F and ratio > 0.25
    xtol_satisfied = dx_norm < xtol * (xtol + x_norm)

    if ftol_satisfied and xtol_satisfied:
        return 4
    elif ftol_satisfied:
        return 2
    elif xtol_satisfied:
        return 3
    else:
        return None


def scale_for_robust_loss_function(J, f, rho):
    """Scale Jacobian and residuals for a robust loss function.
    
    Arrays are modified in place.
    """
    J_scale = rho[1] + 2 * rho[2] * f**2
    J_scale[J_scale < EPS] = EPS
    J_scale **= 0.5

    f *= rho[1] / J_scale

    return left_multiply(J, J_scale, copy=False), f
add in project 6 years ago			`"""Functions used by least-squares algorithms."""`
			`from __future__ import division, print_function, absolute_import`

			`from math import copysign`

			`import numpy as np`
			`from numpy.linalg import norm`

			`from scipy.linalg import cho_factor, cho_solve, LinAlgError`
			`from scipy.sparse import issparse`
			`from scipy.sparse.linalg import LinearOperator, aslinearoperator`


			`EPS = np.finfo(float).eps`


			`# Functions related to a trust-region problem.`


			`def intersect_trust_region(x, s, Delta):`
			`"""Find the intersection of a line with the boundary of a trust region.`

			`This function solves the quadratic equation with respect to t`
			`\|\|(x + st)\|\|2 = Delta*2.`

			`Returns`
			`-------`
			`t_neg, t_pos : tuple of float`
			`Negative and positive roots.`

			`Raises`
			`------`
			`ValueError`
			If `s` is zero or `x` is not within the trust region.
			`"""`
			`a = np.dot(s, s)`
			`if a == 0:`
			raise ValueError("`s` is zero.")

			`b = np.dot(x, s)`

			`c = np.dot(x, x) - Delta**2`
			`if c > 0:`
			raise ValueError("`x` is not within the trust region.")

			`d = np.sqrt(bb - ac) # Root from one fourth of the discriminant.`

			`# Computations below avoid loss of significance, see "Numerical Recipes".`
			`q = -(b + copysign(d, b))`
			`t1 = q / a`
			`t2 = c / q`

			`if t1 < t2:`
			`return t1, t2`
			`else:`
			`return t2, t1`


			`def solve_lsq_trust_region(n, m, uf, s, V, Delta, initial_alpha=None,`
			`rtol=0.01, max_iter=10):`
			`"""Solve a trust-region problem arising in least-squares minimization.`

			`This function implements a method described by J. J. More [1]_ and used`
			`in MINPACK, but it relies on a single SVD of Jacobian instead of series`
			`of Cholesky decompositions. Before running this function, compute:`
			``U, s, VT = svd(J, full_matrices=False)``.

			`Parameters`
			`----------`
			`n : int`
			`Number of variables.`
			`m : int`
			`Number of residuals.`
			`uf : ndarray`
			`Computed as U.T.dot(f).`
			`s : ndarray`
			`Singular values of J.`
			`V : ndarray`
			`Transpose of VT.`
			`Delta : float`
			`Radius of a trust region.`
			`initial_alpha : float, optional`
			`Initial guess for alpha, which might be available from a previous`
			`iteration. If None, determined automatically.`
			`rtol : float, optional`
			`Stopping tolerance for the root-finding procedure. Namely, the`
			solution ``p`` will satisfy ``abs(norm(p) - Delta) < rtol * Delta``.
			`max_iter : int, optional`
			`Maximum allowed number of iterations for the root-finding procedure.`

			`Returns`
			`-------`
			`p : ndarray, shape (n,)`
			`Found solution of a trust-region problem.`
			`alpha : float`
			`Positive value such that (J.TJ + alphaI)p = -J.Tf.`
			`Sometimes called Levenberg-Marquardt parameter.`
			`n_iter : int`
			`Number of iterations made by root-finding procedure. Zero means`
			`that Gauss-Newton step was selected as the solution.`

			`References`
			`----------`
			`.. [1] More, J. J., "The Levenberg-Marquardt Algorithm: Implementation`
			`and Theory," Numerical Analysis, ed. G. A. Watson, Lecture Notes`
			`in Mathematics 630, Springer Verlag, pp. 105-116, 1977.`
			`"""`
			`def phi_and_derivative(alpha, suf, s, Delta):`
			`"""Function of which to find zero.`

