/* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, you can obtain one at https://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ #if HAVE_CMOCKA #include /* IWYU pragma: keep */ #include #include #include #include #include #include #include #include #define UNIT_TESTING #include #include #include #include #include #include #include #include #include #include #include #include "uv_wrap.h" #define KEEP_BEFORE #include "../netmgr/netmgr-int.h" #include "../netmgr/udp.c" #include "../netmgr/uv-compat.c" #include "../netmgr/uv-compat.h" #include "isctest.h" #define MAX_NM 2 static isc_sockaddr_t udp_listen_addr; static uint64_t send_magic = 0; static uint64_t stop_magic = 0; static uv_buf_t send_msg = { .base = (char *)&stop_magic, .len = sizeof(stop_magic) }; static uv_buf_t stop_msg = { .base = (char *)&stop_magic, .len = sizeof(stop_magic) }; static atomic_uint_fast64_t nsends; static atomic_uint_fast64_t ssends; static atomic_uint_fast64_t sreads; static atomic_uint_fast64_t cconnects; static atomic_uint_fast64_t csends; static atomic_uint_fast64_t creads; static atomic_uint_fast64_t ctimeouts; static unsigned int workers = 3; #define NSENDS 100 #define NWRITES 10 /* * The UDP protocol doesn't protect against packet duplication, but instead of * inventing de-duplication, we just ignore the upper bound. */ #define CHECK_RANGE_FULL(v) \ { \ int __v = atomic_load(&v); \ assert_true(NSENDS *NWRITES * 20 / 100 <= __v); \ /* assert_true(__v <= NSENDS * NWRITES * 110 / 100); */ \ } #define CHECK_RANGE_HALF(v) \ { \ int __v = atomic_load(&v); \ assert_true(NSENDS *NWRITES * 10 / 100 <= __v); \ /* assert_true(__v <= NSENDS * NWRITES * 60 / 100); */ \ } /* Enable this to print values while running tests */ #undef PRINT_DEBUG #ifdef PRINT_DEBUG #define X(v) fprintf(stderr, #v " = %" PRIu64 "\n", atomic_load(&v)) #else #define X(v) #endif /* MOCK */ static int setup_ephemeral_port(isc_sockaddr_t *addr, sa_family_t family) { isc_result_t result; socklen_t addrlen = sizeof(*addr); int fd; int r; isc_sockaddr_fromin6(addr, &in6addr_loopback, 0); fd = socket(AF_INET6, family, 0); if (fd < 0) { perror("setup_ephemeral_port: socket()"); return (-1); } r = bind(fd, (const struct sockaddr *)&addr->type.sa, sizeof(addr->type.sin6)); if (r != 0) { perror("setup_ephemeral_port: bind()"); close(fd); return (r); } r = getsockname(fd, (struct sockaddr *)&addr->type.sa, &addrlen); if (r != 0) { perror("setup_ephemeral_port: getsockname()"); close(fd); return (r); } result = isc__nm_socket_reuse(fd); if (result != ISC_R_SUCCESS && result != ISC_R_NOTIMPLEMENTED) { fprintf(stderr, "setup_ephemeral_port: isc__nm_socket_reuse(): %s", isc_result_totext(result)); close(fd); return (-1); } result = isc__nm_socket_reuse_lb(fd); if (result != ISC_R_SUCCESS && result != ISC_R_NOTIMPLEMENTED) { fprintf(stderr, "setup_ephemeral_port: isc__nm_socket_reuse_lb(): %s", isc_result_totext(result)); close(fd); return (-1); } #if IPV6_RECVERR #define setsockopt_on(socket, level, name) \ setsockopt(socket, level, name, &(int){ 1 }, sizeof(int)) r = setsockopt_on(fd, IPPROTO_IPV6, IPV6_RECVERR); if (r != 0) { perror("setup_ephemeral_port"); close(fd); return (r); } #endif return (fd); } static int _setup(void **state) { UNUSED(state); /* workers = isc_os_ncpus(); */ if (isc_test_begin(NULL, true, workers) != ISC_R_SUCCESS) { return (-1); } signal(SIGPIPE, SIG_IGN); return (0); } static int _teardown(void **state) { UNUSED(state); isc_test_end(); return (0); } /* Generic */ static void noop_recv_cb(isc_nmhandle_t *handle, isc_result_t eresult, isc_region_t *region, void *cbarg) { UNUSED(handle); UNUSED(eresult); UNUSED(region); UNUSED(cbarg); } static void noop_connect_cb(isc_nmhandle_t *handle, isc_result_t result, void *cbarg) { UNUSED(handle); UNUSED(result); UNUSED(cbarg); } static int nm_setup(void **state) { size_t nworkers = ISC_MAX(ISC_MIN(workers, 32), 1); int udp_listen_sock = -1; isc_nm_t **nm = NULL; udp_listen_addr = (isc_sockaddr_t){ .length = 0 }; udp_listen_sock = setup_ephemeral_port(&udp_listen_addr, SOCK_DGRAM); if (udp_listen_sock < 0) { return (-1); } close(udp_listen_sock); udp_listen_sock = -1; /* silence scan-build */ UNUSED(udp_listen_sock); atomic_store(&nsends, NSENDS * NWRITES); atomic_store(&csends, 0); atomic_store(&creads, 0); atomic_store(&sreads, 0); atomic_store(&ssends, 0); atomic_store(&ctimeouts, 0); atomic_store(&cconnects, 0); isc_nonce_buf(&send_magic, sizeof(send_magic)); isc_nonce_buf(&stop_magic, sizeof(stop_magic)); if (send_magic == stop_magic) { return (-1); } nm = isc_mem_get(test_mctx, MAX_NM * sizeof(nm[0])); for (size_t i = 0; i < MAX_NM; i++) { nm[i] = isc_nm_start(test_mctx, nworkers); assert_non_null(nm[i]); } *state = nm; return (0); } static int nm_teardown(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; for (size_t i = 0; i < MAX_NM; i++) { isc_nm_destroy(&nm[i]); assert_null(nm[i]); } isc_mem_put(test_mctx, nm, MAX_NM * sizeof(nm[0])); return (0); } /* UDP */ static void udp_listen_send_cb(isc_nmhandle_t *handle, isc_result_t eresult, void *cbarg) { assert_non_null(handle); UNUSED(cbarg); if (eresult == ISC_R_SUCCESS) { atomic_fetch_add(&ssends, 1); } } static void udp_listen_recv_cb(isc_nmhandle_t *handle, isc_result_t eresult, isc_region_t *region, void *cbarg) { uint64_t magic = 0; assert_null(cbarg); if (eresult != ISC_R_SUCCESS) { return; } assert_int_equal(region->length, sizeof(send_magic)); atomic_fetch_add(&sreads, 1); memmove(&magic, region->base, sizeof(magic)); assert_true(magic == stop_magic || magic == send_magic); isc_nm_send(handle, region, udp_listen_send_cb, NULL); } static void mock_listenudp_uv_udp_open(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_udp_open, UV_ENOMEM); result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, noop_recv_cb, NULL, 0, &listen_sock); assert_int_not_equal(result, ISC_R_SUCCESS); assert_null(listen_sock); RESET_RETURN; } static void mock_listenudp_uv_udp_bind(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_udp_bind, UV_EADDRINUSE); result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, noop_recv_cb, NULL, 0, &listen_sock); assert_int_not_equal(result, ISC_R_SUCCESS); assert_null(listen_sock); RESET_RETURN; } static void mock_listenudp_uv_udp_recv_start(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_udp_recv_start, UV_EADDRINUSE); result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, noop_recv_cb, NULL, 0, &listen_sock); assert_int_not_equal(result, ISC_R_SUCCESS); assert_null(listen_sock); RESET_RETURN; } static void mock_udpconnect_uv_udp_open(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_udp_open, UV_ENOMEM); result = isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, noop_connect_cb, NULL, 1000, 0); assert_int_not_equal(result, ISC_R_SUCCESS); isc_nm_closedown(connect_nm); RESET_RETURN; } static void mock_udpconnect_uv_udp_bind(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_udp_bind, UV_ENOMEM); result = isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, noop_connect_cb, NULL, 1000, 0); assert_int_not_equal(result, ISC_R_SUCCESS); isc_nm_closedown(connect_nm); RESET_RETURN; } #if HAVE_UV_UDP_CONNECT static void mock_udpconnect_uv_udp_connect(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_udp_connect, UV_ENOMEM); result = isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, noop_connect_cb, NULL, 1000, 0); assert_int_not_equal(result, ISC_R_SUCCESS); isc_nm_closedown(connect_nm); RESET_RETURN; } #endif static void mock_udpconnect_uv_recv_buffer_size(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_recv_buffer_size, UV_ENOMEM); result = isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, noop_connect_cb, NULL, 1000, 0); assert_int_equal(result, ISC_R_SUCCESS); /* FIXME: should fail */ isc_nm_closedown(connect_nm); RESET_RETURN; } static void mock_udpconnect_uv_send_buffer_size(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); WILL_RETURN(uv_send_buffer_size, UV_ENOMEM); result = isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, noop_connect_cb, NULL, 1000, 0); assert_int_equal(result, ISC_R_SUCCESS); /* FIXME: should fail */ isc_nm_closedown(connect_nm); RESET_RETURN; } static void udp_noop(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, noop_recv_cb, NULL, 0, &listen_sock); assert_int_equal(result, ISC_R_SUCCESS); isc_nm_stoplistening(listen_sock); isc_nmsocket_close(&listen_sock); assert_null(listen_sock); (void)isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, noop_connect_cb, NULL, 1000, 0); isc_nm_closedown(connect_nm); assert_int_equal(0, atomic_load(&cconnects)); assert_int_equal(0, atomic_load(&csends)); assert_int_equal(0, atomic_load(&creads)); assert_int_equal(0, atomic_load(&ctimeouts)); assert_int_equal(0, atomic_load(&sreads)); assert_int_equal(0, atomic_load(&ssends)); } static void udp_connect_send_cb(isc_nmhandle_t *handle, isc_result_t eresult, void *cbarg); static void udp_connect_recv_cb(isc_nmhandle_t *handle, isc_result_t eresult, isc_region_t *region, void *cbarg); static void udp_connect_send_cb(isc_nmhandle_t *handle, isc_result_t eresult, void *cbarg) { assert_non_null(handle); UNUSED(eresult); UNUSED(cbarg); atomic_fetch_add(&csends, 1); } static void udp_connect_send(isc_nmhandle_t *handle, isc_region_t *region) { uint_fast64_t sends = atomic_load(&nsends); while (sends > 0) { /* Continue until we subtract or we are done */ if (atomic_compare_exchange_weak(&nsends, &sends, sends - 1)) { break; } } isc_nm_send(handle, region, udp_connect_send_cb, NULL); } static void udp_connect_recv_cb(isc_nmhandle_t *handle, isc_result_t eresult, isc_region_t *region, void *cbarg) { uint64_t magic = 0; UNUSED(cbarg); assert_non_null(handle); if (eresult != ISC_R_SUCCESS) { goto unref; } assert_int_equal(region->length, sizeof(magic)); atomic_fetch_add(&creads, 1); memmove(&magic, region->base, sizeof(magic)); assert_true(magic == stop_magic || magic == send_magic); if (magic == stop_magic) { goto unref; } if (isc_random_uniform(NWRITES) == 0) { udp_connect_send(handle, (isc_region_t *)&stop_msg); } else { udp_connect_send(handle, (isc_region_t *)&send_msg); } unref: isc_nmhandle_detach(&handle); } static void udp_connect_connect_cb(isc_nmhandle_t *handle, isc_result_t eresult, void *cbarg) { isc_nmhandle_t *readhandle = NULL; UNUSED(cbarg); if (eresult != ISC_R_SUCCESS) { uint_fast64_t sends = atomic_load(&nsends); /* We failed to connect; try again */ while (sends > 