cma.c 148 KB

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  1. // SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
  2. /*
  3. * Copyright (c) 2005 Voltaire Inc. All rights reserved.
  4. * Copyright (c) 2002-2005, Network Appliance, Inc. All rights reserved.
  5. * Copyright (c) 1999-2019, Mellanox Technologies, Inc. All rights reserved.
  6. * Copyright (c) 2005-2006 Intel Corporation. All rights reserved.
  7. */
  8. #include <linux/completion.h>
  9. #include <linux/in.h>
  10. #include <linux/in6.h>
  11. #include <linux/mutex.h>
  12. #include <linux/random.h>
  13. #include <linux/rbtree.h>
  14. #include <linux/igmp.h>
  15. #include <linux/xarray.h>
  16. #include <linux/inetdevice.h>
  17. #include <linux/slab.h>
  18. #include <linux/module.h>
  19. #include <net/route.h>
  20. #include <net/net_namespace.h>
  21. #include <net/netns/generic.h>
  22. #include <net/netevent.h>
  23. #include <net/tcp.h>
  24. #include <net/ipv6.h>
  25. #include <net/ip_fib.h>
  26. #include <net/ip6_route.h>
  27. #include <rdma/rdma_cm.h>
  28. #include <rdma/rdma_cm_ib.h>
  29. #include <rdma/rdma_netlink.h>
  30. #include <rdma/ib.h>
  31. #include <rdma/ib_cache.h>
  32. #include <rdma/ib_cm.h>
  33. #include <rdma/ib_sa.h>
  34. #include <rdma/iw_cm.h>
  35. #include "core_priv.h"
  36. #include "cma_priv.h"
  37. #include "cma_trace.h"
  38. MODULE_AUTHOR("Sean Hefty");
  39. MODULE_DESCRIPTION("Generic RDMA CM Agent");
  40. MODULE_LICENSE("Dual BSD/GPL");
  41. #define CMA_CM_RESPONSE_TIMEOUT 20
  42. #define CMA_MAX_CM_RETRIES 15
  43. #define CMA_IBOE_PACKET_LIFETIME 16
  44. #define CMA_PREFERRED_ROCE_GID_TYPE IB_GID_TYPE_ROCE_UDP_ENCAP
  45. static const char * const cma_events[] = {
  46. [RDMA_CM_EVENT_ADDR_RESOLVED] = "address resolved",
  47. [RDMA_CM_EVENT_ADDR_ERROR] = "address error",
  48. [RDMA_CM_EVENT_ROUTE_RESOLVED] = "route resolved ",
  49. [RDMA_CM_EVENT_ROUTE_ERROR] = "route error",
  50. [RDMA_CM_EVENT_CONNECT_REQUEST] = "connect request",
  51. [RDMA_CM_EVENT_CONNECT_RESPONSE] = "connect response",
  52. [RDMA_CM_EVENT_CONNECT_ERROR] = "connect error",
  53. [RDMA_CM_EVENT_UNREACHABLE] = "unreachable",
  54. [RDMA_CM_EVENT_REJECTED] = "rejected",
  55. [RDMA_CM_EVENT_ESTABLISHED] = "established",
  56. [RDMA_CM_EVENT_DISCONNECTED] = "disconnected",
  57. [RDMA_CM_EVENT_DEVICE_REMOVAL] = "device removal",
  58. [RDMA_CM_EVENT_MULTICAST_JOIN] = "multicast join",
  59. [RDMA_CM_EVENT_MULTICAST_ERROR] = "multicast error",
  60. [RDMA_CM_EVENT_ADDR_CHANGE] = "address change",
  61. [RDMA_CM_EVENT_TIMEWAIT_EXIT] = "timewait exit",
  62. };
  63. static void cma_iboe_set_mgid(struct sockaddr *addr, union ib_gid *mgid,
  64. enum ib_gid_type gid_type);
  65. static void cma_netevent_work_handler(struct work_struct *_work);
  66. const char *__attribute_const__ rdma_event_msg(enum rdma_cm_event_type event)
  67. {
  68. size_t index = event;
  69. return (index < ARRAY_SIZE(cma_events) && cma_events[index]) ?
  70. cma_events[index] : "unrecognized event";
  71. }
  72. EXPORT_SYMBOL(rdma_event_msg);
  73. const char *__attribute_const__ rdma_reject_msg(struct rdma_cm_id *id,
  74. int reason)
  75. {
  76. if (rdma_ib_or_roce(id->device, id->port_num))
  77. return ibcm_reject_msg(reason);
  78. if (rdma_protocol_iwarp(id->device, id->port_num))
  79. return iwcm_reject_msg(reason);
  80. WARN_ON_ONCE(1);
  81. return "unrecognized transport";
  82. }
  83. EXPORT_SYMBOL(rdma_reject_msg);
  84. /**
  85. * rdma_is_consumer_reject - return true if the consumer rejected the connect
  86. * request.
  87. * @id: Communication identifier that received the REJECT event.
  88. * @reason: Value returned in the REJECT event status field.
  89. */
  90. static bool rdma_is_consumer_reject(struct rdma_cm_id *id, int reason)
  91. {
  92. if (rdma_ib_or_roce(id->device, id->port_num))
  93. return reason == IB_CM_REJ_CONSUMER_DEFINED;
  94. if (rdma_protocol_iwarp(id->device, id->port_num))
  95. return reason == -ECONNREFUSED;
  96. WARN_ON_ONCE(1);
  97. return false;
  98. }
  99. const void *rdma_consumer_reject_data(struct rdma_cm_id *id,
  100. struct rdma_cm_event *ev, u8 *data_len)
  101. {
  102. const void *p;
  103. if (rdma_is_consumer_reject(id, ev->status)) {
  104. *data_len = ev->param.conn.private_data_len;
  105. p = ev->param.conn.private_data;
  106. } else {
  107. *data_len = 0;
  108. p = NULL;
  109. }
  110. return p;
  111. }
  112. EXPORT_SYMBOL(rdma_consumer_reject_data);
  113. /**
  114. * rdma_iw_cm_id() - return the iw_cm_id pointer for this cm_id.
  115. * @id: Communication Identifier
  116. */
  117. struct iw_cm_id *rdma_iw_cm_id(struct rdma_cm_id *id)
  118. {
  119. struct rdma_id_private *id_priv;
  120. id_priv = container_of(id, struct rdma_id_private, id);
  121. if (id->device->node_type == RDMA_NODE_RNIC)
  122. return id_priv->cm_id.iw;
  123. return NULL;
  124. }
  125. EXPORT_SYMBOL(rdma_iw_cm_id);
  126. static int cma_add_one(struct ib_device *device);
  127. static void cma_remove_one(struct ib_device *device, void *client_data);
  128. static struct ib_client cma_client = {
  129. .name = "cma",
  130. .add = cma_add_one,
  131. .remove = cma_remove_one
  132. };
  133. static struct ib_sa_client sa_client;
  134. static LIST_HEAD(dev_list);
  135. static LIST_HEAD(listen_any_list);
  136. static DEFINE_MUTEX(lock);
  137. static struct rb_root id_table = RB_ROOT;
  138. /* Serialize operations of id_table tree */
  139. static DEFINE_SPINLOCK(id_table_lock);
  140. static struct workqueue_struct *cma_wq;
  141. static unsigned int cma_pernet_id;
  142. struct cma_pernet {
  143. struct xarray tcp_ps;
  144. struct xarray udp_ps;
  145. struct xarray ipoib_ps;
  146. struct xarray ib_ps;
  147. };
  148. static struct cma_pernet *cma_pernet(struct net *net)
  149. {
  150. return net_generic(net, cma_pernet_id);
  151. }
  152. static
  153. struct xarray *cma_pernet_xa(struct net *net, enum rdma_ucm_port_space ps)
  154. {
  155. struct cma_pernet *pernet = cma_pernet(net);
  156. switch (ps) {
  157. case RDMA_PS_TCP:
  158. return &pernet->tcp_ps;
  159. case RDMA_PS_UDP:
  160. return &pernet->udp_ps;
  161. case RDMA_PS_IPOIB:
  162. return &pernet->ipoib_ps;
  163. case RDMA_PS_IB:
  164. return &pernet->ib_ps;
  165. default:
  166. return NULL;
  167. }
  168. }
  169. struct id_table_entry {
  170. struct list_head id_list;
  171. struct rb_node rb_node;
  172. };
  173. struct cma_device {
  174. struct list_head list;
  175. struct ib_device *device;
  176. struct completion comp;
  177. refcount_t refcount;
  178. struct list_head id_list;
  179. enum ib_gid_type *default_gid_type;
  180. u8 *default_roce_tos;
  181. };
  182. struct rdma_bind_list {
  183. enum rdma_ucm_port_space ps;
  184. struct hlist_head owners;
  185. unsigned short port;
  186. };
  187. static int cma_ps_alloc(struct net *net, enum rdma_ucm_port_space ps,
  188. struct rdma_bind_list *bind_list, int snum)
  189. {
  190. struct xarray *xa = cma_pernet_xa(net, ps);
  191. return xa_insert(xa, snum, bind_list, GFP_KERNEL);
  192. }
  193. static struct rdma_bind_list *cma_ps_find(struct net *net,
  194. enum rdma_ucm_port_space ps, int snum)
  195. {
  196. struct xarray *xa = cma_pernet_xa(net, ps);
  197. return xa_load(xa, snum);
  198. }
  199. static void cma_ps_remove(struct net *net, enum rdma_ucm_port_space ps,
  200. int snum)
  201. {
  202. struct xarray *xa = cma_pernet_xa(net, ps);
  203. xa_erase(xa, snum);
  204. }
  205. enum {
  206. CMA_OPTION_AFONLY,
  207. };
  208. void cma_dev_get(struct cma_device *cma_dev)
  209. {
  210. refcount_inc(&cma_dev->refcount);
  211. }
  212. void cma_dev_put(struct cma_device *cma_dev)
  213. {
  214. if (refcount_dec_and_test(&cma_dev->refcount))
  215. complete(&cma_dev->comp);
  216. }
  217. struct cma_device *cma_enum_devices_by_ibdev(cma_device_filter filter,
  218. void *cookie)
  219. {
  220. struct cma_device *cma_dev;
  221. struct cma_device *found_cma_dev = NULL;
  222. mutex_lock(&lock);
  223. list_for_each_entry(cma_dev, &dev_list, list)
  224. if (filter(cma_dev->device, cookie)) {
  225. found_cma_dev = cma_dev;
  226. break;
  227. }
  228. if (found_cma_dev)
  229. cma_dev_get(found_cma_dev);
  230. mutex_unlock(&lock);
  231. return found_cma_dev;
  232. }
  233. int cma_get_default_gid_type(struct cma_device *cma_dev,
  234. u32 port)
  235. {
  236. if (!rdma_is_port_valid(cma_dev->device, port))
  237. return -EINVAL;
  238. return cma_dev->default_gid_type[port - rdma_start_port(cma_dev->device)];
  239. }
  240. int cma_set_default_gid_type(struct cma_device *cma_dev,
  241. u32 port,
  242. enum ib_gid_type default_gid_type)
  243. {
  244. unsigned long supported_gids;
  245. if (!rdma_is_port_valid(cma_dev->device, port))
  246. return -EINVAL;
  247. if (default_gid_type == IB_GID_TYPE_IB &&
  248. rdma_protocol_roce_eth_encap(cma_dev->device, port))
  249. default_gid_type = IB_GID_TYPE_ROCE;
  250. supported_gids = roce_gid_type_mask_support(cma_dev->device, port);
  251. if (!(supported_gids & 1 << default_gid_type))
  252. return -EINVAL;
  253. cma_dev->default_gid_type[port - rdma_start_port(cma_dev->device)] =
  254. default_gid_type;
  255. return 0;
  256. }
  257. int cma_get_default_roce_tos(struct cma_device *cma_dev, u32 port)
  258. {
  259. if (!rdma_is_port_valid(cma_dev->device, port))
  260. return -EINVAL;
  261. return cma_dev->default_roce_tos[port - rdma_start_port(cma_dev->device)];
  262. }
  263. int cma_set_default_roce_tos(struct cma_device *cma_dev, u32 port,
  264. u8 default_roce_tos)
  265. {
  266. if (!rdma_is_port_valid(cma_dev->device, port))
  267. return -EINVAL;
  268. cma_dev->default_roce_tos[port - rdma_start_port(cma_dev->device)] =
  269. default_roce_tos;
  270. return 0;
  271. }
  272. struct ib_device *cma_get_ib_dev(struct cma_device *cma_dev)
  273. {
  274. return cma_dev->device;
  275. }
  276. /*
  277. * Device removal can occur at anytime, so we need extra handling to
  278. * serialize notifying the user of device removal with other callbacks.
  279. * We do this by disabling removal notification while a callback is in process,
  280. * and reporting it after the callback completes.
  281. */
  282. struct cma_multicast {
  283. struct rdma_id_private *id_priv;
  284. union {
  285. struct ib_sa_multicast *sa_mc;
  286. struct {
  287. struct work_struct work;
  288. struct rdma_cm_event event;
  289. } iboe_join;
  290. };
  291. struct list_head list;
  292. void *context;
  293. struct sockaddr_storage addr;
  294. u8 join_state;
  295. };
  296. struct cma_work {
  297. struct work_struct work;
  298. struct rdma_id_private *id;
  299. enum rdma_cm_state old_state;
  300. enum rdma_cm_state new_state;
  301. struct rdma_cm_event event;
  302. };
  303. union cma_ip_addr {
  304. struct in6_addr ip6;
  305. struct {
  306. __be32 pad[3];
  307. __be32 addr;
  308. } ip4;
  309. };
  310. struct cma_hdr {
  311. u8 cma_version;
  312. u8 ip_version; /* IP version: 7:4 */
  313. __be16 port;
  314. union cma_ip_addr src_addr;
  315. union cma_ip_addr dst_addr;
  316. };
  317. #define CMA_VERSION 0x00
  318. struct cma_req_info {
  319. struct sockaddr_storage listen_addr_storage;
  320. struct sockaddr_storage src_addr_storage;
  321. struct ib_device *device;
  322. union ib_gid local_gid;
  323. __be64 service_id;
  324. int port;
  325. bool has_gid;
  326. u16 pkey;
  327. };
  328. static int cma_comp_exch(struct rdma_id_private *id_priv,
  329. enum rdma_cm_state comp, enum rdma_cm_state exch)
  330. {
  331. unsigned long flags;
  332. int ret;
  333. /*
  334. * The FSM uses a funny double locking where state is protected by both
  335. * the handler_mutex and the spinlock. State is not allowed to change
  336. * to/from a handler_mutex protected value without also holding
  337. * handler_mutex.
  338. */
  339. if (comp == RDMA_CM_CONNECT || exch == RDMA_CM_CONNECT)
  340. lockdep_assert_held(&id_priv->handler_mutex);
  341. spin_lock_irqsave(&id_priv->lock, flags);
  342. if ((ret = (id_priv->state == comp)))
  343. id_priv->state = exch;
  344. spin_unlock_irqrestore(&id_priv->lock, flags);
  345. return ret;
  346. }
  347. static inline u8 cma_get_ip_ver(const struct cma_hdr *hdr)
  348. {
  349. return hdr->ip_version >> 4;
  350. }
  351. static void cma_set_ip_ver(struct cma_hdr *hdr, u8 ip_ver)
  352. {
  353. hdr->ip_version = (ip_ver << 4) | (hdr->ip_version & 0xF);
  354. }
  355. static struct sockaddr *cma_src_addr(struct rdma_id_private *id_priv)
  356. {
  357. return (struct sockaddr *)&id_priv->id.route.addr.src_addr;
  358. }
  359. static inline struct sockaddr *cma_dst_addr(struct rdma_id_private *id_priv)
  360. {
  361. return (struct sockaddr *)&id_priv->id.route.addr.dst_addr;
  362. }
  363. static int cma_igmp_send(struct net_device *ndev, union ib_gid *mgid, bool join)
  364. {
  365. struct in_device *in_dev = NULL;
  366. if (ndev) {
  367. rtnl_lock();
  368. in_dev = __in_dev_get_rtnl(ndev);
  369. if (in_dev) {
  370. if (join)
  371. ip_mc_inc_group(in_dev,
  372. *(__be32 *)(mgid->raw + 12));
  373. else
  374. ip_mc_dec_group(in_dev,
  375. *(__be32 *)(mgid->raw + 12));
  376. }
  377. rtnl_unlock();
  378. }
  379. return (in_dev) ? 0 : -ENODEV;
  380. }
  381. static int compare_netdev_and_ip(int ifindex_a, struct sockaddr *sa,
  382. struct id_table_entry *entry_b)
  383. {
  384. struct rdma_id_private *id_priv = list_first_entry(
  385. &entry_b->id_list, struct rdma_id_private, id_list_entry);
  386. int ifindex_b = id_priv->id.route.addr.dev_addr.bound_dev_if;
  387. struct sockaddr *sb = cma_dst_addr(id_priv);
  388. if (ifindex_a != ifindex_b)
  389. return (ifindex_a > ifindex_b) ? 1 : -1;
  390. if (sa->sa_family != sb->sa_family)
  391. return sa->sa_family - sb->sa_family;
  392. if (sa->sa_family == AF_INET &&
  393. __builtin_object_size(sa, 0) >= sizeof(struct sockaddr_in)) {
  394. return memcmp(&((struct sockaddr_in *)sa)->sin_addr,
  395. &((struct sockaddr_in *)sb)->sin_addr,
  396. sizeof(((struct sockaddr_in *)sa)->sin_addr));
  397. }
  398. if (sa->sa_family == AF_INET6 &&
  399. __builtin_object_size(sa, 0) >= sizeof(struct sockaddr_in6)) {
  400. return ipv6_addr_cmp(&((struct sockaddr_in6 *)sa)->sin6_addr,
  401. &((struct sockaddr_in6 *)sb)->sin6_addr);
  402. }
  403. return -1;
  404. }
  405. static int cma_add_id_to_tree(struct rdma_id_private *node_id_priv)
  406. {
  407. struct rb_node **new, *parent = NULL;
  408. struct id_table_entry *this, *node;
  409. unsigned long flags;
  410. int result;
  411. node = kzalloc_obj(*node);
  412. if (!node)
  413. return -ENOMEM;
  414. spin_lock_irqsave(&id_table_lock, flags);
  415. new = &id_table.rb_node;
  416. while (*new) {
  417. this = container_of(*new, struct id_table_entry, rb_node);
  418. result = compare_netdev_and_ip(
  419. node_id_priv->id.route.addr.dev_addr.bound_dev_if,
  420. cma_dst_addr(node_id_priv), this);
  421. parent = *new;
  422. if (result < 0)
  423. new = &((*new)->rb_left);
  424. else if (result > 0)
  425. new = &((*new)->rb_right);
  426. else {
  427. list_add_tail(&node_id_priv->id_list_entry,
  428. &this->id_list);
  429. kfree(node);
  430. goto unlock;
  431. }
  432. }
  433. INIT_LIST_HEAD(&node->id_list);
  434. list_add_tail(&node_id_priv->id_list_entry, &node->id_list);
  435. rb_link_node(&node->rb_node, parent, new);
  436. rb_insert_color(&node->rb_node, &id_table);
  437. unlock:
  438. spin_unlock_irqrestore(&id_table_lock, flags);
  439. return 0;
  440. }
  441. static struct id_table_entry *
  442. node_from_ndev_ip(struct rb_root *root, int ifindex, struct sockaddr *sa)
  443. {
  444. struct rb_node *node = root->rb_node;
  445. struct id_table_entry *data;
  446. int result;
  447. while (node) {
  448. data = container_of(node, struct id_table_entry, rb_node);
  449. result = compare_netdev_and_ip(ifindex, sa, data);
  450. if (result < 0)
  451. node = node->rb_left;
  452. else if (result > 0)
  453. node = node->rb_right;
  454. else
  455. return data;
  456. }
  457. return NULL;
  458. }
  459. static void cma_remove_id_from_tree(struct rdma_id_private *id_priv)
  460. {
  461. struct id_table_entry *data;
  462. unsigned long flags;
  463. spin_lock_irqsave(&id_table_lock, flags);
  464. if (list_empty(&id_priv->id_list_entry))
  465. goto out;
  466. data = node_from_ndev_ip(&id_table,
  467. id_priv->id.route.addr.dev_addr.bound_dev_if,
  468. cma_dst_addr(id_priv));
  469. if (!data)
  470. goto out;
  471. list_del_init(&id_priv->id_list_entry);
  472. if (list_empty(&data->id_list)) {
  473. rb_erase(&data->rb_node, &id_table);
  474. kfree(data);
  475. }
  476. out:
  477. spin_unlock_irqrestore(&id_table_lock, flags);
  478. }
  479. static void _cma_attach_to_dev(struct rdma_id_private *id_priv,
  480. struct cma_device *cma_dev)
  481. {
  482. cma_dev_get(cma_dev);
  483. id_priv->cma_dev = cma_dev;
  484. id_priv->id.device = cma_dev->device;
  485. id_priv->id.route.addr.dev_addr.transport =
  486. rdma_node_get_transport(cma_dev->device->node_type);
  487. list_add_tail(&id_priv->device_item, &cma_dev->id_list);
  488. trace_cm_id_attach(id_priv, cma_dev->device);
  489. }
  490. static void cma_attach_to_dev(struct rdma_id_private *id_priv,
  491. struct cma_device *cma_dev)
  492. {
  493. _cma_attach_to_dev(id_priv, cma_dev);
  494. id_priv->gid_type =
  495. cma_dev->default_gid_type[id_priv->id.port_num -
  496. rdma_start_port(cma_dev->device)];
  497. }
  498. static void cma_release_dev(struct rdma_id_private *id_priv)
  499. {
  500. mutex_lock(&lock);
  501. list_del_init(&id_priv->device_item);
  502. cma_dev_put(id_priv->cma_dev);
  503. id_priv->cma_dev = NULL;
  504. id_priv->id.device = NULL;
  505. if (id_priv->id.route.addr.dev_addr.sgid_attr) {
  506. rdma_put_gid_attr(id_priv->id.route.addr.dev_addr.sgid_attr);
  507. id_priv->id.route.addr.dev_addr.sgid_attr = NULL;
  508. }
  509. mutex_unlock(&lock);
  510. }
  511. static inline unsigned short cma_family(struct rdma_id_private *id_priv)
  512. {
  513. return id_priv->id.route.addr.src_addr.ss_family;
  514. }
  515. static int cma_set_default_qkey(struct rdma_id_private *id_priv)
  516. {
  517. struct ib_sa_mcmember_rec rec;
  518. int ret = 0;
  519. switch (id_priv->id.ps) {
  520. case RDMA_PS_UDP:
  521. case RDMA_PS_IB:
  522. id_priv->qkey = RDMA_UDP_QKEY;
  523. break;
  524. case RDMA_PS_IPOIB:
  525. ib_addr_get_mgid(&id_priv->id.route.addr.dev_addr, &rec.mgid);
  526. ret = ib_sa_get_mcmember_rec(id_priv->id.device,
  527. id_priv->id.port_num, &rec.mgid,
  528. &rec);
  529. if (!ret)
  530. id_priv->qkey = be32_to_cpu(rec.qkey);
  531. break;
  532. default:
  533. break;
  534. }
  535. return ret;
  536. }
  537. static int cma_set_qkey(struct rdma_id_private *id_priv, u32 qkey)
  538. {
  539. if (!qkey ||
  540. (id_priv->qkey && (id_priv->qkey != qkey)))
  541. return -EINVAL;
  542. id_priv->qkey = qkey;
  543. return 0;
  544. }
  545. static void cma_translate_ib(struct sockaddr_ib *sib, struct rdma_dev_addr *dev_addr)
  546. {
  547. dev_addr->dev_type = ARPHRD_INFINIBAND;
  548. rdma_addr_set_sgid(dev_addr, (union ib_gid *) &sib->sib_addr);
  549. ib_addr_set_pkey(dev_addr, ntohs(sib->sib_pkey));
  550. }
  551. static int cma_translate_addr(struct sockaddr *addr, struct rdma_dev_addr *dev_addr)
  552. {
  553. int ret;
  554. if (addr->sa_family != AF_IB) {
  555. ret = rdma_translate_ip(addr, dev_addr);
  556. } else {
  557. cma_translate_ib((struct sockaddr_ib *) addr, dev_addr);
  558. ret = 0;
  559. }
  560. return ret;
  561. }
  562. static const struct ib_gid_attr *
  563. cma_validate_port(struct ib_device *device, u32 port,
  564. enum ib_gid_type gid_type,
  565. union ib_gid *gid,
  566. struct rdma_id_private *id_priv)
  567. {
  568. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  569. const struct ib_gid_attr *sgid_attr = ERR_PTR(-ENODEV);
  570. int bound_if_index = dev_addr->bound_dev_if;
  571. int dev_type = dev_addr->dev_type;
  572. struct net_device *ndev = NULL;
  573. struct net_device *pdev = NULL;
  574. if (!rdma_dev_access_netns(device, id_priv->id.route.addr.dev_addr.net))
  575. goto out;
  576. if ((dev_type == ARPHRD_INFINIBAND) && !rdma_protocol_ib(device, port))
  577. goto out;
  578. if ((dev_type != ARPHRD_INFINIBAND) && rdma_protocol_ib(device, port))
  579. goto out;
  580. /*
  581. * For drivers that do not associate more than one net device with
  582. * their gid tables, such as iWARP drivers, it is sufficient to
  583. * return the first table entry.
  584. *
  585. * Other driver classes might be included in the future.
  586. */
  587. if (rdma_protocol_iwarp(device, port)) {
  588. sgid_attr = rdma_get_gid_attr(device, port, 0);
  589. if (IS_ERR(sgid_attr))
  590. goto out;
  591. rcu_read_lock();
  592. ndev = rcu_dereference(sgid_attr->ndev);
  593. if (ndev->ifindex != bound_if_index) {
  594. pdev = dev_get_by_index_rcu(dev_addr->net, bound_if_index);
  595. if (pdev) {
  596. if (is_vlan_dev(pdev)) {
  597. pdev = vlan_dev_real_dev(pdev);
  598. if (ndev->ifindex == pdev->ifindex)
  599. bound_if_index = pdev->ifindex;
  600. }
  601. if (is_vlan_dev(ndev)) {
  602. pdev = vlan_dev_real_dev(ndev);
  603. if (bound_if_index == pdev->ifindex)
  604. bound_if_index = ndev->ifindex;
  605. }
  606. }
  607. }
  608. if (!net_eq(dev_net(ndev), dev_addr->net) ||
  609. ndev->ifindex != bound_if_index) {
  610. rdma_put_gid_attr(sgid_attr);
  611. sgid_attr = ERR_PTR(-ENODEV);
  612. }
  613. rcu_read_unlock();
  614. goto out;
  615. }
  616. /*
  617. * For a RXE device, it should work with TUN device and normal ethernet
  618. * devices. Use driver_id to check if a device is a RXE device or not.
  619. * ARPHDR_NONE means a TUN device.
  620. */
  621. if (device->ops.driver_id == RDMA_DRIVER_RXE) {
  622. if ((dev_type == ARPHRD_NONE || dev_type == ARPHRD_ETHER)
  623. && rdma_protocol_roce(device, port)) {
  624. ndev = dev_get_by_index(dev_addr->net, bound_if_index);
  625. if (!ndev)
  626. goto out;
  627. }
  628. } else {
  629. if (dev_type == ARPHRD_ETHER && rdma_protocol_roce(device, port)) {
  630. ndev = dev_get_by_index(dev_addr->net, bound_if_index);
  631. if (!ndev)
  632. goto out;
  633. } else {
  634. gid_type = IB_GID_TYPE_IB;
  635. }
  636. }
  637. sgid_attr = rdma_find_gid_by_port(device, gid, gid_type, port, ndev);
  638. dev_put(ndev);
  639. out:
  640. return sgid_attr;
  641. }
  642. static void cma_bind_sgid_attr(struct rdma_id_private *id_priv,
  643. const struct ib_gid_attr *sgid_attr)
  644. {
  645. WARN_ON(id_priv->id.route.addr.dev_addr.sgid_attr);
  646. id_priv->id.route.addr.dev_addr.sgid_attr = sgid_attr;
  647. }
  648. /**
  649. * cma_acquire_dev_by_src_ip - Acquire cma device, port, gid attribute
  650. * based on source ip address.
  651. * @id_priv: cm_id which should be bound to cma device
  652. *
  653. * cma_acquire_dev_by_src_ip() binds cm id to cma device, port and GID attribute
  654. * based on source IP address. It returns 0 on success or error code otherwise.
  655. * It is applicable to active and passive side cm_id.
