examples/more_garbow_hillstrom.cc - ceres-solver - Git at Google

 // Ceres Solver - A fast non-linear least squares minimizer
 // Copyright 2014 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)
 //
 // Bounds constrained test problems from the paper
 //
 // Testing Unconstrained Optimization Software
 // Jorge J. More, Burton S. Garbow and Kenneth E. Hillstrom
 // ACM Transactions on Mathematical Software, 7(1), pp. 17-41, 1981
 //
 // A subset of these problems were augmented with bounds and used for
 // testing bounds constrained optimization algorithms by
 //
 // A Trust Region Approach to Linearly Constrained Optimization
 // David M. Gay
 // Numerical Analysis (Griffiths, D.F., ed.), pp. 72-105
 // Lecture Notes in Mathematics 1066, Springer Verlag, 1984.
 //
 // The latter paper is behind a paywall. We obtained the bounds on the
 // variables and the function values at the global minimums from
 //
 // http://www.mat.univie.ac.at/~neum/glopt/bounds.html
 //
 // A problem is considered solved if of the log relative error of its
 // objective function is at least 5.


 #include <cmath>
 #include <iostream>  // NOLINT
 #include "ceres/ceres.h"
 #include "gflags/gflags.h"
 #include "glog/logging.h"

 namespace ceres {
 namespace examples {

 const double kDoubleMax = std::numeric_limits<double>::max();

 #define BEGIN_MGH_PROBLEM(name, num_parameters, num_residuals)          \
   struct name {                                                         \
     static const int kNumParameters = num_parameters;                   \
     static const double initial_x[kNumParameters];                      \
     static const double lower_bounds[kNumParameters];                   \
     static const double upper_bounds[kNumParameters];                   \
     static const double constrained_optimal_cost;                       \
     static const double unconstrained_optimal_cost;                     \
     static CostFunction* Create() {                                     \
       return new AutoDiffCostFunction<name,                             \
                                       num_residuals,                    \
                                       num_parameters>(new name);        \
     }                                                                   \
     template <typename T>                                               \
     bool operator()(const T* const x, T* residual) const {

 #define END_MGH_PROBLEM return true; } };  // NOLINT

 // Rosenbrock function.
 BEGIN_MGH_PROBLEM(TestProblem1, 2, 2)
   const T x1 = x[0];
   const T x2 = x[1];
   residual[0] = T(10.0) * (x2 - x1 * x1);
   residual[1] = T(1.0) - x1;
 END_MGH_PROBLEM;

 const double TestProblem1::initial_x[] = {-1.2, 1.0};
 const double TestProblem1::lower_bounds[] = {-kDoubleMax, -kDoubleMax};
 const double TestProblem1::upper_bounds[] = {kDoubleMax, kDoubleMax};
 const double TestProblem1::constrained_optimal_cost =
     std::numeric_limits<double>::quiet_NaN();
 const double TestProblem1::unconstrained_optimal_cost = 0.0;

 // Freudenstein and Roth function.
 BEGIN_MGH_PROBLEM(TestProblem2, 2, 2)
   const T x1 = x[0];
   const T x2 = x[1];
   residual[0] = T(-13.0) + x1 + ((T(5.0) - x2) * x2 - T(2.0)) * x2;
   residual[1] = T(-29.0) + x1 + ((x2 + T(1.0)) * x2 - T(14.0)) * x2;
 END_MGH_PROBLEM;

 const double TestProblem2::initial_x[] = {0.5, -2.0};
 const double TestProblem2::lower_bounds[] = {-kDoubleMax, -kDoubleMax};
 const double TestProblem2::upper_bounds[] = {kDoubleMax, kDoubleMax};
 const double TestProblem2::constrained_optimal_cost =
     std::numeric_limits<double>::quiet_NaN();
 const double TestProblem2::unconstrained_optimal_cost = 0.0;

