// Ceres Solver - A fast non-linear least squares minimizer // Copyright 2012 Google Inc. All rights reserved. // http://code.google.com/p/ceres-solver/ // // 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) #include "ceres/trust_region_minimizer.h" #include #include #include #include #include #include #include #include "Eigen/Core" #include "ceres/array_utils.h" #include "ceres/evaluator.h" #include "ceres/file.h" #include "ceres/internal/eigen.h" #include "ceres/internal/scoped_ptr.h" #include "ceres/line_search.h" #include "ceres/linear_least_squares_problems.h" #include "ceres/sparse_matrix.h" #include "ceres/stringprintf.h" #include "ceres/trust_region_strategy.h" #include "ceres/types.h" #include "ceres/wall_time.h" #include "glog/logging.h" namespace ceres { namespace internal { namespace { LineSearch::Summary DoLineSearch(const Minimizer::Options& options, const Vector& x, const Vector& gradient, const double cost, const Vector& delta, Evaluator* evaluator) { LineSearchFunction line_search_function(evaluator); LineSearch::Options line_search_options; line_search_options.is_silent = true; line_search_options.interpolation_type = options.line_search_interpolation_type; line_search_options.min_step_size = options.min_line_search_step_size; line_search_options.sufficient_decrease = options.line_search_sufficient_function_decrease; line_search_options.max_step_contraction = options.max_line_search_step_contraction; line_search_options.min_step_contraction = options.min_line_search_step_contraction; line_search_options.max_num_iterations = options.max_num_line_search_step_size_iterations; line_search_options.sufficient_curvature_decrease = options.line_search_sufficient_curvature_decrease; line_search_options.max_step_expansion = options.max_line_search_step_expansion; line_search_options.function = &line_search_function; string message; scoped_ptr line_search(CHECK_NOTNULL( LineSearch::Create(ceres::ARMIJO, line_search_options, &message))); LineSearch::Summary summary; line_search_function.Init(x, delta); // Try the trust region step. line_search->Search(1.0, cost, gradient.dot(delta), &summary); if (!summary.success) { // If that was not successful, try the negative gradient as a // search direction. line_search_function.Init(x, -gradient); line_search->Search(1.0, cost, -gradient.squaredNorm(), &summary); } return summary; } } // namespace // Compute a scaling vector that is used to improve the conditioning // of the Jacobian. void TrustRegionMinimizer::EstimateScale(const SparseMatrix& jacobian, double* scale) const { jacobian.SquaredColumnNorm(scale); for (int i = 0; i < jacobian.num_cols(); ++i) { scale[i] = 1.0 / (1.0 + sqrt(scale[i])); } } void TrustRegionMinimizer::Init(const Minimizer::Options& options) { options_ = options; sort(options_.trust_region_minimizer_iterations_to_dump.begin(), options_.trust_region_minimizer_iterations_to_dump.end()); } void TrustRegionMinimizer::Minimize(const Minimizer::Options& options, double* parameters, Solver::Summary* summary) { double start_time = WallTimeInSeconds(); double iteration_start_time = start_time; Init(options); Evaluator* evaluator = CHECK_NOTNULL(options_.evaluator); SparseMatrix* jacobian = CHECK_NOTNULL(options_.jacobian); TrustRegionStrategy* strategy = CHECK_NOTNULL(options_.trust_region_strategy); const bool is_not_silent = !options.is_silent; // If the problem is bounds constrained, then enable the use of a // line search after the trust region step has been computed. This // line search will automatically use a projected test point onto // the feasible set, there by guaranteeing the feasibility of the // final output. // // TODO(sameeragarwal): Make line search available more generally. const bool use_line_search = options.is_constrained; summary->termination_type = NO_CONVERGENCE; summary->num_successful_steps = 0; summary->num_unsuccessful_steps = 0; const int num_parameters = evaluator->NumParameters(); const int num_effective_parameters = evaluator->NumEffectiveParameters(); const int num_residuals = evaluator->NumResiduals(); Vector residuals(num_residuals); Vector trust_region_step(num_effective_parameters); Vector delta(num_effective_parameters); Vector x_plus_delta(num_parameters); Vector gradient(num_effective_parameters); Vector model_residuals(num_residuals); Vector scale(num_effective_parameters); Vector negative_gradient(num_effective_parameters); Vector projected_gradient_step(num_parameters); IterationSummary