internal/ceres/manifold.cc - ceres-solver - Git at Google

 #include "ceres/manifold.h"

 #include <algorithm>
 #include <cmath>

 #include "ceres/internal/eigen.h"
 #include "ceres/internal/fixed_array.h"
 #include "glog/logging.h"

 namespace ceres {
 namespace {

 struct CeresQuaternionOrder {
   static constexpr int kW = 0;
   static constexpr int kX = 1;
   static constexpr int kY = 2;
   static constexpr int kZ = 3;
 };

 struct EigenQuaternionOrder {
   static constexpr int kW = 3;
   static constexpr int kX = 0;
   static constexpr int kY = 1;
   static constexpr int kZ = 2;
 };

 template <typename Order>
 inline void QuaternionPlusImpl(const double* x,
                                const double* delta,
                                double* x_plus_delta) {
   // x_plus_delta = QuaternionProduct(q_delta, x), where q_delta is the
   // quaternion constructed from delta.
   const double norm_delta = std::hypot(delta[0], delta[1], delta[2]);

   if (std::fpclassify(norm_delta) == FP_ZERO) {
     // No change in rotation: return the quaternion as is.
     std::copy_n(x, 4, x_plus_delta);
     return;
   }

   const double sin_delta_by_delta = (std::sin(norm_delta) / norm_delta);
   double q_delta[4];
   q_delta[Order::kW] = std::cos(norm_delta);
   q_delta[Order::kX] = sin_delta_by_delta * delta[0];
   q_delta[Order::kY] = sin_delta_by_delta * delta[1];
   q_delta[Order::kZ] = sin_delta_by_delta * delta[2];

   x_plus_delta[Order::kW] =
       q_delta[Order::kW] * x[Order::kW] - q_delta[Order::kX] * x[Order::kX] -
       q_delta[Order::kY] * x[Order::kY] - q_delta[Order::kZ] * x[Order::kZ];
   x_plus_delta[Order::kX] =
       q_delta[Order::kW] * x[Order::kX] + q_delta[Order::kX] * x[Order::kW] +
       q_delta[Order::kY] * x[Order::kZ] - q_delta[Order::kZ] * x[Order::kY];
   x_plus_delta[Order::kY] =
       q_delta[Order::kW] * x[Order::kY] - q_delta[Order::kX] * x[Order::kZ] +
       q_delta[Order::kY] * x[Order::kW] + q_delta[Order::kZ] * x[Order::kX];
   x_plus_delta[Order::kZ] =
       q_delta[Order::kW] * x[Order::kZ] + q_delta[Order::kX] * x[Order::kY] -
       q_delta[Order::kY] * x[Order::kX] + q_delta[Order::kZ] * x[Order::kW];
 }

 template <typename Order>
 inline void QuaternionPlusJacobianImpl(const double* x, double* jacobian_ptr) {
   Eigen::Map<Eigen::Matrix<double, 4, 3, Eigen::RowMajor>> jacobian(
       jacobian_ptr);

   jacobian(Order::kW, 0) = -x[Order::kX];
   jacobian(Order::kW, 1) = -x[Order::kY];
   jacobian(Order::kW, 2) = -x[Order::kZ];
   jacobian(Order::kX, 0) = x[Order::kW];
   jacobian(Order::kX, 1) = x[Order::kZ];
   jacobian(Order::kX, 2) = -x[Order::kY];
   jacobian(Order::kY, 0) = -x[Order::kZ];
   jacobian(Order::kY, 1) = x[Order::kW];
   jacobian(Order::kY, 2) = x[Order::kX];
   jacobian(Order::kZ, 0) = x[Order::kY];
   jacobian(Order::kZ, 1) = -x[Order::kX];
   jacobian(Order::kZ, 2) = x[Order::kW];
 }

