js8call/.svn/pristine/f7/f7e619cc8f091bda3a605b1b57dc154f12ea991e.svn-base

/*
[begin_description]
Modification of the implicit Euler method, works with the MTL4 matrix library only. 
[end_description]

Copyright 2012-2013 Andreas Angelopoulos
Copyright 2012-2013 Karsten Ahnert
Copyright 2012-2013 Mario Mulansky

Distributed under the Boost Software License, Version 1.0.
(See accompanying file LICENSE_1_0.txt or
copy at http://www.boost.org/LICENSE_1_0.txt)
*/


#ifndef BOOST_NUMERIC_ODEINT_EXTERNAL_IMPLICIT_EULER_MTL4_HPP_INCLUDED
#define BOOST_NUMERIC_ODEINT_EXTERNAL_IMPLICIT_EULER_MTL4_HPP_INCLUDED


#include <utility>

#include <boost/numeric/odeint/util/bind.hpp>
#include <boost/numeric/odeint/util/unwrap_reference.hpp>
#include <boost/numeric/odeint/stepper/stepper_categories.hpp>

#include <boost/numeric/odeint/external/mtl4/mtl4_resize.hpp>

#include <boost/numeric/mtl/mtl.hpp>
#include <boost/numeric/itl/itl.hpp>


namespace boost {
namespace numeric {
namespace odeint {


template< class ValueType , class Resizer = initially_resizer >
class implicit_euler_mtl4
{

public:

    typedef ValueType value_type;
    typedef value_type time_type;
    typedef mtl::dense_vector<value_type> state_type;

    typedef state_wrapper< state_type > wrapped_state_type;
    typedef state_type deriv_type;
    typedef state_wrapper< deriv_type > wrapped_deriv_type;
    typedef mtl::compressed2D< value_type > matrix_type;
    typedef state_wrapper< matrix_type > wrapped_matrix_type;

    typedef Resizer resizer_type;
    typedef stepper_tag stepper_category;

    typedef implicit_euler_mtl4< ValueType , Resizer > stepper_type;


    implicit_euler_mtl4( const value_type epsilon = 1E-6 )
        : m_epsilon( epsilon ) , m_resizer() ,
          m_dxdt() , m_x() ,
          m_identity() , m_jacobi()
    { }


    template< class System >
    void do_step( System system , state_type &x , time_type t , time_type dt )
    {
        typedef typename odeint::unwrap_reference< System >::type system_type;
        typedef typename odeint::unwrap_reference< typename system_type::first_type >::type deriv_func_type;
        typedef typename odeint::unwrap_reference< typename system_type::second_type >::type jacobi_func_type;
        system_type &sys = system;
        deriv_func_type &deriv_func = sys.first;
        jacobi_func_type &jacobi_func = sys.second;

        m_resizer.adjust_size( x , detail::bind(
                                   &stepper_type::template resize_impl< state_type > , detail::ref( *this ) , detail::_1 ) );

        m_identity.m_v = 1;

        t += dt;
        m_x.m_v = x;

        deriv_func( x , m_dxdt.m_v , t );
        jacobi_func( x , m_jacobi.m_v , t );


        m_dxdt.m_v *= -dt;

        m_jacobi.m_v *= dt;
        m_jacobi.m_v -= m_identity.m_v ;


        // using ilu_0 preconditioning -incomplete LU factorisation
        // itl::pc::diagonal<matrix_type,double> L(m_jacobi.m_v);
        itl::pc::ilu_0<matrix_type> L( m_jacobi.m_v );

        solve( m_jacobi.m_v , m_x.m_v , m_dxdt.m_v , L );
        x+= m_x.m_v;


    }


    template< class StateType >
    void adjust_size( const StateType &x )
    {
        resize_impl( x );
    }


private:


    /*
      Applying approximate iterative linear solvers
      default solver is Biconjugate gradient stabilized method
      itl::bicgstab(A, x, b, L, iter);
    */
    template < class LinearOperator, class HilbertSpaceX, class HilbertSpaceB, class Preconditioner>
    void solve(const LinearOperator& A, HilbertSpaceX& x, const HilbertSpaceB& b,
               const Preconditioner& L, int max_iteractions =500)
    {
        // Termination criterion: r < 1e-6 * b or N iterations
        itl::basic_iteration< double > iter( b , max_iteractions , 1e-6 );
        itl::bicgstab( A , x , b , L , iter );

    }


    template< class StateIn >
    bool resize_impl( const StateIn &x )
    {
        bool resized = false;
        resized |= adjust_size_by_resizeability( m_dxdt , x , typename is_resizeable<deriv_type>::type() );
        resized |= adjust_size_by_resizeability( m_x , x , typename is_resizeable<state_type>::type() );
        resized |= adjust_size_by_resizeability( m_identity , x , typename is_resizeable<matrix_type>::type() );
        resized |= adjust_size_by_resizeability( m_jacobi , x , typename is_resizeable<matrix_type>::type() );
        return resized;
    }


private:

    value_type m_epsilon;
    resizer_type m_resizer;
    wrapped_deriv_type m_dxdt;
    wrapped_state_type m_x;
    wrapped_matrix_type m_identity;
    wrapped_matrix_type m_jacobi;
};


} // odeint
} // numeric
} // boost


#endif // BOOST_NUMERIC_ODEINT_EXTERNAL_IMPLICIT_EULER_MTL4_HPP_INCLUDED
Initial Commit 2018-02-08 21:28:33 -05:00			`/*`
			`[begin_description]`
			`Modification of the implicit Euler method, works with the MTL4 matrix library only.`
			`[end_description]`

