boost_1_45_0/libs/msm/doc/PDF/examples/SimpleTimer.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright 2010 Christophe Henry
 // henry UNDERSCORE christophe AT hotmail DOT com
 // This is an extended version of the state machine available in the boost::mpl library
 // Distributed under the same license as the original.
 // Copyright for the original version:
 // Copyright 2005 David Abrahams and Aleksey Gurtovoy. 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)

 #include <vector>
 #include <iostream>

 #include <boost/msm/back/state_machine.hpp>
 #include <boost/msm/front/euml/euml.hpp>

 using namespace std;
 using namespace boost::msm::front::euml;
 namespace msm = boost::msm;

 // how long the timer will ring when countdown elapsed.
 #define RINGING_TIME 5

 namespace  // Concrete FSM implementation
 {
     // events
     BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_timer)
     BOOST_MSM_EUML_ATTRIBUTES((attributes_ << m_timer ), start_timer_attr)
     BOOST_MSM_EUML_EVENT_WITH_ATTRIBUTES(start_timer,start_timer_attr)

     BOOST_MSM_EUML_EVENT(stop_timer)

     BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_tick)
     BOOST_MSM_EUML_ATTRIBUTES((attributes_ << m_tick ), tick_attr)
     BOOST_MSM_EUML_EVENT_WITH_ATTRIBUTES(tick,tick_attr)

     BOOST_MSM_EUML_EVENT(start_ringing)

     // Concrete FSM implementation

     // The list of FSM states
     BOOST_MSM_EUML_ACTION(Stopped_Entry)
     {
         template <class Event,class FSM,class STATE>
         void operator()(Event const&,FSM&,STATE& )
         {
             std::cout << "entering: Stopped" << std::endl;
         }
     };
     BOOST_MSM_EUML_STATE(( Stopped_Entry ),Stopped)

     BOOST_MSM_EUML_ACTION(Started_Entry)
     {
         template <class Event,class FSM,class STATE>
         void operator()(Event const&,FSM&,STATE& )
         {
             std::cout << "entering: Started" << std::endl;
         }
     };

     BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_counter)
     BOOST_MSM_EUML_STATE((  Started_Entry,
                             no_action,
                             attributes_ << m_counter
                   ),
                   Started)

     BOOST_MSM_EUML_ACTION(Ringing_Entry)
     {
         template <class Event,class FSM,class STATE>
         void operator()(Event const&,FSM&,STATE& )
         {
             std::cout << "entering: Ringing" << std::endl;
         }
     };
     BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_ringing_cpt)
     BOOST_MSM_EUML_STATE((  Ringing_Entry,
                             no_action,
                             attributes_ << m_ringing_cpt
                   ),
                   Ringing)

     // external function
     void do_ring(int ringing_time) {std::cout << "ringing " << ringing_time << " s" << std::endl;}
     // create functor and eUML function
     BOOST_MSM_EUML_FUNCTION(Ring_ , do_ring , ring_ , void , void )

     // replaces the old transition table
     BOOST_MSM_EUML_TRANSITION_TABLE((
         //  +------------------------------------------------------------------------------+
           // When we start the countdown, the countdown value is not hardcoded but contained in the start_timer event.
           // We copy this value into Started
           Started     == Stopped + start_timer /(target_(m_counter)= event_(m_timer))         ,
           Stopped     == Started + stop_timer                                                 ,
           // internal transition
           Started + tick
                     // we here use the message queue to move to Started when the countdown is finished
                     // to do this we put start_ringing into the message queue
                     / if_then_( (source_(m_counter) -= event_(m_tick) ) <= Int_<0>(),
                                  process_(start_ringing) )                                        ,
           // when we start ringing, we give to the state its hard-coded ringing time.
           Ringing     == Started + start_ringing
                            / (target_(m_ringing_cpt) = Int_<RINGING_TIME>(),
                               // call the external do_ring function
                               ring_(Int_<RINGING_TIME>()))                                          ,
           // to change a bit, we now do not use the message queue but a transition conflict to solve the same problem.
           // When tick is fired, we have an internal transition Ringing -> Ringing, as long as Counter > 0
           Ringing + tick [ source_(m_ringing_cpt) - event_(m_tick) > Int_<0>() ]
                              /(target_(m_ringing_cpt) -= event_(m_tick) )                           ,
           // And we move to Stopped when the counter is 0
           Stopped     == Ringing + tick[source_(m_ringing_cpt)-event_(m_tick) <= Int_<0>()]   ,
           // we let the user manually stop the ringing by pressing any button
           Stopped     == Ringing + stop_timer                                                 ,
           Stopped     == Ringing + start_timer
           //  +------------------------------------------------------------------------------+
           ),transition_table)

