af_key.c 102 KB

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  1. // SPDX-License-Identifier: GPL-2.0-or-later
  2. /*
  3. * net/key/af_key.c An implementation of PF_KEYv2 sockets.
  4. *
  5. * Authors: Maxim Giryaev <gem@asplinux.ru>
  6. * David S. Miller <davem@redhat.com>
  7. * Alexey Kuznetsov <kuznet@ms2.inr.ac.ru>
  8. * Kunihiro Ishiguro <kunihiro@ipinfusion.com>
  9. * Kazunori MIYAZAWA / USAGI Project <miyazawa@linux-ipv6.org>
  10. * Derek Atkins <derek@ihtfp.com>
  11. */
  12. #include <linux/capability.h>
  13. #include <linux/module.h>
  14. #include <linux/kernel.h>
  15. #include <linux/socket.h>
  16. #include <linux/pfkeyv2.h>
  17. #include <linux/ipsec.h>
  18. #include <linux/skbuff.h>
  19. #include <linux/rtnetlink.h>
  20. #include <linux/in.h>
  21. #include <linux/in6.h>
  22. #include <linux/proc_fs.h>
  23. #include <linux/init.h>
  24. #include <linux/slab.h>
  25. #include <net/net_namespace.h>
  26. #include <net/netns/generic.h>
  27. #include <net/xfrm.h>
  28. #include <net/sock.h>
  29. #define _X2KEY(x) ((x) == XFRM_INF ? 0 : (x))
  30. #define _KEY2X(x) ((x) == 0 ? XFRM_INF : (x))
  31. static unsigned int pfkey_net_id __read_mostly;
  32. struct netns_pfkey {
  33. /* List of all pfkey sockets. */
  34. struct hlist_head table;
  35. atomic_t socks_nr;
  36. };
  37. static DEFINE_MUTEX(pfkey_mutex);
  38. #define DUMMY_MARK 0
  39. static const struct xfrm_mark dummy_mark = {0, 0};
  40. struct pfkey_sock {
  41. /* struct sock must be the first member of struct pfkey_sock */
  42. struct sock sk;
  43. int registered;
  44. int promisc;
  45. struct {
  46. uint8_t msg_version;
  47. uint32_t msg_portid;
  48. int (*dump)(struct pfkey_sock *sk);
  49. void (*done)(struct pfkey_sock *sk);
  50. union {
  51. struct xfrm_policy_walk policy;
  52. struct xfrm_state_walk state;
  53. } u;
  54. struct sk_buff *skb;
  55. } dump;
  56. struct mutex dump_lock;
  57. };
  58. static int parse_sockaddr_pair(struct sockaddr *sa, int ext_len,
  59. xfrm_address_t *saddr, xfrm_address_t *daddr,
  60. u16 *family);
  61. static inline struct pfkey_sock *pfkey_sk(struct sock *sk)
  62. {
  63. return (struct pfkey_sock *)sk;
  64. }
  65. static int pfkey_can_dump(const struct sock *sk)
  66. {
  67. if (3 * atomic_read(&sk->sk_rmem_alloc) <= 2 * sk->sk_rcvbuf)
  68. return 1;
  69. return 0;
  70. }
  71. static void pfkey_terminate_dump(struct pfkey_sock *pfk)
  72. {
  73. if (pfk->dump.dump) {
  74. if (pfk->dump.skb) {
  75. kfree_skb(pfk->dump.skb);
  76. pfk->dump.skb = NULL;
  77. }
  78. pfk->dump.done(pfk);
  79. pfk->dump.dump = NULL;
  80. pfk->dump.done = NULL;
  81. }
  82. }
  83. static void pfkey_sock_destruct(struct sock *sk)
  84. {
  85. struct net *net = sock_net(sk);
  86. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  87. pfkey_terminate_dump(pfkey_sk(sk));
  88. skb_queue_purge(&sk->sk_receive_queue);
  89. if (!sock_flag(sk, SOCK_DEAD)) {
  90. pr_err("Attempt to release alive pfkey socket: %p\n", sk);
  91. return;
  92. }
  93. WARN_ON(atomic_read(&sk->sk_rmem_alloc));
  94. WARN_ON(refcount_read(&sk->sk_wmem_alloc));
  95. atomic_dec(&net_pfkey->socks_nr);
  96. }
  97. static const struct proto_ops pfkey_ops;
  98. static void pfkey_insert(struct sock *sk)
  99. {
  100. struct net *net = sock_net(sk);
  101. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  102. mutex_lock(&pfkey_mutex);
  103. sk_add_node_rcu(sk, &net_pfkey->table);
  104. mutex_unlock(&pfkey_mutex);
  105. }
  106. static void pfkey_remove(struct sock *sk)
  107. {
  108. mutex_lock(&pfkey_mutex);
  109. sk_del_node_init_rcu(sk);
  110. mutex_unlock(&pfkey_mutex);
  111. }
  112. static struct proto key_proto = {
  113. .name = "KEY",
  114. .owner = THIS_MODULE,
  115. .obj_size = sizeof(struct pfkey_sock),
  116. };
  117. static int pfkey_create(struct net *net, struct socket *sock, int protocol,
  118. int kern)
  119. {
  120. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  121. struct sock *sk;
  122. struct pfkey_sock *pfk;
  123. if (!ns_capable(net->user_ns, CAP_NET_ADMIN))
  124. return -EPERM;
  125. if (sock->type != SOCK_RAW)
  126. return -ESOCKTNOSUPPORT;
  127. if (protocol != PF_KEY_V2)
  128. return -EPROTONOSUPPORT;
  129. sk = sk_alloc(net, PF_KEY, GFP_KERNEL, &key_proto, kern);
  130. if (sk == NULL)
  131. return -ENOMEM;
  132. pfk = pfkey_sk(sk);
  133. mutex_init(&pfk->dump_lock);
  134. sock->ops = &pfkey_ops;
  135. sock_init_data(sock, sk);
  136. sk->sk_family = PF_KEY;
  137. sk->sk_destruct = pfkey_sock_destruct;
  138. atomic_inc(&net_pfkey->socks_nr);
  139. pfkey_insert(sk);
  140. return 0;
  141. }
  142. static int pfkey_release(struct socket *sock)
  143. {
  144. struct sock *sk = sock->sk;
  145. if (!sk)
  146. return 0;
  147. pfkey_remove(sk);
  148. sock_orphan(sk);
  149. sock->sk = NULL;
  150. skb_queue_purge(&sk->sk_write_queue);
  151. synchronize_rcu();
  152. sock_put(sk);
  153. return 0;
  154. }
  155. static int pfkey_broadcast_one(struct sk_buff *skb, gfp_t allocation,
  156. struct sock *sk)
  157. {
  158. int err = -ENOBUFS;
  159. if (atomic_read(&sk->sk_rmem_alloc) > sk->sk_rcvbuf)
  160. return err;
  161. skb = skb_clone(skb, allocation);
  162. if (skb) {
  163. skb_set_owner_r(skb, sk);
  164. skb_queue_tail(&sk->sk_receive_queue, skb);
  165. sk->sk_data_ready(sk);
  166. err = 0;
  167. }
  168. return err;
  169. }
  170. /* Send SKB to all pfkey sockets matching selected criteria. */
  171. #define BROADCAST_ALL 0
  172. #define BROADCAST_ONE 1
  173. #define BROADCAST_REGISTERED 2
  174. #define BROADCAST_PROMISC_ONLY 4
  175. static int pfkey_broadcast(struct sk_buff *skb, gfp_t allocation,
  176. int broadcast_flags, struct sock *one_sk,
  177. struct net *net)
  178. {
  179. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  180. struct sock *sk;
  181. int err = -ESRCH;
  182. /* XXX Do we need something like netlink_overrun? I think
  183. * XXX PF_KEY socket apps will not mind current behavior.
  184. */
  185. if (!skb)
  186. return -ENOMEM;
  187. rcu_read_lock();
  188. sk_for_each_rcu(sk, &net_pfkey->table) {
  189. struct pfkey_sock *pfk = pfkey_sk(sk);
  190. int err2;
  191. /* Yes, it means that if you are meant to receive this
  192. * pfkey message you receive it twice as promiscuous
  193. * socket.
