unsupported/Eigen/src/IterativeSolvers/ConstrainedConjGrad.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>

 /* NOTE The functions of this file have been adapted from the GMM++ library */

 //========================================================================
 //
 // Copyright (C) 2002-2007 Yves Renard
 //
 // This file is a part of GETFEM++
 //
 // Getfem++ is free software; you can redistribute it and/or modify
 // it under the terms of the GNU Lesser General Public License as
 // published by the Free Software Foundation; version 2.1 of the License.
 //
 // This program is distributed in the hope that it will be useful,
 // but WITHOUT ANY WARRANTY; without even the implied warranty of
 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 // GNU Lesser General Public License for more details.
 // You should have received a copy of the GNU Lesser General Public
 // License along with this program; if not, write to the Free Software
 // Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301,
 // USA.
 //
 //========================================================================

 #include "../../../../Eigen/src/Core/util/NonMPL2.h"

 #ifndef EIGEN_CONSTRAINEDCG_H
 #define EIGEN_CONSTRAINEDCG_H

 #include <Eigen/Core>

 namespace Eigen {

 namespace internal {

 /** \ingroup IterativeSolvers_Module
   * Compute the pseudo inverse of the non-square matrix C such that
   * \f$ CINV = (C * C^T)^{-1} * C \f$ based on a conjugate gradient method.
   *
   * This function is internally used by constrained_cg.
   */
 template <typename CMatrix, typename CINVMatrix>
 void pseudo_inverse(const CMatrix &C, CINVMatrix &CINV)
 {
   // optimisable : copie de la ligne, precalcul de C * trans(C).
   typedef typename CMatrix::Scalar Scalar;
   typedef typename CMatrix::Index Index;
   // FIXME use sparse vectors ?
   typedef Matrix<Scalar,Dynamic,1> TmpVec;

   Index rows = C.rows(), cols = C.cols();

   TmpVec d(rows), e(rows), l(cols), p(rows), q(rows), r(rows);
   Scalar rho, rho_1, alpha;
   d.setZero();

   typedef Triplet<double> T;
   std::vector<T> tripletList;

   for (Index i = 0; i < rows; ++i)
   {
     d[i] = 1.0;
     rho = 1.0;
     e.setZero();
     r = d;
     p = d;

     while (rho >= 1e-38)
     { /* conjugate gradient to compute e             */
       /* which is the i-th row of inv(C * trans(C))  */
       l = C.transpose() * p;
       q = C * l;
       alpha = rho / p.dot(q);
       e +=  alpha * p;
       r += -alpha * q;
       rho_1 = rho;
       rho = r.dot(r);
       p = (rho/rho_1) * p + r;
     }

     l = C.transpose() * e; // l is the i-th row of CINV
     // FIXME add a generic "prune/filter" expression for both dense and sparse object to sparse
     for (Index j=0; j<l.size(); ++j)
       if (l[j]<1e-15)
 	tripletList.push_back(T(i,j,l(j)));


     d[i] = 0.0;
   }
   CINV.setFromTriplets(tripletList.begin(), tripletList.end());
 }


 /** \ingroup IterativeSolvers_Module
   * Constrained conjugate gradient
   *
   * Computes the minimum of \f$ 1/2((Ax).x) - bx \f$ under the contraint \f$ Cx \le f \f$
   */
 template<typename TMatrix, typename CMatrix,
          typename VectorX, typename VectorB, typename VectorF>
 void constrained_cg(const TMatrix& A, const CMatrix& C, VectorX& x,
                        const VectorB& b, const VectorF& f, IterationController &iter)
 {
   using std::sqrt;
   typedef typename TMatrix::Scalar Scalar;
   typedef typename TMatrix::Index Index;
   typedef Matrix<Scalar,Dynamic,1>  TmpVec;

   Scalar rho = 1.0, rho_1, lambda, gamma;
   Index xSize = x.size();
   TmpVec  p(xSize), q(xSize), q2(xSize),
           r(xSize), old_z(xSize), z(xSize),
           memox(xSize);
   std::vector<bool> satured(C.rows());
   p.setZero();
   iter.setRhsNorm(sqrt(b.dot(b))); // gael vect_sp(PS, b, b)
   if (iter.rhsNorm() == 0.0) iter.setRhsNorm(1.0);

