// SPDX-License-Identifier: GPL-2.0 /* Copyright (c) 2018 Facebook */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bpf_rlimit.h" #include "bpf_util.h" #include "test_progs.h" #include "test_select_reuseport_common.h" #define MAX_TEST_NAME 80 #define MIN_TCPHDR_LEN 20 #define UDPHDR_LEN 8 #define TCP_SYNCOOKIE_SYSCTL "/proc/sys/net/ipv4/tcp_syncookies" #define TCP_FO_SYSCTL "/proc/sys/net/ipv4/tcp_fastopen" #define REUSEPORT_ARRAY_SIZE 32 static int result_map, tmp_index_ovr_map, linum_map, data_check_map; static __u32 expected_results[NR_RESULTS]; static int sk_fds[REUSEPORT_ARRAY_SIZE]; static int reuseport_array = -1, outer_map = -1; static int select_by_skb_data_prog; static int saved_tcp_syncookie = -1; static struct bpf_object *obj; static int saved_tcp_fo = -1; static __u32 index_zero; static int epfd; static union sa46 { struct sockaddr_in6 v6; struct sockaddr_in v4; sa_family_t family; } srv_sa; #define RET_IF(condition, tag, format...) ({ \ if (CHECK_FAIL(condition)) { \ printf(tag " " format); \ return; \ } \ }) #define RET_ERR(condition, tag, format...) ({ \ if (CHECK_FAIL(condition)) { \ printf(tag " " format); \ return -1; \ } \ }) static int create_maps(void) { struct bpf_create_map_attr attr = {}; /* Creating reuseport_array */ attr.name = "reuseport_array"; attr.map_type = BPF_MAP_TYPE_REUSEPORT_SOCKARRAY; attr.key_size = sizeof(__u32); attr.value_size = sizeof(__u32); attr.max_entries = REUSEPORT_ARRAY_SIZE; reuseport_array = bpf_create_map_xattr(&attr); RET_ERR(reuseport_array == -1, "creating reuseport_array", "reuseport_array:%d errno:%d\n", reuseport_array, errno); /* Creating outer_map */ attr.name = "outer_map"; attr.map_type = BPF_MAP_TYPE_ARRAY_OF_MAPS; attr.key_size = sizeof(__u32); attr.value_size = sizeof(__u32); attr.max_entries = 1; attr.inner_map_fd = reuseport_array; outer_map = bpf_create_map_xattr(&attr); RET_ERR(outer_map == -1, "creating outer_map", "outer_map:%d errno:%d\n", outer_map, errno); return 0; } static int prepare_bpf_obj(void) { struct bpf_program *prog; struct bpf_map *map; int err; obj = bpf_object__open("test_select_reuseport_kern.o"); RET_ERR(IS_ERR_OR_NULL(obj), "open test_select_reuseport_kern.o", "obj:%p PTR_ERR(obj):%ld\n", obj, PTR_ERR(obj)); map = bpf_object__find_map_by_name(obj, "outer_map"); RET_ERR(!map, "find outer_map", "!map\n"); err = bpf_map__reuse_fd(map, outer_map); RET_ERR(err, "reuse outer_map", "err:%d\n", err); err = bpf_object__load(obj); RET_ERR(err, "load bpf_object", "err:%d\n", err); prog = bpf_program__next(NULL, obj); RET_ERR(!prog, "get first bpf_program", "!prog\n"); select_by_skb_data_prog = bpf_program__fd(prog); RET_ERR(select_by_skb_data_prog == -1, "get prog fd", "select_by_skb_data_prog:%d\n", select_by_skb_data_prog); map = bpf_object__find_map_by_name(obj, "result_map"); RET_ERR(!map, "find result_map", "!map\n"); result_map = bpf_map__fd(map); RET_ERR(result_map == -1, "get result_map fd", "result_map:%d\n", result_map); map = bpf_object__find_map_by_name(obj, "tmp_index_ovr_map"); RET_ERR(!map, "find tmp_index_ovr_map\n", "!map"); tmp_index_ovr_map = bpf_map__fd(map); RET_ERR(tmp_index_ovr_map == -1, "get tmp_index_ovr_map fd", "tmp_index_ovr_map:%d\n", tmp_index_ovr_map); map = bpf_object__find_map_by_name(obj, "linum_map"); RET_ERR(!map, "find linum_map", "!map\n"); linum_map = bpf_map__fd(map); RET_ERR(linum_map == -1, "get linum_map fd", "linum_map:%d\n", linum_map); map = bpf_object__find_map_by_name(obj, "data_check_map"); RET_ERR(!map, "find data_check_map", "!map\n"); data_check_map = bpf_map__fd(map); RET_ERR(data_check_map == -1, "get data_check_map fd", "data_check_map:%d\n", data_check_map); return 0; } static void sa46_init_loopback(union sa46 *sa, sa_family_t family) { memset(sa, 0, sizeof(*sa)); sa->family = family; if (sa->family == AF_INET6) sa->v6.sin6_addr = in6addr_loopback; else sa->v4.sin_addr.s_addr = htonl(INADDR_LOOPBACK); } static void sa46_init_inany(union sa46 *sa, sa_family_t family) { memset(sa, 0, sizeof(*sa)); sa->family = family; if (sa->family == AF_INET6) sa->v6.sin6_addr = in6addr_any; else sa->v4.sin_addr.s_addr = INADDR_ANY; } static int read_int_sysctl(const char *sysctl) { char buf[16]; int fd, ret; fd = open(sysctl, 0); RET_ERR(fd == -1, "open(sysctl)", "sysctl:%s fd:%d errno:%d\n", sysctl, fd, errno); ret = read(fd, buf, sizeof(buf)); RET_ERR(ret <= 0, "read(sysctl)", "sysctl:%s ret:%d errno:%d\n", sysctl, ret, errno); close(fd); return atoi(buf); } static int write_int_sysctl(const char *sysctl, int v) { int fd, ret, size; char buf[16]; fd = open(sysctl, O_RDWR); RET_ERR(fd == -1, "open(sysctl)", "sysctl:%s fd:%d errno:%d\n", sysctl, fd, errno); size = snprintf(buf, sizeof(buf), "%d", v); ret = write(fd, buf, size); RET_ERR(ret != size, "write(sysctl)", "sysctl:%s ret:%d size:%d errno:%d\n", sysctl, ret, size, errno); close(fd); return 0; } static void restore_sysctls(void) { if (saved_tcp_fo != -1) write_int_sysctl(TCP_FO_SYSCTL, saved_tcp_fo); if (saved_tcp_syncookie != -1) write_int_sysctl(TCP_SYNCOOKIE_SYSCTL, saved_tcp_syncookie); } static int enable_fastopen(void) { int fo; fo = read_int_sysctl(TCP_FO_SYSCTL); if (fo < 0) return -1; return write_int_sysctl(TCP_FO_SYSCTL, fo | 7); } static int enable_syncookie(void) { return write_int_sysctl(TCP_SYNCOOKIE_SYSCTL, 2); } static int disable_syncookie(void) { return write_int_sysctl(TCP_SYNCOOKIE_SYSCTL, 0); } static long get_linum(void) { __u32 linum; int err; err = bpf_map_lookup_elem(linum_map, &index_zero, &linum); RET_ERR(err == -1, "lookup_elem(linum_map)", "err:%d errno:%d\n", err, errno); return linum; } static void check_data(int type, sa_family_t family, const struct cmd *cmd, int cli_fd) { struct data_check expected = {}, result; union sa46 cli_sa; socklen_t