// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2009 Thomas Capricelli <orzel@freehackers.org> // Copyright (C) 2012 Desire Nuentsa <desire.nuentsa_wakam@inria.fr> // // 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_LMQRSOLV_H #define EIGEN_LMQRSOLV_H
namespace Eigen {
namespace internal {
template <typename Scalar,int Rows, int Cols, typename PermIndex> void lmqrsolv(
Matrix<Scalar,Rows,Cols> &s, const PermutationMatrix<Dynamic,Dynamic,PermIndex> &iPerm, const Matrix<Scalar,Dynamic,1> &diag, const Matrix<Scalar,Dynamic,1> &qtb,
Matrix<Scalar,Dynamic,1> &x,
Matrix<Scalar,Dynamic,1> &sdiag)
{ /* Local variables */
Index i, j, k;
Scalar temp;
Index n = s.cols();
Matrix<Scalar,Dynamic,1> wa(n);
JacobiRotation<Scalar> givens;
/* Function Body */ // the following will only change the lower triangular part of s, including // the diagonal, though the diagonal is restored afterward
/* copy r and (q transpose)*b to preserve input and initialize s. */ /* in particular, save the diagonal elements of r in x. */
x = s.diagonal();
wa = qtb;
s.topLeftCorner(n,n).template triangularView<StrictlyLower>() = s.topLeftCorner(n,n).transpose(); /* eliminate the diagonal matrix d using a givens rotation. */ for (j = 0; j < n; ++j) {
/* prepare the row of d to be eliminated, locating the */ /* diagonal element using p from the qr factorization. */ const PermIndex l = iPerm.indices()(j); if (diag[l] == 0.) break;
sdiag.tail(n-j).setZero();
sdiag[j] = diag[l];
/* the transformations to eliminate the row of d */ /* modify only a single element of (q transpose)*b */ /* beyond the first n, which is initially zero. */
Scalar qtbpj = 0.; for (k = j; k < n; ++k) { /* determine a givens rotation which eliminates the */ /* appropriate element in the current row of d. */
givens.makeGivens(-s(k,k), sdiag[k]);
/* compute the modified diagonal element of r and */ /* the modified element of ((q transpose)*b,0). */
s(k,k) = givens.c() * s(k,k) + givens.s() * sdiag[k];
temp = givens.c() * wa[k] + givens.s() * qtbpj;
qtbpj = -givens.s() * wa[k] + givens.c() * qtbpj;
wa[k] = temp;
/* accumulate the transformation in the row of s. */ for (i = k+1; i<n; ++i) {
temp = givens.c() * s(i,k) + givens.s() * sdiag[i];
sdiag[i] = -givens.s() * s(i,k) + givens.c() * sdiag[i];
s(i,k) = temp;
}
}
}
/* solve the triangular system for z. if the system is */ /* singular, then obtain a least squares solution. */
Index nsing; for(nsing=0; nsing<n && sdiag[nsing]!=0; nsing++) {}
/* permute the components of z back to components of x. */
x = iPerm * wa;
}
template <typename Scalar, int _Options, typename Index> void lmqrsolv(
SparseMatrix<Scalar,_Options,Index> &s, const PermutationMatrix<Dynamic,Dynamic> &iPerm, const Matrix<Scalar,Dynamic,1> &diag, const Matrix<Scalar,Dynamic,1> &qtb,
Matrix<Scalar,Dynamic,1> &x,
Matrix<Scalar,Dynamic,1> &sdiag)
{ /* Local variables */ typedef SparseMatrix<Scalar,RowMajor,Index> FactorType;
Index i, j, k, l;
Scalar temp;
Index n = s.cols();
Matrix<Scalar,Dynamic,1> wa(n);
JacobiRotation<Scalar> givens;
/* Function Body */ // the following will only change the lower triangular part of s, including // the diagonal, though the diagonal is restored afterward
/* copy r and (q transpose)*b to preserve input and initialize R. */
wa = qtb;
FactorType R(s); // Eliminate the diagonal matrix d using a givens rotation for (j = 0; j < n; ++j)
{ // Prepare the row of d to be eliminated, locating the // diagonal element using p from the qr factorization
l = iPerm.indices()(j); if (diag(l) == Scalar(0)) break;
sdiag.tail(n-j).setZero();
sdiag[j] = diag[l]; // the transformations to eliminate the row of d // modify only a single element of (q transpose)*b // beyond the first n, which is initially zero.
Scalar qtbpj = 0; // Browse the nonzero elements of row j of the upper triangular s for (k = j; k < n; ++k)
{ typename FactorType::InnerIterator itk(R,k); for (; itk; ++itk){ if (itk.index() < k) continue; elsebreak;
} //At this point, we have the diagonal element R(k,k) // Determine a givens rotation which eliminates // the appropriate element in the current row of d
givens.makeGivens(-itk.value(), sdiag(k));
// Compute the modified diagonal element of r and // the modified element of ((q transpose)*b,0).
itk.valueRef() = givens.c() * itk.value() + givens.s() * sdiag(k);
temp = givens.c() * wa(k) + givens.s() * qtbpj;
qtbpj = -givens.s() * wa(k) + givens.c() * qtbpj;
wa(k) = temp;
// Accumulate the transformation in the remaining k row/column of R for (++itk; itk; ++itk)
{
i = itk.index();
temp = givens.c() * itk.value() + givens.s() * sdiag(i);
sdiag(i) = -givens.s() * itk.value() + givens.c() * sdiag(i);
itk.valueRef() = temp;
}
}
}
// Solve the triangular system for z. If the system is // singular, then obtain a least squares solution
Index nsing; for(nsing = 0; nsing<n && sdiag(nsing) !=0; nsing++) {}
wa.tail(n-nsing).setZero(); // x = wa;
wa.head(nsing) = R.topLeftCorner(nsing,nsing).template triangularView<Upper>().solve/*InPlace*/(wa.head(nsing));
sdiag = R.diagonal(); // Permute the components of z back to components of x
x = iPerm * wa;
}
} // end namespace internal
} // end namespace Eigen
#endif// EIGEN_LMQRSOLV_H
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