iteration_summary; iteration_summary.iteration = 0; iteration_summary.step_is_valid = false; iteration_summary.step_is_successful = false; iteration_summary.cost_change = 0.0; iteration_summary.gradient_max_norm = 0.0; iteration_summary.gradient_norm = 0.0; iteration_summary.step_norm = 0.0; iteration_summary.relative_decrease = 0.0; iteration_summary.trust_region_radius = strategy->Radius(); iteration_summary.eta = options_.eta; iteration_summary.linear_solver_iterations = 0; iteration_summary.step_solver_time_in_seconds = 0; VectorRef x_min(parameters, num_parameters); Vector x = x_min; // Project onto the feasible set. if (options.is_constrained) { delta.setZero(); if (!evaluator->Plus(x.data(), delta.data(), x_plus_delta.data())) { summary->message = "Unable to project initial point onto the feasible set."; summary->termination_type = FAILURE; LOG_IF(WARNING, is_not_silent) << "Terminating: " << summary->message; return; } x_min = x_plus_delta; x = x_plus_delta; } double x_norm = x.norm(); // Do initial cost and Jacobian evaluation. double cost = 0.0; if (!evaluator->Evaluate(x.data(), &cost, residuals.data(), gradient.data(), jacobian)) { summary->message = "Residual and Jacobian evaluation failed."; summary->termination_type = FAILURE; LOG_IF(WARNING, is_not_silent) << "Terminating: " << summary->message; return; } negative_gradient = -gradient; if (!evaluator->Plus(x.data(), negative_gradient.data(), projected_gradient_step.data())) { summary->message = "Unable to compute gradient step."; summary->termination_type = FAILURE; LOG(ERROR) << "Terminating: " << summary->message; return; } summary->initial_cost = cost + summary->fixed_cost; iteration_summary.cost = cost + summary->fixed_cost; iteration_summary.gradient_max_norm = (x - projected_gradient_step).lpNorm(); iteration_summary.gradient_norm = (x - projected_gradient_step).norm(); if (iteration_summary.gradient_max_norm <= options.gradient_tolerance) { summary->message = StringPrintf("Gradient tolerance reached. " "Gradient max norm: %e <= %e", iteration_summary.gradient_max_norm, options_.gradient_tolerance); summary->termination_type = CONVERGENCE; VLOG_IF(1, is_not_silent) << "Terminating: " << summary->message; return; } if (options_.jacobi_scaling) { EstimateScale(*jacobian, scale.data()); jacobian->ScaleColumns(scale.data()); } else { scale.setOnes(); } iteration_summary.iteration_time_in_seconds = WallTimeInSeconds() - iteration_start_time; iteration_summary.cumulative_time_in_seconds = WallTimeInSeconds() - start_time + summary->preprocessor_time_in_seconds; summary->iterations.push_back(iteration_summary); int num_consecutive_nonmonotonic_steps = 0; double minimum_cost = cost; double reference_cost = cost; double accumulated_reference_model_cost_change = 0.0; double candidate_cost = cost; double accumulated_candidate_model_cost_change = 0.0; int num_consecutive_invalid_steps = 0; bool inner_iterations_are_enabled = options.inner_iteration_minimizer != NULL; while (true) { bool inner_iterations_were_useful = false; if (!RunCallbacks(options, iteration_summary, summary)) { return; } iteration_start_time = WallTimeInSeconds(); if (iteration_summary.iteration >= options_.max_num_iterations) { summary->message = "Maximum number of iterations reached."; summary->termination_type = NO_CONVERGENCE; VLOG_IF(1, is_not_silent) << "Terminating: " << summary->message; return; } const double total_solver_time = iteration_start_time - start_time + summary->preprocessor_time_in_seconds; if (total_solver_time >= options_.max_solver_time_in_seconds) { summary->message = "Maximum solver time reached."; summary->termination_type = NO_CONVERGENCE; VLOG_IF(1, is_not_silent) << "Terminating: " << summary->message; return; } const double strategy_start_time = WallTimeInSeconds(); TrustRegionStrategy::PerSolveOptions per_solve_options; per_solve_options.eta = options_.eta; if (find(options_.trust_region_minimizer_iterations_to_dump.begin(), options_.trust_region_minimizer_iterations_to_dump.end(), iteration_summary.iteration) != options_.trust_region_minimizer_iterations_to_dump.end()) { per_solve_options.dump_format_type = options_.trust_region_problem_dump_format_type; per_solve_options.dump_filename_base = JoinPath(options_.trust_region_problem_dump_directory, StringPrintf("ceres_solver_iteration_%03d", iteration_summary.iteration)); } else { per_solve_options.dump_format_type = TEXTFILE; per_solve_options.dump_filename_base.clear(); } TrustRegionStrategy::Summary