bench/btl/libs/mtl4/mtl4_LU_solve_interface.hh - manifest_repos/eigen - Git at Google

 //=====================================================
 // File   :  blitz_LU_solve_interface.hh
 // Author :  L. Plagne <laurent.plagne@edf.fr)>
 // Copyright (C) EDF R&D,  lun sep 30 14:23:31 CEST 2002
 //=====================================================
 //
 // This program is free software; you can redistribute it and/or
 // modify it under the terms of the GNU General Public License
 // as published by the Free Software Foundation; either version 2
 // of the License, or (at your option) any later version.
 //
 // 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 General Public License for more details.
 // You should have received a copy of the GNU General Public License
 // along with this program; if not, write to the Free Software
 // Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
 //
 #ifndef BLITZ_LU_SOLVE_INTERFACE_HH
 #define BLITZ_LU_SOLVE_INTERFACE_HH

 #include "blitz/array.h"
 #include <vector>

 BZ_USING_NAMESPACE(blitz)

 template<class real>
 class blitz_LU_solve_interface : public blitz_interface<real>
 {

 public :

   typedef typename blitz_interface<real>::gene_matrix gene_matrix;
   typedef typename blitz_interface<real>::gene_vector gene_vector;

   typedef blitz::Array<int,1> Pivot_Vector;

   inline static void new_Pivot_Vector(Pivot_Vector & pivot,int N)
   {

     pivot.resize(N);

   }

   inline static void free_Pivot_Vector(Pivot_Vector & pivot)
   {

     return;

   }


   static inline real matrix_vector_product_sliced(const gene_matrix & A, gene_vector B, int row, int col_start, int col_end)
   {

     real somme=0.;

     for (int j=col_start ; j<col_end+1 ; j++){

 	somme+=A(row,j)*B(j);

     }

     return somme;

   }


   static inline real matrix_matrix_product_sliced(gene_matrix & A, int row, int col_start, int col_end, gene_matrix & B, int row_shift, int col )
   {

     real somme=0.;

     for (int j=col_start ; j<col_end+1 ; j++){

 	somme+=A(row,j)*B(j+row_shift,col);

     }

     return somme;

   }

   inline static void LU_factor(gene_matrix & LU, Pivot_Vector & pivot, int N)
   {

     ASSERT( LU.rows()==LU.cols() ) ;
     int index_max = 0 ;
     real big = 0. ;
     real theSum = 0. ;
     real dum = 0. ;
     // Get the implicit scaling information :
     gene_vector ImplicitScaling( N ) ;
     for( int i=0; i<N; i++ ) {
       big = 0. ;
       for( int j=0; j<N; j++ ) {
 	if( abs( LU( i, j ) )>=big ) big = abs( LU( i, j ) ) ;
       }
       if( big==0. ) {
 	INFOS( "blitz_LU_factor::Singular matrix" ) ;
 	exit( 0 ) ;
       }
       ImplicitScaling( i ) = 1./big ;
     }
     // Loop over columns of Crout's method :
     for( int j=0; j<N; j++ ) {
       for( int i=0; i<j; i++ ) {
 	theSum = LU( i, j ) ;
 	theSum -= matrix_matrix_product_sliced(LU, i, 0, i-1, LU, 0, j) ;
 	//	theSum -= sum( LU( i, Range( fromStart, i-1 ) )*LU( Range( fromStart, i-1 ), j ) ) ;
 	LU( i, j ) = theSum ;
       }

       // Search for the largest pivot element :
       big = 0. ;
       for( int i=j; i<N; i++ ) {
 	theSum = LU( i, j ) ;
 	theSum -= matrix_matrix_product_sliced(LU, i, 0, j-1, LU, 0, j) ;
 	//	theSum -= sum( LU( i, Range( fromStart, j-1 ) )*LU( Range( fromStart, j-1 ), j ) ) ;
 	LU( i, j ) = theSum ;
 	if( (ImplicitScaling( i )*abs( theSum ))>=big ) {
 	  dum = ImplicitScaling( i )*abs( theSum ) ;
 	  big = dum ;
 	  index_max = i ;
 	}
       }
       // Interchanging rows and the scale factor :
       if( j!=index_max ) {
 	for( int k=0; k<N; k++ ) {
 	  dum = LU( index_max, k ) ;
 	  LU( index_max, k ) = LU( j, k ) ;
 	  LU( j, k ) = dum ;
 	}
 	ImplicitScaling( index_max ) = ImplicitScaling( j ) ;
       }
       pivot( j ) = index_max ;
       if ( LU( j, j )==0. ) LU( j, j ) = 1.e-20 ;
       // Divide by the pivot element :
       if( j<N ) {
 	dum = 1./LU( j, j ) ;
 	for( int i=j+1; i<N; i++ ) LU( i, j ) *= dum ;
       }
     }