  194. */
  195. if (pfk->promisc)
  196. pfkey_broadcast_one(skb, GFP_ATOMIC, sk);
  197. /* the exact target will be processed later */
  198. if (sk == one_sk)
  199. continue;
  200. if (broadcast_flags != BROADCAST_ALL) {
  201. if (broadcast_flags & BROADCAST_PROMISC_ONLY)
  202. continue;
  203. if ((broadcast_flags & BROADCAST_REGISTERED) &&
  204. !pfk->registered)
  205. continue;
  206. if (broadcast_flags & BROADCAST_ONE)
  207. continue;
  208. }
  209. err2 = pfkey_broadcast_one(skb, GFP_ATOMIC, sk);
  210. /* Error is cleared after successful sending to at least one
  211. * registered KM */
  212. if ((broadcast_flags & BROADCAST_REGISTERED) && err)
  213. err = err2;
  214. }
  215. rcu_read_unlock();
  216. if (one_sk != NULL)
  217. err = pfkey_broadcast_one(skb, allocation, one_sk);
  218. kfree_skb(skb);
  219. return err;
  220. }
  221. static int pfkey_do_dump(struct pfkey_sock *pfk)
  222. {
  223. struct sadb_msg *hdr;
  224. int rc;
  225. mutex_lock(&pfk->dump_lock);
  226. if (!pfk->dump.dump) {
  227. rc = 0;
  228. goto out;
  229. }
  230. rc = pfk->dump.dump(pfk);
  231. if (rc == -ENOBUFS) {
  232. rc = 0;
  233. goto out;
  234. }
  235. if (pfk->dump.skb) {
  236. if (!pfkey_can_dump(&pfk->sk)) {
  237. rc = 0;
  238. goto out;
  239. }
  240. hdr = (struct sadb_msg *) pfk->dump.skb->data;
  241. hdr->sadb_msg_seq = 0;
  242. hdr->sadb_msg_errno = rc;
  243. pfkey_broadcast(pfk->dump.skb, GFP_ATOMIC, BROADCAST_ONE,
  244. &pfk->sk, sock_net(&pfk->sk));
  245. pfk->dump.skb = NULL;
  246. }
  247. pfkey_terminate_dump(pfk);
  248. out:
  249. mutex_unlock(&pfk->dump_lock);
  250. return rc;
  251. }
  252. static inline void pfkey_hdr_dup(struct sadb_msg *new,
  253. const struct sadb_msg *orig)
  254. {
  255. *new = *orig;
  256. }
  257. static int pfkey_error(const struct sadb_msg *orig, int err, struct sock *sk)
  258. {
  259. struct sk_buff *skb = alloc_skb(sizeof(struct sadb_msg) + 16, GFP_KERNEL);
  260. struct sadb_msg *hdr;
  261. if (!skb)
  262. return -ENOBUFS;
  263. /* Woe be to the platform trying to support PFKEY yet
  264. * having normal errnos outside the 1-255 range, inclusive.
  265. */
  266. err = -err;
  267. if (err == ERESTARTSYS ||
  268. err == ERESTARTNOHAND ||
  269. err == ERESTARTNOINTR)
  270. err = EINTR;
  271. if (err >= 512)
  272. err = EINVAL;
  273. BUG_ON(err <= 0 || err >= 256);
  274. hdr = skb_put(skb, sizeof(struct sadb_msg));
  275. pfkey_hdr_dup(hdr, orig);
  276. hdr->sadb_msg_errno = (uint8_t) err;
  277. hdr->sadb_msg_len = (sizeof(struct sadb_msg) /
  278. sizeof(uint64_t));
  279. pfkey_broadcast(skb, GFP_KERNEL, BROADCAST_ONE, sk, sock_net(sk));
  280. return 0;
  281. }
  282. static const u8 sadb_ext_min_len[] = {
  283. [SADB_EXT_RESERVED] = (u8) 0,
  284. [SADB_EXT_SA] = (u8) sizeof(struct sadb_sa),
  285. [SADB_EXT_LIFETIME_CURRENT] = (u8) sizeof(struct sadb_lifetime),
  286. [SADB_EXT_LIFETIME_HARD] = (u8) sizeof(struct sadb_lifetime),
  287. [SADB_EXT_LIFETIME_SOFT] = (u8) sizeof(struct sadb_lifetime),
  288. [SADB_EXT_ADDRESS_SRC] = (u8) sizeof(struct sadb_address),
  289. [SADB_EXT_ADDRESS_DST] = (u8) sizeof(struct sadb_address),
  290. [SADB_EXT_ADDRESS_PROXY] = (u8) sizeof(struct sadb_address),
  291. [SADB_EXT_KEY_AUTH] = (u8) sizeof(struct sadb_key),
  292. [SADB_EXT_KEY_ENCRYPT] = (u8) sizeof(struct sadb_key),
  293. [SADB_EXT_IDENTITY_SRC] = (u8) sizeof(struct sadb_ident),
  294. [SADB_EXT_IDENTITY_DST] = (u8) sizeof(struct sadb_ident),
  295. [SADB_EXT_SENSITIVITY] = (u8) sizeof(struct sadb_sens),
  296. [SADB_EXT_PROPOSAL] = (u8) sizeof(struct sadb_prop),
  297. [SADB_EXT_SUPPORTED_AUTH] = (u8) sizeof(struct sadb_supported),
  298. [SADB_EXT_SUPPORTED_ENCRYPT] = (u8) sizeof(struct sadb_supported),
  299. [SADB_EXT_SPIRANGE] = (u8) sizeof(struct sadb_spirange),
  300. [SADB_X_EXT_KMPRIVATE] = (u8) sizeof(struct sadb_x_kmprivate),
  301. [SADB_X_EXT_POLICY] = (u8) sizeof(struct sadb_x_policy),
  302. [SADB_X_EXT_SA2] = (u8) sizeof(struct sadb_x_sa2),
  303. [SADB_X_EXT_NAT_T_TYPE] = (u8) sizeof(struct sadb_x_nat_t_type),
  304. [SADB_X_EXT_NAT_T_SPORT] = (u8) sizeof(struct sadb_x_nat_t_port),
  305. [SADB_X_EXT_NAT_T_DPORT] = (u8) sizeof(struct sadb_x_nat_t_port),
  306. [SADB_X_EXT_NAT_T_OA] = (u8) sizeof(struct sadb_address),
  307. [SADB_X_EXT_SEC_CTX] = (u8) sizeof(struct sadb_x_sec_ctx),
  308. [SADB_X_EXT_KMADDRESS] = (u8) sizeof(struct sadb_x_kmaddress),
  309. [SADB_X_EXT_FILTER] = (u8) sizeof(struct sadb_x_filter),
  310. };
  311. /* Verify sadb_address_{len,prefixlen} against sa_family. */
  312. static int verify_address_len(const void *p)
  313. {
  314. const struct sadb_address *sp = p;
  315. const struct sockaddr *addr = (const struct sockaddr *)(sp + 1);
  316. const struct sockaddr_in *sin;
  317. #if IS_ENABLED(CONFIG_IPV6)
  318. const struct sockaddr_in6 *sin6;
  319. #endif
  320. int len;
  321. if (sp->sadb_address_len <
  322. DIV_ROUND_UP(sizeof(*sp) + offsetofend(typeof(*addr), sa_family),
  323. sizeof(uint64_t)))
  324. return -EINVAL;
  325. switch (addr->sa_family) {
  326. case AF_INET:
  327. len = DIV_ROUND_UP(sizeof(*sp) + sizeof(*sin), sizeof(uint64_t));
  328. if (sp->sadb_address_len != len ||
  329. sp->sadb_address_prefixlen > 32)
  330. return -EINVAL;
  331. break;
  332. #if IS_ENABLED(CONFIG_IPV6)
  333. case AF_INET6:
  334. len = DIV_ROUND_UP(sizeof(*sp) + sizeof(*sin6), sizeof(uint64_t));
  335. if (sp->sadb_address_len != len ||
  336. sp->sadb_address_prefixlen > 128)
  337. return -EINVAL;
  338. break;
  339. #endif
  340. default:
  341. /* It is user using kernel to keep track of security
  342. * associations for another protocol, such as
  343. * OSPF/RSVP/RIPV2/MIP. It is user's job to verify
  344. * lengths.