  656. */
  657. static int cma_acquire_dev_by_src_ip(struct rdma_id_private *id_priv)
  658. {
  659. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  660. const struct ib_gid_attr *sgid_attr;
  661. union ib_gid gid, iboe_gid, *gidp;
  662. struct cma_device *cma_dev;
  663. enum ib_gid_type gid_type;
  664. int ret = -ENODEV;
  665. u32 port;
  666. if (dev_addr->dev_type != ARPHRD_INFINIBAND &&
  667. id_priv->id.ps == RDMA_PS_IPOIB)
  668. return -EINVAL;
  669. rdma_ip2gid((struct sockaddr *)&id_priv->id.route.addr.src_addr,
  670. &iboe_gid);
  671. memcpy(&gid, dev_addr->src_dev_addr +
  672. rdma_addr_gid_offset(dev_addr), sizeof(gid));
  673. mutex_lock(&lock);
  674. list_for_each_entry(cma_dev, &dev_list, list) {
  675. if (id_priv->restricted_node_type != RDMA_NODE_UNSPECIFIED &&
  676. id_priv->restricted_node_type != cma_dev->device->node_type)
  677. continue;
  678. rdma_for_each_port (cma_dev->device, port) {
  679. gidp = rdma_protocol_roce(cma_dev->device, port) ?
  680. &iboe_gid : &gid;
  681. gid_type = cma_dev->default_gid_type[port - 1];
  682. sgid_attr = cma_validate_port(cma_dev->device, port,
  683. gid_type, gidp, id_priv);
  684. if (!IS_ERR(sgid_attr)) {
  685. id_priv->id.port_num = port;
  686. cma_bind_sgid_attr(id_priv, sgid_attr);
  687. cma_attach_to_dev(id_priv, cma_dev);
  688. ret = 0;
  689. goto out;
  690. }
  691. }
  692. }
  693. out:
  694. mutex_unlock(&lock);
  695. return ret;
  696. }
  697. /**
  698. * cma_ib_acquire_dev - Acquire cma device, port and SGID attribute
  699. * @id_priv: cm id to bind to cma device
  700. * @listen_id_priv: listener cm id to match against
  701. * @req: Pointer to req structure containaining incoming
  702. * request information
  703. * cma_ib_acquire_dev() acquires cma device, port and SGID attribute when
  704. * rdma device matches for listen_id and incoming request. It also verifies
  705. * that a GID table entry is present for the source address.
  706. * Returns 0 on success, or returns error code otherwise.
  707. */
  708. static int cma_ib_acquire_dev(struct rdma_id_private *id_priv,
  709. const struct rdma_id_private *listen_id_priv,
  710. struct cma_req_info *req)
  711. {
  712. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  713. const struct ib_gid_attr *sgid_attr;
  714. enum ib_gid_type gid_type;
  715. union ib_gid gid;
  716. if (dev_addr->dev_type != ARPHRD_INFINIBAND &&
  717. id_priv->id.ps == RDMA_PS_IPOIB)
  718. return -EINVAL;
  719. if (rdma_protocol_roce(req->device, req->port))
  720. rdma_ip2gid((struct sockaddr *)&id_priv->id.route.addr.src_addr,
  721. &gid);
  722. else
  723. memcpy(&gid, dev_addr->src_dev_addr +
  724. rdma_addr_gid_offset(dev_addr), sizeof(gid));
  725. gid_type = listen_id_priv->cma_dev->default_gid_type[req->port - 1];
  726. sgid_attr = cma_validate_port(req->device, req->port,
  727. gid_type, &gid, id_priv);
  728. if (IS_ERR(sgid_attr))
  729. return PTR_ERR(sgid_attr);
  730. id_priv->id.port_num = req->port;
  731. cma_bind_sgid_attr(id_priv, sgid_attr);
  732. /* Need to acquire lock to protect against reader
  733. * of cma_dev->id_list such as cma_netdev_callback() and
  734. * cma_process_remove().
  735. */
  736. mutex_lock(&lock);
  737. cma_attach_to_dev(id_priv, listen_id_priv->cma_dev);
  738. mutex_unlock(&lock);
  739. rdma_restrack_add(&id_priv->res);
  740. return 0;
  741. }
  742. static int cma_iw_acquire_dev(struct rdma_id_private *id_priv,
  743. const struct rdma_id_private *listen_id_priv)
  744. {
  745. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  746. const struct ib_gid_attr *sgid_attr;
  747. struct cma_device *cma_dev;
  748. enum ib_gid_type gid_type;
  749. int ret = -ENODEV;
  750. union ib_gid gid;
  751. u32 port;
  752. if (dev_addr->dev_type != ARPHRD_INFINIBAND &&
  753. id_priv->id.ps == RDMA_PS_IPOIB)
  754. return -EINVAL;
  755. memcpy(&gid, dev_addr->src_dev_addr +
  756. rdma_addr_gid_offset(dev_addr), sizeof(gid));
  757. mutex_lock(&lock);
  758. cma_dev = listen_id_priv->cma_dev;
  759. port = listen_id_priv->id.port_num;
  760. gid_type = listen_id_priv->gid_type;
  761. sgid_attr = cma_validate_port(cma_dev->device, port,
  762. gid_type, &gid, id_priv);
  763. if (!IS_ERR(sgid_attr)) {
  764. id_priv->id.port_num = port;
  765. cma_bind_sgid_attr(id_priv, sgid_attr);
  766. ret = 0;
  767. goto out;
  768. }
  769. list_for_each_entry(cma_dev, &dev_list, list) {
  770. rdma_for_each_port (cma_dev->device, port) {
  771. if (listen_id_priv->cma_dev == cma_dev &&
  772. listen_id_priv->id.port_num == port)
  773. continue;
  774. gid_type = cma_dev->default_gid_type[port - 1];
  775. sgid_attr = cma_validate_port(cma_dev->device, port,
  776. gid_type, &gid, id_priv);
  777. if (!IS_ERR(sgid_attr)) {
  778. id_priv->id.port_num = port;
  779. cma_bind_sgid_attr(id_priv, sgid_attr);
  780. ret = 0;
  781. goto out;
  782. }
  783. }
  784. }
  785. out:
  786. if (!ret) {
  787. cma_attach_to_dev(id_priv, cma_dev);
  788. rdma_restrack_add(&id_priv->res);
  789. }
  790. mutex_unlock(&lock);
  791. return ret;
  792. }
  793. /*
  794. * Select the source IB device and address to reach the destination IB address.
  795. */
  796. static int cma_resolve_ib_dev(struct rdma_id_private *id_priv)
  797. {
  798. struct cma_device *cma_dev, *cur_dev;
  799. struct sockaddr_ib *addr;
  800. union ib_gid gid, sgid, *dgid;
  801. unsigned int p;
  802. u16 pkey, index;
  803. enum ib_port_state port_state;
  804. int ret;
  805. int i;
  806. cma_dev = NULL;
  807. addr = (struct sockaddr_ib *) cma_dst_addr(id_priv);
  808. dgid = (union ib_gid *) &addr->sib_addr;
  809. pkey = ntohs(addr->sib_pkey);
  810. mutex_lock(&lock);
  811. list_for_each_entry(cur_dev, &dev_list, list) {
  812. rdma_for_each_port (cur_dev->device, p) {
  813. if (!rdma_cap_af_ib(cur_dev->device, p))
  814. continue;
  815. if (ib_find_cached_pkey(cur_dev->device, p, pkey, &index))
  816. continue;
  817. if (ib_get_cached_port_state(cur_dev->device, p, &port_state))
  818. continue;
  819. for (i = 0; i < cur_dev->device->port_data[p].immutable.gid_tbl_len;
  820. ++i) {
  821. ret = rdma_query_gid(cur_dev->device, p, i,
  822. &gid);
  823. if (ret)
  824. continue;
  825. if (!memcmp(&gid, dgid, sizeof(gid))) {
  826. cma_dev = cur_dev;
  827. sgid = gid;
  828. id_priv->id.port_num = p;
  829. goto found;
  830. }
  831. if (!cma_dev && (gid.global.subnet_prefix ==
  832. dgid->global.subnet_prefix) &&
  833. port_state == IB_PORT_ACTIVE) {
  834. cma_dev = cur_dev;
  835. sgid = gid;
  836. id_priv->id.port_num = p;
  837. goto found;
  838. }
  839. }
  840. }
  841. }
  842. mutex_unlock(&lock);
  843. return -ENODEV;
  844. found:
  845. cma_attach_to_dev(id_priv, cma_dev);
  846. rdma_restrack_add(&id_priv->res);
  847. mutex_unlock(&lock);
  848. addr = (struct sockaddr_ib *)cma_src_addr(id_priv);
  849. memcpy(&addr->sib_addr, &sgid, sizeof(sgid));
  850. cma_translate_ib(addr, &id_priv->id.route.addr.dev_addr);
  851. return 0;
  852. }
  853. static void cma_id_get(struct rdma_id_private *id_priv)
  854. {
  855. refcount_inc(&id_priv->refcount);
  856. }
  857. static void cma_id_put(struct rdma_id_private *id_priv)
  858. {
  859. if (refcount_dec_and_test(&id_priv->refcount))
  860. complete(&id_priv->comp);
  861. }
  862. static struct rdma_id_private *
  863. __rdma_create_id(struct net *net, rdma_cm_event_handler event_handler,
  864. void *context, enum rdma_ucm_port_space ps,
  865. enum ib_qp_type qp_type, const struct rdma_id_private *parent)
  866. {
  867. struct rdma_id_private *id_priv;
  868. id_priv = kzalloc_obj(*id_priv);
  869. if (!id_priv)
  870. return ERR_PTR(-ENOMEM);
  871. id_priv->state = RDMA_CM_IDLE;
  872. id_priv->restricted_node_type = RDMA_NODE_UNSPECIFIED;
  873. id_priv->id.context = context;
  874. id_priv->id.event_handler = event_handler;
  875. id_priv->id.ps = ps;
  876. id_priv->id.qp_type = qp_type;
  877. id_priv->tos_set = false;
  878. id_priv->timeout_set = false;
  879. id_priv->min_rnr_timer_set = false;
  880. id_priv->gid_type = IB_GID_TYPE_IB;
  881. spin_lock_init(&id_priv->lock);
  882. mutex_init(&id_priv->qp_mutex);
  883. init_completion(&id_priv->comp);
  884. refcount_set(&id_priv->refcount, 1);
  885. mutex_init(&id_priv->handler_mutex);
  886. INIT_LIST_HEAD(&id_priv->device_item);
  887. INIT_LIST_HEAD(&id_priv->id_list_entry);
  888. INIT_LIST_HEAD(&id_priv->listen_list);
  889. INIT_LIST_HEAD(&id_priv->mc_list);
  890. get_random_bytes(&id_priv->seq_num, sizeof id_priv->seq_num);
  891. id_priv->id.route.addr.dev_addr.net = get_net(net);
  892. id_priv->seq_num &= 0x00ffffff;
  893. INIT_WORK(&id_priv->id.net_work, cma_netevent_work_handler);
  894. rdma_restrack_new(&id_priv->res, RDMA_RESTRACK_CM_ID);
  895. if (parent)
  896. rdma_restrack_parent_name(&id_priv->res, &parent->res);
  897. return id_priv;
  898. }
  899. struct rdma_cm_id *
  900. __rdma_create_kernel_id(struct net *net, rdma_cm_event_handler event_handler,
  901. void *context, enum rdma_ucm_port_space ps,
  902. enum ib_qp_type qp_type, const char *caller)
  903. {
  904. struct rdma_id_private *ret;
  905. ret = __rdma_create_id(net, event_handler, context, ps, qp_type, NULL);
  906. if (IS_ERR(ret))
  907. return ERR_CAST(ret);
  908. rdma_restrack_set_name(&ret->res, caller);
  909. return &ret->id;
  910. }
  911. EXPORT_SYMBOL(__rdma_create_kernel_id);
  912. struct rdma_cm_id *rdma_create_user_id(rdma_cm_event_handler event_handler,
  913. void *context,
  914. enum rdma_ucm_port_space ps,
  915. enum ib_qp_type qp_type)
  916. {
  917. struct rdma_id_private *ret;
  918. ret = __rdma_create_id(current->nsproxy->net_ns, event_handler, context,
  919. ps, qp_type, NULL);
  920. if (IS_ERR(ret))
  921. return ERR_CAST(ret);
  922. rdma_restrack_set_name(&ret->res, NULL);
  923. return &ret->id;
  924. }
  925. EXPORT_SYMBOL(rdma_create_user_id);
  926. static int cma_init_ud_qp(struct rdma_id_private *id_priv, struct ib_qp *qp)
  927. {
  928. struct ib_qp_attr qp_attr;
  929. int qp_attr_mask, ret;
  930. qp_attr.qp_state = IB_QPS_INIT;
  931. ret = rdma_init_qp_attr(&id_priv->id, &qp_attr, &qp_attr_mask);
  932. if (ret)
  933. return ret;
  934. ret = ib_modify_qp(qp, &qp_attr, qp_attr_mask);
  935. if (ret)
  936. return ret;
  937. qp_attr.qp_state = IB_QPS_RTR;
  938. ret = ib_modify_qp(qp, &qp_attr, IB_QP_STATE);
  939. if (ret)
  940. return ret;
  941. qp_attr.qp_state = IB_QPS_RTS;
  942. qp_attr.sq_psn = 0;
  943. ret = ib_modify_qp(qp, &qp_attr, IB_QP_STATE | IB_QP_SQ_PSN);
  944. return ret;
  945. }
  946. static int cma_init_conn_qp(struct rdma_id_private *id_priv, struct ib_qp *qp)
  947. {
  948. struct ib_qp_attr qp_attr;
  949. int qp_attr_mask, ret;
  950. qp_attr.qp_state = IB_QPS_INIT;
  951. ret = rdma_init_qp_attr(&id_priv->id, &qp_attr, &qp_attr_mask);
  952. if (ret)
  953. return ret;
  954. return ib_modify_qp(qp, &qp_attr, qp_attr_mask);
  955. }
  956. int rdma_create_qp(struct rdma_cm_id *id, struct ib_pd *pd,
  957. struct ib_qp_init_attr *qp_init_attr)
  958. {
  959. struct rdma_id_private *id_priv;
  960. struct ib_qp *qp;
  961. int ret;
  962. id_priv = container_of(id, struct rdma_id_private, id);
  963. if (id->device != pd->device) {
  964. ret = -EINVAL;
  965. goto out_err;
  966. }
  967. qp_init_attr->port_num = id->port_num;
  968. qp = ib_create_qp(pd, qp_init_attr);
  969. if (IS_ERR(qp)) {
  970. ret = PTR_ERR(qp);
  971. goto out_err;
  972. }
  973. if (id->qp_type == IB_QPT_UD)
  974. ret = cma_init_ud_qp(id_priv, qp);
  975. else
  976. ret = cma_init_conn_qp(id_priv, qp);
  977. if (ret)
  978. goto out_destroy;
  979. id->qp = qp;
  980. id_priv->qp_num = qp->qp_num;
  981. id_priv->srq = (qp->srq != NULL);
  982. trace_cm_qp_create(id_priv, pd, qp_init_attr, 0);
  983. return 0;
  984. out_destroy:
  985. ib_destroy_qp(qp);
  986. out_err:
  987. trace_cm_qp_create(id_priv, pd, qp_init_attr, ret);
  988. return ret;
  989. }
  990. EXPORT_SYMBOL(rdma_create_qp);
  991. void rdma_destroy_qp(struct rdma_cm_id *id)
  992. {
  993. struct rdma_id_private *id_priv;
  994. id_priv = container_of(id, struct rdma_id_private, id);
  995. trace_cm_qp_destroy(id_priv);
  996. mutex_lock(&id_priv->qp_mutex);
  997. ib_destroy_qp(id_priv->id.qp);
  998. id_priv->id.qp = NULL;
  999. mutex_unlock(&id_priv->qp_mutex);
  1000. }
  1001. EXPORT_SYMBOL(rdma_destroy_qp);
  1002. static int cma_modify_qp_rtr(struct rdma_id_private *id_priv,
  1003. struct rdma_conn_param *conn_param)
  1004. {
  1005. struct ib_qp_attr qp_attr;
  1006. int qp_attr_mask, ret;
  1007. mutex_lock(&id_priv->qp_mutex);
  1008. if (!id_priv->id.qp) {
  1009. ret = 0;
  1010. goto out;
  1011. }
  1012. /* Need to update QP attributes from default values. */
  1013. qp_attr.qp_state = IB_QPS_INIT;
  1014. ret = rdma_init_qp_attr(&id_priv->id, &qp_attr, &qp_attr_mask);
  1015. if (ret)
  1016. goto out;
  1017. ret = ib_modify_qp(id_priv->id.qp, &qp_attr, qp_attr_mask);
  1018. if (ret)
  1019. goto out;
  1020. qp_attr.qp_state = IB_QPS_RTR;
  1021. ret = rdma_init_qp_attr(&id_priv->id, &qp_attr, &qp_attr_mask);
  1022. if (ret)
  1023. goto out;
  1024. BUG_ON(id_priv->cma_dev->device != id_priv->id.device);
  1025. if (conn_param)
  1026. qp_attr.max_dest_rd_atomic = conn_param->responder_resources;
  1027. ret = ib_modify_qp(id_priv->id.qp, &qp_attr, qp_attr_mask);
  1028. out:
  1029. mutex_unlock(&id_priv->qp_mutex);
  1030. return ret;
  1031. }
  1032. static int cma_modify_qp_rts(struct rdma_id_private *id_priv,
  1033. struct rdma_conn_param *conn_param)
  1034. {
  1035. struct ib_qp_attr qp_attr;
  1036. int qp_attr_mask, ret;
  1037. mutex_lock(&id_priv->qp_mutex);
  1038. if (!id_priv->id.qp) {
  1039. ret = 0;
  1040. goto out;
  1041. }
  1042. qp_attr.qp_state = IB_QPS_RTS;
  1043. ret = rdma_init_qp_attr(&id_priv->id, &qp_attr, &qp_attr_mask);
  1044. if (ret)
  1045. goto out;
  1046. if (conn_param)
  1047. qp_attr.max_rd_atomic = conn_param->initiator_depth;
  1048. ret = ib_modify_qp(id_priv->id.qp, &qp_attr, qp_attr_mask);
  1049. out:
  1050. mutex_unlock(&id_priv->qp_mutex);
  1051. return ret;
  1052. }
  1053. static int cma_modify_qp_err(struct rdma_id_private *id_priv)
  1054. {
  1055. struct ib_qp_attr qp_attr;
  1056. int ret;
  1057. mutex_lock(&id_priv->qp_mutex);
  1058. if (!id_priv->id.qp) {
  1059. ret = 0;
  1060. goto out;
  1061. }
  1062. qp_attr.qp_state = IB_QPS_ERR;
  1063. ret = ib_modify_qp(id_priv->id.qp, &qp_attr, IB_QP_STATE);
  1064. out:
  1065. mutex_unlock(&id_priv->qp_mutex);
  1066. return ret;
  1067. }
  1068. static int cma_ib_init_qp_attr(struct rdma_id_private *id_priv,
  1069. struct ib_qp_attr *qp_attr, int *qp_attr_mask)
  1070. {
  1071. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  1072. int ret;
  1073. u16 pkey;
  1074. if (rdma_cap_eth_ah(id_priv->id.device, id_priv->id.port_num))
  1075. pkey = 0xffff;
  1076. else
  1077. pkey = ib_addr_get_pkey(dev_addr);
  1078. ret = ib_find_cached_pkey(id_priv->id.device, id_priv->id.port_num,
  1079. pkey, &qp_attr->pkey_index);
  1080. if (ret)
  1081. return ret;
  1082. qp_attr->port_num = id_priv->id.port_num;
  1083. *qp_attr_mask = IB_QP_STATE | IB_QP_PKEY_INDEX | IB_QP_PORT;
  1084. if (id_priv->id.qp_type == IB_QPT_UD) {
  1085. ret = cma_set_default_qkey(id_priv);
  1086. if (ret)
  1087. return ret;
  1088. qp_attr->qkey = id_priv->qkey;
  1089. *qp_attr_mask |= IB_QP_QKEY;
  1090. } else {
  1091. qp_attr->qp_access_flags = 0;
  1092. *qp_attr_mask |= IB_QP_ACCESS_FLAGS;
  1093. }
  1094. return 0;
  1095. }
  1096. int rdma_init_qp_attr(struct rdma_cm_id *id, struct ib_qp_attr *qp_attr,
  1097. int *qp_attr_mask)
  1098. {
  1099. struct rdma_id_private *id_priv;
  1100. int ret = 0;
  1101. id_priv = container_of(id, struct rdma_id_private, id);
  1102. if (rdma_cap_ib_cm(id->device, id->port_num)) {
  1103. if (!id_priv->cm_id.ib || (id_priv->id.qp_type == IB_QPT_UD))
  1104. ret = cma_ib_init_qp_attr(id_priv, qp_attr, qp_attr_mask);
  1105. else
  1106. ret = ib_cm_init_qp_attr(id_priv->cm_id.ib, qp_attr,
  1107. qp_attr_mask);
  1108. if (qp_attr->qp_state == IB_QPS_RTR)
  1109. qp_attr->rq_psn = id_priv->seq_num;
  1110. } else if (rdma_cap_iw_cm(id->device, id->port_num)) {
  1111. if (!id_priv->cm_id.iw) {
  1112. qp_attr->qp_access_flags = 0;
  1113. *qp_attr_mask = IB_QP_STATE | IB_QP_ACCESS_FLAGS;
  1114. } else
  1115. ret = iw_cm_init_qp_attr(id_priv->cm_id.iw, qp_attr,
  1116. qp_attr_mask);
  1117. qp_attr->port_num = id_priv->id.port_num;
  1118. *qp_attr_mask |= IB_QP_PORT;
  1119. } else {
  1120. ret = -ENOSYS;
  1121. }
  1122. if ((*qp_attr_mask & IB_QP_TIMEOUT) && id_priv->timeout_set)
  1123. qp_attr->timeout = id_priv->timeout;
  1124. if ((*qp_attr_mask & IB_QP_MIN_RNR_TIMER) && id_priv->min_rnr_timer_set)
  1125. qp_attr->min_rnr_timer = id_priv->min_rnr_timer;
  1126. return ret;
  1127. }
  1128. EXPORT_SYMBOL(rdma_init_qp_attr);
  1129. static inline bool cma_zero_addr(const struct sockaddr *addr)
  1130. {
  1131. switch (addr->sa_family) {
  1132. case AF_INET:
  1133. return ipv4_is_zeronet(((struct sockaddr_in *)addr)->sin_addr.s_addr);
  1134. case AF_INET6:
  1135. return ipv6_addr_any(&((struct sockaddr_in6 *)addr)->sin6_addr);
  1136. case AF_IB:
  1137. return ib_addr_any(&((struct sockaddr_ib *)addr)->sib_addr);
  1138. default:
  1139. return false;
  1140. }
  1141. }
  1142. static inline bool cma_loopback_addr(const struct sockaddr *addr)
  1143. {
  1144. switch (addr->sa_family) {
  1145. case AF_INET:
  1146. return ipv4_is_loopback(
  1147. ((struct sockaddr_in *)addr)->sin_addr.s_addr);
  1148. case AF_INET6:
  1149. return ipv6_addr_loopback(
  1150. &((struct sockaddr_in6 *)addr)->sin6_addr);
  1151. case AF_IB:
  1152. return ib_addr_loopback(
  1153. &((struct sockaddr_ib *)addr)->sib_addr);
  1154. default:
  1155. return false;
  1156. }
  1157. }
  1158. static inline bool cma_any_addr(const struct sockaddr *addr)
  1159. {
  1160. return cma_zero_addr(addr) || cma_loopback_addr(addr);
  1161. }
  1162. static int cma_addr_cmp(const struct sockaddr *src, const struct sockaddr *dst)
  1163. {
  1164. if (src->sa_family != dst->sa_family)
  1165. return -1;
  1166. switch (src->sa_family) {
  1167. case AF_INET:
  1168. return ((struct sockaddr_in *)src)->sin_addr.s_addr !=
  1169. ((struct sockaddr_in *)dst)->sin_addr.s_addr;
  1170. case AF_INET6: {
  1171. struct sockaddr_in6 *src_addr6 = (struct sockaddr_in6 *)src;
  1172. struct sockaddr_in6 *dst_addr6 = (struct sockaddr_in6 *)dst;
  1173. bool link_local;
  1174. if (ipv6_addr_cmp(&src_addr6->sin6_addr,
  1175. &dst_addr6->sin6_addr))
  1176. return 1;
  1177. link_local = ipv6_addr_type(&dst_addr6->sin6_addr) &
  1178. IPV6_ADDR_LINKLOCAL;
  1179. /* Link local must match their scope_ids */
  1180. return link_local ? (src_addr6->sin6_scope_id !=
  1181. dst_addr6->sin6_scope_id) :
  1182. 0;
  1183. }
  1184. default:
  1185. return ib_addr_cmp(&((struct sockaddr_ib *) src)->sib_addr,
  1186. &((struct sockaddr_ib *) dst)->sib_addr);
  1187. }
  1188. }
  1189. static __be16 cma_port(const struct sockaddr *addr)
  1190. {
  1191. struct sockaddr_ib *sib;
  1192. switch (addr->sa_family) {
  1193. case AF_INET:
  1194. return ((struct sockaddr_in *) addr)->sin_port;
  1195. case AF_INET6:
  1196. return ((struct sockaddr_in6 *) addr)->sin6_port;
  1197. case AF_IB:
  1198. sib = (struct sockaddr_ib *) addr;
  1199. return htons((u16) (be64_to_cpu(sib->sib_sid) &
  1200. be64_to_cpu(sib->sib_sid_mask)));
  1201. default:
  1202. return 0;
  1203. }
  1204. }
  1205. static inline int cma_any_port(const struct sockaddr *addr)
  1206. {
  1207. return !cma_port(addr);
  1208. }
  1209. static void cma_save_ib_info(struct sockaddr *src_addr,
  1210. struct sockaddr *dst_addr,
  1211. const struct rdma_cm_id *listen_id,
  1212. const struct sa_path_rec *path)
  1213. {
  1214. struct sockaddr_ib *listen_ib, *ib;
  1215. listen_ib = (struct sockaddr_ib *) &listen_id->route.addr.src_addr;
  1216. if (src_addr) {
  1217. ib = (struct sockaddr_ib *)src_addr;
  1218. ib->sib_family = AF_IB;
  1219. if (path) {
  1220. ib->sib_pkey = path->pkey;
  1221. ib->sib_flowinfo = path->flow_label;
  1222. memcpy(&ib->sib_addr, &path->sgid, 16);
  1223. ib->sib_sid = path->service_id;
  1224. ib->sib_scope_id = 0;
  1225. } else {
  1226. ib->sib_pkey = listen_ib->sib_pkey;
  1227. ib->sib_flowinfo = listen_ib->sib_flowinfo;
  1228. ib->sib_addr = listen_ib->sib_addr;
  1229. ib->sib_sid = listen_ib->sib_sid;
  1230. ib->sib_scope_id = listen_ib->sib_scope_id;
  1231. }
  1232. ib->sib_sid_mask = cpu_to_be64(0xffffffffffffffffULL);
  1233. }
  1234. if (dst_addr) {
  1235. ib = (struct sockaddr_ib *)dst_addr;
  1236. ib->sib_family = AF_IB;
  1237. if (path) {
  1238. ib->sib_pkey = path->pkey;
  1239. ib->sib_flowinfo = path->flow_label;
  1240. memcpy(&ib->sib_addr, &path->dgid, 16);
  1241. }
  1242. }
  1243. }