			`It is defined as "norm of regularized (by alpha) least-squares`
			solution minus `Delta`". Refer to [1]_.
			`"""`
			`denom = s**2 + alpha`
			`p_norm = norm(suf / denom)`
			`phi = p_norm - Delta`
			`phi_prime = -np.sum(suf 2 / denom3) / p_norm`
			`return phi, phi_prime`

			`suf = s * uf`

			`# Check if J has full rank and try Gauss-Newton step.`
			`if m >= n:`
			`threshold = EPS * m * s[0]`
			`full_rank = s[-1] > threshold`
			`else:`
			`full_rank = False`

			`if full_rank:`
			`p = -V.dot(uf / s)`
			`if norm(p) <= Delta:`
			`return p, 0.0, 0`

			`alpha_upper = norm(suf) / Delta`

			`if full_rank:`
			`phi, phi_prime = phi_and_derivative(0.0, suf, s, Delta)`
			`alpha_lower = -phi / phi_prime`
			`else:`
			`alpha_lower = 0.0`

			`if initial_alpha is None or not full_rank and initial_alpha == 0:`
			`alpha = max(0.001 * alpha_upper, (alpha_lower * alpha_upper)**0.5)`
			`else:`
			`alpha = initial_alpha`

			`for it in range(max_iter):`
			`if alpha < alpha_lower or alpha > alpha_upper:`
			`alpha = max(0.001 * alpha_upper, (alpha_lower * alpha_upper)**0.5)`

			`phi, phi_prime = phi_and_derivative(alpha, suf, s, Delta)`

			`if phi < 0:`
			`alpha_upper = alpha`

			`ratio = phi / phi_prime`
			`alpha_lower = max(alpha_lower, alpha - ratio)`
			`alpha -= (phi + Delta) * ratio / Delta`

			`if np.abs(phi) < rtol * Delta:`
			`break`

			`p = -V.dot(suf / (s**2 + alpha))`

			`# Make the norm of p equal to Delta, p is changed only slightly during`
			`# this. It is done to prevent p lie outside the trust region (which can`
			`# cause problems later).`
			`p *= Delta / norm(p)`

			`return p, alpha, it + 1`


			`def solve_trust_region_2d(B, g, Delta):`
			`"""Solve a general trust-region problem in 2 dimensions.`

			`The problem is reformulated as a 4-th order algebraic equation,`
			`the solution of which is found by numpy.roots.`

			`Parameters`
			`----------`
			`B : ndarray, shape (2, 2)`
			`Symmetric matrix, defines a quadratic term of the function.`
			`g : ndarray, shape (2,)`
			`Defines a linear term of the function.`
			`Delta : float`
			`Radius of a trust region.`

			`Returns`
			`-------`
			`p : ndarray, shape (2,)`
			`Found solution.`
			`newton_step : bool`
			`Whether the returned solution is the Newton step which lies within`
			`the trust region.`
			`"""`
			`try:`
			`R, lower = cho_factor(B)`
			`p = -cho_solve((R, lower), g)`
			`if np.dot(p, p) <= Delta**2:`
			`return p, True`
			`except LinAlgError:`
			`pass`

			`a = B[0, 0] * Delta**2`
			`b = B[0, 1] * Delta**2`
			`c = B[1, 1] * Delta**2`

			`d = g[0] * Delta`
			`f = g[1] * Delta`

			`coeffs = np.array(`
			`[-b + d, 2 * (a - c + f), 6 * b, 2 * (-a + c + f), -b - d])`
			`t = np.roots(coeffs) # Can handle leading zeros.`
			`t = np.real(t[np.isreal(t)])`

			`p = Delta * np.vstack((2 * t / (1 + t2), (1 - t2) / (1 + t**2)))`
			`value = 0.5 * np.sum(p * B.dot(p), axis=0) + np.dot(g, p)`
			`i = np.argmin(value)`
			`p = p[:, i]`

			`return p, False`


			`def update_tr_radius(Delta, actual_reduction, predicted_reduction,`
			`step_norm, bound_hit):`
			`"""Update the radius of a trust region based on the cost reduction.`

