// This tests the features of the and // classes. In addition, it can be used to test the // oneway and twoway latency and throughput at the socket-level. This // is useful as a baseline to compare against ORB-level performance // for the same types of data. #include "CPP-inclient.h" #include "ace/SOCK_Connector.h" #include "ace/INET_Addr.h" #include "ace/Thread_Manager.h" #include "ace/Singleton.h" #include "ace/Get_Opt.h" #include "ace/Truncate.h" #include "ace/High_Res_Timer.h" #include "ace/Basic_Types.h" #include "ace/OS_NS_string.h" #include "ace/OS_NS_unistd.h" #include "ace/OS_main.h" Options::Options (void) : host_ (ACE_DEFAULT_SERVER_HOST), port_ (ACE_DEFAULT_SERVER_PORT), sleep_time_ (0, 0), // By default, don't sleep between calls. threads_ (10), quit_string_ (ACE_TEXT("q")), message_len_ (0), message_buf_ (0), io_source_ (ACE_INVALID_HANDLE), // Defaults to using the generator. iterations_ (10000), oneway_ (1) // Make oneway calls the default. #if defined (ACE_MT_SAFE) && (ACE_MT_SAFE != 0) , barrier_ (0) #endif /* ACE_MT_SAFE */ { } Options::~Options (void) { ACE_MT (delete this->barrier_); delete [] this->message_buf_; } // Options Singleton. typedef ACE_Singleton OPTIONS; int Options::init (void) { ACE_DEBUG((LM_DEBUG,"Options::init, len = %d\n",this->message_len_)); // Check for default case. if (this->message_len_ == 0) this->message_len_ = ACE_OS::strlen ("TAO"); ACE_DEBUG((LM_DEBUG,"Options::init, len = %d\n",this->message_len_)); this->message_len_ += sizeof (ACE_UINT32); ACE_DEBUG((LM_DEBUG,"Options::init, len = %d\n",this->message_len_)); ACE_NEW_RETURN (this->message_buf_, char[this->message_len_], -1); // Copy the length into the beginning of the message. ACE_UINT32 length = ACE_NTOHL (ACE_Utils::truncate_cast (this->message_len_)); ACE_OS::memcpy ((void *) this->message_buf_, (void *) &length, sizeof length); ACE_OS::memset ((void *) (this->message_buf_ + sizeof (ACE_UINT32)), 'a', this->message_len_ - sizeof (ACE_UINT32)); // Allocate the barrier with the correct count. ACE_MT (ACE_NEW_RETURN (this->barrier_, ACE_Barrier ( ACE_Utils::truncate_cast ( this->threads_)), -1)); return 0; } size_t Options::message_len () const { return this->message_len_; } const void * Options::message_buf () const { return this->message_buf_; } ssize_t Options::read (void *buf, size_t len, size_t &iteration) { ACE_UNUSED_ARG (len); if (this->io_source_ == ACE_STDIN) return ACE_OS::read (ACE_STDIN, buf, len); else if (iteration >= this->iterations_) return 0; else { ACE_OS::memcpy (buf, this->message_buf (), len); iteration++; return ACE_Utils::truncate_cast (len); } } int Options::parse_args (int argc, ACE_TCHAR *argv[]) { //FUZZ: disable check_for_lack_ACE_OS ACE_Get_Opt getopt (argc, argv, ACE_TEXT("2h:i:m:p:q:st:T:"), 1); for (int c; (c = getopt ()) != -1; ) //FUZZ: enable check_for_lack_ACE_OS switch (c) { case '2': // Disable the oneway client. this->oneway_ = 0; break; case 'h': this->host_ = getopt.opt_arg (); break; case 'i': this->iterations_ = ACE_OS::atoi (getopt.opt_arg ()); break; case 'm': this->message_len_ = ACE_OS::atoi (getopt.opt_arg ()); break; case 'p': this->port_ = ACE_OS::atoi (getopt.opt_arg ()); break; case 'q': this->quit_string_ = getopt.opt_arg (); break; case 's': this->io_source_ = ACE_STDIN; break; case 't': this->threads_ = (size_t) ACE_OS::atoi (getopt.opt_arg ()); break; case 'T': this->sleep_time_.set (0, ACE_OS::atoi (getopt.opt_arg ())); break; default: ACE_ERROR_RETURN ((LM_ERROR, "(%P|%t) usage: %n [-2] [-h ] [-i iterations] [-m message-size] [-p ] [-q ] [-s] [-t ] [-T ]\n"), -1); } return this->init (); } u_short Options::port () const { return this->port_; } const ACE_TCHAR * Options::host () const { return this->host_; } const ACE_TCHAR * Options::quit_string () const { return this->quit_string_; } size_t Options::threads () const { return this->threads_; } const ACE_Time_Value & Options::sleep_time () const { return this->sleep_time_; } char * Options::shared_client_test (u_short port, ACE_SOCK_Stream &cli_stream) { ACE_INET_Addr remote_addr (port, this->host_); ACE_SOCK_Connector con; if (con.connect (cli_stream, remote_addr) == -1) ACE_ERROR_RETURN ((LM_ERROR, "(%P|%t) %p\n", "connection failed"), 0); else ACE_DEBUG ((LM_DEBUG, "(%P|%t) connected to %s at port %d\n", remote_addr.get_host_name (), remote_addr.get_port_number ())); ACE_INT32 len = ACE_HTONL (ACE_Utils::truncate_cast (this->message_len ())); // Allocate the transmit buffer. char *buf; ACE_DEBUG((LM_DEBUG,"(%P|%t) allocating buffer, len = %d msglen = %d\n", len, message_len_)); ACE_NEW_RETURN (buf, char[this->message_len()], 0); ACE_DEBUG ((LM_DEBUG, "(%P|%t) waiting...