third_party/boost/numeric/odeint/include/boost/numeric/odeint/iterator/impl/const_step_iterator_impl.hpp - platform/external/sdv/vsomeip - Git at Google

 /*
   [auto_generated]
   boost/numeric/odeint/iterator/detail/const_step_iterator_impl.hpp

   [begin_description]
   tba.
   [end_description]

   Copyright 2013 Karsten Ahnert
   Copyright 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_ITERATOR_DETAIL_CONST_STEP_ITERATOR_IMPL_HPP_DEFINED
 #define BOOST_NUMERIC_ODEINT_ITERATOR_DETAIL_CONST_STEP_ITERATOR_IMPL_HPP_DEFINED

 #include <boost/numeric/odeint/iterator/detail/ode_iterator_base.hpp>
 #include <boost/numeric/odeint/util/unit_helper.hpp>


 namespace boost {
 namespace numeric {
 namespace odeint {


     template< class Iterator , class Stepper , class System , class State , typename Tag , class StepperTag >
     class const_step_iterator_impl;


     /*
      * Specilization for steppers and error steppers
      */
     template< class Iterator , class Stepper , class System , class State , typename Tag >
     class const_step_iterator_impl< Iterator , Stepper , System , State , Tag , stepper_tag >
         : public detail::ode_iterator_base< Iterator , Stepper , System , State , Tag >
     {
     private:

         typedef Stepper stepper_type;
         typedef System system_type;
         typedef typename boost::numeric::odeint::unwrap_reference< stepper_type >::type unwrapped_stepper_type;
         typedef State state_type;
         typedef typename traits::time_type< stepper_type >::type time_type;
         typedef typename traits::value_type< stepper_type >::type ode_value_type;
         #ifndef DOXYGEN_SKIP
         typedef detail::ode_iterator_base< Iterator , Stepper , System , State , Tag > base_type;
         #endif

     public:

         /**
          * \brief Constructs a const_step_iterator. This constructor should be used to construct the begin iterator.
          *
          * \param stepper The stepper to use during the iteration.
          * \param sys The system function (ODE) to solve.
          * \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
          * \param t The initial time.
          * \param t_end The end time, at which the iteration should stop.
          * \param dt The initial time step.
          */
         const_step_iterator_impl( stepper_type stepper , system_type sys , state_type &s , time_type t , time_type t_end , time_type dt )
             : base_type( stepper , sys , t , dt ) , m_t_start( t ) , m_t_end( t_end ) , m_state( &s ) , m_step( 0 )
         {
             if( detail::less_with_sign( this->m_t_end , this->m_t , this->m_dt ) )
                 this->m_at_end = true;
         }

         /**
          * \brief Constructs a const_step_iterator. This constructor should be used to construct the end iterator.
          *
          * \param stepper The stepper to use during the iteration.
          * \param sys The system function (ODE) to solve.
          * \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
          */
         const_step_iterator_impl( stepper_type stepper , system_type sys , state_type& /* s */ )
             : base_type( stepper , sys ) { }

     protected:

         friend class boost::iterator_core_access;

         void increment()
         {
             if( detail::less_eq_with_sign( static_cast<time_type>(this->m_t+this->m_dt) ,
                                            this->m_t_end , this->m_dt ) )
             {
                 unwrapped_stepper_type &stepper = this->m_stepper;
                 stepper.do_step( this->m_system , *this->m_state , this->m_t , this->m_dt );
                 // use integer to compute current time to reduce roundoff errors
                 this->m_step++;
                 this->m_t = this->m_t_start + static_cast< typename unit_value_type<time_type>::type >(this->m_step)*this->m_dt;
             } else {
                 this->m_at_end = true;
             }
         }

     public:
         const state_type& get_state() const
         {
             return *m_state;
         }

     private:
         time_type m_t_start;
         time_type m_t_end;
         state_type* m_state;
         size_t m_step;

     };


     /*
      * Specilization for dense output stepper
      */
     /**
      * \brief ODE Iterator with constant step size. The value type of this iterator is the state type of the stepper.
      *
      * Implements an ODE iterator solving the ODE with constant steps. Uses dense-output steppers.
      * const_step_iterator is a model of single-pass iterator.
      *
      * The value type of this iterator is the state type of the stepper. Hence one can only access the state and not the current time.
      *
      * \tparam Stepper The stepper type which should be used during the iteration.
      * \tparam System The type of the system function (ODE) which should be solved.
      */
     template< class Iterator , class Stepper , class System , class State , typename Tag >
     class const_step_iterator_impl< Iterator , Stepper , System , State , Tag , dense_output_stepper_tag >
         : public detail::ode_iterator_base< Iterator , Stepper , System , State , Tag >
     {
     private:

         typedef Stepper stepper_type;
         typedef System system_type;
         typedef typename boost::numeric::odeint::unwrap_reference< stepper_type >::type unwrapped_stepper_type;
         typedef State state_type;
         typedef typename traits::time_type< stepper_type >::type time_type;
         typedef typename traits::value_type< stepper_type >::type ode_value_type;
         #ifndef DOXYGEN_SKIP
         typedef detail::ode_iterator_base< Iterator , Stepper , System , State , Tag > base_type;
         #endif

     public:

         /**
          * \brief Constructs a const_step_iterator. This constructor should be used to construct the begin iterator.
          *
          * \param stepper The stepper to use during the iteration.
          * \param sys The system function (ODE) to solve.
          * \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
          * \param t The initial time.
          * \param t_end The end time, at which the iteration should stop.
          * \param dt The initial time step.
          */
         const_step_iterator_impl( stepper_type stepper , system_type sys , state_type &s , time_type t , time_type t_end , time_type dt )
             : base_type( stepper , sys , t , dt ) , m_t_start( t ) , m_t_end( t_end ) , m_state( &s ) , m_step( 0 )
         {
             if( detail::less_eq_with_sign( this->m_t , this->m_t_end , this->m_dt ) )
             {
                 unwrapped_stepper_type &st = this->m_stepper;
                 st.initialize( * ( this->m_state ) , this->m_t , this->m_dt );
             } else {
                 this->m_at_end = true;
             }
         }

         /**
          * \brief Constructs a const_step_iterator. This constructor should be used to construct the end iterator.
          *
          * \param stepper The stepper to use during the iteration.
          * \param sys The system function (ODE) to solve.
          * \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
          */
         const_step_iterator_impl( stepper_type stepper , system_type sys , state_type &s )
             : base_type( stepper , sys ) , m_state( &s )
         {
         }


     protected:

         friend class boost::iterator_core_access;

         void increment( void )
         {
             if( detail::less_eq_with_sign( static_cast<time_type>(this->m_t+this->m_dt) ,
                                            this->m_t_end , this->m_dt ) )
             {
                 unwrapped_stepper_type &stepper = this->m_stepper;
                 // use integer to compute current time to reduce roundoff errors
                 this->m_step++;
                 this->m_t = this->m_t_start + static_cast< typename unit_value_type<time_type>::type >(this->m_step)*this->m_dt;
                 while( detail::less_with_sign( stepper.current_time() , this->m_t ,
                        stepper.current_time_step() ) )
                 {
                     stepper.do_step( this->m_system );
                 }
                 stepper.calc_state( this->m_t , *( this->m_state ) );
             } else {
                 this->m_at_end = true;
             }
         }

     public:
         const state_type& get_state() const
         {
             return *m_state;
         }

     private:
         time_type m_t_start;
         time_type m_t_end;
         state_type* m_state;
         size_t m_step;
     };

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


 #endif // BOOST_NUMERIC_ODEINT_ITERATOR_DETAIL_CONST_STEP_ITERATOR_IMPL_HPP_DEFINED
	/*
	[auto_generated]
	boost/numeric/odeint/iterator/detail/const_step_iterator_impl.hpp

	[begin_description]
	tba.
	[end_description]

	Copyright 2013 Karsten Ahnert
	Copyright 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_ITERATOR_DETAIL_CONST_STEP_ITERATOR_IMPL_HPP_DEFINED
	#define BOOST_NUMERIC_ODEINT_ITERATOR_DETAIL_CONST_STEP_ITERATOR_IMPL_HPP_DEFINED

	#include <boost/numeric/odeint/iterator/detail/ode_iterator_base.hpp>
	#include <boost/numeric/odeint/util/unit_helper.hpp>



	namespace boost {
	namespace numeric {
	namespace odeint {


	template< class Iterator , class Stepper , class System , class State , typename Tag , class StepperTag >
	class const_step_iterator_impl;


	/*
	* Specilization for steppers and error steppers
	*/
	template< class Iterator , class Stepper , class System , class State , typename Tag >
	class const_step_iterator_impl< Iterator , Stepper , System , State , Tag , stepper_tag >
	: public detail::ode_iterator_base< Iterator , Stepper , System , State , Tag >
	{
	private:

	typedef Stepper stepper_type;
	typedef System system_type;
	typedef typename boost::numeric::odeint::unwrap_reference< stepper_type >::type unwrapped_stepper_type;
	typedef State state_type;
	typedef typename traits::time_type< stepper_type >::type time_type;
	typedef typename traits::value_type< stepper_type >::type ode_value_type;
	#ifndef DOXYGEN_SKIP
	typedef detail::ode_iterator_base< Iterator , Stepper , System , State , Tag > base_type;
	#endif

	public:

	/**
	* \brief Constructs a const_step_iterator. This constructor should be used to construct the begin iterator.
	*
	* \param stepper The stepper to use during the iteration.
	* \param sys The system function (ODE) to solve.
	* \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
	* \param t The initial time.
	* \param t_end The end time, at which the iteration should stop.
	* \param dt The initial time step.
	*/
	const_step_iterator_impl( stepper_type stepper , system_type sys , state_type &s , time_type t , time_type t_end , time_type dt )
	: base_type( stepper , sys , t , dt ) , m_t_start( t ) , m_t_end( t_end ) , m_state( &s ) , m_step( 0 )
	{
	if( detail::less_with_sign( this->m_t_end , this->m_t , this->m_dt ) )
	this->m_at_end = true;
	}