			`Returns`
			`-------`
			`Delta : float`
			`New radius.`
			`ratio : float`
			`Ratio between actual and predicted reductions. Zero if predicted`
			`reduction is zero.`
			`"""`
			`if predicted_reduction > 0:`
			`ratio = actual_reduction / predicted_reduction`
			`else:`
			`ratio = 0`

			`if ratio < 0.25:`
			`Delta = 0.25 * step_norm`
			`elif ratio > 0.75 and bound_hit:`
			`Delta *= 2.0`

			`return Delta, ratio`


			`# Construction and minimization of quadratic functions.`


			`def build_quadratic_1d(J, g, s, diag=None, s0=None):`
			`"""Parameterize a multivariate quadratic function along a line.`

			`The resulting univariate quadratic function is given as follows:`
			`::`
			`f(t) = 0.5 * (s0 + st).T (J.TJ + diag) (s0 + s*t) +`
			`g.T * (s0 + s*t)`

			`Parameters`
			`----------`
			`J : ndarray, sparse matrix or LinearOperator shape (m, n)`
			`Jacobian matrix, affects the quadratic term.`
			`g : ndarray, shape (n,)`
			`Gradient, defines the linear term.`
			`s : ndarray, shape (n,)`
			`Direction vector of a line.`
			`diag : None or ndarray with shape (n,), optional`
			`Addition diagonal part, affects the quadratic term.`
			`If None, assumed to be 0.`
			`s0 : None or ndarray with shape (n,), optional`
			`Initial point. If None, assumed to be 0.`

			`Returns`
			`-------`
			`a : float`
			`Coefficient for t**2.`
			`b : float`
			`Coefficient for t.`
			`c : float`
			Free term. Returned only if `s0` is provided.
			`"""`
			`v = J.dot(s)`
			`a = np.dot(v, v)`
			`if diag is not None:`
			`a += np.dot(s * diag, s)`
			`a *= 0.5`

			`b = np.dot(g, s)`

			`if s0 is not None:`
			`u = J.dot(s0)`
			`b += np.dot(u, v)`
			`c = 0.5 * np.dot(u, u) + np.dot(g, s0)`
			`if diag is not None:`
			`b += np.dot(s0 * diag, s)`
			`c += 0.5 * np.dot(s0 * diag, s0)`
			`return a, b, c`
			`else:`
			`return a, b`


			`def minimize_quadratic_1d(a, b, lb, ub, c=0):`
			`"""Minimize a 1-d quadratic function subject to bounds.`

			The free term `c` is 0 by default. Bounds must be finite.

			`Returns`
			`-------`
			`t : float`
			`Minimum point.`
			`y : float`
			`Minimum value.`
			`"""`
			`t = [lb, ub]`
			`if a != 0:`
			`extremum = -0.5 * b / a`
			`if lb < extremum < ub:`
			`t.append(extremum)`
			`t = np.asarray(t)`
			`y = a * t*2 + b t + c`
			`min_index = np.argmin(y)`
			`return t[min_index], y[min_index]`


			`def evaluate_quadratic(J, g, s, diag=None):`
			`"""Compute values of a quadratic function arising in least squares.`

			`The function is 0.5 * s.T * (J.T * J + diag) * s + g.T * s.`

			`Parameters`
			`----------`
			`J : ndarray, sparse matrix or LinearOperator, shape (m, n)`
			`Jacobian matrix, affects the quadratic term.`
			`g : ndarray, shape (n,)`
			`Gradient, defines the linear term.`
			`s : ndarray, shape (k, n) or (n,)`
			`Array containing steps as rows.`
			`diag : ndarray, shape (n,), optional`
			`Addition diagonal part, affects the quadratic term.`
			`If None, assumed to be 0.`

			`Returns`
			`-------`
			`values : ndarray with shape (k,) or float`
			Values of the function. If `s` was 2-dimensional then ndarray is
			`returned, otherwise float is returned.`
			`"""`
			`if s.ndim == 1:`
			`Js = J.dot(s)`
			`q = np.dot(Js, Js)`
			`if diag is not None:`
			`q += np.dot(s * diag, s)`
			`else:`
			`Js = J.dot(s.T)`
			`q = np.sum(Js**2, axis=0)`
			`if diag is not None:`
			`q += np.sum(diag * s**2, axis=1)`

			`l = np.dot(s, g)`

			`return 0.5 * q + l`


			`# Utility functions to work with bound constraints.`


			`def in_bounds(x, lb, ub):`
			`"""Check if a point lies within bounds."""`
			`return np.all((x >= lb) & (x <= ub))`