 template <typename Order>
 inline void QuaternionMinusImpl(const double* y,
                                 const double* x,
                                 double* y_minus_x) {
   // ambient_y_minus_x = QuaternionProduct(y, -x) where -x is the conjugate of
   // x.
   double ambient_y_minus_x[4];
   ambient_y_minus_x[Order::kW] =
       y[Order::kW] * x[Order::kW] + y[Order::kX] * x[Order::kX] +
       y[Order::kY] * x[Order::kY] + y[Order::kZ] * x[Order::kZ];
   ambient_y_minus_x[Order::kX] =
       -y[Order::kW] * x[Order::kX] + y[Order::kX] * x[Order::kW] -
       y[Order::kY] * x[Order::kZ] + y[Order::kZ] * x[Order::kY];
   ambient_y_minus_x[Order::kY] =
       -y[Order::kW] * x[Order::kY] + y[Order::kX] * x[Order::kZ] +
       y[Order::kY] * x[Order::kW] - y[Order::kZ] * x[Order::kX];
   ambient_y_minus_x[Order::kZ] =
       -y[Order::kW] * x[Order::kZ] - y[Order::kX] * x[Order::kY] +
       y[Order::kY] * x[Order::kX] + y[Order::kZ] * x[Order::kW];

   const double u_norm = std::hypot(ambient_y_minus_x[Order::kX],
                                    ambient_y_minus_x[Order::kY],
                                    ambient_y_minus_x[Order::kZ]);
   if (std::fpclassify(u_norm) != FP_ZERO) {
     const double theta = std::atan2(u_norm, ambient_y_minus_x[Order::kW]);
     y_minus_x[0] = theta * ambient_y_minus_x[Order::kX] / u_norm;
     y_minus_x[1] = theta * ambient_y_minus_x[Order::kY] / u_norm;
     y_minus_x[2] = theta * ambient_y_minus_x[Order::kZ] / u_norm;
   } else {
     std::fill_n(y_minus_x, 3, 0.0);
   }
 }

 template <typename Order>
 inline void QuaternionMinusJacobianImpl(const double* x, double* jacobian_ptr) {
   Eigen::Map<Eigen::Matrix<double, 3, 4, Eigen::RowMajor>> jacobian(
       jacobian_ptr);

   jacobian(0, Order::kW) = -x[Order::kX];
   jacobian(0, Order::kX) = x[Order::kW];
   jacobian(0, Order::kY) = -x[Order::kZ];
   jacobian(0, Order::kZ) = x[Order::kY];
   jacobian(1, Order::kW) = -x[Order::kY];
   jacobian(1, Order::kX) = x[Order::kZ];
   jacobian(1, Order::kY) = x[Order::kW];
   jacobian(1, Order::kZ) = -x[Order::kX];
   jacobian(2, Order::kW) = -x[Order::kZ];
   jacobian(2, Order::kX) = -x[Order::kY];
   jacobian(2, Order::kY) = x[Order::kX];
   jacobian(2, Order::kZ) = x[Order::kW];
 }

 }  // namespace

 Manifold::~Manifold() = default;

 bool Manifold::RightMultiplyByPlusJacobian(const double* x,
                                            const int num_rows,
                                            const double* ambient_matrix,
                                            double* tangent_matrix) const {
   const int tangent_size = TangentSize();
   if (tangent_size == 0) {
     return true;
   }

   const int ambient_size = AmbientSize();
   Matrix plus_jacobian(ambient_size, tangent_size);
   if (!PlusJacobian(x, plus_jacobian.data())) {
     return false;
   }

   MatrixRef(tangent_matrix, num_rows, tangent_size) =
       ConstMatrixRef(ambient_matrix, num_rows, ambient_size) * plus_jacobian;
   return true;
 }

 SubsetManifold::SubsetManifold(const int size,
                                const std::vector<int>& constant_parameters)

     : tangent_size_(size - constant_parameters.size()),
       constancy_mask_(size, false) {
   if (constant_parameters.empty()) {
     return;
   }

   std::vector<int> constant = constant_parameters;
   std::sort(constant.begin(), constant.end());
   CHECK_GE(constant.front(), 0) << "Indices indicating constant parameter must "
                                    "be greater than equal to zero.";
   CHECK_LT(constant.back(), size)
       << "Indices indicating constant parameter must be less than the size "
       << "of the parameter block.";
   CHECK(std::adjacent_find(constant.begin(), constant.end()) == constant.end())
       << "The set of constant parameters cannot contain duplicates";

   for (auto index : constant_parameters) {
     constancy_mask_[index] = true;
   }
 }