  1244. static void cma_save_ip4_info(struct sockaddr_in *src_addr,
  1245. struct sockaddr_in *dst_addr,
  1246. struct cma_hdr *hdr,
  1247. __be16 local_port)
  1248. {
  1249. if (src_addr) {
  1250. *src_addr = (struct sockaddr_in) {
  1251. .sin_family = AF_INET,
  1252. .sin_addr.s_addr = hdr->dst_addr.ip4.addr,
  1253. .sin_port = local_port,
  1254. };
  1255. }
  1256. if (dst_addr) {
  1257. *dst_addr = (struct sockaddr_in) {
  1258. .sin_family = AF_INET,
  1259. .sin_addr.s_addr = hdr->src_addr.ip4.addr,
  1260. .sin_port = hdr->port,
  1261. };
  1262. }
  1263. }
  1264. static void cma_save_ip6_info(struct sockaddr_in6 *src_addr,
  1265. struct sockaddr_in6 *dst_addr,
  1266. struct cma_hdr *hdr,
  1267. __be16 local_port)
  1268. {
  1269. if (src_addr) {
  1270. *src_addr = (struct sockaddr_in6) {
  1271. .sin6_family = AF_INET6,
  1272. .sin6_addr = hdr->dst_addr.ip6,
  1273. .sin6_port = local_port,
  1274. };
  1275. }
  1276. if (dst_addr) {
  1277. *dst_addr = (struct sockaddr_in6) {
  1278. .sin6_family = AF_INET6,
  1279. .sin6_addr = hdr->src_addr.ip6,
  1280. .sin6_port = hdr->port,
  1281. };
  1282. }
  1283. }
  1284. static u16 cma_port_from_service_id(__be64 service_id)
  1285. {
  1286. return (u16)be64_to_cpu(service_id);
  1287. }
  1288. static int cma_save_ip_info(struct sockaddr *src_addr,
  1289. struct sockaddr *dst_addr,
  1290. const struct ib_cm_event *ib_event,
  1291. __be64 service_id)
  1292. {
  1293. struct cma_hdr *hdr;
  1294. __be16 port;
  1295. hdr = ib_event->private_data;
  1296. if (hdr->cma_version != CMA_VERSION)
  1297. return -EINVAL;
  1298. port = htons(cma_port_from_service_id(service_id));
  1299. switch (cma_get_ip_ver(hdr)) {
  1300. case 4:
  1301. cma_save_ip4_info((struct sockaddr_in *)src_addr,
  1302. (struct sockaddr_in *)dst_addr, hdr, port);
  1303. break;
  1304. case 6:
  1305. cma_save_ip6_info((struct sockaddr_in6 *)src_addr,
  1306. (struct sockaddr_in6 *)dst_addr, hdr, port);
  1307. break;
  1308. default:
  1309. return -EAFNOSUPPORT;
  1310. }
  1311. return 0;
  1312. }
  1313. static int cma_save_net_info(struct sockaddr *src_addr,
  1314. struct sockaddr *dst_addr,
  1315. const struct rdma_cm_id *listen_id,
  1316. const struct ib_cm_event *ib_event,
  1317. sa_family_t sa_family, __be64 service_id)
  1318. {
  1319. if (sa_family == AF_IB) {
  1320. if (ib_event->event == IB_CM_REQ_RECEIVED)
  1321. cma_save_ib_info(src_addr, dst_addr, listen_id,
  1322. ib_event->param.req_rcvd.primary_path);
  1323. else if (ib_event->event == IB_CM_SIDR_REQ_RECEIVED)
  1324. cma_save_ib_info(src_addr, dst_addr, listen_id, NULL);
  1325. return 0;
  1326. }
  1327. return cma_save_ip_info(src_addr, dst_addr, ib_event, service_id);
  1328. }
  1329. static int cma_save_req_info(const struct ib_cm_event *ib_event,
  1330. struct cma_req_info *req)
  1331. {
  1332. const struct ib_cm_req_event_param *req_param =
  1333. &ib_event->param.req_rcvd;
  1334. const struct ib_cm_sidr_req_event_param *sidr_param =
  1335. &ib_event->param.sidr_req_rcvd;
  1336. switch (ib_event->event) {
  1337. case IB_CM_REQ_RECEIVED:
  1338. req->device = req_param->listen_id->device;
  1339. req->port = req_param->port;
  1340. memcpy(&req->local_gid, &req_param->primary_path->sgid,
  1341. sizeof(req->local_gid));
  1342. req->has_gid = true;
  1343. req->service_id = req_param->primary_path->service_id;
  1344. req->pkey = be16_to_cpu(req_param->primary_path->pkey);
  1345. if (req->pkey != req_param->bth_pkey)
  1346. pr_warn_ratelimited("RDMA CMA: got different BTH P_Key (0x%x) and primary path P_Key (0x%x)\n"
  1347. "RDMA CMA: in the future this may cause the request to be dropped\n",
  1348. req_param->bth_pkey, req->pkey);
  1349. break;
  1350. case IB_CM_SIDR_REQ_RECEIVED:
  1351. req->device = sidr_param->listen_id->device;
  1352. req->port = sidr_param->port;
  1353. req->has_gid = false;
  1354. req->service_id = sidr_param->service_id;
  1355. req->pkey = sidr_param->pkey;
  1356. if (req->pkey != sidr_param->bth_pkey)
  1357. pr_warn_ratelimited("RDMA CMA: got different BTH P_Key (0x%x) and SIDR request payload P_Key (0x%x)\n"
  1358. "RDMA CMA: in the future this may cause the request to be dropped\n",
  1359. sidr_param->bth_pkey, req->pkey);
  1360. break;
  1361. default:
  1362. return -EINVAL;
  1363. }
  1364. return 0;
  1365. }
  1366. static bool validate_ipv4_net_dev(struct net_device *net_dev,
  1367. const struct sockaddr_in *dst_addr,
  1368. const struct sockaddr_in *src_addr)
  1369. {
  1370. __be32 daddr = dst_addr->sin_addr.s_addr,
  1371. saddr = src_addr->sin_addr.s_addr;
  1372. struct fib_result res;
  1373. struct flowi4 fl4;
  1374. int err;
  1375. bool ret;
  1376. if (ipv4_is_multicast(saddr) || ipv4_is_lbcast(saddr) ||
  1377. ipv4_is_lbcast(daddr) || ipv4_is_zeronet(saddr) ||
  1378. ipv4_is_zeronet(daddr) || ipv4_is_loopback(daddr) ||
  1379. ipv4_is_loopback(saddr))
  1380. return false;
  1381. memset(&fl4, 0, sizeof(fl4));
  1382. fl4.flowi4_oif = net_dev->ifindex;
  1383. fl4.daddr = daddr;
  1384. fl4.saddr = saddr;
  1385. rcu_read_lock();
  1386. err = fib_lookup(dev_net(net_dev), &fl4, &res, 0);
  1387. ret = err == 0 && FIB_RES_DEV(res) == net_dev;
  1388. rcu_read_unlock();
  1389. return ret;
  1390. }
  1391. static bool validate_ipv6_net_dev(struct net_device *net_dev,
  1392. const struct sockaddr_in6 *dst_addr,
  1393. const struct sockaddr_in6 *src_addr)
  1394. {
  1395. #if IS_ENABLED(CONFIG_IPV6)
  1396. const int strict = ipv6_addr_type(&dst_addr->sin6_addr) &
  1397. IPV6_ADDR_LINKLOCAL;
  1398. struct rt6_info *rt = rt6_lookup(dev_net(net_dev), &dst_addr->sin6_addr,
  1399. &src_addr->sin6_addr, net_dev->ifindex,
  1400. NULL, strict);
  1401. bool ret;
  1402. if (!rt)
  1403. return false;
  1404. ret = rt->rt6i_idev->dev == net_dev;
  1405. ip6_rt_put(rt);
  1406. return ret;
  1407. #else
  1408. return false;
  1409. #endif
  1410. }
  1411. static bool validate_net_dev(struct net_device *net_dev,
  1412. const struct sockaddr *daddr,
  1413. const struct sockaddr *saddr)
  1414. {
  1415. const struct sockaddr_in *daddr4 = (const struct sockaddr_in *)daddr;
  1416. const struct sockaddr_in *saddr4 = (const struct sockaddr_in *)saddr;
  1417. const struct sockaddr_in6 *daddr6 = (const struct sockaddr_in6 *)daddr;
  1418. const struct sockaddr_in6 *saddr6 = (const struct sockaddr_in6 *)saddr;
  1419. switch (daddr->sa_family) {
  1420. case AF_INET:
  1421. return saddr->sa_family == AF_INET &&
  1422. validate_ipv4_net_dev(net_dev, daddr4, saddr4);
  1423. case AF_INET6:
  1424. return saddr->sa_family == AF_INET6 &&
  1425. validate_ipv6_net_dev(net_dev, daddr6, saddr6);
  1426. default:
  1427. return false;
  1428. }
  1429. }
  1430. static struct net_device *
  1431. roce_get_net_dev_by_cm_event(const struct ib_cm_event *ib_event)
  1432. {
  1433. const struct ib_gid_attr *sgid_attr = NULL;
  1434. struct net_device *ndev;
  1435. if (ib_event->event == IB_CM_REQ_RECEIVED)
  1436. sgid_attr = ib_event->param.req_rcvd.ppath_sgid_attr;
  1437. else if (ib_event->event == IB_CM_SIDR_REQ_RECEIVED)
  1438. sgid_attr = ib_event->param.sidr_req_rcvd.sgid_attr;
  1439. if (!sgid_attr)
  1440. return NULL;
  1441. rcu_read_lock();
  1442. ndev = rdma_read_gid_attr_ndev_rcu(sgid_attr);
  1443. if (IS_ERR(ndev))
  1444. ndev = NULL;
  1445. else
  1446. dev_hold(ndev);
  1447. rcu_read_unlock();
  1448. return ndev;
  1449. }
  1450. static struct net_device *cma_get_net_dev(const struct ib_cm_event *ib_event,
  1451. struct cma_req_info *req)
  1452. {
  1453. struct sockaddr *listen_addr =
  1454. (struct sockaddr *)&req->listen_addr_storage;
  1455. struct sockaddr *src_addr = (struct sockaddr *)&req->src_addr_storage;
  1456. struct net_device *net_dev;
  1457. const union ib_gid *gid = req->has_gid ? &req->local_gid : NULL;
  1458. int err;
  1459. err = cma_save_ip_info(listen_addr, src_addr, ib_event,
  1460. req->service_id);
  1461. if (err)
  1462. return ERR_PTR(err);
  1463. if (rdma_protocol_roce(req->device, req->port))
  1464. net_dev = roce_get_net_dev_by_cm_event(ib_event);
  1465. else
  1466. net_dev = ib_get_net_dev_by_params(req->device, req->port,
  1467. req->pkey,
  1468. gid, listen_addr);
  1469. if (!net_dev)
  1470. return ERR_PTR(-ENODEV);
  1471. return net_dev;
  1472. }
  1473. static enum rdma_ucm_port_space rdma_ps_from_service_id(__be64 service_id)
  1474. {
  1475. return (be64_to_cpu(service_id) >> 16) & 0xffff;
  1476. }
  1477. static bool cma_match_private_data(struct rdma_id_private *id_priv,
  1478. const struct cma_hdr *hdr)
  1479. {
  1480. struct sockaddr *addr = cma_src_addr(id_priv);
  1481. __be32 ip4_addr;
  1482. struct in6_addr ip6_addr;
  1483. if (cma_any_addr(addr) && !id_priv->afonly)
  1484. return true;
  1485. switch (addr->sa_family) {
  1486. case AF_INET:
  1487. ip4_addr = ((struct sockaddr_in *)addr)->sin_addr.s_addr;
  1488. if (cma_get_ip_ver(hdr) != 4)
  1489. return false;
  1490. if (!cma_any_addr(addr) &&
  1491. hdr->dst_addr.ip4.addr != ip4_addr)
  1492. return false;
  1493. break;
  1494. case AF_INET6:
  1495. ip6_addr = ((struct sockaddr_in6 *)addr)->sin6_addr;
  1496. if (cma_get_ip_ver(hdr) != 6)
  1497. return false;
  1498. if (!cma_any_addr(addr) &&
  1499. memcmp(&hdr->dst_addr.ip6, &ip6_addr, sizeof(ip6_addr)))
  1500. return false;
  1501. break;
  1502. case AF_IB:
  1503. return true;
  1504. default:
  1505. return false;
  1506. }
  1507. return true;
  1508. }
  1509. static bool cma_protocol_roce(const struct rdma_cm_id *id)
  1510. {
  1511. struct ib_device *device = id->device;
  1512. const u32 port_num = id->port_num ?: rdma_start_port(device);
  1513. return rdma_protocol_roce(device, port_num);
  1514. }
  1515. static bool cma_is_req_ipv6_ll(const struct cma_req_info *req)
  1516. {
  1517. const struct sockaddr *daddr =
  1518. (const struct sockaddr *)&req->listen_addr_storage;
  1519. const struct sockaddr_in6 *daddr6 = (const struct sockaddr_in6 *)daddr;
  1520. /* Returns true if the req is for IPv6 link local */
  1521. return (daddr->sa_family == AF_INET6 &&
  1522. (ipv6_addr_type(&daddr6->sin6_addr) & IPV6_ADDR_LINKLOCAL));
  1523. }
  1524. static bool cma_match_net_dev(const struct rdma_cm_id *id,
  1525. const struct net_device *net_dev,
  1526. const struct cma_req_info *req)
  1527. {
  1528. const struct rdma_addr *addr = &id->route.addr;
  1529. if (!net_dev)
  1530. /* This request is an AF_IB request */
  1531. return (!id->port_num || id->port_num == req->port) &&
  1532. (addr->src_addr.ss_family == AF_IB);
  1533. /*
  1534. * If the request is not for IPv6 link local, allow matching
  1535. * request to any netdevice of the one or multiport rdma device.
  1536. */
  1537. if (!cma_is_req_ipv6_ll(req))
  1538. return true;
  1539. /*
  1540. * Net namespaces must match, and if the listner is listening
  1541. * on a specific netdevice than netdevice must match as well.
  1542. */
  1543. if (net_eq(dev_net(net_dev), addr->dev_addr.net) &&
  1544. (!!addr->dev_addr.bound_dev_if ==
  1545. (addr->dev_addr.bound_dev_if == net_dev->ifindex)))
  1546. return true;
  1547. else
  1548. return false;
  1549. }
  1550. static struct rdma_id_private *cma_find_listener(
  1551. const struct rdma_bind_list *bind_list,
  1552. const struct ib_cm_id *cm_id,
  1553. const struct ib_cm_event *ib_event,
  1554. const struct cma_req_info *req,
  1555. const struct net_device *net_dev)
  1556. {
  1557. struct rdma_id_private *id_priv, *id_priv_dev;
  1558. lockdep_assert_held(&lock);
  1559. if (!bind_list)
  1560. return ERR_PTR(-EINVAL);
  1561. hlist_for_each_entry(id_priv, &bind_list->owners, node) {
  1562. if (cma_match_private_data(id_priv, ib_event->private_data)) {
  1563. if (id_priv->id.device == cm_id->device &&
  1564. cma_match_net_dev(&id_priv->id, net_dev, req))
  1565. return id_priv;
  1566. list_for_each_entry(id_priv_dev,
  1567. &id_priv->listen_list,
  1568. listen_item) {
  1569. if (id_priv_dev->id.device == cm_id->device &&
  1570. cma_match_net_dev(&id_priv_dev->id,
  1571. net_dev, req))
  1572. return id_priv_dev;
  1573. }
  1574. }
  1575. }
  1576. return ERR_PTR(-EINVAL);
  1577. }
  1578. static struct rdma_id_private *
  1579. cma_ib_id_from_event(struct ib_cm_id *cm_id,
  1580. const struct ib_cm_event *ib_event,
  1581. struct cma_req_info *req,
  1582. struct net_device **net_dev)
  1583. {
  1584. struct rdma_bind_list *bind_list;
  1585. struct rdma_id_private *id_priv;
  1586. int err;
  1587. err = cma_save_req_info(ib_event, req);
  1588. if (err)
  1589. return ERR_PTR(err);
  1590. *net_dev = cma_get_net_dev(ib_event, req);
  1591. if (IS_ERR(*net_dev)) {
  1592. if (PTR_ERR(*net_dev) == -EAFNOSUPPORT) {
  1593. /* Assuming the protocol is AF_IB */
  1594. *net_dev = NULL;
  1595. } else {
  1596. return ERR_CAST(*net_dev);
  1597. }
  1598. }
  1599. mutex_lock(&lock);
  1600. /*
  1601. * Net namespace might be getting deleted while route lookup,
  1602. * cm_id lookup is in progress. Therefore, perform netdevice
  1603. * validation, cm_id lookup under rcu lock.
  1604. * RCU lock along with netdevice state check, synchronizes with
  1605. * netdevice migrating to different net namespace and also avoids
  1606. * case where net namespace doesn't get deleted while lookup is in
  1607. * progress.
  1608. * If the device state is not IFF_UP, its properties such as ifindex
  1609. * and nd_net cannot be trusted to remain valid without rcu lock.
  1610. * net/core/dev.c change_net_namespace() ensures to synchronize with
  1611. * ongoing operations on net device after device is closed using
  1612. * synchronize_net().
  1613. */
  1614. rcu_read_lock();
  1615. if (*net_dev) {
  1616. /*
  1617. * If netdevice is down, it is likely that it is administratively
  1618. * down or it might be migrating to different namespace.
  1619. * In that case avoid further processing, as the net namespace
  1620. * or ifindex may change.
  1621. */
  1622. if (((*net_dev)->flags & IFF_UP) == 0) {
  1623. id_priv = ERR_PTR(-EHOSTUNREACH);
  1624. goto err;
  1625. }
  1626. if (!validate_net_dev(*net_dev,
  1627. (struct sockaddr *)&req->src_addr_storage,
  1628. (struct sockaddr *)&req->listen_addr_storage)) {
  1629. id_priv = ERR_PTR(-EHOSTUNREACH);
  1630. goto err;
  1631. }
  1632. }
  1633. bind_list = cma_ps_find(*net_dev ? dev_net(*net_dev) : &init_net,
  1634. rdma_ps_from_service_id(req->service_id),
  1635. cma_port_from_service_id(req->service_id));
  1636. id_priv = cma_find_listener(bind_list, cm_id, ib_event, req, *net_dev);
  1637. err:
  1638. rcu_read_unlock();
  1639. mutex_unlock(&lock);
  1640. if (IS_ERR(id_priv) && *net_dev) {
  1641. dev_put(*net_dev);
  1642. *net_dev = NULL;
  1643. }
  1644. return id_priv;
  1645. }
  1646. static inline u8 cma_user_data_offset(struct rdma_id_private *id_priv)
  1647. {
  1648. return cma_family(id_priv) == AF_IB ? 0 : sizeof(struct cma_hdr);
  1649. }
  1650. static void cma_cancel_route(struct rdma_id_private *id_priv)
  1651. {
  1652. if (rdma_cap_ib_sa(id_priv->id.device, id_priv->id.port_num)) {
  1653. if (id_priv->query)
  1654. ib_sa_cancel_query(id_priv->query_id, id_priv->query);
  1655. }
  1656. }
  1657. static void _cma_cancel_listens(struct rdma_id_private *id_priv)
  1658. {
  1659. struct rdma_id_private *dev_id_priv;
  1660. lockdep_assert_held(&lock);
  1661. /*
  1662. * Remove from listen_any_list to prevent added devices from spawning
  1663. * additional listen requests.
  1664. */
  1665. list_del_init(&id_priv->listen_any_item);
  1666. while (!list_empty(&id_priv->listen_list)) {
  1667. dev_id_priv =
  1668. list_first_entry(&id_priv->listen_list,
  1669. struct rdma_id_private, listen_item);
  1670. /* sync with device removal to avoid duplicate destruction */
  1671. list_del_init(&dev_id_priv->device_item);
  1672. list_del_init(&dev_id_priv->listen_item);
  1673. mutex_unlock(&lock);
  1674. rdma_destroy_id(&dev_id_priv->id);
  1675. mutex_lock(&lock);
  1676. }
  1677. }
  1678. static void cma_cancel_listens(struct rdma_id_private *id_priv)
  1679. {
  1680. mutex_lock(&lock);
  1681. _cma_cancel_listens(id_priv);
  1682. mutex_unlock(&lock);
  1683. }
  1684. static void cma_cancel_operation(struct rdma_id_private *id_priv,
  1685. enum rdma_cm_state state)
  1686. {
  1687. switch (state) {
  1688. case RDMA_CM_ADDR_QUERY:
  1689. /*
  1690. * We can avoid doing the rdma_addr_cancel() based on state,
  1691. * only RDMA_CM_ADDR_QUERY has a work that could still execute.
  1692. * Notice that the addr_handler work could still be exiting
  1693. * outside this state, however due to the interaction with the
  1694. * handler_mutex the work is guaranteed not to touch id_priv
  1695. * during exit.
  1696. */
  1697. rdma_addr_cancel(&id_priv->id.route.addr.dev_addr);
  1698. break;
  1699. case RDMA_CM_ROUTE_QUERY:
  1700. cma_cancel_route(id_priv);
  1701. break;
  1702. case RDMA_CM_LISTEN:
  1703. if (cma_any_addr(cma_src_addr(id_priv)) && !id_priv->cma_dev)
  1704. cma_cancel_listens(id_priv);
  1705. break;
  1706. default:
  1707. break;
  1708. }
  1709. }
  1710. static void cma_release_port(struct rdma_id_private *id_priv)
  1711. {
  1712. struct rdma_bind_list *bind_list = id_priv->bind_list;
  1713. struct net *net = id_priv->id.route.addr.dev_addr.net;
  1714. if (!bind_list)
  1715. return;
  1716. mutex_lock(&lock);
  1717. hlist_del(&id_priv->node);
  1718. if (hlist_empty(&bind_list->owners)) {
  1719. cma_ps_remove(net, bind_list->ps, bind_list->port);
  1720. kfree(bind_list);
  1721. }
  1722. mutex_unlock(&lock);
  1723. }
  1724. static void destroy_mc(struct rdma_id_private *id_priv,
  1725. struct cma_multicast *mc)
  1726. {
  1727. bool send_only = mc->join_state == BIT(SENDONLY_FULLMEMBER_JOIN);
  1728. if (rdma_cap_ib_mcast(id_priv->id.device, id_priv->id.port_num))
  1729. ib_sa_free_multicast(mc->sa_mc);
  1730. if (rdma_protocol_roce(id_priv->id.device, id_priv->id.port_num)) {
  1731. struct rdma_cm_event *event = &mc->iboe_join.event;
  1732. struct rdma_dev_addr *dev_addr =
  1733. &id_priv->id.route.addr.dev_addr;
  1734. struct net_device *ndev = NULL;
  1735. if (dev_addr->bound_dev_if)
  1736. ndev = dev_get_by_index(dev_addr->net,
  1737. dev_addr->bound_dev_if);
  1738. if (ndev && !send_only) {
  1739. enum ib_gid_type gid_type;
  1740. union ib_gid mgid;
  1741. gid_type = id_priv->cma_dev->default_gid_type
  1742. [id_priv->id.port_num -
  1743. rdma_start_port(
  1744. id_priv->cma_dev->device)];
  1745. cma_iboe_set_mgid((struct sockaddr *)&mc->addr, &mgid,
  1746. gid_type);
  1747. cma_igmp_send(ndev, &mgid, false);
  1748. }
  1749. dev_put(ndev);
  1750. cancel_work_sync(&mc->iboe_join.work);
  1751. if (event->event == RDMA_CM_EVENT_MULTICAST_JOIN)
  1752. rdma_destroy_ah_attr(&event->param.ud.ah_attr);
  1753. }
  1754. kfree(mc);
  1755. }
  1756. static void cma_leave_mc_groups(struct rdma_id_private *id_priv)
  1757. {
  1758. struct cma_multicast *mc;
  1759. while (!list_empty(&id_priv->mc_list)) {
  1760. mc = list_first_entry(&id_priv->mc_list, struct cma_multicast,
  1761. list);
  1762. list_del(&mc->list);
  1763. destroy_mc(id_priv, mc);
  1764. }
  1765. }
  1766. static void _destroy_id(struct rdma_id_private *id_priv,
  1767. enum rdma_cm_state state)
  1768. {
  1769. cma_cancel_operation(id_priv, state);
  1770. rdma_restrack_del(&id_priv->res);
  1771. cma_remove_id_from_tree(id_priv);
  1772. if (id_priv->cma_dev) {
  1773. if (rdma_cap_ib_cm(id_priv->id.device, 1)) {
  1774. if (id_priv->cm_id.ib)
  1775. ib_destroy_cm_id(id_priv->cm_id.ib);
  1776. } else if (rdma_cap_iw_cm(id_priv->id.device, 1)) {
  1777. if (id_priv->cm_id.iw)
  1778. iw_destroy_cm_id(id_priv->cm_id.iw);
  1779. }
  1780. cma_leave_mc_groups(id_priv);
  1781. cma_release_dev(id_priv);
  1782. }
  1783. cma_release_port(id_priv);
  1784. cma_id_put(id_priv);
  1785. wait_for_completion(&id_priv->comp);
  1786. if (id_priv->internal_id)
  1787. cma_id_put(id_priv->id.context);
  1788. kfree(id_priv->id.route.path_rec);
  1789. kfree(id_priv->id.route.path_rec_inbound);
  1790. kfree(id_priv->id.route.path_rec_outbound);
  1791. kfree(id_priv->id.route.service_recs);
  1792. put_net(id_priv->id.route.addr.dev_addr.net);
  1793. kfree(id_priv);
  1794. }
  1795. /*
  1796. * destroy an ID from within the handler_mutex. This ensures that no other
  1797. * handlers can start running concurrently.
  1798. */
  1799. static void destroy_id_handler_unlock(struct rdma_id_private *id_priv)
  1800. __releases(&idprv->handler_mutex)
  1801. {
  1802. enum rdma_cm_state state;
  1803. unsigned long flags;
  1804. trace_cm_id_destroy(id_priv);
  1805. /*
  1806. * Setting the state to destroyed under the handler mutex provides a
  1807. * fence against calling handler callbacks. If this is invoked due to
  1808. * the failure of a handler callback then it guarentees that no future
  1809. * handlers will be called.
