include/ceres/types.h - ceres-solver - Git at Google

 // Ceres Solver - A fast non-linear least squares minimizer
 // Copyright 2010, 2011, 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)
 //
 // Enums and other top level class definitions.
 //
 // Note: internal/types.cc defines stringification routines for some
 // of these enums. Please update those routines if you extend or
 // remove enums from here.

 #ifndef CERES_PUBLIC_TYPES_H_
 #define CERES_PUBLIC_TYPES_H_

 #include <string>

 #include "ceres/internal/port.h"
 #include "ceres/internal/disable_warnings.h"

 namespace ceres {

 // Basic integer types. These typedefs are in the Ceres namespace to avoid
 // conflicts with other packages having similar typedefs.
 typedef int   int32;

 // Argument type used in interfaces that can optionally take ownership
 // of a passed in argument. If TAKE_OWNERSHIP is passed, the called
 // object takes ownership of the pointer argument, and will call
 // delete on it upon completion.
 enum Ownership {
   DO_NOT_TAKE_OWNERSHIP,
   TAKE_OWNERSHIP
 };

 // TODO(keir): Considerably expand the explanations of each solver type.
 enum LinearSolverType {
   // These solvers are for general rectangular systems formed from the
   // normal equations A'A x = A'b. They are direct solvers and do not
   // assume any special problem structure.

   // Solve the normal equations using a dense Cholesky solver; based
   // on Eigen.
   DENSE_NORMAL_CHOLESKY,

   // Solve the normal equations using a dense QR solver; based on
   // Eigen.
   DENSE_QR,

   // Solve the normal equations using a sparse cholesky solver; requires
   // SuiteSparse or CXSparse.
   SPARSE_NORMAL_CHOLESKY,

   // Specialized solvers, specific to problems with a generalized
   // bi-partitite structure.

   // Solves the reduced linear system using a dense Cholesky solver;
   // based on Eigen.
   DENSE_SCHUR,

   // Solves the reduced linear system using a sparse Cholesky solver;
   // based on CHOLMOD.
   SPARSE_SCHUR,

   // Solves the reduced linear system using Conjugate Gradients, based
   // on a new Ceres implementation.  Suitable for large scale
   // problems.
   ITERATIVE_SCHUR,

   // Conjugate gradients on the normal equations.
   CGNR
 };

 enum PreconditionerType {
   // Trivial preconditioner - the identity matrix.
   IDENTITY,

   // Block diagonal of the Gauss-Newton Hessian.
   JACOBI,

   // Note: The following three preconditioners can only be used with
   // the ITERATIVE_SCHUR solver. They are well suited for Structure
   // from Motion problems.

   // Block diagonal of the Schur complement. This preconditioner may
   // only be used with the ITERATIVE_SCHUR solver.
   SCHUR_JACOBI,

   // Visibility clustering based preconditioners.
   //
   // The following two preconditioners use the visibility structure of
   // the scene to determine the sparsity structure of the
   // preconditioner. This is done using a clustering algorithm. The
   // available visibility clustering algorithms are described below.
   //
   // Note: Requires SuiteSparse.
   CLUSTER_JACOBI,
   CLUSTER_TRIDIAGONAL
 };

 enum VisibilityClusteringType {
   // Canonical views algorithm as described in
   //
   // "Scene Summarization for Online Image Collections", Ian Simon, Noah
   // Snavely, Steven M. Seitz, ICCV 2007.
   //
   // This clustering algorithm can be quite slow, but gives high
   // quality clusters. The original visibility based clustering paper
   // used this algorithm.
   CANONICAL_VIEWS,

   // The classic single linkage algorithm. It is extremely fast as
   // compared to CANONICAL_VIEWS, but can give slightly poorer
   // results. For problems with large number of cameras though, this
   // is generally a pretty good option.
   //
   // If you are using SCHUR_JACOBI preconditioner and have SuiteSparse
   // available, CLUSTER_JACOBI and CLUSTER_TRIDIAGONAL in combination
   // with the SINGLE_LINKAGE algorithm will generally give better
   // results.
   SINGLE_LINKAGE
 };

 enum SparseLinearAlgebraLibraryType {
   // High performance sparse Cholesky factorization and approximate
   // minimum degree ordering.
   SUITE_SPARSE,

   // A lightweight replacment for SuiteSparse, which does not require
   // a LAPACK/BLAS implementation. Consequently, its performance is
   // also a bit lower than SuiteSparse.
   CX_SPARSE,

