| .. highlight:: c++ |
| |
| .. default-domain:: cpp |
| |
| .. _chapter-gradient_problem_solver: |
| |
| ================================== |
| General Unconstrained Minimization |
| ================================== |
| |
| Modeling |
| ======== |
| |
| :class:`FirstOrderFunction` |
| --------------------------- |
| |
| .. class:: FirstOrderFunction |
| |
| Instances of :class:`FirstOrderFunction` implement the evaluation of |
| a function and its gradient. |
| |
| .. code-block:: c++ |
| |
| class FirstOrderFunction { |
| public: |
| virtual ~FirstOrderFunction() {} |
| virtual bool Evaluate(const double* const parameters, |
| double* cost, |
| double* gradient) const = 0; |
| virtual int NumParameters() const = 0; |
| }; |
| |
| .. function:: bool FirstOrderFunction::Evaluate(const double* const parameters, double* cost, double* gradient) const |
| |
| Evaluate the cost/value of the function. If ``gradient`` is not |
| ``NULL`` then evaluate the gradient too. If evaluation is |
| successful return, ``true`` else return ``false``. |
| |
| ``cost`` guaranteed to be never ``NULL``, ``gradient`` can be ``NULL``. |
| |
| .. function:: int FirstOrderFunction::NumParameters() const |
| |
| Number of parameters in the domain of the function. |
| |
| |
| :class:`GradientProblem` |
| ------------------------ |
| |
| .. class:: GradientProblem |
| |
| .. code-block:: c++ |
| |
| class GradientProblem { |
| public: |
| explicit GradientProblem(FirstOrderFunction* function); |
| GradientProblem(FirstOrderFunction* function, |
| LocalParameterization* parameterization); |
| int NumParameters() const; |
| int NumLocalParameters() const; |
| bool Evaluate(const double* parameters, double* cost, double* gradient) const; |
| bool Plus(const double* x, const double* delta, double* x_plus_delta) const; |
| }; |
| |
| Instances of :class:`GradientProblem` represent general non-linear |
| optimization problems that must be solved using just the value of the |
| objective function and its gradient. Unlike the :class:`Problem` |
| class, which can only be used to model non-linear least squares |
| problems, instances of :class:`GradientProblem` not restricted in the |
| form of the objective function. |
| |
| Structurally :class:`GradientProblem` is a composition of a |
| :class:`FirstOrderFunction` and optionally a |
| :class:`LocalParameterization`. |
| |
| The :class:`FirstOrderFunction` is responsible for evaluating the cost |
| and gradient of the objective function. |
| |
| The :class:`LocalParameterization` is responsible for going back and |
| forth between the ambient space and the local tangent space. When a |
| :class:`LocalParameterization` is not provided, then the tangent space |
| is assumed to coincide with the ambient Euclidean space that the |
| gradient vector lives in. |
| |
| The constructor takes ownership of the :class:`FirstOrderFunction` and |
| :class:`LocalParamterization` objects passed to it. |
| |
| |
| .. function:: void Solve(const GradientProblemSolver::Options& options, const GradientProblem& problem, double* parameters, GradientProblemSolver::Summary* summary) |
| |
| Solve the given :class:`GradientProblem` using the values in |
| ``parameters`` as the initial guess of the solution. |
| |
| |
| Solving |
| ======= |
| |
| :class:`GradientProblemSolver::Options` |
| --------------------------------------- |
| |
| .. class:: GradientProblemSolver::Options |
| |
| :class:`GradientProblemSolver::Options` controls the overall |
| behavior of the solver. We list the various settings and their |
| default values below. |
| |
| .. function:: bool GradientProblemSolver::Options::IsValid(string* error) const |
| |
| Validate the values in the options struct and returns true on |
| success. If there is a problem, the method returns false with |
| ``error`` containing a textual description of the cause. |
| |
| .. member:: LineSearchDirectionType GradientProblemSolver::Options::line_search_direction_type |
| |
| Default: ``LBFGS`` |
| |
