unsupported/Eigen/src/LevenbergMarquardt/LMpar.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // This code initially comes from MINPACK whose original authors are:
 // Copyright Jorge More - Argonne National Laboratory
 // Copyright Burt Garbow - Argonne National Laboratory
 // Copyright Ken Hillstrom - Argonne National Laboratory
 //
 // This Source Code Form is subject to the terms of the Minpack license
 // (a BSD-like license) described in the campaigned CopyrightMINPACK.txt file.

 #ifndef EIGEN_LMPAR_H
 #define EIGEN_LMPAR_H

 namespace Eigen {

 namespace internal {

   template <typename QRSolver, typename VectorType>
     void lmpar2(
     const QRSolver &qr,
     const VectorType  &diag,
     const VectorType  &qtb,
     typename VectorType::Scalar m_delta,
     typename VectorType::Scalar &par,
     VectorType  &x)

   {
     using std::sqrt;
     using std::abs;
     typedef typename QRSolver::MatrixType MatrixType;
     typedef typename QRSolver::Scalar Scalar;
 //    typedef typename QRSolver::StorageIndex StorageIndex;

     /* Local variables */
     Index j;
     Scalar fp;
     Scalar parc, parl;
     Index iter;
     Scalar temp, paru;
     Scalar gnorm;
     Scalar dxnorm;

     // Make a copy of the triangular factor.
     // This copy is modified during call the qrsolv
     MatrixType s;
     s = qr.matrixR();

     /* Function Body */
     const Scalar dwarf = (std::numeric_limits<Scalar>::min)();
     const Index n = qr.matrixR().cols();
     eigen_assert(n==diag.size());
     eigen_assert(n==qtb.size());

     VectorType  wa1, wa2;

     /* compute and store in x the gauss-newton direction. if the */
     /* jacobian is rank-deficient, obtain a least squares solution. */

     //    const Index rank = qr.nonzeroPivots(); // exactly double(0.)
     const Index rank = qr.rank(); // use a threshold
     wa1 = qtb;
     wa1.tail(n-rank).setZero();
     //FIXME There is no solve in place for sparse triangularView
     wa1.head(rank) = s.topLeftCorner(rank,rank).template triangularView<Upper>().solve(qtb.head(rank));

     x = qr.colsPermutation()*wa1;

     /* initialize the iteration counter. */
     /* evaluate the function at the origin, and test */
     /* for acceptance of the gauss-newton direction. */
     iter = 0;
     wa2 = diag.cwiseProduct(x);
     dxnorm = wa2.blueNorm();
     fp = dxnorm - m_delta;
     if (fp <= Scalar(0.1) * m_delta) {
       par = 0;
       return;
     }

     /* if the jacobian is not rank deficient, the newton */
     /* step provides a lower bound, parl, for the zero of */
     /* the function. otherwise set this bound to zero. */
     parl = 0.;
     if (rank==n) {
       wa1 = qr.colsPermutation().inverse() *  diag.cwiseProduct(wa2)/dxnorm;
       s.topLeftCorner(n,n).transpose().template triangularView<Lower>().solveInPlace(wa1);
       temp = wa1.blueNorm();
       parl = fp / m_delta / temp / temp;
     }

     /* calculate an upper bound, paru, for the zero of the function. */
     for (j = 0; j < n; ++j)
       wa1[j] = s.col(j).head(j+1).dot(qtb.head(j+1)) / diag[qr.colsPermutation().indices()(j)];

     gnorm = wa1.stableNorm();
     paru = gnorm / m_delta;
     if (paru == 0.)
       paru = dwarf / (std::min)(m_delta,Scalar(0.1));

     /* if the input par lies outside of the interval (parl,paru), */
     /* set par to the closer endpoint. */
     par = (std::max)(par,parl);
     par = (std::min)(par,paru);
     if (par == 0.)
       par = gnorm / dxnorm;

     /* beginning of an iteration. */
     while (true) {
       ++iter;

       /* evaluate the function at the current value of par. */
       if (par == 0.)
         par = (std::max)(dwarf,Scalar(.001) * paru); /* Computing MAX */
       wa1 = sqrt(par)* diag;

       VectorType sdiag(n);
       lmqrsolv(s, qr.colsPermutation(), wa1, qtb, x, sdiag);

       wa2 = diag.cwiseProduct(x);
       dxnorm = wa2.blueNorm();
       temp = fp;
       fp = dxnorm - m_delta;

       /* if the function is small enough, accept the current value */
       /* of par. also test for the exceptional cases where parl */
       /* is zero or the number of iterations has reached 10. */
       if (abs(fp) <= Scalar(0.1) * m_delta || (parl == 0. && fp <= temp && temp < 0.) || iter == 10)
         break;

       /* compute the newton correction. */
       wa1 = qr.colsPermutation().inverse() * diag.cwiseProduct(wa2/dxnorm);
       // we could almost use this here, but the diagonal is outside qr, in sdiag[]
       for (j = 0; j < n; ++j) {
         wa1[j] /= sdiag[j];
         temp = wa1[j];
         for (Index i = j+1; i < n; ++i)
           wa1[i] -= s.coeff(i,j) * temp;
       }
       temp = wa1.blueNorm();
       parc = fp / m_delta / temp / temp;

       /* depending on the sign of the function, update parl or paru. */
       if (fp > 0.)
         parl = (std::max)(parl,par);
       if (fp < 0.)
         paru = (std::min)(paru,par);

       /* compute an improved estimate for par. */
       par = (std::max)(parl,par+parc);
     }
     if (iter == 0)
       par = 0.;
     return;
   }
 } // end namespace internal

 } // end namespace Eigen

 #endif // EIGEN_LMPAR_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// This code initially comes from MINPACK whose original authors are:
	// Copyright Jorge More - Argonne National Laboratory
	// Copyright Burt Garbow - Argonne National Laboratory
	// Copyright Ken Hillstrom - Argonne National Laboratory
	//
	// This Source Code Form is subject to the terms of the Minpack license
	// (a BSD-like license) described in the campaigned CopyrightMINPACK.txt file.

