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

 // Ceres Solver - A fast non-linear least squares minimizer
 // Copyright 2022 Google Inc. All rights reserved.
 // http://ceres-solver.org/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are met:
 //
 // * Redistributions of source code must retain the above copyright notice,
 //   this list of conditions and the following disclaimer.
 // * Redistributions in binary form must reproduce the above copyright notice,
 //   this list of conditions and the following disclaimer in the documentation
 //   and/or other materials provided with the distribution.
 // * Neither the name of Google Inc. nor the names of its contributors may be
 //   used to endorse or promote products derived from this software without
 //   specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 // POSSIBILITY OF SUCH DAMAGE.
 //
 // Author: jodebo_beck@gmx.de (Johannes Beck)
 //

 #ifndef CERES_PUBLIC_LINE_MANIFOLD_H_
 #define CERES_PUBLIC_LINE_MANIFOLD_H_

 #include <Eigen/Core>
 #include <algorithm>
 #include <array>
 #include <memory>
 #include <vector>

 #include "ceres/internal/disable_warnings.h"
 #include "ceres/internal/export.h"
 #include "ceres/internal/householder_vector.h"
 #include "ceres/internal/sphere_manifold_functions.h"
 #include "ceres/manifold.h"
 #include "ceres/types.h"
 #include "glog/logging.h"

 namespace ceres {
 // This provides a manifold for lines, where the line is
 // over-parameterized by an origin point and a direction vector. So the
 // parameter vector size needs to be two times the ambient space dimension,
 // where the first half is interpreted as the origin point and the second half
 // as the direction.
 //
 // The plus operator for the line direction is the same as for the
 // SphereManifold. The update of the origin point is
 // perpendicular to the line direction before the update.
 //
 // This manifold is a special case of the affine Grassmannian
 // manifold (see https://en.wikipedia.org/wiki/Affine_Grassmannian_(manifold))
 // for the case Graff_1(R^n).
 //
 // The class works with dynamic and static ambient space dimensions. If the
 // ambient space dimensions is known at compile time use
 //
 //    LineManifold<3> manifold;
 //
 // If the ambient space dimensions is not known at compile time the template
 // parameter needs to be set to ceres::DYNAMIC and the actual dimension needs
 // to be provided as a constructor argument:
 //
 //    LineManifold<ceres::DYNAMIC> manifold(ambient_dim);
 //
 template <int AmbientSpaceDimension>
 class LineManifold final : public Manifold {
  public:
   static_assert(AmbientSpaceDimension == DYNAMIC || AmbientSpaceDimension >= 2,
                 "The ambient space must be at least 2.");
   static_assert(ceres::DYNAMIC == Eigen::Dynamic,
                 "ceres::DYNAMIC needs to be the same as Eigen::Dynamic.");

   LineManifold();
   explicit LineManifold(int size);

   int AmbientSize() const override { return 2 * size_; }
   int TangentSize() const override { return 2 * (size_ - 1); }
   bool Plus(const double* x,
             const double* delta,
             double* x_plus_delta) const override;
   bool PlusJacobian(const double* x, double* jacobian) const override;
   bool Minus(const double* y,
              const double* x,
              double* y_minus_x) const override;
   bool MinusJacobian(const double* x, double* jacobian) const override;

  private:
   static constexpr bool IsDynamic = (AmbientSpaceDimension == ceres::DYNAMIC);
   static constexpr int TangentSpaceDimension =
       IsDynamic ? ceres::DYNAMIC : AmbientSpaceDimension - 1;

   static constexpr int DAmbientSpaceDimension =
       IsDynamic ? ceres::DYNAMIC : 2 * AmbientSpaceDimension;
   static constexpr int DTangentSpaceDimension =
       IsDynamic ? ceres::DYNAMIC : 2 * TangentSpaceDimension;