addrlen; int err; addrlen = sizeof(cli_sa); err = getsockname(cli_fd, (struct sockaddr *)&cli_sa, &addrlen); RET_IF(err == -1, "getsockname(cli_fd)", "err:%d errno:%d\n", err, errno); err = bpf_map_lookup_elem(data_check_map, &index_zero, &result); RET_IF(err == -1, "lookup_elem(data_check_map)", "err:%d errno:%d\n", err, errno); if (type == SOCK_STREAM) { expected.len = MIN_TCPHDR_LEN; expected.ip_protocol = IPPROTO_TCP; } else { expected.len = UDPHDR_LEN; expected.ip_protocol = IPPROTO_UDP; } if (family == AF_INET6) { expected.eth_protocol = htons(ETH_P_IPV6); expected.bind_inany = !srv_sa.v6.sin6_addr.s6_addr32[3] && !srv_sa.v6.sin6_addr.s6_addr32[2] && !srv_sa.v6.sin6_addr.s6_addr32[1] && !srv_sa.v6.sin6_addr.s6_addr32[0]; memcpy(&expected.skb_addrs[0], cli_sa.v6.sin6_addr.s6_addr32, sizeof(cli_sa.v6.sin6_addr)); memcpy(&expected.skb_addrs[4], &in6addr_loopback, sizeof(in6addr_loopback)); expected.skb_ports[0] = cli_sa.v6.sin6_port; expected.skb_ports[1] = srv_sa.v6.sin6_port; } else { expected.eth_protocol = htons(ETH_P_IP); expected.bind_inany = !srv_sa.v4.sin_addr.s_addr; expected.skb_addrs[0] = cli_sa.v4.sin_addr.s_addr; expected.skb_addrs[1] = htonl(INADDR_LOOPBACK); expected.skb_ports[0] = cli_sa.v4.sin_port; expected.skb_ports[1] = srv_sa.v4.sin_port; } if (memcmp(&result, &expected, offsetof(struct data_check, equal_check_end))) { printf("unexpected data_check\n"); printf(" result: (0x%x, %u, %u)\n", result.eth_protocol, result.ip_protocol, result.bind_inany); printf("expected: (0x%x, %u, %u)\n", expected.eth_protocol, expected.ip_protocol, expected.bind_inany); RET_IF(1, "data_check result != expected", "bpf_prog_linum:%ld\n", get_linum()); } RET_IF(!result.hash, "data_check result.hash empty", "result.hash:%u", result.hash); expected.len += cmd ? sizeof(*cmd) : 0; if (type == SOCK_STREAM) RET_IF(expected.len > result.len, "expected.len > result.len", "expected.len:%u result.len:%u bpf_prog_linum:%ld\n", expected.len, result.len, get_linum()); else RET_IF(expected.len != result.len, "expected.len != result.len", "expected.len:%u result.len:%u bpf_prog_linum:%ld\n", expected.len, result.len, get_linum()); } static const char *result_to_str(enum result res) { switch (res) { case DROP_ERR_INNER_MAP: return "DROP_ERR_INNER_MAP"; case DROP_ERR_SKB_DATA: return "DROP_ERR_SKB_DATA"; case DROP_ERR_SK_SELECT_REUSEPORT: return "DROP_ERR_SK_SELECT_REUSEPORT"; case DROP_MISC: return "DROP_MISC"; case PASS: return "PASS"; case PASS_ERR_SK_SELECT_REUSEPORT: return "PASS_ERR_SK_SELECT_REUSEPORT"; default: return "UNKNOWN"; } } static void check_results(void) { __u32 results[NR_RESULTS]; __u32 i, broken = 0; int err; for (i = 0; i < NR_RESULTS; i++) { err = bpf_map_lookup_elem(result_map, &i, &results[i]); RET_IF(err == -1, "lookup_elem(result_map)", "i:%u err:%d errno:%d\n", i, err, errno); } for (i = 0; i < NR_RESULTS; i++) { if (results[i] != expected_results[i]) { broken = i; break; } } if (i == NR_RESULTS) return; printf("unexpected result\n"); printf(" result: ["); printf("%u", results[0]); for (i = 1; i < NR_RESULTS; i++) printf(", %u", results[i]); printf("]\n"); printf("expected: ["); printf("%u", expected_results[0]); for (i = 1; i < NR_RESULTS; i++) printf(", %u", expected_results[i]); printf("]\n"); printf("mismatch on %s (bpf_prog_linum:%ld)\n", result_to_str(broken), get_linum()); CHECK_FAIL(true); } static int send_data(int type, sa_family_t family, void *data, size_t len, enum result expected) { union sa46 cli_sa; int fd, err; fd = socket(family, type, 0); RET_ERR(fd == -1, "socket()", "fd:%d errno:%d\n", fd, errno); sa46_init_loopback(&cli_sa, family); err = bind(fd, (struct sockaddr *)&cli_sa, sizeof(cli_sa)); RET_ERR(fd == -1, "bind(cli_sa)", "err:%d errno:%d\n", err, errno); err = sendto(fd, data, len, MSG_FASTOPEN, (struct sockaddr *)&srv_sa, sizeof(srv_sa)); RET_ERR(err != len && expected >= PASS, "sendto()", "family:%u err:%d errno:%d expected:%d\n", family, err, errno, expected); return fd; } static void do_test(int type, sa_family_t family, struct cmd *cmd, enum result expected) { int nev, srv_fd, cli_fd; struct epoll_event ev; struct cmd rcv_cmd; ssize_t nread; cli_fd = send_data(type, family, cmd, cmd ? sizeof(*cmd) : 0, expected); if (cli_fd < 0) return; nev = epoll_wait(epfd, &ev, 1, expected >= PASS ? 5 : 0); RET_IF((nev <= 0 && expected >= PASS) || (nev > 0 && expected < PASS), "nev <> expected", "nev:%d expected:%d type:%d family:%d data:(%d, %d)\n", nev, expected, type, family, cmd ? cmd->reuseport_index : -1, cmd ? cmd->pass_on_failure : -1); check_results(); check_data(type, family, cmd, cli_fd); if (expected < PASS) return; RET_IF(expected != PASS_ERR_SK_SELECT_REUSEPORT && cmd->reuseport_index != ev.data.u32, "check cmd->reuseport_index", "cmd:(%u, %u) ev.data.u32:%u\n", cmd->pass_on_failure, cmd->reuseport_index, ev.data.u32); srv_fd = sk_fds[ev.data.u32]; if (type == SOCK_STREAM) { int new_fd = accept(srv_fd, NULL, 0); RET_IF(new_fd == -1, "accept(srv_fd)", "ev.data.u32:%u new_fd:%d errno:%d\n", ev.data.u32, new_fd, errno); nread = recv(new_fd, &rcv_cmd, sizeof(rcv_cmd), MSG_DONTWAIT); RET_IF(nread != sizeof(rcv_cmd), "recv(new_fd)", "ev.data.u32:%u nread:%zd sizeof(rcv_cmd):%zu errno:%d\n", ev.data.u32, nread, sizeof(rcv_cmd), errno); close(new_fd); } else { nread = recv(srv_fd, &rcv_cmd, sizeof(rcv_cmd), MSG_DONTWAIT); RET_IF(nread != sizeof(rcv_cmd), "recv(sk_fds)", "ev.data.u32:%u nread:%zd sizeof(rcv_cmd):%zu errno:%d\n", ev.data.u32, nread, sizeof(rcv_cmd), errno); } close(cli_fd); } static void test_err_inner_map(int type, sa_family_t family) { struct cmd cmd = { .reuseport_index = 0, .pass_on_failure = 0, }; expected_results[DROP_ERR_INNER_MAP]++; do_test(type, family, &cmd, DROP_ERR_INNER_MAP); } static void