			`def step_size_to_bound(x, s, lb, ub):`
			`"""Compute a min_step size required to reach a bound.`

			`The function computes a positive scalar t, such that x + s * t is on`
			`the bound.`

			`Returns`
			`-------`
			`step : float`
			`Computed step. Non-negative value.`
			`hits : ndarray of int with shape of x`
			`Each element indicates whether a corresponding variable reaches the`
			`bound:`

			`* 0 - the bound was not hit.`
			`* -1 - the lower bound was hit.`
			`* 1 - the upper bound was hit.`
			`"""`
			`non_zero = np.nonzero(s)`
			`s_non_zero = s[non_zero]`
			`steps = np.empty_like(x)`
			`steps.fill(np.inf)`
			`with np.errstate(over='ignore'):`
			`steps[non_zero] = np.maximum((lb - x)[non_zero] / s_non_zero,`
			`(ub - x)[non_zero] / s_non_zero)`
			`min_step = np.min(steps)`
			`return min_step, np.equal(steps, min_step) * np.sign(s).astype(int)`


			`def find_active_constraints(x, lb, ub, rtol=1e-10):`
			`"""Determine which constraints are active in a given point.`

			The threshold is computed using `rtol` and the absolute value of the
			`closest bound.`

			`Returns`
			`-------`
			`active : ndarray of int with shape of x`
			`Each component shows whether the corresponding constraint is active:`

			`* 0 - a constraint is not active.`
			`* -1 - a lower bound is active.`
			`* 1 - a upper bound is active.`
			`"""`
			`active = np.zeros_like(x, dtype=int)`

			`if rtol == 0:`
			`active[x <= lb] = -1`
			`active[x >= ub] = 1`
			`return active`

			`lower_dist = x - lb`
			`upper_dist = ub - x`

			`lower_threshold = rtol * np.maximum(1, np.abs(lb))`
			`upper_threshold = rtol * np.maximum(1, np.abs(ub))`

			`lower_active = (np.isfinite(lb) &`
			`(lower_dist <= np.minimum(upper_dist, lower_threshold)))`
			`active[lower_active] = -1`

			`upper_active = (np.isfinite(ub) &`
			`(upper_dist <= np.minimum(lower_dist, upper_threshold)))`
			`active[upper_active] = 1`

			`return active`


			`def make_strictly_feasible(x, lb, ub, rstep=1e-10):`
			`"""Shift a point to the interior of a feasible region.`

			`Each element of the returned vector is at least at a relative distance`
			`rstep` from the closest bound. If ``rstep=0`` then `np.nextafter` is used.
			`"""`
			`x_new = x.copy()`

			`active = find_active_constraints(x, lb, ub, rstep)`
			`lower_mask = np.equal(active, -1)`
			`upper_mask = np.equal(active, 1)`

			`if rstep == 0:`
			`x_new[lower_mask] = np.nextafter(lb[lower_mask], ub[lower_mask])`
			`x_new[upper_mask] = np.nextafter(ub[upper_mask], lb[upper_mask])`
			`else:`
			`x_new[lower_mask] = (lb[lower_mask] +`
			`rstep * np.maximum(1, np.abs(lb[lower_mask])))`
			`x_new[upper_mask] = (ub[upper_mask] -`
			`rstep * np.maximum(1, np.abs(ub[upper_mask])))`

			`tight_bounds = (x_new < lb) \| (x_new > ub)`
			`x_new[tight_bounds] = 0.5 * (lb[tight_bounds] + ub[tight_bounds])`

			`return x_new`


			`def CL_scaling_vector(x, g, lb, ub):`
			`"""Compute Coleman-Li scaling vector and its derivatives.`

			`Components of a vector v are defined as follows:`
			`::`
			`\| ub[i] - x[i], if g[i] < 0 and ub[i] < np.inf`
			`v[i] = \| x[i] - lb[i], if g[i] > 0 and lb[i] > -np.inf`
			`\| 1, otherwise`

			`According to this definition v[i] >= 0 for all i. It differs from the`
			`definition in paper [1]_ (eq. (2.2)), where the absolute value of v is`
			`used. Both definitions are equivalent down the line.`
			`Derivatives of v with respect to x take value 1, -1 or 0 depending on a`
			`case.`

