third_party/boost/numeric/odeint/include/boost/numeric/odeint/stepper/runge_kutta_cash_karp54_classic.hpp - platform/external/sdv/vsomeip - Git at Google

 /*
  [auto_generated]
  boost/numeric/odeint/stepper/runge_kutta_cash_karp54_classic.hpp

  [begin_description]
  Classical implementation of the Runge-Kutta Cash-Karp 5(4) method.
  [end_description]

  Copyright 2010-2013 Mario Mulansky
  Copyright 2010-2013 Karsten Ahnert
  Copyright 2012 Christoph Koke

  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_STEPPER_RUNGE_KUTTA_CASH_KARP54_CLASSIC_HPP_INCLUDED
 #define BOOST_NUMERIC_ODEINT_STEPPER_RUNGE_KUTTA_CASH_KARP54_CLASSIC_HPP_INCLUDED


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

 #include <boost/numeric/odeint/stepper/base/explicit_error_stepper_base.hpp>
 #include <boost/numeric/odeint/algebra/range_algebra.hpp>
 #include <boost/numeric/odeint/algebra/default_operations.hpp>
 #include <boost/numeric/odeint/algebra/algebra_dispatcher.hpp>
 #include <boost/numeric/odeint/algebra/operations_dispatcher.hpp>
 #include <boost/numeric/odeint/stepper/stepper_categories.hpp>
 #include <boost/numeric/odeint/util/state_wrapper.hpp>
 #include <boost/numeric/odeint/util/is_resizeable.hpp>
 #include <boost/numeric/odeint/util/resizer.hpp>

 namespace boost {
 namespace numeric {
 namespace odeint {


 template<
 class State ,
 class Value = double ,
 class Deriv = State ,
 class Time = Value ,
 class Algebra = typename algebra_dispatcher< State >::algebra_type ,
 class Operations = typename operations_dispatcher< State >::operations_type ,
 class Resizer = initially_resizer
 >
 #ifndef DOXYGEN_SKIP
 class runge_kutta_cash_karp54_classic
 : public explicit_error_stepper_base<
   runge_kutta_cash_karp54_classic< State , Value , Deriv , Time , Algebra , Operations , Resizer > ,
   5 , 5 , 4 , State , Value , Deriv , Time , Algebra , Operations , Resizer >
 #else
 class runge_kutta_cash_karp54_classic : public explicit_error_stepper_base
 #endif
 {


 public :

     #ifndef DOXYGEN_SKIP
     typedef explicit_error_stepper_base<
     runge_kutta_cash_karp54_classic< State , Value , Deriv , Time , Algebra , Operations , Resizer > ,
     5 , 5 , 4 , State , Value , Deriv , Time , Algebra , Operations , Resizer > stepper_base_type;
     #else
     typedef explicit_error_stepper_base< runge_kutta_cash_karp54_classic< ... > , ... > stepper_base_type;
     #endif

     typedef typename stepper_base_type::state_type state_type;
     typedef typename stepper_base_type::value_type value_type;
     typedef typename stepper_base_type::deriv_type deriv_type;
     typedef typename stepper_base_type::time_type time_type;
     typedef typename stepper_base_type::algebra_type algebra_type;
     typedef typename stepper_base_type::operations_type operations_type;
     typedef typename stepper_base_type::resizer_type resizer_type;

     #ifndef DOXYGEN_SKIP
     typedef typename stepper_base_type::wrapped_state_type wrapped_state_type;
     typedef typename stepper_base_type::wrapped_deriv_type wrapped_deriv_type;
     typedef typename stepper_base_type::stepper_type stepper_type;
     #endif


     runge_kutta_cash_karp54_classic( const algebra_type &algebra = algebra_type() ) : stepper_base_type( algebra )
     { }


     template< class System , class StateIn , class DerivIn , class StateOut , class Err >
     void do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt , Err &xerr )
     {
         const value_type c1 = static_cast<value_type> ( 37 ) / static_cast<value_type>( 378 );
         const value_type c3 = static_cast<value_type> ( 250 ) / static_cast<value_type>( 621 );
         const value_type c4 = static_cast<value_type> ( 125 ) / static_cast<value_type>( 594 );
         const value_type c6 = static_cast<value_type> ( 512 ) / static_cast<value_type>( 1771 );

         const value_type dc1 = c1 - static_cast<value_type> ( 2825 ) / static_cast<value_type>( 27648 );
         const value_type dc3 = c3 - static_cast<value_type> ( 18575 ) / static_cast<value_type>( 48384 );
         const value_type dc4 = c4 - static_cast<value_type> ( 13525 ) / static_cast<value_type>( 55296 );
         const value_type dc5 = static_cast<value_type> ( -277 ) / static_cast<value_type>( 14336 );
         const value_type dc6 = c6 - static_cast<value_type> ( 1 ) / static_cast<value_type> ( 4 );

         do_step_impl( system , in , dxdt , t , out , dt );