   using AmbientVector = Eigen::Matrix<double, AmbientSpaceDimension, 1>;
   using TangentVector = Eigen::Matrix<double, TangentSpaceDimension, 1>;
   using MatrixPlusJacobian = Eigen::Matrix<double,
                                            DAmbientSpaceDimension,
                                            DTangentSpaceDimension,
                                            Eigen::RowMajor>;
   using MatrixMinusJacobian = Eigen::Matrix<double,
                                             DTangentSpaceDimension,
                                             DAmbientSpaceDimension,
                                             Eigen::RowMajor>;

   const int size_{AmbientSpaceDimension};
 };

 template <int AmbientSpaceDimension>
 LineManifold<AmbientSpaceDimension>::LineManifold()
     : size_{AmbientSpaceDimension} {
   static_assert(
       AmbientSpaceDimension != Eigen::Dynamic,
       "The size is set to dynamic. Please call the constructor with a size.");
 }

 template <int AmbientSpaceDimension>
 LineManifold<AmbientSpaceDimension>::LineManifold(int size) : size_{size} {
   if (AmbientSpaceDimension != Eigen::Dynamic) {
     CHECK_EQ(AmbientSpaceDimension, size)
         << "Specified size by template parameter differs from the supplied "
            "one.";
   } else {
     CHECK_GT(size_, 1)
         << "The size of the manifold needs to be greater than 1.";
   }
 }

 template <int AmbientSpaceDimension>
 bool LineManifold<AmbientSpaceDimension>::Plus(const double* x_ptr,
                                                const double* delta_ptr,
                                                double* x_plus_delta_ptr) const {
   // We seek a box plus operator of the form
   //
   //   [o*, d*] = Plus([o, d], [delta_o, delta_d])
   //
   // where o is the origin point, d is the direction vector, delta_o is
   // the delta of the origin point and delta_d the delta of the direction and
   // o* and d* is the updated origin point and direction.
   //
   // We separate the Plus operator into the origin point and directional part
   //   d* = Plus_d(d, delta_d)
   //   o* = Plus_o(o, d, delta_o)
   //
   // The direction update function Plus_d is the same as as the SphereManifold:
   //
   //   d* = H_{v(d)} [0.5 sinc(0.5 |delta_d|) delta_d, cos(0.5 |delta_d|)]^T
   //
   // where H is the householder matrix
   //   H_{v} = I - (2 / |v|^2) v v^T
   // and
   //   v(d) = d - sign(d_n) |d| e_n.
   //
   // The origin point update function Plus_o is defined as
   //
   //   o* = o + H_{v(d)} [0.5 delta_o, 0]^T.

   Eigen::Map<const AmbientVector> o(x_ptr, size_);
   Eigen::Map<const AmbientVector> d(x_ptr + size_, size_);

   Eigen::Map<const TangentVector> delta_o(delta_ptr, size_ - 1);
   Eigen::Map<const TangentVector> delta_d(delta_ptr + size_ - 1, size_ - 1);
   Eigen::Map<AmbientVector> o_plus_delta(x_plus_delta_ptr, size_);
   Eigen::Map<AmbientVector> d_plus_delta(x_plus_delta_ptr + size_, size_);

   const double norm_delta_d = delta_d.norm();

   o_plus_delta = o;

   // Shortcut for zero delta direction.
   if (norm_delta_d == 0.0) {
     d_plus_delta = d;

     if (delta_o.isZero(0.0)) {
       return true;
     }
   }

   // Calculate the householder transformation which is needed for f_d and f_o.
   AmbientVector v(size_);
   double beta;

   // NOTE: The explicit template arguments are needed here because
   // ComputeHouseholderVector is templated and some versions of MSVC
   // have trouble deducing the type of v automatically.
   internal::ComputeHouseholderVector<Eigen::Map<const AmbientVector>,
                                      double,
                                      AmbientSpaceDimension>(d, &v, &beta);

   if (norm_delta_d != 0.0) {
     internal::ComputeSphereManifoldPlus(
         v, beta, d, delta_d, norm_delta_d, &d_plus_delta);
   }