0) { /* Continue until we subtract or we are done */ if (atomic_compare_exchange_weak(&nsends, &sends, sends - 1)) { break; } } return; } atomic_fetch_add(&cconnects, 1); isc_nmhandle_attach(handle, &readhandle); isc_nm_read(handle, udp_connect_recv_cb, NULL); udp_connect_send(handle, (isc_region_t *)&send_msg); } static isc_threadresult_t udp_connect_thread(isc_threadarg_t arg) { isc_nm_t *connect_nm = (isc_nm_t *)arg; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); while (atomic_load(&nsends) > 0) { (void)isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, udp_connect_connect_cb, NULL, 1000, 0); } return ((isc_threadresult_t)0); } static void udp_noresponse(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; isc_sockaddr_t udp_connect_addr; udp_connect_addr = (isc_sockaddr_t){ .length = 0 }; isc_sockaddr_fromin6(&udp_connect_addr, &in6addr_loopback, 0); result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, noop_recv_cb, NULL, 0, &listen_sock); assert_int_equal(result, ISC_R_SUCCESS); (void)isc_nm_udpconnect(connect_nm, (isc_nmiface_t *)&udp_connect_addr, (isc_nmiface_t *)&udp_listen_addr, udp_connect_connect_cb, NULL, 1000, 0); isc_nm_stoplistening(listen_sock); isc_nmsocket_close(&listen_sock); assert_null(listen_sock); isc_nm_closedown(connect_nm); while (atomic_load(&cconnects) != 1) { isc_thread_yield(); } X(cconnects); X(csends); X(creads); X(ctimeouts); X(sreads); X(ssends); assert_int_equal(1, atomic_load(&cconnects)); assert_true(atomic_load(&csends) <= 1); assert_int_equal(0, atomic_load(&creads)); assert_int_equal(0, atomic_load(&ctimeouts)); assert_int_equal(0, atomic_load(&sreads)); assert_int_equal(0, atomic_load(&ssends)); } static void udp_recv_send(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; size_t nthreads = ISC_MAX(ISC_MIN(workers, 32), 1); isc_thread_t threads[32] = { 0 }; result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, udp_listen_recv_cb, NULL, 0, &listen_sock); assert_int_equal(result, ISC_R_SUCCESS); for (size_t i = 0; i < nthreads; i++) { isc_thread_create(udp_connect_thread, connect_nm, &threads[i]); } for (size_t i = 0; i < nthreads; i++) { isc_thread_join(threads[i], NULL); } isc_nm_stoplistening(listen_sock); isc_nmsocket_close(&listen_sock); assert_null(listen_sock); isc_nm_closedown(connect_nm); X(cconnects); X(csends); X(creads); X(ctimeouts); X(sreads); X(ssends); assert_true(atomic_load(&cconnects) >= (NSENDS - 1) * NWRITES); CHECK_RANGE_FULL(csends); CHECK_RANGE_FULL(creads); CHECK_RANGE_FULL(sreads); CHECK_RANGE_FULL(ssends); } static void udp_recv_half_send(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; size_t nthreads = ISC_MAX(ISC_MIN(workers, 32), 1); isc_thread_t threads[32] = { 0 }; result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, udp_listen_recv_cb, NULL, 0, &listen_sock); assert_int_equal(result, ISC_R_SUCCESS); for (size_t i = 0; i < nthreads; i++) { isc_thread_create(udp_connect_thread, connect_nm, &threads[i]); } while (atomic_load(&nsends) >= (NSENDS * NWRITES) / 2) { isc_thread_yield(); } isc_nm_closedown(connect_nm); for (size_t i = 0; i < nthreads; i++) { isc_thread_join(threads[i], NULL); } isc_nm_stoplistening(listen_sock); isc_nmsocket_close(&listen_sock); assert_null(listen_sock); X(cconnects); X(csends); X(creads); X(ctimeouts); X(sreads); X(ssends); assert_true(atomic_load(&cconnects) >= (NSENDS - 1) * NWRITES); CHECK_RANGE_FULL(csends); CHECK_RANGE_HALF(creads); CHECK_RANGE_HALF(sreads); CHECK_RANGE_HALF(ssends); } static