         //error estimate
         stepper_base_type::m_algebra.for_each6( xerr , dxdt , m_k3.m_v , m_k4.m_v , m_k5.m_v , m_k6.m_v ,
                 typename operations_type::template scale_sum5< time_type , time_type , time_type , time_type , time_type >( dt*dc1 , dt*dc3 , dt*dc4 , dt*dc5 , dt*dc6 ));

     }


     template< class System , class StateIn , class DerivIn , class StateOut >
     void do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt )
     {
         const value_type a2 = static_cast<value_type> ( 1 ) / static_cast<value_type> ( 5 );
         const value_type a3 = static_cast<value_type> ( 3 ) / static_cast<value_type> ( 10 );
         const value_type a4 = static_cast<value_type> ( 3 ) / static_cast<value_type> ( 5 );
         const value_type a5 = static_cast<value_type> ( 1 );
         const value_type a6 = static_cast<value_type> ( 7 ) / static_cast<value_type> ( 8 );

         const value_type b21 = static_cast<value_type> ( 1 ) / static_cast<value_type> ( 5 );
         const value_type b31 = static_cast<value_type> ( 3 ) / static_cast<value_type>( 40 );
         const value_type b32 = static_cast<value_type> ( 9 ) / static_cast<value_type>( 40 );
         const value_type b41 = static_cast<value_type> ( 3 ) / static_cast<value_type> ( 10 );
         const value_type b42 = static_cast<value_type> ( -9 ) / static_cast<value_type> ( 10 );
         const value_type b43 = static_cast<value_type> ( 6 ) / static_cast<value_type> ( 5 );
         const value_type b51 = static_cast<value_type> ( -11 ) / static_cast<value_type>( 54 );
         const value_type b52 = static_cast<value_type> ( 5 ) / static_cast<value_type> ( 2 );
         const value_type b53 = static_cast<value_type> ( -70 ) / static_cast<value_type>( 27 );
         const value_type b54 = static_cast<value_type> ( 35 ) / static_cast<value_type>( 27 );
         const value_type b61 = static_cast<value_type> ( 1631 ) / static_cast<value_type>( 55296 );
         const value_type b62 = static_cast<value_type> ( 175 ) / static_cast<value_type>( 512 );
         const value_type b63 = static_cast<value_type> ( 575 ) / static_cast<value_type>( 13824 );
         const value_type b64 = static_cast<value_type> ( 44275 ) / static_cast<value_type>( 110592 );
         const value_type b65 = static_cast<value_type> ( 253 ) / static_cast<value_type>( 4096 );

         const value_type c1 = static_cast<value_type> ( 37 ) / static_cast<value_type>( 378 );
         const value_type c3 = static_cast<value_type> ( 250 ) / static_cast<value_type>( 621 );
         const value_type c4 = static_cast<value_type> ( 125 ) / static_cast<value_type>( 594 );
         const value_type c6 = static_cast<value_type> ( 512 ) / static_cast<value_type>( 1771 );

         typename odeint::unwrap_reference< System >::type &sys = system;

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

         //m_x1 = x + dt*b21*dxdt
         stepper_base_type::m_algebra.for_each3( m_x_tmp.m_v , in , dxdt ,
                 typename operations_type::template scale_sum2< value_type , time_type >( 1.0 , dt*b21 ) );

         sys( m_x_tmp.m_v , m_k2.m_v , t + dt*a2 );
         // m_x_tmp = x + dt*b31*dxdt + dt*b32*m_x2
         stepper_base_type::m_algebra.for_each4( m_x_tmp.m_v , in , dxdt , m_k2.m_v ,
                 typename operations_type::template scale_sum3< value_type , time_type , time_type >( 1.0 , dt*b31 , dt*b32 ));