  1810. */
  1811. lockdep_assert_held(&id_priv->handler_mutex);
  1812. spin_lock_irqsave(&id_priv->lock, flags);
  1813. state = id_priv->state;
  1814. id_priv->state = RDMA_CM_DESTROYING;
  1815. spin_unlock_irqrestore(&id_priv->lock, flags);
  1816. mutex_unlock(&id_priv->handler_mutex);
  1817. _destroy_id(id_priv, state);
  1818. }
  1819. void rdma_destroy_id(struct rdma_cm_id *id)
  1820. {
  1821. struct rdma_id_private *id_priv =
  1822. container_of(id, struct rdma_id_private, id);
  1823. mutex_lock(&id_priv->handler_mutex);
  1824. destroy_id_handler_unlock(id_priv);
  1825. }
  1826. EXPORT_SYMBOL(rdma_destroy_id);
  1827. static int cma_rep_recv(struct rdma_id_private *id_priv)
  1828. {
  1829. int ret;
  1830. ret = cma_modify_qp_rtr(id_priv, NULL);
  1831. if (ret)
  1832. goto reject;
  1833. ret = cma_modify_qp_rts(id_priv, NULL);
  1834. if (ret)
  1835. goto reject;
  1836. trace_cm_send_rtu(id_priv);
  1837. ret = ib_send_cm_rtu(id_priv->cm_id.ib, NULL, 0);
  1838. if (ret)
  1839. goto reject;
  1840. return 0;
  1841. reject:
  1842. pr_debug_ratelimited("RDMA CM: CONNECT_ERROR: failed to handle reply. status %d\n", ret);
  1843. cma_modify_qp_err(id_priv);
  1844. trace_cm_send_rej(id_priv);
  1845. ib_send_cm_rej(id_priv->cm_id.ib, IB_CM_REJ_CONSUMER_DEFINED,
  1846. NULL, 0, NULL, 0);
  1847. return ret;
  1848. }
  1849. static void cma_set_rep_event_data(struct rdma_cm_event *event,
  1850. const struct ib_cm_rep_event_param *rep_data,
  1851. void *private_data)
  1852. {
  1853. event->param.conn.private_data = private_data;
  1854. event->param.conn.private_data_len = IB_CM_REP_PRIVATE_DATA_SIZE;
  1855. event->param.conn.responder_resources = rep_data->responder_resources;
  1856. event->param.conn.initiator_depth = rep_data->initiator_depth;
  1857. event->param.conn.flow_control = rep_data->flow_control;
  1858. event->param.conn.rnr_retry_count = rep_data->rnr_retry_count;
  1859. event->param.conn.srq = rep_data->srq;
  1860. event->param.conn.qp_num = rep_data->remote_qpn;
  1861. event->ece.vendor_id = rep_data->ece.vendor_id;
  1862. event->ece.attr_mod = rep_data->ece.attr_mod;
  1863. }
  1864. static int cma_cm_event_handler(struct rdma_id_private *id_priv,
  1865. struct rdma_cm_event *event)
  1866. {
  1867. int ret;
  1868. lockdep_assert_held(&id_priv->handler_mutex);
  1869. trace_cm_event_handler(id_priv, event);
  1870. ret = id_priv->id.event_handler(&id_priv->id, event);
  1871. trace_cm_event_done(id_priv, event, ret);
  1872. return ret;
  1873. }
  1874. static int cma_ib_handler(struct ib_cm_id *cm_id,
  1875. const struct ib_cm_event *ib_event)
  1876. {
  1877. struct rdma_id_private *id_priv = cm_id->context;
  1878. struct rdma_cm_event event = {};
  1879. enum rdma_cm_state state;
  1880. int ret;
  1881. mutex_lock(&id_priv->handler_mutex);
  1882. state = READ_ONCE(id_priv->state);
  1883. if ((ib_event->event != IB_CM_TIMEWAIT_EXIT &&
  1884. state != RDMA_CM_CONNECT) ||
  1885. (ib_event->event == IB_CM_TIMEWAIT_EXIT &&
  1886. state != RDMA_CM_DISCONNECT))
  1887. goto out;
  1888. switch (ib_event->event) {
  1889. case IB_CM_REQ_ERROR:
  1890. case IB_CM_REP_ERROR:
  1891. event.event = RDMA_CM_EVENT_UNREACHABLE;
  1892. event.status = -ETIMEDOUT;
  1893. break;
  1894. case IB_CM_REP_RECEIVED:
  1895. if (state == RDMA_CM_CONNECT &&
  1896. (id_priv->id.qp_type != IB_QPT_UD)) {
  1897. trace_cm_prepare_mra(id_priv);
  1898. ib_prepare_cm_mra(cm_id);
  1899. }
  1900. if (id_priv->id.qp) {
  1901. event.status = cma_rep_recv(id_priv);
  1902. event.event = event.status ? RDMA_CM_EVENT_CONNECT_ERROR :
  1903. RDMA_CM_EVENT_ESTABLISHED;
  1904. } else {
  1905. event.event = RDMA_CM_EVENT_CONNECT_RESPONSE;
  1906. }
  1907. cma_set_rep_event_data(&event, &ib_event->param.rep_rcvd,
  1908. ib_event->private_data);
  1909. break;
  1910. case IB_CM_RTU_RECEIVED:
  1911. case IB_CM_USER_ESTABLISHED:
  1912. event.event = RDMA_CM_EVENT_ESTABLISHED;
  1913. break;
  1914. case IB_CM_DREQ_ERROR:
  1915. event.status = -ETIMEDOUT;
  1916. fallthrough;
  1917. case IB_CM_DREQ_RECEIVED:
  1918. case IB_CM_DREP_RECEIVED:
  1919. if (!cma_comp_exch(id_priv, RDMA_CM_CONNECT,
  1920. RDMA_CM_DISCONNECT))
  1921. goto out;
  1922. event.event = RDMA_CM_EVENT_DISCONNECTED;
  1923. break;
  1924. case IB_CM_TIMEWAIT_EXIT:
  1925. event.event = RDMA_CM_EVENT_TIMEWAIT_EXIT;
  1926. break;
  1927. case IB_CM_MRA_RECEIVED:
  1928. /* ignore event */
  1929. goto out;
  1930. case IB_CM_REJ_RECEIVED:
  1931. pr_debug_ratelimited("RDMA CM: REJECTED: %s\n", rdma_reject_msg(&id_priv->id,
  1932. ib_event->param.rej_rcvd.reason));
  1933. cma_modify_qp_err(id_priv);
  1934. event.status = ib_event->param.rej_rcvd.reason;
  1935. event.event = RDMA_CM_EVENT_REJECTED;
  1936. event.param.conn.private_data = ib_event->private_data;
  1937. event.param.conn.private_data_len = IB_CM_REJ_PRIVATE_DATA_SIZE;
  1938. break;
  1939. default:
  1940. pr_err("RDMA CMA: unexpected IB CM event: %d\n",
  1941. ib_event->event);
  1942. goto out;
  1943. }
  1944. ret = cma_cm_event_handler(id_priv, &event);
  1945. if (ret) {
  1946. /* Destroy the CM ID by returning a non-zero value. */
  1947. id_priv->cm_id.ib = NULL;
  1948. destroy_id_handler_unlock(id_priv);
  1949. return ret;
  1950. }
  1951. out:
  1952. mutex_unlock(&id_priv->handler_mutex);
  1953. return 0;
  1954. }
  1955. static struct rdma_id_private *
  1956. cma_ib_new_conn_id(const struct rdma_cm_id *listen_id,
  1957. const struct ib_cm_event *ib_event,
  1958. struct net_device *net_dev)
  1959. {
  1960. struct rdma_id_private *listen_id_priv;
  1961. struct rdma_id_private *id_priv;
  1962. struct rdma_cm_id *id;
  1963. struct rdma_route *rt;
  1964. const sa_family_t ss_family = listen_id->route.addr.src_addr.ss_family;
  1965. struct sa_path_rec *path = ib_event->param.req_rcvd.primary_path;
  1966. const __be64 service_id =
  1967. ib_event->param.req_rcvd.primary_path->service_id;
  1968. int ret;
  1969. listen_id_priv = container_of(listen_id, struct rdma_id_private, id);
  1970. id_priv = __rdma_create_id(listen_id->route.addr.dev_addr.net,
  1971. listen_id->event_handler, listen_id->context,
  1972. listen_id->ps,
  1973. ib_event->param.req_rcvd.qp_type,
  1974. listen_id_priv);
  1975. if (IS_ERR(id_priv))
  1976. return NULL;
  1977. id = &id_priv->id;
  1978. if (cma_save_net_info((struct sockaddr *)&id->route.addr.src_addr,
  1979. (struct sockaddr *)&id->route.addr.dst_addr,
  1980. listen_id, ib_event, ss_family, service_id))
  1981. goto err;
  1982. rt = &id->route;
  1983. rt->num_pri_alt_paths = ib_event->param.req_rcvd.alternate_path ? 2 : 1;
  1984. rt->path_rec = kmalloc_objs(*rt->path_rec, rt->num_pri_alt_paths);
  1985. if (!rt->path_rec)
  1986. goto err;
  1987. rt->path_rec[0] = *path;
  1988. if (rt->num_pri_alt_paths == 2)
  1989. rt->path_rec[1] = *ib_event->param.req_rcvd.alternate_path;
  1990. if (net_dev) {
  1991. rdma_copy_src_l2_addr(&rt->addr.dev_addr, net_dev);
  1992. } else {
  1993. if (!cma_protocol_roce(listen_id) &&
  1994. cma_any_addr(cma_src_addr(id_priv))) {
  1995. rt->addr.dev_addr.dev_type = ARPHRD_INFINIBAND;
  1996. rdma_addr_set_sgid(&rt->addr.dev_addr, &rt->path_rec[0].sgid);
  1997. ib_addr_set_pkey(&rt->addr.dev_addr, be16_to_cpu(rt->path_rec[0].pkey));
  1998. } else if (!cma_any_addr(cma_src_addr(id_priv))) {
  1999. ret = cma_translate_addr(cma_src_addr(id_priv), &rt->addr.dev_addr);
  2000. if (ret)
  2001. goto err;
  2002. }
  2003. }
  2004. rdma_addr_set_dgid(&rt->addr.dev_addr, &rt->path_rec[0].dgid);
  2005. id_priv->state = RDMA_CM_CONNECT;
  2006. return id_priv;
  2007. err:
  2008. rdma_destroy_id(id);
  2009. return NULL;
  2010. }
  2011. static struct rdma_id_private *
  2012. cma_ib_new_udp_id(const struct rdma_cm_id *listen_id,
  2013. const struct ib_cm_event *ib_event,
  2014. struct net_device *net_dev)
  2015. {
  2016. const struct rdma_id_private *listen_id_priv;
  2017. struct rdma_id_private *id_priv;
  2018. struct rdma_cm_id *id;
  2019. const sa_family_t ss_family = listen_id->route.addr.src_addr.ss_family;
  2020. struct net *net = listen_id->route.addr.dev_addr.net;
  2021. int ret;
  2022. listen_id_priv = container_of(listen_id, struct rdma_id_private, id);
  2023. id_priv = __rdma_create_id(net, listen_id->event_handler,
  2024. listen_id->context, listen_id->ps, IB_QPT_UD,
  2025. listen_id_priv);
  2026. if (IS_ERR(id_priv))
  2027. return NULL;
  2028. id = &id_priv->id;
  2029. if (cma_save_net_info((struct sockaddr *)&id->route.addr.src_addr,
  2030. (struct sockaddr *)&id->route.addr.dst_addr,
  2031. listen_id, ib_event, ss_family,
  2032. ib_event->param.sidr_req_rcvd.service_id))
  2033. goto err;
  2034. if (net_dev) {
  2035. rdma_copy_src_l2_addr(&id->route.addr.dev_addr, net_dev);
  2036. } else {
  2037. if (!cma_any_addr(cma_src_addr(id_priv))) {
  2038. ret = cma_translate_addr(cma_src_addr(id_priv),
  2039. &id->route.addr.dev_addr);
  2040. if (ret)
  2041. goto err;
  2042. }
  2043. }
  2044. id_priv->state = RDMA_CM_CONNECT;
  2045. return id_priv;
  2046. err:
  2047. rdma_destroy_id(id);
  2048. return NULL;
  2049. }
  2050. static void cma_set_req_event_data(struct rdma_cm_event *event,
  2051. const struct ib_cm_req_event_param *req_data,
  2052. void *private_data, int offset)
  2053. {
  2054. event->param.conn.private_data = private_data + offset;
  2055. event->param.conn.private_data_len = IB_CM_REQ_PRIVATE_DATA_SIZE - offset;
  2056. event->param.conn.responder_resources = req_data->responder_resources;
  2057. event->param.conn.initiator_depth = req_data->initiator_depth;
  2058. event->param.conn.flow_control = req_data->flow_control;
  2059. event->param.conn.retry_count = req_data->retry_count;
  2060. event->param.conn.rnr_retry_count = req_data->rnr_retry_count;
  2061. event->param.conn.srq = req_data->srq;
  2062. event->param.conn.qp_num = req_data->remote_qpn;
  2063. event->ece.vendor_id = req_data->ece.vendor_id;
  2064. event->ece.attr_mod = req_data->ece.attr_mod;
  2065. }
  2066. static int cma_ib_check_req_qp_type(const struct rdma_cm_id *id,
  2067. const struct ib_cm_event *ib_event)
  2068. {
  2069. return (((ib_event->event == IB_CM_REQ_RECEIVED) &&
  2070. (ib_event->param.req_rcvd.qp_type == id->qp_type)) ||
  2071. ((ib_event->event == IB_CM_SIDR_REQ_RECEIVED) &&
  2072. (id->qp_type == IB_QPT_UD)) ||
  2073. (!id->qp_type));
  2074. }
  2075. static int cma_ib_req_handler(struct ib_cm_id *cm_id,
  2076. const struct ib_cm_event *ib_event)
  2077. {
  2078. struct rdma_id_private *listen_id, *conn_id = NULL;
  2079. struct rdma_cm_event event = {};
  2080. struct cma_req_info req = {};
  2081. struct net_device *net_dev;
  2082. u8 offset;
  2083. int ret;
  2084. listen_id = cma_ib_id_from_event(cm_id, ib_event, &req, &net_dev);
  2085. if (IS_ERR(listen_id))
  2086. return PTR_ERR(listen_id);
  2087. trace_cm_req_handler(listen_id, ib_event->event);
  2088. if (!cma_ib_check_req_qp_type(&listen_id->id, ib_event)) {
  2089. ret = -EINVAL;
  2090. goto net_dev_put;
  2091. }
  2092. mutex_lock(&listen_id->handler_mutex);
  2093. if (READ_ONCE(listen_id->state) != RDMA_CM_LISTEN) {
  2094. ret = -ECONNABORTED;
  2095. goto err_unlock;
  2096. }
  2097. offset = cma_user_data_offset(listen_id);
  2098. event.event = RDMA_CM_EVENT_CONNECT_REQUEST;
  2099. if (ib_event->event == IB_CM_SIDR_REQ_RECEIVED) {
  2100. conn_id = cma_ib_new_udp_id(&listen_id->id, ib_event, net_dev);
  2101. event.param.ud.private_data = ib_event->private_data + offset;
  2102. event.param.ud.private_data_len =
  2103. IB_CM_SIDR_REQ_PRIVATE_DATA_SIZE - offset;
  2104. } else {
  2105. conn_id = cma_ib_new_conn_id(&listen_id->id, ib_event, net_dev);
  2106. cma_set_req_event_data(&event, &ib_event->param.req_rcvd,
  2107. ib_event->private_data, offset);
  2108. }
  2109. if (!conn_id) {
  2110. ret = -ENOMEM;
  2111. goto err_unlock;
  2112. }
  2113. mutex_lock_nested(&conn_id->handler_mutex, SINGLE_DEPTH_NESTING);
  2114. ret = cma_ib_acquire_dev(conn_id, listen_id, &req);
  2115. if (ret) {
  2116. destroy_id_handler_unlock(conn_id);
  2117. goto err_unlock;
  2118. }
  2119. conn_id->cm_id.ib = cm_id;
  2120. cm_id->context = conn_id;
  2121. cm_id->cm_handler = cma_ib_handler;
  2122. ret = cma_cm_event_handler(conn_id, &event);
  2123. if (ret) {
  2124. /* Destroy the CM ID by returning a non-zero value. */
  2125. conn_id->cm_id.ib = NULL;
  2126. mutex_unlock(&listen_id->handler_mutex);
  2127. destroy_id_handler_unlock(conn_id);
  2128. goto net_dev_put;
  2129. }
  2130. if (READ_ONCE(conn_id->state) == RDMA_CM_CONNECT &&
  2131. conn_id->id.qp_type != IB_QPT_UD) {
  2132. trace_cm_prepare_mra(cm_id->context);
  2133. ib_prepare_cm_mra(cm_id);
  2134. }
  2135. mutex_unlock(&conn_id->handler_mutex);
  2136. err_unlock:
  2137. mutex_unlock(&listen_id->handler_mutex);
  2138. net_dev_put:
  2139. dev_put(net_dev);
  2140. return ret;
  2141. }
  2142. __be64 rdma_get_service_id(struct rdma_cm_id *id, struct sockaddr *addr)
  2143. {
  2144. if (addr->sa_family == AF_IB)
  2145. return ((struct sockaddr_ib *) addr)->sib_sid;
  2146. return cpu_to_be64(((u64)id->ps << 16) + be16_to_cpu(cma_port(addr)));
  2147. }
  2148. EXPORT_SYMBOL(rdma_get_service_id);
  2149. void rdma_read_gids(struct rdma_cm_id *cm_id, union ib_gid *sgid,
  2150. union ib_gid *dgid)
  2151. {
  2152. struct rdma_addr *addr = &cm_id->route.addr;
  2153. if (!cm_id->device) {
  2154. if (sgid)
  2155. memset(sgid, 0, sizeof(*sgid));
  2156. if (dgid)
  2157. memset(dgid, 0, sizeof(*dgid));
  2158. return;
  2159. }
  2160. if (rdma_protocol_roce(cm_id->device, cm_id->port_num)) {
  2161. if (sgid)
  2162. rdma_ip2gid((struct sockaddr *)&addr->src_addr, sgid);
  2163. if (dgid)
  2164. rdma_ip2gid((struct sockaddr *)&addr->dst_addr, dgid);
  2165. } else {
  2166. if (sgid)
  2167. rdma_addr_get_sgid(&addr->dev_addr, sgid);
  2168. if (dgid)
  2169. rdma_addr_get_dgid(&addr->dev_addr, dgid);
  2170. }
  2171. }
  2172. EXPORT_SYMBOL(rdma_read_gids);
  2173. static int cma_iw_handler(struct iw_cm_id *iw_id, struct iw_cm_event *iw_event)
  2174. {
  2175. struct rdma_id_private *id_priv = iw_id->context;
  2176. struct rdma_cm_event event = {};
  2177. int ret = 0;
  2178. struct sockaddr *laddr = (struct sockaddr *)&iw_event->local_addr;
  2179. struct sockaddr *raddr = (struct sockaddr *)&iw_event->remote_addr;
  2180. mutex_lock(&id_priv->handler_mutex);
  2181. if (READ_ONCE(id_priv->state) != RDMA_CM_CONNECT)
  2182. goto out;
  2183. switch (iw_event->event) {
  2184. case IW_CM_EVENT_CLOSE:
  2185. event.event = RDMA_CM_EVENT_DISCONNECTED;
  2186. break;
  2187. case IW_CM_EVENT_CONNECT_REPLY:
  2188. memcpy(cma_src_addr(id_priv), laddr,
  2189. rdma_addr_size(laddr));
  2190. memcpy(cma_dst_addr(id_priv), raddr,
  2191. rdma_addr_size(raddr));
  2192. switch (iw_event->status) {
  2193. case 0:
  2194. event.event = RDMA_CM_EVENT_ESTABLISHED;
  2195. event.param.conn.initiator_depth = iw_event->ird;
  2196. event.param.conn.responder_resources = iw_event->ord;
  2197. break;
  2198. case -ECONNRESET:
  2199. case -ECONNREFUSED:
  2200. event.event = RDMA_CM_EVENT_REJECTED;
  2201. break;
  2202. case -ETIMEDOUT:
  2203. event.event = RDMA_CM_EVENT_UNREACHABLE;
  2204. break;
  2205. default:
  2206. event.event = RDMA_CM_EVENT_CONNECT_ERROR;
  2207. break;
  2208. }
  2209. break;
  2210. case IW_CM_EVENT_ESTABLISHED:
  2211. event.event = RDMA_CM_EVENT_ESTABLISHED;
  2212. event.param.conn.initiator_depth = iw_event->ird;
  2213. event.param.conn.responder_resources = iw_event->ord;
  2214. break;
  2215. default:
  2216. goto out;
  2217. }
  2218. event.status = iw_event->status;
  2219. event.param.conn.private_data = iw_event->private_data;
  2220. event.param.conn.private_data_len = iw_event->private_data_len;
  2221. ret = cma_cm_event_handler(id_priv, &event);
  2222. if (ret) {
  2223. /* Destroy the CM ID by returning a non-zero value. */
  2224. id_priv->cm_id.iw = NULL;
  2225. destroy_id_handler_unlock(id_priv);
  2226. return ret;
  2227. }
  2228. out:
  2229. mutex_unlock(&id_priv->handler_mutex);
  2230. return ret;
  2231. }
  2232. static int iw_conn_req_handler(struct iw_cm_id *cm_id,
  2233. struct iw_cm_event *iw_event)
  2234. {
  2235. struct rdma_id_private *listen_id, *conn_id;
  2236. struct rdma_cm_event event = {};
  2237. int ret = -ECONNABORTED;
  2238. struct sockaddr *laddr = (struct sockaddr *)&iw_event->local_addr;
  2239. struct sockaddr *raddr = (struct sockaddr *)&iw_event->remote_addr;
  2240. event.event = RDMA_CM_EVENT_CONNECT_REQUEST;
  2241. event.param.conn.private_data = iw_event->private_data;
  2242. event.param.conn.private_data_len = iw_event->private_data_len;
  2243. event.param.conn.initiator_depth = iw_event->ird;
  2244. event.param.conn.responder_resources = iw_event->ord;
  2245. listen_id = cm_id->context;
  2246. mutex_lock(&listen_id->handler_mutex);
  2247. if (READ_ONCE(listen_id->state) != RDMA_CM_LISTEN)
  2248. goto out;
  2249. /* Create a new RDMA id for the new IW CM ID */
  2250. conn_id = __rdma_create_id(listen_id->id.route.addr.dev_addr.net,
  2251. listen_id->id.event_handler,
  2252. listen_id->id.context, RDMA_PS_TCP,
  2253. IB_QPT_RC, listen_id);
  2254. if (IS_ERR(conn_id)) {
  2255. ret = -ENOMEM;
  2256. goto out;
  2257. }
  2258. mutex_lock_nested(&conn_id->handler_mutex, SINGLE_DEPTH_NESTING);
  2259. conn_id->state = RDMA_CM_CONNECT;
  2260. ret = rdma_translate_ip(laddr, &conn_id->id.route.addr.dev_addr);
  2261. if (ret) {
  2262. mutex_unlock(&listen_id->handler_mutex);
  2263. destroy_id_handler_unlock(conn_id);
  2264. return ret;
  2265. }
  2266. ret = cma_iw_acquire_dev(conn_id, listen_id);
  2267. if (ret) {
  2268. mutex_unlock(&listen_id->handler_mutex);
  2269. destroy_id_handler_unlock(conn_id);
  2270. return ret;
  2271. }
  2272. conn_id->cm_id.iw = cm_id;
  2273. cm_id->context = conn_id;
  2274. cm_id->cm_handler = cma_iw_handler;
  2275. memcpy(cma_src_addr(conn_id), laddr, rdma_addr_size(laddr));
  2276. memcpy(cma_dst_addr(conn_id), raddr, rdma_addr_size(raddr));
  2277. ret = cma_cm_event_handler(conn_id, &event);
  2278. if (ret) {
  2279. /* User wants to destroy the CM ID */
  2280. conn_id->cm_id.iw = NULL;
  2281. mutex_unlock(&listen_id->handler_mutex);
  2282. destroy_id_handler_unlock(conn_id);
  2283. return ret;
  2284. }
  2285. mutex_unlock(&conn_id->handler_mutex);
  2286. out:
  2287. mutex_unlock(&listen_id->handler_mutex);
  2288. return ret;
  2289. }
  2290. static int cma_ib_listen(struct rdma_id_private *id_priv)
  2291. {
  2292. struct sockaddr *addr;
  2293. struct ib_cm_id *id;
  2294. __be64 svc_id;
  2295. addr = cma_src_addr(id_priv);
  2296. svc_id = rdma_get_service_id(&id_priv->id, addr);
  2297. id = ib_cm_insert_listen(id_priv->id.device,
  2298. cma_ib_req_handler, svc_id);
  2299. if (IS_ERR(id))
  2300. return PTR_ERR(id);
  2301. id_priv->cm_id.ib = id;
  2302. return 0;
  2303. }
  2304. static int cma_iw_listen(struct rdma_id_private *id_priv, int backlog)
  2305. {
  2306. int ret;
  2307. struct iw_cm_id *id;
  2308. id = iw_create_cm_id(id_priv->id.device,
  2309. iw_conn_req_handler,
  2310. id_priv);
  2311. if (IS_ERR(id))
  2312. return PTR_ERR(id);
  2313. mutex_lock(&id_priv->qp_mutex);
  2314. id->tos = id_priv->tos;
  2315. id->tos_set = id_priv->tos_set;
  2316. mutex_unlock(&id_priv->qp_mutex);
  2317. id->afonly = id_priv->afonly;
  2318. id_priv->cm_id.iw = id;
  2319. memcpy(&id_priv->cm_id.iw->local_addr, cma_src_addr(id_priv),
  2320. rdma_addr_size(cma_src_addr(id_priv)));
  2321. ret = iw_cm_listen(id_priv->cm_id.iw, backlog);
  2322. if (ret) {
  2323. iw_destroy_cm_id(id_priv->cm_id.iw);
  2324. id_priv->cm_id.iw = NULL;
  2325. }
  2326. return ret;
  2327. }
  2328. static int cma_listen_handler(struct rdma_cm_id *id,
  2329. struct rdma_cm_event *event)
  2330. {
  2331. struct rdma_id_private *id_priv = id->context;
  2332. /* Listening IDs are always destroyed on removal */
  2333. if (event->event == RDMA_CM_EVENT_DEVICE_REMOVAL)
  2334. return -1;
  2335. id->context = id_priv->id.context;
  2336. id->event_handler = id_priv->id.event_handler;
  2337. trace_cm_event_handler(id_priv, event);
  2338. return id_priv->id.event_handler(id, event);
  2339. }
  2340. static int cma_listen_on_dev(struct rdma_id_private *id_priv,
  2341. struct cma_device *cma_dev,
  2342. struct rdma_id_private **to_destroy)
  2343. {
  2344. struct rdma_id_private *dev_id_priv;
  2345. struct net *net = id_priv->id.route.addr.dev_addr.net;
  2346. int ret;
  2347. lockdep_assert_held(&lock);
  2348. *to_destroy = NULL;
  2349. if (cma_family(id_priv) == AF_IB && !rdma_cap_ib_cm(cma_dev->device, 1))
  2350. return 0;
  2351. if (id_priv->restricted_node_type != RDMA_NODE_UNSPECIFIED &&
  2352. id_priv->restricted_node_type != cma_dev->device->node_type)
  2353. return 0;
  2354. dev_id_priv =
  2355. __rdma_create_id(net, cma_listen_handler, id_priv,
  2356. id_priv->id.ps, id_priv->id.qp_type, id_priv);
  2357. if (IS_ERR(dev_id_priv))
  2358. return PTR_ERR(dev_id_priv);
  2359. dev_id_priv->restricted_node_type = id_priv->restricted_node_type;
  2360. dev_id_priv->state = RDMA_CM_ADDR_BOUND;
  2361. memcpy(cma_src_addr(dev_id_priv), cma_src_addr(id_priv),
  2362. rdma_addr_size(cma_src_addr(id_priv)));
  2363. _cma_attach_to_dev(dev_id_priv, cma_dev);
  2364. rdma_restrack_add(&dev_id_priv->res);
  2365. cma_id_get(id_priv);
  2366. dev_id_priv->internal_id = 1;
  2367. dev_id_priv->afonly = id_priv->afonly;
  2368. mutex_lock(&id_priv->qp_mutex);
  2369. dev_id_priv->tos_set = id_priv->tos_set;
  2370. dev_id_priv->tos = id_priv->tos;
  2371. mutex_unlock(&id_priv->qp_mutex);
  2372. ret = rdma_listen(&dev_id_priv->id, id_priv->backlog);
  2373. if (ret)
  2374. goto err_listen;
  2375. list_add_tail(&dev_id_priv->listen_item, &id_priv->listen_list);
  2376. return 0;
  2377. err_listen:
  2378. /* Caller must destroy this after releasing lock */
  2379. *to_destroy = dev_id_priv;
  2380. dev_warn(&cma_dev->device->dev, "RDMA CMA: %s, error %d\n", __func__, ret);
  2381. return ret;
  2382. }
  2383. static int cma_listen_on_all(struct rdma_id_private *id_priv)
  2384. {
  2385. struct rdma_id_private *to_destroy;
  2386. struct cma_device *cma_dev;
  2387. int ret;
  2388. mutex_lock(&lock);
  2389. list_add_tail(&id_priv->listen_any_item, &listen_any_list);
  2390. list_for_each_entry(cma_dev, &dev_list, list) {
  2391. ret = cma_listen_on_dev(id_priv, cma_dev, &to_destroy);
  2392. if (ret) {
  2393. /* Prevent racing with cma_process_remove() */
  2394. if (to_destroy)
  2395. list_del_init(&to_destroy->device_item);
  2396. goto err_listen;
  2397. }
  2398. }
  2399. mutex_unlock(&lock);
  2400. return 0;
  2401. err_listen:
  2402. _cma_cancel_listens(id_priv);
  2403. mutex_unlock(&lock);
  2404. if (to_destroy)
  2405. rdma_destroy_id(&to_destroy->id);
  2406. return ret;
  2407. }
  2408. void rdma_set_service_type(struct rdma_cm_id *id, int tos)
  2409. {
  2410. struct rdma_id_private *id_priv;
  2411. id_priv = container_of(id, struct rdma_id_private, id);
  2412. mutex_lock(&id_priv->qp_mutex);
  2413. id_priv->tos = (u8) tos;
  2414. id_priv->tos_set = true;
  2415. mutex_unlock(&id_priv->qp_mutex);
  2416. }
  2417. EXPORT_SYMBOL(rdma_set_service_type);
  2418. /**
  2419. * rdma_set_ack_timeout() - Set the ack timeout of QP associated
  2420. * with a connection identifier.
  2421. * @id: Communication identifier to associated with service type.
  2422. * @timeout: Ack timeout to set a QP, expressed as 4.096 * 2^(timeout) usec.
  2423. *
  2424. * This function should be called before rdma_connect() on active side,
  2425. * and on passive side before rdma_accept(). It is applicable to primary
  2426. * path only. The timeout will affect the local side of the QP, it is not
  2427. * negotiated with remote side and zero disables the timer. In case it is
  2428. * set before rdma_resolve_route, the value will also be used to determine
  2429. * PacketLifeTime for RoCE.
  2430. *
  2431. * Return: 0 for success
  2432. */
  2433. int rdma_set_ack_timeout(struct rdma_cm_id *id, u8 timeout)
  2434. {
  2435. struct rdma_id_private *id_priv;
  2436. if (id->qp_type != IB_QPT_RC && id->qp_type != IB_QPT_XRC_INI)
  2437. return -EINVAL;
  2438. id_priv = container_of(id, struct rdma_id_private, id);
  2439. mutex_lock(&id_priv->qp_mutex);
  2440. id_priv->timeout = timeout;
  2441. id_priv->timeout_set = true;
  2442. mutex_unlock(&id_priv->qp_mutex);
  2443. return 0;
  2444. }
  2445. EXPORT_SYMBOL(rdma_set_ack_timeout);
  2446. /**
  2447. * rdma_set_min_rnr_timer() - Set the minimum RNR Retry timer of the
  2448. * QP associated with a connection identifier.
  2449. * @id: Communication identifier to associated with service type.
  2450. * @min_rnr_timer: 5-bit value encoded as Table 45: "Encoding for RNR NAK
  2451. * Timer Field" in the IBTA specification.
  2452. *
  2453. * This function should be called before rdma_connect() on active
  2454. * side, and on passive side before rdma_accept(). The timer value
  2455. * will be associated with the local QP. When it receives a send it is
  2456. * not read to handle, typically if the receive queue is empty, an RNR
  2457. * Retry NAK is returned to the requester with the min_rnr_timer
  2458. * encoded. The requester will then wait at least the time specified
  2459. * in the NAK before retrying. The default is zero, which translates
  2460. * to a minimum RNR Timer value of 655 ms.
