// Exercise the wrapper along with the . // This test simply ping-pongs datagrams back and forth between the // peer1 and peer2 processes. This test can be run in two ways: // // 1. Stand-alone -- e.g., // // % ./Dgram // // which will spawn a child process and run peer1 and peer2 // in different processes on the same machine. // // 2. Distributed -- e.g., // // # Peer1 // % ./Dgram 10002 tango.cs.wustl.edu 10003 peer1 // // # Peer1 // % ./Dgram 10003 tango.cs.wustl.edu 10002 peer2 // // which will run peer1 and peer2 in different processes // on the same or different machines. Note that you MUST // give the name "peer1" as the final argument to one and // only one of the programs so that the test will work properly. #include "ace/OS_main.h" #include "ace/OS_NS_string.h" #include "ace/OS_NS_unistd.h" #include "ace/Reactor.h" #include "ace/Process.h" #include "ace/SOCK_Dgram.h" #include "ace/INET_Addr.h" #include "ace/Log_Msg.h" // Port used to receive for dgrams. static u_short port1; class Dgram_Endpoint : public ACE_Event_Handler { public: Dgram_Endpoint (const ACE_INET_Addr &local_addr); // = Hook methods inherited from the . virtual ACE_HANDLE get_handle () const; virtual int handle_input (ACE_HANDLE handle); virtual int handle_timeout (const ACE_Time_Value & tv, const void *arg = 0); virtual int handle_close (ACE_HANDLE handle, ACE_Reactor_Mask close_mask); //FUZZ: disable check_for_lack_ACE_OS int send (const char *buf, size_t len, const ACE_INET_Addr &); // Send the to the peer. //FUZZ: enable check_for_lack_ACE_OS private: ACE_SOCK_Dgram endpoint_; // Wrapper for sending/receiving dgrams. }; int Dgram_Endpoint::send (const char *buf, size_t len, const ACE_INET_Addr &addr) { return this->endpoint_.send (buf, len, addr); } Dgram_Endpoint::Dgram_Endpoint (const ACE_INET_Addr &local_addr) : endpoint_ (local_addr) { } ACE_HANDLE Dgram_Endpoint::get_handle () const { return this->endpoint_.get_handle (); } int Dgram_Endpoint::handle_close (ACE_HANDLE handle, ACE_Reactor_Mask) { ACE_UNUSED_ARG (handle); this->endpoint_.close (); delete this; return 0; } int Dgram_Endpoint::handle_input (ACE_HANDLE) { char buf[BUFSIZ]; ACE_INET_Addr from_addr; ACE_DEBUG ((LM_DEBUG, "(%P|%t) activity occurred on handle %d!\n", this->endpoint_.get_handle ())); ssize_t n = this->endpoint_.recv (buf, sizeof buf, from_addr); if (n == -1) ACE_ERROR ((LM_ERROR, "%p\n", "handle_input")); else ACE_DEBUG ((LM_DEBUG, "(%P|%t) buf of size %d = %*s\n", n, n, buf)); return 0; } int Dgram_Endpoint::handle_timeout (const ACE_Time_Value &, const void *) { ACE_DEBUG ((LM_DEBUG, "(%P|%t) timed out for endpoint\n")); return 0; } static int run_test (u_short localport, const ACE_TCHAR *remotehost, u_short remoteport, const ACE_TCHAR *peer) { ACE_INET_Addr remote_addr (remoteport, remotehost); ACE_INET_Addr local_addr (localport); Dgram_Endpoint *endpoint; ACE_NEW_RETURN (endpoint, Dgram_Endpoint (local_addr), -1); // Read data from other side. if (ACE_Reactor::instance ()->register_handler (endpoint, ACE_Event_Handler::READ_MASK) == -1) ACE_ERROR_RETURN ((LM_ERROR, "ACE_Reactor::register_handler"), -1); char buf[BUFSIZ]; ACE_OS::strcpy (buf, "Data to transmit"); size_t len = ACE_OS::strlen (buf); if (ACE_OS::strncmp (peer, ACE_TEXT("peer1"), 5) == 0) { ACE_DEBUG ((LM_DEBUG, "(%P|%t) sending data\n")); for (size_t i = 0; i < 20; i++) { endpoint->send (buf, len, remote_addr); ACE_DEBUG ((LM_DEBUG, "(%P|%t) .\n")); ACE_OS::sleep (1); } } for (int i = 0; i < 40; i++) { // Wait up to 10 seconds for data. ACE_Time_Value tv (10, 0); if (ACE_Reactor::instance ()->handle_events (tv) <= 0) ACE_ERROR_RETURN ((LM_DEBUG, "(%P|%t) %p\n", "handle_events"), -1); ACE_DEBUG ((LM_DEBUG, "(%P|%t) return from handle events\n")); endpoint->send (buf, len, remote_addr); ACE_DEBUG ((LM_DEBUG, "(%P|%t) .\n")); } if (ACE_Reactor::instance ()->remove_handler (endpoint, ACE_Event_Handler::READ_MASK) == -1) ACE_ERROR_RETURN ((LM_ERROR, "ACE_Reactor::remove_handler"), -1); ACE_DEBUG ((LM_DEBUG, "(%P|%t) exiting\n")); return 0; } int ACE_TMAIN (int argc, ACE_TCHAR *argv[]) { // Estabish call backs and socket names. port1 = argc > 1 ? ACE_OS::atoi (argv[1]) : ACE_DEFAULT_SERVER_PORT; const ACE_TCHAR *remotehost = argc > 2 ? argv[2] : ACE_DEFAULT_SERVER_HOST; const u_short port2 = argc > 3 ? ACE_OS::atoi (argv[3]) : port1 + 1; // Providing the fourth command line argument indicate we don't want // to spawn a new process. On Win32, we use this to exec the new // program. if (argc > 4) run_test (port1, remotehost, port2, argv[4]); else { ACE_DEBUG ((LM_DEBUG, "(%P|%t) local port = %d, remote host = %s, remote port = %d\n", port1, remotehost, port2)); ACE_Process_Options options; options.command_line (ACE_TEXT ("%s %d %s %d %c"), argv[0], port1, remotehost, port2, 'c'); // This has no effect on NT and will spawn a process that exec // the above run_test function. options.creation_flags (ACE_Process_Options::NO_EXEC); ACE_Process new_process; switch (new_process.spawn (options)) { case -1: return -1; case 0: run_test (port1, remotehost, port2, ACE_TEXT("peer1")); break; default: run_test (port2, remotehost, port1, ACE_TEXT("peer2")); new_process.wait (); break; } } return 0; }