         sys( m_x_tmp.m_v , m_k3.m_v , t + dt*a3 );
         // m_x_tmp = x + dt * (b41*dxdt + b42*m_x2 + b43*m_x3)
         stepper_base_type::m_algebra.for_each5( m_x_tmp.m_v , in , dxdt , m_k2.m_v , m_k3.m_v ,
                 typename operations_type::template scale_sum4< value_type , time_type , time_type , time_type >( 1.0 , dt*b41 , dt*b42 , dt*b43 ));

         sys( m_x_tmp.m_v, m_k4.m_v , t + dt*a4 );
         stepper_base_type::m_algebra.for_each6( m_x_tmp.m_v , in , dxdt , m_k2.m_v , m_k3.m_v , m_k4.m_v ,
                 typename operations_type::template scale_sum5< value_type , time_type , time_type , time_type , time_type >( 1.0 , dt*b51 , dt*b52 , dt*b53 , dt*b54 ));

         sys( m_x_tmp.m_v , m_k5.m_v , t + dt*a5 );
         stepper_base_type::m_algebra.for_each7( m_x_tmp.m_v , in , dxdt , m_k2.m_v , m_k3.m_v , m_k4.m_v , m_k5.m_v ,
                 typename operations_type::template scale_sum6< value_type , time_type , time_type , time_type , time_type , time_type >( 1.0 , dt*b61 , dt*b62 , dt*b63 , dt*b64 , dt*b65 ));

         sys( m_x_tmp.m_v , m_k6.m_v , t + dt*a6 );
         stepper_base_type::m_algebra.for_each6( out , in , dxdt , m_k3.m_v , m_k4.m_v , m_k6.m_v ,
                 typename operations_type::template scale_sum5< value_type , time_type , time_type , time_type , time_type >( 1.0 , dt*c1 , dt*c3 , dt*c4 , dt*c6 ));

     }

     /**
      * \brief Adjust the size of all temporaries in the stepper manually.
      * \param x A state from which the size of the temporaries to be resized is deduced.
      */
     template< class StateIn >
     void adjust_size( const StateIn &x )
     {
         resize_impl( x );
         stepper_base_type::adjust_size( x );
     }

 private:

     template< class StateIn >
     bool resize_impl( const StateIn &x )
     {
         bool resized = false;
         resized |= adjust_size_by_resizeability( m_x_tmp , x , typename is_resizeable<state_type>::type() );
         resized |= adjust_size_by_resizeability( m_k2 , x , typename is_resizeable<deriv_type>::type() );
         resized |= adjust_size_by_resizeability( m_k3 , x , typename is_resizeable<deriv_type>::type() );
         resized |= adjust_size_by_resizeability( m_k4 , x , typename is_resizeable<deriv_type>::type() );
         resized |= adjust_size_by_resizeability( m_k5 , x , typename is_resizeable<deriv_type>::type() );
         resized |= adjust_size_by_resizeability( m_k6 , x , typename is_resizeable<deriv_type>::type() );
         return resized;
     }


     wrapped_state_type m_x_tmp;
     wrapped_deriv_type m_k2, m_k3, m_k4, m_k5, m_k6;
     resizer_type m_resizer;

 };


 /************ DOXYGEN *************/

 /**
  * \class runge_kutta_cash_karp54_classic
  * \brief The Runge-Kutta Cash-Karp method implemented without the generic Runge-Kutta algorithm.
  *
  * The Runge-Kutta Cash-Karp method is one of the standard methods for
  * solving ordinary differential equations, see
  * <a href="http://en.wikipedia.org/wiki/Cash%E2%80%93Karp_method">en.wikipedia.org/wiki/Cash-Karp_method</a>.
  * The method is explicit and fulfills the Error Stepper concept. Step size control
  * is provided but continuous output is not available for this method.
  *
  * This class derives from explicit_error_stepper_base and inherits its interface via CRTP (current recurring
  * template pattern). This class implements the method directly, hence the generic Runge-Kutta algorithm is not used.
  *
  * \tparam State The state type.
  * \tparam Value The value type.
  * \tparam Deriv The type representing the time derivative of the state.
  * \tparam Time The time representing the independent variable - the time.
  * \tparam Algebra The algebra type.
  * \tparam Operations The operations type.
  * \tparam Resizer The resizer policy type.
  */


