// SPDX-License-Identifier: GPL-2.0 #include #include #include #include #include "utils.h" static const u8 dev_default_lladdr[] = { 0x01, 0x02 }; /* helper for simple sock setup: single device, with dev_default_lladdr as its * hardware address, assigned with a local EID 8, and a route to EID 9 */ static void __mctp_sock_test_init(struct kunit *test, struct mctp_test_dev **devp, struct mctp_test_route **rtp, struct socket **sockp) { struct mctp_test_route *rt; struct mctp_test_dev *dev; struct socket *sock; unsigned long flags; u8 *addrs; int rc; dev = mctp_test_create_dev_lladdr(sizeof(dev_default_lladdr), dev_default_lladdr); KUNIT_ASSERT_NOT_ERR_OR_NULL(test, dev); addrs = kmalloc(1, GFP_KERNEL); KUNIT_ASSERT_NOT_ERR_OR_NULL(test, addrs); addrs[0] = 8; spin_lock_irqsave(&dev->mdev->addrs_lock, flags); dev->mdev->num_addrs = 1; swap(addrs, dev->mdev->addrs); spin_unlock_irqrestore(&dev->mdev->addrs_lock, flags); kfree(addrs); rt = mctp_test_create_route_direct(dev_net(dev->ndev), dev->mdev, 9, 0); KUNIT_ASSERT_NOT_ERR_OR_NULL(test, rt); rc = sock_create_kern(&init_net, AF_MCTP, SOCK_DGRAM, 0, &sock); KUNIT_ASSERT_EQ(test, rc, 0); *devp = dev; *rtp = rt; *sockp = sock; } static void __mctp_sock_test_fini(struct kunit *test, struct mctp_test_dev *dev, struct mctp_test_route *rt, struct socket *sock) { sock_release(sock); mctp_test_route_destroy(test, rt); mctp_test_destroy_dev(dev); } struct mctp_test_sock_local_output_config { struct mctp_test_dev *dev; size_t halen; u8 haddr[MAX_ADDR_LEN]; bool invoked; int rc; }; static int mctp_test_sock_local_output(struct sock *sk, struct mctp_dst *dst, struct sk_buff *skb, mctp_eid_t daddr, u8 req_tag) { struct kunit *test = kunit_get_current_test(); struct mctp_test_sock_local_output_config *cfg = test->priv; KUNIT_EXPECT_PTR_EQ(test, dst->dev, cfg->dev->mdev); KUNIT_EXPECT_EQ(test, dst->halen, cfg->halen); KUNIT_EXPECT_MEMEQ(test, dst->haddr, cfg->haddr, dst->halen); cfg->invoked = true; kfree_skb(skb); return cfg->rc; } static void mctp_test_sock_sendmsg_extaddr(struct kunit *test) { struct sockaddr_mctp_ext addr = { .smctp_base = { .smctp_family = AF_MCTP, .smctp_tag = MCTP_TAG_OWNER, .smctp_network = MCTP_NET_ANY, }, }; struct mctp_test_sock_local_output_config cfg = { 0 }; u8 haddr[] = { 0xaa, 0x01 }; u8 buf[4] = { 0, 1, 2, 3 }; struct mctp_test_route *rt; struct msghdr msg = { 0 }; struct mctp_test_dev *dev; struct mctp_sock *msk; struct socket *sock; ssize_t send_len; struct kvec vec = { .iov_base = buf, .iov_len = sizeof(buf), }; __mctp_sock_test_init(test, &dev, &rt, &sock); /* Expect to see the dst configured up with the addressing data we * provide in the struct sockaddr_mctp_ext */ cfg.dev = dev; cfg.halen = sizeof(haddr); memcpy(cfg.haddr, haddr, sizeof(haddr)); test->priv = &cfg; kunit_activate_static_stub(test, mctp_local_output, mctp_test_sock_local_output); /* enable and configure direct addressing */ msk = container_of(sock->sk, struct mctp_sock, sk); msk->addr_ext = true; addr.smctp_ifindex = dev->ndev->ifindex; addr.smctp_halen = sizeof(haddr); memcpy(addr.smctp_haddr, haddr, sizeof(haddr)); msg.msg_name = &addr; msg.msg_namelen = sizeof(addr); iov_iter_kvec(&msg.msg_iter, ITER_SOURCE, &vec, 1, sizeof(buf)); send_len = mctp_sendmsg(sock, &msg, sizeof(buf)); KUNIT_EXPECT_EQ(test, send_len, sizeof(buf)); KUNIT_EXPECT_TRUE(test, cfg.invoked); __mctp_sock_test_fini(test, dev, rt, sock); } static void mctp_test_sock_recvmsg_extaddr(struct kunit *test) { struct sockaddr_mctp_ext recv_addr = { 0 }; u8 rcv_buf[1], rcv_data[] = { 0, 1 }; u8 haddr[] = { 0xaa, 0x02 }; struct mctp_test_route *rt; struct mctp_test_dev *dev; struct mctp_skb_cb *cb; struct mctp_sock *msk; struct sk_buff *skb; struct mctp_hdr hdr; struct socket *sock; struct msghdr msg; ssize_t recv_len; int rc; struct kvec vec = { .iov_base = rcv_buf, .iov_len = sizeof(rcv_buf), }; __mctp_sock_test_init(test, &dev, &rt, &sock); /* enable extended addressing on recv */ msk = container_of(sock->sk, struct mctp_sock, sk); msk->addr_ext = true; /* base incoming header, using a nul-EID dest */ hdr.ver = 1; hdr.dest = 0; hdr.src = 9; hdr.flags_seq_tag = MCTP_HDR_FLAG_SOM | MCTP_HDR_FLAG_EOM | MCTP_HDR_FLAG_TO; skb = mctp_test_create_skb_data(&hdr, &rcv_data); KUNIT_ASSERT_NOT_ERR_OR_NULL(test, skb); mctp_test_skb_set_dev(skb, dev); /* set incoming extended address data */ cb = mctp_cb(skb); cb->halen = sizeof(haddr); cb->ifindex = dev->ndev->ifindex; memcpy(cb->haddr, haddr, sizeof(haddr)); /* Deliver to socket. The route input path pulls the network header, * leaving skb data at type byte onwards. recvmsg will consume the * type for addr.smctp_type */ skb_pull(skb, sizeof(hdr)); rc = sock_queue_rcv_skb(sock->sk, skb); KUNIT_ASSERT_EQ(test, rc, 0); msg.msg_name = &recv_addr; msg.msg_namelen = sizeof(recv_addr); iov_iter_kvec(&msg.msg_iter, ITER_DEST, &vec, 1, sizeof(rcv_buf)); recv_len = mctp_recvmsg(sock, &msg, sizeof(rcv_buf), MSG_DONTWAIT | MSG_TRUNC); KUNIT_EXPECT_EQ(test, recv_len, sizeof(rcv_buf)); /* expect our extended address to be populated from hdr and cb */ KUNIT_EXPECT_EQ(test, msg.msg_namelen, sizeof(recv_addr)); KUNIT_EXPECT_EQ(test, recv_addr.smctp_base.smctp_family, AF_MCTP); KUNIT_EXPECT_EQ(test, recv_addr.smctp_ifindex, dev->ndev->ifindex); KUNIT_EXPECT_EQ(test, recv_addr.smctp_halen, sizeof(haddr)); KUNIT_EXPECT_MEMEQ(test, recv_addr.smctp_haddr, haddr, sizeof(haddr)); __mctp_sock_test_fini(test, dev, rt, sock); } static const struct mctp_test_bind_setup bind_addrany_netdefault_type1 = { .bind_addr = MCTP_ADDR_ANY, .bind_net = MCTP_NET_ANY, .bind_type = 1, }; static const struct mctp_test_bind_setup bind_addrany_net2_type1 = { .bind_addr = MCTP_ADDR_ANY, .bind_net = 2, .bind_type = 1, }; /* 1 is default net */ static const struct mctp_test_bind_setup bind_addr8_net1_type1 = { .bind_addr = 8, .bind_net = 1, .bind_type = 1, }; static const struct mctp_test_bind_setup bind_addrany_net1_type1 = { .bind_addr = MCTP_ADDR_ANY, .bind_net = 1, .bind_type = 1, }; /* 2 is an arbitrary net */ static const struct mctp_test_bind_setup bind_addr8_net2_type1 = { .bind_addr = 8, .bind_net = 2, .bind_type = 1, }; static const struct mctp_test_bind_setup bind_addr8_netdefault_type1 = { .bind_addr = 8, .bind_net = MCTP_NET_ANY, .bind_type = 1, }; static const struct mctp_test_bind_setup bind_addrany_net2_type2 = { .bind_addr = MCTP_ADDR_ANY, .bind_net = 2, .bind_type = 2, }; static const struct mctp_test_bind_setup bind_addrany_net2_type1_peer9 = { .bind_addr = MCTP_ADDR_ANY, .bind_net = 2, .bind_type = 1, .have_peer = true, .peer_addr = 9, .peer_net = 2, }; struct mctp_bind_pair_test { const struct mctp_test_bind_setup *bind1; const struct mctp_test_bind_setup *bind2; int error; }; /* Pairs of binds and whether they will conflict */ static const struct mctp_bind_pair_test mctp_bind_pair_tests[] = { /* Both ADDR_ANY, conflict */ { &bind_addrany_netdefault_type1, &bind_addrany_netdefault_type1, EADDRINUSE }, /* Same specific EID, conflict */ { &bind_addr8_netdefault_type1, &bind_addr8_netdefault_type1, EADDRINUSE }, /* ADDR_ANY vs specific EID, OK */ { &bind_addrany_netdefault_type1, &bind_addr8_netdefault_type1, 0 }, /* ADDR_ANY different types, OK */ { &bind_addrany_net2_type2, &bind_addrany_net2_type1, 0 }, /* ADDR_ANY different nets, OK */ { &bind_addrany_net2_type1, &bind_addrany_netdefault_type1, 