 // Powell badly scaled function.
 BEGIN_MGH_PROBLEM(TestProblem3, 2, 2)
   const T x1 = x[0];
   const T x2 = x[1];
   residual[0] = T(10000.0) * x1 * x2 - T(1.0);
   residual[1] = exp(-x1) + exp(-x2) - T(1.0001);
 END_MGH_PROBLEM;

 const double TestProblem3::initial_x[] = {0.0, 1.0};
 const double TestProblem3::lower_bounds[] = {0.0, 1.0};
 const double TestProblem3::upper_bounds[] = {1.0, 9.0};
 const double TestProblem3::constrained_optimal_cost = 0.15125900e-9;
 const double TestProblem3::unconstrained_optimal_cost = 0.0;

 // Brown badly scaled function.
 BEGIN_MGH_PROBLEM(TestProblem4, 2, 3)
   const T x1 = x[0];
   const T x2 = x[1];
   residual[0] = x1  - T(1000000.0);
   residual[1] = x2 - T(0.000002);
   residual[2] = x1 * x2 - T(2.0);
 END_MGH_PROBLEM;

 const double TestProblem4::initial_x[] = {1.0, 1.0};
 const double TestProblem4::lower_bounds[] = {0.0, 0.00003};
 const double TestProblem4::upper_bounds[] = {1000000.0, 100.0};
 const double TestProblem4::constrained_optimal_cost = 0.78400000e3;
 const double TestProblem4::unconstrained_optimal_cost = 0.0;

 // Beale function.
 BEGIN_MGH_PROBLEM(TestProblem5, 2, 3)
   const T x1 = x[0];
   const T x2 = x[1];
   residual[0] = T(1.5) - x1 * (T(1.0) - x2);
   residual[1] = T(2.25) - x1 * (T(1.0) - x2 * x2);
   residual[2] = T(2.625) - x1 * (T(1.0) - x2 * x2 * x2);
 END_MGH_PROBLEM;

 const double TestProblem5::initial_x[] = {1.0, 1.0};
 const double TestProblem5::lower_bounds[] = {0.6, 0.5};
 const double TestProblem5::upper_bounds[] = {10.0, 100.0};
 const double TestProblem5::constrained_optimal_cost = 0.0;
 const double TestProblem5::unconstrained_optimal_cost = 0.0;

 // Jennrich and Sampson function.
 BEGIN_MGH_PROBLEM(TestProblem6, 2, 10)
   const T x1 = x[0];
   const T x2 = x[1];
   for (int i = 1; i <= 10; ++i) {
     residual[i - 1] = T(2.0) + T(2.0 * i) -
         exp(T(static_cast<double>(i)) * x1) -
         exp(T(static_cast<double>(i) * x2));
   }
 END_MGH_PROBLEM;

 const double TestProblem6::initial_x[] = {1.0, 1.0};
 const double TestProblem6::lower_bounds[] = {-kDoubleMax, -kDoubleMax};
 const double TestProblem6::upper_bounds[] = {kDoubleMax, kDoubleMax};
 const double TestProblem6::constrained_optimal_cost =
     std::numeric_limits<double>::quiet_NaN();
 const double TestProblem6::unconstrained_optimal_cost = 124.362;

 // Helical valley function.
 BEGIN_MGH_PROBLEM(TestProblem7, 3, 3)
   const T x1 = x[0];
   const T x2 = x[1];
   const T x3 = x[2];
   const T theta = T(0.5 / M_PI)  * atan(x2 / x1) + (x1 > 0.0 ? T(0.0) : T(0.5));

   residual[0] = T(10.0) * (x3 - T(10.0) * theta);
   residual[1] = T(10.0) * (sqrt(x1 * x1 + x2 * x2) - T(1.0));
   residual[2] = x3;
 END_MGH_PROBLEM;

 const double TestProblem7::initial_x[] = {-1.0, 0.0, 0.0};
 const double TestProblem7::lower_bounds[] = {-100.0, -1.0, -1.0};
 const double TestProblem7::upper_bounds[] = {0.8, 1.0, 1.0};
 const double TestProblem7::constrained_optimal_cost = 0.99042212;
 const double TestProblem7::unconstrained_optimal_cost = 0.0;