  2461. *
  2462. * Return: 0 for success
  2463. */
  2464. int rdma_set_min_rnr_timer(struct rdma_cm_id *id, u8 min_rnr_timer)
  2465. {
  2466. struct rdma_id_private *id_priv;
  2467. /* It is a five-bit value */
  2468. if (min_rnr_timer & 0xe0)
  2469. return -EINVAL;
  2470. if (WARN_ON(id->qp_type != IB_QPT_RC && id->qp_type != IB_QPT_XRC_TGT))
  2471. return -EINVAL;
  2472. id_priv = container_of(id, struct rdma_id_private, id);
  2473. mutex_lock(&id_priv->qp_mutex);
  2474. id_priv->min_rnr_timer = min_rnr_timer;
  2475. id_priv->min_rnr_timer_set = true;
  2476. mutex_unlock(&id_priv->qp_mutex);
  2477. return 0;
  2478. }
  2479. EXPORT_SYMBOL(rdma_set_min_rnr_timer);
  2480. static int route_set_path_rec_inbound(struct cma_work *work,
  2481. struct sa_path_rec *path_rec)
  2482. {
  2483. struct rdma_route *route = &work->id->id.route;
  2484. if (!route->path_rec_inbound) {
  2485. route->path_rec_inbound = kzalloc_obj(*route->path_rec_inbound);
  2486. if (!route->path_rec_inbound)
  2487. return -ENOMEM;
  2488. }
  2489. *route->path_rec_inbound = *path_rec;
  2490. return 0;
  2491. }
  2492. static int route_set_path_rec_outbound(struct cma_work *work,
  2493. struct sa_path_rec *path_rec)
  2494. {
  2495. struct rdma_route *route = &work->id->id.route;
  2496. if (!route->path_rec_outbound) {
  2497. route->path_rec_outbound = kzalloc_obj(*route->path_rec_outbound);
  2498. if (!route->path_rec_outbound)
  2499. return -ENOMEM;
  2500. }
  2501. *route->path_rec_outbound = *path_rec;
  2502. return 0;
  2503. }
  2504. static void cma_query_handler(int status, struct sa_path_rec *path_rec,
  2505. unsigned int num_prs, void *context)
  2506. {
  2507. struct cma_work *work = context;
  2508. struct rdma_route *route;
  2509. int i;
  2510. route = &work->id->id.route;
  2511. if (status)
  2512. goto fail;
  2513. for (i = 0; i < num_prs; i++) {
  2514. if (!path_rec[i].flags || (path_rec[i].flags & IB_PATH_GMP))
  2515. *route->path_rec = path_rec[i];
  2516. else if (path_rec[i].flags & IB_PATH_INBOUND)
  2517. status = route_set_path_rec_inbound(work, &path_rec[i]);
  2518. else if (path_rec[i].flags & IB_PATH_OUTBOUND)
  2519. status = route_set_path_rec_outbound(work,
  2520. &path_rec[i]);
  2521. else
  2522. status = -EINVAL;
  2523. if (status)
  2524. goto fail;
  2525. }
  2526. route->num_pri_alt_paths = 1;
  2527. queue_work(cma_wq, &work->work);
  2528. return;
  2529. fail:
  2530. work->old_state = RDMA_CM_ROUTE_QUERY;
  2531. work->new_state = RDMA_CM_ADDR_RESOLVED;
  2532. work->event.event = RDMA_CM_EVENT_ROUTE_ERROR;
  2533. work->event.status = status;
  2534. pr_debug_ratelimited("RDMA CM: ROUTE_ERROR: failed to query path. status %d\n",
  2535. status);
  2536. queue_work(cma_wq, &work->work);
  2537. }
  2538. static int cma_query_ib_route(struct rdma_id_private *id_priv,
  2539. unsigned long timeout_ms, struct cma_work *work)
  2540. {
  2541. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  2542. struct sa_path_rec path_rec;
  2543. ib_sa_comp_mask comp_mask;
  2544. struct sockaddr_in6 *sin6;
  2545. struct sockaddr_ib *sib;
  2546. memset(&path_rec, 0, sizeof path_rec);
  2547. if (rdma_cap_opa_ah(id_priv->id.device, id_priv->id.port_num))
  2548. path_rec.rec_type = SA_PATH_REC_TYPE_OPA;
  2549. else
  2550. path_rec.rec_type = SA_PATH_REC_TYPE_IB;
  2551. rdma_addr_get_sgid(dev_addr, &path_rec.sgid);
  2552. rdma_addr_get_dgid(dev_addr, &path_rec.dgid);
  2553. path_rec.pkey = cpu_to_be16(ib_addr_get_pkey(dev_addr));
  2554. path_rec.numb_path = 1;
  2555. path_rec.reversible = 1;
  2556. path_rec.service_id = rdma_get_service_id(&id_priv->id,
  2557. cma_dst_addr(id_priv));
  2558. comp_mask = IB_SA_PATH_REC_DGID | IB_SA_PATH_REC_SGID |
  2559. IB_SA_PATH_REC_PKEY | IB_SA_PATH_REC_NUMB_PATH |
  2560. IB_SA_PATH_REC_REVERSIBLE | IB_SA_PATH_REC_SERVICE_ID;
  2561. switch (cma_family(id_priv)) {
  2562. case AF_INET:
  2563. path_rec.qos_class = cpu_to_be16((u16) id_priv->tos);
  2564. comp_mask |= IB_SA_PATH_REC_QOS_CLASS;
  2565. break;
  2566. case AF_INET6:
  2567. sin6 = (struct sockaddr_in6 *) cma_src_addr(id_priv);
  2568. path_rec.traffic_class = (u8) (be32_to_cpu(sin6->sin6_flowinfo) >> 20);
  2569. comp_mask |= IB_SA_PATH_REC_TRAFFIC_CLASS;
  2570. break;
  2571. case AF_IB:
  2572. sib = (struct sockaddr_ib *) cma_src_addr(id_priv);
  2573. path_rec.traffic_class = (u8) (be32_to_cpu(sib->sib_flowinfo) >> 20);
  2574. comp_mask |= IB_SA_PATH_REC_TRAFFIC_CLASS;
  2575. break;
  2576. }
  2577. id_priv->query_id = ib_sa_path_rec_get(&sa_client, id_priv->id.device,
  2578. id_priv->id.port_num, &path_rec,
  2579. comp_mask, timeout_ms,
  2580. GFP_KERNEL, cma_query_handler,
  2581. work, &id_priv->query);
  2582. return (id_priv->query_id < 0) ? id_priv->query_id : 0;
  2583. }
  2584. static void cma_iboe_join_work_handler(struct work_struct *work)
  2585. {
  2586. struct cma_multicast *mc =
  2587. container_of(work, struct cma_multicast, iboe_join.work);
  2588. struct rdma_cm_event *event = &mc->iboe_join.event;
  2589. struct rdma_id_private *id_priv = mc->id_priv;
  2590. int ret;
  2591. mutex_lock(&id_priv->handler_mutex);
  2592. if (READ_ONCE(id_priv->state) == RDMA_CM_DESTROYING ||
  2593. READ_ONCE(id_priv->state) == RDMA_CM_DEVICE_REMOVAL)
  2594. goto out_unlock;
  2595. ret = cma_cm_event_handler(id_priv, event);
  2596. WARN_ON(ret);
  2597. out_unlock:
  2598. mutex_unlock(&id_priv->handler_mutex);
  2599. if (event->event == RDMA_CM_EVENT_MULTICAST_JOIN)
  2600. rdma_destroy_ah_attr(&event->param.ud.ah_attr);
  2601. }
  2602. static void cma_work_handler(struct work_struct *_work)
  2603. {
  2604. struct cma_work *work = container_of(_work, struct cma_work, work);
  2605. struct rdma_id_private *id_priv = work->id;
  2606. mutex_lock(&id_priv->handler_mutex);
  2607. if (READ_ONCE(id_priv->state) == RDMA_CM_DESTROYING ||
  2608. READ_ONCE(id_priv->state) == RDMA_CM_DEVICE_REMOVAL)
  2609. goto out_unlock;
  2610. if (work->old_state != 0 || work->new_state != 0) {
  2611. if (!cma_comp_exch(id_priv, work->old_state, work->new_state))
  2612. goto out_unlock;
  2613. }
  2614. if (cma_cm_event_handler(id_priv, &work->event)) {
  2615. cma_id_put(id_priv);
  2616. destroy_id_handler_unlock(id_priv);
  2617. goto out_free;
  2618. }
  2619. out_unlock:
  2620. mutex_unlock(&id_priv->handler_mutex);
  2621. cma_id_put(id_priv);
  2622. out_free:
  2623. if (work->event.event == RDMA_CM_EVENT_MULTICAST_JOIN)
  2624. rdma_destroy_ah_attr(&work->event.param.ud.ah_attr);
  2625. kfree(work);
  2626. }
  2627. static void cma_init_resolve_route_work(struct cma_work *work,
  2628. struct rdma_id_private *id_priv)
  2629. {
  2630. work->id = id_priv;
  2631. INIT_WORK(&work->work, cma_work_handler);
  2632. work->old_state = RDMA_CM_ROUTE_QUERY;
  2633. work->new_state = RDMA_CM_ROUTE_RESOLVED;
  2634. work->event.event = RDMA_CM_EVENT_ROUTE_RESOLVED;
  2635. }
  2636. static void enqueue_resolve_addr_work(struct cma_work *work,
  2637. struct rdma_id_private *id_priv)
  2638. {
  2639. /* Balances with cma_id_put() in cma_work_handler */
  2640. cma_id_get(id_priv);
  2641. work->id = id_priv;
  2642. INIT_WORK(&work->work, cma_work_handler);
  2643. work->old_state = RDMA_CM_ADDR_QUERY;
  2644. work->new_state = RDMA_CM_ADDR_RESOLVED;
  2645. work->event.event = RDMA_CM_EVENT_ADDR_RESOLVED;
  2646. queue_work(cma_wq, &work->work);
  2647. }
  2648. static int cma_resolve_ib_route(struct rdma_id_private *id_priv,
  2649. unsigned long timeout_ms)
  2650. {
  2651. struct rdma_route *route = &id_priv->id.route;
  2652. struct cma_work *work;
  2653. int ret;
  2654. work = kzalloc_obj(*work);
  2655. if (!work)
  2656. return -ENOMEM;
  2657. cma_init_resolve_route_work(work, id_priv);
  2658. if (!route->path_rec)
  2659. route->path_rec = kmalloc_obj(*route->path_rec);
  2660. if (!route->path_rec) {
  2661. ret = -ENOMEM;
  2662. goto err1;
  2663. }
  2664. ret = cma_query_ib_route(id_priv, timeout_ms, work);
  2665. if (ret)
  2666. goto err2;
  2667. return 0;
  2668. err2:
  2669. kfree(route->path_rec);
  2670. route->path_rec = NULL;
  2671. err1:
  2672. kfree(work);
  2673. return ret;
  2674. }
  2675. static enum ib_gid_type cma_route_gid_type(enum rdma_network_type network_type,
  2676. unsigned long supported_gids,
  2677. enum ib_gid_type default_gid)
  2678. {
  2679. if ((network_type == RDMA_NETWORK_IPV4 ||
  2680. network_type == RDMA_NETWORK_IPV6) &&
  2681. test_bit(IB_GID_TYPE_ROCE_UDP_ENCAP, &supported_gids))
  2682. return IB_GID_TYPE_ROCE_UDP_ENCAP;
  2683. return default_gid;
  2684. }
  2685. /*
  2686. * cma_iboe_set_path_rec_l2_fields() is helper function which sets
  2687. * path record type based on GID type.
  2688. * It also sets up other L2 fields which includes destination mac address
  2689. * netdev ifindex, of the path record.
  2690. * It returns the netdev of the bound interface for this path record entry.
  2691. */
  2692. static struct net_device *
  2693. cma_iboe_set_path_rec_l2_fields(struct rdma_id_private *id_priv)
  2694. {
  2695. struct rdma_route *route = &id_priv->id.route;
  2696. enum ib_gid_type gid_type = IB_GID_TYPE_ROCE;
  2697. struct rdma_addr *addr = &route->addr;
  2698. unsigned long supported_gids;
  2699. struct net_device *ndev;
  2700. if (!addr->dev_addr.bound_dev_if)
  2701. return NULL;
  2702. ndev = dev_get_by_index(addr->dev_addr.net,
  2703. addr->dev_addr.bound_dev_if);
  2704. if (!ndev)
  2705. return NULL;
  2706. supported_gids = roce_gid_type_mask_support(id_priv->id.device,
  2707. id_priv->id.port_num);
  2708. gid_type = cma_route_gid_type(addr->dev_addr.network,
  2709. supported_gids,
  2710. id_priv->gid_type);
  2711. /* Use the hint from IP Stack to select GID Type */
  2712. if (gid_type < ib_network_to_gid_type(addr->dev_addr.network))
  2713. gid_type = ib_network_to_gid_type(addr->dev_addr.network);
  2714. route->path_rec->rec_type = sa_conv_gid_to_pathrec_type(gid_type);
  2715. route->path_rec->roce.route_resolved = true;
  2716. sa_path_set_dmac(route->path_rec, addr->dev_addr.dst_dev_addr);
  2717. return ndev;
  2718. }
  2719. int rdma_set_ib_path(struct rdma_cm_id *id,
  2720. struct sa_path_rec *path_rec)
  2721. {
  2722. struct rdma_id_private *id_priv;
  2723. struct net_device *ndev;
  2724. int ret;
  2725. id_priv = container_of(id, struct rdma_id_private, id);
  2726. if (!cma_comp_exch(id_priv, RDMA_CM_ADDR_RESOLVED,
  2727. RDMA_CM_ROUTE_RESOLVED))
  2728. return -EINVAL;
  2729. id->route.path_rec = kmemdup(path_rec, sizeof(*path_rec),
  2730. GFP_KERNEL);
  2731. if (!id->route.path_rec) {
  2732. ret = -ENOMEM;
  2733. goto err;
  2734. }
  2735. if (rdma_protocol_roce(id->device, id->port_num)) {
  2736. ndev = cma_iboe_set_path_rec_l2_fields(id_priv);
  2737. if (!ndev) {
  2738. ret = -ENODEV;
  2739. goto err_free;
  2740. }
  2741. dev_put(ndev);
  2742. }
  2743. id->route.num_pri_alt_paths = 1;
  2744. return 0;
  2745. err_free:
  2746. kfree(id->route.path_rec);
  2747. id->route.path_rec = NULL;
  2748. err:
  2749. cma_comp_exch(id_priv, RDMA_CM_ROUTE_RESOLVED, RDMA_CM_ADDR_RESOLVED);
  2750. return ret;
  2751. }
  2752. EXPORT_SYMBOL(rdma_set_ib_path);
  2753. static int cma_resolve_iw_route(struct rdma_id_private *id_priv)
  2754. {
  2755. struct cma_work *work;
  2756. work = kzalloc_obj(*work);
  2757. if (!work)
  2758. return -ENOMEM;
  2759. cma_init_resolve_route_work(work, id_priv);
  2760. queue_work(cma_wq, &work->work);
  2761. return 0;
  2762. }
  2763. static int get_vlan_ndev_tc(struct net_device *vlan_ndev, int prio)
  2764. {
  2765. struct net_device *dev;
  2766. dev = vlan_dev_real_dev(vlan_ndev);
  2767. if (dev->num_tc)
  2768. return netdev_get_prio_tc_map(dev, prio);
  2769. return (vlan_dev_get_egress_qos_mask(vlan_ndev, prio) &
  2770. VLAN_PRIO_MASK) >> VLAN_PRIO_SHIFT;
  2771. }
  2772. struct iboe_prio_tc_map {
  2773. int input_prio;
  2774. int output_tc;
  2775. bool found;
  2776. };
  2777. static int get_lower_vlan_dev_tc(struct net_device *dev,
  2778. struct netdev_nested_priv *priv)
  2779. {
  2780. struct iboe_prio_tc_map *map = (struct iboe_prio_tc_map *)priv->data;
  2781. if (is_vlan_dev(dev))
  2782. map->output_tc = get_vlan_ndev_tc(dev, map->input_prio);
  2783. else if (dev->num_tc)
  2784. map->output_tc = netdev_get_prio_tc_map(dev, map->input_prio);
  2785. else
  2786. map->output_tc = 0;
  2787. /* We are interested only in first level VLAN device, so always
  2788. * return 1 to stop iterating over next level devices.
  2789. */
  2790. map->found = true;
  2791. return 1;
  2792. }
  2793. static int iboe_tos_to_sl(struct net_device *ndev, int tos)
  2794. {
  2795. struct iboe_prio_tc_map prio_tc_map = {};
  2796. int prio = rt_tos2priority(tos);
  2797. struct netdev_nested_priv priv;
  2798. /* If VLAN device, get it directly from the VLAN netdev */
  2799. if (is_vlan_dev(ndev))
  2800. return get_vlan_ndev_tc(ndev, prio);
  2801. prio_tc_map.input_prio = prio;
  2802. priv.data = (void *)&prio_tc_map;
  2803. rcu_read_lock();
  2804. netdev_walk_all_lower_dev_rcu(ndev,
  2805. get_lower_vlan_dev_tc,
  2806. &priv);
  2807. rcu_read_unlock();
  2808. /* If map is found from lower device, use it; Otherwise
  2809. * continue with the current netdevice to get priority to tc map.
  2810. */
  2811. if (prio_tc_map.found)
  2812. return prio_tc_map.output_tc;
  2813. else if (ndev->num_tc)
  2814. return netdev_get_prio_tc_map(ndev, prio);
  2815. else
  2816. return 0;
  2817. }
  2818. static __be32 cma_get_roce_udp_flow_label(struct rdma_id_private *id_priv)
  2819. {
  2820. struct sockaddr_in6 *addr6;
  2821. u16 dport, sport;
  2822. u32 hash, fl;
  2823. addr6 = (struct sockaddr_in6 *)cma_src_addr(id_priv);
  2824. fl = be32_to_cpu(addr6->sin6_flowinfo) & IB_GRH_FLOWLABEL_MASK;
  2825. if ((cma_family(id_priv) != AF_INET6) || !fl) {
  2826. dport = be16_to_cpu(cma_port(cma_dst_addr(id_priv)));
  2827. sport = be16_to_cpu(cma_port(cma_src_addr(id_priv)));
  2828. hash = (u32)sport * 31 + dport;
  2829. fl = hash & IB_GRH_FLOWLABEL_MASK;
  2830. }
  2831. return cpu_to_be32(fl);
  2832. }
  2833. static int cma_resolve_iboe_route(struct rdma_id_private *id_priv)
  2834. {
  2835. struct rdma_route *route = &id_priv->id.route;
  2836. struct rdma_addr *addr = &route->addr;
  2837. struct cma_work *work;
  2838. int ret;
  2839. struct net_device *ndev;
  2840. u8 default_roce_tos = id_priv->cma_dev->default_roce_tos[id_priv->id.port_num -
  2841. rdma_start_port(id_priv->cma_dev->device)];
  2842. u8 tos;
  2843. mutex_lock(&id_priv->qp_mutex);
  2844. tos = id_priv->tos_set ? id_priv->tos : default_roce_tos;
  2845. mutex_unlock(&id_priv->qp_mutex);
  2846. work = kzalloc_obj(*work);
  2847. if (!work)
  2848. return -ENOMEM;
  2849. route->path_rec = kzalloc_obj(*route->path_rec);
  2850. if (!route->path_rec) {
  2851. ret = -ENOMEM;
  2852. goto err1;
  2853. }
  2854. route->num_pri_alt_paths = 1;
  2855. ndev = cma_iboe_set_path_rec_l2_fields(id_priv);
  2856. if (!ndev) {
  2857. ret = -ENODEV;
  2858. goto err2;
  2859. }
  2860. rdma_ip2gid((struct sockaddr *)&id_priv->id.route.addr.src_addr,
  2861. &route->path_rec->sgid);
  2862. rdma_ip2gid((struct sockaddr *)&id_priv->id.route.addr.dst_addr,
  2863. &route->path_rec->dgid);
  2864. if (((struct sockaddr *)&id_priv->id.route.addr.dst_addr)->sa_family != AF_IB)
  2865. /* TODO: get the hoplimit from the inet/inet6 device */
  2866. route->path_rec->hop_limit = addr->dev_addr.hoplimit;
  2867. else
  2868. route->path_rec->hop_limit = 1;
  2869. route->path_rec->reversible = 1;
  2870. route->path_rec->pkey = cpu_to_be16(0xffff);
  2871. route->path_rec->mtu_selector = IB_SA_EQ;
  2872. route->path_rec->sl = iboe_tos_to_sl(ndev, tos);
  2873. route->path_rec->traffic_class = tos;
  2874. route->path_rec->mtu = iboe_get_mtu(ndev->mtu);
  2875. route->path_rec->rate_selector = IB_SA_EQ;
  2876. route->path_rec->rate = IB_RATE_PORT_CURRENT;
  2877. dev_put(ndev);
  2878. route->path_rec->packet_life_time_selector = IB_SA_EQ;
  2879. /* In case ACK timeout is set, use this value to calculate
  2880. * PacketLifeTime. As per IBTA 12.7.34,
  2881. * local ACK timeout = (2 * PacketLifeTime + Local CA’s ACK delay).
  2882. * Assuming a negligible local ACK delay, we can use
  2883. * PacketLifeTime = local ACK timeout/2
  2884. * as a reasonable approximation for RoCE networks.
  2885. */
  2886. mutex_lock(&id_priv->qp_mutex);
  2887. if (id_priv->timeout_set && id_priv->timeout)
  2888. route->path_rec->packet_life_time = id_priv->timeout - 1;
  2889. else
  2890. route->path_rec->packet_life_time = CMA_IBOE_PACKET_LIFETIME;
  2891. mutex_unlock(&id_priv->qp_mutex);
  2892. if (!route->path_rec->mtu) {
  2893. ret = -EINVAL;
  2894. goto err2;
  2895. }
  2896. if (rdma_protocol_roce_udp_encap(id_priv->id.device,
  2897. id_priv->id.port_num))
  2898. route->path_rec->flow_label =
  2899. cma_get_roce_udp_flow_label(id_priv);
  2900. cma_init_resolve_route_work(work, id_priv);
  2901. queue_work(cma_wq, &work->work);
  2902. return 0;
  2903. err2:
  2904. kfree(route->path_rec);
  2905. route->path_rec = NULL;
  2906. route->num_pri_alt_paths = 0;
  2907. err1:
  2908. kfree(work);
  2909. return ret;
  2910. }
  2911. int rdma_resolve_route(struct rdma_cm_id *id, unsigned long timeout_ms)
  2912. {
  2913. struct rdma_id_private *id_priv;
  2914. enum rdma_cm_state state;
  2915. int ret;
  2916. if (!timeout_ms)
  2917. return -EINVAL;
  2918. id_priv = container_of(id, struct rdma_id_private, id);
  2919. state = id_priv->state;
  2920. if (!cma_comp_exch(id_priv, RDMA_CM_ADDR_RESOLVED,
  2921. RDMA_CM_ROUTE_QUERY) &&
  2922. !cma_comp_exch(id_priv, RDMA_CM_ADDRINFO_RESOLVED,
  2923. RDMA_CM_ROUTE_QUERY))
  2924. return -EINVAL;
  2925. cma_id_get(id_priv);
  2926. if (rdma_cap_ib_sa(id->device, id->port_num))
  2927. ret = cma_resolve_ib_route(id_priv, timeout_ms);
  2928. else if (rdma_protocol_roce(id->device, id->port_num)) {
  2929. ret = cma_resolve_iboe_route(id_priv);
  2930. if (!ret)
  2931. cma_add_id_to_tree(id_priv);
  2932. }
  2933. else if (rdma_protocol_iwarp(id->device, id->port_num))
  2934. ret = cma_resolve_iw_route(id_priv);
  2935. else
  2936. ret = -ENOSYS;
  2937. if (ret)
  2938. goto err;
  2939. return 0;
  2940. err:
  2941. cma_comp_exch(id_priv, RDMA_CM_ROUTE_QUERY, state);
  2942. cma_id_put(id_priv);
  2943. return ret;
  2944. }
  2945. EXPORT_SYMBOL(rdma_resolve_route);
  2946. static void cma_set_loopback(struct sockaddr *addr)
  2947. {
  2948. switch (addr->sa_family) {
  2949. case AF_INET:
  2950. ((struct sockaddr_in *) addr)->sin_addr.s_addr = htonl(INADDR_LOOPBACK);
  2951. break;
  2952. case AF_INET6:
  2953. ipv6_addr_set(&((struct sockaddr_in6 *) addr)->sin6_addr,
  2954. 0, 0, 0, htonl(1));
  2955. break;
  2956. default:
  2957. ib_addr_set(&((struct sockaddr_ib *) addr)->sib_addr,
  2958. 0, 0, 0, htonl(1));
  2959. break;
  2960. }
  2961. }
  2962. static int cma_bind_loopback(struct rdma_id_private *id_priv)
  2963. {
  2964. struct cma_device *cma_dev, *cur_dev;
  2965. union ib_gid gid;
  2966. enum ib_port_state port_state;
  2967. unsigned int p;
  2968. u16 pkey;
  2969. int ret;
  2970. cma_dev = NULL;
  2971. mutex_lock(&lock);
  2972. list_for_each_entry(cur_dev, &dev_list, list) {
  2973. if (cma_family(id_priv) == AF_IB &&
  2974. !rdma_cap_ib_cm(cur_dev->device, 1))
  2975. continue;
  2976. if (!cma_dev)
  2977. cma_dev = cur_dev;
  2978. rdma_for_each_port (cur_dev->device, p) {
  2979. if (!ib_get_cached_port_state(cur_dev->device, p, &port_state) &&
  2980. port_state == IB_PORT_ACTIVE) {
  2981. cma_dev = cur_dev;
  2982. goto port_found;
  2983. }
  2984. }
  2985. }
  2986. if (!cma_dev) {
  2987. ret = -ENODEV;
  2988. goto out;
  2989. }
  2990. p = 1;
  2991. port_found:
  2992. ret = rdma_query_gid(cma_dev->device, p, 0, &gid);
  2993. if (ret)
  2994. goto out;
  2995. ret = ib_get_cached_pkey(cma_dev->device, p, 0, &pkey);
  2996. if (ret)
  2997. goto out;
  2998. id_priv->id.route.addr.dev_addr.dev_type =
  2999. (rdma_protocol_ib(cma_dev->device, p)) ?
  3000. ARPHRD_INFINIBAND : ARPHRD_ETHER;
  3001. rdma_addr_set_sgid(&id_priv->id.route.addr.dev_addr, &gid);
  3002. ib_addr_set_pkey(&id_priv->id.route.addr.dev_addr, pkey);
  3003. id_priv->id.port_num = p;
  3004. cma_attach_to_dev(id_priv, cma_dev);
  3005. rdma_restrack_add(&id_priv->res);
  3006. cma_set_loopback(cma_src_addr(id_priv));
  3007. out:
  3008. mutex_unlock(&lock);
  3009. return ret;
  3010. }
  3011. static void addr_handler(int status, struct sockaddr *src_addr,
  3012. struct rdma_dev_addr *dev_addr, void *context)
  3013. {
  3014. struct rdma_id_private *id_priv = context;
  3015. struct rdma_cm_event event = {};
  3016. struct sockaddr *addr;
  3017. struct sockaddr_storage old_addr;
  3018. mutex_lock(&id_priv->handler_mutex);
  3019. if (!cma_comp_exch(id_priv, RDMA_CM_ADDR_QUERY,
  3020. RDMA_CM_ADDR_RESOLVED))
  3021. goto out;
  3022. /*
  3023. * Store the previous src address, so that if we fail to acquire
  3024. * matching rdma device, old address can be restored back, which helps
  3025. * to cancel the cma listen operation correctly.
