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Home --> Documentations --> PJLIB Reference Test: I/O Queue (UDP)This file provides implementation to test the functionality of the I/O queue when UDP socket is used. This file is pjlib-test/ioq_udp.c /* $Id: ioq_udp.c 3553 2011-05-05 06:14:19Z nanang $ */ /* * Copyright (C) 2008-2011 Teluu Inc. (http://www.teluu.com) * Copyright (C) 2003-2008 Benny Prijono <benny@prijono.org> * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "test.h" #if INCLUDE_UDP_IOQUEUE_TEST #include <pjlib.h> #include <pj/compat/socket.h> #define THIS_FILE "test_udp" #define PORT 51233 #define LOOP 2 #define BUF_MIN_SIZE 32 #define BUF_MAX_SIZE 2048 #define SOCK_INACTIVE_MIN (1) #define SOCK_INACTIVE_MAX (PJ_IOQUEUE_MAX_HANDLES - 2) #define POOL_SIZE (2*BUF_MAX_SIZE + SOCK_INACTIVE_MAX*128 + 2048) #undef TRACE_ #define TRACE_(msg) PJ_LOG(3,(THIS_FILE,"....." msg)) #if 0 # define TRACE__(args) PJ_LOG(3,args) #else # define TRACE__(args) #endif static pj_ssize_t callback_read_size, callback_write_size, callback_accept_status, callback_connect_status; static pj_ioqueue_key_t *callback_read_key, *callback_write_key, *callback_accept_key, *callback_connect_key; static pj_ioqueue_op_key_t *callback_read_op, *callback_write_op, *callback_accept_op; static void on_ioqueue_read(pj_ioqueue_key_t *key, pj_ioqueue_op_key_t *op_key, pj_ssize_t bytes_read) { callback_read_key = key; callback_read_op = op_key; callback_read_size = bytes_read; TRACE__((THIS_FILE, " callback_read_key = %p, bytes=%d", key, bytes_read)); } static void on_ioqueue_write(pj_ioqueue_key_t *key, pj_ioqueue_op_key_t *op_key, pj_ssize_t bytes_written) { callback_write_key = key; callback_write_op = op_key; callback_write_size = bytes_written; } static void on_ioqueue_accept(pj_ioqueue_key_t *key, pj_ioqueue_op_key_t *op_key, pj_sock_t sock, int status) { PJ_UNUSED_ARG(sock); callback_accept_key = key; callback_accept_op = op_key; callback_accept_status = status; } static void on_ioqueue_connect(pj_ioqueue_key_t *key, int status) { callback_connect_key = key; callback_connect_status = status; } static pj_ioqueue_callback test_cb = { &on_ioqueue_read, &on_ioqueue_write, &on_ioqueue_accept, &on_ioqueue_connect, }; #ifdef PJ_WIN32 # define S_ADDR S_un.S_addr #else # define S_ADDR s_addr #endif /* * compliance_test() * To test that the basic IOQueue functionality works. It will just exchange * data between two sockets. */ static int compliance_test(pj_bool_t allow_concur) { pj_sock_t ssock=-1, csock=-1; pj_sockaddr_in addr, dst_addr; int addrlen; pj_pool_t *pool = NULL; char *send_buf, *recv_buf; pj_ioqueue_t *ioque = NULL; pj_ioqueue_key_t *skey = NULL, *ckey = NULL; pj_ioqueue_op_key_t read_op, write_op; int bufsize = BUF_MIN_SIZE; pj_ssize_t bytes, status = -1; pj_str_t temp; pj_bool_t send_pending, recv_pending; pj_status_t rc; pj_set_os_error(PJ_SUCCESS); // Create pool. pool = pj_pool_create(mem, NULL, POOL_SIZE, 4000, NULL); // Allocate buffers for send and receive. send_buf = (char*)pj_pool_alloc(pool, bufsize); recv_buf = (char*)pj_pool_alloc(pool, bufsize); // Allocate sockets for sending and receiving. TRACE_("creating sockets..."); rc = pj_sock_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, &ssock); if (rc==PJ_SUCCESS) rc = pj_sock_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, &csock); else csock = PJ_INVALID_SOCKET; if (rc != PJ_SUCCESS) { app_perror("...ERROR in pj_sock_socket()", rc); status=-1; goto on_error; } // Bind server socket. TRACE_("bind socket..."); pj_bzero(&addr, sizeof(addr)); addr.sin_family = pj_AF_INET(); addr.sin_port = pj_htons(PORT); if (pj_sock_bind(ssock, &addr, sizeof(addr))) { status=-10; goto on_error; } // Create I/O Queue. TRACE_("create ioqueue..."); rc = pj_ioqueue_create(pool, PJ_IOQUEUE_MAX_HANDLES, &ioque); if (rc != PJ_SUCCESS) { status=-20; goto on_error; } // Set concurrency TRACE_("set concurrency..."); rc = pj_ioqueue_set_default_concurrency(ioque, allow_concur); if (rc != PJ_SUCCESS) { status=-21; goto on_error; } // Register server and client socket. // We put this after inactivity socket, hopefully this can represent the // worst waiting time. TRACE_("registering first sockets..."); rc = pj_ioqueue_register_sock(pool, ioque, ssock, NULL, &test_cb, &skey); if (rc != PJ_SUCCESS) { app_perror("...error(10): ioqueue_register error", rc); status=-25; goto on_error; } TRACE_("registering second sockets..."); rc = pj_ioqueue_register_sock( pool, ioque, csock, NULL, &test_cb, &ckey); if (rc != PJ_SUCCESS) { app_perror("...error(11): ioqueue_register error", rc); status=-26; goto on_error; } // Randomize send_buf. pj_create_random_string(send_buf, bufsize); // Register reading from ioqueue. TRACE_("start recvfrom..."); pj_bzero(&addr, sizeof(addr)); addrlen = sizeof(addr); bytes = bufsize; rc = pj_ioqueue_recvfrom(skey, &read_op, recv_buf, &bytes, 0, &addr, &addrlen); if (rc != PJ_SUCCESS && rc != PJ_EPENDING) { app_perror("...error: pj_ioqueue_recvfrom", rc); status=-28; goto on_error; } else if (rc == PJ_EPENDING) { recv_pending = 1; PJ_LOG(3, (THIS_FILE, "......ok: recvfrom returned pending")); } else { PJ_LOG(3, (THIS_FILE, "......error: recvfrom returned immediate ok!")); status=-29; goto on_error; } // Set destination address to send the packet. TRACE_("set destination address..."); temp = pj_str("127.0.0.1"); if ((rc=pj_sockaddr_in_init(&dst_addr, &temp, PORT)) != 0) { app_perror("...error: unable to resolve 127.0.0.1", rc); status=-290; goto on_error; } // Write must return the number of bytes. TRACE_("start sendto..."); bytes = bufsize; rc = pj_ioqueue_sendto(ckey, &write_op, send_buf, &bytes, 0, &dst_addr, sizeof(dst_addr)); if (rc != PJ_SUCCESS && rc != PJ_EPENDING) { app_perror("...error: pj_ioqueue_sendto", rc); status=-30; goto on_error; } else if (rc == PJ_EPENDING) { send_pending = 1; PJ_LOG(3, (THIS_FILE, "......ok: sendto returned pending")); } else { send_pending = 0; PJ_LOG(3, (THIS_FILE, "......ok: sendto returned immediate success")); } // reset callback variables. callback_read_size = callback_write_size = 0; callback_accept_status = callback_connect_status = -2; callback_read_key = callback_write_key = callback_accept_key = callback_connect_key = NULL; callback_read_op = callback_write_op = NULL; // Poll if pending. while (send_pending || recv_pending) { int rc; pj_time_val timeout = { 5, 0 }; TRACE_("poll..."); #ifdef PJ_SYMBIAN rc = pj_symbianos_poll(-1, 