 // Bard function
 BEGIN_MGH_PROBLEM(TestProblem8, 3, 15)
   const T x1 = x[0];
   const T x2 = x[1];
   const T x3 = x[2];

   double y[] = {0.14, 0.18, 0.22, 0.25,
                 0.29, 0.32, 0.35, 0.39, 0.37, 0.58,
                 0.73, 0.96, 1.34, 2.10, 4.39};

   for (int i = 1; i <=15; ++i) {
     const T u = T(static_cast<double>(i));
     const T v = T(static_cast<double>(16 - i));
     const T w = T(static_cast<double>(std::min(i, 16 - i)));
     residual[i - 1] = T(y[i - 1]) - x1 + u / (v * x2 + w * x3);
   }
 END_MGH_PROBLEM;

 const double TestProblem8::initial_x[] = {1.0, 1.0, 1.0};
 const double TestProblem8::lower_bounds[] = {
   -kDoubleMax, -kDoubleMax, -kDoubleMax};
 const double TestProblem8::upper_bounds[] = {
   kDoubleMax, kDoubleMax, kDoubleMax};
 const double TestProblem8::constrained_optimal_cost =
     std::numeric_limits<double>::quiet_NaN();
 const double TestProblem8::unconstrained_optimal_cost = 8.21487e-3;

 // Gaussian function.
 BEGIN_MGH_PROBLEM(TestProblem9, 3, 15)
   const T x1 = x[0];
   const T x2 = x[1];
   const T x3 = x[2];

   const double y[] = {0.0009, 0.0044, 0.0175, 0.0540, 0.1295, 0.2420, 0.3521,
                       0.3989,
                       0.3521, 0.2420, 0.1295, 0.0540, 0.0175, 0.0044, 0.0009};
   for (int i = 0; i < 15; ++i) {
     const T t_i = T((8.0 - i - 1.0) / 2.0);
     const T y_i = T(y[i]);
     residual[i] = x1 * exp(-x2 * (t_i - x3) * (t_i - x3) / T(2.0)) - y_i;
   }
 END_MGH_PROBLEM;

 const double TestProblem9::initial_x[] = {0.4, 1.0, 0.0};
 const double TestProblem9::lower_bounds[] = {0.398, 1.0, -0.5};
 const double TestProblem9::upper_bounds[] = {4.2, 2.0, 0.1};
 const double TestProblem9::constrained_optimal_cost = 0.11279300e-7;
 const double TestProblem9::unconstrained_optimal_cost = 0.112793e-7;

 // Meyer function.
 BEGIN_MGH_PROBLEM(TestProblem10, 3, 16)
   const T x1 = x[0];
   const T x2 = x[1];
   const T x3 = x[2];

   const double y[] = {34780, 28610, 23650, 19630, 16370, 13720, 11540, 9744,
                       8261, 7030, 6005, 5147, 4427, 3820, 3307, 2872};

   for (int i = 0; i < 16; ++i) {
     T t = T(45 + 5.0 * (i + 1));
     residual[i] = x1 * exp(x2 / (t + x3)) - y[i];
   }
 END_MGH_PROBLEM


 const double TestProblem10::initial_x[] = {0.02, 4000, 250};
 const double TestProblem10::lower_bounds[] ={
   -kDoubleMax, -kDoubleMax, -kDoubleMax};
 const double TestProblem10::upper_bounds[] ={
   kDoubleMax, kDoubleMax, kDoubleMax};
 const double TestProblem10::constrained_optimal_cost =
     std::numeric_limits<double>::quiet_NaN();
 const double TestProblem10::unconstrained_optimal_cost = 87.9458;