  3026. */
  3027. addr = cma_src_addr(id_priv);
  3028. memcpy(&old_addr, addr, rdma_addr_size(addr));
  3029. memcpy(addr, src_addr, rdma_addr_size(src_addr));
  3030. if (!status && !id_priv->cma_dev) {
  3031. status = cma_acquire_dev_by_src_ip(id_priv);
  3032. if (status)
  3033. pr_debug_ratelimited("RDMA CM: ADDR_ERROR: failed to acquire device. status %d\n",
  3034. status);
  3035. rdma_restrack_add(&id_priv->res);
  3036. } else if (status) {
  3037. pr_debug_ratelimited("RDMA CM: ADDR_ERROR: failed to resolve IP. status %d\n", status);
  3038. }
  3039. if (status) {
  3040. memcpy(addr, &old_addr,
  3041. rdma_addr_size((struct sockaddr *)&old_addr));
  3042. if (!cma_comp_exch(id_priv, RDMA_CM_ADDR_RESOLVED,
  3043. RDMA_CM_ADDR_BOUND))
  3044. goto out;
  3045. event.event = RDMA_CM_EVENT_ADDR_ERROR;
  3046. event.status = status;
  3047. } else
  3048. event.event = RDMA_CM_EVENT_ADDR_RESOLVED;
  3049. if (cma_cm_event_handler(id_priv, &event)) {
  3050. destroy_id_handler_unlock(id_priv);
  3051. return;
  3052. }
  3053. out:
  3054. mutex_unlock(&id_priv->handler_mutex);
  3055. }
  3056. static int cma_resolve_loopback(struct rdma_id_private *id_priv)
  3057. {
  3058. struct cma_work *work;
  3059. union ib_gid gid;
  3060. int ret;
  3061. work = kzalloc_obj(*work);
  3062. if (!work)
  3063. return -ENOMEM;
  3064. if (!id_priv->cma_dev) {
  3065. ret = cma_bind_loopback(id_priv);
  3066. if (ret)
  3067. goto err;
  3068. }
  3069. rdma_addr_get_sgid(&id_priv->id.route.addr.dev_addr, &gid);
  3070. rdma_addr_set_dgid(&id_priv->id.route.addr.dev_addr, &gid);
  3071. enqueue_resolve_addr_work(work, id_priv);
  3072. return 0;
  3073. err:
  3074. kfree(work);
  3075. return ret;
  3076. }
  3077. static int cma_resolve_ib_addr(struct rdma_id_private *id_priv)
  3078. {
  3079. struct cma_work *work;
  3080. int ret;
  3081. work = kzalloc_obj(*work);
  3082. if (!work)
  3083. return -ENOMEM;
  3084. if (!id_priv->cma_dev) {
  3085. ret = cma_resolve_ib_dev(id_priv);
  3086. if (ret)
  3087. goto err;
  3088. }
  3089. rdma_addr_set_dgid(&id_priv->id.route.addr.dev_addr, (union ib_gid *)
  3090. &(((struct sockaddr_ib *) &id_priv->id.route.addr.dst_addr)->sib_addr));
  3091. enqueue_resolve_addr_work(work, id_priv);
  3092. return 0;
  3093. err:
  3094. kfree(work);
  3095. return ret;
  3096. }
  3097. int rdma_set_reuseaddr(struct rdma_cm_id *id, int reuse)
  3098. {
  3099. struct rdma_id_private *id_priv;
  3100. unsigned long flags;
  3101. int ret;
  3102. id_priv = container_of(id, struct rdma_id_private, id);
  3103. spin_lock_irqsave(&id_priv->lock, flags);
  3104. if ((reuse && id_priv->state != RDMA_CM_LISTEN) ||
  3105. id_priv->state == RDMA_CM_IDLE) {
  3106. id_priv->reuseaddr = reuse;
  3107. ret = 0;
  3108. } else {
  3109. ret = -EINVAL;
  3110. }
  3111. spin_unlock_irqrestore(&id_priv->lock, flags);
  3112. return ret;
  3113. }
  3114. EXPORT_SYMBOL(rdma_set_reuseaddr);
  3115. int rdma_set_afonly(struct rdma_cm_id *id, int afonly)
  3116. {
  3117. struct rdma_id_private *id_priv;
  3118. unsigned long flags;
  3119. int ret;
  3120. id_priv = container_of(id, struct rdma_id_private, id);
  3121. spin_lock_irqsave(&id_priv->lock, flags);
  3122. if (id_priv->state == RDMA_CM_IDLE || id_priv->state == RDMA_CM_ADDR_BOUND) {
  3123. id_priv->options |= (1 << CMA_OPTION_AFONLY);
  3124. id_priv->afonly = afonly;
  3125. ret = 0;
  3126. } else {
  3127. ret = -EINVAL;
  3128. }
  3129. spin_unlock_irqrestore(&id_priv->lock, flags);
  3130. return ret;
  3131. }
  3132. EXPORT_SYMBOL(rdma_set_afonly);
  3133. static void cma_bind_port(struct rdma_bind_list *bind_list,
  3134. struct rdma_id_private *id_priv)
  3135. {
  3136. struct sockaddr *addr;
  3137. struct sockaddr_ib *sib;
  3138. u64 sid, mask;
  3139. __be16 port;
  3140. lockdep_assert_held(&lock);
  3141. addr = cma_src_addr(id_priv);
  3142. port = htons(bind_list->port);
  3143. switch (addr->sa_family) {
  3144. case AF_INET:
  3145. ((struct sockaddr_in *) addr)->sin_port = port;
  3146. break;
  3147. case AF_INET6:
  3148. ((struct sockaddr_in6 *) addr)->sin6_port = port;
  3149. break;
  3150. case AF_IB:
  3151. sib = (struct sockaddr_ib *) addr;
  3152. sid = be64_to_cpu(sib->sib_sid);
  3153. mask = be64_to_cpu(sib->sib_sid_mask);
  3154. sib->sib_sid = cpu_to_be64((sid & mask) | (u64) ntohs(port));
  3155. sib->sib_sid_mask = cpu_to_be64(~0ULL);
  3156. break;
  3157. }
  3158. id_priv->bind_list = bind_list;
  3159. hlist_add_head(&id_priv->node, &bind_list->owners);
  3160. }
  3161. static int cma_alloc_port(enum rdma_ucm_port_space ps,
  3162. struct rdma_id_private *id_priv, unsigned short snum)
  3163. {
  3164. struct rdma_bind_list *bind_list;
  3165. int ret;
  3166. lockdep_assert_held(&lock);
  3167. bind_list = kzalloc_obj(*bind_list);
  3168. if (!bind_list)
  3169. return -ENOMEM;
  3170. ret = cma_ps_alloc(id_priv->id.route.addr.dev_addr.net, ps, bind_list,
  3171. snum);
  3172. if (ret < 0)
  3173. goto err;
  3174. bind_list->ps = ps;
  3175. bind_list->port = snum;
  3176. cma_bind_port(bind_list, id_priv);
  3177. return 0;
  3178. err:
  3179. kfree(bind_list);
  3180. return ret == -ENOSPC ? -EADDRNOTAVAIL : ret;
  3181. }
  3182. static int cma_port_is_unique(struct rdma_bind_list *bind_list,
  3183. struct rdma_id_private *id_priv)
  3184. {
  3185. struct rdma_id_private *cur_id;
  3186. struct sockaddr *daddr = cma_dst_addr(id_priv);
  3187. struct sockaddr *saddr = cma_src_addr(id_priv);
  3188. __be16 dport = cma_port(daddr);
  3189. lockdep_assert_held(&lock);
  3190. hlist_for_each_entry(cur_id, &bind_list->owners, node) {
  3191. struct sockaddr *cur_daddr = cma_dst_addr(cur_id);
  3192. struct sockaddr *cur_saddr = cma_src_addr(cur_id);
  3193. __be16 cur_dport = cma_port(cur_daddr);
  3194. if (id_priv == cur_id)
  3195. continue;
  3196. /* different dest port -> unique */
  3197. if (!cma_any_port(daddr) &&
  3198. !cma_any_port(cur_daddr) &&
  3199. (dport != cur_dport))
  3200. continue;
  3201. /* different src address -> unique */
  3202. if (!cma_any_addr(saddr) &&
  3203. !cma_any_addr(cur_saddr) &&
  3204. cma_addr_cmp(saddr, cur_saddr))
  3205. continue;
  3206. /* different dst address -> unique */
  3207. if (!cma_any_addr(daddr) &&
  3208. !cma_any_addr(cur_daddr) &&
  3209. cma_addr_cmp(daddr, cur_daddr))
  3210. continue;
  3211. return -EADDRNOTAVAIL;
  3212. }
  3213. return 0;
  3214. }
  3215. static int cma_alloc_any_port(enum rdma_ucm_port_space ps,
  3216. struct rdma_id_private *id_priv)
  3217. {
  3218. static unsigned int last_used_port;
  3219. int low, high, remaining;
  3220. unsigned int rover;
  3221. struct net *net = id_priv->id.route.addr.dev_addr.net;
  3222. lockdep_assert_held(&lock);
  3223. inet_get_local_port_range(net, &low, &high);
  3224. remaining = (high - low) + 1;
  3225. rover = get_random_u32_inclusive(low, remaining + low - 1);
  3226. retry:
  3227. if (last_used_port != rover) {
  3228. struct rdma_bind_list *bind_list;
  3229. int ret;
  3230. bind_list = cma_ps_find(net, ps, (unsigned short)rover);
  3231. if (!bind_list) {
  3232. ret = cma_alloc_port(ps, id_priv, rover);
  3233. } else {
  3234. ret = cma_port_is_unique(bind_list, id_priv);
  3235. if (!ret)
  3236. cma_bind_port(bind_list, id_priv);
  3237. }
  3238. /*
  3239. * Remember previously used port number in order to avoid
  3240. * re-using same port immediately after it is closed.
  3241. */
  3242. if (!ret)
  3243. last_used_port = rover;
  3244. if (ret != -EADDRNOTAVAIL)
  3245. return ret;
  3246. }
  3247. if (--remaining) {
  3248. rover++;
  3249. if ((rover < low) || (rover > high))
  3250. rover = low;
  3251. goto retry;
  3252. }
  3253. return -EADDRNOTAVAIL;
  3254. }
  3255. /*
  3256. * Check that the requested port is available. This is called when trying to
  3257. * bind to a specific port, or when trying to listen on a bound port. In
  3258. * the latter case, the provided id_priv may already be on the bind_list, but
  3259. * we still need to check that it's okay to start listening.
  3260. */
  3261. static int cma_check_port(struct rdma_bind_list *bind_list,
  3262. struct rdma_id_private *id_priv, uint8_t reuseaddr)
  3263. {
  3264. struct rdma_id_private *cur_id;
  3265. struct sockaddr *addr, *cur_addr;
  3266. lockdep_assert_held(&lock);
  3267. addr = cma_src_addr(id_priv);
  3268. hlist_for_each_entry(cur_id, &bind_list->owners, node) {
  3269. if (id_priv == cur_id)
  3270. continue;
  3271. if (reuseaddr && cur_id->reuseaddr)
  3272. continue;
  3273. cur_addr = cma_src_addr(cur_id);
  3274. if (id_priv->afonly && cur_id->afonly &&
  3275. (addr->sa_family != cur_addr->sa_family))
  3276. continue;
  3277. if (cma_any_addr(addr) || cma_any_addr(cur_addr))
  3278. return -EADDRNOTAVAIL;
  3279. if (!cma_addr_cmp(addr, cur_addr))
  3280. return -EADDRINUSE;
  3281. }
  3282. return 0;
  3283. }
  3284. static int cma_use_port(enum rdma_ucm_port_space ps,
  3285. struct rdma_id_private *id_priv)
  3286. {
  3287. struct rdma_bind_list *bind_list;
  3288. unsigned short snum;
  3289. int ret;
  3290. lockdep_assert_held(&lock);
  3291. snum = ntohs(cma_port(cma_src_addr(id_priv)));
  3292. if (snum < PROT_SOCK && !capable(CAP_NET_BIND_SERVICE))
  3293. return -EACCES;
  3294. bind_list = cma_ps_find(id_priv->id.route.addr.dev_addr.net, ps, snum);
  3295. if (!bind_list) {
  3296. ret = cma_alloc_port(ps, id_priv, snum);
  3297. } else {
  3298. ret = cma_check_port(bind_list, id_priv, id_priv->reuseaddr);
  3299. if (!ret)
  3300. cma_bind_port(bind_list, id_priv);
  3301. }
  3302. return ret;
  3303. }
  3304. static enum rdma_ucm_port_space
  3305. cma_select_inet_ps(struct rdma_id_private *id_priv)
  3306. {
  3307. switch (id_priv->id.ps) {
  3308. case RDMA_PS_TCP:
  3309. case RDMA_PS_UDP:
  3310. case RDMA_PS_IPOIB:
  3311. case RDMA_PS_IB:
  3312. return id_priv->id.ps;
  3313. default:
  3314. return 0;
  3315. }
  3316. }
  3317. static enum rdma_ucm_port_space
  3318. cma_select_ib_ps(struct rdma_id_private *id_priv)
  3319. {
  3320. enum rdma_ucm_port_space ps = 0;
  3321. struct sockaddr_ib *sib;
  3322. u64 sid_ps, mask, sid;
  3323. sib = (struct sockaddr_ib *) cma_src_addr(id_priv);
  3324. mask = be64_to_cpu(sib->sib_sid_mask) & RDMA_IB_IP_PS_MASK;
  3325. sid = be64_to_cpu(sib->sib_sid) & mask;
  3326. if ((id_priv->id.ps == RDMA_PS_IB) && (sid == (RDMA_IB_IP_PS_IB & mask))) {
  3327. sid_ps = RDMA_IB_IP_PS_IB;
  3328. ps = RDMA_PS_IB;
  3329. } else if (((id_priv->id.ps == RDMA_PS_IB) || (id_priv->id.ps == RDMA_PS_TCP)) &&
  3330. (sid == (RDMA_IB_IP_PS_TCP & mask))) {
  3331. sid_ps = RDMA_IB_IP_PS_TCP;
  3332. ps = RDMA_PS_TCP;
  3333. } else if (((id_priv->id.ps == RDMA_PS_IB) || (id_priv->id.ps == RDMA_PS_UDP)) &&
  3334. (sid == (RDMA_IB_IP_PS_UDP & mask))) {
  3335. sid_ps = RDMA_IB_IP_PS_UDP;
  3336. ps = RDMA_PS_UDP;
  3337. }
  3338. if (ps) {
  3339. sib->sib_sid = cpu_to_be64(sid_ps | ntohs(cma_port((struct sockaddr *) sib)));
  3340. sib->sib_sid_mask = cpu_to_be64(RDMA_IB_IP_PS_MASK |
  3341. be64_to_cpu(sib->sib_sid_mask));
  3342. }
  3343. return ps;
  3344. }
  3345. static int cma_get_port(struct rdma_id_private *id_priv)
  3346. {
  3347. enum rdma_ucm_port_space ps;
  3348. int ret;
  3349. if (cma_family(id_priv) != AF_IB)
  3350. ps = cma_select_inet_ps(id_priv);
  3351. else
  3352. ps = cma_select_ib_ps(id_priv);
  3353. if (!ps)
  3354. return -EPROTONOSUPPORT;
  3355. mutex_lock(&lock);
  3356. if (cma_any_port(cma_src_addr(id_priv)))
  3357. ret = cma_alloc_any_port(ps, id_priv);
  3358. else
  3359. ret = cma_use_port(ps, id_priv);
  3360. mutex_unlock(&lock);
  3361. return ret;
  3362. }
  3363. static int cma_check_linklocal(struct rdma_dev_addr *dev_addr,
  3364. struct sockaddr *addr)
  3365. {
  3366. #if IS_ENABLED(CONFIG_IPV6)
  3367. struct sockaddr_in6 *sin6;
  3368. if (addr->sa_family != AF_INET6)
  3369. return 0;
  3370. sin6 = (struct sockaddr_in6 *) addr;
  3371. if (!(ipv6_addr_type(&sin6->sin6_addr) & IPV6_ADDR_LINKLOCAL))
  3372. return 0;
  3373. if (!sin6->sin6_scope_id)
  3374. return -EINVAL;
  3375. dev_addr->bound_dev_if = sin6->sin6_scope_id;
  3376. #endif
  3377. return 0;
  3378. }
  3379. int rdma_listen(struct rdma_cm_id *id, int backlog)
  3380. {
  3381. struct rdma_id_private *id_priv =
  3382. container_of(id, struct rdma_id_private, id);
  3383. int ret;
  3384. if (!cma_comp_exch(id_priv, RDMA_CM_ADDR_BOUND, RDMA_CM_LISTEN)) {
  3385. struct sockaddr_in any_in = {
  3386. .sin_family = AF_INET,
  3387. .sin_addr.s_addr = htonl(INADDR_ANY),
  3388. };
  3389. /* For a well behaved ULP state will be RDMA_CM_IDLE */
  3390. ret = rdma_bind_addr(id, (struct sockaddr *)&any_in);
  3391. if (ret)
  3392. return ret;
  3393. if (WARN_ON(!cma_comp_exch(id_priv, RDMA_CM_ADDR_BOUND,
  3394. RDMA_CM_LISTEN)))
  3395. return -EINVAL;
  3396. }
  3397. /*
  3398. * Once the ID reaches RDMA_CM_LISTEN it is not allowed to be reusable
  3399. * any more, and has to be unique in the bind list.
  3400. */
  3401. if (id_priv->reuseaddr) {
  3402. mutex_lock(&lock);
  3403. ret = cma_check_port(id_priv->bind_list, id_priv, 0);
  3404. if (!ret)
  3405. id_priv->reuseaddr = 0;
  3406. mutex_unlock(&lock);
  3407. if (ret)
  3408. goto err;
  3409. }
  3410. id_priv->backlog = backlog;
  3411. if (id_priv->cma_dev) {
  3412. if (rdma_cap_ib_cm(id->device, 1)) {
  3413. ret = cma_ib_listen(id_priv);
  3414. if (ret)
  3415. goto err;
  3416. } else if (rdma_cap_iw_cm(id->device, 1)) {
  3417. ret = cma_iw_listen(id_priv, backlog);
  3418. if (ret)
  3419. goto err;
  3420. } else {
  3421. ret = -ENOSYS;
  3422. goto err;
  3423. }
  3424. } else {
  3425. ret = cma_listen_on_all(id_priv);
  3426. if (ret)
  3427. goto err;
  3428. }
  3429. return 0;
  3430. err:
  3431. id_priv->backlog = 0;
  3432. /*
  3433. * All the failure paths that lead here will not allow the req_handler's
  3434. * to have run.
  3435. */
  3436. cma_comp_exch(id_priv, RDMA_CM_LISTEN, RDMA_CM_ADDR_BOUND);
  3437. return ret;
  3438. }
  3439. EXPORT_SYMBOL(rdma_listen);
  3440. static int rdma_bind_addr_dst(struct rdma_id_private *id_priv,
  3441. struct sockaddr *addr, const struct sockaddr *daddr)
  3442. {
  3443. struct sockaddr *id_daddr;
  3444. int ret;
  3445. if (addr->sa_family != AF_INET && addr->sa_family != AF_INET6 &&
  3446. addr->sa_family != AF_IB)
  3447. return -EAFNOSUPPORT;
  3448. if (!cma_comp_exch(id_priv, RDMA_CM_IDLE, RDMA_CM_ADDR_BOUND))
  3449. return -EINVAL;
  3450. ret = cma_check_linklocal(&id_priv->id.route.addr.dev_addr, addr);
  3451. if (ret)
  3452. goto err1;
  3453. memcpy(cma_src_addr(id_priv), addr, rdma_addr_size(addr));
  3454. if (!cma_any_addr(addr)) {
  3455. ret = cma_translate_addr(addr, &id_priv->id.route.addr.dev_addr);
  3456. if (ret)
  3457. goto err1;
  3458. ret = cma_acquire_dev_by_src_ip(id_priv);
  3459. if (ret)
  3460. goto err1;
  3461. }
  3462. if (!(id_priv->options & (1 << CMA_OPTION_AFONLY))) {
  3463. if (addr->sa_family == AF_INET)
  3464. id_priv->afonly = 1;
  3465. #if IS_ENABLED(CONFIG_IPV6)
  3466. else if (addr->sa_family == AF_INET6) {
  3467. struct net *net = id_priv->id.route.addr.dev_addr.net;
  3468. id_priv->afonly = net->ipv6.sysctl.bindv6only;
  3469. }
  3470. #endif
  3471. }
  3472. id_daddr = cma_dst_addr(id_priv);
  3473. if (daddr != id_daddr)
  3474. memcpy(id_daddr, daddr, rdma_addr_size(addr));
  3475. id_daddr->sa_family = addr->sa_family;
  3476. ret = cma_get_port(id_priv);
  3477. if (ret)
  3478. goto err2;
  3479. if (!cma_any_addr(addr))
  3480. rdma_restrack_add(&id_priv->res);
  3481. return 0;
  3482. err2:
  3483. if (id_priv->cma_dev)
  3484. cma_release_dev(id_priv);
  3485. err1:
  3486. cma_comp_exch(id_priv, RDMA_CM_ADDR_BOUND, RDMA_CM_IDLE);
  3487. return ret;
  3488. }
  3489. static int cma_bind_addr(struct rdma_cm_id *id, struct sockaddr *src_addr,
  3490. const struct sockaddr *dst_addr)
  3491. {
  3492. struct rdma_id_private *id_priv =
  3493. container_of(id, struct rdma_id_private, id);
  3494. struct sockaddr_storage zero_sock = {};
  3495. if (src_addr && src_addr->sa_family)
  3496. return rdma_bind_addr_dst(id_priv, src_addr, dst_addr);
  3497. /*
  3498. * When the src_addr is not specified, automatically supply an any addr
  3499. */
  3500. zero_sock.ss_family = dst_addr->sa_family;
  3501. if (IS_ENABLED(CONFIG_IPV6) && dst_addr->sa_family == AF_INET6) {
  3502. struct sockaddr_in6 *src_addr6 =
  3503. (struct sockaddr_in6 *)&zero_sock;
  3504. struct sockaddr_in6 *dst_addr6 =
  3505. (struct sockaddr_in6 *)dst_addr;
  3506. src_addr6->sin6_scope_id = dst_addr6->sin6_scope_id;
  3507. if (ipv6_addr_type(&dst_addr6->sin6_addr) & IPV6_ADDR_LINKLOCAL)
  3508. id->route.addr.dev_addr.bound_dev_if =
  3509. dst_addr6->sin6_scope_id;
  3510. } else if (dst_addr->sa_family == AF_IB) {
  3511. ((struct sockaddr_ib *)&zero_sock)->sib_pkey =
  3512. ((struct sockaddr_ib *)dst_addr)->sib_pkey;
  3513. }
  3514. return rdma_bind_addr_dst(id_priv, (struct sockaddr *)&zero_sock, dst_addr);
  3515. }
  3516. /*
  3517. * If required, resolve the source address for bind and leave the id_priv in
  3518. * state RDMA_CM_ADDR_BOUND. This oddly uses the state to determine the prior
  3519. * calls made by ULP, a previously bound ID will not be re-bound and src_addr is
  3520. * ignored.
  3521. */
  3522. static int resolve_prepare_src(struct rdma_id_private *id_priv,
  3523. struct sockaddr *src_addr,
  3524. const struct sockaddr *dst_addr)
  3525. {
  3526. int ret;
  3527. if (!cma_comp_exch(id_priv, RDMA_CM_ADDR_BOUND, RDMA_CM_ADDR_QUERY)) {
  3528. /* For a well behaved ULP state will be RDMA_CM_IDLE */
  3529. ret = cma_bind_addr(&id_priv->id, src_addr, dst_addr);
  3530. if (ret)
  3531. return ret;
  3532. if (WARN_ON(!cma_comp_exch(id_priv, RDMA_CM_ADDR_BOUND,
  3533. RDMA_CM_ADDR_QUERY)))
  3534. return -EINVAL;
  3535. } else {
  3536. memcpy(cma_dst_addr(id_priv), dst_addr, rdma_addr_size(dst_addr));
  3537. }
  3538. if (cma_family(id_priv) != dst_addr->sa_family) {
  3539. ret = -EINVAL;
  3540. goto err_state;
  3541. }
  3542. return 0;
  3543. err_state:
  3544. cma_comp_exch(id_priv, RDMA_CM_ADDR_QUERY, RDMA_CM_ADDR_BOUND);
  3545. return ret;
  3546. }
  3547. int rdma_resolve_addr(struct rdma_cm_id *id, struct sockaddr *src_addr,
  3548. const struct sockaddr *dst_addr, unsigned long timeout_ms)
  3549. {
  3550. struct rdma_id_private *id_priv =
  3551. container_of(id, struct rdma_id_private, id);
  3552. int ret;
  3553. ret = resolve_prepare_src(id_priv, src_addr, dst_addr);
  3554. if (ret)
  3555. return ret;
  3556. if (cma_any_addr(dst_addr)) {
  3557. ret = cma_resolve_loopback(id_priv);
  3558. } else {
  3559. if (dst_addr->sa_family == AF_IB) {
  3560. ret = cma_resolve_ib_addr(id_priv);
  3561. } else {
  3562. /*
  3563. * The FSM can return back to RDMA_CM_ADDR_BOUND after
  3564. * rdma_resolve_ip() is called, eg through the error
  3565. * path in addr_handler(). If this happens the existing
  3566. * request must be canceled before issuing a new one.
  3567. * Since canceling a request is a bit slow and this
  3568. * oddball path is rare, keep track once a request has
  3569. * been issued. The track turns out to be a permanent
  3570. * state since this is the only cancel as it is
  3571. * immediately before rdma_resolve_ip().
