399 lines
13 KiB
C++
399 lines
13 KiB
C++
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// Ceres Solver - A fast non-linear least squares minimizer
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// Copyright 2015 Google Inc. All rights reserved.
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// http://ceres-solver.org/
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are met:
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//
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// * Redistributions of source code must retain the above copyright notice,
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// this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above copyright notice,
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// this list of conditions and the following disclaimer in the documentation
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// and/or other materials provided with the distribution.
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// * Neither the name of Google Inc. nor the names of its contributors may be
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// used to endorse or promote products derived from this software without
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// specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
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// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
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// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
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// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
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// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
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// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
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// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
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// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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// POSSIBILITY OF SUCH DAMAGE.
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//
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// Author: moll.markus@arcor.de (Markus Moll)
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// sameeragarwal@google.com (Sameer Agarwal)
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#include "ceres/polynomial.h"
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#include <cmath>
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#include <cstddef>
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#include <vector>
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#include "Eigen/Dense"
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#include "ceres/internal/port.h"
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#include "ceres/stringprintf.h"
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#include "glog/logging.h"
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namespace ceres {
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namespace internal {
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using std::string;
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using std::vector;
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namespace {
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// Balancing function as described by B. N. Parlett and C. Reinsch,
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// "Balancing a Matrix for Calculation of Eigenvalues and Eigenvectors".
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// In: Numerische Mathematik, Volume 13, Number 4 (1969), 293-304,
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// Springer Berlin / Heidelberg. DOI: 10.1007/BF02165404
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void BalanceCompanionMatrix(Matrix* companion_matrix_ptr) {
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CHECK_NOTNULL(companion_matrix_ptr);
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Matrix& companion_matrix = *companion_matrix_ptr;
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Matrix companion_matrix_offdiagonal = companion_matrix;
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companion_matrix_offdiagonal.diagonal().setZero();
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const int degree = companion_matrix.rows();
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// gamma <= 1 controls how much a change in the scaling has to
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// lower the 1-norm of the companion matrix to be accepted.
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//
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// gamma = 1 seems to lead to cycles (numerical issues?), so
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// we set it slightly lower.
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const double gamma = 0.9;
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// Greedily scale row/column pairs until there is no change.
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bool scaling_has_changed;
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do {
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scaling_has_changed = false;
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for (int i = 0; i < degree; ++i) {
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const double row_norm = companion_matrix_offdiagonal.row(i).lpNorm<1>();
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const double col_norm = companion_matrix_offdiagonal.col(i).lpNorm<1>();
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// Decompose row_norm/col_norm into mantissa * 2^exponent,
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// where 0.5 <= mantissa < 1. Discard mantissa (return value
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// of frexp), as only the exponent is needed.
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int exponent = 0;
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std::frexp(row_norm / col_norm, &exponent);
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exponent /= 2;
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if (exponent != 0) {
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const double scaled_col_norm = std::ldexp(col_norm, exponent);
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const double scaled_row_norm = std::ldexp(row_norm, -exponent);
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if (scaled_col_norm + scaled_row_norm < gamma * (col_norm + row_norm)) {
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// Accept the new scaling. (Multiplication by powers of 2 should not
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// introduce rounding errors (ignoring non-normalized numbers and
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// over- or underflow))
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scaling_has_changed = true;
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companion_matrix_offdiagonal.row(i) *= std::ldexp(1.0, -exponent);
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companion_matrix_offdiagonal.col(i) *= std::ldexp(1.0, exponent);
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}
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}
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}
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} while (scaling_has_changed);
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companion_matrix_offdiagonal.diagonal() = companion_matrix.diagonal();
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companion_matrix = companion_matrix_offdiagonal;
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VLOG(3) << "Balanced companion matrix is\n" << companion_matrix;
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}
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void BuildCompanionMatrix(const Vector& polynomial,
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Matrix* companion_matrix_ptr) {
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CHECK_NOTNULL(companion_matrix_ptr);
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Matrix& companion_matrix = *companion_matrix_ptr;
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const int degree = polynomial.size() - 1;
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companion_matrix.resize(degree, degree);
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companion_matrix.setZero();
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companion_matrix.diagonal(-1).setOnes();
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companion_matrix.col(degree - 1) = -polynomial.reverse().head(degree);
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}
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// Remove leading terms with zero coefficients.