 #undef BEGIN_MGH_PROBLEM
 #undef END_MGH_PROBLEM

 template<typename TestProblem> string ConstrainedSolve() {
   double x[TestProblem::kNumParameters];
   std::copy(TestProblem::initial_x,
             TestProblem::initial_x + TestProblem::kNumParameters,
             x);

   Problem problem;
   problem.AddResidualBlock(TestProblem::Create(), NULL, x);
   for (int i = 0; i < TestProblem::kNumParameters; ++i) {
     problem.SetParameterLowerBound(x, i, TestProblem::lower_bounds[i]);
     problem.SetParameterUpperBound(x, i, TestProblem::upper_bounds[i]);
   }

   Solver::Options options;
   options.parameter_tolerance = 1e-18;
   options.function_tolerance = 1e-18;
   options.gradient_tolerance = 1e-18;
   options.max_num_iterations = 1000;
   options.linear_solver_type = DENSE_QR;
   Solver::Summary summary;
   Solve(options, &problem, &summary);

   const double kMinLogRelativeError = 5.0;
   const double log_relative_error = -std::log10(
       std::abs(2.0 * summary.final_cost -
                TestProblem::constrained_optimal_cost) /
       (TestProblem::constrained_optimal_cost > 0.0
        ? TestProblem::constrained_optimal_cost
        : 1.0));

   return (log_relative_error >= kMinLogRelativeError
           ? "Success\n"
           : "Failure\n");
 }

 template<typename TestProblem> string UnconstrainedSolve() {
   double x[TestProblem::kNumParameters];
   std::copy(TestProblem::initial_x,
             TestProblem::initial_x + TestProblem::kNumParameters,
             x);

   Problem problem;
   problem.AddResidualBlock(TestProblem::Create(), NULL, x);

   Solver::Options options;
   options.parameter_tolerance = 1e-18;
   options.function_tolerance = 0.0;
   options.gradient_tolerance = 1e-18;
   options.max_num_iterations = 1000;
   options.linear_solver_type = DENSE_QR;
   Solver::Summary summary;
   Solve(options, &problem, &summary);

   const double kMinLogRelativeError = 5.0;
   const double log_relative_error = -std::log10(
       std::abs(2.0 * summary.final_cost -
                TestProblem::unconstrained_optimal_cost) /
       (TestProblem::unconstrained_optimal_cost > 0.0
        ? TestProblem::unconstrained_optimal_cost
        : 1.0));

   return (log_relative_error >= kMinLogRelativeError
           ? "Success\n"
           : "Failure\n");
 }

 }  // namespace examples
 }  // namespace ceres

 int main(int argc, char** argv) {
   google::ParseCommandLineFlags(&argc, &argv, true);
   google::InitGoogleLogging(argv[0]);

   using ceres::examples::UnconstrainedSolve;
   using ceres::examples::ConstrainedSolve;

 #define UNCONSTRAINED_SOLVE(n)                                          \
   std::cout << "Problem " << n << " : "                                 \
             << UnconstrainedSolve<ceres::examples::TestProblem##n>();

 #define CONSTRAINED_SOLVE(n)                                            \
   std::cout << "Problem " << n << " : "                                 \
             << ConstrainedSolve<ceres::examples::TestProblem##n>();

   std::cout << "Unconstrained problems\n";
   UNCONSTRAINED_SOLVE(1);
   UNCONSTRAINED_SOLVE(2);
   UNCONSTRAINED_SOLVE(3);
   UNCONSTRAINED_SOLVE(4);
   UNCONSTRAINED_SOLVE(5);
   UNCONSTRAINED_SOLVE(6);
   UNCONSTRAINED_SOLVE(7);
   UNCONSTRAINED_SOLVE(8);
   UNCONSTRAINED_SOLVE(9);
   UNCONSTRAINED_SOLVE(10);

   std::cout << "\nConstrained problems\n";
   CONSTRAINED_SOLVE(3);
   CONSTRAINED_SOLVE(4);
   CONSTRAINED_SOLVE(5);
   CONSTRAINED_SOLVE(7);
   CONSTRAINED_SOLVE(9);