  345. *
  346. * XXX Actually, association/policy database is not yet
  347. * XXX able to cope with arbitrary sockaddr families.
  348. * XXX When it can, remove this -EINVAL. -DaveM
  349. */
  350. return -EINVAL;
  351. }
  352. return 0;
  353. }
  354. static inline int sadb_key_len(const struct sadb_key *key)
  355. {
  356. int key_bytes = DIV_ROUND_UP(key->sadb_key_bits, 8);
  357. return DIV_ROUND_UP(sizeof(struct sadb_key) + key_bytes,
  358. sizeof(uint64_t));
  359. }
  360. static int verify_key_len(const void *p)
  361. {
  362. const struct sadb_key *key = p;
  363. if (sadb_key_len(key) > key->sadb_key_len)
  364. return -EINVAL;
  365. return 0;
  366. }
  367. static inline int pfkey_sec_ctx_len(const struct sadb_x_sec_ctx *sec_ctx)
  368. {
  369. return DIV_ROUND_UP(sizeof(struct sadb_x_sec_ctx) +
  370. sec_ctx->sadb_x_ctx_len,
  371. sizeof(uint64_t));
  372. }
  373. static inline int verify_sec_ctx_len(const void *p)
  374. {
  375. const struct sadb_x_sec_ctx *sec_ctx = p;
  376. int len = sec_ctx->sadb_x_ctx_len;
  377. if (len > PAGE_SIZE)
  378. return -EINVAL;
  379. len = pfkey_sec_ctx_len(sec_ctx);
  380. if (sec_ctx->sadb_x_sec_len != len)
  381. return -EINVAL;
  382. return 0;
  383. }
  384. static inline struct xfrm_user_sec_ctx *pfkey_sadb2xfrm_user_sec_ctx(const struct sadb_x_sec_ctx *sec_ctx,
  385. gfp_t gfp)
  386. {
  387. struct xfrm_user_sec_ctx *uctx = NULL;
  388. int ctx_size = sec_ctx->sadb_x_ctx_len;
  389. uctx = kmalloc((sizeof(*uctx)+ctx_size), gfp);
  390. if (!uctx)
  391. return NULL;
  392. uctx->len = pfkey_sec_ctx_len(sec_ctx);
  393. uctx->exttype = sec_ctx->sadb_x_sec_exttype;
  394. uctx->ctx_doi = sec_ctx->sadb_x_ctx_doi;
  395. uctx->ctx_alg = sec_ctx->sadb_x_ctx_alg;
  396. uctx->ctx_len = sec_ctx->sadb_x_ctx_len;
  397. memcpy(uctx + 1, sec_ctx + 1,
  398. uctx->ctx_len);
  399. return uctx;
  400. }
  401. static int present_and_same_family(const struct sadb_address *src,
  402. const struct sadb_address *dst)
  403. {
  404. const struct sockaddr *s_addr, *d_addr;
  405. if (!src || !dst)
  406. return 0;
  407. s_addr = (const struct sockaddr *)(src + 1);
  408. d_addr = (const struct sockaddr *)(dst + 1);
  409. if (s_addr->sa_family != d_addr->sa_family)
  410. return 0;
  411. if (s_addr->sa_family != AF_INET
  412. #if IS_ENABLED(CONFIG_IPV6)
  413. && s_addr->sa_family != AF_INET6
  414. #endif
  415. )
  416. return 0;
  417. return 1;
  418. }
  419. static int parse_exthdrs(struct sk_buff *skb, const struct sadb_msg *hdr, void **ext_hdrs)
  420. {
  421. const char *p = (char *) hdr;
  422. int len = skb->len;
  423. len -= sizeof(*hdr);
  424. p += sizeof(*hdr);
  425. while (len > 0) {
  426. const struct sadb_ext *ehdr = (const struct sadb_ext *) p;
  427. uint16_t ext_type;
  428. int ext_len;
  429. if (len < sizeof(*ehdr))
  430. return -EINVAL;
  431. ext_len = ehdr->sadb_ext_len;
  432. ext_len *= sizeof(uint64_t);
  433. ext_type = ehdr->sadb_ext_type;
  434. if (ext_len < sizeof(uint64_t) ||
  435. ext_len > len ||
  436. ext_type == SADB_EXT_RESERVED)
  437. return -EINVAL;
  438. if (ext_type <= SADB_EXT_MAX) {
  439. int min = (int) sadb_ext_min_len[ext_type];
  440. if (ext_len < min)
  441. return -EINVAL;
  442. if (ext_hdrs[ext_type-1] != NULL)
  443. return -EINVAL;
  444. switch (ext_type) {
  445. case SADB_EXT_ADDRESS_SRC:
  446. case SADB_EXT_ADDRESS_DST:
  447. case SADB_EXT_ADDRESS_PROXY:
  448. case SADB_X_EXT_NAT_T_OA:
  449. if (verify_address_len(p))
  450. return -EINVAL;
  451. break;
  452. case SADB_X_EXT_SEC_CTX:
  453. if (verify_sec_ctx_len(p))
  454. return -EINVAL;
  455. break;
  456. case SADB_EXT_KEY_AUTH:
  457. case SADB_EXT_KEY_ENCRYPT:
  458. if (verify_key_len(p))
  459. return -EINVAL;
  460. break;
  461. default:
  462. break;
  463. }
  464. ext_hdrs[ext_type-1] = (void *) p;
  465. }
  466. p += ext_len;
  467. len -= ext_len;
  468. }
  469. return 0;
  470. }
  471. static uint16_t
  472. pfkey_satype2proto(uint8_t satype)
  473. {
  474. switch (satype) {
  475. case SADB_SATYPE_UNSPEC:
  476. return IPSEC_PROTO_ANY;
  477. case SADB_SATYPE_AH:
  478. return IPPROTO_AH;
  479. case SADB_SATYPE_ESP:
  480. return IPPROTO_ESP;
  481. case SADB_X_SATYPE_IPCOMP:
  482. return IPPROTO_COMP;
  483. default:
  484. return 0;
  485. }
  486. /* NOTREACHED */
  487. }
  488. static uint8_t
  489. pfkey_proto2satype(uint16_t proto)
  490. {
  491. switch (proto) {
  492. case IPPROTO_AH:
  493. return SADB_SATYPE_AH;
  494. case IPPROTO_ESP:
  495. return SADB_SATYPE_ESP;
  496. case IPPROTO_COMP:
  497. return SADB_X_SATYPE_IPCOMP;
  498. default:
  499. return 0;
  500. }
  501. /* NOTREACHED */
  502. }
  503. /* BTW, this scheme means that there is no way with PFKEY2 sockets to
  504. * say specifically 'just raw sockets' as we encode them as 255.