| Choices are ``STEEPEST_DESCENT``, ``NONLINEAR_CONJUGATE_GRADIENT``, |
| ``BFGS`` and ``LBFGS``. |
| |
| .. member:: LineSearchType GradientProblemSolver::Options::line_search_type |
| |
| Default: ``WOLFE`` |
| |
| Choices are ``ARMIJO`` and ``WOLFE`` (strong Wolfe conditions). |
| Note that in order for the assumptions underlying the ``BFGS`` and |
| ``LBFGS`` line search direction algorithms to be guaranteed to be |
| satisifed, the ``WOLFE`` line search should be used. |
| |
| .. member:: NonlinearConjugateGradientType GradientProblemSolver::Options::nonlinear_conjugate_gradient_type |
| |
| Default: ``FLETCHER_REEVES`` |
| |
| Choices are ``FLETCHER_REEVES``, ``POLAK_RIBIERE`` and |
| ``HESTENES_STIEFEL``. |
| |
| .. member:: int GradientProblemSolver::Options::max_lbfs_rank |
| |
| Default: 20 |
| |
| The L-BFGS hessian approximation is a low rank approximation to the |
| inverse of the Hessian matrix. The rank of the approximation |
| determines (linearly) the space and time complexity of using the |
| approximation. Higher the rank, the better is the quality of the |
| approximation. The increase in quality is however is bounded for a |
| number of reasons. |
| |
| 1. The method only uses secant information and not actual |
| derivatives. |
| |
| 2. The Hessian approximation is constrained to be positive |
| definite. |
| |
| So increasing this rank to a large number will cost time and space |
| complexity without the corresponding increase in solution |
| quality. There are no hard and fast rules for choosing the maximum |
| rank. The best choice usually requires some problem specific |
| experimentation. |
| |
| .. member:: bool GradientProblemSolver::Options::use_approximate_eigenvalue_bfgs_scaling |
| |
| Default: ``false`` |
| |
| As part of the ``BFGS`` update step / ``LBFGS`` right-multiply |
| step, the initial inverse Hessian approximation is taken to be the |
| Identity. However, [Oren]_ showed that using instead :math:`I * |
| \gamma`, where :math:`\gamma` is a scalar chosen to approximate an |
| eigenvalue of the true inverse Hessian can result in improved |
| convergence in a wide variety of cases. Setting |
| ``use_approximate_eigenvalue_bfgs_scaling`` to true enables this |
| scaling in ``BFGS`` (before first iteration) and ``LBFGS`` (at each |
| iteration). |
| |
| Precisely, approximate eigenvalue scaling equates to |
| |
| .. math:: \gamma = \frac{y_k' s_k}{y_k' y_k} |
| |
| With: |
| |
| .. math:: y_k = \nabla f_{k+1} - \nabla f_k |
| .. math:: s_k = x_{k+1} - x_k |
| |
| Where :math:`f()` is the line search objective and :math:`x` the |
| vector of parameter values [NocedalWright]_. |
| |
| It is important to note that approximate eigenvalue scaling does |
| **not** *always* improve convergence, and that it can in fact |
| *significantly* degrade performance for certain classes of problem, |
| which is why it is disabled by default. In particular it can |
| degrade performance when the sensitivity of the problem to different |
| parameters varies significantly, as in this case a single scalar |
| factor fails to capture this variation and detrimentally downscales |
| parts of the Jacobian approximation which correspond to |
| low-sensitivity parameters. It can also reduce the robustness of the |
| solution to errors in the Jacobians. |
| |
| .. member:: LineSearchIterpolationType GradientProblemSolver::Options::line_search_interpolation_type |
| |
| Default: ``CUBIC`` |
| |
| Degree of the polynomial used to approximate the objective |
| function. Valid values are ``BISECTION``, ``QUADRATIC`` and |
| ``CUBIC``. |
| |
| .. member:: double GradientProblemSolver::Options::min_line_search_step_size |
| |
| The line search terminates if: |
| |
| .. math:: \|\Delta x_k\|_\infty < \text{min_line_search_step_size} |
| |
| where :math:`\|\cdot\|_\infty` refers to the max norm, and |
| :math:`\Delta x_k` is the step change in the parameter values at |
| the :math:`k`-th iteration. |
| |
| .. member:: double GradientProblemSolver::Options::line_search_sufficient_function_decrease |