   return 0;
 }
	// Ceres Solver - A fast non-linear least squares minimizer
	// Copyright 2014 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)
	//
	// Bounds constrained test problems from the paper
	//
	// Testing Unconstrained Optimization Software
	// Jorge J. More, Burton S. Garbow and Kenneth E. Hillstrom
	// ACM Transactions on Mathematical Software, 7(1), pp. 17-41, 1981
	//
	// A subset of these problems were augmented with bounds and used for
	// testing bounds constrained optimization algorithms by
	//
	// A Trust Region Approach to Linearly Constrained Optimization
	// David M. Gay
	// Numerical Analysis (Griffiths, D.F., ed.), pp. 72-105
	// Lecture Notes in Mathematics 1066, Springer Verlag, 1984.
	//
	// The latter paper is behind a paywall. We obtained the bounds on the
	// variables and the function values at the global minimums from
	//
	// http://www.mat.univie.ac.at/~neum/glopt/bounds.html
	//
	// A problem is considered solved if of the log relative error of its
	// objective function is at least 5.


	#include <cmath>
	#include <iostream> // NOLINT
	#include "ceres/ceres.h"
	#include "gflags/gflags.h"
	#include "glog/logging.h"

	namespace ceres {
	namespace examples {

	const double kDoubleMax = std::numeric_limits<double>::max();

	#define BEGIN_MGH_PROBLEM(name, num_parameters, num_residuals) \
	struct name { \
	static const int kNumParameters = num_parameters; \
	static const double initial_x[kNumParameters]; \
	static const double lower_bounds[kNumParameters]; \
	static const double upper_bounds[kNumParameters]; \
	static const double constrained_optimal_cost; \
	static const double unconstrained_optimal_cost; \
	static CostFunction* Create() { \
	return new AutoDiffCostFunction<name, \
	num_residuals, \
	num_parameters>(new name); \
	} \
	template <typename T> \
	bool operator()(const T* const x, T* residual) const {

	#define END_MGH_PROBLEM return true; } }; // NOLINT

	// Rosenbrock function.
	BEGIN_MGH_PROBLEM(TestProblem1, 2, 2)
	const T x1 = x[0];
	const T x2 = x[1];
	residual[0] = T(10.0) * (x2 - x1 * x1);
	residual[1] = T(1.0) - x1;
	END_MGH_PROBLEM;

	const double TestProblem1::initial_x[] = {-1.2, 1.0};
	const double TestProblem1::lower_bounds[] = {-kDoubleMax, -kDoubleMax};
	const double TestProblem1::upper_bounds[] = {kDoubleMax, kDoubleMax};
	const double TestProblem1::constrained_optimal_cost =
	std::numeric_limits<double>::quiet_NaN();
	const double TestProblem1::unconstrained_optimal_cost = 0.0;

	// Freudenstein and Roth function.
	BEGIN_MGH_PROBLEM(TestProblem2, 2, 2)
	const T x1 = x[0];
	const T x2 = x[1];
	residual[0] = T(-13.0) + x1 + ((T(5.0) - x2) * x2 - T(2.0)) * x2;
	residual[1] = T(-29.0) + x1 + ((x2 + T(1.0)) * x2 - T(14.0)) * x2;
	END_MGH_PROBLEM;

	const double TestProblem2::initial_x[] = {0.5, -2.0};
	const double TestProblem2::lower_bounds[] = {-kDoubleMax, -kDoubleMax};
	const double TestProblem2::upper_bounds[] = {kDoubleMax, kDoubleMax};
	const double TestProblem2::constrained_optimal_cost =
	std::numeric_limits<double>::quiet_NaN();
	const double TestProblem2::unconstrained_optimal_cost = 0.0;

