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ceres-solver / ceres-solver / a9b3fcff426eb33644413f766fdc785af937d9ed / . / include / ceres / internal / numeric_diff.h
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// Ceres Solver - A fast non-linear least squares minimizer
// Copyright 2023 Google Inc. All rights reserved.
// http://ceres-solver.org/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are met:
//
// * Redistributions of source code must retain the above copyright notice,
// this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above copyright notice,
// this list of conditions and the following disclaimer in the documentation
// and/or other materials provided with the distribution.
// * Neither the name of Google Inc. nor the names of its contributors may be
// used to endorse or promote products derived from this software without
// specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
//
// Author: sameeragarwal@google.com (Sameer Agarwal)
// mierle@gmail.com (Keir Mierle)
// tbennun@gmail.com (Tal Ben-Nun)
//
// Finite differencing routines used by NumericDiffCostFunction.
#ifndef CERES_PUBLIC_INTERNAL_NUMERIC_DIFF_H_
#define CERES_PUBLIC_INTERNAL_NUMERIC_DIFF_H_
#include <cstring>
#include <utility>
#include "Eigen/Dense"
#include "Eigen/StdVector"
#include "ceres/cost_function.h"
#include "ceres/internal/fixed_array.h"
#include "ceres/internal/variadic_evaluate.h"
#include "ceres/numeric_diff_options.h"
#include "ceres/types.h"
#include "glog/logging.h"
namespace ceres::internal {
// This is split from the main class because C++ doesn't allow partial template
// specializations for member functions. The alternative is to repeat the main
// class for differing numbers of parameters, which is also unfortunate.
template <typename CostFunctor,
NumericDiffMethodType kMethod,
int kNumResiduals,
typename ParameterDims,
int kParameterBlock,
int kParameterBlockSize>
struct NumericDiff {
// Mutates parameters but must restore them before return.
static bool EvaluateJacobianForParameterBlock(
const CostFunctor* functor,
const double* residuals_at_eval_point,
const NumericDiffOptions& options,
int num_residuals,
int parameter_block_index,
int parameter_block_size,
double** parameters,
double* jacobian) {
using Eigen::ColMajor;
using Eigen::Map;
using Eigen::Matrix;
using Eigen::RowMajor;
DCHECK(jacobian);
const int num_residuals_internal =
(kNumResiduals != ceres::DYNAMIC ? kNumResiduals : num_residuals);
const int parameter_block_index_internal =
(kParameterBlock != ceres::DYNAMIC ? kParameterBlock
: parameter_block_index);
const int parameter_block_size_internal =
(kParameterBlockSize != ceres::DYNAMIC ? kParameterBlockSize
: parameter_block_size);
using ResidualVector = Matrix<double, kNumResiduals, 1>;
using ParameterVector = Matrix<double, kParameterBlockSize, 1>;
// The convoluted reasoning for choosing the Row/Column major
// ordering of the matrix is an artifact of the restrictions in
// Eigen that prevent it from creating RowMajor matrices with a
// single column. In these cases, we ask for a ColMajor matrix.
using JacobianMatrix =
Matrix<double,
kNumResiduals,
kParameterBlockSize,
(kParameterBlockSize == 1) ? ColMajor : RowMajor>;
Map<JacobianMatrix> parameter_jacobian(
jacobian, num_residuals_internal, parameter_block_size_internal);
Map<ParameterVector> x_plus_delta(
parameters[parameter_block_index_internal],
parameter_block_size_internal);
ParameterVector x(x_plus_delta);
ParameterVector step_size =
x.array().abs() * ((kMethod == RIDDERS)
? options.ridders_relative_initial_step_size
: options.relative_step_size);
// It is not a good idea to make the step size arbitrarily
// small. This will lead to problems with round off and numerical
// instability when dividing by the step size. The general
// recommendation is to not go down below sqrt(epsilon).
double min_step_size = std::sqrt(std::numeric_limits<double>::epsilon());
// For Ridders' method, the initial step size is required to be large,
// thus ridders_relative_initial_step_size is used.
if (kMethod == RIDDERS) {
min_step_size =
(std::max)(min_step_size, options.ridders_relative_initial_step_size);
}
// For each parameter in the parameter block, use finite differences to
// compute the derivative for that parameter.