   SparseMatrix<Scalar,RowMajor> CINV(C.rows(), C.cols());
   pseudo_inverse(C, CINV);

   while(true)
   {
     // computation of residual
     old_z = z;
     memox = x;
     r = b;
     r += A * -x;
     z = r;
     bool transition = false;
     for (Index i = 0; i < C.rows(); ++i)
     {
       Scalar al = C.row(i).dot(x) - f.coeff(i);
       if (al >= -1.0E-15)
       {
         if (!satured[i])
         {
           satured[i] = true;
           transition = true;
         }
         Scalar bb = CINV.row(i).dot(z);
         if (bb > 0.0)
           // FIXME: we should allow that: z += -bb * C.row(i);
           for (typename CMatrix::InnerIterator it(C,i); it; ++it)
             z.coeffRef(it.index()) -= bb*it.value();
       }
       else
         satured[i] = false;
     }

     // descent direction
     rho_1 = rho;
     rho = r.dot(z);

     if (iter.finished(rho)) break;

     if (iter.noiseLevel() > 0 && transition) std::cerr << "CCG: transition\n";
     if (transition || iter.first()) gamma = 0.0;
     else gamma = (std::max)(0.0, (rho - old_z.dot(z)) / rho_1);
     p = z + gamma*p;

     ++iter;
     // one dimensionnal optimization
     q = A * p;
     lambda = rho / q.dot(p);
     for (Index i = 0; i < C.rows(); ++i)
     {
       if (!satured[i])
       {
         Scalar bb = C.row(i).dot(p) - f[i];
         if (bb > 0.0)
           lambda = (std::min)(lambda, (f.coeff(i)-C.row(i).dot(x)) / bb);
       }
     }
     x += lambda * p;
     memox -= x;
   }
 }

 } // end namespace internal

 } // end namespace Eigen

 #endif // EIGEN_CONSTRAINEDCG_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr>

	/* NOTE The functions of this file have been adapted from the GMM++ library */

	//========================================================================
	//
	// Copyright (C) 2002-2007 Yves Renard
	//
	// This file is a part of GETFEM++
	//
	// Getfem++ is free software; you can redistribute it and/or modify
	// it under the terms of the GNU Lesser General Public License as
	// published by the Free Software Foundation; version 2.1 of the License.
	//
	// This program is distributed in the hope that it will be useful,
	// but WITHOUT ANY WARRANTY; without even the implied warranty of
	// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	// GNU Lesser General Public License for more details.
	// You should have received a copy of the GNU Lesser General Public
	// License along with this program; if not, write to the Free Software
	// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301,
	// USA.
	//
	//========================================================================

	#include "../../../../Eigen/src/Core/util/NonMPL2.h"

	#ifndef EIGEN_CONSTRAINEDCG_H
	#define EIGEN_CONSTRAINEDCG_H

	#include <Eigen/Core>

	namespace Eigen {

	namespace internal {

	/** \ingroup IterativeSolvers_Module
	* Compute the pseudo inverse of the non-square matrix C such that
	* \f$ CINV = (C * C^T)^{-1} * C \f$ based on a conjugate gradient method.
	*
	* This function is internally used by constrained_cg.
	*/
	template <typename CMatrix, typename CINVMatrix>
	void pseudo_inverse(const CMatrix &C, CINVMatrix &CINV)
	{
	// optimisable : copie de la ligne, precalcul de C * trans(C).
	typedef typename CMatrix::Scalar Scalar;
	typedef typename CMatrix::Index Index;
	// FIXME use sparse vectors ?
	typedef Matrix<Scalar,Dynamic,1> TmpVec;

	Index rows = C.rows(), cols = C.cols();