   // Eigen's sparse linear algebra routines. In particular Ceres uses
   // the Simplicial LDLT routines.
   EIGEN_SPARSE
 };

 enum DenseLinearAlgebraLibraryType {
   EIGEN,
   LAPACK
 };

 // Logging options
 // The options get progressively noisier.
 enum LoggingType {
   SILENT,
   PER_MINIMIZER_ITERATION
 };

 enum MinimizerType {
   LINE_SEARCH,
   TRUST_REGION
 };

 enum LineSearchDirectionType {
   // Negative of the gradient.
   STEEPEST_DESCENT,

   // A generalization of the Conjugate Gradient method to non-linear
   // functions. The generalization can be performed in a number of
   // different ways, resulting in a variety of search directions. The
   // precise choice of the non-linear conjugate gradient algorithm
   // used is determined by NonlinerConjuateGradientType.
   NONLINEAR_CONJUGATE_GRADIENT,

   // BFGS, and it's limited memory approximation L-BFGS, are quasi-Newton
   // algorithms that approximate the Hessian matrix by iteratively refining
   // an initial estimate with rank-one updates using the gradient at each
   // iteration. They are a generalisation of the Secant method and satisfy
   // the Secant equation.  The Secant equation has an infinium of solutions
   // in multiple dimensions, as there are N*(N+1)/2 degrees of freedom in a
   // symmetric matrix but only N conditions are specified by the Secant
   // equation. The requirement that the Hessian approximation be positive
   // definite imposes another N additional constraints, but that still leaves
   // remaining degrees-of-freedom.  (L)BFGS methods uniquely deteremine the
   // approximate Hessian by imposing the additional constraints that the
   // approximation at the next iteration must be the 'closest' to the current
   // approximation (the nature of how this proximity is measured is actually
   // the defining difference between a family of quasi-Newton methods including
   // (L)BFGS & DFP). (L)BFGS is currently regarded as being the best known
   // general quasi-Newton method.
   //
   // The principal difference between BFGS and L-BFGS is that whilst BFGS
   // maintains a full, dense approximation to the (inverse) Hessian, L-BFGS
   // maintains only a window of the last M observations of the parameters and
   // gradients. Using this observation history, the calculation of the next
   // search direction can be computed without requiring the construction of the
   // full dense inverse Hessian approximation. This is particularly important
   // for problems with a large number of parameters, where storage of an N-by-N
   // matrix in memory would be prohibitive.
   //
   // For more details on BFGS see:
   //
   // Broyden, C.G., "The Convergence of a Class of Double-rank Minimization
   // Algorithms,"; J. Inst. Maths. Applics., Vol. 6, pp 76–90, 1970.
   //
   // Fletcher, R., "A New Approach to Variable Metric Algorithms,"
   // Computer Journal, Vol. 13, pp 317–322, 1970.
   //
   // Goldfarb, D., "A Family of Variable Metric Updates Derived by Variational
   // Means," Mathematics of Computing, Vol. 24, pp 23–26, 1970.
   //
   // Shanno, D.F., "Conditioning of Quasi-Newton Methods for Function
   // Minimization," Mathematics of Computing, Vol. 24, pp 647–656, 1970.
   //
   // For more details on L-BFGS see:
   //
   // Nocedal, J. (1980). "Updating Quasi-Newton Matrices with Limited
   // Storage". Mathematics of Computation 35 (151): 773–782.
   //
   // Byrd, R. H.; Nocedal, J.; Schnabel, R. B. (1994).
   // "Representations of Quasi-Newton Matrices and their use in
   // Limited Memory Methods". Mathematical Programming 63 (4):
   // 129–156.
   //
   // A general reference for both methods:
   //
   // Nocedal J., Wright S., Numerical Optimization, 2nd Ed. Springer, 1999.
   LBFGS,
   BFGS,
 };

 // Nonliner conjugate gradient methods are a generalization of the
 // method of Conjugate Gradients for linear systems. The
 // generalization can be carried out in a number of different ways
 // leading to number of different rules for computing the search
 // direction. Ceres provides a number of different variants. For more
 // details see Numerical Optimization by Nocedal & Wright.
 enum NonlinearConjugateGradientType {
   FLETCHER_REEVES,
   POLAK_RIBIERE,
   HESTENES_STIEFEL,
 };

 enum LineSearchType {
   // Backtracking line search with polynomial interpolation or
   // bisection.
   ARMIJO,
   WOLFE,
 };