  505. */
  506. static uint8_t pfkey_proto_to_xfrm(uint8_t proto)
  507. {
  508. return proto == IPSEC_PROTO_ANY ? 0 : proto;
  509. }
  510. static uint8_t pfkey_proto_from_xfrm(uint8_t proto)
  511. {
  512. return proto ? proto : IPSEC_PROTO_ANY;
  513. }
  514. static inline int pfkey_sockaddr_len(sa_family_t family)
  515. {
  516. switch (family) {
  517. case AF_INET:
  518. return sizeof(struct sockaddr_in);
  519. #if IS_ENABLED(CONFIG_IPV6)
  520. case AF_INET6:
  521. return sizeof(struct sockaddr_in6);
  522. #endif
  523. }
  524. return 0;
  525. }
  526. static
  527. int pfkey_sockaddr_extract(const struct sockaddr *sa, xfrm_address_t *xaddr)
  528. {
  529. switch (sa->sa_family) {
  530. case AF_INET:
  531. xaddr->a4 =
  532. ((struct sockaddr_in *)sa)->sin_addr.s_addr;
  533. return AF_INET;
  534. #if IS_ENABLED(CONFIG_IPV6)
  535. case AF_INET6:
  536. memcpy(xaddr->a6,
  537. &((struct sockaddr_in6 *)sa)->sin6_addr,
  538. sizeof(struct in6_addr));
  539. return AF_INET6;
  540. #endif
  541. }
  542. return 0;
  543. }
  544. static
  545. int pfkey_sadb_addr2xfrm_addr(const struct sadb_address *addr, xfrm_address_t *xaddr)
  546. {
  547. return pfkey_sockaddr_extract((struct sockaddr *)(addr + 1),
  548. xaddr);
  549. }
  550. static struct xfrm_state *pfkey_xfrm_state_lookup(struct net *net, const struct sadb_msg *hdr, void * const *ext_hdrs)
  551. {
  552. const struct sadb_sa *sa;
  553. const struct sadb_address *addr;
  554. uint16_t proto;
  555. unsigned short family;
  556. xfrm_address_t *xaddr;
  557. sa = ext_hdrs[SADB_EXT_SA - 1];
  558. if (sa == NULL)
  559. return NULL;
  560. proto = pfkey_satype2proto(hdr->sadb_msg_satype);
  561. if (proto == 0)
  562. return NULL;
  563. /* sadb_address_len should be checked by caller */
  564. addr = ext_hdrs[SADB_EXT_ADDRESS_DST - 1];
  565. if (addr == NULL)
  566. return NULL;
  567. family = ((const struct sockaddr *)(addr + 1))->sa_family;
  568. switch (family) {
  569. case AF_INET:
  570. xaddr = (xfrm_address_t *)&((const struct sockaddr_in *)(addr + 1))->sin_addr;
  571. break;
  572. #if IS_ENABLED(CONFIG_IPV6)
  573. case AF_INET6:
  574. xaddr = (xfrm_address_t *)&((const struct sockaddr_in6 *)(addr + 1))->sin6_addr;
  575. break;
  576. #endif
  577. default:
  578. xaddr = NULL;
  579. }
  580. if (!xaddr)
  581. return NULL;
  582. return xfrm_state_lookup(net, DUMMY_MARK, xaddr, sa->sadb_sa_spi, proto, family);
  583. }
  584. #define PFKEY_ALIGN8(a) (1 + (((a) - 1) | (8 - 1)))
  585. static int
  586. pfkey_sockaddr_size(sa_family_t family)
  587. {
  588. return PFKEY_ALIGN8(pfkey_sockaddr_len(family));
  589. }
  590. static inline int pfkey_mode_from_xfrm(int mode)
  591. {
  592. switch(mode) {
  593. case XFRM_MODE_TRANSPORT:
  594. return IPSEC_MODE_TRANSPORT;
  595. case XFRM_MODE_TUNNEL:
  596. return IPSEC_MODE_TUNNEL;
  597. case XFRM_MODE_BEET:
  598. return IPSEC_MODE_BEET;
  599. default:
  600. return -1;
  601. }
  602. }
  603. static inline int pfkey_mode_to_xfrm(int mode)
  604. {
  605. switch(mode) {
  606. case IPSEC_MODE_ANY: /*XXX*/
  607. case IPSEC_MODE_TRANSPORT:
  608. return XFRM_MODE_TRANSPORT;
  609. case IPSEC_MODE_TUNNEL:
  610. return XFRM_MODE_TUNNEL;
  611. case IPSEC_MODE_BEET:
  612. return XFRM_MODE_BEET;
  613. default:
  614. return -1;
  615. }
  616. }
  617. static unsigned int pfkey_sockaddr_fill(const xfrm_address_t *xaddr, __be16 port,
  618. struct sockaddr *sa,
  619. unsigned short family)
  620. {
  621. switch (family) {
  622. case AF_INET:
  623. {
  624. struct sockaddr_in *sin = (struct sockaddr_in *)sa;
  625. sin->sin_family = AF_INET;
  626. sin->sin_port = port;
  627. sin->sin_addr.s_addr = xaddr->a4;
  628. memset(sin->sin_zero, 0, sizeof(sin->sin_zero));
  629. return 32;
  630. }
  631. #if IS_ENABLED(CONFIG_IPV6)
  632. case AF_INET6:
  633. {
  634. struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)sa;
  635. sin6->sin6_family = AF_INET6;
  636. sin6->sin6_port = port;
  637. sin6->sin6_flowinfo = 0;
  638. sin6->sin6_addr = xaddr->in6;
  639. sin6->sin6_scope_id = 0;
  640. return 128;
  641. }
  642. #endif
  643. }
  644. return 0;
  645. }
  646. static unsigned int pfkey_sockaddr_fill_zero_tail(const xfrm_address_t *xaddr,
  647. __be16 port,
  648. struct sockaddr *sa,
  649. unsigned short family)
  650. {
  651. unsigned int prefixlen;
  652. int sockaddr_len = pfkey_sockaddr_len(family);
  653. int sockaddr_size = pfkey_sockaddr_size(family);
  654. prefixlen = pfkey_sockaddr_fill(xaddr, port, sa, family);
  655. if (sockaddr_size > sockaddr_len)
  656. memset((u8 *)sa + sockaddr_len, 0, sockaddr_size - sockaddr_len);
  657. return prefixlen;
  658. }
  659. static struct sk_buff *__pfkey_xfrm_state2msg(const struct xfrm_state *x,
  660. int add_keys, int hsc)
  661. {
  662. struct sk_buff *skb;
  663. struct sadb_msg *hdr;
  664. struct sadb_sa *sa;
  665. struct sadb_lifetime *lifetime;
  666. struct sadb_address *addr;
  667. struct sadb_key *key;
  668. struct sadb_x_sa2 *sa2;
  669. struct sadb_x_sec_ctx *sec_ctx;
  670. struct xfrm_sec_ctx *xfrm_ctx;
  671. int ctx_size = 0;
  672. int size;
  673. int auth_key_size = 0;
  674. int encrypt_key_size = 0;
  675. int sockaddr_size;
  676. struct xfrm_encap_tmpl *natt = NULL;
  677. int mode;
  678. /* address family check */
  679. sockaddr_size = pfkey_sockaddr_size(x->props.family);
  680. if (!sockaddr_size)
  681. return ERR_PTR(-EINVAL);
  682. /* base, SA, (lifetime (HSC),) address(SD), (address(P),)
  683. key(AE), (identity(SD),) (sensitivity)> */
  684. size = sizeof(struct sadb_msg) +sizeof(struct sadb_sa) +
  685. sizeof(struct sadb_lifetime) +
  686. ((hsc & 1) ? sizeof(struct sadb_lifetime) : 0) +
  687. ((hsc & 2) ? sizeof(struct sadb_lifetime) : 0) +
  688. sizeof(struct sadb_address)*2 +
  689. sockaddr_size*2 +
  690. sizeof(struct sadb_x_sa2);
  691. if ((xfrm_ctx = x->security)) {
  692. ctx_size = PFKEY_ALIGN8(xfrm_ctx->ctx_len);
  693. size += sizeof(struct sadb_x_sec_ctx) + ctx_size;
  694. }
  695. /* identity & sensitivity */
  696. if (!xfrm_addr_equal(&x->sel.saddr, &x->props.saddr, x->props.family))
  697. size += sizeof(struct sadb_address) + sockaddr_size;
  698. if (add_keys) {
  699. if (x->aalg && x->aalg->alg_key_len) {
  700. auth_key_size =
  701. PFKEY_ALIGN8((x->aalg->alg_key_len + 7) / 8);
  702. size += sizeof(struct sadb_key) + auth_key_size;
  703. }
  704. if (x->ealg && x->ealg->alg_key_len) {
  705. encrypt_key_size =
  706. PFKEY_ALIGN8((x->ealg->alg_key_len+7) / 8);
  707. size += sizeof(struct sadb_key) + encrypt_key_size;
  708. }
  709. }
  710. if (x->encap)
  711. natt = x->encap;
  712. if (natt && natt->encap_type) {
  713. size += sizeof(struct sadb_x_nat_t_type);
  714. size += sizeof(struct sadb_x_nat_t_port);
  715. size += sizeof(struct sadb_x_nat_t_port);
  716. }
  717. skb = alloc_skb(size + 16, GFP_ATOMIC);
  718. if (skb == NULL)
  719. return ERR_PTR(-ENOBUFS);
  720. /* call should fill header later */
  721. hdr = skb_put(skb, sizeof(struct sadb_msg));
  722. memset(hdr, 0, size); /* XXX do we need this ? */
  723. hdr->sadb_msg_len = size / sizeof(uint64_t);
  724. /* sa */
  725. sa = skb_put(skb, sizeof(struct sadb_sa));
  726. sa->sadb_sa_len = sizeof(struct sadb_sa)/sizeof(uint64_t);
  727. sa->sadb_sa_exttype = SADB_EXT_SA;
  728. sa->sadb_sa_spi = x->id.spi;
  729. sa->sadb_sa_replay = x->props.replay_window;
  730. switch (x->km.state) {
  731. case XFRM_STATE_VALID:
  732. sa->sadb_sa_state = x->km.dying ?