   // The null space is in the direction of the line, so the tangent space is
   // perpendicular to the line direction. This is achieved by using the
   // householder matrix of the direction and allow only movements
   // perpendicular to e_n.
   //
   // The factor of 0.5 is used to be consistent with the line direction
   // update.
   AmbientVector y(size_);
   y << 0.5 * delta_o, 0;
   o_plus_delta += internal::ApplyHouseholderVector(y, v, beta);

   return true;
 }

 template <int AmbientSpaceDimension>
 bool LineManifold<AmbientSpaceDimension>::PlusJacobian(
     const double* x_ptr, double* jacobian_ptr) const {
   Eigen::Map<const AmbientVector> d(x_ptr + size_, size_);
   Eigen::Map<MatrixPlusJacobian> jacobian(
       jacobian_ptr, 2 * size_, 2 * (size_ - 1));

   // Clear the Jacobian as only half of the matrix is not zero.
   jacobian.setZero();

   auto jacobian_d =
       jacobian
           .template topLeftCorner<AmbientSpaceDimension, TangentSpaceDimension>(
               size_, size_ - 1);
   auto jacobian_o = jacobian.template bottomRightCorner<AmbientSpaceDimension,
                                                         TangentSpaceDimension>(
       size_, size_ - 1);
   internal::ComputeSphereManifoldPlusJacobian(d, &jacobian_d);
   jacobian_o = jacobian_d;
   return true;
 }

 template <int AmbientSpaceDimension>
 bool LineManifold<AmbientSpaceDimension>::Minus(const double* y_ptr,
                                                 const double* x_ptr,
                                                 double* y_minus_x) const {
   Eigen::Map<const AmbientVector> y_o(y_ptr, size_);
   Eigen::Map<const AmbientVector> y_d(y_ptr + size_, size_);
   Eigen::Map<const AmbientVector> x_o(x_ptr, size_);
   Eigen::Map<const AmbientVector> x_d(x_ptr + size_, size_);

   Eigen::Map<TangentVector> y_minus_x_o(y_minus_x, size_ - 1);
   Eigen::Map<TangentVector> y_minus_x_d(y_minus_x + size_ - 1, size_ - 1);

   AmbientVector v(size_);
   double beta;

   // NOTE: The explicit template arguments are needed here because
   // ComputeHouseholderVector is templated and some versions of MSVC
   // have trouble deducing the type of v automatically.
   internal::ComputeHouseholderVector<Eigen::Map<const AmbientVector>,
                                      double,
                                      AmbientSpaceDimension>(x_d, &v, &beta);

   internal::ComputeSphereManifoldMinus(v, beta, x_d, y_d, &y_minus_x_d);

   AmbientVector delta_o = y_o - x_o;
   const AmbientVector h_delta_o =
       2.0 * internal::ApplyHouseholderVector(delta_o, v, beta);
   y_minus_x_o = h_delta_o.template head<TangentSpaceDimension>(size_ - 1);

   return true;
 }

 template <int AmbientSpaceDimension>
 bool LineManifold<AmbientSpaceDimension>::MinusJacobian(
     const double* x_ptr, double* jacobian_ptr) const {
   Eigen::Map<const AmbientVector> d(x_ptr + size_, size_);
   Eigen::Map<MatrixMinusJacobian> jacobian(
       jacobian_ptr, 2 * (size_ - 1), 2 * size_);

   // Clear the Jacobian as only half of the matrix is not zero.
   jacobian.setZero();

   auto jacobian_d =
       jacobian
           .template topLeftCorner<TangentSpaceDimension, AmbientSpaceDimension>(
               size_ - 1, size_);
   auto jacobian_o = jacobian.template bottomRightCorner<TangentSpaceDimension,
                                                         AmbientSpaceDimension>(
       size_ - 1, size_);
   internal::ComputeSphereManifoldMinusJacobian(d, &jacobian_d);
   jacobian_o = jacobian_d;

   return true;
 }

 }  // namespace ceres

 // clang-format off
 #include "ceres/internal/reenable_warnings.h"
 // clang-format on