| |
| Default: ``1e-4`` |
| |
| Solving the line search problem exactly is computationally |
| prohibitive. Fortunately, line search based optimization algorithms |
| can still guarantee convergence if instead of an exact solution, |
| the line search algorithm returns a solution which decreases the |
| value of the objective function sufficiently. More precisely, we |
| are looking for a step size s.t. |
| |
| .. math:: f(\text{step_size}) \le f(0) + \text{sufficient_decrease} * [f'(0) * \text{step_size}] |
| |
| This condition is known as the Armijo condition. |
| |
| .. member:: double GradientProblemSolver::Options::max_line_search_step_contraction |
| |
| Default: ``1e-3`` |
| |
| In each iteration of the line search, |
| |
| .. math:: \text{new_step_size} \geq \text{max_line_search_step_contraction} * \text{step_size} |
| |
| Note that by definition, for contraction: |
| |
| .. math:: 0 < \text{max_step_contraction} < \text{min_step_contraction} < 1 |
| |
| .. member:: double GradientProblemSolver::Options::min_line_search_step_contraction |
| |
| Default: ``0.6`` |
| |
| In each iteration of the line search, |
| |
| .. math:: \text{new_step_size} \leq \text{min_line_search_step_contraction} * \text{step_size} |
| |
| Note that by definition, for contraction: |
| |
| .. math:: 0 < \text{max_step_contraction} < \text{min_step_contraction} < 1 |
| |
| .. member:: int GradientProblemSolver::Options::max_num_line_search_step_size_iterations |
| |
| Default: ``20`` |
| |
| Maximum number of trial step size iterations during each line |
| search, if a step size satisfying the search conditions cannot be |
| found within this number of trials, the line search will stop. |
| |
| As this is an 'artificial' constraint (one imposed by the user, not |
| the underlying math), if ``WOLFE`` line search is being used, *and* |
| points satisfying the Armijo sufficient (function) decrease |
| condition have been found during the current search (in :math:`\leq` |
| ``max_num_line_search_step_size_iterations``). Then, the step size |
| with the lowest function value which satisfies the Armijo condition |
| will be returned as the new valid step, even though it does *not* |
| satisfy the strong Wolfe conditions. This behaviour protects |
| against early termination of the optimizer at a sub-optimal point. |
| |
| .. member:: int GradientProblemSolver::Options::max_num_line_search_direction_restarts |
| |
| Default: ``5`` |
| |
| Maximum number of restarts of the line search direction algorithm |
| before terminating the optimization. Restarts of the line search |
| direction algorithm occur when the current algorithm fails to |
| produce a new descent direction. This typically indicates a |
| numerical failure, or a breakdown in the validity of the |
| approximations used. |
| |
| .. member:: double GradientProblemSolver::Options::line_search_sufficient_curvature_decrease |
| |
| Default: ``0.9`` |
| |
| The strong Wolfe conditions consist of the Armijo sufficient |
| decrease condition, and an additional requirement that the |
| step size be chosen s.t. the *magnitude* ('strong' Wolfe |
| conditions) of the gradient along the search direction |
| decreases sufficiently. Precisely, this second condition |
| is that we seek a step size s.t. |
| |
| .. math:: \|f'(\text{step_size})\| \leq \text{sufficient_curvature_decrease} * \|f'(0)\| |
| |
| Where :math:`f()` is the line search objective and :math:`f'()` is the derivative |
| of :math:`f` with respect to the step size: :math:`\frac{d f}{d~\text{step size}}`. |
| |
| .. member:: double GradientProblemSolver::Options::max_line_search_step_expansion |
| |
| Default: ``10.0`` |
| |
| During the bracketing phase of a Wolfe line search, the step size |
| is increased until either a point satisfying the Wolfe conditions |
| is found, or an upper bound for a bracket containing a point |
| satisfying the conditions is found. Precisely, at each iteration |
| of the expansion: |
