// $Id$ // =========================================================================== // // = LIBRARY // tests // // = FILENAME // SOCK_Send_Recv_Test.cpp // // = DESCRIPTION // This is a test of the 's various send and receive // methods. The test forks two processes or spawns two threads // (depending upon the platform) and then executes client and // server allowing them to connect and exchange data in ways // designed to exercise the send and recv functions. // // Right now, it primarily tests the iov-like send and recv // functions, but others should be added to completely cover the // possible scenarios. // // = AUTHOR // Steve Huston // // ============================================================================ #include "test_config.h" #include "ace/OS_NS_sys_wait.h" #include "ace/OS_NS_unistd.h" #include "ace/Thread.h" #include "ace/Thread_Manager.h" #include "ace/Time_Value.h" #include "ace/SOCK_Connector.h" #include "ace/SOCK_Acceptor.h" #include "ace/SOCK_Stream.h" ACE_RCSID(tests, SOCK_Send_Recv_Test, "$Id$") // Change to non-zero if test fails static int Test_Result = 0; #if !defined (ACE_LACKS_FORK) || defined (ACE_HAS_THREADS) // In test 3, a large amount of data is sent. The purpose is to overflow the // TCP send window, causing the sender to block (it's a send_n). This value // is the amount to send. The assumption is that no implementation has a // receive window larger than 128K bytes. If one is found, this is the place // to change it. // For some odd reason, NT will try to send a single large buffer, but not // multiple smaller ones that add up to the large size. const size_t Test3_Send_Size = 4*1024; const size_t Test3_Loops = 10; const size_t Test3_Total_Size = Test3_Send_Size * Test3_Loops; static void * client (void *arg) { ACE_INET_Addr *remote_addr = ACE_reinterpret_cast (ACE_INET_Addr *, arg); ACE_INET_Addr server_addr (remote_addr->get_port_number (), ACE_LOCALHOST); ACE_SOCK_Stream cli_stream; ACE_SOCK_Connector con; ACE_Time_Value timeout (ACE_DEFAULT_TIMEOUT); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%P|%t) Connecting to port %d\n"), server_addr.get_port_number())); // Initiate connection with server; don't wait forever if (con.connect (cli_stream, server_addr, &timeout) == -1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n"), ACE_TEXT ("connection failed"))); Test_Result = 1; return 0; } ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%P|%t) connected to %s\n"), ACE_TEXT_CHAR_TO_TCHAR(server_addr.get_host_name ()))); //******************* TEST 1 ****************************** // // Do a iovec sendv - send the 255 byte buffer in 5 chunks. The // server will verify that the correct data is sent, and that there // is no more and no less. u_char buffer[255]; size_t i; ssize_t len; // The server will verify that this data pattern gets there intact. for (i = 0; i < sizeof buffer; ++i) buffer[i] = ACE_static_cast (u_char, i); iovec iov[5]; iov[0].iov_base = ACE_reinterpret_cast (char *, &buffer[0]); iov[0].iov_len = 50; iov[1].iov_base = ACE_reinterpret_cast (char *, &buffer[50]); iov[1].iov_len = 25; iov[2].iov_base = ACE_reinterpret_cast (char *, &buffer[75]); iov[2].iov_len = 150; iov[3].iov_base = ACE_reinterpret_cast (char *, &buffer[225]); iov[3].iov_len = 29; iov[4].iov_base = ACE_reinterpret_cast (char *, &buffer[254]); iov[4].iov_len = 1; len = cli_stream.sendv (iov, 5); if (len == -1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n"), ACE_TEXT ("Test 1, sendv failed"))); Test_Result = 1; } else ACE_ASSERT (len == 255); //******************* TEST 2 ****************************** // // The same data is coming back - receive it using recv (size_t n, // ...) and compare it to the original data. u_char buffer2[255]; // Give it a chance to get here ACE_OS::sleep (2); len = cli_stream.recv (4, buffer2, 150, &buffer2[150], 105); if (len != 255) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p; len is %d, but should be 255!\n"), len)); } ACE_ASSERT (len == 255); for (i = 0; i < 255; i++) if (buffer2[i] != buffer[i]) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) Test 2, rcvd byte %d is %d, not %d\n"), i, buffer2[i], buffer[i])); Test_Result = 1; } //******************* TEST 3 ****************************** // // Do a send_n of a large size. The receive should sleep some to // cause the data reception to be delayed, which will fill up the // TCP window and cause send_n to block at some point. The particular // case this tests only needs to be exercised if the socket is // non-blocking, so set that first. ssize_t sent; char buff[Test3_Send_Size]; ACE_ASSERT (cli_stream.enable (ACE_NONBLOCK) != -1); for (i = 0; i < Test3_Loops; ++i) { errno = 0; sent = cli_stream.send_n (buff, sizeof (buff)); if (sent != sizeof (buff) && errno != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) Test 3, pass %d, sent %d, %p\n"), i, sent, ACE_TEXT ("error"))); Test_Result = 1; // Fail } } cli_stream.close (); return 0; } static void * server (void *arg) { ACE_SOCK_Acceptor *peer_acceptor = (ACE_SOCK_Acceptor *) arg; ACE_SOCK_Stream sock_str; ACE_INET_Addr cli_addr; ACE_Time_Value timeout (ACE_DEFAULT_TIMEOUT); // Accept the connection over which the stream tests will run. // Don't lock up if client doesn't connect if (peer_acceptor->accept (sock_str, &cli_addr, &timeout) == -1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n"), ACE_TEXT ("accept"))); Test_Result = 1; return 0; } ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%P|%t) client %s connected from %d\n"), ACE_TEXT_CHAR_TO_TCHAR(cli_addr.get_host_name ()), cli_addr.get_port_number ())); //******************* TEST 1 ****************************** // // Do a iovec recvv - the client should send 255 bytes, which we // will be detected and read into a ACE-allocated buffer. Use a 5 // second timeout to give the client a chance to send it all. ACE_OS::sleep (5); iovec iov[3]; u_char buffer[255]; ssize_t len; int i; iov[0].iov_base = ACE_reinterpret_cast (char *, &buffer[0]); iov[0].iov_len = 75; iov[1].iov_base = ACE_reinterpret_cast (char *, &buffer[75]); iov[1].iov_len = 100; iov[2].iov_base = ACE_reinterpret_cast (char *, &buffer[175]); iov[2].iov_len = 80; len = sock_str.recvv_n (iov, 3); if (len == -1) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n"), ACE_TEXT ("Test 1, recvv failed"))); Test_Result = 1; } ACE_ASSERT (len == 255); for (i = 0; i < 255; i++) if (buffer[i] != i) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) Test 1, rcvd byte %d is %d, not %d\n"), i, buffer[i], i)); Test_Result = 1; } //******************* TEST 2 ****************************** // // Send the buffer back, using send (size_t n, ...) in 3 pieces. len = sock_str.send (6, buffer, 42, &buffer[42], 189, &buffer[231], 24); ACE_ASSERT (len == 255); //******************* TEST 3 ****************************** // // The sender is testing send_n to make sure it blocks if the TCP // window fills. So sleep here for a bit to avoid getting the data // yet. Then just read and empty out the received data. ACE_OS::sleep (8); // Keep reading until the peer closes. sock_str.disable (ACE_NONBLOCK); ssize_t got = 1; size_t total_recv = 0; while (got != 0) { errno = 0; got = sock_str.recv (buffer, sizeof (buffer)); if (got < 0) break; total_recv += got; } ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%P|%t) Test 3 received %d bytes\n"), total_recv)); if (total_recv == Test3_Total_Size) { if (got != 0 || errno != 0) { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) Test 3 final recv status %d, expected 0\n"), got)); ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n"), ACE_TEXT ("expected errno == 0, instead"))); Test_Result = 1; // Fail } } else { ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) Test 3 expected %d %p\n"), Test3_Total_Size, ACE_TEXT ("bytes"))); Test_Result = 1; } sock_str.close(); return 0; } #endif /* !ACE_LACKS_FORK || ACE_HAS_THREADS */ static void spawn (void) { // Acceptor ACE_SOCK_Acceptor peer_acceptor; // Create a server address. ACE_INET_Addr server_addr; // Bind listener to any port and then find out what the port was. if (peer_acceptor.open (ACE_Addr::sap_any) == -1 || peer_acceptor.get_local_addr (server_addr) == -1) ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n"), ACE_TEXT ("open"))); else { ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%P|%t) starting server at port %d\n"), server_addr.get_port_number ())); #if !defined (ACE_LACKS_FORK) switch (ACE_OS::fork ("child")) { case -1: ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n%a"), ACE_TEXT ("fork failed"), 1)); /* NOTREACHED */ case 0: client (&server_addr); ACE_OS::exit (0); /* NOTREACHED */ default: server (ACE_reinterpret_cast (void *, &peer_acceptor)); ACE_OS::wait (); } #elif defined (ACE_HAS_THREADS) if (ACE_Thread_Manager::instance ()->spawn (ACE_THR_FUNC (server), ACE_reinterpret_cast (void *, &peer_acceptor), THR_NEW_LWP | THR_DETACHED) == -1) ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n%a"), ACE_TEXT ("thread create failed"), 1)); if (ACE_Thread_Manager::instance ()->spawn (ACE_THR_FUNC (client), ACE_reinterpret_cast (void *, &server_addr), THR_NEW_LWP | THR_DETACHED) == -1) ACE_ERROR ((LM_ERROR, ACE_TEXT ("(%P|%t) %p\n%a"), ACE_TEXT ("thread create failed"), 1)); // Wait for the threads to exit. ACE_Thread_Manager::instance ()->wait (); #else ACE_ERROR ((LM_INFO, ACE_TEXT ("(%P|%t) ") ACE_TEXT ("only one thread may be run ") ACE_TEXT ("in a process on this platform\n"))); #endif /* ACE_HAS_THREADS */ peer_acceptor.close (); } } int run_main (int, ACE_TCHAR *[]) { ACE_START_TEST (ACE_TEXT ("SOCK_Send_Recv_Test")); spawn (); ACE_END_TEST; return Test_Result; }