			`Returns`
			`-------`
			`v : ndarray with shape of x`
			`Scaling vector.`
			`dv : ndarray with shape of x`
			`Derivatives of v[i] with respect to x[i], diagonal elements of v's`
			`Jacobian.`

			`References`
			`----------`
			`.. [1] M.A. Branch, T.F. Coleman, and Y. Li, "A Subspace, Interior,`
			`and Conjugate Gradient Method for Large-Scale Bound-Constrained`
			`Minimization Problems," SIAM Journal on Scientific Computing,`
			`Vol. 21, Number 1, pp 1-23, 1999.`
			`"""`
			`v = np.ones_like(x)`
			`dv = np.zeros_like(x)`

			`mask = (g < 0) & np.isfinite(ub)`
			`v[mask] = ub[mask] - x[mask]`
			`dv[mask] = -1`

			`mask = (g > 0) & np.isfinite(lb)`
			`v[mask] = x[mask] - lb[mask]`
			`dv[mask] = 1`

			`return v, dv`


			`def reflective_transformation(y, lb, ub):`
			`"""Compute reflective transformation and its gradient."""`
			`if in_bounds(y, lb, ub):`
			`return y, np.ones_like(y)`

			`lb_finite = np.isfinite(lb)`
			`ub_finite = np.isfinite(ub)`

			`x = y.copy()`
			`g_negative = np.zeros_like(y, dtype=bool)`

			`mask = lb_finite & ~ub_finite`
			`x[mask] = np.maximum(y[mask], 2 * lb[mask] - y[mask])`
			`g_negative[mask] = y[mask] < lb[mask]`

			`mask = ~lb_finite & ub_finite`
			`x[mask] = np.minimum(y[mask], 2 * ub[mask] - y[mask])`
			`g_negative[mask] = y[mask] > ub[mask]`

			`mask = lb_finite & ub_finite`
			`d = ub - lb`
			`t = np.remainder(y[mask] - lb[mask], 2 * d[mask])`
			`x[mask] = lb[mask] + np.minimum(t, 2 * d[mask] - t)`
			`g_negative[mask] = t > d[mask]`

			`g = np.ones_like(y)`
			`g[g_negative] = -1`

			`return x, g`


			`# Functions to display algorithm's progress.`


			`def print_header_nonlinear():`
			`print("{0:^15}{1:^15}{2:^15}{3:^15}{4:^15}{5:^15}"`
			`.format("Iteration", "Total nfev", "Cost", "Cost reduction",`
			`"Step norm", "Optimality"))`


			`def print_iteration_nonlinear(iteration, nfev, cost, cost_reduction,`
			`step_norm, optimality):`
			`if cost_reduction is None:`
			`cost_reduction = " " * 15`
			`else:`
			`cost_reduction = "{0:^15.2e}".format(cost_reduction)`

			`if step_norm is None:`
			`step_norm = " " * 15`
			`else:`
			`step_norm = "{0:^15.2e}".format(step_norm)`

			`print("{0:^15}{1:^15}{2:^15.4e}{3}{4}{5:^15.2e}"`
			`.format(iteration, nfev, cost, cost_reduction,`
			`step_norm, optimality))`


			`def print_header_linear():`
			`print("{0:^15}{1:^15}{2:^15}{3:^15}{4:^15}"`
			`.format("Iteration", "Cost", "Cost reduction", "Step norm",`
			`"Optimality"))`


			`def print_iteration_linear(iteration, cost, cost_reduction, step_norm,`
			`optimality):`
			`if cost_reduction is None:`
			`cost_reduction = " " * 15`
			`else:`
			`cost_reduction = "{0:^15.2e}".format(cost_reduction)`

			`if step_norm is None:`
			`step_norm = " " * 15`
			`else:`
			`step_norm = "{0:^15.2e}".format(step_norm)`

			`print("{0:^15}{1:^15.4e}{2}{3}{4:^15.2e}".format(`
			`iteration, cost, cost_reduction, step_norm, optimality))`


			`# Simple helper functions.`


			`def compute_grad(J, f):`
			`"""Compute gradient of the least-squares cost function."""`
			`if isinstance(J, LinearOperator):`
			`return J.rmatvec(f)`
			`else:`
			`return J.T.dot(f)`