5000); #else rc = pj_ioqueue_poll(ioque, &timeout); #endif if (rc == 0) { PJ_LOG(1,(THIS_FILE, "...ERROR: timed out...")); status=-45; goto on_error; } else if (rc < 0) { app_perror("...ERROR in ioqueue_poll()", -rc); status=-50; goto on_error; } if (callback_read_key != NULL) { if (callback_read_size != bufsize) { status=-61; goto on_error; } if (callback_read_key != skey) { status=-65; goto on_error; } if (callback_read_op != &read_op) { status=-66; goto on_error; } if (pj_memcmp(send_buf, recv_buf, bufsize) != 0) { status=-67; goto on_error; } if (addrlen != sizeof(pj_sockaddr_in)) { status=-68; goto on_error; } if (addr.sin_family != pj_AF_INET()) { status=-69; goto on_error; } recv_pending = 0; } if (callback_write_key != NULL) { if (callback_write_size != bufsize) { status=-73; goto on_error; } if (callback_write_key != ckey) { status=-75; goto on_error; } if (callback_write_op != &write_op) { status=-76; goto on_error; } send_pending = 0; } } // Success status = 0; on_error: if (skey) pj_ioqueue_unregister(skey); else if (ssock != -1) pj_sock_close(ssock); if (ckey) pj_ioqueue_unregister(ckey); else if (csock != -1) pj_sock_close(csock); if (ioque != NULL) pj_ioqueue_destroy(ioque); pj_pool_release(pool); return status; } static void on_read_complete(pj_ioqueue_key_t *key, pj_ioqueue_op_key_t *op_key, pj_ssize_t bytes_read) { unsigned *p_packet_cnt = (unsigned*) pj_ioqueue_get_user_data(key); PJ_UNUSED_ARG(op_key); PJ_UNUSED_ARG(bytes_read); (*p_packet_cnt)++; } /* * unregister_test() * Check if callback is still called after socket has been unregistered or * closed. */ static int unregister_test(pj_bool_t allow_concur) { enum { RPORT = 50000, SPORT = 50001 }; pj_pool_t *pool; pj_ioqueue_t *ioqueue; pj_sock_t ssock; pj_sock_t rsock; int addrlen; pj_sockaddr_in addr; pj_ioqueue_key_t *key; pj_ioqueue_op_key_t opkey; pj_ioqueue_callback cb; unsigned packet_cnt; char sendbuf[10], recvbuf[10]; pj_ssize_t bytes; pj_time_val timeout; pj_status_t status; pool = pj_pool_create(mem, "test", 4000, 4000, NULL); if (!pool) { app_perror("Unable to create pool", PJ_ENOMEM); return -100; } status = pj_ioqueue_create(pool, 16, &ioqueue); if (status != PJ_SUCCESS) { app_perror("Error creating ioqueue", status); return -110; } // Set concurrency TRACE_("set concurrency..."); status = pj_ioqueue_set_default_concurrency(ioqueue, allow_concur); if (status != PJ_SUCCESS) { return -112; } /* Create sender socket */ status = app_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, SPORT, &ssock); if (status != PJ_SUCCESS) { app_perror("Error initializing socket", status); return -120; } /* Create receiver socket. */ status = app_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, RPORT, &rsock); if (status != PJ_SUCCESS) { app_perror("Error initializing socket", status); return -130; } /* Register rsock to ioqueue. */ pj_bzero(&cb, sizeof(cb)); cb.on_read_complete = &on_read_complete; packet_cnt = 0; status = pj_ioqueue_register_sock(pool, ioqueue, rsock, &packet_cnt, &cb, &key); if (status != PJ_SUCCESS) { app_perror("Error registering to ioqueue", status); return -140; } /* Init operation key. */ pj_ioqueue_op_key_init(&opkey, sizeof(opkey)); /* Start reading. */ bytes = sizeof(recvbuf); status = pj_ioqueue_recv( key, &opkey, recvbuf, &bytes, 0); if (status != PJ_EPENDING) { app_perror("Expecting PJ_EPENDING, but got this", status); return -150; } /* Init destination address. */ addrlen = sizeof(addr); status = pj_sock_getsockname(rsock, &addr, &addrlen); if (status != PJ_SUCCESS) { app_perror("getsockname error", status); return -160; } /* Override address with 127.0.0.1, since getsockname will return * zero in the address field. */ addr.sin_addr = pj_inet_addr2("127.0.0.1"); /* Init buffer to send */ pj_ansi_strcpy(sendbuf, "Hello0123"); /* Send one packet. */ bytes = sizeof(sendbuf); status = pj_sock_sendto(ssock, sendbuf, &bytes, 0, &addr, sizeof(addr)); if (status != PJ_SUCCESS) { app_perror("sendto error", status); return -170; } /* Check if packet is received. */ timeout.sec = 1; timeout.msec = 0; #ifdef PJ_SYMBIAN pj_symbianos_poll(-1, 1000); #else pj_ioqueue_poll(ioqueue, &timeout); #endif if (packet_cnt != 1) { return -180; } /* Just to make sure things are settled.. */ pj_thread_sleep(100); /* Start reading again. */ bytes = sizeof(recvbuf); status = pj_ioqueue_recv( key, &opkey, recvbuf, &bytes, 0); if (status != PJ_EPENDING) { app_perror("Expecting PJ_EPENDING, but got this", status); return -190; } /* Reset packet counter */ packet_cnt = 0; /* Send one packet. */ bytes = sizeof(sendbuf); status = pj_sock_sendto(ssock, sendbuf, &bytes, 0, &addr, sizeof(addr)); if (status != PJ_SUCCESS) { app_perror("sendto error", status); return -200; } /* Now unregister and close socket. */ pj_ioqueue_unregister(key); /* Poll ioqueue. */ #ifdef PJ_SYMBIAN pj_symbianos_poll(-1, 1000); #else timeout.sec = 1; timeout.msec = 0; pj_ioqueue_poll(ioqueue, &timeout); #endif /* Must NOT receive any packets after socket is closed! */ if (packet_cnt > 0) { PJ_LOG(3,(THIS_FILE, "....errror: not expecting to receive packet " "after socket has been closed")); return -210; } /* Success */ pj_sock_close(ssock); pj_ioqueue_destroy(ioqueue); pj_pool_release(pool); return 0; } /* * Testing with many handles. * This will just test registering PJ_IOQUEUE_MAX_HANDLES count * of sockets to the ioqueue. */ static int many_handles_test(pj_bool_t allow_concur) { enum { MAX = PJ_IOQUEUE_MAX_HANDLES }; pj_pool_t *pool; pj_ioqueue_t *ioqueue; pj_sock_t *sock; pj_ioqueue_key_t **key; pj_status_t rc; int count, i; /* must be signed */ PJ_LOG(3,(THIS_FILE,"...testing with so many handles")); pool = pj_pool_create(mem, NULL, 4000, 4000, NULL); if (!pool) return PJ_ENOMEM; key = (pj_ioqueue_key_t**) pj_pool_alloc(pool, MAX*sizeof(pj_ioqueue_key_t*)); sock = (pj_sock_t*) pj_pool_alloc(pool, MAX*sizeof(pj_sock_t)); /* Create IOQueue */ rc = pj_ioqueue_create(pool, MAX, &ioqueue); if (rc != PJ_SUCCESS || ioqueue == NULL) { app_perror("...error in pj_ioqueue_create", rc); return -10; } // Set concurrency rc = pj_ioqueue_set_default_concurrency(ioqueue, allow_concur); if (rc != PJ_SUCCESS) { return -11; } /* Register as many sockets. */ for (count=0; count<MAX; ++count) { sock[count] = PJ_INVALID_SOCKET; rc = pj_sock_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, &sock[count]); if (rc != PJ_SUCCESS || sock[count] == PJ_INVALID_SOCKET) { PJ_LOG(3,(THIS_FILE, "....unable