  3572. */
  3573. if (id_priv->used_resolve_ip)
  3574. rdma_addr_cancel(&id->route.addr.dev_addr);
  3575. else
  3576. id_priv->used_resolve_ip = 1;
  3577. ret = rdma_resolve_ip(cma_src_addr(id_priv), dst_addr,
  3578. &id->route.addr.dev_addr,
  3579. timeout_ms, addr_handler,
  3580. false, id_priv);
  3581. }
  3582. }
  3583. if (ret)
  3584. goto err;
  3585. return 0;
  3586. err:
  3587. cma_comp_exch(id_priv, RDMA_CM_ADDR_QUERY, RDMA_CM_ADDR_BOUND);
  3588. return ret;
  3589. }
  3590. EXPORT_SYMBOL(rdma_resolve_addr);
  3591. int rdma_restrict_node_type(struct rdma_cm_id *id, u8 node_type)
  3592. {
  3593. struct rdma_id_private *id_priv =
  3594. container_of(id, struct rdma_id_private, id);
  3595. int ret = 0;
  3596. switch (node_type) {
  3597. case RDMA_NODE_UNSPECIFIED:
  3598. case RDMA_NODE_IB_CA:
  3599. case RDMA_NODE_RNIC:
  3600. break;
  3601. default:
  3602. return -EINVAL;
  3603. }
  3604. mutex_lock(&lock);
  3605. if (READ_ONCE(id_priv->state) != RDMA_CM_IDLE)
  3606. ret = -EALREADY;
  3607. else
  3608. id_priv->restricted_node_type = node_type;
  3609. mutex_unlock(&lock);
  3610. return ret;
  3611. }
  3612. EXPORT_SYMBOL(rdma_restrict_node_type);
  3613. int rdma_bind_addr(struct rdma_cm_id *id, struct sockaddr *addr)
  3614. {
  3615. struct rdma_id_private *id_priv =
  3616. container_of(id, struct rdma_id_private, id);
  3617. return rdma_bind_addr_dst(id_priv, addr, cma_dst_addr(id_priv));
  3618. }
  3619. EXPORT_SYMBOL(rdma_bind_addr);
  3620. static int cma_format_hdr(void *hdr, struct rdma_id_private *id_priv)
  3621. {
  3622. struct cma_hdr *cma_hdr;
  3623. cma_hdr = hdr;
  3624. cma_hdr->cma_version = CMA_VERSION;
  3625. if (cma_family(id_priv) == AF_INET) {
  3626. struct sockaddr_in *src4, *dst4;
  3627. src4 = (struct sockaddr_in *) cma_src_addr(id_priv);
  3628. dst4 = (struct sockaddr_in *) cma_dst_addr(id_priv);
  3629. cma_set_ip_ver(cma_hdr, 4);
  3630. cma_hdr->src_addr.ip4.addr = src4->sin_addr.s_addr;
  3631. cma_hdr->dst_addr.ip4.addr = dst4->sin_addr.s_addr;
  3632. cma_hdr->port = src4->sin_port;
  3633. } else if (cma_family(id_priv) == AF_INET6) {
  3634. struct sockaddr_in6 *src6, *dst6;
  3635. src6 = (struct sockaddr_in6 *) cma_src_addr(id_priv);
  3636. dst6 = (struct sockaddr_in6 *) cma_dst_addr(id_priv);
  3637. cma_set_ip_ver(cma_hdr, 6);
  3638. cma_hdr->src_addr.ip6 = src6->sin6_addr;
  3639. cma_hdr->dst_addr.ip6 = dst6->sin6_addr;
  3640. cma_hdr->port = src6->sin6_port;
  3641. }
  3642. return 0;
  3643. }
  3644. static int cma_sidr_rep_handler(struct ib_cm_id *cm_id,
  3645. const struct ib_cm_event *ib_event)
  3646. {
  3647. struct rdma_id_private *id_priv = cm_id->context;
  3648. struct rdma_cm_event event = {};
  3649. const struct ib_cm_sidr_rep_event_param *rep =
  3650. &ib_event->param.sidr_rep_rcvd;
  3651. int ret;
  3652. mutex_lock(&id_priv->handler_mutex);
  3653. if (READ_ONCE(id_priv->state) != RDMA_CM_CONNECT)
  3654. goto out;
  3655. switch (ib_event->event) {
  3656. case IB_CM_SIDR_REQ_ERROR:
  3657. event.event = RDMA_CM_EVENT_UNREACHABLE;
  3658. event.status = -ETIMEDOUT;
  3659. break;
  3660. case IB_CM_SIDR_REP_RECEIVED:
  3661. event.param.ud.private_data = ib_event->private_data;
  3662. event.param.ud.private_data_len = IB_CM_SIDR_REP_PRIVATE_DATA_SIZE;
  3663. if (rep->status != IB_SIDR_SUCCESS) {
  3664. event.event = RDMA_CM_EVENT_UNREACHABLE;
  3665. event.status = ib_event->param.sidr_rep_rcvd.status;
  3666. pr_debug_ratelimited("RDMA CM: UNREACHABLE: bad SIDR reply. status %d\n",
  3667. event.status);
  3668. break;
  3669. }
  3670. ret = cma_set_qkey(id_priv, rep->qkey);
  3671. if (ret) {
  3672. pr_debug_ratelimited("RDMA CM: ADDR_ERROR: failed to set qkey. status %d\n", ret);
  3673. event.event = RDMA_CM_EVENT_ADDR_ERROR;
  3674. event.status = ret;
  3675. break;
  3676. }
  3677. ib_init_ah_attr_from_path(id_priv->id.device,
  3678. id_priv->id.port_num,
  3679. id_priv->id.route.path_rec,
  3680. &event.param.ud.ah_attr,
  3681. rep->sgid_attr);
  3682. event.param.ud.qp_num = rep->qpn;
  3683. event.param.ud.qkey = rep->qkey;
  3684. event.event = RDMA_CM_EVENT_ESTABLISHED;
  3685. event.status = 0;
  3686. break;
  3687. default:
  3688. pr_err("RDMA CMA: unexpected IB CM event: %d\n",
  3689. ib_event->event);
  3690. goto out;
  3691. }
  3692. ret = cma_cm_event_handler(id_priv, &event);
  3693. rdma_destroy_ah_attr(&event.param.ud.ah_attr);
  3694. if (ret) {
  3695. /* Destroy the CM ID by returning a non-zero value. */
  3696. id_priv->cm_id.ib = NULL;
  3697. destroy_id_handler_unlock(id_priv);
  3698. return ret;
  3699. }
  3700. out:
  3701. mutex_unlock(&id_priv->handler_mutex);
  3702. return 0;
  3703. }
  3704. static int cma_resolve_ib_udp(struct rdma_id_private *id_priv,
  3705. struct rdma_conn_param *conn_param)
  3706. {
  3707. struct ib_cm_sidr_req_param req;
  3708. struct ib_cm_id *id;
  3709. void *private_data;
  3710. u8 offset;
  3711. int ret;
  3712. memset(&req, 0, sizeof req);
  3713. offset = cma_user_data_offset(id_priv);
  3714. if (check_add_overflow(offset, conn_param->private_data_len, &req.private_data_len))
  3715. return -EINVAL;
  3716. if (req.private_data_len) {
  3717. private_data = kzalloc(req.private_data_len, GFP_ATOMIC);
  3718. if (!private_data)
  3719. return -ENOMEM;
  3720. } else {
  3721. private_data = NULL;
  3722. }
  3723. if (conn_param->private_data && conn_param->private_data_len)
  3724. memcpy(private_data + offset, conn_param->private_data,
  3725. conn_param->private_data_len);
  3726. if (private_data) {
  3727. ret = cma_format_hdr(private_data, id_priv);
  3728. if (ret)
  3729. goto out;
  3730. req.private_data = private_data;
  3731. }
  3732. id = ib_create_cm_id(id_priv->id.device, cma_sidr_rep_handler,
  3733. id_priv);
  3734. if (IS_ERR(id)) {
  3735. ret = PTR_ERR(id);
  3736. goto out;
  3737. }
  3738. id_priv->cm_id.ib = id;
  3739. req.path = id_priv->id.route.path_rec;
  3740. req.sgid_attr = id_priv->id.route.addr.dev_addr.sgid_attr;
  3741. req.service_id = rdma_get_service_id(&id_priv->id, cma_dst_addr(id_priv));
  3742. req.timeout_ms = 1 << (CMA_CM_RESPONSE_TIMEOUT - 8);
  3743. req.max_cm_retries = CMA_MAX_CM_RETRIES;
  3744. trace_cm_send_sidr_req(id_priv);
  3745. ret = ib_send_cm_sidr_req(id_priv->cm_id.ib, &req);
  3746. if (ret) {
  3747. ib_destroy_cm_id(id_priv->cm_id.ib);
  3748. id_priv->cm_id.ib = NULL;
  3749. }
  3750. out:
  3751. kfree(private_data);
  3752. return ret;
  3753. }
  3754. static int cma_connect_ib(struct rdma_id_private *id_priv,
  3755. struct rdma_conn_param *conn_param)
  3756. {
  3757. struct ib_cm_req_param req;
  3758. struct rdma_route *route;
  3759. void *private_data;
  3760. struct ib_cm_id *id;
  3761. u8 offset;
  3762. int ret;
  3763. memset(&req, 0, sizeof req);
  3764. offset = cma_user_data_offset(id_priv);
  3765. if (check_add_overflow(offset, conn_param->private_data_len, &req.private_data_len))
  3766. return -EINVAL;
  3767. if (req.private_data_len) {
  3768. private_data = kzalloc(req.private_data_len, GFP_ATOMIC);
  3769. if (!private_data)
  3770. return -ENOMEM;
  3771. } else {
  3772. private_data = NULL;
  3773. }
  3774. if (conn_param->private_data && conn_param->private_data_len)
  3775. memcpy(private_data + offset, conn_param->private_data,
  3776. conn_param->private_data_len);
  3777. id = ib_create_cm_id(id_priv->id.device, cma_ib_handler, id_priv);
  3778. if (IS_ERR(id)) {
  3779. ret = PTR_ERR(id);
  3780. goto out;
  3781. }
  3782. id_priv->cm_id.ib = id;
  3783. route = &id_priv->id.route;
  3784. if (private_data) {
  3785. ret = cma_format_hdr(private_data, id_priv);
  3786. if (ret)
  3787. goto out;
  3788. req.private_data = private_data;
  3789. }
  3790. req.primary_path = &route->path_rec[0];
  3791. req.primary_path_inbound = route->path_rec_inbound;
  3792. req.primary_path_outbound = route->path_rec_outbound;
  3793. if (route->num_pri_alt_paths == 2)
  3794. req.alternate_path = &route->path_rec[1];
  3795. req.ppath_sgid_attr = id_priv->id.route.addr.dev_addr.sgid_attr;
  3796. /* Alternate path SGID attribute currently unsupported */
  3797. req.service_id = rdma_get_service_id(&id_priv->id, cma_dst_addr(id_priv));
  3798. req.qp_num = id_priv->qp_num;
  3799. req.qp_type = id_priv->id.qp_type;
  3800. req.starting_psn = id_priv->seq_num;
  3801. req.responder_resources = conn_param->responder_resources;
  3802. req.initiator_depth = conn_param->initiator_depth;
  3803. req.flow_control = conn_param->flow_control;
  3804. req.retry_count = min_t(u8, 7, conn_param->retry_count);
  3805. req.rnr_retry_count = min_t(u8, 7, conn_param->rnr_retry_count);
  3806. req.remote_cm_response_timeout = CMA_CM_RESPONSE_TIMEOUT;
  3807. req.local_cm_response_timeout = CMA_CM_RESPONSE_TIMEOUT;
  3808. req.max_cm_retries = CMA_MAX_CM_RETRIES;
  3809. req.srq = id_priv->srq ? 1 : 0;
  3810. req.ece.vendor_id = id_priv->ece.vendor_id;
  3811. req.ece.attr_mod = id_priv->ece.attr_mod;
  3812. trace_cm_send_req(id_priv);
  3813. ret = ib_send_cm_req(id_priv->cm_id.ib, &req);
  3814. out:
  3815. if (ret && !IS_ERR(id)) {
  3816. ib_destroy_cm_id(id);
  3817. id_priv->cm_id.ib = NULL;
  3818. }
  3819. kfree(private_data);
  3820. return ret;
  3821. }
  3822. static int cma_connect_iw(struct rdma_id_private *id_priv,
  3823. struct rdma_conn_param *conn_param)
  3824. {
  3825. struct iw_cm_id *cm_id;
  3826. int ret;
  3827. struct iw_cm_conn_param iw_param;
  3828. cm_id = iw_create_cm_id(id_priv->id.device, cma_iw_handler, id_priv);
  3829. if (IS_ERR(cm_id))
  3830. return PTR_ERR(cm_id);
  3831. mutex_lock(&id_priv->qp_mutex);
  3832. cm_id->tos = id_priv->tos;
  3833. cm_id->tos_set = id_priv->tos_set;
  3834. mutex_unlock(&id_priv->qp_mutex);
  3835. id_priv->cm_id.iw = cm_id;
  3836. memcpy(&cm_id->local_addr, cma_src_addr(id_priv),
  3837. rdma_addr_size(cma_src_addr(id_priv)));
  3838. memcpy(&cm_id->remote_addr, cma_dst_addr(id_priv),
  3839. rdma_addr_size(cma_dst_addr(id_priv)));
  3840. ret = cma_modify_qp_rtr(id_priv, conn_param);
  3841. if (ret)
  3842. goto out;
  3843. if (conn_param) {
  3844. iw_param.ord = conn_param->initiator_depth;
  3845. iw_param.ird = conn_param->responder_resources;
  3846. iw_param.private_data = conn_param->private_data;
  3847. iw_param.private_data_len = conn_param->private_data_len;
  3848. iw_param.qpn = id_priv->id.qp ? id_priv->qp_num : conn_param->qp_num;
  3849. } else {
  3850. memset(&iw_param, 0, sizeof iw_param);
  3851. iw_param.qpn = id_priv->qp_num;
  3852. }
  3853. ret = iw_cm_connect(cm_id, &iw_param);
  3854. out:
  3855. if (ret) {
  3856. iw_destroy_cm_id(cm_id);
  3857. id_priv->cm_id.iw = NULL;
  3858. }
  3859. return ret;
  3860. }
  3861. /**
  3862. * rdma_connect_locked - Initiate an active connection request.
  3863. * @id: Connection identifier to connect.
  3864. * @conn_param: Connection information used for connected QPs.
  3865. *
  3866. * Same as rdma_connect() but can only be called from the
  3867. * RDMA_CM_EVENT_ROUTE_RESOLVED handler callback.
  3868. */
  3869. int rdma_connect_locked(struct rdma_cm_id *id,
  3870. struct rdma_conn_param *conn_param)
  3871. {
  3872. struct rdma_id_private *id_priv =
  3873. container_of(id, struct rdma_id_private, id);
  3874. int ret;
  3875. lockdep_assert_held(&id_priv->handler_mutex);
  3876. if (!cma_comp_exch(id_priv, RDMA_CM_ROUTE_RESOLVED, RDMA_CM_CONNECT))
  3877. return -EINVAL;
  3878. if (!id->qp) {
  3879. id_priv->qp_num = conn_param->qp_num;
  3880. id_priv->srq = conn_param->srq;
  3881. }
  3882. if (rdma_cap_ib_cm(id->device, id->port_num)) {
  3883. if (id->qp_type == IB_QPT_UD)
  3884. ret = cma_resolve_ib_udp(id_priv, conn_param);
  3885. else
  3886. ret = cma_connect_ib(id_priv, conn_param);
  3887. } else if (rdma_cap_iw_cm(id->device, id->port_num)) {
  3888. ret = cma_connect_iw(id_priv, conn_param);
  3889. } else {
  3890. ret = -ENOSYS;
  3891. }
  3892. if (ret)
  3893. goto err_state;
  3894. return 0;
  3895. err_state:
  3896. cma_comp_exch(id_priv, RDMA_CM_CONNECT, RDMA_CM_ROUTE_RESOLVED);
  3897. return ret;
  3898. }
  3899. EXPORT_SYMBOL(rdma_connect_locked);
  3900. /**
  3901. * rdma_connect - Initiate an active connection request.
  3902. * @id: Connection identifier to connect.
  3903. * @conn_param: Connection information used for connected QPs.
  3904. *
  3905. * Users must have resolved a route for the rdma_cm_id to connect with by having
  3906. * called rdma_resolve_route before calling this routine.
  3907. *
  3908. * This call will either connect to a remote QP or obtain remote QP information
  3909. * for unconnected rdma_cm_id's. The actual operation is based on the
  3910. * rdma_cm_id's port space.
  3911. */
  3912. int rdma_connect(struct rdma_cm_id *id, struct rdma_conn_param *conn_param)
  3913. {
  3914. struct rdma_id_private *id_priv =
  3915. container_of(id, struct rdma_id_private, id);
  3916. int ret;
  3917. mutex_lock(&id_priv->handler_mutex);
  3918. ret = rdma_connect_locked(id, conn_param);
  3919. mutex_unlock(&id_priv->handler_mutex);
  3920. return ret;
  3921. }
  3922. EXPORT_SYMBOL(rdma_connect);
  3923. /**
  3924. * rdma_connect_ece - Initiate an active connection request with ECE data.
  3925. * @id: Connection identifier to connect.
  3926. * @conn_param: Connection information used for connected QPs.
  3927. * @ece: ECE parameters
  3928. *
  3929. * See rdma_connect() explanation.
  3930. */
  3931. int rdma_connect_ece(struct rdma_cm_id *id, struct rdma_conn_param *conn_param,
  3932. struct rdma_ucm_ece *ece)
  3933. {
  3934. struct rdma_id_private *id_priv =
  3935. container_of(id, struct rdma_id_private, id);
  3936. id_priv->ece.vendor_id = ece->vendor_id;
  3937. id_priv->ece.attr_mod = ece->attr_mod;
  3938. return rdma_connect(id, conn_param);
  3939. }
  3940. EXPORT_SYMBOL(rdma_connect_ece);
  3941. static int cma_accept_ib(struct rdma_id_private *id_priv,
  3942. struct rdma_conn_param *conn_param)
  3943. {
  3944. struct ib_cm_rep_param rep;
  3945. int ret;
  3946. ret = cma_modify_qp_rtr(id_priv, conn_param);
  3947. if (ret)
  3948. goto out;
  3949. ret = cma_modify_qp_rts(id_priv, conn_param);
  3950. if (ret)
  3951. goto out;
  3952. memset(&rep, 0, sizeof rep);
  3953. rep.qp_num = id_priv->qp_num;
  3954. rep.starting_psn = id_priv->seq_num;
  3955. rep.private_data = conn_param->private_data;
  3956. rep.private_data_len = conn_param->private_data_len;
  3957. rep.responder_resources = conn_param->responder_resources;
  3958. rep.initiator_depth = conn_param->initiator_depth;
  3959. rep.failover_accepted = 0;
  3960. rep.flow_control = conn_param->flow_control;
  3961. rep.rnr_retry_count = min_t(u8, 7, conn_param->rnr_retry_count);
  3962. rep.srq = id_priv->srq ? 1 : 0;
  3963. rep.ece.vendor_id = id_priv->ece.vendor_id;
  3964. rep.ece.attr_mod = id_priv->ece.attr_mod;
  3965. trace_cm_send_rep(id_priv);
  3966. ret = ib_send_cm_rep(id_priv->cm_id.ib, &rep);
  3967. out:
  3968. return ret;
  3969. }
  3970. static int cma_accept_iw(struct rdma_id_private *id_priv,
  3971. struct rdma_conn_param *conn_param)
  3972. {
  3973. struct iw_cm_conn_param iw_param;
  3974. int ret;
  3975. if (!conn_param)
  3976. return -EINVAL;
  3977. ret = cma_modify_qp_rtr(id_priv, conn_param);
  3978. if (ret)
  3979. return ret;
  3980. iw_param.ord = conn_param->initiator_depth;
  3981. iw_param.ird = conn_param->responder_resources;
  3982. iw_param.private_data = conn_param->private_data;
  3983. iw_param.private_data_len = conn_param->private_data_len;
  3984. if (id_priv->id.qp)
  3985. iw_param.qpn = id_priv->qp_num;
  3986. else
  3987. iw_param.qpn = conn_param->qp_num;
  3988. return iw_cm_accept(id_priv->cm_id.iw, &iw_param);
  3989. }
  3990. static int cma_send_sidr_rep(struct rdma_id_private *id_priv,
  3991. enum ib_cm_sidr_status status, u32 qkey,
  3992. const void *private_data, int private_data_len)
  3993. {
  3994. struct ib_cm_sidr_rep_param rep;
  3995. int ret;
  3996. memset(&rep, 0, sizeof rep);
  3997. rep.status = status;
  3998. if (status == IB_SIDR_SUCCESS) {
  3999. if (qkey)
  4000. ret = cma_set_qkey(id_priv, qkey);
  4001. else
  4002. ret = cma_set_default_qkey(id_priv);
  4003. if (ret)
  4004. return ret;
  4005. rep.qp_num = id_priv->qp_num;
  4006. rep.qkey = id_priv->qkey;
  4007. rep.ece.vendor_id = id_priv->ece.vendor_id;
  4008. rep.ece.attr_mod = id_priv->ece.attr_mod;
  4009. }
  4010. rep.private_data = private_data;
  4011. rep.private_data_len = private_data_len;
  4012. trace_cm_send_sidr_rep(id_priv);
  4013. return ib_send_cm_sidr_rep(id_priv->cm_id.ib, &rep);
  4014. }
  4015. /**
  4016. * rdma_accept - Called to accept a connection request or response.
  4017. * @id: Connection identifier associated with the request.
  4018. * @conn_param: Information needed to establish the connection. This must be
  4019. * provided if accepting a connection request. If accepting a connection
  4020. * response, this parameter must be NULL.
  4021. *
  4022. * Typically, this routine is only called by the listener to accept a connection
  4023. * request. It must also be called on the active side of a connection if the
  4024. * user is performing their own QP transitions.
  4025. *
  4026. * In the case of error, a reject message is sent to the remote side and the
  4027. * state of the qp associated with the id is modified to error, such that any
  4028. * previously posted receive buffers would be flushed.
  4029. *
  4030. * This function is for use by kernel ULPs and must be called from under the
  4031. * handler callback.
  4032. */
  4033. int rdma_accept(struct rdma_cm_id *id, struct rdma_conn_param *conn_param)
  4034. {
  4035. struct rdma_id_private *id_priv =
  4036. container_of(id, struct rdma_id_private, id);
  4037. int ret;
  4038. lockdep_assert_held(&id_priv->handler_mutex);
  4039. if (READ_ONCE(id_priv->state) != RDMA_CM_CONNECT)
  4040. return -EINVAL;
  4041. if (!id->qp && conn_param) {
  4042. id_priv->qp_num = conn_param->qp_num;
  4043. id_priv->srq = conn_param->srq;
  4044. }
  4045. if (rdma_cap_ib_cm(id->device, id->port_num)) {
  4046. if (id->qp_type == IB_QPT_UD) {
  4047. if (conn_param)
  4048. ret = cma_send_sidr_rep(id_priv, IB_SIDR_SUCCESS,
  4049. conn_param->qkey,
  4050. conn_param->private_data,
  4051. conn_param->private_data_len);
  4052. else
  4053. ret = cma_send_sidr_rep(id_priv, IB_SIDR_SUCCESS,
  4054. 0, NULL, 0);
  4055. } else {
  4056. if (conn_param)
  4057. ret = cma_accept_ib(id_priv, conn_param);
  4058. else
  4059. ret = cma_rep_recv(id_priv);
  4060. }
  4061. } else if (rdma_cap_iw_cm(id->device, id->port_num)) {
  4062. ret = cma_accept_iw(id_priv, conn_param);
  4063. } else {
  4064. ret = -ENOSYS;
  4065. }
  4066. if (ret)
  4067. goto reject;
  4068. return 0;
  4069. reject:
  4070. cma_modify_qp_err(id_priv);
  4071. rdma_reject(id, NULL, 0, IB_CM_REJ_CONSUMER_DEFINED);
  4072. return ret;
  4073. }
  4074. EXPORT_SYMBOL(rdma_accept);
  4075. int rdma_accept_ece(struct rdma_cm_id *id, struct rdma_conn_param *conn_param,
  4076. struct rdma_ucm_ece *ece)
  4077. {
  4078. struct rdma_id_private *id_priv =
  4079. container_of(id, struct rdma_id_private, id);
  4080. id_priv->ece.vendor_id = ece->vendor_id;
  4081. id_priv->ece.attr_mod = ece->attr_mod;
  4082. return rdma_accept(id, conn_param);
  4083. }
  4084. EXPORT_SYMBOL(rdma_accept_ece);
  4085. void rdma_lock_handler(struct rdma_cm_id *id)
  4086. {
  4087. struct rdma_id_private *id_priv =
  4088. container_of(id, struct rdma_id_private, id);
  4089. mutex_lock(&id_priv->handler_mutex);
  4090. }
  4091. EXPORT_SYMBOL(rdma_lock_handler);
  4092. void rdma_unlock_handler(struct rdma_cm_id *id)
  4093. {
  4094. struct rdma_id_private *id_priv =
  4095. container_of(id, struct rdma_id_private, id);
  4096. mutex_unlock(&id_priv->handler_mutex);
  4097. }
  4098. EXPORT_SYMBOL(rdma_unlock_handler);
  4099. int rdma_notify(struct rdma_cm_id *id, enum ib_event_type event)
  4100. {
  4101. struct rdma_id_private *id_priv;
  4102. int ret;
  4103. id_priv = container_of(id, struct rdma_id_private, id);
  4104. if (!id_priv->cm_id.ib)
  4105. return -EINVAL;
  4106. switch (id->device->node_type) {
  4107. case RDMA_NODE_IB_CA:
  4108. ret = ib_cm_notify(id_priv->cm_id.ib, event);
  4109. break;
  4110. default:
  4111. ret = 0;
  4112. break;
  4113. }
  4114. return ret;
  4115. }
  4116. EXPORT_SYMBOL(rdma_notify);
  4117. int rdma_reject(struct rdma_cm_id *id, const void *private_data,
  4118. u8 private_data_len, u8 reason)
  4119. {
  4120. struct rdma_id_private *id_priv;
  4121. int ret;
  4122. id_priv = container_of(id, struct rdma_id_private, id);
  4123. if (!id_priv->cm_id.ib)
  4124. return -EINVAL;
  4125. if (rdma_cap_ib_cm(id->device, id->port_num)) {
  4126. if (id->qp_type == IB_QPT_UD) {
  4127. ret = cma_send_sidr_rep(id_priv, IB_SIDR_REJECT, 0,
  4128. private_data, private_data_len);
  4129. } else {
  4130. trace_cm_send_rej(id_priv);
  4131. ret = ib_send_cm_rej(id_priv->cm_id.ib, reason, NULL, 0,
  4132. private_data, private_data_len);
  4133. }
  4134. } else if (rdma_cap_iw_cm(id->device, id->port_num)) {
  4135. ret = iw_cm_reject(id_priv->cm_id.iw,
  4136. private_data, private_data_len);
  4137. } else {
  4138. ret = -ENOSYS;
  4139. }
  4140. return ret;
  4141. }
  4142. EXPORT_SYMBOL(rdma_reject);
  4143. int rdma_disconnect(struct rdma_cm_id *id)
  4144. {
  4145. struct rdma_id_private *id_priv;
  4146. int ret;
  4147. id_priv = container_of(id, struct rdma_id_private, id);
  4148. if (!id_priv->cm_id.ib)
  4149. return -EINVAL;
  4150. if (rdma_cap_ib_cm(id->device, id->port_num)) {
  4151. ret = cma_modify_qp_err(id_priv);
  4152. if (ret)
  4153. goto out;
  4154. /* Initiate or respond to a disconnect. */
  4155. trace_cm_disconnect(id_priv);
  4156. if (ib_send_cm_dreq(id_priv->cm_id.ib, NULL, 0)) {
  4157. if (!ib_send_cm_drep(id_priv->cm_id.ib, NULL, 0))
  4158. trace_cm_sent_drep(id_priv);
  4159. } else {
  4160. trace_cm_sent_dreq(id_priv);
  4161. }
  4162. } else if (rdma_cap_iw_cm(id->device, id->port_num)) {
  4163. ret = iw_cm_disconnect(id_priv->cm_id.iw, 0);
  4164. } else
  4165. ret = -EINVAL;
  4166. out:
  4167. return ret;
  4168. }
  4169. EXPORT_SYMBOL(rdma_disconnect);
  4170. static void cma_make_mc_event(int status, struct rdma_id_private *id_priv,
  4171. struct ib_sa_multicast *multicast,
  4172. struct rdma_cm_event *event,
  4173. struct cma_multicast *mc)
  4174. {
  4175. struct rdma_dev_addr *dev_addr;
  4176. enum ib_gid_type gid_type;
  4177. struct net_device *ndev;
  4178. if (status)
  4179. pr_debug_ratelimited("RDMA CM: MULTICAST_ERROR: failed to join multicast. status %d\n",
  4180. status);
  4181. event->status = status;
  4182. event->param.ud.private_data = mc->context;
  4183. if (status) {
  4184. event->event = RDMA_CM_EVENT_MULTICAST_ERROR;
  4185. return;
  4186. }
  4187. dev_addr = &id_priv->id.route.addr.dev_addr;
  4188. ndev = dev_get_by_index(dev_addr->net, dev_addr->bound_dev_if);
  4189. gid_type =
  4190. id_priv->cma_dev
  4191. ->default_gid_type[id_priv->id.port_num -
  4192. rdma_start_port(
  4193. id_priv->cma_dev->device)];
  4194. event->event = RDMA_CM_EVENT_MULTICAST_JOIN;
  4195. if (ib_init_ah_from_mcmember(id_priv->id.device, id_priv->id.port_num,
  4196. &multicast->rec, ndev, gid_type,
  4197. &event->param.ud.ah_attr)) {
  4198. event->event = RDMA_CM_EVENT_MULTICAST_ERROR;
  4199. goto out;
  4200. }
  4201. event->param.ud.qp_num = 0xFFFFFF;
  4202. event->param.ud.qkey = id_priv->qkey;
  4203. out:
  4204. dev_put(ndev);
  4205. }
  4206. static int cma_ib_mc_handler(int status, struct ib_sa_multicast *multicast)
  4207. {
  4208. struct cma_multicast *mc = multicast->context;
  4209. struct rdma_id_private *id_priv = mc->id_priv;
  4210. struct rdma_cm_event event = {};
  4211. int ret = 0;
  4212. mutex_lock(&id_priv->handler_mutex);
