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// $Id$
#include "Consumer.h"
#include "AddrServer.h"
#include "orbsvcs/Event_Service_Constants.h"
#include "orbsvcs/Event/EC_Event_Channel.h"
#include "orbsvcs/Event/EC_Default_Factory.h"
#include "orbsvcs/Event/ECG_Mcast_EH.h"
#include "orbsvcs/Event/ECG_UDP_Receiver.h"
#include "orbsvcs/Event/ECG_UDP_Out_Endpoint.h"
#include "tao/ORB_Core.h"
#include "ace/Get_Opt.h"
#include "ace/OS_NS_unistd.h"
#include "TestC.h"
const ACE_TCHAR *udp_mcast_address =
ACE_TEXT (ACE_DEFAULT_MULTICAST_ADDR) ACE_TEXT(":10001");
bool valuetype = false;
int parse_args (int argc, ACE_TCHAR *argv[]);
int
ACE_TMAIN(int argc, ACE_TCHAR *argv[])
{
// Register the default factory in the Service Configurator.
// If your platform supports static constructors then you can
// simply using the ACE_STATIC_SVC_DEFINE() macro, unfortunately TAO
// must run on platforms where static constructors do not work well,
// so we have to explicitly invoke this function.
TAO_EC_Default_Factory::init_svcs ();
// The exception macros are described in $ACE_ROOT/docs/exceptions.html
// and defined in $ACE_ROOT/ace/CORBA_macros.h.
// If your platform supports native exceptions, and TAO was compiled
// with native exception support then you can simply use try/catch
// and avoid the argument.
// Unfortunately many embedded systems cannot use exceptions due to
// the space and time overhead.
//
try
{
// **************** HERE STARTS THE ORB SETUP
// Create the ORB, pass the argv list for parsing.
CORBA::ORB_var orb =
CORBA::ORB_init (argc, argv);
// Parse the arguments, you usually want to do this after
// invoking ORB_init() because ORB_init() will remove all the
// -ORB options from the command line.
if (parse_args (argc, argv) == -1)
{
ACE_ERROR ((LM_ERROR,
"Usage: Service [-m udp_mcast_addr]\n"));
return 1;
}
if (valuetype)
{
Hello::ValueTypeData_init *vb_factory = 0;
ACE_NEW_RETURN (vb_factory,
Hello::ValueTypeData_init,
1); // supplied by mapping
orb->register_value_factory (vb_factory->tao_repository_id (),
vb_factory);
vb_factory->_remove_ref (); // release ownership
}
// This is the standard code to get access to the POA and
// activate it.
// The POA starts in the holding state, if it is not activated
// it will not process any requests.
CORBA::Object_var object =
orb->resolve_initial_references ("RootPOA");
PortableServer::POA_var poa =
PortableServer::POA::_narrow (object.in ());
PortableServer::POAManager_var poa_manager =
poa->the_POAManager ();
poa_manager->activate ();
// **************** THAT COMPLETS THE ORB SETUP
// **************** HERE START THE LOCAL EVENT CHANNEL SETUP
// This structure is used to define the startup time event
// channel configuration.
// This structure is described in
//
// $TAO_ROOT/docs/ec_options.html
//
TAO_EC_Event_Channel_Attributes attributes (poa.in (),
poa.in ());
// Create the Event Channel implementation class
TAO_EC_Event_Channel ec_impl (attributes);
// Activate the Event Channel, depending on the configuration
// that may involve creating some threads.
// But it should always be invoked because several internal data
// structures are initialized at that point.
ec_impl.activate ();
// The event channel is activated as any other CORBA servant.
// In this case we use the simple implicit activation with the
// RootPOA
RtecEventChannelAdmin::EventChannel_var event_channel =
ec_impl._this ();
// **************** THAT COMPLETES THE LOCAL EVENT CHANNEL SETUP
// **************** HERE STARTS THE FEDERATION SETUP
// The next step is to setup the multicast gateways.
// There are two gateways involved, one sends the locally
// generated events to the federated peers, the second gateway
// receives multicast traffic and turns it into local events.
// The sender requires a helper object to select what
// multicast group will carry what traffic, this is the
// so-called 'Address Server'.
// The intention is that advanced applications can use different
// multicast groups for different events, this can exploit
// network interfaces that filter unwanted multicast traffic.
// The helper object is accessed through an IDL interface, so it
// can reside remotely.
// In this example, and in many application, using a fixed
// multicast group is enough, and a local address server is the
// right approach.