 // Ceres supports different strategies for computing the trust region
 // step.
 enum TrustRegionStrategyType {
   // The default trust region strategy is to use the step computation
   // used in the Levenberg-Marquardt algorithm. For more details see
   // levenberg_marquardt_strategy.h
   LEVENBERG_MARQUARDT,

   // Powell's dogleg algorithm interpolates between the Cauchy point
   // and the Gauss-Newton step. It is particularly useful if the
   // LEVENBERG_MARQUARDT algorithm is making a large number of
   // unsuccessful steps. For more details see dogleg_strategy.h.
   //
   // NOTES:
   //
   // 1. This strategy has not been experimented with or tested as
   // extensively as LEVENBERG_MARQUARDT, and therefore it should be
   // considered EXPERIMENTAL for now.
   //
   // 2. For now this strategy should only be used with exact
   // factorization based linear solvers, i.e., SPARSE_SCHUR,
   // DENSE_SCHUR, DENSE_QR and SPARSE_NORMAL_CHOLESKY.
   DOGLEG
 };

 // Ceres supports two different dogleg strategies.
 // The "traditional" dogleg method by Powell and the
 // "subspace" method described in
 // R. H. Byrd, R. B. Schnabel, and G. A. Shultz,
 // "Approximate solution of the trust region problem by minimization
 //  over two-dimensional subspaces", Mathematical Programming,
 // 40 (1988), pp. 247--263
 enum DoglegType {
   // The traditional approach constructs a dogleg path
   // consisting of two line segments and finds the furthest
   // point on that path that is still inside the trust region.
   TRADITIONAL_DOGLEG,

   // The subspace approach finds the exact minimum of the model
   // constrained to the subspace spanned by the dogleg path.
   SUBSPACE_DOGLEG
 };

 enum TerminationType {
   // Minimizer terminated because one of the convergence criterion set
   // by the user was satisfied.
   //
   // 1.  (new_cost - old_cost) < function_tolerance * old_cost;
   // 2.  max_i |gradient_i| < gradient_tolerance
   // 3.  |step|_2 <= parameter_tolerance * ( |x|_2 +  parameter_tolerance)
   //
   // The user's parameter blocks will be updated with the solution.
   CONVERGENCE,

   // The solver ran for maximum number of iterations or maximum amount
   // of time specified by the user, but none of the convergence
   // criterion specified by the user were met. The user's parameter
   // blocks will be updated with the solution found so far.
   NO_CONVERGENCE,

   // The minimizer terminated because of an error.  The user's
   // parameter blocks will not be updated.
   FAILURE,

   // Using an IterationCallback object, user code can control the
   // minimizer. The following enums indicate that the user code was
   // responsible for termination.
   //
   // Minimizer terminated successfully because a user
   // IterationCallback returned SOLVER_TERMINATE_SUCCESSFULLY.
   //
   // The user's parameter blocks will be updated with the solution.
   USER_SUCCESS,

   // Minimizer terminated because because a user IterationCallback
   // returned SOLVER_ABORT.
   //
   // The user's parameter blocks will not be updated.
   USER_FAILURE
 };

 // Enums used by the IterationCallback instances to indicate to the
 // solver whether it should continue solving, the user detected an
 // error or the solution is good enough and the solver should
 // terminate.
 enum CallbackReturnType {
   // Continue solving to next iteration.
   SOLVER_CONTINUE,

   // Terminate solver, and do not update the parameter blocks upon
   // return. Unless the user has set
   // Solver:Options:::update_state_every_iteration, in which case the
   // state would have been updated every iteration
   // anyways. Solver::Summary::termination_type is set to USER_ABORT.
   SOLVER_ABORT,

   // Terminate solver, update state and
   // return. Solver::Summary::termination_type is set to USER_SUCCESS.
   SOLVER_TERMINATE_SUCCESSFULLY
 };

 // The format in which linear least squares problems should be logged
 // when Solver::Options::lsqp_iterations_to_dump is non-empty.
 enum DumpFormatType {
   // Print the linear least squares problem in a human readable format
   // to stderr. The Jacobian is printed as a dense matrix. The vectors
   // D, x and f are printed as dense vectors. This should only be used
   // for small problems.
   CONSOLE,