 #endif  // CERES_PUBLIC_LINE_MANIFOLD_H_
	// Ceres Solver - A fast non-linear least squares minimizer
	// Copyright 2022 Google Inc. All rights reserved.
	// http://ceres-solver.org/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are met:
	//
	// * Redistributions of source code must retain the above copyright notice,
	// this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above copyright notice,
	// this list of conditions and the following disclaimer in the documentation
	// and/or other materials provided with the distribution.
	// * Neither the name of Google Inc. nor the names of its contributors may be
	// used to endorse or promote products derived from this software without
	// specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
	// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
	// POSSIBILITY OF SUCH DAMAGE.
	//
	// Author: jodebo_beck@gmx.de (Johannes Beck)
	//

	#ifndef CERES_PUBLIC_LINE_MANIFOLD_H_
	#define CERES_PUBLIC_LINE_MANIFOLD_H_

	#include <Eigen/Core>
	#include <algorithm>
	#include <array>
	#include <memory>
	#include <vector>

	#include "ceres/internal/disable_warnings.h"
	#include "ceres/internal/export.h"
	#include "ceres/internal/householder_vector.h"
	#include "ceres/internal/sphere_manifold_functions.h"
	#include "ceres/manifold.h"
	#include "ceres/types.h"
	#include "glog/logging.h"

	namespace ceres {
	// This provides a manifold for lines, where the line is
	// over-parameterized by an origin point and a direction vector. So the
	// parameter vector size needs to be two times the ambient space dimension,
	// where the first half is interpreted as the origin point and the second half
	// as the direction.
	//
	// The plus operator for the line direction is the same as for the
	// SphereManifold. The update of the origin point is
	// perpendicular to the line direction before the update.
	//
	// This manifold is a special case of the affine Grassmannian
	// manifold (see https://en.wikipedia.org/wiki/Affine_Grassmannian_(manifold))
	// for the case Graff_1(R^n).
	//
	// The class works with dynamic and static ambient space dimensions. If the
	// ambient space dimensions is known at compile time use
	//
	// LineManifold<3> manifold;
	//
	// If the ambient space dimensions is not known at compile time the template
	// parameter needs to be set to ceres::DYNAMIC and the actual dimension needs
	// to be provided as a constructor argument:
	//
	// LineManifold<ceres::DYNAMIC> manifold(ambient_dim);
	//
	template <int AmbientSpaceDimension>
	class LineManifold final : public Manifold {
	public:
	static_assert(AmbientSpaceDimension == DYNAMIC \|\| AmbientSpaceDimension >= 2,
	"The ambient space must be at least 2.");
	static_assert(ceres::DYNAMIC == Eigen::Dynamic,
	"ceres::DYNAMIC needs to be the same as Eigen::Dynamic.");

	LineManifold();
	explicit LineManifold(int size);

	int AmbientSize() const override { return 2 * size_; }
	int TangentSize() const override { return 2 * (size_ - 1); }
	bool Plus(const double* x,
	const double* delta,
	double* x_plus_delta) const override;
	bool PlusJacobian(const double* x, double* jacobian) const override;
	bool Minus(const double* y,
	const double* x,
	double* y_minus_x) const override;
	bool MinusJacobian(const double* x, double* jacobian) const override;

	private:
	static constexpr bool IsDynamic = (AmbientSpaceDimension == ceres::DYNAMIC);
	static constexpr int TangentSpaceDimension =
	IsDynamic ? ceres::DYNAMIC : AmbientSpaceDimension - 1;

	static constexpr int DAmbientSpaceDimension =
	IsDynamic ? ceres::DYNAMIC : 2 * AmbientSpaceDimension;
	static constexpr int DTangentSpaceDimension =
	IsDynamic ? ceres::DYNAMIC : 2 * TangentSpaceDimension;