 int SubsetManifold::AmbientSize() const { return constancy_mask_.size(); }

 int SubsetManifold::TangentSize() const { return tangent_size_; }

 bool SubsetManifold::Plus(const double* x,
                           const double* delta,
                           double* x_plus_delta) const {
   const int ambient_size = AmbientSize();
   for (int i = 0, j = 0; i < ambient_size; ++i) {
     if (constancy_mask_[i]) {
       x_plus_delta[i] = x[i];
     } else {
       x_plus_delta[i] = x[i] + delta[j++];
     }
   }
   return true;
 }

 bool SubsetManifold::PlusJacobian(const double* /*x*/,
                                   double* plus_jacobian) const {
   if (tangent_size_ == 0) {
     return true;
   }

   const int ambient_size = AmbientSize();
   MatrixRef m(plus_jacobian, ambient_size, tangent_size_);
   m.setZero();
   for (int r = 0, c = 0; r < ambient_size; ++r) {
     if (!constancy_mask_[r]) {
       m(r, c++) = 1.0;
     }
   }
   return true;
 }

 bool SubsetManifold::RightMultiplyByPlusJacobian(const double* /*x*/,
                                                  const int num_rows,
                                                  const double* ambient_matrix,
                                                  double* tangent_matrix) const {
   if (tangent_size_ == 0) {
     return true;
   }

   const int ambient_size = AmbientSize();
   for (int r = 0; r < num_rows; ++r) {
     for (int idx = 0, c = 0; idx < ambient_size; ++idx) {
       if (!constancy_mask_[idx]) {
         tangent_matrix[r * tangent_size_ + c++] =
             ambient_matrix[r * ambient_size + idx];
       }
     }
   }
   return true;
 }

 bool SubsetManifold::Minus(const double* y,
                            const double* x,
                            double* y_minus_x) const {
   if (tangent_size_ == 0) {
     return true;
   }

   const int ambient_size = AmbientSize();
   for (int i = 0, j = 0; i < ambient_size; ++i) {
     if (!constancy_mask_[i]) {
       y_minus_x[j++] = y[i] - x[i];
     }
   }
   return true;
 }

 bool SubsetManifold::MinusJacobian(const double* /*x*/,
                                    double* minus_jacobian) const {
   const int ambient_size = AmbientSize();
   MatrixRef m(minus_jacobian, tangent_size_, ambient_size);
   m.setZero();
   for (int c = 0, r = 0; c < ambient_size; ++c) {
     if (!constancy_mask_[c]) {
       m(r++, c) = 1.0;
     }
   }
   return true;
 }

 bool QuaternionManifold::Plus(const double* x,
                               const double* delta,
                               double* x_plus_delta) const {
   QuaternionPlusImpl<CeresQuaternionOrder>(x, delta, x_plus_delta);
   return true;
 }

 bool QuaternionManifold::PlusJacobian(const double* x, double* jacobian) const {
   QuaternionPlusJacobianImpl<CeresQuaternionOrder>(x, jacobian);
   return true;
 }

 bool QuaternionManifold::Minus(const double* y,
                                const double* x,
                                double* y_minus_x) const {
   QuaternionMinusImpl<CeresQuaternionOrder>(y, x, y_minus_x);
   return true;
 }

 bool QuaternionManifold::MinusJacobian(const double* x,
                                        double* jacobian) const {
   QuaternionMinusJacobianImpl<CeresQuaternionOrder>(x, jacobian);
   return true;
 }

 bool EigenQuaternionManifold::Plus(const double* x,
                                    const double* delta,
                                    double* x_plus_delta) const {
   QuaternionPlusImpl<EigenQuaternionOrder>(x, delta, x_plus_delta);
   return true;
 }

 bool EigenQuaternionManifold::PlusJacobian(const double* x,
                                            double* jacobian) const {
   QuaternionPlusJacobianImpl<EigenQuaternionOrder>(x, jacobian);
   return true;
 }

 bool EigenQuaternionManifold::Minus(const double* y,
                                     const double* x,
                                     double* y_minus_x) const {
   QuaternionMinusImpl<EigenQuaternionOrder>(y, x, y_minus_x);
   return true;
 }

 bool EigenQuaternionManifold::MinusJacobian(const double* x,
                                             double* jacobian) const {
   QuaternionMinusJacobianImpl<EigenQuaternionOrder>(x, jacobian);
   return true;
 }