test_err_skb_data(int type, sa_family_t family) { expected_results[DROP_ERR_SKB_DATA]++; do_test(type, family, NULL, DROP_ERR_SKB_DATA); } static void test_err_sk_select_port(int type, sa_family_t family) { struct cmd cmd = { .reuseport_index = REUSEPORT_ARRAY_SIZE, .pass_on_failure = 0, }; expected_results[DROP_ERR_SK_SELECT_REUSEPORT]++; do_test(type, family, &cmd, DROP_ERR_SK_SELECT_REUSEPORT); } static void test_pass(int type, sa_family_t family) { struct cmd cmd; int i; cmd.pass_on_failure = 0; for (i = 0; i < REUSEPORT_ARRAY_SIZE; i++) { expected_results[PASS]++; cmd.reuseport_index = i; do_test(type, family, &cmd, PASS); } } static void test_syncookie(int type, sa_family_t family) { int err, tmp_index = 1; struct cmd cmd = { .reuseport_index = 0, .pass_on_failure = 0, }; if (type != SOCK_STREAM) return; /* * +1 for TCP-SYN and * +1 for the TCP-ACK (ack the syncookie) */ expected_results[PASS] += 2; enable_syncookie(); /* * Simulate TCP-SYN and TCP-ACK are handled by two different sk: * TCP-SYN: select sk_fds[tmp_index = 1] tmp_index is from the * tmp_index_ovr_map * TCP-ACK: select sk_fds[reuseport_index = 0] reuseport_index * is from the cmd.reuseport_index */ err = bpf_map_update_elem(tmp_index_ovr_map, &index_zero, &tmp_index, BPF_ANY); RET_IF(err == -1, "update_elem(tmp_index_ovr_map, 0, 1)", "err:%d errno:%d\n", err, errno); do_test(type, family, &cmd, PASS); err = bpf_map_lookup_elem(tmp_index_ovr_map, &index_zero, &tmp_index); RET_IF(err == -1 || tmp_index != -1, "lookup_elem(tmp_index_ovr_map)", "err:%d errno:%d tmp_index:%d\n", err, errno, tmp_index); disable_syncookie(); } static void test_pass_on_err(int type, sa_family_t family) { struct cmd cmd = { .reuseport_index = REUSEPORT_ARRAY_SIZE, .pass_on_failure = 1, }; expected_results[PASS_ERR_SK_SELECT_REUSEPORT] += 1; do_test(type, family, &cmd, PASS_ERR_SK_SELECT_REUSEPORT); } static void test_detach_bpf(int type, sa_family_t family) { #ifdef SO_DETACH_REUSEPORT_BPF __u32 nr_run_before = 0, nr_run_after = 0, tmp, i; struct epoll_event ev; int cli_fd, err, nev; struct cmd cmd = {}; int optvalue = 0; err = setsockopt(sk_fds[0], SOL_SOCKET, SO_DETACH_REUSEPORT_BPF, &optvalue, sizeof(optvalue)); RET_IF(err == -1, "setsockopt(SO_DETACH_REUSEPORT_BPF)", "err:%d errno:%d\n", err, errno); err = setsockopt(sk_fds[1], SOL_SOCKET, SO_DETACH_REUSEPORT_BPF, &optvalue, sizeof(optvalue)); RET_IF(err == 0 || errno != ENOENT, "setsockopt(SO_DETACH_REUSEPORT_BPF)", "err:%d errno:%d\n", err, errno); for (i = 0; i < NR_RESULTS; i++) { err = bpf_map_lookup_elem(result_map, &i, &tmp); RET_IF(err == -1, "lookup_elem(result_map)", "i:%u err:%d errno:%d\n", i, err, errno); nr_run_before += tmp; } cli_fd = send_data(type, family, &cmd, sizeof(cmd), PASS); if (cli_fd < 0) return; nev = epoll_wait(epfd, &ev, 1, 5); RET_IF(nev <= 0, "nev <= 0", "nev:%d expected:1 type:%d family:%d data:(0, 