// First we convert the string into an INET address, then we
// convert that into the right IDL structure:
ACE_INET_Addr udp_addr (udp_mcast_address);
ACE_DEBUG ((LM_DEBUG,
"udp mcast address is: %s\n",
udp_mcast_address));
// Now we create and activate the servant
AddrServer as_impl (udp_addr);
RtecUDPAdmin::AddrServer_var address_server =
as_impl._this ();
TAO_ECG_Refcounted_Endpoint endpoint(new TAO_ECG_UDP_Out_Endpoint);
// Now we connect the sender as a consumer of events, it will
// receive any event from any source and send it to the "right"
// multicast group, as defined by the address server set above:
RtecEventChannelAdmin::ConsumerQOS sub;
sub.is_gateway = 1;
sub.dependencies.length (1);
sub.dependencies[0].event.header.type =
ACE_ES_EVENT_ANY; // first free event type
sub.dependencies[0].event.header.source =
ACE_ES_EVENT_SOURCE_ANY; // Any source is OK
// To receive events we need to setup an event handler:
TAO_EC_Servant_Var<TAO_ECG_UDP_Receiver> receiver = TAO_ECG_UDP_Receiver::create();
TAO_ECG_Mcast_EH mcast_eh (&(*receiver));
// The event handler uses the ORB reactor to wait for multicast
// traffic:
mcast_eh.reactor (orb->orb_core ()->reactor ());
// The multicast Event Handler needs to know to what multicast
// groups it should listen to. To do so it becomes an observer
// with the event channel, to determine the list of events
// required by all the local consumer.
// Then it register for the multicast groups that carry those
// events:
mcast_eh.open (event_channel.in ());
// Again the receiver connects to the event channel as a
// supplier of events, using the Observer features to detect
// local consumers and their interests:
receiver->init (event_channel.in (),
endpoint,
address_server.in ());
// The Receiver is also a supplier of events. The exact type of
// events is only known to the application, because it depends
// on the traffic carried by all the multicast groups that the
// different event handlers subscribe to.
// In this example we choose to simply describe our publications
// using wilcards, any event from any source. More advanced
// application could use the Observer features in the event
// channel to update this information (and reduce the number of
// multicast groups that each receive subscribes to).
// In a future version the event channel could perform some of
// those tasks automatically
RtecEventChannelAdmin::SupplierQOS pub;
pub.publications.length (1);
pub.publications[0].event.header.type = ACE_ES_EVENT_ANY;
pub.publications[0].event.header.source = ACE_ES_EVENT_SOURCE_ANY;
pub.is_gateway = 1;
receiver->connect (pub);
// **************** THAT COMPLETES THE FEDERATION SETUP
// **************** HERE STARTS THE CLIENT SETUP
// First let us create a consumer and connect it to the event
// channel
Consumer consumer (valuetype);
RtecEventChannelAdmin::ConsumerAdmin_var consumer_admin =
event_channel->for_consumers ();
consumer.connect (consumer_admin.in ());
// **************** THAT COMPLETES THE CLIENT SETUP
// **************** HERE STARTS THE EVENT LOOP
// Wait for events, including incoming multicast data.
// We could also use orb->run(), but that will not let us
// terminate the application in a nice way.
for (int i = 0; i != 100; ++i)
{
CORBA::Boolean there_is_work =
orb->work_pending ();
if (there_is_work)
{
// We use a TAO extension. The CORBA mechanism does not
// provide any decent way to control the duration of
// perform_work() or work_pending(), so just calling
// them results in a spin loop.
ACE_Time_Value tv (0, 50000);
orb->perform_work (tv);
}
ACE_Time_Value tv (0, 100000);
ACE_OS::sleep (tv);
if (consumer.event_count () == 25)
{
break;
}
}
// **************** THAT COMPLETES THE EVENT LOOP
// **************** HERE STARTS THE CLEANUP CODE
consumer.disconnect ();
// Now let us close the Receiver
receiver->shutdown ();
int const r = mcast_eh.shutdown ();
if (r == -1)
{
ACE_ERROR_RETURN ((LM_ERROR,
"Closing MCast event handler\n"), 1);
}
// The event channel must be destroyed, so it can release its
// resources, and inform all the clients that are still
// connected that it is going away.
event_channel->destroy ();
// Deactivating the event channel implementation is not strictly
// required, the POA will do it for us, but it is good manners:
{
// Using _this() activates with the default POA, we must gain
// access to that POA to deactivate the object.
// Notice that we 'know' that the default POA for this servant
// is the root POA, but the code is more robust if we don't
// rely on that.
PortableServer::POA_var poa =
ec_impl._default_POA ();
// Get the Object Id used for the servant..
PortableServer::ObjectId_var oid =
poa->servant_to_id (&ec_impl);
// Deactivate the object
poa->deactivate_object (oid.in ());
}
// Now we can destroy the POA, the flags mean that we want to
// wait until the POA is really destroyed
poa->destroy (1, 1);
// Finally destroy the ORB
orb->destroy ();
// **************** THAT COMPLETES THE CLEANUP CODE
ACE_DEBUG ((LM_DEBUG,
"UDP receiver ready\n"));
}
catch (const CORBA::Exception& ex)
{
ex._tao_print_exception ("Service");
return 1;
}
return 0;
}
// ****************************************************************
int parse_args (int argc, ACE_TCHAR *argv[])
{
ACE_Get_Opt get_opts (argc, argv, ACE_TEXT("vm:"));
int c;
while ((c = get_opts ()) != -1)
switch (c)
{
case 'm':
udp_mcast_address = get_opts.opt_arg ();
break;
case 'v':
valuetype = true;
break;
case '?':
default:
ACE_ERROR_RETURN ((LM_ERROR,
"usage: %s "
"[-m udp_mcast_address]"
"[-v]"
"\n",
argv [0]),
-1);
}
// Indicates sucessful parsing of the command line
return 0;
}
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