FixedArray<double> temp_residual_array(num_residuals_internal);
FixedArray<double> residual_array(num_residuals_internal);
Map<ResidualVector> residuals(residual_array.data(),
num_residuals_internal);
for (int j = 0; j < parameter_block_size_internal; ++j) {
const double delta = (std::max)(min_step_size, step_size(j));
if (kMethod == RIDDERS) {
if (!EvaluateRiddersJacobianColumn(functor,
j,
delta,
options,
num_residuals_internal,
parameter_block_size_internal,
x.data(),
residuals_at_eval_point,
parameters,
x_plus_delta.data(),
temp_residual_array.data(),
residual_array.data())) {
return false;
}
} else {
if (!EvaluateJacobianColumn(functor,
j,
delta,
num_residuals_internal,
parameter_block_size_internal,
x.data(),
residuals_at_eval_point,
parameters,
x_plus_delta.data(),
temp_residual_array.data(),
residual_array.data())) {
return false;
}
}
parameter_jacobian.col(j).matrix() = residuals;
}
return true;
}
static bool EvaluateJacobianColumn(const CostFunctor* functor,
int parameter_index,
double delta,
int num_residuals,
int parameter_block_size,
const double* x_ptr,
const double* residuals_at_eval_point,
double** parameters,
double* x_plus_delta_ptr,
double* temp_residuals_ptr,
double* residuals_ptr) {
using Eigen::Map;
using Eigen::Matrix;
using ResidualVector = Matrix<double, kNumResiduals, 1>;
using ParameterVector = Matrix<double, kParameterBlockSize, 1>;
Map<const ParameterVector> x(x_ptr, parameter_block_size);
Map<ParameterVector> x_plus_delta(x_plus_delta_ptr, parameter_block_size);
Map<ResidualVector> residuals(residuals_ptr, num_residuals);
Map<ResidualVector> temp_residuals(temp_residuals_ptr, num_residuals);
// Mutate 1 element at a time and then restore.
x_plus_delta(parameter_index) = x(parameter_index) + delta;
if (!VariadicEvaluate<ParameterDims>(
*functor, parameters, residuals.data())) {
return false;
}
// Compute this column of the jacobian in 3 steps:
// 1. Store residuals for the forward part.
// 2. Subtract residuals for the backward (or 0) part.
// 3. Divide out the run.
double one_over_delta = 1.0 / delta;
if (kMethod == CENTRAL || kMethod == RIDDERS) {
// Compute the function on the other side of x(parameter_index).
x_plus_delta(parameter_index) = x(parameter_index) - delta;
if (!VariadicEvaluate<ParameterDims>(
*functor, parameters, temp_residuals.data())) {
return false;
}
residuals -= temp_residuals;
one_over_delta /= 2;
} else {
// Forward difference only; reuse existing residuals evaluation.
residuals -=
Map<const ResidualVector>(residuals_at_eval_point, num_residuals);
}
// Restore x_plus_delta.
x_plus_delta(parameter_index) = x(parameter_index);
// Divide out the run to get slope.
residuals *= one_over_delta;
return true;
}
// This numeric difference implementation uses adaptive differentiation
// on the parameters to obtain the Jacobian matrix. The adaptive algorithm
// is based on Ridders' method for adaptive differentiation, which creates
// a Romberg tableau from varying step sizes and extrapolates the
// intermediate results to obtain the current computational error.