			`Copyright 2012-2013 Andreas Angelopoulos`
			`Copyright 2012-2013 Karsten Ahnert`
			`Copyright 2012-2013 Mario Mulansky`

			`Distributed under the Boost Software License, Version 1.0.`
			`(See accompanying file LICENSE_1_0.txt or`
			`copy at http://www.boost.org/LICENSE_1_0.txt)`
			`*/`


			`#ifndef BOOST_NUMERIC_ODEINT_EXTERNAL_IMPLICIT_EULER_MTL4_HPP_INCLUDED`
			`#define BOOST_NUMERIC_ODEINT_EXTERNAL_IMPLICIT_EULER_MTL4_HPP_INCLUDED`


			`#include <utility>`

			`#include <boost/numeric/odeint/util/bind.hpp>`
			`#include <boost/numeric/odeint/util/unwrap_reference.hpp>`
			`#include <boost/numeric/odeint/stepper/stepper_categories.hpp>`

			`#include <boost/numeric/odeint/external/mtl4/mtl4_resize.hpp>`

			`#include <boost/numeric/mtl/mtl.hpp>`
			`#include <boost/numeric/itl/itl.hpp>`




			`namespace boost {`
			`namespace numeric {`
			`namespace odeint {`


			`template< class ValueType , class Resizer = initially_resizer >`
			`class implicit_euler_mtl4`
			`{`

			`public:`

			`typedef ValueType value_type;`
			`typedef value_type time_type;`
			`typedef mtl::dense_vector<value_type> state_type;`

			`typedef state_wrapper< state_type > wrapped_state_type;`
			`typedef state_type deriv_type;`
			`typedef state_wrapper< deriv_type > wrapped_deriv_type;`
			`typedef mtl::compressed2D< value_type > matrix_type;`
			`typedef state_wrapper< matrix_type > wrapped_matrix_type;`

			`typedef Resizer resizer_type;`
			`typedef stepper_tag stepper_category;`

			`typedef implicit_euler_mtl4< ValueType , Resizer > stepper_type;`


			`implicit_euler_mtl4( const value_type epsilon = 1E-6 )`
			`: m_epsilon( epsilon ) , m_resizer() ,`
			`m_dxdt() , m_x() ,`
			`m_identity() , m_jacobi()`
			`{ }`


			`template< class System >`
			`void do_step( System system , state_type &x , time_type t , time_type dt )`
			`{`
			`typedef typename odeint::unwrap_reference< System >::type system_type;`
			`typedef typename odeint::unwrap_reference< typename system_type::first_type >::type deriv_func_type;`
			`typedef typename odeint::unwrap_reference< typename system_type::second_type >::type jacobi_func_type;`
			`system_type &sys = system;`
			`deriv_func_type &deriv_func = sys.first;`
			`jacobi_func_type &jacobi_func = sys.second;`

			`m_resizer.adjust_size( x , detail::bind(`
			`&stepper_type::template resize_impl< state_type > , detail::ref( *this ) , detail::_1 ) );`

			`m_identity.m_v = 1;`

			`t += dt;`
			`m_x.m_v = x;`

			`deriv_func( x , m_dxdt.m_v , t );`
			`jacobi_func( x , m_jacobi.m_v , t );`


			`m_dxdt.m_v *= -dt;`

			`m_jacobi.m_v *= dt;`
			`m_jacobi.m_v -= m_identity.m_v ;`



			`// using ilu_0 preconditioning -incomplete LU factorisation`
			`// itl::pc::diagonal<matrix_type,double> L(m_jacobi.m_v);`
			`itl::pc::ilu_0<matrix_type> L( m_jacobi.m_v );`

			`solve( m_jacobi.m_v , m_x.m_v , m_dxdt.m_v , L );`
			`x+= m_x.m_v;`


			`}`


			`template< class StateType >`
			`void adjust_size( const StateType &x )`
			`{`
			`resize_impl( x );`
			`}`


			`private:`


			`/*`
			`Applying approximate iterative linear solvers`
			`default solver is Biconjugate gradient stabilized method`
			`itl::bicgstab(A, x, b, L, iter);`
			`*/`
			`template < class LinearOperator, class HilbertSpaceX, class HilbertSpaceB, class Preconditioner>`
			`void solve(const LinearOperator& A, HilbertSpaceX& x, const HilbertSpaceB& b,`
			`const Preconditioner& L, int max_iteractions =500)`
			`{`
			`// Termination criterion: r < 1e-6 * b or N iterations`
			`itl::basic_iteration< double > iter( b , max_iteractions , 1e-6 );`
			`itl::bicgstab( A , x , b , L , iter );`

			`}`


			`template< class StateIn >`
			`bool resize_impl( const StateIn &x )`
			`{`
			`bool resized = false;`
			`resized \|= adjust_size_by_resizeability( m_dxdt , x , typename is_resizeable<deriv_type>::type() );`
			`resized \|= adjust_size_by_resizeability( m_x , x , typename is_resizeable<state_type>::type() );`
			`resized \|= adjust_size_by_resizeability( m_identity , x , typename is_resizeable<matrix_type>::type() );`
			`resized \|= adjust_size_by_resizeability( m_jacobi , x , typename is_resizeable<matrix_type>::type() );`
			`return resized;`
			`}`


			`private:`

			`value_type m_epsilon;`
			`resizer_type m_resizer;`
			`wrapped_deriv_type m_dxdt;`
			`wrapped_state_type m_x;`
			`wrapped_matrix_type m_identity;`
			`wrapped_matrix_type m_jacobi;`
			`};`


			`} // odeint`
			`} // numeric`
			`} // boost`


			`#endif // BOOST_NUMERIC_ODEINT_EXTERNAL_IMPLICIT_EULER_MTL4_HPP_INCLUDED`