	/**
	* \brief Constructs a const_step_iterator. This constructor should be used to construct the end iterator.
	*
	* \param stepper The stepper to use during the iteration.
	* \param sys The system function (ODE) to solve.
	* \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
	*/
	const_step_iterator_impl( stepper_type stepper , system_type sys , state_type& /* s */ )
	: base_type( stepper , sys ) { }

	protected:

	friend class boost::iterator_core_access;

	void increment()
	{
	if( detail::less_eq_with_sign( static_cast<time_type>(this->m_t+this->m_dt) ,
	this->m_t_end , this->m_dt ) )
	{
	unwrapped_stepper_type &stepper = this->m_stepper;
	stepper.do_step( this->m_system , *this->m_state , this->m_t , this->m_dt );
	// use integer to compute current time to reduce roundoff errors
	this->m_step++;
	this->m_t = this->m_t_start + static_cast< typename unit_value_type<time_type>::type >(this->m_step)*this->m_dt;
	} else {
	this->m_at_end = true;
	}
	}

	public:
	const state_type& get_state() const
	{
	return *m_state;
	}

	private:
	time_type m_t_start;
	time_type m_t_end;
	state_type* m_state;
	size_t m_step;

	};



	/*
	* Specilization for dense output stepper
	*/
	/**
	* \brief ODE Iterator with constant step size. The value type of this iterator is the state type of the stepper.
	*
	* Implements an ODE iterator solving the ODE with constant steps. Uses dense-output steppers.
	* const_step_iterator is a model of single-pass iterator.
	*
	* The value type of this iterator is the state type of the stepper. Hence one can only access the state and not the current time.
	*
	* \tparam Stepper The stepper type which should be used during the iteration.
	* \tparam System The type of the system function (ODE) which should be solved.
	*/
	template< class Iterator , class Stepper , class System , class State , typename Tag >
	class const_step_iterator_impl< Iterator , Stepper , System , State , Tag , dense_output_stepper_tag >
	: public detail::ode_iterator_base< Iterator , Stepper , System , State , Tag >
	{
	private:

	typedef Stepper stepper_type;
	typedef System system_type;
	typedef typename boost::numeric::odeint::unwrap_reference< stepper_type >::type unwrapped_stepper_type;
	typedef State state_type;
	typedef typename traits::time_type< stepper_type >::type time_type;
	typedef typename traits::value_type< stepper_type >::type ode_value_type;
	#ifndef DOXYGEN_SKIP
	typedef detail::ode_iterator_base< Iterator , Stepper , System , State , Tag > base_type;
	#endif

	public:

	/**
	* \brief Constructs a const_step_iterator. This constructor should be used to construct the begin iterator.
	*
	* \param stepper The stepper to use during the iteration.
	* \param sys The system function (ODE) to solve.
	* \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
	* \param t The initial time.
	* \param t_end The end time, at which the iteration should stop.
	* \param dt The initial time step.
	*/
	const_step_iterator_impl( stepper_type stepper , system_type sys , state_type &s , time_type t , time_type t_end , time_type dt )
	: base_type( stepper , sys , t , dt ) , m_t_start( t ) , m_t_end( t_end ) , m_state( &s ) , m_step( 0 )
	{
	if( detail::less_eq_with_sign( this->m_t , this->m_t_end , this->m_dt ) )
	{
	unwrapped_stepper_type &st = this->m_stepper;
	st.initialize( * ( this->m_state ) , this->m_t , this->m_dt );
	} else {
	this->m_at_end = true;
	}
	}

	/**
	* \brief Constructs a const_step_iterator. This constructor should be used to construct the end iterator.
	*
	* \param stepper The stepper to use during the iteration.
	* \param sys The system function (ODE) to solve.
	* \param s The initial state. const_step_iterator stores a reference of s and changes its value during the iteration.
	*/
	const_step_iterator_impl( stepper_type stepper , system_type sys , state_type &s )
	: base_type( stepper , sys ) , m_state( &s )
	{
	}



	protected:

	friend class boost::iterator_core_access;

	void increment( void )
	{
	if( detail::less_eq_with_sign( static_cast<time_type>(this->m_t+this->m_dt) ,
	this->m_t_end , this->m_dt ) )
	{
	unwrapped_stepper_type &stepper = this->m_stepper;
	// use integer to compute current time to reduce roundoff errors
	this->m_step++;
	this->m_t = this->m_t_start + static_cast< typename unit_value_type<time_type>::type >(this->m_step)*this->m_dt;
	while( detail::less_with_sign( stepper.current_time() , this->m_t ,
	stepper.current_time_step() ) )
	{
	stepper.do_step( this->m_system );
	}
	stepper.calc_state( this->m_t , *( this->m_state ) );
	} else {
	this->m_at_end = true;
	}
	}

	public:
	const state_type& get_state() const
	{
	return *m_state;
	}

	private:
	time_type m_t_start;
	time_type m_t_end;
	state_type* m_state;
	size_t m_step;
	};

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


	#endif // BOOST_NUMERIC_ODEINT_ITERATOR_DETAIL_CONST_STEP_ITERATOR_IMPL_HPP_DEFINED