strategy_summary = strategy->ComputeStep(per_solve_options, jacobian, residuals.data(), trust_region_step.data()); if (strategy_summary.termination_type == LINEAR_SOLVER_FATAL_ERROR) { summary->message = "Linear solver failed due to unrecoverable " "non-numeric causes. Please see the error log for clues. "; summary->termination_type = FAILURE; LOG_IF(WARNING, is_not_silent) << "Terminating: " << summary->message; return; } iteration_summary = IterationSummary(); iteration_summary.iteration = summary->iterations.back().iteration + 1; iteration_summary.step_solver_time_in_seconds = WallTimeInSeconds() - strategy_start_time; iteration_summary.linear_solver_iterations = strategy_summary.num_iterations; iteration_summary.step_is_valid = false; iteration_summary.step_is_successful = false; double model_cost_change = 0.0; if (strategy_summary.termination_type != LINEAR_SOLVER_FAILURE) { // new_model_cost // = 1/2 [f + J * step]^2 // = 1/2 [ f'f + 2f'J * step + step' * J' * J * step ] // model_cost_change // = cost - new_model_cost // = f'f/2 - 1/2 [ f'f + 2f'J * step + step' * J' * J * step] // = -f'J * step - step' * J' * J * step / 2 model_residuals.setZero(); jacobian->RightMultiply(trust_region_step.data(), model_residuals.data()); model_cost_change = - model_residuals.dot(residuals + model_residuals / 2.0); if (model_cost_change < 0.0) { VLOG_IF(1, is_not_silent) << "Invalid step: current_cost: " << cost << " absolute difference " << model_cost_change << " relative difference " << (model_cost_change / cost); } else { iteration_summary.step_is_valid = true; } } if (!iteration_summary.step_is_valid) { // Invalid steps can happen due to a number of reasons, and we // allow a limited number of successive failures, and return with // FAILURE if this limit is exceeded. if (++num_consecutive_invalid_steps >= options_.max_num_consecutive_invalid_steps) { summary->message = StringPrintf( "Number of successive invalid steps more " "than Solver::Options::max_num_consecutive_invalid_steps: %d", options_.max_num_consecutive_invalid_steps); summary->termination_type = FAILURE; LOG_IF(WARNING, is_not_silent) << "Terminating: " << summary->message; return; } // We are going to try and reduce the trust region radius and // solve again. To do this, we are going to treat this iteration // as an unsuccessful iteration. Since the various callbacks are // still executed, we are going to fill the iteration summary // with data that assumes a step of length zero and no progress. iteration_summary.cost = cost + summary->fixed_cost; iteration_summary.cost_change = 0.0; iteration_summary.gradient_max_norm = summary->iterations.back().gradient_max_norm; iteration_summary.gradient_norm = summary->iterations.back().gradient_norm; iteration_summary.step_norm = 0.0; iteration_summary.relative_decrease = 0.0; iteration_summary.eta = options_.eta; } else { // The step is numerically valid, so now we can judge its quality. num_consecutive_invalid_steps = 0; // Undo the Jacobian column scaling. delta = (trust_region_step.array() * scale.array()).matrix(); // Try improving the step further by using an ARMIJO line // search. // // TODO(sameeragarwal): What happens to trust region sizing as // it interacts with the line search ? if (use_line_search) { const LineSearch::Summary line_search_summary = DoLineSearch(options, x, gradient, cost, delta, evaluator); if (line_search_summary.success) { delta *= line_search_summary.optimal_step_size; } } double new_cost = std::numeric_limits::max(); if (evaluator->Plus(x.data(), delta.data(), x_plus_delta.data())) { if (!evaluator->Evaluate(x_plus_delta.data(), &new_cost, NULL, NULL, NULL)) { LOG(WARNING) << "Step failed to evaluate. " << "Treating it as a step with infinite cost"; new_cost = numeric_limits::max(); } } else { LOG(WARNING) << "x_plus_delta = Plus(x, delta) failed. " << "Treating it as a step with infinite cost"; } if (new_cost < std::numeric_limits::max()) { // Check if performing an inner iteration will make it better. if (inner_iterations_are_enabled) { ++summary->num_inner_iteration_steps; double inner_iteration_start_time = WallTimeInSeconds(); const double x_plus_delta_cost = new_cost; Vector inner_iteration_x = x_plus_delta; Solver::Summary inner_iteration_summary; options.inner_iteration_minimizer->Minimize(options, inner_iteration_x.data(), &inner_iteration_summary); if (!evaluator->Evaluate(inner_iteration_x.data(), &new_cost, NULL, NULL, NULL)) { VLOG_IF(2, is_not_silent) << "Inner