   }

   inline static void LU_solve(const gene_matrix & LU, const Pivot_Vector pivot, gene_vector &B, gene_vector X, int N)
   {

     // Pour conserver le meme header, on travaille sur X, copie du second-membre B
     X = B.copy() ;
     ASSERT( LU.rows()==LU.cols() ) ;
     firstIndex indI ;
     // Forward substitution :
     int ii = 0 ;
     real theSum = 0. ;
     for( int i=0; i<N; i++ ) {
       int ip = pivot( i ) ;
       theSum = X( ip ) ;
       //      theSum = B( ip ) ;
       X( ip ) = X( i ) ;
       //      B( ip ) = B( i ) ;
       if( ii ) {
 	theSum -= matrix_vector_product_sliced(LU, X, i, ii-1, i-1) ;
 	//	theSum -= sum( LU( i, Range( ii-1, i-1 ) )*X( Range( ii-1, i-1 ) ) ) ;
 	//	theSum -= sum( LU( i, Range( ii-1, i-1 ) )*B( Range( ii-1, i-1 ) ) ) ;
       } else if( theSum ) {
 	ii = i+1 ;
       }
       X( i ) = theSum ;
       //      B( i ) = theSum ;
     }
     // Backsubstitution :
     for( int i=N-1; i>=0; i-- ) {
       theSum = X( i ) ;
       //      theSum = B( i ) ;
       theSum -= matrix_vector_product_sliced(LU, X, i, i+1, N) ;
       //      theSum -= sum( LU( i, Range( i+1, toEnd ) )*X( Range( i+1, toEnd ) ) ) ;
       //      theSum -= sum( LU( i, Range( i+1, toEnd ) )*B( Range( i+1, toEnd ) ) ) ;
       // Store a component of the solution vector :
       X( i ) = theSum/LU( i, i ) ;
       //      B( i ) = theSum/LU( i, i ) ;
     }

   }

 };

 #endif
	//=====================================================
	// File : blitz_LU_solve_interface.hh
	// Author : L. Plagne <laurent.plagne@edf.fr)>
	// Copyright (C) EDF R&D, lun sep 30 14:23:31 CEST 2002
	//=====================================================
	//
	// This program is free software; you can redistribute it and/or
	// modify it under the terms of the GNU General Public License
	// as published by the Free Software Foundation; either version 2
	// of the License, or (at your option) any later version.
	//
	// 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 General Public License for more details.
	// You should have received a copy of the GNU General Public License
	// along with this program; if not, write to the Free Software
	// Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
	//
	#ifndef BLITZ_LU_SOLVE_INTERFACE_HH
	#define BLITZ_LU_SOLVE_INTERFACE_HH

	#include "blitz/array.h"
	#include <vector>

	BZ_USING_NAMESPACE(blitz)

	template<class real>
	class blitz_LU_solve_interface : public blitz_interface<real>
	{

	public :

	typedef typename blitz_interface<real>::gene_matrix gene_matrix;
	typedef typename blitz_interface<real>::gene_vector gene_vector;

	typedef blitz::Array<int,1> Pivot_Vector;

	inline static void new_Pivot_Vector(Pivot_Vector & pivot,int N)
	{

	pivot.resize(N);

	}

	inline static void free_Pivot_Vector(Pivot_Vector & pivot)
	{

	return;

	}


	static inline real matrix_vector_product_sliced(const gene_matrix & A, gene_vector B, int row, int col_start, int col_end)
	{

	real somme=0.;

	for (int j=col_start ; j<col_end+1 ; j++){

	somme+=A(row,j)*B(j);

	}

	return somme;

	}




	static inline real matrix_matrix_product_sliced(gene_matrix & A, int row, int col_start, int col_end, gene_matrix & B, int row_shift, int col )
	{

	real somme=0.;

	for (int j=col_start ; j<col_end+1 ; j++){

	somme+=A(row,j)*B(j+row_shift,col);

	}

	return somme;

