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// $Id$
// ================================================================
//
// = FILENAME
// client.cpp
//
// = DESCRIPTION
// This is a client that uses oneways with buffering constraints
// and roundtrip timeout constraints.
//
// = AUTHOR
// Irfan Pyarali
//
// ================================================================
#include "testC.h"
#include "tao/Messaging/Messaging.h"
#include "tao/AnyTypeCode/TAOA.h"
#include "tao/AnyTypeCode/Any.h"
#include "tao/TAOC.h"
#include "ace/Get_Opt.h"
#include "ace/Read_Buffer.h"
#include "ace/OS_NS_unistd.h"
#include "ace/OS_NS_sys_time.h"
ACE_RCSID(Timed_Buffered_Oneways, client, "$Id$")
// Eager buffering option.
static int eager_buffering = 0;
// Name of file contains ior.
static const ACE_TCHAR *IOR = ACE_TEXT ("file://ior");
// Default iterations.
static u_long iterations = 20;
// Default number of bytes to send as data.
static CORBA::ULong data_bytes = 100000;
// Default roundtrip timeout (in milli seconds).
static long timeout = 500;
// Default amount of work.
static CORBA::ULong work = 3000;
// Time interval between invocation (in milli seconds).
static u_long interval = 500;
// Flag indicates whether to shutdown remote server or not upon client
// shutdown.
static int shutdown_server = 0;
static int
parse_args (int argc, ACE_TCHAR **argv)
{
ACE_Get_Opt get_opts (argc, argv, ACE_TEXT("ek:i:d:t:w:z:x"));
int c;
while ((c = get_opts ()) != -1)
switch (c)
{
case 'e':
eager_buffering = 1;
break;
case 'k':
IOR = get_opts.opt_arg ();
break;
case 'i':
iterations = ACE_OS::atoi (get_opts.opt_arg ());
break;
case 'd':
data_bytes = ACE_OS::atoi (get_opts.opt_arg ());
break;
case 't':
timeout = ACE_OS::atoi (get_opts.opt_arg ());
break;
case 'w':
work = ACE_OS::atoi (get_opts.opt_arg ());
break;
case 'z':
interval = ACE_OS::atoi (get_opts.opt_arg ());
break;
case 'x':
shutdown_server = 1;
break;
case '?':
default:
ACE_ERROR_RETURN ((LM_ERROR,
"usage: %s "
"-e eager buffering [default is delayed] "
"-k IOR "
"-i iterations "
"-d data bytes "
"-t roundtrip timeout "
"-w remote work "
"-z interval between calls "
"-x shutdown server "
"\n",
argv [0]),
-1);
}
if (IOR == 0)
ACE_ERROR_RETURN ((LM_ERROR,
"Please specify the IOR for the servant\n"), -1);
// Indicates successful parsing of command line.
return 0;
}
test_ptr
setup_policies (CORBA::ORB_ptr orb, test_ptr object)
{
test_var object_with_policy;
CORBA::PolicyList policy_list (1);
if (timeout == -1)
{
object_with_policy = test::_duplicate (object);
}
else
{
policy_list.length (1);
TimeBase::TimeT rt_timeout = 10 * 1000 * timeout;
CORBA::Any rt_timeout_any;
rt_timeout_any <<= rt_timeout;
policy_list[0] =
orb->create_policy (Messaging::RELATIVE_RT_TIMEOUT_POLICY_TYPE,
rt_timeout_any);
CORBA::Object_var object_temp =
object->_set_policy_overrides (policy_list,
CORBA::ADD_OVERRIDE);
object_with_policy = test::_narrow (object_temp.in ());
policy_list[0]->destroy ();
}
Messaging::SyncScope sync =
eager_buffering ? Messaging::SYNC_NONE : TAO::SYNC_DELAYED_BUFFERING;
CORBA::Any sync_any;
sync_any <<= sync;
policy_list.length (1);
policy_list[0] =
orb->create_policy (Messaging::SYNC_SCOPE_POLICY_TYPE,
sync_any);
CORBA::Object_var object_temp =
object_with_policy->_set_policy_overrides (policy_list,
CORBA::ADD_OVERRIDE);
test_var object_with_two_policies = test::_narrow (object_temp.in ());
policy_list[0]->destroy ();
return object_with_two_policies._retn ();
}
int
ACE_TMAIN (int argc, ACE_TCHAR *argv[])
{
try
{
// Initialize the ORB.
CORBA::ORB_var orb =
CORBA::ORB_init (argc, argv);
// Initialize options based on command-line arguments.
int parse_args_result = parse_args (argc, argv);
if (parse_args_result != 0)
return parse_args_result;
// Get an object reference from the argument string.
CORBA::Object_var object =
orb->string_to_object (IOR);
// Try to narrow the object reference to a <test> reference.
test_var test_object_no_policy = test::_narrow (object.in ());
// Setup buffering and timeout
test_var test_object = setup_policies (orb.in (),
test_object_no_policy.in ());
test::data the_data (data_bytes);
the_data.length (data_bytes);
for (CORBA::ULong i = 1; i <= iterations; ++i)
{
ACE_Time_Value start = ACE_OS::gettimeofday (), end;
try
{
// Invoke the oneway method.
test_object->method (i,
start.msec (),
the_data,
work);
end = ACE_OS::gettimeofday ();
ACE_DEBUG ((LM_DEBUG,
"client:\t%d took\t%dms\n",
i, (end - start).msec ()));
// Interval between successive calls.
ACE_Time_Value sleep_interval (0, interval * 1000);
// If we don't run the orb, then no data will be sent, and no
// connection will be made initially.
orb->run (sleep_interval);
}
catch (const CORBA::TIMEOUT& )
{
// The timeout could be from a previous loop.
// A simplistic analysis could incorrectly conclude
// that as an unexpected timeout exception.
// We need to maintain a base start time thats updated
// in each iteration.
ACE_DEBUG ((LM_DEBUG, "client: caught expected timeout\n"));
}
}
ACE_DEBUG ((LM_DEBUG, "client: flushing\n"));
test_object_no_policy->flush ();
ACE_DEBUG ((LM_DEBUG, "client: Shutting down...\n"));
if (shutdown_server)
{
ACE_DEBUG ((LM_DEBUG,"client killing server\n"));
long now = ACE_OS::gettimeofday ().msec ();
test_object_no_policy->shutdown (now);
}
orb->shutdown (1);
// Destroy the ORB. On some platforms, e.g., Win32, the socket
// library is closed at the end of main(). This means that any
// socket calls made after main() fail. Hence if we wait for
// static destructors to flush the queues, it will be too late.
// Therefore, we use explicit destruction here and flush the
// queues before main() ends.
orb->destroy ();
}
catch (const CORBA::Exception& ex)
{
ex._tao_print_exception ("Client side exception caught:");
return -1;
}
return 0;
}
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