	// Powell badly scaled function.
	BEGIN_MGH_PROBLEM(TestProblem3, 2, 2)
	const T x1 = x[0];
	const T x2 = x[1];
	residual[0] = T(10000.0) * x1 * x2 - T(1.0);
	residual[1] = exp(-x1) + exp(-x2) - T(1.0001);
	END_MGH_PROBLEM;

	const double TestProblem3::initial_x[] = {0.0, 1.0};
	const double TestProblem3::lower_bounds[] = {0.0, 1.0};
	const double TestProblem3::upper_bounds[] = {1.0, 9.0};
	const double TestProblem3::constrained_optimal_cost = 0.15125900e-9;
	const double TestProblem3::unconstrained_optimal_cost = 0.0;

	// Brown badly scaled function.
	BEGIN_MGH_PROBLEM(TestProblem4, 2, 3)
	const T x1 = x[0];
	const T x2 = x[1];
	residual[0] = x1 - T(1000000.0);
	residual[1] = x2 - T(0.000002);
	residual[2] = x1 * x2 - T(2.0);
	END_MGH_PROBLEM;

	const double TestProblem4::initial_x[] = {1.0, 1.0};
	const double TestProblem4::lower_bounds[] = {0.0, 0.00003};
	const double TestProblem4::upper_bounds[] = {1000000.0, 100.0};
	const double TestProblem4::constrained_optimal_cost = 0.78400000e3;
	const double TestProblem4::unconstrained_optimal_cost = 0.0;

	// Beale function.
	BEGIN_MGH_PROBLEM(TestProblem5, 2, 3)
	const T x1 = x[0];
	const T x2 = x[1];
	residual[0] = T(1.5) - x1 * (T(1.0) - x2);
	residual[1] = T(2.25) - x1 * (T(1.0) - x2 * x2);
	residual[2] = T(2.625) - x1 * (T(1.0) - x2 * x2 * x2);
	END_MGH_PROBLEM;

	const double TestProblem5::initial_x[] = {1.0, 1.0};
	const double TestProblem5::lower_bounds[] = {0.6, 0.5};
	const double TestProblem5::upper_bounds[] = {10.0, 100.0};
	const double TestProblem5::constrained_optimal_cost = 0.0;
	const double TestProblem5::unconstrained_optimal_cost = 0.0;

	// Jennrich and Sampson function.
	BEGIN_MGH_PROBLEM(TestProblem6, 2, 10)
	const T x1 = x[0];
	const T x2 = x[1];
	for (int i = 1; i <= 10; ++i) {
	residual[i - 1] = T(2.0) + T(2.0 * i) -
	exp(T(static_cast<double>(i)) * x1) -
	exp(T(static_cast<double>(i) * x2));
	}
	END_MGH_PROBLEM;

	const double TestProblem6::initial_x[] = {1.0, 1.0};
	const double TestProblem6::lower_bounds[] = {-kDoubleMax, -kDoubleMax};
	const double TestProblem6::upper_bounds[] = {kDoubleMax, kDoubleMax};
	const double TestProblem6::constrained_optimal_cost =
	std::numeric_limits<double>::quiet_NaN();
	const double TestProblem6::unconstrained_optimal_cost = 124.362;

	// Helical valley function.
	BEGIN_MGH_PROBLEM(TestProblem7, 3, 3)
	const T x1 = x[0];
	const T x2 = x[1];
	const T x3 = x[2];
	const T theta = T(0.5 / M_PI) * atan(x2 / x1) + (x1 > 0.0 ? T(0.0) : T(0.5));

	residual[0] = T(10.0) * (x3 - T(10.0) * theta);
	residual[1] = T(10.0) * (sqrt(x1 * x1 + x2 * x2) - T(1.0));
	residual[2] = x3;
	END_MGH_PROBLEM;

	const double TestProblem7::initial_x[] = {-1.0, 0.0, 0.0};
	const double TestProblem7::lower_bounds[] = {-100.0, -1.0, -1.0};
	const double TestProblem7::upper_bounds[] = {0.8, 1.0, 1.0};
	const double TestProblem7::constrained_optimal_cost = 0.99042212;
	const double TestProblem7::unconstrained_optimal_cost = 0.0;