  733. SADB_SASTATE_DYING : SADB_SASTATE_MATURE;
  734. break;
  735. case XFRM_STATE_ACQ:
  736. sa->sadb_sa_state = SADB_SASTATE_LARVAL;
  737. break;
  738. default:
  739. sa->sadb_sa_state = SADB_SASTATE_DEAD;
  740. break;
  741. }
  742. sa->sadb_sa_auth = 0;
  743. if (x->aalg) {
  744. struct xfrm_algo_desc *a = xfrm_aalg_get_byname(x->aalg->alg_name, 0);
  745. sa->sadb_sa_auth = (a && a->pfkey_supported) ?
  746. a->desc.sadb_alg_id : 0;
  747. }
  748. sa->sadb_sa_encrypt = 0;
  749. BUG_ON(x->ealg && x->calg);
  750. if (x->ealg) {
  751. struct xfrm_algo_desc *a = xfrm_ealg_get_byname(x->ealg->alg_name, 0);
  752. sa->sadb_sa_encrypt = (a && a->pfkey_supported) ?
  753. a->desc.sadb_alg_id : 0;
  754. }
  755. /* KAME compatible: sadb_sa_encrypt is overloaded with calg id */
  756. if (x->calg) {
  757. struct xfrm_algo_desc *a = xfrm_calg_get_byname(x->calg->alg_name, 0);
  758. sa->sadb_sa_encrypt = (a && a->pfkey_supported) ?
  759. a->desc.sadb_alg_id : 0;
  760. }
  761. sa->sadb_sa_flags = 0;
  762. if (x->props.flags & XFRM_STATE_NOECN)
  763. sa->sadb_sa_flags |= SADB_SAFLAGS_NOECN;
  764. if (x->props.flags & XFRM_STATE_DECAP_DSCP)
  765. sa->sadb_sa_flags |= SADB_SAFLAGS_DECAP_DSCP;
  766. if (x->props.flags & XFRM_STATE_NOPMTUDISC)
  767. sa->sadb_sa_flags |= SADB_SAFLAGS_NOPMTUDISC;
  768. /* hard time */
  769. if (hsc & 2) {
  770. lifetime = skb_put(skb, sizeof(struct sadb_lifetime));
  771. lifetime->sadb_lifetime_len =
  772. sizeof(struct sadb_lifetime)/sizeof(uint64_t);
  773. lifetime->sadb_lifetime_exttype = SADB_EXT_LIFETIME_HARD;
  774. lifetime->sadb_lifetime_allocations = _X2KEY(x->lft.hard_packet_limit);
  775. lifetime->sadb_lifetime_bytes = _X2KEY(x->lft.hard_byte_limit);
  776. lifetime->sadb_lifetime_addtime = x->lft.hard_add_expires_seconds;
  777. lifetime->sadb_lifetime_usetime = x->lft.hard_use_expires_seconds;
  778. }
  779. /* soft time */
  780. if (hsc & 1) {
  781. lifetime = skb_put(skb, sizeof(struct sadb_lifetime));
  782. lifetime->sadb_lifetime_len =
  783. sizeof(struct sadb_lifetime)/sizeof(uint64_t);
  784. lifetime->sadb_lifetime_exttype = SADB_EXT_LIFETIME_SOFT;
  785. lifetime->sadb_lifetime_allocations = _X2KEY(x->lft.soft_packet_limit);
  786. lifetime->sadb_lifetime_bytes = _X2KEY(x->lft.soft_byte_limit);
  787. lifetime->sadb_lifetime_addtime = x->lft.soft_add_expires_seconds;
  788. lifetime->sadb_lifetime_usetime = x->lft.soft_use_expires_seconds;
  789. }
  790. /* current time */
  791. lifetime = skb_put(skb, sizeof(struct sadb_lifetime));
  792. lifetime->sadb_lifetime_len =
  793. sizeof(struct sadb_lifetime)/sizeof(uint64_t);
  794. lifetime->sadb_lifetime_exttype = SADB_EXT_LIFETIME_CURRENT;
  795. lifetime->sadb_lifetime_allocations = x->curlft.packets;
  796. lifetime->sadb_lifetime_bytes = x->curlft.bytes;
  797. lifetime->sadb_lifetime_addtime = x->curlft.add_time;
  798. lifetime->sadb_lifetime_usetime = x->curlft.use_time;
  799. /* src address */
  800. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  801. addr->sadb_address_len =
  802. (sizeof(struct sadb_address)+sockaddr_size)/
  803. sizeof(uint64_t);
  804. addr->sadb_address_exttype = SADB_EXT_ADDRESS_SRC;
  805. /* "if the ports are non-zero, then the sadb_address_proto field,
  806. normally zero, MUST be filled in with the transport
  807. protocol's number." - RFC2367 */
  808. addr->sadb_address_proto = 0;
  809. addr->sadb_address_reserved = 0;
  810. addr->sadb_address_prefixlen =
  811. pfkey_sockaddr_fill(&x->props.saddr, 0,
  812. (struct sockaddr *) (addr + 1),
  813. x->props.family);
  814. BUG_ON(!addr->sadb_address_prefixlen);
  815. /* dst address */
  816. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  817. addr->sadb_address_len =
  818. (sizeof(struct sadb_address)+sockaddr_size)/
  819. sizeof(uint64_t);
  820. addr->sadb_address_exttype = SADB_EXT_ADDRESS_DST;
  821. addr->sadb_address_proto = 0;
  822. addr->sadb_address_reserved = 0;
  823. addr->sadb_address_prefixlen =
  824. pfkey_sockaddr_fill(&x->id.daddr, 0,
  825. (struct sockaddr *) (addr + 1),
  826. x->props.family);
  827. BUG_ON(!addr->sadb_address_prefixlen);
  828. if (!xfrm_addr_equal(&x->sel.saddr, &x->props.saddr,
  829. x->props.family)) {
  830. addr = skb_put(skb,
  831. sizeof(struct sadb_address) + sockaddr_size);
  832. addr->sadb_address_len =
  833. (sizeof(struct sadb_address)+sockaddr_size)/
  834. sizeof(uint64_t);
  835. addr->sadb_address_exttype = SADB_EXT_ADDRESS_PROXY;
  836. addr->sadb_address_proto =
  837. pfkey_proto_from_xfrm(x->sel.proto);
  838. addr->sadb_address_prefixlen = x->sel.prefixlen_s;
  839. addr->sadb_address_reserved = 0;
  840. pfkey_sockaddr_fill(&x->sel.saddr, x->sel.sport,
  841. (struct sockaddr *) (addr + 1),
  842. x->props.family);
  843. }
  844. /* auth key */
  845. if (add_keys && auth_key_size) {
  846. key = skb_put(skb, sizeof(struct sadb_key) + auth_key_size);
