boost/boost/numeric/odeint/iterator/integrate/integrate_n_steps.hpp - nest-cam/4320010/boost - Git at Google

 /*
  [auto_generated]
  boost/numeric/odeint/integrate/integrate_n_steps.hpp

  [begin_description]
  Integration of n steps with constant time size. Adaptive and dense-output methods are fully supported.
  [end_description]

  Copyright 2009-2011 Karsten Ahnert
  Copyright 2009-2011 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_INTEGRATE_INTEGRATE_N_STEPS_HPP_INCLUDED
 #define BOOST_NUMERIC_ODEINT_INTEGRATE_INTEGRATE_N_STEPS_HPP_INCLUDED

 #include <boost/type_traits/is_same.hpp>

 #include <boost/numeric/odeint/stepper/stepper_categories.hpp>
 #include <boost/numeric/odeint/iterator/integrate/null_observer.hpp>
 #include <boost/numeric/odeint/iterator/integrate/detail/integrate_n_steps.hpp>

 namespace boost {
 namespace numeric {
 namespace odeint {


 /*
  * Integrates n steps
  *
  * the two overloads are needed in order to solve the forwarding problem
  */
 template< class Stepper , class System , class State , class Time , class Observer>
 Time integrate_n_steps(
         Stepper stepper , System system , State &start_state ,
         Time start_time , Time dt , size_t num_of_steps ,
         Observer observer )
 {
     typedef typename odeint::unwrap_reference< Stepper >::type::stepper_category stepper_category;
     return detail::integrate_n_steps(
                 stepper , system , start_state ,
                 start_time , dt , num_of_steps ,
                 observer , stepper_category() );
 }

 /**
  * \brief Solves the forwarding problem, can be called with Boost.Range as start_state.
  */
 template< class Stepper , class System , class State , class Time , class Observer >
 Time integrate_n_steps(
         Stepper stepper , System system , const State &start_state ,
         Time start_time , Time dt , size_t num_of_steps ,
         Observer observer )
 {
     typedef typename odeint::unwrap_reference< Stepper >::type::stepper_category stepper_category;
     return detail::integrate_n_steps(
                  stepper , system , start_state ,
                  start_time , dt , num_of_steps ,
                  observer , stepper_category() );
 }


 /**
  * \brief The same function as above, but without observer calls.
  */
 template< class Stepper , class System , class State , class Time >
 Time integrate_n_steps(
         Stepper stepper , System system , State &start_state ,
         Time start_time , Time dt , size_t num_of_steps )
 {
     return integrate_n_steps( stepper , system , start_state , start_time , dt , num_of_steps , null_observer() );
 }

 /**
  * \brief Solves the forwarding problem, can be called with Boost.Range as start_state.
  */
 template< class Stepper , class System , class State , class Time >
 Time integrate_n_steps(
         Stepper stepper , System system , const State &start_state ,
         Time start_time , Time dt , size_t num_of_steps )
 {
     return integrate_n_steps( stepper , system , start_state , start_time , dt , num_of_steps , null_observer() );
 }


 /************* DOXYGEN *************/
     /**
      * \fn Time integrate_n_steps( Stepper stepper , System system , State &start_state , Time start_time , Time dt , size_t num_of_steps , Observer observer )
      * \brief Integrates the ODE with constant step size.
      *
      * This function is similar to integrate_const. The observer is called at
      * equidistant time intervals t0 + n*dt.
      * If the Stepper is a normal stepper without step size control, dt is also
      * used for the numerical scheme. If a ControlledStepper is provided, the
      * algorithm might reduce the step size to meet the error bounds, but it is
      * ensured that the observer is always called at equidistant time points
      * t0 + n*dt. If a DenseOutputStepper is used, the step size also may vary
      * and the dense output is used to call the observer at equidistant time
      * points. The final integration time is always t0 + num_of_steps*dt.
      *
      * \param stepper The stepper to be used for numerical integration.
      * \param system Function/Functor defining the rhs of the ODE.
      * \param start_state The initial condition x0.
      * \param start_time The initial time t0.
      * \param dt The time step between observer calls, _not_ necessarily the
      * time step of the integration.
      * \param num_of_steps Number of steps to be performed
      * \param observer Function/Functor called at equidistant time intervals.
      * \return The number of steps performed.
      */