     /**
      * \fn runge_kutta_cash_karp54_classic::runge_kutta_cash_karp54_classic( const algebra_type &algebra )
      * \brief Constructs the runge_kutta_cash_karp54_classic class. This constructor can be used as a default
      * constructor if the algebra has a default constructor.
      * \param algebra A copy of algebra is made and stored inside explicit_stepper_base.
      */


     /**
      * \fn runge_kutta_cash_karp54_classic::do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt , Err &xerr )
      * \brief This method performs one step. The derivative `dxdt` of `in` at the time `t` is passed to the method.
      *
      * The result is updated out-of-place, hence the input is in `in` and the output in `out`. Futhermore, an
      * estimation of the error is stored in `xerr`.
      * Access to this step functionality is provided by explicit_error_stepper_base and
      * `do_step_impl` should not be called directly.

      *
      * \param system The system function to solve, hence the r.h.s. of the ODE. It must fulfill the
      *               Simple System concept.
      * \param in The state of the ODE which should be solved. in is not modified in this method
      * \param dxdt The derivative of x at t.
      * \param t The value of the time, at which the step should be performed.
      * \param out The result of the step is written in out.
      * \param dt The step size.
      * \param xerr The result of the error estimation is written in xerr.
      */

     /**
      * \fn runge_kutta_cash_karp54_classic::do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt )
      * \brief This method performs one step. The derivative `dxdt` of `in` at the time `t` is passed to the method.
      * The result is updated out-of-place, hence the input is in `in` and the output in `out`.
      * Access to this step functionality is provided by explicit_error_stepper_base and
      * `do_step_impl` should not be called directly.
      *
      * \param system The system function to solve, hence the r.h.s. of the ODE. It must fulfill the
      *               Simple System concept.
      * \param in The state of the ODE which should be solved. in is not modified in this method
      * \param dxdt The derivative of x at t.
      * \param t The value of the time, at which the step should be performed.
      * \param out The result of the step is written in out.
      * \param dt The step size.
      */

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


 #endif // BOOST_NUMERIC_ODEINT_STEPPER_RUNGE_KUTTA_CASH_KARP54_CLASSIC_HPP_INCLUDED
	/*
	[auto_generated]
	boost/numeric/odeint/stepper/runge_kutta_cash_karp54_classic.hpp

	[begin_description]
	Classical implementation of the Runge-Kutta Cash-Karp 5(4) method.
	[end_description]

	Copyright 2010-2013 Mario Mulansky
	Copyright 2010-2013 Karsten Ahnert
	Copyright 2012 Christoph Koke

	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_STEPPER_RUNGE_KUTTA_CASH_KARP54_CLASSIC_HPP_INCLUDED
	#define BOOST_NUMERIC_ODEINT_STEPPER_RUNGE_KUTTA_CASH_KARP54_CLASSIC_HPP_INCLUDED


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

	#include <boost/numeric/odeint/stepper/base/explicit_error_stepper_base.hpp>
	#include <boost/numeric/odeint/algebra/range_algebra.hpp>
	#include <boost/numeric/odeint/algebra/default_operations.hpp>
	#include <boost/numeric/odeint/algebra/algebra_dispatcher.hpp>
	#include <boost/numeric/odeint/algebra/operations_dispatcher.hpp>
	#include <boost/numeric/odeint/stepper/stepper_categories.hpp>
	#include <boost/numeric/odeint/util/state_wrapper.hpp>
	#include <boost/numeric/odeint/util/is_resizeable.hpp>
	#include <boost/numeric/odeint/util/resizer.hpp>

	namespace boost {
	namespace numeric {
	namespace odeint {




	template<
	class State ,
	class Value = double ,
	class Deriv = State ,
	class Time = Value ,
	class Algebra = typename algebra_dispatcher< State >::algebra_type ,
	class Operations = typename operations_dispatcher< State >::operations_type ,
	class Resizer = initially_resizer
	>
	#ifndef DOXYGEN_SKIP
	class runge_kutta_cash_karp54_classic
	: public explicit_error_stepper_base<
	runge_kutta_cash_karp54_classic< State , Value , Deriv , Time , Algebra , Operations , Resizer > ,
	5 , 5 , 4 , State , Value , Deriv , Time , Algebra , Operations , Resizer >
	#else
	class runge_kutta_cash_karp54_classic : public explicit_error_stepper_base
	#endif
	{


	public :