void udp_half_recv_send(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; size_t nthreads = ISC_MAX(ISC_MIN(workers, 32), 1); isc_thread_t threads[32] = { 0 }; result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, udp_listen_recv_cb, NULL, 0, &listen_sock); assert_int_equal(result, ISC_R_SUCCESS); for (size_t i = 0; i < nthreads; i++) { isc_thread_create(udp_connect_thread, connect_nm, &threads[i]); } while (atomic_load(&nsends) >= (NSENDS * NWRITES) / 2) { isc_thread_yield(); } isc_nm_stoplistening(listen_sock); isc_nmsocket_close(&listen_sock); assert_null(listen_sock); for (size_t i = 0; i < nthreads; i++) { isc_thread_join(threads[i], NULL); } isc_nm_closedown(connect_nm); X(cconnects); X(csends); X(creads); X(ctimeouts); X(sreads); X(ssends); assert_true(atomic_load(&cconnects) >= (NSENDS - 1) * NWRITES); CHECK_RANGE_FULL(csends); CHECK_RANGE_HALF(creads); CHECK_RANGE_HALF(sreads); CHECK_RANGE_HALF(ssends); } static void udp_half_recv_half_send(void **state) { isc_nm_t **nm = (isc_nm_t **)*state; isc_nm_t *listen_nm = nm[0]; isc_nm_t *connect_nm = nm[1]; isc_result_t result = ISC_R_SUCCESS; isc_nmsocket_t *listen_sock = NULL; size_t nthreads = ISC_MAX(ISC_MIN(workers, 32), 1); isc_thread_t threads[32] = { 0 }; result = isc_nm_listenudp(listen_nm, (isc_nmiface_t *)&udp_listen_addr, udp_listen_recv_cb, NULL, 0, &listen_sock); assert_int_equal(result, ISC_R_SUCCESS); for (size_t i = 0; i < nthreads; i++) { isc_thread_create(udp_connect_thread, connect_nm, &threads[i]); } while (atomic_load(&nsends) >= (NSENDS * NWRITES) / 2) { isc_thread_yield(); } isc_nm_closedown(connect_nm); isc_nm_stoplistening(listen_sock); isc_nmsocket_close(&listen_sock); assert_null(listen_sock); for (size_t i = 0; i < nthreads; i++) { isc_thread_join(threads[i], NULL); } X(cconnects); X(csends); X(creads); X(ctimeouts); X(sreads); X(ssends); assert_true(atomic_load(&cconnects) >= (NSENDS - 1) * NWRITES); CHECK_RANGE_FULL(csends); CHECK_RANGE_HALF(creads); CHECK_RANGE_HALF(sreads); CHECK_RANGE_HALF(ssends); } int main(void) { const struct CMUnitTest tests[] = { cmocka_unit_test_setup_teardown(mock_listenudp_uv_udp_open, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(mock_listenudp_uv_udp_bind, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown( mock_listenudp_uv_udp_recv_start, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(mock_udpconnect_uv_udp_open, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(mock_udpconnect_uv_udp_bind, nm_setup, nm_teardown), #if HAVE_UV_UDP_CONNECT cmocka_unit_test_setup_teardown(mock_udpconnect_uv_udp_connect, nm_setup, nm_teardown), #endif cmocka_unit_test_setup_teardown( mock_udpconnect_uv_recv_buffer_size, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown( mock_udpconnect_uv_send_buffer_size, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(udp_noop, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(udp_noresponse, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(udp_recv_send, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(udp_recv_half_send, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(udp_half_recv_send, nm_setup, nm_teardown), cmocka_unit_test_setup_teardown(udp_half_recv_half_send, nm_setup, nm_teardown), }; return (cmocka_run_group_tests(tests, _setup, _teardown)); } #else /* HAVE_CMOCKA */ #include int main(void) { printf("1..0 # Skipped: cmocka not available\n"); return (SKIPPED_TEST_EXIT_CODE); } #endif /* if HAVE_CMOCKA */