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SO 5.6 InDepth User Type Msg
Prior to v.5.5.9 every message had to be represented by an instance of a class derived from message_t. It means that if a single integer value need to be sent to an agent the whole dedicated class must have been defined. For example:
enum class engine_action { turn_on, speed_up, slow_down, turn_off };
struct msg_engine_action : public so_5::message_t
{
engine_action m_action;
msg_engine_action( engine_action action ) : m_action{ action } {}
};
...
// Message sending...
so_5::send< msg_engine_action >( engine_agent, engine_action::turn_on );
...
// Message processing…
void engine_agent::evt_engine_action( const msg_engine_action & msg )
{
switch( msg.m_action )
{...}
}Since v.5.5.9 there is a possibility to send an object of arbitrary type as a message. For example:
enum class engine_action { turn_on, speed_up, slow_down, turn_off };
...
// Message sending...
so_5::send< engine_action >( engine_agent, engine_action::turn_on );
...
// Message processing…
void engine_agent::evt_engine_action( engine_action msg )
{
switch( msg )
{...}
}There is a very simple trick: when a user calls send<T>(mbox,args) and T is not derived from message_t then an instance of a special template type user_type_message_t<T> is constructed and delivered as a message.
When an instance of user_type_message_t<T> is extracted from an event queue and the event handler for it has the signature void(const T&) or void(T) then this event handler is called and a reference to the content of user_type_message_t<T> is passed to that event handler.
So it is possible to say that call to send<T>(mbox, args) where T is not derived from message_t is replaced by send<user_message_type_t<T>>(mbox, args).
And the event handler in the form void(const T&) is replaced by:
// void some_class::evt_handler(const T &):
void some_class::real_evt_handler(const user_type_message_t<T> & evt) {
evt_handler(evt.m_payload);
}The user_type_message_t<T> itself is a very simple template:
template< typename T >
struct user_type_message_t : public message_t
{
const T m_payload;
template< typename... Args >
user_type_message_t( Args &&... args )
: m_payload( std::forward< Args >( args )... )
{}
};Messages of arbitrary type T must be handled by non-static methods with signature like:
void event_handler(const T & ); // (1)
void event_handler(T); // (2)
void event_handler(const so_5::mhood_t<T> &); // (3)
void event_handler(so_5::mhood_t<T>); // (3)Or by lambda-function with signatures like:
void(const T&); // (1)
void(T); // (2)
void(const so_5::mhood_t<T> &); // (3)
void(so_5::mhood_t<T>); // (3)But note that in the cases (1) and (3) event-handler will receive a reference to the source message instance. In the case (2) a copy of message content will be passed to the event handler. It can be costly if T is a heavy object.
For example:
struct new_config { ... };
enum class overload_status { normal_load, high_load };
...
class overload_controller : public so_5::agent_t
{
public :
...
virtual void so_define_agent() override
{
so_subscribe_self()
.event( &overload_controller::evt_new_config )
.event( [this]( overload_status status ) {
if( overload_status::high_load == status )
handle_overload();
} );
...
}
void evt_new_config( const new_config & cfg ) {...}
...
};If an event handler receives a message via so_5::mhood_t<T> then T can be a message or signal type.
Delivery filters can be used for messages of arbitrary types. Delivery filter must be a callable object (lambda-function or function) with signatures:
bool(const T&); // (1)
bool(T); // (2)But note that in the case (1) filter will receive a reference to the source message instance. In the case (2) a copy of message content will be passed to filter. It can be costly if T is a heavy object.
class sensor_listener : public so_5::agent_t
{
public :
...
void so_define_agent() override
{
auto mbox = so_environment().create_mbox("sensor");
so_set_delivery_filter( mbox, []( int v ) {
return v > -10 && v < 65;
} );
so_subscribe(mbox).event( &sensor_listener::evt_value );
...
}
...
void evt_value( int v )
{
...
}
};Messages of arbitrary type T can be handled by limit_then_transform helper method. But it is strongly recommended to use make_transformed for new message instance. For example:
enum class overload_status { normal_load, high_load };
...
class request_processor : public so_5::agent_t
{
public :
request_processor( context_t ctx )
: so_5::agent_t( ctx +
limit_then_transform< std::string >( 1000,
[this]( const std::string & ) {
return make_transformed< overload_status >(
overload_controller_mbox,
overload_status::high_load );
} ) )
{...}
...
};