   // Write out the linear least squares problem to the directory
   // pointed to by Solver::Options::lsqp_dump_directory as text files
   // which can be read into MATLAB/Octave. The Jacobian is dumped as a
   // text file containing (i,j,s) triplets, the vectors D, x and f are
   // dumped as text files containing a list of their values.
   //
   // A MATLAB/octave script called lm_iteration_???.m is also output,
   // which can be used to parse and load the problem into memory.
   TEXTFILE
 };

 // For SizedCostFunction and AutoDiffCostFunction, DYNAMIC can be
 // specified for the number of residuals. If specified, then the
 // number of residuas for that cost function can vary at runtime.
 enum DimensionType {
   DYNAMIC = -1
 };

 enum NumericDiffMethod {
   CENTRAL,
   FORWARD
 };

 enum LineSearchInterpolationType {
   BISECTION,
   QUADRATIC,
   CUBIC
 };

 enum CovarianceAlgorithmType {
   DENSE_SVD,
   SUITE_SPARSE_QR,
   EIGEN_SPARSE_QR
 };

 CERES_EXPORT const char* LinearSolverTypeToString(
     LinearSolverType type);
 CERES_EXPORT bool StringToLinearSolverType(string value,
                                            LinearSolverType* type);

 CERES_EXPORT const char* PreconditionerTypeToString(PreconditionerType type);
 CERES_EXPORT bool StringToPreconditionerType(string value,
                                              PreconditionerType* type);

 CERES_EXPORT const char* VisibilityClusteringTypeToString(
     VisibilityClusteringType type);
 CERES_EXPORT bool StringToVisibilityClusteringType(string value,
                                       VisibilityClusteringType* type);

 CERES_EXPORT const char* SparseLinearAlgebraLibraryTypeToString(
     SparseLinearAlgebraLibraryType type);
 CERES_EXPORT bool StringToSparseLinearAlgebraLibraryType(
     string value,
     SparseLinearAlgebraLibraryType* type);

 CERES_EXPORT const char* DenseLinearAlgebraLibraryTypeToString(
     DenseLinearAlgebraLibraryType type);
 CERES_EXPORT bool StringToDenseLinearAlgebraLibraryType(
     string value,
     DenseLinearAlgebraLibraryType* type);

 CERES_EXPORT const char* TrustRegionStrategyTypeToString(
     TrustRegionStrategyType type);
 CERES_EXPORT bool StringToTrustRegionStrategyType(string value,
                                      TrustRegionStrategyType* type);

 CERES_EXPORT const char* DoglegTypeToString(DoglegType type);
 CERES_EXPORT bool StringToDoglegType(string value, DoglegType* type);

 CERES_EXPORT const char* MinimizerTypeToString(MinimizerType type);
 CERES_EXPORT bool StringToMinimizerType(string value, MinimizerType* type);

 CERES_EXPORT const char* LineSearchDirectionTypeToString(
     LineSearchDirectionType type);
 CERES_EXPORT bool StringToLineSearchDirectionType(string value,
                                      LineSearchDirectionType* type);

 CERES_EXPORT const char* LineSearchTypeToString(LineSearchType type);
 CERES_EXPORT bool StringToLineSearchType(string value, LineSearchType* type);

 CERES_EXPORT const char* NonlinearConjugateGradientTypeToString(
     NonlinearConjugateGradientType type);
 CERES_EXPORT bool StringToNonlinearConjugateGradientType(
     string value,
     NonlinearConjugateGradientType* type);

 CERES_EXPORT const char* LineSearchInterpolationTypeToString(
     LineSearchInterpolationType type);
 CERES_EXPORT bool StringToLineSearchInterpolationType(
     string value,
     LineSearchInterpolationType* type);

 CERES_EXPORT const char* CovarianceAlgorithmTypeToString(
     CovarianceAlgorithmType type);
 CERES_EXPORT bool StringToCovarianceAlgorithmType(
     string value,
     CovarianceAlgorithmType* type);

 CERES_EXPORT const char* TerminationTypeToString(TerminationType type);

 CERES_EXPORT bool IsSchurType(LinearSolverType type);
 CERES_EXPORT bool IsSparseLinearAlgebraLibraryTypeAvailable(
     SparseLinearAlgebraLibraryType type);
 CERES_EXPORT bool IsDenseLinearAlgebraLibraryTypeAvailable(
     DenseLinearAlgebraLibraryType type);

 }  // namespace ceres

 #include "ceres/internal/reenable_warnings.h"

 #endif  // CERES_PUBLIC_TYPES_H_
	// Ceres Solver - A fast non-linear least squares minimizer
	// Copyright 2010, 2011, 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)
	//
	// Enums and other top level class definitions.
	//
	// Note: internal/types.cc defines stringification routines for some
	// of these enums. Please update those routines if you extend or
	// remove enums from here.