	using AmbientVector = Eigen::Matrix<double, AmbientSpaceDimension, 1>;
	using TangentVector = Eigen::Matrix<double, TangentSpaceDimension, 1>;
	using MatrixPlusJacobian = Eigen::Matrix<double,
	DAmbientSpaceDimension,
	DTangentSpaceDimension,
	Eigen::RowMajor>;
	using MatrixMinusJacobian = Eigen::Matrix<double,
	DTangentSpaceDimension,
	DAmbientSpaceDimension,
	Eigen::RowMajor>;

	const int size_{AmbientSpaceDimension};
	};

	template <int AmbientSpaceDimension>
	LineManifold<AmbientSpaceDimension>::LineManifold()
	: size_{AmbientSpaceDimension} {
	static_assert(
	AmbientSpaceDimension != Eigen::Dynamic,
	"The size is set to dynamic. Please call the constructor with a size.");
	}

	template <int AmbientSpaceDimension>
	LineManifold<AmbientSpaceDimension>::LineManifold(int size) : size_{size} {
	if (AmbientSpaceDimension != Eigen::Dynamic) {
	CHECK_EQ(AmbientSpaceDimension, size)
	<< "Specified size by template parameter differs from the supplied "
	"one.";
	} else {
	CHECK_GT(size_, 1)
	<< "The size of the manifold needs to be greater than 1.";
	}
	}

	template <int AmbientSpaceDimension>
	bool LineManifold<AmbientSpaceDimension>::Plus(const double* x_ptr,
	const double* delta_ptr,
	double* x_plus_delta_ptr) const {
	// We seek a box plus operator of the form
	//
	// [o, d] = Plus([o, d], [delta_o, delta_d])
	//
	// where o is the origin point, d is the direction vector, delta_o is
	// the delta of the origin point and delta_d the delta of the direction and
	// o* and d* is the updated origin point and direction.
	//
	// We separate the Plus operator into the origin point and directional part
	// d* = Plus_d(d, delta_d)
	// o* = Plus_o(o, d, delta_o)
	//
	// The direction update function Plus_d is the same as as the SphereManifold:
	//
	// d* = H_{v(d)} [0.5 sinc(0.5 \|delta_d\|) delta_d, cos(0.5 \|delta_d\|)]^T
	//
	// where H is the householder matrix
	// H_{v} = I - (2 / \|v\|^2) v v^T
	// and
	// v(d) = d - sign(d_n) \|d\| e_n.
	//
	// The origin point update function Plus_o is defined as
	//
	// o* = o + H_{v(d)} [0.5 delta_o, 0]^T.

	Eigen::Map<const AmbientVector> o(x_ptr, size_);
	Eigen::Map<const AmbientVector> d(x_ptr + size_, size_);

	Eigen::Map<const TangentVector> delta_o(delta_ptr, size_ - 1);
	Eigen::Map<const TangentVector> delta_d(delta_ptr + size_ - 1, size_ - 1);
	Eigen::Map<AmbientVector> o_plus_delta(x_plus_delta_ptr, size_);
	Eigen::Map<AmbientVector> d_plus_delta(x_plus_delta_ptr + size_, size_);

	const double norm_delta_d = delta_d.norm();

	o_plus_delta = o;

	// Shortcut for zero delta direction.
	if (norm_delta_d == 0.0) {
	d_plus_delta = d;

	if (delta_o.isZero(0.0)) {
	return true;
	}
	}

	// Calculate the householder transformation which is needed for f_d and f_o.
	AmbientVector v(size_);
	double beta;

	// NOTE: The explicit template arguments are needed here because
	// ComputeHouseholderVector is templated and some versions of MSVC
	// have trouble deducing the type of v automatically.
	internal::ComputeHouseholderVector<Eigen::Map<const AmbientVector>,
	double,
	AmbientSpaceDimension>(d, &v, &beta);

	if (norm_delta_d != 0.0) {
	internal::ComputeSphereManifoldPlus(
	v, beta, d, delta_d, norm_delta_d, &d_plus_delta);
	}