     // create a state machine "on the fly"
     BOOST_MSM_EUML_DECLARE_STATE_MACHINE(( transition_table, //STT
                                         init_ << Stopped // Init State
                                         ),
                                       SimpleTimer_) //fsm name

     // choice of back-end
     typedef msm::back::state_machine<SimpleTimer_> SimpleTimer;

     //
     // Testing utilities.
     //
     static char const* const state_names[] = { "Stopped", "Started","Ringing" };
     void pstate(SimpleTimer const& p)
     {
         std::cout << " -> " << state_names[p.current_state()[0]] << std::endl;
     }

     void test()
     {
         SimpleTimer p;
         // needed to start the highest-level SM. This will call on_entry and mark the start of the SM
         p.start();

         p.process_event(start_timer(5));pstate(p); //timer set to 5 ticks
         p.process_event(tick(2));pstate(p);
         p.process_event(tick(1));pstate(p);
         p.process_event(tick(1));pstate(p);
         p.process_event(tick(1));pstate(p);
         // we are now ringing, let it ring a bit
         p.process_event(tick(2));pstate(p);
         p.process_event(tick(1));pstate(p);
         p.process_event(tick(1));pstate(p);
         p.process_event(tick(1));pstate(p);
     }
 }

 int main()
 {
     test();
     return 0;
 }
	// Copyright 2010 Christophe Henry
	// henry UNDERSCORE christophe AT hotmail DOT com
	// This is an extended version of the state machine available in the boost::mpl library
	// Distributed under the same license as the original.
	// Copyright for the original version:
	// Copyright 2005 David Abrahams and Aleksey Gurtovoy. 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)

	#include <vector>
	#include <iostream>

	#include <boost/msm/back/state_machine.hpp>
	#include <boost/msm/front/euml/euml.hpp>

	using namespace std;
	using namespace boost::msm::front::euml;
	namespace msm = boost::msm;

	// how long the timer will ring when countdown elapsed.
	#define RINGING_TIME 5

	namespace // Concrete FSM implementation
	{
	// events
	BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_timer)
	BOOST_MSM_EUML_ATTRIBUTES((attributes_ << m_timer ), start_timer_attr)
	BOOST_MSM_EUML_EVENT_WITH_ATTRIBUTES(start_timer,start_timer_attr)

	BOOST_MSM_EUML_EVENT(stop_timer)

	BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_tick)
	BOOST_MSM_EUML_ATTRIBUTES((attributes_ << m_tick ), tick_attr)
	BOOST_MSM_EUML_EVENT_WITH_ATTRIBUTES(tick,tick_attr)

	BOOST_MSM_EUML_EVENT(start_ringing)

	// Concrete FSM implementation

	// The list of FSM states
	BOOST_MSM_EUML_ACTION(Stopped_Entry)
	{
	template <class Event,class FSM,class STATE>
	void operator()(Event const&,FSM&,STATE& )
	{
	std::cout << "entering: Stopped" << std::endl;
	}
	};
	BOOST_MSM_EUML_STATE(( Stopped_Entry ),Stopped)

	BOOST_MSM_EUML_ACTION(Started_Entry)
	{
	template <class Event,class FSM,class STATE>
	void operator()(Event const&,FSM&,STATE& )
	{
	std::cout << "entering: Started" << std::endl;
	}
	};

	BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_counter)
	BOOST_MSM_EUML_STATE(( Started_Entry,
	no_action,
	attributes_ << m_counter
	),
	Started)

	BOOST_MSM_EUML_ACTION(Ringing_Entry)
	{
	template <class Event,class FSM,class STATE>
	void operator()(Event const&,FSM&,STATE& )
	{
	std::cout << "entering: Ringing" << std::endl;
	}
	};
	BOOST_MSM_EUML_DECLARE_ATTRIBUTE(int,m_ringing_cpt)
	BOOST_MSM_EUML_STATE(( Ringing_Entry,
	no_action,
	attributes_ << m_ringing_cpt
	),
	Ringing)

	// external function
	void do_ring(int ringing_time) {std::cout << "ringing " << ringing_time << " s" << std::endl;}
	// create functor and eUML function
	BOOST_MSM_EUML_FUNCTION(Ring_ , do_ring , ring_ , void , void )

	// replaces the old transition table
	BOOST_MSM_EUML_TRANSITION_TABLE((
	// +------------------------------------------------------------------------------+
	// When we start the countdown, the countdown value is not hardcoded but contained in the start_timer event.
	// We copy this value into Started
	Started == Stopped + start_timer /(target_(m_counter)= event_(m_timer)) ,
	Stopped == Started + stop_timer ,
	// internal transition
	Started + tick
	// we here use the message queue to move to Started when the countdown is finished
	// to do this we put start_ringing into the message queue
	/ if_then_( (source_(m_counter) -= event_(m_tick) ) <= Int_<0>(),
	process_(start_ringing) ) ,
	// when we start ringing, we give to the state its hard-coded ringing time.
	Ringing == Started + start_ringing
	/ (target_(m_ringing_cpt) = Int_<RINGING_TIME>(),
	// call the external do_ring function
	ring_(Int_<RINGING_TIME>())) ,
	// to change a bit, we now do not use the message queue but a transition conflict to solve the same problem.
	// When tick is fired, we have an internal transition Ringing -> Ringing, as long as Counter > 0
	Ringing + tick [ source_(m_ringing_cpt) - event_(m_tick) > Int_<0>() ]
	/(target_(m_ringing_cpt) -= event_(m_tick) ) ,
	// And we move to Stopped when the counter is 0
	Stopped == Ringing + tick[source_(m_ringing_cpt)-event_(m_tick) <= Int_<0>()] ,
	// we let the user manually stop the ringing by pressing any button
	Stopped == Ringing + stop_timer ,
	Stopped == Ringing + start_timer
	// +------------------------------------------------------------------------------+
	),transition_table)

	// create a state machine "on the fly"
	BOOST_MSM_EUML_DECLARE_STATE_MACHINE(( transition_table, //STT
	init_ << Stopped // Init State
	),
	SimpleTimer_) //fsm name

	// choice of back-end
	typedef msm::back::state_machine<SimpleTimer_> SimpleTimer;

	//
	// Testing utilities.
	//
	static char const* const state_names[] = { "Stopped", "Started","Ringing" };
	void pstate(SimpleTimer const& p)
	{
	std::cout << " -> " << state_names[p.current_state()[0]] << std::endl;
	}

	void test()
	{
	SimpleTimer p;
	// needed to start the highest-level SM. This will call on_entry and mark the start of the SM
	p.start();

	p.process_event(start_timer(5));pstate(p); //timer set to 5 ticks
	p.process_event(tick(2));pstate(p);
	p.process_event(tick(1));pstate(p);
	p.process_event(tick(1));pstate(p);
	p.process_event(tick(1));pstate(p);
	// we are now ringing, let it ring a bit
	p.process_event(tick(2));pstate(p);
	p.process_event(tick(1));pstate(p);
	p.process_event(tick(1));pstate(p);
	p.process_event(tick(1));pstate(p);
	}
	}

	int main()
	{
	test();
	return 0;
	}