iteration failed."; new_cost = x_plus_delta_cost; } else { x_plus_delta = inner_iteration_x; // Boost the model_cost_change, since the inner iteration // improvements are not accounted for by the trust region. model_cost_change += x_plus_delta_cost - new_cost; VLOG_IF(2, is_not_silent) << "Inner iteration succeeded; Current cost: " << cost << " Trust region step cost: " << x_plus_delta_cost << " Inner iteration cost: " << new_cost; inner_iterations_were_useful = new_cost < cost; const double inner_iteration_relative_progress = 1.0 - new_cost / x_plus_delta_cost; // Disable inner iterations once the relative improvement // drops below tolerance. inner_iterations_are_enabled = (inner_iteration_relative_progress > options.inner_iteration_tolerance); VLOG_IF(2, is_not_silent && !inner_iterations_are_enabled) << "Disabling inner iterations. Progress : " << inner_iteration_relative_progress; } summary->inner_iteration_time_in_seconds += WallTimeInSeconds() - inner_iteration_start_time; } } iteration_summary.step_norm = (x - x_plus_delta).norm(); // Convergence based on parameter_tolerance. const double step_size_tolerance = options_.parameter_tolerance * (x_norm + options_.parameter_tolerance); if (iteration_summary.step_norm <= step_size_tolerance) { summary->message = StringPrintf("Parameter tolerance reached. " "Relative step_norm: %e <= %e.", (iteration_summary.step_norm / (x_norm + options_.parameter_tolerance)), options_.parameter_tolerance); summary->termination_type = CONVERGENCE; VLOG_IF(1, is_not_silent) << "Terminating: " << summary->message; return; } iteration_summary.cost_change = cost - new_cost; const double absolute_function_tolerance = options_.function_tolerance * cost; if (fabs(iteration_summary.cost_change) < absolute_function_tolerance) { summary->message = StringPrintf("Function tolerance reached. " "|cost_change|/cost: %e <= %e", fabs(iteration_summary.cost_change) / cost, options_.function_tolerance); summary->termination_type = CONVERGENCE; VLOG_IF(1, is_not_silent) << "Terminating: " << summary->message; return; } const double relative_decrease = iteration_summary.cost_change / model_cost_change; const double historical_relative_decrease = (reference_cost - new_cost) / (accumulated_reference_model_cost_change + model_cost_change); // If monotonic steps are being used, then the relative_decrease // is the usual ratio of the change in objective function value // divided by the change in model cost. // // If non-monotonic steps are allowed, then we take the maximum // of the relative_decrease and the // historical_relative_decrease, which measures the increase // from a reference iteration. The model cost change is // estimated by accumulating the model cost changes since the // reference iteration. The historical relative_decrease offers // a boost to a step which is not too bad compared to the // reference iteration, allowing for non-monotonic steps. iteration_summary.relative_decrease = options.use_nonmonotonic_steps ? max(relative_decrease, historical_relative_decrease) : relative_decrease; // Normally, the quality of a trust region step is measured by // the ratio // // cost_change // r = ----------------- // model_cost_change // // All the change in the nonlinear objective is due to the trust // region step so this ratio is a good measure of the quality of // the trust region radius. However, when inner iterations are // being used, cost_change includes the contribution of the // inner iterations and its not fair to credit it all to the // trust region algorithm. So we change the ratio to be // // cost_change // r = ------------------------------------------------ // (model_cost_change + inner_iteration_cost_change) // // In most cases this is fine, but it can be the case that the // change in solution quality due to inner iterations is so large // and the trust region step is so bad, that this ratio can become // quite small. // // This can cause the trust region loop to reject this step. To // get around this, we expicitly check if the inner iterations // led to a net decrease in the objective function value. If // they did, we accept the step even if the trust region ratio // is small. // // Notice that we do not just check that cost_change is positive // which is a weaker condition and would render the // min_relative_decrease threshold useless. Instead, we keep // track of inner_iterations_were_useful, which is true