	#ifndef EIGEN_LMPAR_H
	#define EIGEN_LMPAR_H

	namespace Eigen {

	namespace internal {

	template <typename QRSolver, typename VectorType>
	void lmpar2(
	const QRSolver &qr,
	const VectorType &diag,
	const VectorType &qtb,
	typename VectorType::Scalar m_delta,
	typename VectorType::Scalar &par,
	VectorType &x)

	{
	using std::sqrt;
	using std::abs;
	typedef typename QRSolver::MatrixType MatrixType;
	typedef typename QRSolver::Scalar Scalar;
	// typedef typename QRSolver::StorageIndex StorageIndex;

	/* Local variables */
	Index j;
	Scalar fp;
	Scalar parc, parl;
	Index iter;
	Scalar temp, paru;
	Scalar gnorm;
	Scalar dxnorm;

	// Make a copy of the triangular factor.
	// This copy is modified during call the qrsolv
	MatrixType s;
	s = qr.matrixR();

	/* Function Body */
	const Scalar dwarf = (std::numeric_limits<Scalar>::min)();
	const Index n = qr.matrixR().cols();
	eigen_assert(n==diag.size());
	eigen_assert(n==qtb.size());

	VectorType wa1, wa2;

	/* compute and store in x the gauss-newton direction. if the */
	/* jacobian is rank-deficient, obtain a least squares solution. */

	// const Index rank = qr.nonzeroPivots(); // exactly double(0.)
	const Index rank = qr.rank(); // use a threshold
	wa1 = qtb;
	wa1.tail(n-rank).setZero();
	//FIXME There is no solve in place for sparse triangularView
	wa1.head(rank) = s.topLeftCorner(rank,rank).template triangularView<Upper>().solve(qtb.head(rank));

	x = qr.colsPermutation()*wa1;

	/* initialize the iteration counter. */
	/* evaluate the function at the origin, and test */
	/* for acceptance of the gauss-newton direction. */
	iter = 0;
	wa2 = diag.cwiseProduct(x);
	dxnorm = wa2.blueNorm();
	fp = dxnorm - m_delta;
	if (fp <= Scalar(0.1) * m_delta) {
	par = 0;
	return;
	}

	/* if the jacobian is not rank deficient, the newton */
	/* step provides a lower bound, parl, for the zero of */
	/* the function. otherwise set this bound to zero. */
	parl = 0.;
	if (rank==n) {
	wa1 = qr.colsPermutation().inverse() * diag.cwiseProduct(wa2)/dxnorm;
	s.topLeftCorner(n,n).transpose().template triangularView<Lower>().solveInPlace(wa1);
	temp = wa1.blueNorm();
	parl = fp / m_delta / temp / temp;
	}

	/* calculate an upper bound, paru, for the zero of the function. */
	for (j = 0; j < n; ++j)
	wa1[j] = s.col(j).head(j+1).dot(qtb.head(j+1)) / diag[qr.colsPermutation().indices()(j)];

	gnorm = wa1.stableNorm();
	paru = gnorm / m_delta;
	if (paru == 0.)
	paru = dwarf / (std::min)(m_delta,Scalar(0.1));

	/* if the input par lies outside of the interval (parl,paru), */
	/* set par to the closer endpoint. */
	par = (std::max)(par,parl);
	par = (std::min)(par,paru);
	if (par == 0.)
	par = gnorm / dxnorm;

	/* beginning of an iteration. */
	while (true) {
	++iter;

	/* evaluate the function at the current value of par. */
	if (par == 0.)
	par = (std::max)(dwarf,Scalar(.001) * paru); /* Computing MAX */
	wa1 = sqrt(par)* diag;

	VectorType sdiag(n);
	lmqrsolv(s, qr.colsPermutation(), wa1, qtb, x, sdiag);

	wa2 = diag.cwiseProduct(x);
	dxnorm = wa2.blueNorm();
	temp = fp;
	fp = dxnorm - m_delta;

	/* if the function is small enough, accept the current value */
	/* of par. also test for the exceptional cases where parl */
	/* is zero or the number of iterations has reached 10. */
	if (abs(fp) <= Scalar(0.1) * m_delta \|\| (parl == 0. && fp <= temp && temp < 0.) \|\| iter == 10)
	break;

	/* compute the newton correction. */
	wa1 = qr.colsPermutation().inverse() * diag.cwiseProduct(wa2/dxnorm);
	// we could almost use this here, but the diagonal is outside qr, in sdiag[]
	for (j = 0; j < n; ++j) {
	wa1[j] /= sdiag[j];
	temp = wa1[j];
	for (Index i = j+1; i < n; ++i)
	wa1[i] -= s.coeff(i,j) * temp;
	}
	temp = wa1.blueNorm();
	parc = fp / m_delta / temp / temp;

	/* depending on the sign of the function, update parl or paru. */
	if (fp > 0.)
	parl = (std::max)(parl,par);
	if (fp < 0.)
	paru = (std::min)(paru,par);

	/* compute an improved estimate for par. */
	par = (std::max)(parl,par+parc);
	}
	if (iter == 0)
	par = 0.;
	return;
	}
	} // end namespace internal

	} // end namespace Eigen

	#endif // EIGEN_LMPAR_H