	#ifndef DOXYGEN_SKIP
	typedef explicit_error_stepper_base<
	runge_kutta_cash_karp54_classic< State , Value , Deriv , Time , Algebra , Operations , Resizer > ,
	5 , 5 , 4 , State , Value , Deriv , Time , Algebra , Operations , Resizer > stepper_base_type;
	#else
	typedef explicit_error_stepper_base< runge_kutta_cash_karp54_classic< ... > , ... > stepper_base_type;
	#endif

	typedef typename stepper_base_type::state_type state_type;
	typedef typename stepper_base_type::value_type value_type;
	typedef typename stepper_base_type::deriv_type deriv_type;
	typedef typename stepper_base_type::time_type time_type;
	typedef typename stepper_base_type::algebra_type algebra_type;
	typedef typename stepper_base_type::operations_type operations_type;
	typedef typename stepper_base_type::resizer_type resizer_type;

	#ifndef DOXYGEN_SKIP
	typedef typename stepper_base_type::wrapped_state_type wrapped_state_type;
	typedef typename stepper_base_type::wrapped_deriv_type wrapped_deriv_type;
	typedef typename stepper_base_type::stepper_type stepper_type;
	#endif


	runge_kutta_cash_karp54_classic( const algebra_type &algebra = algebra_type() ) : stepper_base_type( algebra )
	{ }



	template< class System , class StateIn , class DerivIn , class StateOut , class Err >
	void do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt , Err &xerr )
	{
	const value_type c1 = static_cast<value_type> ( 37 ) / static_cast<value_type>( 378 );
	const value_type c3 = static_cast<value_type> ( 250 ) / static_cast<value_type>( 621 );
	const value_type c4 = static_cast<value_type> ( 125 ) / static_cast<value_type>( 594 );
	const value_type c6 = static_cast<value_type> ( 512 ) / static_cast<value_type>( 1771 );

	const value_type dc1 = c1 - static_cast<value_type> ( 2825 ) / static_cast<value_type>( 27648 );
	const value_type dc3 = c3 - static_cast<value_type> ( 18575 ) / static_cast<value_type>( 48384 );
	const value_type dc4 = c4 - static_cast<value_type> ( 13525 ) / static_cast<value_type>( 55296 );
	const value_type dc5 = static_cast<value_type> ( -277 ) / static_cast<value_type>( 14336 );
	const value_type dc6 = c6 - static_cast<value_type> ( 1 ) / static_cast<value_type> ( 4 );

	do_step_impl( system , in , dxdt , t , out , dt );

	//error estimate
	stepper_base_type::m_algebra.for_each6( xerr , dxdt , m_k3.m_v , m_k4.m_v , m_k5.m_v , m_k6.m_v ,
	typename operations_type::template scale_sum5< time_type , time_type , time_type , time_type , time_type >( dtdc1 , dtdc3 , dtdc4 , dtdc5 , dt*dc6 ));

	}



	template< class System , class StateIn , class DerivIn , class StateOut >
	void do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt )
	{
	const value_type a2 = static_cast<value_type> ( 1 ) / static_cast<value_type> ( 5 );
	const value_type a3 = static_cast<value_type> ( 3 ) / static_cast<value_type> ( 10 );
	const value_type a4 = static_cast<value_type> ( 3 ) / static_cast<value_type> ( 5 );
	const value_type a5 = static_cast<value_type> ( 1 );
	const value_type a6 = static_cast<value_type> ( 7 ) / static_cast<value_type> ( 8 );