\n")); // Wait for all other threads to finish initialization. ACE_MT (this->barrier_->wait ()); return buf; } // Static function entry point to the oneway client service. void * Options::oneway_client_test (void *) { Options *options = OPTIONS::instance (); ACE_SOCK_Stream cli_stream; ACE_DEBUG((LM_DEBUG,"options = %d, len = %d\n",options,options->message_len())); // Add 1 to the port to trigger the oneway test! char *request = options->shared_client_test (options->port () + 1, cli_stream); if (request == 0) return 0; // This variable is allocated off the stack to obviate the need for // locking. size_t iteration = 0; // Keep track of return value. intptr_t result = 0; ACE_INT32 len = ACE_Utils::truncate_cast (options->message_len ()); ACE_DEBUG ((LM_DEBUG, "(%P|%t) starting oneway transmission\n")); // Perform oneway transmission of data to server (correctly handles // "incomplete writes"). for (ssize_t r_bytes; (r_bytes = options->read (request, len, iteration)) > 0; // Transmit at the proper rate. ACE_OS::sleep (options->sleep_time ())) if (ACE_OS::memcmp (request, options->quit_string (), ACE_OS::strlen (options->quit_string ())) == 0) break; else if (cli_stream.send_n (request, r_bytes) == -1) { ACE_ERROR ((LM_ERROR, "(%P|%t) %p\n", "send_n")); result = -1; break; } // Close the connection. cli_stream.close (); delete [] request; return reinterpret_cast (result); } // Static function entry point to the twoway client service. void * Options::twoway_client_test (void *) { Options *options = OPTIONS::instance (); ACE_SOCK_Stream cli_stream; char *request = options->shared_client_test (options->port (), cli_stream); if (request == 0) return 0; // This variable is allocated off the stack to obviate the need for // locking. size_t iteration = 0; // Keep track of return value. intptr_t result = 0; // Timer business. ACE_High_Res_Timer timer; ACE_INT32 len = ACE_Utils::truncate_cast (options->message_len ()); ACE_DEBUG ((LM_DEBUG, "(%P|%t) starting twoway transmission\n")); // Perform twoway transmission of data to server (correctly handles // "incomplete writes"). for (ssize_t r_bytes; (r_bytes = options->read (request, len, iteration)) > 0; // Transmit at the proper rate. ACE_OS::sleep (options->sleep_time ())) if (ACE_OS::memcmp (request, options->quit_string (), ACE_OS::strlen (options->quit_string ())) == 0) break; // Transmit to the server. else { // Note that we use the incremental feature of the // so that we don't get "charged" for the // used to control the rate at which requests // are sent. timer.start_incr (); if (cli_stream.send_n (request, r_bytes) == -1) { ACE_ERROR ((LM_ERROR, "(%P|%t) %p\n", "send_n")); result = -1; break; } // Receive the reply from the server. Normally, it just sends // back 24 bytes, which is typical for an IIOP reply. else if (cli_stream.recv (request, r_bytes) <= 0) { ACE_ERROR ((LM_ERROR, "(%P|%t) %p\n", "recv")); result = -1; break; } timer.stop_incr (); } ACE_Time_Value tv; timer.elapsed_time_incr (tv); double real_time = (long) tv.sec () * ACE_ONE_SECOND_IN_USECS + tv.usec (); double messages_per_sec = iteration * double (ACE_ONE_SECOND_IN_USECS) / real_time; ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%t) messages = %d\n(%t) usec-per-message = %f\n(%t) messages-per-second = %0.00f\n"), iteration, real_time / double (iteration), messages_per_sec < 0 ? 0 : messages_per_sec)); // Close the connection. cli_stream.close (); delete [] request; return reinterpret_cast (result); } ACE_THR_FUNC Options::thr_func (void) { ACE_DEBUG((LM_DEBUG,"(%P|%t) in thread func, mesg len = %d\n",this->message_len())); if (this->oneway_ == 0) return ACE_THR_FUNC (&Options::twoway_client_test); else return ACE_THR_FUNC (&Options::oneway_client_test); } static int run_client (void) { // Raise the socket handle limit to the maximum. ACE::set_handle_limit (); #if defined (ACE_HAS_THREADS) ACE_DEBUG((LM_DEBUG,"(%P|%t) spawning client test thread options = %d\n", OPTIONS::instance())); if (ACE_Thread_Manager::instance ()->spawn_n (OPTIONS::instance ()->threads (), OPTIONS::instance ()->thr_func ()) == -1) ACE_ERROR_RETURN ((LM_ERROR, "(%P|%t) %p\n", "spawn_n"), 1); else ACE_Thread_Manager::instance ()->wait (); #else (void) *(OPTIONS::instance ()->thr_func) (); #endif /* ACE_HAS_THREADS */ return 0; } int ACE_TMAIN (int argc, ACE_TCHAR *argv[]) { // Initialize the logger. ACE_LOG_MSG->open (argv[0]); if (OPTIONS::instance ()->parse_args (argc, argv) == -1) return -1; // Run the client run_client (); return 0; } ACE_SINGLETON_TEMPLATE_INSTANTIATE(ACE_Singleton, Options, ACE_SYNCH_RECURSIVE_MUTEX);