	#ifndef CERES_PUBLIC_TYPES_H_
	#define CERES_PUBLIC_TYPES_H_

	#include <string>

	#include "ceres/internal/port.h"
	#include "ceres/internal/disable_warnings.h"

	namespace ceres {

	// Basic integer types. These typedefs are in the Ceres namespace to avoid
	// conflicts with other packages having similar typedefs.
	typedef int int32;

	// Argument type used in interfaces that can optionally take ownership
	// of a passed in argument. If TAKE_OWNERSHIP is passed, the called
	// object takes ownership of the pointer argument, and will call
	// delete on it upon completion.
	enum Ownership {
	DO_NOT_TAKE_OWNERSHIP,
	TAKE_OWNERSHIP
	};

	// TODO(keir): Considerably expand the explanations of each solver type.
	enum LinearSolverType {
	// These solvers are for general rectangular systems formed from the
	// normal equations A'A x = A'b. They are direct solvers and do not
	// assume any special problem structure.

	// Solve the normal equations using a dense Cholesky solver; based
	// on Eigen.
	DENSE_NORMAL_CHOLESKY,

	// Solve the normal equations using a dense QR solver; based on
	// Eigen.
	DENSE_QR,

	// Solve the normal equations using a sparse cholesky solver; requires
	// SuiteSparse or CXSparse.
	SPARSE_NORMAL_CHOLESKY,

	// Specialized solvers, specific to problems with a generalized
	// bi-partitite structure.

	// Solves the reduced linear system using a dense Cholesky solver;
	// based on Eigen.
	DENSE_SCHUR,

	// Solves the reduced linear system using a sparse Cholesky solver;
	// based on CHOLMOD.
	SPARSE_SCHUR,

	// Solves the reduced linear system using Conjugate Gradients, based
	// on a new Ceres implementation. Suitable for large scale
	// problems.
	ITERATIVE_SCHUR,

	// Conjugate gradients on the normal equations.
	CGNR
	};

	enum PreconditionerType {
	// Trivial preconditioner - the identity matrix.
	IDENTITY,

	// Block diagonal of the Gauss-Newton Hessian.
	JACOBI,

	// Note: The following three preconditioners can only be used with
	// the ITERATIVE_SCHUR solver. They are well suited for Structure
	// from Motion problems.

	// Block diagonal of the Schur complement. This preconditioner may
	// only be used with the ITERATIVE_SCHUR solver.
	SCHUR_JACOBI,

	// Visibility clustering based preconditioners.
	//
	// The following two preconditioners use the visibility structure of
	// the scene to determine the sparsity structure of the
	// preconditioner. This is done using a clustering algorithm. The
	// available visibility clustering algorithms are described below.
	//
	// Note: Requires SuiteSparse.
	CLUSTER_JACOBI,
	CLUSTER_TRIDIAGONAL
	};

	enum VisibilityClusteringType {
	// Canonical views algorithm as described in
	//
	// "Scene Summarization for Online Image Collections", Ian Simon, Noah
	// Snavely, Steven M. Seitz, ICCV 2007.
	//
	// This clustering algorithm can be quite slow, but gives high
	// quality clusters. The original visibility based clustering paper
	// used this algorithm.
	CANONICAL_VIEWS,

	// The classic single linkage algorithm. It is extremely fast as
	// compared to CANONICAL_VIEWS, but can give slightly poorer
	// results. For problems with large number of cameras though, this
	// is generally a pretty good option.
	//
	// If you are using SCHUR_JACOBI preconditioner and have SuiteSparse
	// available, CLUSTER_JACOBI and CLUSTER_TRIDIAGONAL in combination
	// with the SINGLE_LINKAGE algorithm will generally give better
	// results.
	SINGLE_LINKAGE
	};

	enum SparseLinearAlgebraLibraryType {
	// High performance sparse Cholesky factorization and approximate
	// minimum degree ordering.
	SUITE_SPARSE,

	// A lightweight replacment for SuiteSparse, which does not require
	// a LAPACK/BLAS implementation. Consequently, its performance is
	// also a bit lower than SuiteSparse.
	CX_SPARSE,