	// Bard function
	BEGIN_MGH_PROBLEM(TestProblem8, 3, 15)
	const T x1 = x[0];
	const T x2 = x[1];
	const T x3 = x[2];

	double y[] = {0.14, 0.18, 0.22, 0.25,
	0.29, 0.32, 0.35, 0.39, 0.37, 0.58,
	0.73, 0.96, 1.34, 2.10, 4.39};

	for (int i = 1; i <=15; ++i) {
	const T u = T(static_cast<double>(i));
	const T v = T(static_cast<double>(16 - i));
	const T w = T(static_cast<double>(std::min(i, 16 - i)));
	residual[i - 1] = T(y[i - 1]) - x1 + u / (v * x2 + w * x3);
	}
	END_MGH_PROBLEM;

	const double TestProblem8::initial_x[] = {1.0, 1.0, 1.0};
	const double TestProblem8::lower_bounds[] = {
	-kDoubleMax, -kDoubleMax, -kDoubleMax};
	const double TestProblem8::upper_bounds[] = {
	kDoubleMax, kDoubleMax, kDoubleMax};
	const double TestProblem8::constrained_optimal_cost =
	std::numeric_limits<double>::quiet_NaN();
	const double TestProblem8::unconstrained_optimal_cost = 8.21487e-3;

	// Gaussian function.
	BEGIN_MGH_PROBLEM(TestProblem9, 3, 15)
	const T x1 = x[0];
	const T x2 = x[1];
	const T x3 = x[2];

	const double y[] = {0.0009, 0.0044, 0.0175, 0.0540, 0.1295, 0.2420, 0.3521,
	0.3989,
	0.3521, 0.2420, 0.1295, 0.0540, 0.0175, 0.0044, 0.0009};
	for (int i = 0; i < 15; ++i) {
	const T t_i = T((8.0 - i - 1.0) / 2.0);
	const T y_i = T(y[i]);
	residual[i] = x1 * exp(-x2 * (t_i - x3) * (t_i - x3) / T(2.0)) - y_i;
	}
	END_MGH_PROBLEM;

	const double TestProblem9::initial_x[] = {0.4, 1.0, 0.0};
	const double TestProblem9::lower_bounds[] = {0.398, 1.0, -0.5};
	const double TestProblem9::upper_bounds[] = {4.2, 2.0, 0.1};
	const double TestProblem9::constrained_optimal_cost = 0.11279300e-7;
	const double TestProblem9::unconstrained_optimal_cost = 0.112793e-7;

	// Meyer function.
	BEGIN_MGH_PROBLEM(TestProblem10, 3, 16)
	const T x1 = x[0];
	const T x2 = x[1];
	const T x3 = x[2];

	const double y[] = {34780, 28610, 23650, 19630, 16370, 13720, 11540, 9744,
	8261, 7030, 6005, 5147, 4427, 3820, 3307, 2872};

	for (int i = 0; i < 16; ++i) {
	T t = T(45 + 5.0 * (i + 1));
	residual[i] = x1 * exp(x2 / (t + x3)) - y[i];
	}
	END_MGH_PROBLEM


	const double TestProblem10::initial_x[] = {0.02, 4000, 250};
	const double TestProblem10::lower_bounds[] ={
	-kDoubleMax, -kDoubleMax, -kDoubleMax};
	const double TestProblem10::upper_bounds[] ={
	kDoubleMax, kDoubleMax, kDoubleMax};
	const double TestProblem10::constrained_optimal_cost =
	std::numeric_limits<double>::quiet_NaN();
	const double TestProblem10::unconstrained_optimal_cost = 87.9458;

	#undef BEGIN_MGH_PROBLEM
	#undef END_MGH_PROBLEM

	template<typename TestProblem> string ConstrainedSolve() {
	double x[TestProblem::kNumParameters];
	std::copy(TestProblem::initial_x,
	TestProblem::initial_x + TestProblem::kNumParameters,
	x);