 }  // namespace ceres
	#include "ceres/manifold.h"

	#include <algorithm>
	#include <cmath>

	#include "ceres/internal/eigen.h"
	#include "ceres/internal/fixed_array.h"
	#include "glog/logging.h"

	namespace ceres {
	namespace {

	struct CeresQuaternionOrder {
	static constexpr int kW = 0;
	static constexpr int kX = 1;
	static constexpr int kY = 2;
	static constexpr int kZ = 3;
	};

	struct EigenQuaternionOrder {
	static constexpr int kW = 3;
	static constexpr int kX = 0;
	static constexpr int kY = 1;
	static constexpr int kZ = 2;
	};

	template <typename Order>
	inline void QuaternionPlusImpl(const double* x,
	const double* delta,
	double* x_plus_delta) {
	// x_plus_delta = QuaternionProduct(q_delta, x), where q_delta is the
	// quaternion constructed from delta.
	const double norm_delta = std::hypot(delta[0], delta[1], delta[2]);

	if (std::fpclassify(norm_delta) == FP_ZERO) {
	// No change in rotation: return the quaternion as is.
	std::copy_n(x, 4, x_plus_delta);
	return;
	}

	const double sin_delta_by_delta = (std::sin(norm_delta) / norm_delta);
	double q_delta[4];
	q_delta[Order::kW] = std::cos(norm_delta);
	q_delta[Order::kX] = sin_delta_by_delta * delta[0];
	q_delta[Order::kY] = sin_delta_by_delta * delta[1];
	q_delta[Order::kZ] = sin_delta_by_delta * delta[2];

	x_plus_delta[Order::kW] =
	q_delta[Order::kW] * x[Order::kW] - q_delta[Order::kX] * x[Order::kX] -
	q_delta[Order::kY] * x[Order::kY] - q_delta[Order::kZ] * x[Order::kZ];
	x_plus_delta[Order::kX] =
	q_delta[Order::kW] * x[Order::kX] + q_delta[Order::kX] * x[Order::kW] +
	q_delta[Order::kY] * x[Order::kZ] - q_delta[Order::kZ] * x[Order::kY];
	x_plus_delta[Order::kY] =
	q_delta[Order::kW] * x[Order::kY] - q_delta[Order::kX] * x[Order::kZ] +
	q_delta[Order::kY] * x[Order::kW] + q_delta[Order::kZ] * x[Order::kX];
	x_plus_delta[Order::kZ] =
	q_delta[Order::kW] * x[Order::kZ] + q_delta[Order::kX] * x[Order::kY] -
	q_delta[Order::kY] * x[Order::kX] + q_delta[Order::kZ] * x[Order::kW];
	}

	template <typename Order>
	inline void QuaternionPlusJacobianImpl(const double* x, double* jacobian_ptr) {
	Eigen::Map<Eigen::Matrix<double, 4, 3, Eigen::RowMajor>> jacobian(
	jacobian_ptr);

	jacobian(Order::kW, 0) = -x[Order::kX];
	jacobian(Order::kW, 1) = -x[Order::kY];
	jacobian(Order::kW, 2) = -x[Order::kZ];
	jacobian(Order::kX, 0) = x[Order::kW];
	jacobian(Order::kX, 1) = x[Order::kZ];
	jacobian(Order::kX, 2) = -x[Order::kY];
	jacobian(Order::kY, 0) = -x[Order::kZ];
	jacobian(Order::kY, 1) = x[Order::kW];
	jacobian(Order::kY, 2) = x[Order::kX];
	jacobian(Order::kZ, 0) = x[Order::kY];
	jacobian(Order::kZ, 1) = -x[Order::kX];
	jacobian(Order::kZ, 2) = x[Order::kW];
	}