	// Eigen's sparse linear algebra routines. In particular Ceres uses
	// the Simplicial LDLT routines.
	EIGEN_SPARSE
	};

	enum DenseLinearAlgebraLibraryType {
	EIGEN,
	LAPACK
	};

	// Logging options
	// The options get progressively noisier.
	enum LoggingType {
	SILENT,
	PER_MINIMIZER_ITERATION
	};

	enum MinimizerType {
	LINE_SEARCH,
	TRUST_REGION
	};

	enum LineSearchDirectionType {
	// Negative of the gradient.
	STEEPEST_DESCENT,

	// A generalization of the Conjugate Gradient method to non-linear
	// functions. The generalization can be performed in a number of
	// different ways, resulting in a variety of search directions. The
	// precise choice of the non-linear conjugate gradient algorithm
	// used is determined by NonlinerConjuateGradientType.
	NONLINEAR_CONJUGATE_GRADIENT,

	// BFGS, and it's limited memory approximation L-BFGS, are quasi-Newton
	// algorithms that approximate the Hessian matrix by iteratively refining
	// an initial estimate with rank-one updates using the gradient at each
	// iteration. They are a generalisation of the Secant method and satisfy
	// the Secant equation. The Secant equation has an infinium of solutions
	// in multiple dimensions, as there are N*(N+1)/2 degrees of freedom in a
	// symmetric matrix but only N conditions are specified by the Secant
	// equation. The requirement that the Hessian approximation be positive
	// definite imposes another N additional constraints, but that still leaves
	// remaining degrees-of-freedom. (L)BFGS methods uniquely deteremine the
	// approximate Hessian by imposing the additional constraints that the
	// approximation at the next iteration must be the 'closest' to the current
	// approximation (the nature of how this proximity is measured is actually
	// the defining difference between a family of quasi-Newton methods including
	// (L)BFGS & DFP). (L)BFGS is currently regarded as being the best known
	// general quasi-Newton method.
	//
	// The principal difference between BFGS and L-BFGS is that whilst BFGS
	// maintains a full, dense approximation to the (inverse) Hessian, L-BFGS
	// maintains only a window of the last M observations of the parameters and
	// gradients. Using this observation history, the calculation of the next
	// search direction can be computed without requiring the construction of the
	// full dense inverse Hessian approximation. This is particularly important
	// for problems with a large number of parameters, where storage of an N-by-N
	// matrix in memory would be prohibitive.
	//
	// For more details on BFGS see:
	//
	// Broyden, C.G., "The Convergence of a Class of Double-rank Minimization
	// Algorithms,"; J. Inst. Maths. Applics., Vol. 6, pp 76–90, 1970.
	//
	// Fletcher, R., "A New Approach to Variable Metric Algorithms,"
	// Computer Journal, Vol. 13, pp 317–322, 1970.
	//
	// Goldfarb, D., "A Family of Variable Metric Updates Derived by Variational
	// Means," Mathematics of Computing, Vol. 24, pp 23–26, 1970.
	//
	// Shanno, D.F., "Conditioning of Quasi-Newton Methods for Function
	// Minimization," Mathematics of Computing, Vol. 24, pp 647–656, 1970.
	//
	// For more details on L-BFGS see:
	//
	// Nocedal, J. (1980). "Updating Quasi-Newton Matrices with Limited
	// Storage". Mathematics of Computation 35 (151): 773–782.
	//
	// Byrd, R. H.; Nocedal, J.; Schnabel, R. B. (1994).
	// "Representations of Quasi-Newton Matrices and their use in
	// Limited Memory Methods". Mathematical Programming 63 (4):
	// 129–156.
	//
	// A general reference for both methods:
	//
	// Nocedal J., Wright S., Numerical Optimization, 2nd Ed. Springer, 1999.
	LBFGS,
	BFGS,
	};

	// Nonliner conjugate gradient methods are a generalization of the
	// method of Conjugate Gradients for linear systems. The
	// generalization can be carried out in a number of different ways
	// leading to number of different rules for computing the search
	// direction. Ceres provides a number of different variants. For more
	// details see Numerical Optimization by Nocedal & Wright.
	enum NonlinearConjugateGradientType {
	FLETCHER_REEVES,
	POLAK_RIBIERE,
	HESTENES_STIEFEL,
	};

	enum LineSearchType {
	// Backtracking line search with polynomial interpolation or
	// bisection.
	ARMIJO,
	WOLFE,
	};