  4213. if (READ_ONCE(id_priv->state) == RDMA_CM_DEVICE_REMOVAL ||
  4214. READ_ONCE(id_priv->state) == RDMA_CM_DESTROYING)
  4215. goto out;
  4216. ret = cma_set_qkey(id_priv, be32_to_cpu(multicast->rec.qkey));
  4217. if (!ret) {
  4218. cma_make_mc_event(status, id_priv, multicast, &event, mc);
  4219. ret = cma_cm_event_handler(id_priv, &event);
  4220. }
  4221. rdma_destroy_ah_attr(&event.param.ud.ah_attr);
  4222. WARN_ON(ret);
  4223. out:
  4224. mutex_unlock(&id_priv->handler_mutex);
  4225. return 0;
  4226. }
  4227. static void cma_set_mgid(struct rdma_id_private *id_priv,
  4228. struct sockaddr *addr, union ib_gid *mgid)
  4229. {
  4230. unsigned char mc_map[MAX_ADDR_LEN];
  4231. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  4232. struct sockaddr_in *sin = (struct sockaddr_in *) addr;
  4233. struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *) addr;
  4234. if (cma_any_addr(addr)) {
  4235. memset(mgid, 0, sizeof *mgid);
  4236. } else if ((addr->sa_family == AF_INET6) &&
  4237. ((be32_to_cpu(sin6->sin6_addr.s6_addr32[0]) & 0xFFF0FFFF) ==
  4238. 0xFF10A01B)) {
  4239. /* IPv6 address is an SA assigned MGID. */
  4240. memcpy(mgid, &sin6->sin6_addr, sizeof *mgid);
  4241. } else if (addr->sa_family == AF_IB) {
  4242. memcpy(mgid, &((struct sockaddr_ib *) addr)->sib_addr, sizeof *mgid);
  4243. } else if (addr->sa_family == AF_INET6) {
  4244. ipv6_ib_mc_map(&sin6->sin6_addr, dev_addr->broadcast, mc_map);
  4245. if (id_priv->id.ps == RDMA_PS_UDP)
  4246. mc_map[7] = 0x01; /* Use RDMA CM signature */
  4247. *mgid = *(union ib_gid *) (mc_map + 4);
  4248. } else {
  4249. ip_ib_mc_map(sin->sin_addr.s_addr, dev_addr->broadcast, mc_map);
  4250. if (id_priv->id.ps == RDMA_PS_UDP)
  4251. mc_map[7] = 0x01; /* Use RDMA CM signature */
  4252. *mgid = *(union ib_gid *) (mc_map + 4);
  4253. }
  4254. }
  4255. static int cma_join_ib_multicast(struct rdma_id_private *id_priv,
  4256. struct cma_multicast *mc)
  4257. {
  4258. struct ib_sa_mcmember_rec rec;
  4259. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  4260. ib_sa_comp_mask comp_mask;
  4261. int ret;
  4262. ib_addr_get_mgid(dev_addr, &rec.mgid);
  4263. ret = ib_sa_get_mcmember_rec(id_priv->id.device, id_priv->id.port_num,
  4264. &rec.mgid, &rec);
  4265. if (ret)
  4266. return ret;
  4267. if (!id_priv->qkey) {
  4268. ret = cma_set_default_qkey(id_priv);
  4269. if (ret)
  4270. return ret;
  4271. }
  4272. cma_set_mgid(id_priv, (struct sockaddr *) &mc->addr, &rec.mgid);
  4273. rec.qkey = cpu_to_be32(id_priv->qkey);
  4274. rdma_addr_get_sgid(dev_addr, &rec.port_gid);
  4275. rec.pkey = cpu_to_be16(ib_addr_get_pkey(dev_addr));
  4276. rec.join_state = mc->join_state;
  4277. comp_mask = IB_SA_MCMEMBER_REC_MGID | IB_SA_MCMEMBER_REC_PORT_GID |
  4278. IB_SA_MCMEMBER_REC_PKEY | IB_SA_MCMEMBER_REC_JOIN_STATE |
  4279. IB_SA_MCMEMBER_REC_QKEY | IB_SA_MCMEMBER_REC_SL |
  4280. IB_SA_MCMEMBER_REC_FLOW_LABEL |
  4281. IB_SA_MCMEMBER_REC_TRAFFIC_CLASS;
  4282. if (id_priv->id.ps == RDMA_PS_IPOIB)
  4283. comp_mask |= IB_SA_MCMEMBER_REC_RATE |
  4284. IB_SA_MCMEMBER_REC_RATE_SELECTOR |
  4285. IB_SA_MCMEMBER_REC_MTU_SELECTOR |
  4286. IB_SA_MCMEMBER_REC_MTU |
  4287. IB_SA_MCMEMBER_REC_HOP_LIMIT;
  4288. mc->sa_mc = ib_sa_join_multicast(&sa_client, id_priv->id.device,
  4289. id_priv->id.port_num, &rec, comp_mask,
  4290. GFP_KERNEL, cma_ib_mc_handler, mc);
  4291. return PTR_ERR_OR_ZERO(mc->sa_mc);
  4292. }
  4293. static void cma_iboe_set_mgid(struct sockaddr *addr, union ib_gid *mgid,
  4294. enum ib_gid_type gid_type)
  4295. {
  4296. struct sockaddr_in *sin = (struct sockaddr_in *)addr;
  4297. struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)addr;
  4298. if (cma_any_addr(addr)) {
  4299. memset(mgid, 0, sizeof *mgid);
  4300. } else if (addr->sa_family == AF_INET6) {
  4301. memcpy(mgid, &sin6->sin6_addr, sizeof *mgid);
  4302. } else {
  4303. mgid->raw[0] =
  4304. (gid_type == IB_GID_TYPE_ROCE_UDP_ENCAP) ? 0 : 0xff;
  4305. mgid->raw[1] =
  4306. (gid_type == IB_GID_TYPE_ROCE_UDP_ENCAP) ? 0 : 0x0e;
  4307. mgid->raw[2] = 0;
  4308. mgid->raw[3] = 0;
  4309. mgid->raw[4] = 0;
  4310. mgid->raw[5] = 0;
  4311. mgid->raw[6] = 0;
  4312. mgid->raw[7] = 0;
  4313. mgid->raw[8] = 0;
  4314. mgid->raw[9] = 0;
  4315. mgid->raw[10] = 0xff;
  4316. mgid->raw[11] = 0xff;
  4317. *(__be32 *)(&mgid->raw[12]) = sin->sin_addr.s_addr;
  4318. }
  4319. }
  4320. static int cma_iboe_join_multicast(struct rdma_id_private *id_priv,
  4321. struct cma_multicast *mc)
  4322. {
  4323. struct rdma_dev_addr *dev_addr = &id_priv->id.route.addr.dev_addr;
  4324. int err = 0;
  4325. struct sockaddr *addr = (struct sockaddr *)&mc->addr;
  4326. struct net_device *ndev = NULL;
  4327. struct ib_sa_multicast ib = {};
  4328. enum ib_gid_type gid_type;
  4329. bool send_only;
  4330. send_only = mc->join_state == BIT(SENDONLY_FULLMEMBER_JOIN);
  4331. if (cma_zero_addr(addr))
  4332. return -EINVAL;
  4333. gid_type = id_priv->cma_dev->default_gid_type[id_priv->id.port_num -
  4334. rdma_start_port(id_priv->cma_dev->device)];
  4335. cma_iboe_set_mgid(addr, &ib.rec.mgid, gid_type);
  4336. ib.rec.pkey = cpu_to_be16(0xffff);
  4337. if (dev_addr->bound_dev_if)
  4338. ndev = dev_get_by_index(dev_addr->net, dev_addr->bound_dev_if);
  4339. if (!ndev)
  4340. return -ENODEV;
  4341. ib.rec.rate = IB_RATE_PORT_CURRENT;
  4342. ib.rec.hop_limit = 1;
  4343. ib.rec.mtu = iboe_get_mtu(ndev->mtu);
  4344. if (addr->sa_family == AF_INET) {
  4345. if (gid_type == IB_GID_TYPE_ROCE_UDP_ENCAP) {
  4346. ib.rec.hop_limit = IPV6_DEFAULT_HOPLIMIT;
  4347. if (!send_only) {
  4348. err = cma_igmp_send(ndev, &ib.rec.mgid,
  4349. true);
  4350. }
  4351. }
  4352. } else {
  4353. if (gid_type == IB_GID_TYPE_ROCE_UDP_ENCAP)
  4354. err = -ENOTSUPP;
  4355. }
  4356. dev_put(ndev);
  4357. if (err || !ib.rec.mtu)
  4358. return err ?: -EINVAL;
  4359. if (!id_priv->qkey)
  4360. cma_set_default_qkey(id_priv);
  4361. rdma_ip2gid((struct sockaddr *)&id_priv->id.route.addr.src_addr,
  4362. &ib.rec.port_gid);
  4363. INIT_WORK(&mc->iboe_join.work, cma_iboe_join_work_handler);
  4364. cma_make_mc_event(0, id_priv, &ib, &mc->iboe_join.event, mc);
  4365. queue_work(cma_wq, &mc->iboe_join.work);
  4366. return 0;
  4367. }
  4368. int rdma_join_multicast(struct rdma_cm_id *id, struct sockaddr *addr,
  4369. u8 join_state, void *context)
  4370. {
  4371. struct rdma_id_private *id_priv =
  4372. container_of(id, struct rdma_id_private, id);
  4373. struct cma_multicast *mc;
  4374. int ret;
  4375. /* Not supported for kernel QPs */
  4376. if (WARN_ON(id->qp))
  4377. return -EINVAL;
  4378. /* ULP is calling this wrong. */
  4379. if (!id->device || (READ_ONCE(id_priv->state) != RDMA_CM_ADDR_BOUND &&
  4380. READ_ONCE(id_priv->state) != RDMA_CM_ADDR_RESOLVED))
  4381. return -EINVAL;
  4382. if (id_priv->id.qp_type != IB_QPT_UD)
  4383. return -EINVAL;
  4384. mc = kzalloc_obj(*mc);
  4385. if (!mc)
  4386. return -ENOMEM;
  4387. memcpy(&mc->addr, addr, rdma_addr_size(addr));
  4388. mc->context = context;
  4389. mc->id_priv = id_priv;
  4390. mc->join_state = join_state;
  4391. if (rdma_protocol_roce(id->device, id->port_num)) {
  4392. ret = cma_iboe_join_multicast(id_priv, mc);
  4393. if (ret)
  4394. goto out_err;
  4395. } else if (rdma_cap_ib_mcast(id->device, id->port_num)) {
  4396. ret = cma_join_ib_multicast(id_priv, mc);
  4397. if (ret)
  4398. goto out_err;
  4399. } else {
  4400. ret = -ENOSYS;
  4401. goto out_err;
  4402. }
  4403. spin_lock(&id_priv->lock);
  4404. list_add(&mc->list, &id_priv->mc_list);
  4405. spin_unlock(&id_priv->lock);
  4406. return 0;
  4407. out_err:
  4408. kfree(mc);
  4409. return ret;
  4410. }
  4411. EXPORT_SYMBOL(rdma_join_multicast);
  4412. void rdma_leave_multicast(struct rdma_cm_id *id, struct sockaddr *addr)
  4413. {
  4414. struct rdma_id_private *id_priv;
  4415. struct cma_multicast *mc;
  4416. id_priv = container_of(id, struct rdma_id_private, id);
  4417. spin_lock_irq(&id_priv->lock);
  4418. list_for_each_entry(mc, &id_priv->mc_list, list) {
  4419. if (memcmp(&mc->addr, addr, rdma_addr_size(addr)) != 0)
  4420. continue;
  4421. list_del(&mc->list);
  4422. spin_unlock_irq(&id_priv->lock);
  4423. WARN_ON(id_priv->cma_dev->device != id->device);
  4424. destroy_mc(id_priv, mc);
  4425. return;
  4426. }
  4427. spin_unlock_irq(&id_priv->lock);
  4428. }
  4429. EXPORT_SYMBOL(rdma_leave_multicast);
  4430. static int cma_netdev_change(struct net_device *ndev, struct rdma_id_private *id_priv)
  4431. {
  4432. struct rdma_dev_addr *dev_addr;
  4433. struct cma_work *work;
  4434. dev_addr = &id_priv->id.route.addr.dev_addr;
  4435. if ((dev_addr->bound_dev_if == ndev->ifindex) &&
  4436. (net_eq(dev_net(ndev), dev_addr->net)) &&
  4437. memcmp(dev_addr->src_dev_addr, ndev->dev_addr, ndev->addr_len)) {
  4438. pr_info("RDMA CM addr change for ndev %s used by id %p\n",
  4439. ndev->name, &id_priv->id);
  4440. work = kzalloc_obj(*work);
  4441. if (!work)
  4442. return -ENOMEM;
  4443. INIT_WORK(&work->work, cma_work_handler);
  4444. work->id = id_priv;
  4445. work->event.event = RDMA_CM_EVENT_ADDR_CHANGE;
  4446. cma_id_get(id_priv);
  4447. queue_work(cma_wq, &work->work);
  4448. }
  4449. return 0;
  4450. }
  4451. static int cma_netdev_callback(struct notifier_block *self, unsigned long event,
  4452. void *ptr)
  4453. {
  4454. struct net_device *ndev = netdev_notifier_info_to_dev(ptr);
  4455. struct cma_device *cma_dev;
  4456. struct rdma_id_private *id_priv;
  4457. int ret = NOTIFY_DONE;
  4458. if (event != NETDEV_BONDING_FAILOVER)
  4459. return NOTIFY_DONE;
  4460. if (!netif_is_bond_master(ndev))
  4461. return NOTIFY_DONE;
  4462. mutex_lock(&lock);
  4463. list_for_each_entry(cma_dev, &dev_list, list)
  4464. list_for_each_entry(id_priv, &cma_dev->id_list, device_item) {
  4465. ret = cma_netdev_change(ndev, id_priv);
  4466. if (ret)
  4467. goto out;
  4468. }
  4469. out:
  4470. mutex_unlock(&lock);
  4471. return ret;
  4472. }
  4473. static void cma_netevent_work_handler(struct work_struct *_work)
  4474. {
  4475. struct rdma_id_private *id_priv =
  4476. container_of(_work, struct rdma_id_private, id.net_work);
  4477. struct rdma_cm_event event = {};
  4478. mutex_lock(&id_priv->handler_mutex);
  4479. if (READ_ONCE(id_priv->state) == RDMA_CM_DESTROYING ||
  4480. READ_ONCE(id_priv->state) == RDMA_CM_DEVICE_REMOVAL)
  4481. goto out_unlock;
  4482. event.event = RDMA_CM_EVENT_UNREACHABLE;
  4483. event.status = -ETIMEDOUT;
  4484. if (cma_cm_event_handler(id_priv, &event)) {
  4485. __acquire(&id_priv->handler_mutex);
  4486. id_priv->cm_id.ib = NULL;
  4487. cma_id_put(id_priv);
  4488. destroy_id_handler_unlock(id_priv);
  4489. return;
  4490. }
  4491. out_unlock:
  4492. mutex_unlock(&id_priv->handler_mutex);
  4493. cma_id_put(id_priv);
  4494. }
  4495. static int cma_netevent_callback(struct notifier_block *self,
  4496. unsigned long event, void *ctx)
  4497. {
  4498. struct id_table_entry *ips_node = NULL;
  4499. struct rdma_id_private *current_id;
  4500. struct neighbour *neigh = ctx;
  4501. unsigned long flags;
  4502. if (event != NETEVENT_NEIGH_UPDATE)
  4503. return NOTIFY_DONE;
  4504. spin_lock_irqsave(&id_table_lock, flags);
  4505. if (neigh->tbl->family == AF_INET6) {
  4506. struct sockaddr_in6 neigh_sock_6;
  4507. neigh_sock_6.sin6_family = AF_INET6;
  4508. neigh_sock_6.sin6_addr = *(struct in6_addr *)neigh->primary_key;
  4509. ips_node = node_from_ndev_ip(&id_table, neigh->dev->ifindex,
  4510. (struct sockaddr *)&neigh_sock_6);
  4511. } else if (neigh->tbl->family == AF_INET) {
  4512. struct sockaddr_in neigh_sock_4;
  4513. neigh_sock_4.sin_family = AF_INET;
  4514. neigh_sock_4.sin_addr.s_addr = *(__be32 *)(neigh->primary_key);
  4515. ips_node = node_from_ndev_ip(&id_table, neigh->dev->ifindex,
  4516. (struct sockaddr *)&neigh_sock_4);
  4517. } else
  4518. goto out;
  4519. if (!ips_node)
  4520. goto out;
  4521. list_for_each_entry(current_id, &ips_node->id_list, id_list_entry) {
  4522. if (!memcmp(current_id->id.route.addr.dev_addr.dst_dev_addr,
  4523. neigh->ha, ETH_ALEN))
  4524. continue;
  4525. cma_id_get(current_id);
  4526. if (!queue_work(cma_wq, &current_id->id.net_work))
  4527. cma_id_put(current_id);
  4528. }
  4529. out:
  4530. spin_unlock_irqrestore(&id_table_lock, flags);
  4531. return NOTIFY_DONE;
  4532. }
  4533. static struct notifier_block cma_nb = {
  4534. .notifier_call = cma_netdev_callback
  4535. };
  4536. static struct notifier_block cma_netevent_cb = {
  4537. .notifier_call = cma_netevent_callback
  4538. };
  4539. static void cma_send_device_removal_put(struct rdma_id_private *id_priv)
  4540. {
  4541. struct rdma_cm_event event = { .event = RDMA_CM_EVENT_DEVICE_REMOVAL };
  4542. enum rdma_cm_state state;
  4543. unsigned long flags;
  4544. mutex_lock(&id_priv->handler_mutex);
  4545. /* Record that we want to remove the device */
  4546. spin_lock_irqsave(&id_priv->lock, flags);
  4547. state = id_priv->state;
  4548. if (state == RDMA_CM_DESTROYING || state == RDMA_CM_DEVICE_REMOVAL) {
  4549. spin_unlock_irqrestore(&id_priv->lock, flags);
  4550. mutex_unlock(&id_priv->handler_mutex);
  4551. cma_id_put(id_priv);
  4552. return;
  4553. }
  4554. id_priv->state = RDMA_CM_DEVICE_REMOVAL;
  4555. spin_unlock_irqrestore(&id_priv->lock, flags);
  4556. if (cma_cm_event_handler(id_priv, &event)) {
  4557. /*
  4558. * At this point the ULP promises it won't call
  4559. * rdma_destroy_id() concurrently
  4560. */
  4561. cma_id_put(id_priv);
  4562. mutex_unlock(&id_priv->handler_mutex);
  4563. trace_cm_id_destroy(id_priv);
  4564. _destroy_id(id_priv, state);
  4565. return;
  4566. }
  4567. mutex_unlock(&id_priv->handler_mutex);
  4568. /*
  4569. * If this races with destroy then the thread that first assigns state
  4570. * to a destroying does the cancel.
  4571. */
  4572. cma_cancel_operation(id_priv, state);
  4573. cma_id_put(id_priv);
  4574. }
  4575. static void cma_process_remove(struct cma_device *cma_dev)
  4576. {
  4577. mutex_lock(&lock);
  4578. while (!list_empty(&cma_dev->id_list)) {
  4579. struct rdma_id_private *id_priv = list_first_entry(
  4580. &cma_dev->id_list, struct rdma_id_private, device_item);
  4581. list_del_init(&id_priv->listen_item);
  4582. list_del_init(&id_priv->device_item);
  4583. cma_id_get(id_priv);
  4584. mutex_unlock(&lock);
  4585. cma_send_device_removal_put(id_priv);
  4586. mutex_lock(&lock);
  4587. }
  4588. mutex_unlock(&lock);
  4589. cma_dev_put(cma_dev);
  4590. wait_for_completion(&cma_dev->comp);
  4591. }
  4592. static bool cma_supported(struct ib_device *device)
  4593. {
  4594. u32 i;
  4595. rdma_for_each_port(device, i) {
  4596. if (rdma_cap_ib_cm(device, i) || rdma_cap_iw_cm(device, i))
  4597. return true;
  4598. }
  4599. return false;
  4600. }
  4601. static int cma_add_one(struct ib_device *device)
  4602. {
  4603. struct rdma_id_private *to_destroy;
  4604. struct cma_device *cma_dev;
  4605. struct rdma_id_private *id_priv;
  4606. unsigned long supported_gids = 0;
  4607. int ret;
  4608. u32 i;
  4609. if (!cma_supported(device))
  4610. return -EOPNOTSUPP;
  4611. cma_dev = kmalloc_obj(*cma_dev);
  4612. if (!cma_dev)
  4613. return -ENOMEM;
  4614. cma_dev->device = device;
  4615. cma_dev->default_gid_type = kzalloc_objs(*cma_dev->default_gid_type,
  4616. device->phys_port_cnt);
  4617. if (!cma_dev->default_gid_type) {
  4618. ret = -ENOMEM;
  4619. goto free_cma_dev;
  4620. }
  4621. cma_dev->default_roce_tos = kcalloc(device->phys_port_cnt,
  4622. sizeof(*cma_dev->default_roce_tos),
  4623. GFP_KERNEL);
  4624. if (!cma_dev->default_roce_tos) {
  4625. ret = -ENOMEM;
  4626. goto free_gid_type;
  4627. }
  4628. rdma_for_each_port (device, i) {
  4629. supported_gids = roce_gid_type_mask_support(device, i);
  4630. WARN_ON(!supported_gids);
  4631. if (supported_gids & (1 << CMA_PREFERRED_ROCE_GID_TYPE))
  4632. cma_dev->default_gid_type[i - rdma_start_port(device)] =
  4633. CMA_PREFERRED_ROCE_GID_TYPE;
  4634. else
  4635. cma_dev->default_gid_type[i - rdma_start_port(device)] =
  4636. find_first_bit(&supported_gids, BITS_PER_LONG);
  4637. cma_dev->default_roce_tos[i - rdma_start_port(device)] = 0;
  4638. }
  4639. init_completion(&cma_dev->comp);
  4640. refcount_set(&cma_dev->refcount, 1);
  4641. INIT_LIST_HEAD(&cma_dev->id_list);
  4642. ib_set_client_data(device, &cma_client, cma_dev);
  4643. mutex_lock(&lock);
  4644. list_add_tail(&cma_dev->list, &dev_list);
  4645. list_for_each_entry(id_priv, &listen_any_list, listen_any_item) {
  4646. ret = cma_listen_on_dev(id_priv, cma_dev, &to_destroy);
  4647. if (ret)
  4648. goto free_listen;
  4649. }
  4650. mutex_unlock(&lock);
  4651. trace_cm_add_one(device);
  4652. return 0;
  4653. free_listen:
  4654. list_del(&cma_dev->list);
  4655. mutex_unlock(&lock);
  4656. /* cma_process_remove() will delete to_destroy */
  4657. cma_process_remove(cma_dev);
  4658. kfree(cma_dev->default_roce_tos);
  4659. free_gid_type:
  4660. kfree(cma_dev->default_gid_type);
  4661. free_cma_dev:
  4662. kfree(cma_dev);
  4663. return ret;
  4664. }
  4665. static void cma_remove_one(struct ib_device *device, void *client_data)
  4666. {
  4667. struct cma_device *cma_dev = client_data;
  4668. trace_cm_remove_one(device);
  4669. mutex_lock(&lock);
  4670. list_del(&cma_dev->list);
  4671. mutex_unlock(&lock);
  4672. cma_process_remove(cma_dev);
  4673. kfree(cma_dev->default_roce_tos);
  4674. kfree(cma_dev->default_gid_type);
  4675. kfree(cma_dev);
  4676. }
  4677. static int cma_init_net(struct net *net)
  4678. {
  4679. struct cma_pernet *pernet = cma_pernet(net);
  4680. xa_init(&pernet->tcp_ps);
  4681. xa_init(&pernet->udp_ps);
  4682. xa_init(&pernet->ipoib_ps);
  4683. xa_init(&pernet->ib_ps);
  4684. return 0;
  4685. }
  4686. static void cma_exit_net(struct net *net)
  4687. {
  4688. struct cma_pernet *pernet = cma_pernet(net);
  4689. WARN_ON(!xa_empty(&pernet->tcp_ps));
  4690. WARN_ON(!xa_empty(&pernet->udp_ps));
  4691. WARN_ON(!xa_empty(&pernet->ipoib_ps));
  4692. WARN_ON(!xa_empty(&pernet->ib_ps));
  4693. }
  4694. static struct pernet_operations cma_pernet_operations = {
  4695. .init = cma_init_net,
  4696. .exit = cma_exit_net,
  4697. .id = &cma_pernet_id,
  4698. .size = sizeof(struct cma_pernet),
  4699. };
  4700. static int __init cma_init(void)
  4701. {
  4702. int ret;
  4703. /*
  4704. * There is a rare lock ordering dependency in cma_netdev_callback()
  4705. * that only happens when bonding is enabled. Teach lockdep that rtnl
  4706. * must never be nested under lock so it can find these without having
  4707. * to test with bonding.
  4708. */
  4709. if (IS_ENABLED(CONFIG_LOCKDEP)) {
  4710. rtnl_lock();
  4711. mutex_lock(&lock);
  4712. mutex_unlock(&lock);
  4713. rtnl_unlock();
  4714. }
  4715. cma_wq = alloc_ordered_workqueue("rdma_cm", WQ_MEM_RECLAIM);
  4716. if (!cma_wq)
  4717. return -ENOMEM;
  4718. ret = register_pernet_subsys(&cma_pernet_operations);
  4719. if (ret)
  4720. goto err_wq;
  4721. ib_sa_register_client(&sa_client);
  4722. register_netdevice_notifier(&cma_nb);
  4723. register_netevent_notifier(&cma_netevent_cb);
  4724. ret = ib_register_client(&cma_client);
  4725. if (ret)
  4726. goto err;
  4727. ret = cma_configfs_init();
  4728. if (ret)
  4729. goto err_ib;
  4730. return 0;
  4731. err_ib:
  4732. ib_unregister_client(&cma_client);
  4733. err:
  4734. unregister_netevent_notifier(&cma_netevent_cb);
  4735. unregister_netdevice_notifier(&cma_nb);
  4736. ib_sa_unregister_client(&sa_client);
  4737. unregister_pernet_subsys(&cma_pernet_operations);
  4738. err_wq:
  4739. destroy_workqueue(cma_wq);
  4740. return ret;
  4741. }
  4742. static void __exit cma_cleanup(void)
  4743. {
  4744. cma_configfs_exit();
  4745. ib_unregister_client(&cma_client);
  4746. unregister_netevent_notifier(&cma_netevent_cb);
  4747. unregister_netdevice_notifier(&cma_nb);
  4748. ib_sa_unregister_client(&sa_client);
  4749. unregister_pernet_subsys(&cma_pernet_operations);
  4750. destroy_workqueue(cma_wq);
  4751. }
  4752. module_init(cma_init);
  4753. module_exit(cma_cleanup);
  4754. static void cma_query_ib_service_handler(int status,
  4755. struct sa_service_rec *recs,
  4756. unsigned int num_recs, void *context)
  4757. {
  4758. struct cma_work *work = context;
  4759. struct rdma_id_private *id_priv = work->id;
  4760. struct sockaddr_ib *addr;
  4761. if (status)
  4762. goto fail;
  4763. if (!num_recs) {
  4764. status = -ENOENT;
  4765. goto fail;
  4766. }
  4767. if (id_priv->id.route.service_recs) {
  4768. status = -EALREADY;
  4769. goto fail;
  4770. }
  4771. id_priv->id.route.service_recs =
  4772. kmalloc_objs(*recs, num_recs);
  4773. if (!id_priv->id.route.service_recs) {
  4774. status = -ENOMEM;
  4775. goto fail;
  4776. }
  4777. id_priv->id.route.num_service_recs = num_recs;
  4778. memcpy(id_priv->id.route.service_recs, recs, sizeof(*recs) * num_recs);
  4779. addr = (struct sockaddr_ib *)&id_priv->id.route.addr.dst_addr;
  4780. addr->sib_family = AF_IB;
  4781. addr->sib_addr = *(struct ib_addr *)&recs->gid;
  4782. addr->sib_pkey = recs->pkey;
  4783. addr->sib_sid = recs->id;
  4784. rdma_addr_set_dgid(&id_priv->id.route.addr.dev_addr,
  4785. (union ib_gid *)&addr->sib_addr);
  4786. ib_addr_set_pkey(&id_priv->id.route.addr.dev_addr,
  4787. ntohs(addr->sib_pkey));
  4788. queue_work(cma_wq, &work->work);
  4789. return;
  4790. fail:
  4791. work->old_state = RDMA_CM_ADDRINFO_QUERY;
  4792. work->new_state = RDMA_CM_ADDR_BOUND;
  4793. work->event.event = RDMA_CM_EVENT_ADDRINFO_ERROR;
  4794. work->event.status = status;
  4795. pr_debug_ratelimited(
  4796. "RDMA CM: SERVICE_ERROR: failed to query service record. status %d\n",
  4797. status);
  4798. queue_work(cma_wq, &work->work);
  4799. }
  4800. static int cma_resolve_ib_service(struct rdma_id_private *id_priv,
  4801. struct rdma_ucm_ib_service *ibs)
  4802. {
  4803. struct sa_service_rec sr = {};
  4804. ib_sa_comp_mask mask = 0;
  4805. struct cma_work *work;
  4806. work = kzalloc_obj(*work);
  4807. if (!work)
  4808. return -ENOMEM;
  4809. cma_id_get(id_priv);
  4810. work->id = id_priv;
  4811. INIT_WORK(&work->work, cma_work_handler);
  4812. work->old_state = RDMA_CM_ADDRINFO_QUERY;
  4813. work->new_state = RDMA_CM_ADDRINFO_RESOLVED;
  4814. work->event.event = RDMA_CM_EVENT_ADDRINFO_RESOLVED;
  4815. if (ibs->flags & RDMA_USER_CM_IB_SERVICE_FLAG_ID) {
  4816. sr.id = cpu_to_be64(ibs->service_id);
  4817. mask |= IB_SA_SERVICE_REC_SERVICE_ID;
  4818. }
  4819. if (ibs->flags & RDMA_USER_CM_IB_SERVICE_FLAG_NAME) {
  4820. strscpy(sr.name, ibs->service_name, sizeof(sr.name));
  4821. mask |= IB_SA_SERVICE_REC_SERVICE_NAME;
  4822. }
  4823. id_priv->query_id = ib_sa_service_rec_get(&sa_client,
  4824. id_priv->id.device,
  4825. id_priv->id.port_num,
  4826. &sr, mask,
  4827. 2000, GFP_KERNEL,
  4828. cma_query_ib_service_handler,
  4829. work, &id_priv->query);
  4830. if (id_priv->query_id < 0) {
  4831. cma_id_put(id_priv);
  4832. kfree(work);
  4833. return id_priv->query_id;
  4834. }
  4835. return 0;
  4836. }
  4837. int rdma_resolve_ib_service(struct rdma_cm_id *id,
  4838. struct rdma_ucm_ib_service *ibs)
  4839. {
  4840. struct rdma_id_private *id_priv;
  4841. int ret;
  4842. id_priv = container_of(id, struct rdma_id_private, id);
  4843. if (!id_priv->cma_dev ||
  4844. !cma_comp_exch(id_priv, RDMA_CM_ADDR_BOUND, RDMA_CM_ADDRINFO_QUERY))
  4845. return -EINVAL;
  4846. if (rdma_cap_ib_sa(id->device, id->port_num))
  4847. ret = cma_resolve_ib_service(id_priv, ibs);
  4848. else
  4849. ret = -EOPNOTSUPP;
  4850. if (ret)
  4851. goto err;
  4852. return 0;
  4853. err:
  4854. cma_comp_exch(id_priv, RDMA_CM_ADDRINFO_QUERY, RDMA_CM_ADDR_BOUND);
  4855. return ret;
  4856. }
  4857. EXPORT_SYMBOL(rdma_resolve_ib_service);