| |
| .. math:: \text{new_step_size} \leq \text{max_step_expansion} * \text{step_size} |
| |
| By definition for expansion |
| |
| .. math:: \text{max_step_expansion} > 1.0 |
| |
| .. member:: int GradientProblemSolver::Options::max_num_iterations |
| |
| Default: ``50`` |
| |
| Maximum number of iterations for which the solver should run. |
| |
| .. member:: double GradientProblemSolver::Options::max_solver_time_in_seconds |
| |
| Default: ``1e6`` |
| Maximum amount of time for which the solver should run. |
| |
| .. member:: double GradientProblemSolver::Options::function_tolerance |
| |
| Default: ``1e-6`` |
| |
| Solver terminates if |
| |
| .. math:: \frac{|\Delta \text{cost}|}{\text{cost}} \leq \text{function_tolerance} |
| |
| where, :math:`\Delta \text{cost}` is the change in objective |
| function value (up or down) in the current iteration of the line search. |
| |
| .. member:: double GradientProblemSolver::Options::gradient_tolerance |
| |
| Default: ``1e-10`` |
| |
| Solver terminates if |
| |
| .. math:: \|x - \Pi \boxplus(x, -g(x))\|_\infty \leq \text{gradient_tolerance} |
| |
| where :math:`\|\cdot\|_\infty` refers to the max norm, :math:`\Pi` |
| is projection onto the bounds constraints and :math:`\boxplus` is |
| Plus operation for the overall local parameterization associated |
| with the parameter vector. |
| |
| .. member:: double GradientProblemSolver::Options::parameter_tolerance |
| |
| Default: ``1e-8`` |
| |
| Solver terminates if |
| |
| .. math:: \|\Delta x\| \leq (\|x\| + \text{parameter_tolerance}) * \text{parameter_tolerance} |
| |
| where :math:`\Delta x` is the step computed by the linear solver in |
| the current iteration of the line search. |
| |
| .. member:: LoggingType GradientProblemSolver::Options::logging_type |
| |
| Default: ``PER_MINIMIZER_ITERATION`` |
| |
| .. member:: bool GradientProblemSolver::Options::minimizer_progress_to_stdout |
| |
| Default: ``false`` |
| |
| By default the :class:`Minimizer` progress is logged to ``STDERR`` |
| depending on the ``vlog`` level. If this flag is set to true, and |
| :member:`GradientProblemSolver::Options::logging_type` is not |
| ``SILENT``, the logging output is sent to ``STDOUT``. |
| |
| The progress display looks like |
| |
| .. code-block:: bash |
| |
| 0: f: 2.317806e+05 d: 0.00e+00 g: 3.19e-01 h: 0.00e+00 s: 0.00e+00 e: 0 it: 2.98e-02 tt: 8.50e-02 |
| 1: f: 2.312019e+05 d: 5.79e+02 g: 3.18e-01 h: 2.41e+01 s: 1.00e+00 e: 1 it: 4.54e-02 tt: 1.31e-01 |
| 2: f: 2.300462e+05 d: 1.16e+03 g: 3.17e-01 h: 4.90e+01 s: 2.54e-03 e: 1 it: 4.96e-02 tt: 1.81e-01 |
| |
| Here |
| |
| #. ``f`` is the value of the objective function. |
| #. ``d`` is the change in the value of the objective function if |
| the step computed in this iteration is accepted. |
| #. ``g`` is the max norm of the gradient. |
| #. ``h`` is the change in the parameter vector. |
| #. ``s`` is the optimal step length computed by the line search. |
| #. ``it`` is the time take by the current iteration. |
| #. ``tt`` is the total time taken by the minimizer. |
| |
| .. member:: vector<IterationCallback> GradientProblemSolver::Options::callbacks |
| |
| Callbacks that are executed at the end of each iteration of the |
| :class:`Minimizer`. They are executed in the order that they are |
| specified in this vector. By default, parameter blocks are updated |
| only at the end of the optimization, i.e., when the |
| :class:`Minimizer` terminates. This behavior is controlled by |
| :member:`GradientProblemSolver::Options::update_state_every_variable`. If |
| the user wishes to have access to the update parameter blocks when |
| his/her callbacks are executed, then set |
| :member:`GradientProblemSolver::Options::update_state_every_iteration` |
| to true. |
| |
| The solver does NOT take ownership of these pointers. |
| |
| |
| .. member:: bool Solver::Options::update_state_every_iteration |
| |
| Default: ``false`` |
| |
| Normally the parameter vector is only updated when the solver |