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Vector RemoveLeadingZeros(const Vector& polynomial_in) {
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int i = 0;
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while (i < (polynomial_in.size() - 1) && polynomial_in(i) == 0.0) {
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++i;
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}
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return polynomial_in.tail(polynomial_in.size() - i);
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}
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void FindLinearPolynomialRoots(const Vector& polynomial,
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Vector* real,
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Vector* imaginary) {
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CHECK_EQ(polynomial.size(), 2);
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if (real != NULL) {
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real->resize(1);
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(*real)(0) = -polynomial(1) / polynomial(0);
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}
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if (imaginary != NULL) {
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imaginary->setZero(1);
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}
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}
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void FindQuadraticPolynomialRoots(const Vector& polynomial,
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Vector* real,
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Vector* imaginary) {
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CHECK_EQ(polynomial.size(), 3);
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const double a = polynomial(0);
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const double b = polynomial(1);
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const double c = polynomial(2);
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const double D = b * b - 4 * a * c;
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const double sqrt_D = sqrt(fabs(D));
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if (real != NULL) {
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real->setZero(2);
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}
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if (imaginary != NULL) {
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imaginary->setZero(2);
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}
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// Real roots.
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if (D >= 0) {
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if (real != NULL) {
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// Stable quadratic roots according to BKP Horn.
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// http://people.csail.mit.edu/bkph/articles/Quadratics.pdf
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if (b >= 0) {
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(*real)(0) = (-b - sqrt_D) / (2.0 * a);
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(*real)(1) = (2.0 * c) / (-b - sqrt_D);
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} else {
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(*real)(0) = (2.0 * c) / (-b + sqrt_D);
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(*real)(1) = (-b + sqrt_D) / (2.0 * a);
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}
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}
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return;
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}
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// Use the normal quadratic formula for the complex case.
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if (real != NULL) {
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(*real)(0) = -b / (2.0 * a);
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(*real)(1) = -b / (2.0 * a);
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}
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if (imaginary != NULL) {
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(*imaginary)(0) = sqrt_D / (2.0 * a);
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(*imaginary)(1) = -sqrt_D / (2.0 * a);
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}
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}
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} // namespace
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bool FindPolynomialRoots(const Vector& polynomial_in,
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Vector* real,
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Vector* imaginary) {
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if (polynomial_in.size() == 0) {
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LOG(ERROR) << "Invalid polynomial of size 0 passed to FindPolynomialRoots";
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return false;
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}
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Vector polynomial = RemoveLeadingZeros(polynomial_in);
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const int degree = polynomial.size() - 1;
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VLOG(3) << "Input polynomial: " << polynomial_in.transpose();
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if (polynomial.size() != polynomial_in.size()) {
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VLOG(3) << "Trimmed polynomial: " << polynomial.transpose();
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}
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// Is the polynomial constant?
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if (degree == 0) {
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LOG(WARNING) << "Trying to extract roots from a constant "
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<< "polynomial in FindPolynomialRoots";
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// We return true with no roots, not false, as if the polynomial is constant
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// it is correct that there are no roots. It is not the case that they were
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// there, but that we have failed to extract them.
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return true;
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}
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// Linear
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if (degree == 1) {
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FindLinearPolynomialRoots(polynomial, real, imaginary);
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return true;
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}
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// Quadratic
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if (degree == 2) {
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FindQuadraticPolynomialRoots(polynomial, real, imaginary);
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return true;
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}
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// The degree is now known to be at least 3. For cubic or higher
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// roots we use the method of companion matrices.
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// Divide by leading term
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const double leading_term = polynomial(0);
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polynomial /= leading_term;
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// Build and balance the companion matrix to the polynomial.
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Matrix companion_matrix(degree, degree);
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BuildCompanionMatrix(polynomial, &companion_matrix);
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BalanceCompanionMatrix(&companion_matrix);
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// Find its (complex) eigenvalues.
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Eigen::EigenSolver<Matrix> solver(companion_matrix, false);
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if (solver.info() != Eigen::Success) {
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LOG(ERROR) << "Failed to extract eigenvalues from companion matrix.";
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return false;
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}
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// Output roots
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if (real != NULL) {
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*real = solver.eigenvalues().real();
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} else {
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LOG(WARNING) << "NULL pointer passed as real argument to "
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<< "FindPolynomialRoots. Real parts of the roots will not "
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<< "be returned.";
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}
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if (imaginary != NULL) {
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*imaginary = solver.eigenvalues().imag();
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}
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return true;
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}
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Vector DifferentiatePolynomial(const Vector& polynomial) {
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const int degree = polynomial.rows() - 1;
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CHECK_GE(degree, 0);
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// Degree zero polynomials are constants, and their derivative does
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// not result in a smaller degree polynomial, just a degree zero
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// polynomial with value zero.