//
// References:
// C.J.F. Ridders, Accurate computation of F'(x) and F'(x) F"(x), Advances
// in Engineering Software (1978), Volume 4, Issue 2, April 1982,
// Pages 75-76, ISSN 0141-1195,
// http://dx.doi.org/10.1016/S0141-1195(82)80057-0.
static bool EvaluateRiddersJacobianColumn(
const CostFunctor* functor,
int parameter_index,
double delta,
const NumericDiffOptions& options,
int num_residuals,
int parameter_block_size,
const double* x_ptr,
const double* residuals_at_eval_point,
double** parameters,
double* x_plus_delta_ptr,
double* temp_residuals_ptr,
double* residuals_ptr) {
using Eigen::aligned_allocator;
using Eigen::Map;
using Eigen::Matrix;
using ResidualVector = Matrix<double, kNumResiduals, 1>;
using ResidualCandidateMatrix =
Matrix<double, kNumResiduals, Eigen::Dynamic>;
using ParameterVector = Matrix<double, kParameterBlockSize, 1>;
Map<const ParameterVector> x(x_ptr, parameter_block_size);
Map<ParameterVector> x_plus_delta(x_plus_delta_ptr, parameter_block_size);
Map<ResidualVector> residuals(residuals_ptr, num_residuals);
Map<ResidualVector> temp_residuals(temp_residuals_ptr, num_residuals);
// In order for the algorithm to converge, the step size should be
// initialized to a value that is large enough to produce a significant
// change in the function.
// As the derivative is estimated, the step size decreases.
// By default, the step sizes are chosen so that the middle column
// of the Romberg tableau uses the input delta.
double current_step_size =
delta * pow(options.ridders_step_shrink_factor,
options.max_num_ridders_extrapolations / 2);
// Double-buffering temporary differential candidate vectors
// from previous step size.
ResidualCandidateMatrix stepsize_candidates_a(
num_residuals, options.max_num_ridders_extrapolations);
ResidualCandidateMatrix stepsize_candidates_b(
num_residuals, options.max_num_ridders_extrapolations);
ResidualCandidateMatrix* current_candidates = &stepsize_candidates_a;
ResidualCandidateMatrix* previous_candidates = &stepsize_candidates_b;
// Represents the computational error of the derivative. This variable is
// initially set to a large value, and is set to the difference between
// current and previous finite difference extrapolations.
// norm_error is supposed to decrease as the finite difference tableau
// generation progresses, serving both as an estimate for differentiation
// error and as a measure of differentiation numerical stability.
double norm_error = (std::numeric_limits<double>::max)();
// Loop over decreasing step sizes until:
// 1. Error is smaller than a given value (ridders_epsilon),
// 2. Maximal order of extrapolation reached, or
// 3. Extrapolation becomes numerically unstable.
for (int i = 0; i < options.max_num_ridders_extrapolations; ++i) {
// Compute the numerical derivative at this step size.
if (!EvaluateJacobianColumn(functor,
parameter_index,
current_step_size,
num_residuals,
parameter_block_size,
x.data(),
residuals_at_eval_point,
parameters,
x_plus_delta.data(),
temp_residuals.data(),
current_candidates->col(0).data())) {
// Something went wrong; bail.
return false;
}
// Store initial results.
if (i == 0) {
residuals = current_candidates->col(0);
}
// Shrink differentiation step size.
current_step_size /= options.ridders_step_shrink_factor;
// Extrapolation factor for Richardson acceleration method (see below).
double richardson_factor = options.ridders_step_shrink_factor *
options.ridders_step_shrink_factor;
for (int k = 1; k <= i; ++k) {
// Extrapolate the various orders of finite differences using
// the Richardson acceleration method.
current_candidates->col(k) =
(richardson_factor * current_candidates->col(k - 1) -
previous_candidates->col(k - 1)) /
(richardson_factor - 1.0);
richardson_factor *= options.ridders_step_shrink_factor *
options.ridders_step_shrink_factor;
// Compute the difference between the previous value and the current.
double candidate_error = (std::max)(
(current_candidates->col(k) - current_candidates->col(k - 1))
.norm(),
(current_candidates->col(k) - previous_candidates->col(k - 1))
.norm());
// If the error has decreased, update results.
if (candidate_error <= norm_error) {
norm_error = candidate_error;
residuals = current_candidates->col(k);
// If the error is small enough, stop.
if (norm_error < options.ridders_epsilon) {
break;
}
}
}
// After breaking out of the inner loop, declare convergence.
if (norm_error < options.ridders_epsilon) {
break;
}
// Check to see if the current gradient estimate is numerically unstable.
