3RNN/Lib/site-packages/scipy/optimize/_lsq/trf_linear.py

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2024-05-26 19:49:15 +02:00
"""The adaptation of Trust Region Reflective algorithm for a linear
least-squares problem."""
import numpy as np
from numpy.linalg import norm
from scipy.linalg import qr, solve_triangular
from scipy.sparse.linalg import lsmr
from scipy.optimize import OptimizeResult
from .givens_elimination import givens_elimination
from .common import (
EPS, step_size_to_bound, find_active_constraints, in_bounds,
make_strictly_feasible, build_quadratic_1d, evaluate_quadratic,
minimize_quadratic_1d, CL_scaling_vector, reflective_transformation,
print_header_linear, print_iteration_linear, compute_grad,
regularized_lsq_operator, right_multiplied_operator)
def regularized_lsq_with_qr(m, n, R, QTb, perm, diag, copy_R=True):
"""Solve regularized least squares using information from QR-decomposition.
The initial problem is to solve the following system in a least-squares
sense::
A x = b
D x = 0
where D is diagonal matrix. The method is based on QR decomposition
of the form A P = Q R, where P is a column permutation matrix, Q is an
orthogonal matrix and R is an upper triangular matrix.
Parameters
----------
m, n : int
Initial shape of A.
R : ndarray, shape (n, n)
Upper triangular matrix from QR decomposition of A.
QTb : ndarray, shape (n,)
First n components of Q^T b.
perm : ndarray, shape (n,)
Array defining column permutation of A, such that ith column of
P is perm[i]-th column of identity matrix.
diag : ndarray, shape (n,)
Array containing diagonal elements of D.
Returns
-------
x : ndarray, shape (n,)
Found least-squares solution.
"""
if copy_R:
R = R.copy()
v = QTb.copy()
givens_elimination(R, v, diag[perm])
abs_diag_R = np.abs(np.diag(R))
threshold = EPS * max(m, n) * np.max(abs_diag_R)
nns, = np.nonzero(abs_diag_R > threshold)
R = R[np.ix_(nns, nns)]
v = v[nns]
x = np.zeros(n)
x[perm[nns]] = solve_triangular(R, v)
return x
def backtracking(A, g, x, p, theta, p_dot_g, lb, ub):
"""Find an appropriate step size using backtracking line search."""
alpha = 1
while True:
x_new, _ = reflective_transformation(x + alpha * p, lb, ub)
step = x_new - x
cost_change = -evaluate_quadratic(A, g, step)
if cost_change > -0.1 * alpha * p_dot_g:
break
alpha *= 0.5
active = find_active_constraints(x_new, lb, ub)
if np.any(active != 0):
x_new, _ = reflective_transformation(x + theta * alpha * p, lb, ub)
x_new = make_strictly_feasible(x_new, lb, ub, rstep=0)
step = x_new - x
cost_change = -evaluate_quadratic(A, g, step)
return x, step, cost_change
def select_step(x, A_h, g_h, c_h, p, p_h, d, lb, ub, theta):
"""Select the best step according to Trust Region Reflective algorithm."""
if in_bounds(x + p, lb, ub):
return p
p_stride, hits = step_size_to_bound(x, p, lb, ub)
r_h = np.copy(p_h)
r_h[hits.astype(bool)] *= -1
r = d * r_h
# Restrict step, such that it hits the bound.
p *= p_stride
p_h *= p_stride
x_on_bound = x + p
# Find the step size along reflected direction.
r_stride_u, _ = step_size_to_bound(x_on_bound, r, lb, ub)
# Stay interior.
r_stride_l = (1 - theta) * r_stride_u
r_stride_u *= theta
if r_stride_u > 0:
a, b, c = build_quadratic_1d(A_h, g_h, r_h, s0=p_h, diag=c_h)
r_stride, r_value = minimize_quadratic_1d(
a, b, r_stride_l, r_stride_u, c=c)
r_h = p_h + r_h * r_stride
r = d * r_h
else:
r_value = np.inf
# Now correct p_h to make it strictly interior.
p_h *= theta
p *= theta
p_value = evaluate_quadratic(A_h, g_h, p_h, diag=c_h)
ag_h = -g_h
ag = d * ag_h
ag_stride_u, _ = step_size_to_bound(x, ag, lb, ub)
ag_stride_u *= theta
a, b = build_quadratic_1d(A_h, g_h, ag_h, diag=c_h)
ag_stride, ag_value = minimize_quadratic_1d(a, b, 0, ag_stride_u)
ag *= ag_stride
if p_value < r_value and p_value < ag_value:
return p
elif r_value < p_value and r_value < ag_value:
return r
else:
return ag
def trf_linear(A, b, x_lsq, lb, ub, tol, lsq_solver, lsmr_tol,
max_iter, verbose, *, lsmr_maxiter=None):
m, n = A.shape
x, _ = reflective_transformation(x_lsq, lb, ub)
x = make_strictly_feasible(x, lb, ub, rstep=0.1)
if lsq_solver == 'exact':
QT, R, perm = qr(A, mode='economic', pivoting=True)
QT = QT.T
if m < n:
R = np.vstack((R, np.zeros((n - m, n))))
QTr = np.zeros(n)
k = min(m, n)
elif lsq_solver == 'lsmr':
r_aug = np.zeros(m + n)
auto_lsmr_tol = False
if lsmr_tol is None:
lsmr_tol = 1e-2 * tol
elif lsmr_tol == 'auto':
auto_lsmr_tol = True
r = A.dot(x) - b
g = compute_grad(A, r)
cost = 0.5 * np.dot(r, r)
initial_cost = cost
termination_status = None
step_norm = None
cost_change = None
if max_iter is None:
max_iter = 100
if verbose == 2:
print_header_linear()
for iteration in range(max_iter):
v, dv = CL_scaling_vector(x, g, lb, ub)
g_scaled = g * v
g_norm = norm(g_scaled, ord=np.inf)
if g_norm < tol:
termination_status = 1
if verbose == 2:
print_iteration_linear(iteration, cost, cost_change,
step_norm, g_norm)
if termination_status is not None:
break
diag_h = g * dv
diag_root_h = diag_h ** 0.5
d = v ** 0.5
g_h = d * g
A_h = right_multiplied_operator(A, d)
if lsq_solver == 'exact':
QTr[:k] = QT.dot(r)
p_h = -regularized_lsq_with_qr(m, n, R * d[perm], QTr, perm,
diag_root_h, copy_R=False)
elif lsq_solver == 'lsmr':
lsmr_op = regularized_lsq_operator(A_h, diag_root_h)
r_aug[:m] = r
if auto_lsmr_tol:
eta = 1e-2 * min(0.5, g_norm)
lsmr_tol = max(EPS, min(0.1, eta * g_norm))
p_h = -lsmr(lsmr_op, r_aug, maxiter=lsmr_maxiter,
atol=lsmr_tol, btol=lsmr_tol)[0]
p = d * p_h
p_dot_g = np.dot(p, g)
if p_dot_g > 0:
termination_status = -1
theta = 1 - min(0.005, g_norm)
step = select_step(x, A_h, g_h, diag_h, p, p_h, d, lb, ub, theta)
cost_change = -evaluate_quadratic(A, g, step)
# Perhaps almost never executed, the idea is that `p` is descent
# direction thus we must find acceptable cost decrease using simple
# "backtracking", otherwise the algorithm's logic would break.
if cost_change < 0:
x, step, cost_change = backtracking(
A, g, x, p, theta, p_dot_g, lb, ub)
else:
x = make_strictly_feasible(x + step, lb, ub, rstep=0)
step_norm = norm(step)
r = A.dot(x) - b
g = compute_grad(A, r)
if cost_change < tol * cost:
termination_status = 2
cost = 0.5 * np.dot(r, r)
if termination_status is None:
termination_status = 0
active_mask = find_active_constraints(x, lb, ub, rtol=tol)
return OptimizeResult(
x=x, fun=r, cost=cost, optimality=g_norm, active_mask=active_mask,
nit=iteration + 1, status=termination_status,
initial_cost=initial_cost)