	template <typename Order>
	inline void QuaternionMinusImpl(const double* y,
	const double* x,
	double* y_minus_x) {
	// ambient_y_minus_x = QuaternionProduct(y, -x) where -x is the conjugate of
	// x.
	double ambient_y_minus_x[4];
	ambient_y_minus_x[Order::kW] =
	y[Order::kW] * x[Order::kW] + y[Order::kX] * x[Order::kX] +
	y[Order::kY] * x[Order::kY] + y[Order::kZ] * x[Order::kZ];
	ambient_y_minus_x[Order::kX] =
	-y[Order::kW] * x[Order::kX] + y[Order::kX] * x[Order::kW] -
	y[Order::kY] * x[Order::kZ] + y[Order::kZ] * x[Order::kY];
	ambient_y_minus_x[Order::kY] =
	-y[Order::kW] * x[Order::kY] + y[Order::kX] * x[Order::kZ] +
	y[Order::kY] * x[Order::kW] - y[Order::kZ] * x[Order::kX];
	ambient_y_minus_x[Order::kZ] =
	-y[Order::kW] * x[Order::kZ] - y[Order::kX] * x[Order::kY] +
	y[Order::kY] * x[Order::kX] + y[Order::kZ] * x[Order::kW];

	const double u_norm = std::hypot(ambient_y_minus_x[Order::kX],
	ambient_y_minus_x[Order::kY],
	ambient_y_minus_x[Order::kZ]);
	if (std::fpclassify(u_norm) != FP_ZERO) {
	const double theta = std::atan2(u_norm, ambient_y_minus_x[Order::kW]);
	y_minus_x[0] = theta * ambient_y_minus_x[Order::kX] / u_norm;
	y_minus_x[1] = theta * ambient_y_minus_x[Order::kY] / u_norm;
	y_minus_x[2] = theta * ambient_y_minus_x[Order::kZ] / u_norm;
	} else {
	std::fill_n(y_minus_x, 3, 0.0);
	}
	}

	template <typename Order>
	inline void QuaternionMinusJacobianImpl(const double* x, double* jacobian_ptr) {
	Eigen::Map<Eigen::Matrix<double, 3, 4, Eigen::RowMajor>> jacobian(
	jacobian_ptr);

	jacobian(0, Order::kW) = -x[Order::kX];
	jacobian(0, Order::kX) = x[Order::kW];
	jacobian(0, Order::kY) = -x[Order::kZ];
	jacobian(0, Order::kZ) = x[Order::kY];
	jacobian(1, Order::kW) = -x[Order::kY];
	jacobian(1, Order::kX) = x[Order::kZ];
	jacobian(1, Order::kY) = x[Order::kW];
	jacobian(1, Order::kZ) = -x[Order::kX];
	jacobian(2, Order::kW) = -x[Order::kZ];
	jacobian(2, Order::kX) = -x[Order::kY];
	jacobian(2, Order::kY) = x[Order::kX];
	jacobian(2, Order::kZ) = x[Order::kW];
	}

	} // namespace

	Manifold::~Manifold() = default;

	bool Manifold::RightMultiplyByPlusJacobian(const double* x,
	const int num_rows,
	const double* ambient_matrix,
	double* tangent_matrix) const {
	const int tangent_size = TangentSize();
	if (tangent_size == 0) {
	return true;
	}

	const int ambient_size = AmbientSize();
	Matrix plus_jacobian(ambient_size, tangent_size);
	if (!PlusJacobian(x, plus_jacobian.data())) {
	return false;
	}

	MatrixRef(tangent_matrix, num_rows, tangent_size) =
	ConstMatrixRef(ambient_matrix, num_rows, ambient_size) * plus_jacobian;
	return true;
	}

	SubsetManifold::SubsetManifold(const int size,
	const std::vector<int>& constant_parameters)

	: tangent_size_(size - constant_parameters.size()),
	constancy_mask_(size, false) {
	if (constant_parameters.empty()) {
	return;
	}

	std::vector<int> constant = constant_parameters;
	std::sort(constant.begin(), constant.end());
	CHECK_GE(constant.front(), 0) << "Indices indicating constant parameter must "
	"be greater than equal to zero.";
	CHECK_LT(constant.back(), size)
	<< "Indices indicating constant parameter must be less than the size "
	<< "of the parameter block.";
	CHECK(std::adjacent_find(constant.begin(), constant.end()) == constant.end())
	<< "The set of constant parameters cannot contain duplicates";