0)\n", nev, type, family); for (i = 0; i < NR_RESULTS; i++) { err = bpf_map_lookup_elem(result_map, &i, &tmp); RET_IF(err == -1, "lookup_elem(result_map)", "i:%u err:%d errno:%d\n", i, err, errno); nr_run_after += tmp; } RET_IF(nr_run_before != nr_run_after, "nr_run_before != nr_run_after", "nr_run_before:%u nr_run_after:%u\n", nr_run_before, nr_run_after); close(cli_fd); #else test__skip(); #endif } static void prepare_sk_fds(int type, sa_family_t family, bool inany) { const int first = REUSEPORT_ARRAY_SIZE - 1; int i, err, optval = 1; struct epoll_event ev; socklen_t addrlen; if (inany) sa46_init_inany(&srv_sa, family); else sa46_init_loopback(&srv_sa, family); addrlen = sizeof(srv_sa); /* * The sk_fds[] is filled from the back such that the order * is exactly opposite to the (struct sock_reuseport *)reuse->socks[]. */ for (i = first; i >= 0; i--) { sk_fds[i] = socket(family, type, 0); RET_IF(sk_fds[i] == -1, "socket()", "sk_fds[%d]:%d errno:%d\n", i, sk_fds[i], errno); err = setsockopt(sk_fds[i], SOL_SOCKET, SO_REUSEPORT, &optval, sizeof(optval)); RET_IF(err == -1, "setsockopt(SO_REUSEPORT)", "sk_fds[%d] err:%d errno:%d\n", i, err, errno); if (i == first) { err = setsockopt(sk_fds[i], SOL_SOCKET, SO_ATTACH_REUSEPORT_EBPF, &select_by_skb_data_prog, sizeof(select_by_skb_data_prog)); RET_IF(err == -1, "setsockopt(SO_ATTACH_REUEPORT_EBPF)", "err:%d errno:%d\n", err, errno); } err = bind(sk_fds[i], (struct sockaddr *)&srv_sa, addrlen); RET_IF(err == -1, "bind()", "sk_fds[%d] err:%d errno:%d\n", i, err, errno); if (type == SOCK_STREAM) { err = listen(sk_fds[i], 10); RET_IF(err == -1, "listen()", "sk_fds[%d] err:%d errno:%d\n", i, err, errno); } err = bpf_map_update_elem(reuseport_array, &i, &sk_fds[i], BPF_NOEXIST); RET_IF(err == -1, "update_elem(reuseport_array)", "sk_fds[%d] err:%d errno:%d\n", i, err, errno); if (i == first) { socklen_t addrlen = sizeof(srv_sa); err = getsockname(sk_fds[i], (struct sockaddr *)&srv_sa, &addrlen); RET_IF(err == -1, "getsockname()", "sk_fds[%d] err:%d errno:%d\n", i, err, errno); } } epfd = epoll_create(1); RET_IF(epfd == -1, "epoll_create(1)", "epfd:%d errno:%d\n", epfd, errno); ev.events = EPOLLIN; for (i = 0; i < REUSEPORT_ARRAY_SIZE; i++) { ev.data.u32 = i; err = epoll_ctl(epfd, EPOLL_CTL_ADD, sk_fds[i], &ev); RET_IF(err, "epoll_ctl(EPOLL_CTL_ADD)", "sk_fds[%d]\n", i); } } static void setup_per_test(int type, sa_family_t family, bool inany, bool no_inner_map) { int ovr = -1, err; prepare_sk_fds(type, family, inany); err = bpf_map_update_elem(tmp_index_ovr_map, &index_zero, &ovr, BPF_ANY); RET_IF(err == -1, "update_elem(tmp_index_ovr_map, 0, -1)", "err:%d errno:%d\n", err, errno); /* Install reuseport_array to outer_map? */ if (no_inner_map) return; err = bpf_map_update_elem(outer_map, &index_zero, &reuseport_array, BPF_ANY); RET_IF(err == -1, "update_elem(outer_map, 0, reuseport_array)", "err:%d