	Problem problem;
	problem.AddResidualBlock(TestProblem::Create(), NULL, x);
	for (int i = 0; i < TestProblem::kNumParameters; ++i) {
	problem.SetParameterLowerBound(x, i, TestProblem::lower_bounds[i]);
	problem.SetParameterUpperBound(x, i, TestProblem::upper_bounds[i]);
	}

	Solver::Options options;
	options.parameter_tolerance = 1e-18;
	options.function_tolerance = 1e-18;
	options.gradient_tolerance = 1e-18;
	options.max_num_iterations = 1000;
	options.linear_solver_type = DENSE_QR;
	Solver::Summary summary;
	Solve(options, &problem, &summary);

	const double kMinLogRelativeError = 5.0;
	const double log_relative_error = -std::log10(
	std::abs(2.0 * summary.final_cost -
	TestProblem::constrained_optimal_cost) /
	(TestProblem::constrained_optimal_cost > 0.0
	? TestProblem::constrained_optimal_cost
	: 1.0));

	return (log_relative_error >= kMinLogRelativeError
	? "Success\n"
	: "Failure\n");
	}

	template<typename TestProblem> string UnconstrainedSolve() {
	double x[TestProblem::kNumParameters];
	std::copy(TestProblem::initial_x,
	TestProblem::initial_x + TestProblem::kNumParameters,
	x);

	Problem problem;
	problem.AddResidualBlock(TestProblem::Create(), NULL, x);

	Solver::Options options;
	options.parameter_tolerance = 1e-18;
	options.function_tolerance = 0.0;
	options.gradient_tolerance = 1e-18;
	options.max_num_iterations = 1000;
	options.linear_solver_type = DENSE_QR;
	Solver::Summary summary;
	Solve(options, &problem, &summary);

	const double kMinLogRelativeError = 5.0;
	const double log_relative_error = -std::log10(
	std::abs(2.0 * summary.final_cost -
	TestProblem::unconstrained_optimal_cost) /
	(TestProblem::unconstrained_optimal_cost > 0.0
	? TestProblem::unconstrained_optimal_cost
	: 1.0));

	return (log_relative_error >= kMinLogRelativeError
	? "Success\n"
	: "Failure\n");
	}

	} // namespace examples
	} // namespace ceres

	int main(int argc, char** argv) {
	google::ParseCommandLineFlags(&argc, &argv, true);
	google::InitGoogleLogging(argv[0]);

	using ceres::examples::UnconstrainedSolve;
	using ceres::examples::ConstrainedSolve;

	#define UNCONSTRAINED_SOLVE(n) \
	std::cout << "Problem " << n << " : " \
	<< UnconstrainedSolve<ceres::examples::TestProblem##n>();

	#define CONSTRAINED_SOLVE(n) \
	std::cout << "Problem " << n << " : " \
	<< ConstrainedSolve<ceres::examples::TestProblem##n>();

	std::cout << "Unconstrained problems\n";
	UNCONSTRAINED_SOLVE(1);
	UNCONSTRAINED_SOLVE(2);
	UNCONSTRAINED_SOLVE(3);
	UNCONSTRAINED_SOLVE(4);
	UNCONSTRAINED_SOLVE(5);
	UNCONSTRAINED_SOLVE(6);
	UNCONSTRAINED_SOLVE(7);
	UNCONSTRAINED_SOLVE(8);
	UNCONSTRAINED_SOLVE(9);
	UNCONSTRAINED_SOLVE(10);

	std::cout << "\nConstrained problems\n";
	CONSTRAINED_SOLVE(3);
	CONSTRAINED_SOLVE(4);
	CONSTRAINED_SOLVE(5);
	CONSTRAINED_SOLVE(7);
	CONSTRAINED_SOLVE(9);

	return 0;
	}