	const value_type b21 = static_cast<value_type> ( 1 ) / static_cast<value_type> ( 5 );
	const value_type b31 = static_cast<value_type> ( 3 ) / static_cast<value_type>( 40 );
	const value_type b32 = static_cast<value_type> ( 9 ) / static_cast<value_type>( 40 );
	const value_type b41 = static_cast<value_type> ( 3 ) / static_cast<value_type> ( 10 );
	const value_type b42 = static_cast<value_type> ( -9 ) / static_cast<value_type> ( 10 );
	const value_type b43 = static_cast<value_type> ( 6 ) / static_cast<value_type> ( 5 );
	const value_type b51 = static_cast<value_type> ( -11 ) / static_cast<value_type>( 54 );
	const value_type b52 = static_cast<value_type> ( 5 ) / static_cast<value_type> ( 2 );
	const value_type b53 = static_cast<value_type> ( -70 ) / static_cast<value_type>( 27 );
	const value_type b54 = static_cast<value_type> ( 35 ) / static_cast<value_type>( 27 );
	const value_type b61 = static_cast<value_type> ( 1631 ) / static_cast<value_type>( 55296 );
	const value_type b62 = static_cast<value_type> ( 175 ) / static_cast<value_type>( 512 );
	const value_type b63 = static_cast<value_type> ( 575 ) / static_cast<value_type>( 13824 );
	const value_type b64 = static_cast<value_type> ( 44275 ) / static_cast<value_type>( 110592 );
	const value_type b65 = static_cast<value_type> ( 253 ) / static_cast<value_type>( 4096 );

	const value_type c1 = static_cast<value_type> ( 37 ) / static_cast<value_type>( 378 );
	const value_type c3 = static_cast<value_type> ( 250 ) / static_cast<value_type>( 621 );
	const value_type c4 = static_cast<value_type> ( 125 ) / static_cast<value_type>( 594 );
	const value_type c6 = static_cast<value_type> ( 512 ) / static_cast<value_type>( 1771 );

	typename odeint::unwrap_reference< System >::type &sys = system;

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

	//m_x1 = x + dtb21dxdt
	stepper_base_type::m_algebra.for_each3( m_x_tmp.m_v , in , dxdt ,
	typename operations_type::template scale_sum2< value_type , time_type >( 1.0 , dt*b21 ) );

	sys( m_x_tmp.m_v , m_k2.m_v , t + dt*a2 );
	// m_x_tmp = x + dtb31dxdt + dtb32m_x2
	stepper_base_type::m_algebra.for_each4( m_x_tmp.m_v , in , dxdt , m_k2.m_v ,
	typename operations_type::template scale_sum3< value_type , time_type , time_type >( 1.0 , dtb31 , dtb32 ));

	sys( m_x_tmp.m_v , m_k3.m_v , t + dt*a3 );
	// m_x_tmp = x + dt * (b41dxdt + b42m_x2 + b43*m_x3)
	stepper_base_type::m_algebra.for_each5( m_x_tmp.m_v , in , dxdt , m_k2.m_v , m_k3.m_v ,
	typename operations_type::template scale_sum4< value_type , time_type , time_type , time_type >( 1.0 , dtb41 , dtb42 , dt*b43 ));

	sys( m_x_tmp.m_v, m_k4.m_v , t + dt*a4 );
	stepper_base_type::m_algebra.for_each6( m_x_tmp.m_v , in , dxdt , m_k2.m_v , m_k3.m_v , m_k4.m_v ,
	typename operations_type::template scale_sum5< value_type , time_type , time_type , time_type , time_type >( 1.0 , dtb51 , dtb52 , dtb53 , dtb54 ));

	sys( m_x_tmp.m_v , m_k5.m_v , t + dt*a5 );
	stepper_base_type::m_algebra.for_each7( m_x_tmp.m_v , in , dxdt , m_k2.m_v , m_k3.m_v , m_k4.m_v , m_k5.m_v ,
	typename operations_type::template scale_sum6< value_type , time_type , time_type , time_type , time_type , time_type >( 1.0 , dtb61 , dtb62 , dtb63 , dtb64 , dt*b65 ));

	sys( m_x_tmp.m_v , m_k6.m_v , t + dt*a6 );
	stepper_base_type::m_algebra.for_each6( out , in , dxdt , m_k3.m_v , m_k4.m_v , m_k6.m_v ,
	typename operations_type::template scale_sum5< value_type , time_type , time_type , time_type , time_type >( 1.0 , dtc1 , dtc3 , dtc4 , dtc6 ));