			`def compute_jac_scale(J, scale_inv_old=None):`
			`"""Compute variables scale based on the Jacobian matrix."""`
			`if issparse(J):`
			`scale_inv = np.asarray(J.power(2).sum(axis=0)).ravel()**0.5`
			`else:`
			`scale_inv = np.sum(J2, axis=0)0.5`

			`if scale_inv_old is None:`
			`scale_inv[scale_inv == 0] = 1`
			`else:`
			`scale_inv = np.maximum(scale_inv, scale_inv_old)`

			`return 1 / scale_inv, scale_inv`


			`def left_multiplied_operator(J, d):`
			`"""Return diag(d) J as LinearOperator."""`
			`J = aslinearoperator(J)`

			`def matvec(x):`
			`return d * J.matvec(x)`

			`def matmat(X):`
			`return d[:, np.newaxis] * J.matmat(X)`

			`def rmatvec(x):`
			`return J.rmatvec(x.ravel() * d)`

			`return LinearOperator(J.shape, matvec=matvec, matmat=matmat,`
			`rmatvec=rmatvec)`


			`def right_multiplied_operator(J, d):`
			`"""Return J diag(d) as LinearOperator."""`
			`J = aslinearoperator(J)`

			`def matvec(x):`
			`return J.matvec(np.ravel(x) * d)`

			`def matmat(X):`
			`return J.matmat(X * d[:, np.newaxis])`

			`def rmatvec(x):`
			`return d * J.rmatvec(x)`

			`return LinearOperator(J.shape, matvec=matvec, matmat=matmat,`
			`rmatvec=rmatvec)`


			`def regularized_lsq_operator(J, diag):`
			`"""Return a matrix arising in regularized least squares as LinearOperator.`

			`The matrix is`
			`[ J ]`
			`[ D ]`
			where D is diagonal matrix with elements from `diag`.
			`"""`
			`J = aslinearoperator(J)`
			`m, n = J.shape`

			`def matvec(x):`
			`return np.hstack((J.matvec(x), diag * x))`

			`def rmatvec(x):`
			`x1 = x[:m]`
			`x2 = x[m:]`
			`return J.rmatvec(x1) + diag * x2`

			`return LinearOperator((m + n, n), matvec=matvec, rmatvec=rmatvec)`


			`def right_multiply(J, d, copy=True):`
			`"""Compute J diag(d).`

			If `copy` is False, `J` is modified in place (unless being LinearOperator).
			`"""`
			`if copy and not isinstance(J, LinearOperator):`
			`J = J.copy()`

			`if issparse(J):`
			`J.data *= d.take(J.indices, mode='clip') # scikit-learn recipe.`
			`elif isinstance(J, LinearOperator):`
			`J = right_multiplied_operator(J, d)`
			`else:`
			`J *= d`

			`return J`


			`def left_multiply(J, d, copy=True):`
			`"""Compute diag(d) J.`

			If `copy` is False, `J` is modified in place (unless being LinearOperator).
			`"""`
			`if copy and not isinstance(J, LinearOperator):`
			`J = J.copy()`

			`if issparse(J):`
			`J.data *= np.repeat(d, np.diff(J.indptr)) # scikit-learn recipe.`
			`elif isinstance(J, LinearOperator):`
			`J = left_multiplied_operator(J, d)`
			`else:`
			`J *= d[:, np.newaxis]`

			`return J`


			`def check_termination(dF, F, dx_norm, x_norm, ratio, ftol, xtol):`
			`"""Check termination condition for nonlinear least squares."""`
			`ftol_satisfied = dF < ftol * F and ratio > 0.25`
			`xtol_satisfied = dx_norm < xtol * (xtol + x_norm)`

			`if ftol_satisfied and xtol_satisfied:`
			`return 4`
			`elif ftol_satisfied:`
			`return 2`
			`elif xtol_satisfied:`
			`return 3`
			`else:`
			`return None`


			`def scale_for_robust_loss_function(J, f, rho):`
			`"""Scale Jacobian and residuals for a robust loss function.`

			`Arrays are modified in place.`
			`"""`
			`J_scale = rho[1] + 2 * rho[2] * f**2`
			`J_scale[J_scale < EPS] = EPS`
			`J_scale **= 0.5`

			`f *= rho[1] / J_scale`

			`return left_multiply(J, J_scale, copy=False), f`