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if (degree == 0) {
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return Eigen::VectorXd::Zero(1);
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}
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Vector derivative(degree);
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for (int i = 0; i < degree; ++i) {
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derivative(i) = (degree - i) * polynomial(i);
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}
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return derivative;
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}
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void MinimizePolynomial(const Vector& polynomial,
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const double x_min,
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const double x_max,
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double* optimal_x,
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double* optimal_value) {
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// Find the minimum of the polynomial at the two ends.
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//
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// We start by inspecting the middle of the interval. Technically
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// this is not needed, but we do this to make this code as close to
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// the minFunc package as possible.
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*optimal_x = (x_min + x_max) / 2.0;
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*optimal_value = EvaluatePolynomial(polynomial, *optimal_x);
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const double x_min_value = EvaluatePolynomial(polynomial, x_min);
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if (x_min_value < *optimal_value) {
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*optimal_value = x_min_value;
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*optimal_x = x_min;
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}
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const double x_max_value = EvaluatePolynomial(polynomial, x_max);
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if (x_max_value < *optimal_value) {
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*optimal_value = x_max_value;
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*optimal_x = x_max;
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}
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// If the polynomial is linear or constant, we are done.
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if (polynomial.rows() <= 2) {
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return;
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}
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const Vector derivative = DifferentiatePolynomial(polynomial);
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Vector roots_real;
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if (!FindPolynomialRoots(derivative, &roots_real, NULL)) {
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LOG(WARNING) << "Unable to find the critical points of "
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<< "the interpolating polynomial.";
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return;
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}
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// This is a bit of an overkill, as some of the roots may actually
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// have a complex part, but its simpler to just check these values.
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for (int i = 0; i < roots_real.rows(); ++i) {
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const double root = roots_real(i);
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if ((root < x_min) || (root > x_max)) {
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continue;
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}
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const double value = EvaluatePolynomial(polynomial, root);
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if (value < *optimal_value) {
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*optimal_value = value;
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*optimal_x = root;
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}
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}
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}
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string FunctionSample::ToDebugString() const {
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return StringPrintf("[x: %.8e, value: %.8e, gradient: %.8e, "
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"value_is_valid: %d, gradient_is_valid: %d]",
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x, value, gradient, value_is_valid, gradient_is_valid);
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}
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Vector FindInterpolatingPolynomial(const vector<FunctionSample>& samples) {
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const int num_samples = samples.size();
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int num_constraints = 0;
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for (int i = 0; i < num_samples; ++i) {
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if (samples[i].value_is_valid) {
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++num_constraints;
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}
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if (samples[i].gradient_is_valid) {
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++num_constraints;
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}
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}
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const int degree = num_constraints - 1;
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Matrix lhs = Matrix::Zero(num_constraints, num_constraints);
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Vector rhs = Vector::Zero(num_constraints);
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int row = 0;
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for (int i = 0; i < num_samples; ++i) {
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const FunctionSample& sample = samples[i];
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if (sample.value_is_valid) {
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for (int j = 0; j <= degree; ++j) {
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lhs(row, j) = pow(sample.x, degree - j);
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}
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rhs(row) = sample.value;
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++row;
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}
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if (sample.gradient_is_valid) {
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for (int j = 0; j < degree; ++j) {
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lhs(row, j) = (degree - j) * pow(sample.x, degree - j - 1);
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}
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rhs(row) = sample.gradient;
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++row;
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}
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}
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return lhs.fullPivLu().solve(rhs);
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}
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void MinimizeInterpolatingPolynomial(const vector<FunctionSample>& samples,
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double x_min,
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double x_max,
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double* optimal_x,
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double* optimal_value) {
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const Vector polynomial = FindInterpolatingPolynomial(samples);
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MinimizePolynomial(polynomial, x_min, x_max, optimal_x, optimal_value);
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for (int i = 0; i < samples.size(); ++i) {
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const FunctionSample& sample = samples[i];
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if ((sample.x < x_min) || (sample.x > x_max)) {
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continue;
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}
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const double value = EvaluatePolynomial(polynomial, sample.x);
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if (value < *optimal_value) {
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*optimal_x = sample.x;
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*optimal_value = value;
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}
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}
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}
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} // namespace internal
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} // namespace ceres
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