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


 #endif // BOOST_NUMERIC_ODEINT_INTEGRATE_INTEGRATE_N_STEPS_HPP_INCLUDED
	/*
	[auto_generated]
	boost/numeric/odeint/integrate/integrate_n_steps.hpp

	[begin_description]
	Integration of n steps with constant time size. Adaptive and dense-output methods are fully supported.
	[end_description]

	Copyright 2009-2011 Karsten Ahnert
	Copyright 2009-2011 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_INTEGRATE_INTEGRATE_N_STEPS_HPP_INCLUDED
	#define BOOST_NUMERIC_ODEINT_INTEGRATE_INTEGRATE_N_STEPS_HPP_INCLUDED

	#include <boost/type_traits/is_same.hpp>

	#include <boost/numeric/odeint/stepper/stepper_categories.hpp>
	#include <boost/numeric/odeint/iterator/integrate/null_observer.hpp>
	#include <boost/numeric/odeint/iterator/integrate/detail/integrate_n_steps.hpp>

	namespace boost {
	namespace numeric {
	namespace odeint {


	/*
	* Integrates n steps
	*
	* the two overloads are needed in order to solve the forwarding problem
	*/
	template< class Stepper , class System , class State , class Time , class Observer>
	Time integrate_n_steps(
	Stepper stepper , System system , State &start_state ,
	Time start_time , Time dt , size_t num_of_steps ,
	Observer observer )
	{
	typedef typename odeint::unwrap_reference< Stepper >::type::stepper_category stepper_category;
	return detail::integrate_n_steps(
	stepper , system , start_state ,
	start_time , dt , num_of_steps ,
	observer , stepper_category() );
	}

	/**
	* \brief Solves the forwarding problem, can be called with Boost.Range as start_state.
	*/
	template< class Stepper , class System , class State , class Time , class Observer >
	Time integrate_n_steps(
	Stepper stepper , System system , const State &start_state ,
	Time start_time , Time dt , size_t num_of_steps ,
	Observer observer )
	{
	typedef typename odeint::unwrap_reference< Stepper >::type::stepper_category stepper_category;
	return detail::integrate_n_steps(
	stepper , system , start_state ,
	start_time , dt , num_of_steps ,
	observer , stepper_category() );
	}


	/**
	* \brief The same function as above, but without observer calls.
	*/
	template< class Stepper , class System , class State , class Time >
	Time integrate_n_steps(
	Stepper stepper , System system , State &start_state ,
	Time start_time , Time dt , size_t num_of_steps )
	{
	return integrate_n_steps( stepper , system , start_state , start_time , dt , num_of_steps , null_observer() );
	}

	/**
	* \brief Solves the forwarding problem, can be called with Boost.Range as start_state.
	*/
	template< class Stepper , class System , class State , class Time >
	Time integrate_n_steps(
	Stepper stepper , System system , const State &start_state ,
	Time start_time , Time dt , size_t num_of_steps )
	{
	return integrate_n_steps( stepper , system , start_state , start_time , dt , num_of_steps , null_observer() );
	}



	/*********** DOXYGEN ***********/
	/**
	* \fn Time integrate_n_steps( Stepper stepper , System system , State &start_state , Time start_time , Time dt , size_t num_of_steps , Observer observer )
	* \brief Integrates the ODE with constant step size.
	*
	* This function is similar to integrate_const. The observer is called at
	* equidistant time intervals t0 + n*dt.
	* If the Stepper is a normal stepper without step size control, dt is also
	* used for the numerical scheme. If a ControlledStepper is provided, the
	* algorithm might reduce the step size to meet the error bounds, but it is
	* ensured that the observer is always called at equidistant time points
	* t0 + n*dt. If a DenseOutputStepper is used, the step size also may vary
	* and the dense output is used to call the observer at equidistant time
	* points. The final integration time is always t0 + num_of_steps*dt.
	*
	* \param stepper The stepper to be used for numerical integration.
	* \param system Function/Functor defining the rhs of the ODE.
	* \param start_state The initial condition x0.
	* \param start_time The initial time t0.
	* \param dt The time step between observer calls, _not_ necessarily the
	* time step of the integration.
	* \param num_of_steps Number of steps to be performed
	* \param observer Function/Functor called at equidistant time intervals.
	* \return The number of steps performed.
	*/



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



	#endif // BOOST_NUMERIC_ODEINT_INTEGRATE_INTEGRATE_N_STEPS_HPP_INCLUDED