only // when inner iterations lead to a net decrease in the cost. iteration_summary.step_is_successful = (inner_iterations_were_useful || iteration_summary.relative_decrease > options_.min_relative_decrease); if (iteration_summary.step_is_successful) { accumulated_candidate_model_cost_change += model_cost_change; accumulated_reference_model_cost_change += model_cost_change; if (!inner_iterations_were_useful && relative_decrease <= options_.min_relative_decrease) { iteration_summary.step_is_nonmonotonic = true; VLOG_IF(2, is_not_silent) << "Non-monotonic step! " << " relative_decrease: " << relative_decrease << " historical_relative_decrease: " << historical_relative_decrease; } } } if (iteration_summary.step_is_successful) { ++summary->num_successful_steps; strategy->StepAccepted(iteration_summary.relative_decrease); x = x_plus_delta; x_norm = x.norm(); // Step looks good, evaluate the residuals and Jacobian at this // point. if (!evaluator->Evaluate(x.data(), &cost, residuals.data(), gradient.data(), jacobian)) { summary->message = "Residual and Jacobian evaluation failed."; summary->termination_type = FAILURE; LOG_IF(WARNING, is_not_silent) << "Terminating: " << summary->message; return; } negative_gradient = -gradient; if (!evaluator->Plus(x.data(), negative_gradient.data(), projected_gradient_step.data())) { summary->message = "projected_gradient_step = Plus(x, -gradient) failed."; summary->termination_type = FAILURE; LOG(ERROR) << "Terminating: " << summary->message; return; } iteration_summary.gradient_max_norm = (x - projected_gradient_step).lpNorm(); iteration_summary.gradient_norm = (x - projected_gradient_step).norm(); if (iteration_summary.gradient_max_norm <= options.gradient_tolerance) { summary->message = StringPrintf("Gradient tolerance reached. " "Gradient max norm: %e <= %e", iteration_summary.gradient_max_norm, options_.gradient_tolerance); summary->termination_type = CONVERGENCE; VLOG_IF(1, is_not_silent) << "Terminating: " << summary->message; return; } if (options_.jacobi_scaling) { jacobian->ScaleColumns(scale.data()); } // Update the best, reference and candidate iterates. // // Based on algorithm 10.1.2 (page 357) of "Trust Region // Methods" by Conn Gould & Toint, or equations 33-40 of // "Non-monotone trust-region algorithms for nonlinear // optimization subject to convex constraints" by Phil Toint, // Mathematical Programming, 77, 1997. if (cost < minimum_cost) { // A step that improves solution quality was found. x_min = x; minimum_cost = cost; // Set the candidate iterate to the current point. candidate_cost = cost; num_consecutive_nonmonotonic_steps = 0; accumulated_candidate_model_cost_change = 0.0; } else { ++num_consecutive_nonmonotonic_steps; if (cost > candidate_cost) { // The current iterate is has a higher cost than the // candidate iterate. Set the candidate to this point. VLOG_IF(2, is_not_silent) << "Updating the candidate iterate to the current point."; candidate_cost = cost; accumulated_candidate_model_cost_change = 0.0; } // At this point we have made too many non-monotonic steps and // we are going to reset the value of the reference iterate so // as to force the algorithm to descend. // // This is the case because the candidate iterate has a value // greater than minimum_cost but smaller than the reference // iterate. if (num_consecutive_nonmonotonic_steps == options.max_consecutive_nonmonotonic_steps) { VLOG_IF(2, is_not_silent) << "Resetting the reference point to the candidate point"; reference_cost = candidate_cost; accumulated_reference_model_cost_change = accumulated_candidate_model_cost_change; } } } else { ++summary->num_unsuccessful_steps; if (iteration_summary.step_is_valid) { strategy->StepRejected(iteration_summary.relative_decrease); } else { strategy->StepIsInvalid(); } } iteration_summary.cost = cost + summary->fixed_cost; iteration_summary.trust_region_radius = strategy->Radius(); if (iteration_summary.trust_region_radius < options_.min_trust_region_radius) { summary->message = "Termination. Minimum trust region radius reached."; summary->termination_type = CONVERGENCE; VLOG_IF(1, is_not_silent) << summary->message; return; } iteration_summary.iteration_time_in_seconds = WallTimeInSeconds() - iteration_start_time; iteration_summary.cumulative_time_in_seconds = WallTimeInSeconds() - start_time + summary->preprocessor_time_in_seconds; summary->iterations.push_back(iteration_summary); } } } // namespace internal } // namespace ceres