| terminates. Setting this to true updates it every iteration. This |
| setting is useful when building an interactive application using |
| Ceres and using an :class:`IterationCallback`. |
| |
| :class:`GradientProblemSolver::Summary` |
| --------------------------------------- |
| |
| .. class:: GradientProblemSolver::Summary |
| |
| Summary of the various stages of the solver after termination. |
| |
| .. function:: string GradientProblemSolver::Summary::BriefReport() const |
| |
| A brief one line description of the state of the solver after |
| termination. |
| |
| .. function:: string GradientProblemSolver::Summary::FullReport() const |
| |
| A full multiline description of the state of the solver after |
| termination. |
| |
| .. function:: bool GradientProblemSolver::Summary::IsSolutionUsable() const |
| |
| Whether the solution returned by the optimization algorithm can be |
| relied on to be numerically sane. This will be the case if |
| `GradientProblemSolver::Summary:termination_type` is set to `CONVERGENCE`, |
| `USER_SUCCESS` or `NO_CONVERGENCE`, i.e., either the solver |
| converged by meeting one of the convergence tolerances or because |
| the user indicated that it had converged or it ran to the maximum |
| number of iterations or time. |
| |
| .. member:: TerminationType GradientProblemSolver::Summary::termination_type |
| |
| The cause of the minimizer terminating. |
| |
| .. member:: string GradientProblemSolver::Summary::message |
| |
| Reason why the solver terminated. |
| |
| .. member:: double GradientProblemSolver::Summary::initial_cost |
| |
| Cost of the problem (value of the objective function) before the |
| optimization. |
| |
| .. member:: double GradientProblemSolver::Summary::final_cost |
| |
| Cost of the problem (value of the objective function) after the |
| optimization. |
| |
| .. member:: vector<IterationSummary> GradientProblemSolver::Summary::iterations |
| |
| :class:`IterationSummary` for each minimizer iteration in order. |
| |
| .. member:: int num_cost_evaluations |
| |
| Number of times the cost (and not the gradient) was evaluated. |
| |
| .. member:: int num_gradient_evaluations |
| |
| Number of times the gradient (and the cost) were evaluated. |
| |
| .. member:: double GradientProblemSolver::Summary::total_time_in_seconds |
| |
| Time (in seconds) spent in the solver. |
| |
| .. member:: double GradientProblemSolver::Summary::cost_evaluation_time_in_seconds |
| |
| Time (in seconds) spent evaluating the cost vector. |
| |
| .. member:: double GradientProblemSolver::Summary::gradient_evaluation_time_in_seconds |
| |
| Time (in seconds) spent evaluating the gradient vector. |
| |
| .. member:: int GradientProblemSolver::Summary::num_parameters |
| |
| Number of parameters in the problem. |
| |
| .. member:: int GradientProblemSolver::Summary::num_local_parameters |
| |
| Dimension of the tangent space of the problem. This is different |
| from :member:`GradientProblemSolver::Summary::num_parameters` if a |
| :class:`LocalParameterization` object is used. |
| |
| .. member:: LineSearchDirectionType GradientProblemSolver::Summary::line_search_direction_type |
| |
| Type of line search direction used. |
| |
| .. member:: LineSearchType GradientProblemSolver::Summary::line_search_type |
| |
| Type of the line search algorithm used. |
| |
| .. member:: LineSearchInterpolationType GradientProblemSolver::Summary::line_search_interpolation_type |
| |
| When performing line search, the degree of the polynomial used to |
| approximate the objective function. |
| |
| .. member:: NonlinearConjugateGradientType GradientProblemSolver::Summary::nonlinear_conjugate_gradient_type |
| |
| If the line search direction is `NONLINEAR_CONJUGATE_GRADIENT`, |
| then this indicates the particular variant of non-linear conjugate |
| gradient used. |
| |
| .. member:: int GradientProblemSolver::Summary::max_lbfgs_rank |
| |
| If the type of the line search direction is `LBFGS`, then this |
| indicates the rank of the Hessian approximation. |