errno:%d\n", err, errno); } static void cleanup_per_test(bool no_inner_map) { int i, err, zero = 0; memset(expected_results, 0, sizeof(expected_results)); for (i = 0; i < NR_RESULTS; i++) { err = bpf_map_update_elem(result_map, &i, &zero, BPF_ANY); RET_IF(err, "reset elem in result_map", "i:%u err:%d errno:%d\n", i, err, errno); } err = bpf_map_update_elem(linum_map, &zero, &zero, BPF_ANY); RET_IF(err, "reset line number in linum_map", "err:%d errno:%d\n", err, errno); for (i = 0; i < REUSEPORT_ARRAY_SIZE; i++) close(sk_fds[i]); close(epfd); /* Delete reuseport_array from outer_map? */ if (no_inner_map) return; err = bpf_map_delete_elem(outer_map, &index_zero); RET_IF(err == -1, "delete_elem(outer_map)", "err:%d errno:%d\n", err, errno); } static void cleanup(void) { if (outer_map != -1) close(outer_map); if (reuseport_array != -1) close(reuseport_array); if (obj) bpf_object__close(obj); } static const char *family_str(sa_family_t family) { switch (family) { case AF_INET: return "IPv4"; case AF_INET6: return "IPv6"; default: return "unknown"; } } static const char *sotype_str(int sotype) { switch (sotype) { case SOCK_STREAM: return "TCP"; case SOCK_DGRAM: return "UDP"; default: return "unknown"; } } #define TEST_INIT(fn, ...) { fn, #fn, __VA_ARGS__ } static void test_config(int sotype, sa_family_t family, bool inany) { const struct test { void (*fn)(int sotype, sa_family_t family); const char *name; bool no_inner_map; } tests[] = { TEST_INIT(test_err_inner_map, true /* no_inner_map */), TEST_INIT(test_err_skb_data), TEST_INIT(test_err_sk_select_port), TEST_INIT(test_pass), TEST_INIT(test_syncookie), TEST_INIT(test_pass_on_err), TEST_INIT(test_detach_bpf), }; char s[MAX_TEST_NAME]; const struct test *t; for (t = tests; t < tests + ARRAY_SIZE(tests); t++) { snprintf(s, sizeof(s), "%s/%s %s %s", family_str(family), sotype_str(sotype), inany ? "INANY" : "LOOPBACK", t->name); if (!test__start_subtest(s)) continue; setup_per_test(sotype, family, inany, t->no_inner_map); t->fn(sotype, family); cleanup_per_test(t->no_inner_map); } } #define BIND_INANY true static void test_all(void) { const struct config { int sotype; sa_family_t family; bool inany; } configs[] = { { SOCK_STREAM, AF_INET }, { SOCK_STREAM, AF_INET, BIND_INANY }, { SOCK_STREAM, AF_INET6 }, { SOCK_STREAM, AF_INET6, BIND_INANY }, { SOCK_DGRAM, AF_INET }, { SOCK_DGRAM, AF_INET6 }, }; const struct config *c; for (c = configs; c < configs + ARRAY_SIZE(configs); c++) test_config(c->sotype, c->family, c->inany); } void test_select_reuseport(void) { if (create_maps()) goto out; if (prepare_bpf_obj()) goto out; saved_tcp_fo = read_int_sysctl(TCP_FO_SYSCTL); saved_tcp_syncookie = read_int_sysctl(TCP_SYNCOOKIE_SYSCTL); if (saved_tcp_syncookie < 0 || saved_tcp_syncookie < 0) goto out; if (enable_fastopen()) goto out; if (disable_syncookie()) goto out; test_all(); out: cleanup(); restore_sysctls(); }