// If so, bail out and return the last stable result.
if (i > 0) {
double tableau_error =
(current_candidates->col(i) - previous_candidates->col(i - 1))
.norm();
// Compare current error to the chosen candidate's error.
if (tableau_error >= 2 * norm_error) {
break;
}
}
std::swap(current_candidates, previous_candidates);
}
return true;
}
};
// This function calls NumericDiff<...>::EvaluateJacobianForParameterBlock for
// each parameter block.
//
// Example:
// A call to
// EvaluateJacobianForParameterBlocks<StaticParameterDims<2, 3>>(
// functor,
// residuals_at_eval_point,
// options,
// num_residuals,
// parameters,
// jacobians);
// will result in the following calls to
// NumericDiff<...>::EvaluateJacobianForParameterBlock:
//
// if (jacobians[0] != nullptr) {
// if (!NumericDiff<
// CostFunctor,
// method,
// kNumResiduals,
// StaticParameterDims<2, 3>,
// 0,
// 2>::EvaluateJacobianForParameterBlock(functor,
// residuals_at_eval_point,
// options,
// num_residuals,
// 0,
// 2,
// parameters,
// jacobians[0])) {
// return false;
// }
// }
// if (jacobians[1] != nullptr) {
// if (!NumericDiff<
// CostFunctor,
// method,
// kNumResiduals,
// StaticParameterDims<2, 3>,
// 1,
// 3>::EvaluateJacobianForParameterBlock(functor,
// residuals_at_eval_point,
// options,
// num_residuals,
// 1,
// 3,
// parameters,
// jacobians[1])) {
// return false;
// }
// }
template <typename ParameterDims,
typename Parameters = typename ParameterDims::Parameters,
int ParameterIdx = 0>
struct EvaluateJacobianForParameterBlocks;
template <typename ParameterDims, int N, int... Ns, int ParameterIdx>
struct EvaluateJacobianForParameterBlocks<ParameterDims,
std::integer_sequence<int, N, Ns...>,
ParameterIdx> {
template <NumericDiffMethodType method,
int kNumResiduals,
typename CostFunctor>
static bool Apply(const CostFunctor* functor,
const double* residuals_at_eval_point,
const NumericDiffOptions& options,
int num_residuals,
double** parameters,
double** jacobians) {
if (jacobians[ParameterIdx] != nullptr) {
if (!NumericDiff<
CostFunctor,
method,
kNumResiduals,
ParameterDims,
ParameterIdx,
N>::EvaluateJacobianForParameterBlock(functor,
residuals_at_eval_point,
options,
num_residuals,
ParameterIdx,
N,
parameters,
jacobians[ParameterIdx])) {
return false;
}
}
return EvaluateJacobianForParameterBlocks<ParameterDims,
std::integer_sequence<int, Ns...>,
ParameterIdx + 1>::
template Apply<method, kNumResiduals>(functor,
residuals_at_eval_point,
options,
num_residuals,
parameters,
jacobians);
}
};
// End of 'recursion'. Nothing more to do.
template <typename ParameterDims, int ParameterIdx>
struct EvaluateJacobianForParameterBlocks<ParameterDims,
std::integer_sequence<int>,
ParameterIdx> {
template <NumericDiffMethodType method,
int kNumResiduals,
typename CostFunctor>
static bool Apply(const CostFunctor* /* NOT USED*/,
const double* /* NOT USED*/,
const NumericDiffOptions& /* NOT USED*/,
int /* NOT USED*/,
double** /* NOT USED*/,
double** /* NOT USED*/) {
return true;
}
};
} // namespace ceres::internal
#endif // CERES_PUBLIC_INTERNAL_NUMERIC_DIFF_H_