  847. key->sadb_key_len = (sizeof(struct sadb_key) + auth_key_size) /
  848. sizeof(uint64_t);
  849. key->sadb_key_exttype = SADB_EXT_KEY_AUTH;
  850. key->sadb_key_bits = x->aalg->alg_key_len;
  851. key->sadb_key_reserved = 0;
  852. memcpy(key + 1, x->aalg->alg_key, (x->aalg->alg_key_len+7)/8);
  853. }
  854. /* encrypt key */
  855. if (add_keys && encrypt_key_size) {
  856. key = skb_put(skb, sizeof(struct sadb_key) + encrypt_key_size);
  857. key->sadb_key_len = (sizeof(struct sadb_key) +
  858. encrypt_key_size) / sizeof(uint64_t);
  859. key->sadb_key_exttype = SADB_EXT_KEY_ENCRYPT;
  860. key->sadb_key_bits = x->ealg->alg_key_len;
  861. key->sadb_key_reserved = 0;
  862. memcpy(key + 1, x->ealg->alg_key,
  863. (x->ealg->alg_key_len+7)/8);
  864. }
  865. /* sa */
  866. sa2 = skb_put(skb, sizeof(struct sadb_x_sa2));
  867. sa2->sadb_x_sa2_len = sizeof(struct sadb_x_sa2)/sizeof(uint64_t);
  868. sa2->sadb_x_sa2_exttype = SADB_X_EXT_SA2;
  869. if ((mode = pfkey_mode_from_xfrm(x->props.mode)) < 0) {
  870. kfree_skb(skb);
  871. return ERR_PTR(-EINVAL);
  872. }
  873. sa2->sadb_x_sa2_mode = mode;
  874. sa2->sadb_x_sa2_reserved1 = 0;
  875. sa2->sadb_x_sa2_reserved2 = 0;
  876. sa2->sadb_x_sa2_sequence = 0;
  877. sa2->sadb_x_sa2_reqid = x->props.reqid;
  878. if (natt && natt->encap_type) {
  879. struct sadb_x_nat_t_type *n_type;
  880. struct sadb_x_nat_t_port *n_port;
  881. /* type */
  882. n_type = skb_put(skb, sizeof(*n_type));
  883. n_type->sadb_x_nat_t_type_len = sizeof(*n_type)/sizeof(uint64_t);
  884. n_type->sadb_x_nat_t_type_exttype = SADB_X_EXT_NAT_T_TYPE;
  885. n_type->sadb_x_nat_t_type_type = natt->encap_type;
  886. n_type->sadb_x_nat_t_type_reserved[0] = 0;
  887. n_type->sadb_x_nat_t_type_reserved[1] = 0;
  888. n_type->sadb_x_nat_t_type_reserved[2] = 0;
  889. /* source port */
  890. n_port = skb_put(skb, sizeof(*n_port));
  891. n_port->sadb_x_nat_t_port_len = sizeof(*n_port)/sizeof(uint64_t);
  892. n_port->sadb_x_nat_t_port_exttype = SADB_X_EXT_NAT_T_SPORT;
  893. n_port->sadb_x_nat_t_port_port = natt->encap_sport;
  894. n_port->sadb_x_nat_t_port_reserved = 0;
  895. /* dest port */
  896. n_port = skb_put(skb, sizeof(*n_port));
  897. n_port->sadb_x_nat_t_port_len = sizeof(*n_port)/sizeof(uint64_t);
  898. n_port->sadb_x_nat_t_port_exttype = SADB_X_EXT_NAT_T_DPORT;
  899. n_port->sadb_x_nat_t_port_port = natt->encap_dport;
  900. n_port->sadb_x_nat_t_port_reserved = 0;
  901. }
  902. /* security context */
  903. if (xfrm_ctx) {
  904. sec_ctx = skb_put(skb,
  905. sizeof(struct sadb_x_sec_ctx) + ctx_size);
  906. sec_ctx->sadb_x_sec_len =
  907. (sizeof(struct sadb_x_sec_ctx) + ctx_size) / sizeof(uint64_t);
  908. sec_ctx->sadb_x_sec_exttype = SADB_X_EXT_SEC_CTX;
  909. sec_ctx->sadb_x_ctx_doi = xfrm_ctx->ctx_doi;
  910. sec_ctx->sadb_x_ctx_alg = xfrm_ctx->ctx_alg;
  911. sec_ctx->sadb_x_ctx_len = xfrm_ctx->ctx_len;
  912. memcpy(sec_ctx + 1, xfrm_ctx->ctx_str,
  913. xfrm_ctx->ctx_len);
  914. }
  915. return skb;
  916. }
  917. static inline struct sk_buff *pfkey_xfrm_state2msg(const struct xfrm_state *x)
  918. {
  919. struct sk_buff *skb;
  920. skb = __pfkey_xfrm_state2msg(x, 1, 3);
  921. return skb;
  922. }
  923. static inline struct sk_buff *pfkey_xfrm_state2msg_expire(const struct xfrm_state *x,
  924. int hsc)
  925. {
  926. return __pfkey_xfrm_state2msg(x, 0, hsc);
  927. }
  928. static struct xfrm_state * pfkey_msg2xfrm_state(struct net *net,
  929. const struct sadb_msg *hdr,
  930. void * const *ext_hdrs)
  931. {
  932. struct xfrm_state *x;
  933. const struct sadb_lifetime *lifetime;
  934. const struct sadb_sa *sa;
  935. const struct sadb_key *key;
  936. const struct sadb_x_sec_ctx *sec_ctx;
  937. uint16_t proto;
  938. int err;
  939. sa = ext_hdrs[SADB_EXT_SA - 1];
  940. if (!sa ||
  941. !present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  942. ext_hdrs[SADB_EXT_ADDRESS_DST-1]))
  943. return ERR_PTR(-EINVAL);
  944. if (hdr->sadb_msg_satype == SADB_SATYPE_ESP &&
  945. !ext_hdrs[SADB_EXT_KEY_ENCRYPT-1])
  946. return ERR_PTR(-EINVAL);
  947. if (hdr->sadb_msg_satype == SADB_SATYPE_AH &&
  948. !ext_hdrs[SADB_EXT_KEY_AUTH-1])
  949. return ERR_PTR(-EINVAL);
  950. if (!!ext_hdrs[SADB_EXT_LIFETIME_HARD-1] !=
  951. !!ext_hdrs[SADB_EXT_LIFETIME_SOFT-1])
  952. return ERR_PTR(-EINVAL);
  953. proto = pfkey_satype2proto(hdr->sadb_msg_satype);
  954. if (proto == 0)
  955. return ERR_PTR(-EINVAL);
  956. /* default error is no buffer space */
  957. err = -ENOBUFS;
  958. /* RFC2367:
  959. Only SADB_SASTATE_MATURE SAs may be submitted in an SADB_ADD message.
  960. SADB_SASTATE_LARVAL SAs are created by SADB_GETSPI and it is not
  961. sensible to add a new SA in the DYING or SADB_SASTATE_DEAD state.
  962. Therefore, the sadb_sa_state field of all submitted SAs MUST be
  963. SADB_SASTATE_MATURE and the kernel MUST return an error if this is
  964. not true.