	for (auto index : constant_parameters) {
	constancy_mask_[index] = true;
	}
	}

	int SubsetManifold::AmbientSize() const { return constancy_mask_.size(); }

	int SubsetManifold::TangentSize() const { return tangent_size_; }

	bool SubsetManifold::Plus(const double* x,
	const double* delta,
	double* x_plus_delta) const {
	const int ambient_size = AmbientSize();
	for (int i = 0, j = 0; i < ambient_size; ++i) {
	if (constancy_mask_[i]) {
	x_plus_delta[i] = x[i];
	} else {
	x_plus_delta[i] = x[i] + delta[j++];
	}
	}
	return true;
	}

	bool SubsetManifold::PlusJacobian(const double* /x/,
	double* plus_jacobian) const {
	if (tangent_size_ == 0) {
	return true;
	}

	const int ambient_size = AmbientSize();
	MatrixRef m(plus_jacobian, ambient_size, tangent_size_);
	m.setZero();
	for (int r = 0, c = 0; r < ambient_size; ++r) {
	if (!constancy_mask_[r]) {
	m(r, c++) = 1.0;
	}
	}
	return true;
	}

	bool SubsetManifold::RightMultiplyByPlusJacobian(const double* /x/,
	const int num_rows,
	const double* ambient_matrix,
	double* tangent_matrix) const {
	if (tangent_size_ == 0) {
	return true;
	}

	const int ambient_size = AmbientSize();
	for (int r = 0; r < num_rows; ++r) {
	for (int idx = 0, c = 0; idx < ambient_size; ++idx) {
	if (!constancy_mask_[idx]) {
	tangent_matrix[r * tangent_size_ + c++] =
	ambient_matrix[r * ambient_size + idx];
	}
	}
	}
	return true;
	}

	bool SubsetManifold::Minus(const double* y,
	const double* x,
	double* y_minus_x) const {
	if (tangent_size_ == 0) {
	return true;
	}

	const int ambient_size = AmbientSize();
	for (int i = 0, j = 0; i < ambient_size; ++i) {
	if (!constancy_mask_[i]) {
	y_minus_x[j++] = y[i] - x[i];
	}
	}
	return true;
	}

	bool SubsetManifold::MinusJacobian(const double* /x/,
	double* minus_jacobian) const {
	const int ambient_size = AmbientSize();
	MatrixRef m(minus_jacobian, tangent_size_, ambient_size);
	m.setZero();
	for (int c = 0, r = 0; c < ambient_size; ++c) {
	if (!constancy_mask_[c]) {
	m(r++, c) = 1.0;
	}
	}
	return true;
	}

	bool QuaternionManifold::Plus(const double* x,
	const double* delta,
	double* x_plus_delta) const {
	QuaternionPlusImpl<CeresQuaternionOrder>(x, delta, x_plus_delta);
	return true;
	}

	bool QuaternionManifold::PlusJacobian(const double* x, double* jacobian) const {
	QuaternionPlusJacobianImpl<CeresQuaternionOrder>(x, jacobian);
	return true;
	}

	bool QuaternionManifold::Minus(const double* y,
	const double* x,
	double* y_minus_x) const {
	QuaternionMinusImpl<CeresQuaternionOrder>(y, x, y_minus_x);
	return true;
	}

	bool QuaternionManifold::MinusJacobian(const double* x,
	double* jacobian) const {
	QuaternionMinusJacobianImpl<CeresQuaternionOrder>(x, jacobian);
	return true;
	}

	bool EigenQuaternionManifold::Plus(const double* x,
	const double* delta,
	double* x_plus_delta) const {
	QuaternionPlusImpl<EigenQuaternionOrder>(x, delta, x_plus_delta);
	return true;
	}

	bool EigenQuaternionManifold::PlusJacobian(const double* x,
	double* jacobian) const {
	QuaternionPlusJacobianImpl<EigenQuaternionOrder>(x, jacobian);
	return true;
	}

	bool EigenQuaternionManifold::Minus(const double* y,
	const double* x,
	double* y_minus_x) const {
	QuaternionMinusImpl<EigenQuaternionOrder>(y, x, y_minus_x);
	return true;
	}

	bool EigenQuaternionManifold::MinusJacobian(const double* x,
	double* jacobian) const {
	QuaternionMinusJacobianImpl<EigenQuaternionOrder>(x, jacobian);
	return true;
	}

	} // namespace ceres