	// Ceres supports different strategies for computing the trust region
	// step.
	enum TrustRegionStrategyType {
	// The default trust region strategy is to use the step computation
	// used in the Levenberg-Marquardt algorithm. For more details see
	// levenberg_marquardt_strategy.h
	LEVENBERG_MARQUARDT,

	// Powell's dogleg algorithm interpolates between the Cauchy point
	// and the Gauss-Newton step. It is particularly useful if the
	// LEVENBERG_MARQUARDT algorithm is making a large number of
	// unsuccessful steps. For more details see dogleg_strategy.h.
	//
	// NOTES:
	//
	// 1. This strategy has not been experimented with or tested as
	// extensively as LEVENBERG_MARQUARDT, and therefore it should be
	// considered EXPERIMENTAL for now.
	//
	// 2. For now this strategy should only be used with exact
	// factorization based linear solvers, i.e., SPARSE_SCHUR,
	// DENSE_SCHUR, DENSE_QR and SPARSE_NORMAL_CHOLESKY.
	DOGLEG
	};

	// Ceres supports two different dogleg strategies.
	// The "traditional" dogleg method by Powell and the
	// "subspace" method described in
	// R. H. Byrd, R. B. Schnabel, and G. A. Shultz,
	// "Approximate solution of the trust region problem by minimization
	// over two-dimensional subspaces", Mathematical Programming,
	// 40 (1988), pp. 247--263
	enum DoglegType {
	// The traditional approach constructs a dogleg path
	// consisting of two line segments and finds the furthest
	// point on that path that is still inside the trust region.
	TRADITIONAL_DOGLEG,

	// The subspace approach finds the exact minimum of the model
	// constrained to the subspace spanned by the dogleg path.
	SUBSPACE_DOGLEG
	};

	enum TerminationType {
	// Minimizer terminated because one of the convergence criterion set
	// by the user was satisfied.
	//
	// 1. (new_cost - old_cost) < function_tolerance * old_cost;
	// 2. max_i \|gradient_i\| < gradient_tolerance
	// 3. \|step\|_2 <= parameter_tolerance * ( \|x\|_2 + parameter_tolerance)
	//
	// The user's parameter blocks will be updated with the solution.
	CONVERGENCE,

	// The solver ran for maximum number of iterations or maximum amount
	// of time specified by the user, but none of the convergence
	// criterion specified by the user were met. The user's parameter
	// blocks will be updated with the solution found so far.
	NO_CONVERGENCE,

	// The minimizer terminated because of an error. The user's
	// parameter blocks will not be updated.
	FAILURE,

	// Using an IterationCallback object, user code can control the
	// minimizer. The following enums indicate that the user code was
	// responsible for termination.
	//
	// Minimizer terminated successfully because a user
	// IterationCallback returned SOLVER_TERMINATE_SUCCESSFULLY.
	//
	// The user's parameter blocks will be updated with the solution.
	USER_SUCCESS,

	// Minimizer terminated because because a user IterationCallback
	// returned SOLVER_ABORT.
	//
	// The user's parameter blocks will not be updated.
	USER_FAILURE
	};

	// Enums used by the IterationCallback instances to indicate to the
	// solver whether it should continue solving, the user detected an
	// error or the solution is good enough and the solver should
	// terminate.
	enum CallbackReturnType {
	// Continue solving to next iteration.
	SOLVER_CONTINUE,

	// Terminate solver, and do not update the parameter blocks upon
	// return. Unless the user has set
	// Solver:Options:::update_state_every_iteration, in which case the
	// state would have been updated every iteration
	// anyways. Solver::Summary::termination_type is set to USER_ABORT.
	SOLVER_ABORT,

	// Terminate solver, update state and
	// return. Solver::Summary::termination_type is set to USER_SUCCESS.
	SOLVER_TERMINATE_SUCCESSFULLY
	};

	// The format in which linear least squares problems should be logged
	// when Solver::Options::lsqp_iterations_to_dump is non-empty.
	enum DumpFormatType {
	// Print the linear least squares problem in a human readable format
	// to stderr. The Jacobian is printed as a dense matrix. The vectors
	// D, x and f are printed as dense vectors. This should only be used
	// for small problems.
	CONSOLE,