  965. However, KAME setkey always uses SADB_SASTATE_LARVAL.
  966. Hence, we have to _ignore_ sadb_sa_state, which is also reasonable.
  967. */
  968. if (sa->sadb_sa_auth > SADB_AALG_MAX ||
  969. (hdr->sadb_msg_satype == SADB_X_SATYPE_IPCOMP &&
  970. sa->sadb_sa_encrypt > SADB_X_CALG_MAX) ||
  971. sa->sadb_sa_encrypt > SADB_EALG_MAX)
  972. return ERR_PTR(-EINVAL);
  973. key = ext_hdrs[SADB_EXT_KEY_AUTH - 1];
  974. if (key != NULL &&
  975. sa->sadb_sa_auth != SADB_X_AALG_NULL &&
  976. key->sadb_key_bits == 0)
  977. return ERR_PTR(-EINVAL);
  978. key = ext_hdrs[SADB_EXT_KEY_ENCRYPT-1];
  979. if (key != NULL &&
  980. sa->sadb_sa_encrypt != SADB_EALG_NULL &&
  981. key->sadb_key_bits == 0)
  982. return ERR_PTR(-EINVAL);
  983. x = xfrm_state_alloc(net);
  984. if (x == NULL)
  985. return ERR_PTR(-ENOBUFS);
  986. x->id.proto = proto;
  987. x->id.spi = sa->sadb_sa_spi;
  988. x->props.replay_window = min_t(unsigned int, sa->sadb_sa_replay,
  989. (sizeof(x->replay.bitmap) * 8));
  990. if (sa->sadb_sa_flags & SADB_SAFLAGS_NOECN)
  991. x->props.flags |= XFRM_STATE_NOECN;
  992. if (sa->sadb_sa_flags & SADB_SAFLAGS_DECAP_DSCP)
  993. x->props.flags |= XFRM_STATE_DECAP_DSCP;
  994. if (sa->sadb_sa_flags & SADB_SAFLAGS_NOPMTUDISC)
  995. x->props.flags |= XFRM_STATE_NOPMTUDISC;
  996. lifetime = ext_hdrs[SADB_EXT_LIFETIME_HARD - 1];
  997. if (lifetime != NULL) {
  998. x->lft.hard_packet_limit = _KEY2X(lifetime->sadb_lifetime_allocations);
  999. x->lft.hard_byte_limit = _KEY2X(lifetime->sadb_lifetime_bytes);
  1000. x->lft.hard_add_expires_seconds = lifetime->sadb_lifetime_addtime;
  1001. x->lft.hard_use_expires_seconds = lifetime->sadb_lifetime_usetime;
  1002. }
  1003. lifetime = ext_hdrs[SADB_EXT_LIFETIME_SOFT - 1];
  1004. if (lifetime != NULL) {
  1005. x->lft.soft_packet_limit = _KEY2X(lifetime->sadb_lifetime_allocations);
  1006. x->lft.soft_byte_limit = _KEY2X(lifetime->sadb_lifetime_bytes);
  1007. x->lft.soft_add_expires_seconds = lifetime->sadb_lifetime_addtime;
  1008. x->lft.soft_use_expires_seconds = lifetime->sadb_lifetime_usetime;
  1009. }
  1010. sec_ctx = ext_hdrs[SADB_X_EXT_SEC_CTX - 1];
  1011. if (sec_ctx != NULL) {
  1012. struct xfrm_user_sec_ctx *uctx = pfkey_sadb2xfrm_user_sec_ctx(sec_ctx, GFP_KERNEL);
  1013. if (!uctx)
  1014. goto out;
  1015. err = security_xfrm_state_alloc(x, uctx);
  1016. kfree(uctx);
  1017. if (err)
  1018. goto out;
  1019. }
  1020. err = -ENOBUFS;
  1021. key = ext_hdrs[SADB_EXT_KEY_AUTH - 1];
  1022. if (sa->sadb_sa_auth) {
  1023. int keysize = 0;
  1024. struct xfrm_algo_desc *a = xfrm_aalg_get_byid(sa->sadb_sa_auth);
  1025. if (!a || !a->pfkey_supported) {
  1026. err = -ENOSYS;
  1027. goto out;
  1028. }
  1029. if (key)
  1030. keysize = (key->sadb_key_bits + 7) / 8;
  1031. x->aalg = kmalloc(sizeof(*x->aalg) + keysize, GFP_KERNEL);
  1032. if (!x->aalg) {
  1033. err = -ENOMEM;
  1034. goto out;
  1035. }
  1036. strcpy(x->aalg->alg_name, a->name);
  1037. x->aalg->alg_key_len = 0;
  1038. if (key) {
  1039. x->aalg->alg_key_len = key->sadb_key_bits;
  1040. memcpy(x->aalg->alg_key, key+1, keysize);
  1041. }
  1042. x->aalg->alg_trunc_len = a->uinfo.auth.icv_truncbits;
  1043. x->props.aalgo = sa->sadb_sa_auth;
  1044. /* x->algo.flags = sa->sadb_sa_flags; */
  1045. }
  1046. if (sa->sadb_sa_encrypt) {
  1047. if (hdr->sadb_msg_satype == SADB_X_SATYPE_IPCOMP) {
  1048. struct xfrm_algo_desc *a = xfrm_calg_get_byid(sa->sadb_sa_encrypt);
  1049. if (!a || !a->pfkey_supported) {
  1050. err = -ENOSYS;
  1051. goto out;
  1052. }
  1053. x->calg = kmalloc_obj(*x->calg);
  1054. if (!x->calg) {
  1055. err = -ENOMEM;
  1056. goto out;
  1057. }
  1058. strcpy(x->calg->alg_name, a->name);
  1059. x->props.calgo = sa->sadb_sa_encrypt;
  1060. } else {
  1061. int keysize = 0;
  1062. struct xfrm_algo_desc *a = xfrm_ealg_get_byid(sa->sadb_sa_encrypt);
  1063. if (!a || !a->pfkey_supported) {
  1064. err = -ENOSYS;
  1065. goto out;
  1066. }
  1067. key = (struct sadb_key*) ext_hdrs[SADB_EXT_KEY_ENCRYPT-1];
  1068. if (key)
  1069. keysize = (key->sadb_key_bits + 7) / 8;
  1070. x->ealg = kmalloc(sizeof(*x->ealg) + keysize, GFP_KERNEL);
  1071. if (!x->ealg) {
  1072. err = -ENOMEM;
  1073. goto out;
  1074. }
  1075. strcpy(x->ealg->alg_name, a->name);
  1076. x->ealg->alg_key_len = 0;
  1077. if (key) {
  1078. x->ealg->alg_key_len = key->sadb_key_bits;
  1079. memcpy(x->ealg->alg_key, key+1, keysize);
  1080. }
  1081. x->props.ealgo = sa->sadb_sa_encrypt;
  1082. x->geniv = a->uinfo.encr.geniv;
  1083. }
  1084. }
  1085. /* x->algo.flags = sa->sadb_sa_flags; */
  1086. x->props.family = pfkey_sadb_addr2xfrm_addr((struct sadb_address *) ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  1087. &x->props.saddr);
  1088. pfkey_sadb_addr2xfrm_addr((struct sadb_address *) ext_hdrs[SADB_EXT_ADDRESS_DST-1],
  1089. &x->id.daddr);
  1090. if (ext_hdrs[SADB_X_EXT_SA2-1]) {
  1091. const struct sadb_x_sa2 *sa2 = ext_hdrs[SADB_X_EXT_SA2-1];
  1092. int mode = pfkey_mode_to_xfrm(sa2->sadb_x_sa2_mode);
  1093. if (mode < 0) {
  1094. err = -EINVAL;
  1095. goto out;
  1096. }
  1097. x->props.mode = mode;
  1098. x->props.reqid = sa2->sadb_x_sa2_reqid;
  1099. }
  1100. if (ext_hdrs[SADB_EXT_ADDRESS_PROXY-1]) {
  1101. const struct sadb_address *addr = ext_hdrs[SADB_EXT_ADDRESS_PROXY-1];
  1102. /* Nobody uses this, but we try. */
  1103. x->sel.family = pfkey_sadb_addr2xfrm_addr(addr, &x->sel.saddr);
  1104. x->sel.prefixlen_s = addr->sadb_address_prefixlen;
  1105. }
  1106. if (!x->sel.family)
  1107. x->sel.family = x->props.family;
  1108. if (ext_hdrs[SADB_X_EXT_NAT_T_TYPE-1]) {
  1109. const struct sadb_x_nat_t_type* n_type;
  1110. struct xfrm_encap_tmpl *natt;
  1111. x->encap = kzalloc_obj(*x->encap);
  1112. if (!x->encap) {
  1113. err = -ENOMEM;
  1114. goto out;
  1115. }
  1116. natt = x->encap;
  1117. n_type = ext_hdrs[SADB_X_EXT_NAT_T_TYPE-1];
  1118. natt->encap_type = n_type->sadb_x_nat_t_type_type;
  1119. if (ext_hdrs[SADB_X_EXT_NAT_T_SPORT-1]) {
  1120. const struct sadb_x_nat_t_port *n_port =