	// The null space is in the direction of the line, so the tangent space is
	// perpendicular to the line direction. This is achieved by using the
	// householder matrix of the direction and allow only movements
	// perpendicular to e_n.
	//
	// The factor of 0.5 is used to be consistent with the line direction
	// update.
	AmbientVector y(size_);
	y << 0.5 * delta_o, 0;
	o_plus_delta += internal::ApplyHouseholderVector(y, v, beta);

	return true;
	}

	template <int AmbientSpaceDimension>
	bool LineManifold<AmbientSpaceDimension>::PlusJacobian(
	const double* x_ptr, double* jacobian_ptr) const {
	Eigen::Map<const AmbientVector> d(x_ptr + size_, size_);
	Eigen::Map<MatrixPlusJacobian> jacobian(
	jacobian_ptr, 2 * size_, 2 * (size_ - 1));

	// Clear the Jacobian as only half of the matrix is not zero.
	jacobian.setZero();

	auto jacobian_d =
	jacobian
	.template topLeftCorner<AmbientSpaceDimension, TangentSpaceDimension>(
	size_, size_ - 1);
	auto jacobian_o = jacobian.template bottomRightCorner<AmbientSpaceDimension,
	TangentSpaceDimension>(
	size_, size_ - 1);
	internal::ComputeSphereManifoldPlusJacobian(d, &jacobian_d);
	jacobian_o = jacobian_d;
	return true;
	}

	template <int AmbientSpaceDimension>
	bool LineManifold<AmbientSpaceDimension>::Minus(const double* y_ptr,
	const double* x_ptr,
	double* y_minus_x) const {
	Eigen::Map<const AmbientVector> y_o(y_ptr, size_);
	Eigen::Map<const AmbientVector> y_d(y_ptr + size_, size_);
	Eigen::Map<const AmbientVector> x_o(x_ptr, size_);
	Eigen::Map<const AmbientVector> x_d(x_ptr + size_, size_);

	Eigen::Map<TangentVector> y_minus_x_o(y_minus_x, size_ - 1);
	Eigen::Map<TangentVector> y_minus_x_d(y_minus_x + size_ - 1, size_ - 1);

	AmbientVector v(size_);
	double beta;

	// NOTE: The explicit template arguments are needed here because
	// ComputeHouseholderVector is templated and some versions of MSVC
	// have trouble deducing the type of v automatically.
	internal::ComputeHouseholderVector<Eigen::Map<const AmbientVector>,
	double,
	AmbientSpaceDimension>(x_d, &v, &beta);

	internal::ComputeSphereManifoldMinus(v, beta, x_d, y_d, &y_minus_x_d);

	AmbientVector delta_o = y_o - x_o;
	const AmbientVector h_delta_o =
	2.0 * internal::ApplyHouseholderVector(delta_o, v, beta);
	y_minus_x_o = h_delta_o.template head<TangentSpaceDimension>(size_ - 1);

	return true;
	}

	template <int AmbientSpaceDimension>
	bool LineManifold<AmbientSpaceDimension>::MinusJacobian(
	const double* x_ptr, double* jacobian_ptr) const {
	Eigen::Map<const AmbientVector> d(x_ptr + size_, size_);
	Eigen::Map<MatrixMinusJacobian> jacobian(
	jacobian_ptr, 2 * (size_ - 1), 2 * size_);

	// Clear the Jacobian as only half of the matrix is not zero.
	jacobian.setZero();

	auto jacobian_d =
	jacobian
	.template topLeftCorner<TangentSpaceDimension, AmbientSpaceDimension>(
	size_ - 1, size_);
	auto jacobian_o = jacobian.template bottomRightCorner<TangentSpaceDimension,
	AmbientSpaceDimension>(
	size_ - 1, size_);
	internal::ComputeSphereManifoldMinusJacobian(d, &jacobian_d);
	jacobian_o = jacobian_d;

	return true;
	}

	} // namespace ceres

	// clang-format off
	#include "ceres/internal/reenable_warnings.h"
	// clang-format on

	#endif // CERES_PUBLIC_LINE_MANIFOLD_H_