	}

	/**
	* \brief Adjust the size of all temporaries in the stepper manually.
	* \param x A state from which the size of the temporaries to be resized is deduced.
	*/
	template< class StateIn >
	void adjust_size( const StateIn &x )
	{
	resize_impl( x );
	stepper_base_type::adjust_size( x );
	}

	private:

	template< class StateIn >
	bool resize_impl( const StateIn &x )
	{
	bool resized = false;
	resized \|= adjust_size_by_resizeability( m_x_tmp , x , typename is_resizeable<state_type>::type() );
	resized \|= adjust_size_by_resizeability( m_k2 , x , typename is_resizeable<deriv_type>::type() );
	resized \|= adjust_size_by_resizeability( m_k3 , x , typename is_resizeable<deriv_type>::type() );
	resized \|= adjust_size_by_resizeability( m_k4 , x , typename is_resizeable<deriv_type>::type() );
	resized \|= adjust_size_by_resizeability( m_k5 , x , typename is_resizeable<deriv_type>::type() );
	resized \|= adjust_size_by_resizeability( m_k6 , x , typename is_resizeable<deriv_type>::type() );
	return resized;
	}


	wrapped_state_type m_x_tmp;
	wrapped_deriv_type m_k2, m_k3, m_k4, m_k5, m_k6;
	resizer_type m_resizer;

	};



	/********** DOXYGEN ***********/

	/**
	* \class runge_kutta_cash_karp54_classic
	* \brief The Runge-Kutta Cash-Karp method implemented without the generic Runge-Kutta algorithm.
	*
	* The Runge-Kutta Cash-Karp method is one of the standard methods for
	* solving ordinary differential equations, see
	* <a href="http://en.wikipedia.org/wiki/Cash%E2%80%93Karp_method">en.wikipedia.org/wiki/Cash-Karp_method</a>.
	* The method is explicit and fulfills the Error Stepper concept. Step size control
	* is provided but continuous output is not available for this method.
	*
	* This class derives from explicit_error_stepper_base and inherits its interface via CRTP (current recurring
	* template pattern). This class implements the method directly, hence the generic Runge-Kutta algorithm is not used.
	*
	* \tparam State The state type.
	* \tparam Value The value type.
	* \tparam Deriv The type representing the time derivative of the state.
	* \tparam Time The time representing the independent variable - the time.
	* \tparam Algebra The algebra type.
	* \tparam Operations The operations type.
	* \tparam Resizer The resizer policy type.
	*/


	/**
	* \fn runge_kutta_cash_karp54_classic::runge_kutta_cash_karp54_classic( const algebra_type &algebra )
	* \brief Constructs the runge_kutta_cash_karp54_classic class. This constructor can be used as a default
	* constructor if the algebra has a default constructor.
	* \param algebra A copy of algebra is made and stored inside explicit_stepper_base.
	*/


	/**
	* \fn runge_kutta_cash_karp54_classic::do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt , Err &xerr )
	* \brief This method performs one step. The derivative `dxdt` of `in` at the time `t` is passed to the method.
	*
	* The result is updated out-of-place, hence the input is in `in` and the output in `out`. Futhermore, an
	* estimation of the error is stored in `xerr`.
	* Access to this step functionality is provided by explicit_error_stepper_base and
	* `do_step_impl` should not be called directly.

	*
	* \param system The system function to solve, hence the r.h.s. of the ODE. It must fulfill the
	* Simple System concept.
	* \param in The state of the ODE which should be solved. in is not modified in this method
	* \param dxdt The derivative of x at t.
	* \param t The value of the time, at which the step should be performed.
	* \param out The result of the step is written in out.
	* \param dt The step size.
	* \param xerr The result of the error estimation is written in xerr.
	*/

	/**
	* \fn runge_kutta_cash_karp54_classic::do_step_impl( System system , const StateIn &in , const DerivIn &dxdt , time_type t , StateOut &out , time_type dt )
	* \brief This method performs one step. The derivative `dxdt` of `in` at the time `t` is passed to the method.
	* The result is updated out-of-place, hence the input is in `in` and the output in `out`.
	* Access to this step functionality is provided by explicit_error_stepper_base and
	* `do_step_impl` should not be called directly.
	*
	* \param system The system function to solve, hence the r.h.s. of the ODE. It must fulfill the
	* Simple System concept.
	* \param in The state of the ODE which should be solved. in is not modified in this method
	* \param dxdt The derivative of x at t.
	* \param t The value of the time, at which the step should be performed.
	* \param out The result of the step is written in out.
	* \param dt The step size.
	*/

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




	#endif // BOOST_NUMERIC_ODEINT_STEPPER_RUNGE_KUTTA_CASH_KARP54_CLASSIC_HPP_INCLUDED