to create %d-th socket, rc=%d", count, rc)); break; } key[count] = NULL; rc = pj_ioqueue_register_sock(pool, ioqueue, sock[count], NULL, &test_cb, &key[count]); if (rc != PJ_SUCCESS || key[count] == NULL) { PJ_LOG(3,(THIS_FILE, "....unable to register %d-th socket, rc=%d", count, rc)); return -30; } } /* Test complete. */ /* Now deregister and close all handles. */ /* NOTE for RTEMS: * It seems that the order of close(sock) is pretty important here. * If we close the sockets with the same order as when they were created, * RTEMS doesn't seem to reuse the sockets, thus next socket created * will have descriptor higher than the last socket created. * If we close the sockets in the reverse order, then the descriptor will * get reused. * This used to cause problem with select ioqueue, since the ioqueue * always gives FD_SETSIZE for the first select() argument. This ioqueue * behavior can be changed with setting PJ_SELECT_NEEDS_NFDS macro. */ for (i=count-1; i>=0; --i) { rc = pj_ioqueue_unregister(key[i]); if (rc != PJ_SUCCESS) { app_perror("...error in pj_ioqueue_unregister", rc); } } rc = pj_ioqueue_destroy(ioqueue); if (rc != PJ_SUCCESS) { app_perror("...error in pj_ioqueue_destroy", rc); } pj_pool_release(pool); PJ_LOG(3,(THIS_FILE,"....many_handles_test() ok")); return 0; } /* * Multi-operation test. */ /* * Benchmarking IOQueue */ static int bench_test(pj_bool_t allow_concur, int bufsize, int inactive_sock_count) { pj_sock_t ssock=-1, csock=-1; pj_sockaddr_in addr; pj_pool_t *pool = NULL; pj_sock_t *inactive_sock=NULL; pj_ioqueue_op_key_t *inactive_read_op; char *send_buf, *recv_buf; pj_ioqueue_t *ioque = NULL; pj_ioqueue_key_t *skey, *ckey, *keys[SOCK_INACTIVE_MAX+2]; pj_timestamp t1, t2, t_elapsed; int rc=0, i; /* i must be signed */ pj_str_t temp; char errbuf[PJ_ERR_MSG_SIZE]; TRACE__((THIS_FILE, " bench test %d", inactive_sock_count)); // Create pool. pool = pj_pool_create(mem, NULL, POOL_SIZE, 4000, NULL); // Allocate buffers for send and receive. send_buf = (char*)pj_pool_alloc(pool, bufsize); recv_buf = (char*)pj_pool_alloc(pool, bufsize); // Allocate sockets for sending and receiving. rc = pj_sock_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, &ssock); if (rc == PJ_SUCCESS) { rc = pj_sock_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, &csock); } else csock = PJ_INVALID_SOCKET; if (rc != PJ_SUCCESS) { app_perror("...error: pj_sock_socket()", rc); goto on_error; } // Bind server socket. pj_bzero(&addr, sizeof(addr)); addr.sin_family = pj_AF_INET(); addr.sin_port = pj_htons(PORT); if (pj_sock_bind(ssock, &addr, sizeof(addr))) goto on_error; pj_assert(inactive_sock_count+2 <= PJ_IOQUEUE_MAX_HANDLES); // Create I/O Queue. rc = pj_ioqueue_create(pool, PJ_IOQUEUE_MAX_HANDLES, &ioque); if (rc != PJ_SUCCESS) { app_perror("...error: pj_ioqueue_create()", rc); goto on_error; } // Set concurrency rc = pj_ioqueue_set_default_concurrency(ioque, allow_concur); if (rc != PJ_SUCCESS) { app_perror("...error: pj_ioqueue_set_default_concurrency()", rc); goto on_error; } // Allocate inactive sockets, and bind them to some arbitrary address. // Then register them to the I/O queue, and start a read operation. inactive_sock = (pj_sock_t*)pj_pool_alloc(pool, inactive_sock_count*sizeof(pj_sock_t)); inactive_read_op = (pj_ioqueue_op_key_t*)pj_pool_alloc(pool, inactive_sock_count*sizeof(pj_ioqueue_op_key_t)); pj_bzero(&addr, sizeof(addr)); addr.sin_family = pj_AF_INET(); for (i=0; i<inactive_sock_count; ++i) { pj_ssize_t bytes; rc = pj_sock_socket(pj_AF_INET(), pj_SOCK_DGRAM(), 0, &inactive_sock[i]); if (rc != PJ_SUCCESS || inactive_sock[i] < 0) { app_perror("...error: pj_sock_socket()", rc); goto on_error; } if ((rc=pj_sock_bind(inactive_sock[i], &addr, sizeof(addr))) != 0) { pj_sock_close(inactive_sock[i]); inactive_sock[i] = PJ_INVALID_SOCKET; app_perror("...error: pj_sock_bind()", rc); goto on_error; } rc = pj_ioqueue_register_sock(pool, ioque, inactive_sock[i], NULL, &test_cb, &keys[i]); if (rc != PJ_SUCCESS) { pj_sock_close(inactive_sock[i]); inactive_sock[i] = PJ_INVALID_SOCKET; app_perror("...error(1): pj_ioqueue_register_sock()", rc); PJ_LOG(3,(THIS_FILE, "....i=%d", i)); goto on_error; } bytes = bufsize; rc = pj_ioqueue_recv(keys[i], &inactive_read_op[i], recv_buf, &bytes, 0); if (rc != PJ_EPENDING) { pj_sock_close(inactive_sock[i]); inactive_sock[i] = PJ_INVALID_SOCKET; app_perror("...error: pj_ioqueue_read()", rc); goto on_error; } } // Register server and client socket. // We put this after inactivity socket, hopefully this can represent the // worst waiting time. rc = pj_ioqueue_register_sock(pool, ioque, ssock, NULL, &test_cb, &skey); if (rc != PJ_SUCCESS) { app_perror("...error(2): pj_ioqueue_register_sock()", rc); goto on_error; } rc = pj_ioqueue_register_sock(pool, ioque, csock, NULL, &test_cb, &ckey); if (rc != PJ_SUCCESS) { app_perror("...error(3): pj_ioqueue_register_sock()", rc); goto on_error; } // Set destination address to send the packet. pj_sockaddr_in_init(&addr, pj_cstr(&temp, "127.0.0.1"), PORT); // Test loop. t_elapsed.u64 = 0; for (i=0; i<LOOP; ++i) { pj_ssize_t bytes; pj_ioqueue_op_key_t read_op, write_op; // Randomize send buffer. pj_create_random_string(send_buf, bufsize); // Start reading on the server side. bytes = bufsize; rc = pj_ioqueue_recv(skey, &read_op, recv_buf, &bytes, 0); if (rc != PJ_EPENDING) { app_perror("...error: pj_ioqueue_read()", rc); break; } // Starts send on the client side. bytes = bufsize; rc = pj_ioqueue_sendto(ckey, &write_op, send_buf, &bytes, 0, &addr, sizeof(addr)); if (rc != PJ_SUCCESS && rc != PJ_EPENDING) { app_perror("...error: pj_ioqueue_write()", rc); break; } if (rc == PJ_SUCCESS) { if (bytes < 0) { app_perror("...error: pj_ioqueue_sendto()", -bytes); break; } } // Begin time. pj_get_timestamp(&t1); // Poll the queue until we've got completion event in the server side. callback_read_key = NULL; callback_read_size = 0; TRACE__((THIS_FILE, " waiting for key = %p", skey)); do { pj_time_val timeout = { 1, 0 }; #ifdef PJ_SYMBIAN rc = pj_symbianos_poll(-1, 1000); #else rc = pj_ioqueue_poll(ioque, &timeout); #endif TRACE__((THIS_FILE, " poll rc=%d", rc)); } while (rc >= 0 && callback_read_key != skey); // End time. pj_get_timestamp(&t2); t_elapsed.u64 += (t2.u64 - t1.u64); if (rc < 0) { app_perror(" error: pj_ioqueue_poll", -rc); break; } // Compare recv buffer with send buffer. if (callback_read_size != bufsize || pj_memcmp(send_buf, recv_buf, bufsize)) { rc = -10; PJ_LOG(3,(THIS_FILE, " error: size/buffer mismatch")); break; } // Poll until all events are exhausted, before we start the next loop. do { pj_time_val timeout = { 0, 10 }; #ifdef PJ_SYMBIAN rc = pj_symbianos_poll(-1, 100); #else rc = pj_ioqueue_poll(ioque, &timeout); #endif } while (rc>0); rc = 0; } // Print results if (rc == 0) { pj_timestamp tzero; pj_uint32_t usec_delay; tzero.u32.hi = tzero.u32.lo = 0; usec_delay = pj_elapsed_usec( &tzero, &t_elapsed); PJ_LOG(3, (THIS_FILE, "...%10d %15d % 9d", bufsize, inactive_sock_count, usec_delay)); } else { PJ_LOG(2, (THIS_FILE, "...ERROR rc=%d (buf:%d, fds:%d)", rc, bufsize, inactive_sock_count+2)); } // Cleaning up. for (i=inactive_sock_count-1; i>=0; --i) { pj_ioqueue_unregister(keys[i]); } pj_ioqueue_unregister(skey); pj_ioqueue_unregister(ckey); pj_ioqueue_destroy(ioque); pj_pool_release( pool); return rc; on_error: PJ_LOG(1,(THIS_FILE, "...ERROR: %s", pj_strerror(pj_get_netos_error(), errbuf, sizeof(errbuf)))); if (ssock) pj_sock_close(ssock); if (csock) pj_sock_close(csock); for (i=0; i<inactive_sock_count && inactive_sock && inactive_sock[i]!=PJ_INVALID_SOCKET; ++i) { pj_sock_close(inactive_sock[i]); } if (ioque != NULL) pj_ioqueue_destroy(ioque); pj_pool_release( pool); return -1; } static int udp_ioqueue_test_imp(pj_bool_t allow_concur) { int status; int bufsize, sock_count; PJ_LOG(3,(THIS_FILE, "..testing with concurency=%d", allow_concur)); //goto pass1; PJ_LOG(3, (THIS_FILE, "...compliance test (%s)", pj_ioqueue_name())); if ((status=compliance_test(allow_concur)) != 0) { return status; } PJ_LOG(3, (THIS_FILE, "....compliance test ok")); PJ_LOG(3, (THIS_FILE, "...unregister test (%s)", pj_ioqueue_name())); if ((status=unregister_test(allow_concur)) != 0) { return status; } PJ_LOG(3, (THIS_FILE, "....unregister test ok")); if ((status=many_handles_test(allow_concur)) != 0) { return status; } //return 0; PJ_LOG(4, (THIS_FILE, "...benchmarking different buffer size:")); PJ_LOG(4, (THIS_FILE, "... note: buf=bytes sent, fds=# of fds, " "elapsed=in timer ticks")); //pass1: PJ_LOG(3, (THIS_FILE, "...Benchmarking poll times for %s:", pj_ioqueue_name())); PJ_LOG(3, (THIS_FILE, "...=====================================")); PJ_LOG(3, (THIS_FILE, "...Buf.size #inactive-socks Time/poll")); PJ_LOG(3, (THIS_FILE, "... (bytes) (nanosec)")); PJ_LOG(3, (THIS_FILE, "...=====================================")); //goto pass2; for (bufsize=BUF_MIN_SIZE; bufsize <= BUF_MAX_SIZE; bufsize *= 2) { if ((status=bench_test(allow_concur, bufsize, SOCK_INACTIVE_MIN)) != 0) return status; } //pass2: bufsize = 512; for (sock_count=SOCK_INACTIVE_MIN+2; sock_count<=SOCK_INACTIVE_MAX+2; sock_count *= 2) { //PJ_LOG(3,(THIS_FILE, "...testing with %d fds", sock_count)); if ((status=bench_test(allow_concur, bufsize, sock_count-2)) != 0) return status; } return 0; } int udp_ioqueue_test() { int rc; rc = udp_ioqueue_test_imp(PJ_TRUE); if (rc != 0) return rc; rc = udp_ioqueue_test_imp(PJ_FALSE); if (rc != 0) return rc; return 0; } #else /* To prevent warning about "translation unit is empty" * when this test is disabled. */ int dummy_uiq_udp; #endif /* INCLUDE_UDP_IOQUEUE_TEST */
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