0 }, /* specific EID, NET_ANY (resolves to default) * vs specific EID, explicit default net 1, conflict */ { &bind_addr8_netdefault_type1, &bind_addr8_net1_type1, EADDRINUSE }, /* specific EID, net 1 vs specific EID, net 2, ok */ { &bind_addr8_net1_type1, &bind_addr8_net2_type1, 0 }, /* ANY_ADDR, NET_ANY (doesn't resolve to default) * vs ADDR_ANY, explicit default net 1, OK */ { &bind_addrany_netdefault_type1, &bind_addrany_net1_type1, 0 }, /* specific remote peer doesn't conflict with any-peer bind */ { &bind_addrany_net2_type1_peer9, &bind_addrany_net2_type1, 0 }, /* bind() NET_ANY is allowed with a connect() net */ { &bind_addrany_net2_type1_peer9, &bind_addrany_netdefault_type1, 0 }, }; static void mctp_bind_pair_desc(const struct mctp_bind_pair_test *t, char *desc) { char peer1[25] = {0}, peer2[25] = {0}; if (t->bind1->have_peer) snprintf(peer1, sizeof(peer1), ", peer %d net %d", t->bind1->peer_addr, t->bind1->peer_net); if (t->bind2->have_peer) snprintf(peer2, sizeof(peer2), ", peer %d net %d", t->bind2->peer_addr, t->bind2->peer_net); snprintf(desc, KUNIT_PARAM_DESC_SIZE, "{bind(addr %d, type %d, net %d%s)} {bind(addr %d, type %d, net %d%s)} -> error %d", t->bind1->bind_addr, t->bind1->bind_type, t->bind1->bind_net, peer1, t->bind2->bind_addr, t->bind2->bind_type, t->bind2->bind_net, peer2, t->error); } KUNIT_ARRAY_PARAM(mctp_bind_pair, mctp_bind_pair_tests, mctp_bind_pair_desc); static void mctp_test_bind_invalid(struct kunit *test) { struct socket *sock; int rc; /* bind() fails if the bind() vs connect() networks mismatch. */ const struct mctp_test_bind_setup bind_connect_net_mismatch = { .bind_addr = MCTP_ADDR_ANY, .bind_net = 1, .bind_type = 1, .have_peer = true, .peer_addr = 9, .peer_net = 2, }; mctp_test_bind_run(test, &bind_connect_net_mismatch, &rc, &sock); KUNIT_EXPECT_EQ(test, -rc, EINVAL); sock_release(sock); } static int mctp_test_bind_conflicts_inner(struct kunit *test, const struct mctp_test_bind_setup *bind1, const struct mctp_test_bind_setup *bind2) { struct socket *sock1 = NULL, *sock2 = NULL, *sock3 = NULL; int bind_errno; /* Bind to first address, always succeeds */ mctp_test_bind_run(test, bind1, &bind_errno, &sock1); KUNIT_EXPECT_EQ(test, bind_errno, 0); /* A second identical bind always fails */ mctp_test_bind_run(test, bind1, &bind_errno, &sock2); KUNIT_EXPECT_EQ(test, -bind_errno, EADDRINUSE); /* A different bind, result is returned */ mctp_test_bind_run(test, bind2, &bind_errno, &sock3); if (sock1) sock_release(sock1); if (sock2) sock_release(sock2); if (sock3) sock_release(sock3); return bind_errno; } static void mctp_test_bind_conflicts(struct kunit *test) { const struct mctp_bind_pair_test *pair; int bind_errno; pair = test->param_value; bind_errno = mctp_test_bind_conflicts_inner(test, pair->bind1, pair->bind2); KUNIT_EXPECT_EQ(test, -bind_errno, pair->error); /* swapping the calls, the second bind should still fail */ bind_errno = mctp_test_bind_conflicts_inner(test, pair->bind2, pair->bind1); KUNIT_EXPECT_EQ(test, -bind_errno, pair->error); } static void mctp_test_assumptions(struct kunit *test) { /* check assumption of default net from bind_addr8_net1_type1 */ KUNIT_ASSERT_EQ(test, mctp_default_net(&init_net), 1); } static struct kunit_case mctp_test_cases[] = { KUNIT_CASE(mctp_test_assumptions), KUNIT_CASE(mctp_test_sock_sendmsg_extaddr), KUNIT_CASE(mctp_test_sock_recvmsg_extaddr), KUNIT_CASE_PARAM(mctp_test_bind_conflicts, mctp_bind_pair_gen_params), KUNIT_CASE(mctp_test_bind_invalid), {} }; static struct kunit_suite mctp_test_suite = { .name = "mctp-sock", .test_cases = mctp_test_cases, }; kunit_test_suite(mctp_test_suite);