	// Write out the linear least squares problem to the directory
	// pointed to by Solver::Options::lsqp_dump_directory as text files
	// which can be read into MATLAB/Octave. The Jacobian is dumped as a
	// text file containing (i,j,s) triplets, the vectors D, x and f are
	// dumped as text files containing a list of their values.
	//
	// A MATLAB/octave script called lm_iteration_???.m is also output,
	// which can be used to parse and load the problem into memory.
	TEXTFILE
	};

	// For SizedCostFunction and AutoDiffCostFunction, DYNAMIC can be
	// specified for the number of residuals. If specified, then the
	// number of residuas for that cost function can vary at runtime.
	enum DimensionType {
	DYNAMIC = -1
	};

	enum NumericDiffMethod {
	CENTRAL,
	FORWARD
	};

	enum LineSearchInterpolationType {
	BISECTION,
	QUADRATIC,
	CUBIC
	};

	enum CovarianceAlgorithmType {
	DENSE_SVD,
	SUITE_SPARSE_QR,
	EIGEN_SPARSE_QR
	};

	CERES_EXPORT const char* LinearSolverTypeToString(
	LinearSolverType type);
	CERES_EXPORT bool StringToLinearSolverType(string value,
	LinearSolverType* type);

	CERES_EXPORT const char* PreconditionerTypeToString(PreconditionerType type);
	CERES_EXPORT bool StringToPreconditionerType(string value,
	PreconditionerType* type);

	CERES_EXPORT const char* VisibilityClusteringTypeToString(
	VisibilityClusteringType type);
	CERES_EXPORT bool StringToVisibilityClusteringType(string value,
	VisibilityClusteringType* type);

	CERES_EXPORT const char* SparseLinearAlgebraLibraryTypeToString(
	SparseLinearAlgebraLibraryType type);
	CERES_EXPORT bool StringToSparseLinearAlgebraLibraryType(
	string value,
	SparseLinearAlgebraLibraryType* type);

	CERES_EXPORT const char* DenseLinearAlgebraLibraryTypeToString(
	DenseLinearAlgebraLibraryType type);
	CERES_EXPORT bool StringToDenseLinearAlgebraLibraryType(
	string value,
	DenseLinearAlgebraLibraryType* type);

	CERES_EXPORT const char* TrustRegionStrategyTypeToString(
	TrustRegionStrategyType type);
	CERES_EXPORT bool StringToTrustRegionStrategyType(string value,
	TrustRegionStrategyType* type);

	CERES_EXPORT const char* DoglegTypeToString(DoglegType type);
	CERES_EXPORT bool StringToDoglegType(string value, DoglegType* type);

	CERES_EXPORT const char* MinimizerTypeToString(MinimizerType type);
	CERES_EXPORT bool StringToMinimizerType(string value, MinimizerType* type);

	CERES_EXPORT const char* LineSearchDirectionTypeToString(
	LineSearchDirectionType type);
	CERES_EXPORT bool StringToLineSearchDirectionType(string value,
	LineSearchDirectionType* type);

	CERES_EXPORT const char* LineSearchTypeToString(LineSearchType type);
	CERES_EXPORT bool StringToLineSearchType(string value, LineSearchType* type);

	CERES_EXPORT const char* NonlinearConjugateGradientTypeToString(
	NonlinearConjugateGradientType type);
	CERES_EXPORT bool StringToNonlinearConjugateGradientType(
	string value,
	NonlinearConjugateGradientType* type);

	CERES_EXPORT const char* LineSearchInterpolationTypeToString(
	LineSearchInterpolationType type);
	CERES_EXPORT bool StringToLineSearchInterpolationType(
	string value,
	LineSearchInterpolationType* type);

	CERES_EXPORT const char* CovarianceAlgorithmTypeToString(
	CovarianceAlgorithmType type);
	CERES_EXPORT bool StringToCovarianceAlgorithmType(
	string value,
	CovarianceAlgorithmType* type);

	CERES_EXPORT const char* TerminationTypeToString(TerminationType type);

	CERES_EXPORT bool IsSchurType(LinearSolverType type);
	CERES_EXPORT bool IsSparseLinearAlgebraLibraryTypeAvailable(
	SparseLinearAlgebraLibraryType type);
	CERES_EXPORT bool IsDenseLinearAlgebraLibraryTypeAvailable(
	DenseLinearAlgebraLibraryType type);

	} // namespace ceres

	#include "ceres/internal/reenable_warnings.h"

	#endif // CERES_PUBLIC_TYPES_H_