	TmpVec d(rows), e(rows), l(cols), p(rows), q(rows), r(rows);
	Scalar rho, rho_1, alpha;
	d.setZero();

	typedef Triplet<double> T;
	std::vector<T> tripletList;

	for (Index i = 0; i < rows; ++i)
	{
	d[i] = 1.0;
	rho = 1.0;
	e.setZero();
	r = d;
	p = d;

	while (rho >= 1e-38)
	{ /* conjugate gradient to compute e */
	/* which is the i-th row of inv(C * trans(C)) */
	l = C.transpose() * p;
	q = C * l;
	alpha = rho / p.dot(q);
	e += alpha * p;
	r += -alpha * q;
	rho_1 = rho;
	rho = r.dot(r);
	p = (rho/rho_1) * p + r;
	}

	l = C.transpose() * e; // l is the i-th row of CINV
	// FIXME add a generic "prune/filter" expression for both dense and sparse object to sparse
	for (Index j=0; j<l.size(); ++j)
	if (l[j]<1e-15)
	tripletList.push_back(T(i,j,l(j)));


	d[i] = 0.0;
	}
	CINV.setFromTriplets(tripletList.begin(), tripletList.end());
	}



	/** \ingroup IterativeSolvers_Module
	* Constrained conjugate gradient
	*
	* Computes the minimum of \f$ 1/2((Ax).x) - bx \f$ under the contraint \f$ Cx \le f \f$
	*/
	template<typename TMatrix, typename CMatrix,
	typename VectorX, typename VectorB, typename VectorF>
	void constrained_cg(const TMatrix& A, const CMatrix& C, VectorX& x,
	const VectorB& b, const VectorF& f, IterationController &iter)
	{
	using std::sqrt;
	typedef typename TMatrix::Scalar Scalar;
	typedef typename TMatrix::Index Index;
	typedef Matrix<Scalar,Dynamic,1> TmpVec;

	Scalar rho = 1.0, rho_1, lambda, gamma;
	Index xSize = x.size();
	TmpVec p(xSize), q(xSize), q2(xSize),
	r(xSize), old_z(xSize), z(xSize),
	memox(xSize);
	std::vector<bool> satured(C.rows());
	p.setZero();
	iter.setRhsNorm(sqrt(b.dot(b))); // gael vect_sp(PS, b, b)
	if (iter.rhsNorm() == 0.0) iter.setRhsNorm(1.0);

	SparseMatrix<Scalar,RowMajor> CINV(C.rows(), C.cols());
	pseudo_inverse(C, CINV);

	while(true)
	{
	// computation of residual
	old_z = z;
	memox = x;
	r = b;
	r += A * -x;
	z = r;
	bool transition = false;
	for (Index i = 0; i < C.rows(); ++i)
	{
	Scalar al = C.row(i).dot(x) - f.coeff(i);
	if (al >= -1.0E-15)
	{
	if (!satured[i])
	{
	satured[i] = true;
	transition = true;
	}
	Scalar bb = CINV.row(i).dot(z);
	if (bb > 0.0)
	// FIXME: we should allow that: z += -bb * C.row(i);
	for (typename CMatrix::InnerIterator it(C,i); it; ++it)
	z.coeffRef(it.index()) -= bb*it.value();
	}
	else
	satured[i] = false;
	}

	// descent direction
	rho_1 = rho;
	rho = r.dot(z);

	if (iter.finished(rho)) break;

	if (iter.noiseLevel() > 0 && transition) std::cerr << "CCG: transition\n";
	if (transition \|\| iter.first()) gamma = 0.0;
	else gamma = (std::max)(0.0, (rho - old_z.dot(z)) / rho_1);
	p = z + gamma*p;

	++iter;
	// one dimensionnal optimization
	q = A * p;
	lambda = rho / q.dot(p);
	for (Index i = 0; i < C.rows(); ++i)
	{
	if (!satured[i])
	{
	Scalar bb = C.row(i).dot(p) - f[i];
	if (bb > 0.0)
	lambda = (std::min)(lambda, (f.coeff(i)-C.row(i).dot(x)) / bb);
	}
	}
	x += lambda * p;
	memox -= x;
	}
	}

	} // end namespace internal

	} // end namespace Eigen

	#endif // EIGEN_CONSTRAINEDCG_H