	}

	inline static void LU_factor(gene_matrix & LU, Pivot_Vector & pivot, int N)
	{

	ASSERT( LU.rows()==LU.cols() ) ;
	int index_max = 0 ;
	real big = 0. ;
	real theSum = 0. ;
	real dum = 0. ;
	// Get the implicit scaling information :
	gene_vector ImplicitScaling( N ) ;
	for( int i=0; i<N; i++ ) {
	big = 0. ;
	for( int j=0; j<N; j++ ) {
	if( abs( LU( i, j ) )>=big ) big = abs( LU( i, j ) ) ;
	}
	if( big==0. ) {
	INFOS( "blitz_LU_factor::Singular matrix" ) ;
	exit( 0 ) ;
	}
	ImplicitScaling( i ) = 1./big ;
	}
	// Loop over columns of Crout's method :
	for( int j=0; j<N; j++ ) {
	for( int i=0; i<j; i++ ) {
	theSum = LU( i, j ) ;
	theSum -= matrix_matrix_product_sliced(LU, i, 0, i-1, LU, 0, j) ;
	// theSum -= sum( LU( i, Range( fromStart, i-1 ) )*LU( Range( fromStart, i-1 ), j ) ) ;
	LU( i, j ) = theSum ;
	}

	// Search for the largest pivot element :
	big = 0. ;
	for( int i=j; i<N; i++ ) {
	theSum = LU( i, j ) ;
	theSum -= matrix_matrix_product_sliced(LU, i, 0, j-1, LU, 0, j) ;
	// theSum -= sum( LU( i, Range( fromStart, j-1 ) )*LU( Range( fromStart, j-1 ), j ) ) ;
	LU( i, j ) = theSum ;
	if( (ImplicitScaling( i )*abs( theSum ))>=big ) {
	dum = ImplicitScaling( i )*abs( theSum ) ;
	big = dum ;
	index_max = i ;
	}
	}
	// Interchanging rows and the scale factor :
	if( j!=index_max ) {
	for( int k=0; k<N; k++ ) {
	dum = LU( index_max, k ) ;
	LU( index_max, k ) = LU( j, k ) ;
	LU( j, k ) = dum ;
	}
	ImplicitScaling( index_max ) = ImplicitScaling( j ) ;
	}
	pivot( j ) = index_max ;
	if ( LU( j, j )==0. ) LU( j, j ) = 1.e-20 ;
	// Divide by the pivot element :
	if( j<N ) {
	dum = 1./LU( j, j ) ;
	for( int i=j+1; i<N; i++ ) LU( i, j ) *= dum ;
	}
	}

	}

	inline static void LU_solve(const gene_matrix & LU, const Pivot_Vector pivot, gene_vector &B, gene_vector X, int N)
	{

	// Pour conserver le meme header, on travaille sur X, copie du second-membre B
	X = B.copy() ;
	ASSERT( LU.rows()==LU.cols() ) ;
	firstIndex indI ;
	// Forward substitution :
	int ii = 0 ;
	real theSum = 0. ;
	for( int i=0; i<N; i++ ) {
	int ip = pivot( i ) ;
	theSum = X( ip ) ;
	// theSum = B( ip ) ;
	X( ip ) = X( i ) ;
	// B( ip ) = B( i ) ;
	if( ii ) {
	theSum -= matrix_vector_product_sliced(LU, X, i, ii-1, i-1) ;
	// theSum -= sum( LU( i, Range( ii-1, i-1 ) )*X( Range( ii-1, i-1 ) ) ) ;
	// theSum -= sum( LU( i, Range( ii-1, i-1 ) )*B( Range( ii-1, i-1 ) ) ) ;
	} else if( theSum ) {
	ii = i+1 ;
	}
	X( i ) = theSum ;
	// B( i ) = theSum ;
	}
	// Backsubstitution :
	for( int i=N-1; i>=0; i-- ) {
	theSum = X( i ) ;
	// theSum = B( i ) ;
	theSum -= matrix_vector_product_sliced(LU, X, i, i+1, N) ;
	// theSum -= sum( LU( i, Range( i+1, toEnd ) )*X( Range( i+1, toEnd ) ) ) ;
	// theSum -= sum( LU( i, Range( i+1, toEnd ) )*B( Range( i+1, toEnd ) ) ) ;
	// Store a component of the solution vector :
	X( i ) = theSum/LU( i, i ) ;
	// B( i ) = theSum/LU( i, i ) ;
	}

	}

	};

	#endif