  1121. ext_hdrs[SADB_X_EXT_NAT_T_SPORT-1];
  1122. natt->encap_sport = n_port->sadb_x_nat_t_port_port;
  1123. }
  1124. if (ext_hdrs[SADB_X_EXT_NAT_T_DPORT-1]) {
  1125. const struct sadb_x_nat_t_port *n_port =
  1126. ext_hdrs[SADB_X_EXT_NAT_T_DPORT-1];
  1127. natt->encap_dport = n_port->sadb_x_nat_t_port_port;
  1128. }
  1129. }
  1130. err = xfrm_init_state(x);
  1131. if (err)
  1132. goto out;
  1133. x->km.seq = hdr->sadb_msg_seq;
  1134. return x;
  1135. out:
  1136. x->km.state = XFRM_STATE_DEAD;
  1137. xfrm_state_put(x);
  1138. return ERR_PTR(err);
  1139. }
  1140. static int pfkey_reserved(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1141. {
  1142. return -EOPNOTSUPP;
  1143. }
  1144. static int pfkey_getspi(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1145. {
  1146. struct net *net = sock_net(sk);
  1147. struct sk_buff *resp_skb;
  1148. struct sadb_x_sa2 *sa2;
  1149. struct sadb_address *saddr, *daddr;
  1150. struct sadb_msg *out_hdr;
  1151. struct sadb_spirange *range;
  1152. struct xfrm_state *x = NULL;
  1153. int mode;
  1154. int err;
  1155. u32 min_spi, max_spi;
  1156. u32 reqid;
  1157. u8 proto;
  1158. unsigned short family;
  1159. xfrm_address_t *xsaddr = NULL, *xdaddr = NULL;
  1160. if (!present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  1161. ext_hdrs[SADB_EXT_ADDRESS_DST-1]))
  1162. return -EINVAL;
  1163. proto = pfkey_satype2proto(hdr->sadb_msg_satype);
  1164. if (proto == 0)
  1165. return -EINVAL;
  1166. if ((sa2 = ext_hdrs[SADB_X_EXT_SA2-1]) != NULL) {
  1167. mode = pfkey_mode_to_xfrm(sa2->sadb_x_sa2_mode);
  1168. if (mode < 0)
  1169. return -EINVAL;
  1170. reqid = sa2->sadb_x_sa2_reqid;
  1171. } else {
  1172. mode = 0;
  1173. reqid = 0;
  1174. }
  1175. saddr = ext_hdrs[SADB_EXT_ADDRESS_SRC-1];
  1176. daddr = ext_hdrs[SADB_EXT_ADDRESS_DST-1];
  1177. family = ((struct sockaddr *)(saddr + 1))->sa_family;
  1178. switch (family) {
  1179. case AF_INET:
  1180. xdaddr = (xfrm_address_t *)&((struct sockaddr_in *)(daddr + 1))->sin_addr.s_addr;
  1181. xsaddr = (xfrm_address_t *)&((struct sockaddr_in *)(saddr + 1))->sin_addr.s_addr;
  1182. break;
  1183. #if IS_ENABLED(CONFIG_IPV6)
  1184. case AF_INET6:
  1185. xdaddr = (xfrm_address_t *)&((struct sockaddr_in6 *)(daddr + 1))->sin6_addr;
  1186. xsaddr = (xfrm_address_t *)&((struct sockaddr_in6 *)(saddr + 1))->sin6_addr;
  1187. break;
  1188. #endif
  1189. }
  1190. if (hdr->sadb_msg_seq) {
  1191. x = xfrm_find_acq_byseq(net, DUMMY_MARK, hdr->sadb_msg_seq, UINT_MAX);
  1192. if (x && !xfrm_addr_equal(&x->id.daddr, xdaddr, family)) {
  1193. xfrm_state_put(x);
  1194. x = NULL;
  1195. }
  1196. }
  1197. if (!x)
  1198. x = xfrm_find_acq(net, &dummy_mark, mode, reqid, 0, UINT_MAX,
  1199. proto, xdaddr, xsaddr, 1, family);
  1200. if (x == NULL)
  1201. return -ENOENT;
  1202. min_spi = 0x100;
  1203. max_spi = 0x0fffffff;
  1204. range = ext_hdrs[SADB_EXT_SPIRANGE-1];
  1205. if (range) {
  1206. min_spi = range->sadb_spirange_min;
  1207. max_spi = range->sadb_spirange_max;
  1208. }
  1209. err = verify_spi_info(x->id.proto, min_spi, max_spi, NULL);
  1210. if (err) {
  1211. xfrm_state_put(x);
  1212. return err;
  1213. }
  1214. err = xfrm_alloc_spi(x, min_spi, max_spi, NULL);
  1215. resp_skb = err ? ERR_PTR(err) : pfkey_xfrm_state2msg(x);
  1216. if (IS_ERR(resp_skb)) {
  1217. xfrm_state_put(x);
  1218. return PTR_ERR(resp_skb);
  1219. }
  1220. out_hdr = (struct sadb_msg *) resp_skb->data;
  1221. out_hdr->sadb_msg_version = hdr->sadb_msg_version;
  1222. out_hdr->sadb_msg_type = SADB_GETSPI;
  1223. out_hdr->sadb_msg_satype = pfkey_proto2satype(proto);
  1224. out_hdr->sadb_msg_errno = 0;
  1225. out_hdr->sadb_msg_reserved = 0;
  1226. out_hdr->sadb_msg_seq = hdr->sadb_msg_seq;
  1227. out_hdr->sadb_msg_pid = hdr->sadb_msg_pid;
  1228. xfrm_state_put(x);
  1229. pfkey_broadcast(resp_skb, GFP_KERNEL, BROADCAST_ONE, sk, net);
  1230. return 0;
  1231. }
  1232. static int pfkey_acquire(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1233. {
  1234. struct net *net = sock_net(sk);
  1235. struct xfrm_state *x;
  1236. if (hdr->sadb_msg_len != sizeof(struct sadb_msg)/8)
  1237. return -EOPNOTSUPP;
  1238. if (hdr->sadb_msg_seq == 0 || hdr->sadb_msg_errno == 0)
  1239. return 0;
  1240. x = xfrm_find_acq_byseq(net, DUMMY_MARK, hdr->sadb_msg_seq, UINT_MAX);
  1241. if (x == NULL)
  1242. return 0;
  1243. spin_lock_bh(&x->lock);
  1244. if (x->km.state == XFRM_STATE_ACQ)
  1245. x->km.state = XFRM_STATE_ERROR;
  1246. spin_unlock_bh(&x->lock);
  1247. xfrm_state_put(x);
  1248. return 0;
  1249. }
  1250. static inline int event2poltype(int event)
  1251. {
  1252. switch (event) {
  1253. case XFRM_MSG_DELPOLICY:
  1254. return SADB_X_SPDDELETE;
  1255. case XFRM_MSG_NEWPOLICY:
  1256. return SADB_X_SPDADD;
  1257. case XFRM_MSG_UPDPOLICY:
  1258. return SADB_X_SPDUPDATE;
  1259. case XFRM_MSG_POLEXPIRE:
  1260. // return SADB_X_SPDEXPIRE;
  1261. default:
  1262. pr_err("pfkey: Unknown policy event %d\n", event);
  1263. break;
  1264. }
  1265. return 0;
  1266. }
  1267. static inline int event2keytype(int event)
  1268. {
  1269. switch (event) {
  1270. case XFRM_MSG_DELSA:
  1271. return SADB_DELETE;
  1272. case XFRM_MSG_NEWSA:
  1273. return SADB_ADD;
  1274. case XFRM_MSG_UPDSA:
  1275. return SADB_UPDATE;
  1276. case XFRM_MSG_EXPIRE:
  1277. return SADB_EXPIRE;
  1278. default:
  1279. pr_err("pfkey: Unknown SA event %d\n", event);
  1280. break;
  1281. }
  1282. return 0;
  1283. }
  1284. /* ADD/UPD/DEL */
  1285. static int key_notify_sa(struct xfrm_state *x, const struct km_event *c)
  1286. {
  1287. struct sk_buff *skb;
  1288. struct sadb_msg *hdr;
  1289. skb = pfkey_xfrm_state2msg(x);
  1290. if (IS_ERR(skb))
  1291. return PTR_ERR(skb);
  1292. hdr = (struct sadb_msg *) skb->data;
  1293. hdr->sadb_msg_version = PF_KEY_V2;
  1294. hdr->sadb_msg_type = event2keytype(c->event);
  1295. hdr->sadb_msg_satype = pfkey_proto2satype(x->id.proto);
  1296. hdr->sadb_msg_errno = 0;
  1297. hdr->sadb_msg_reserved = 0;
  1298. hdr->sadb_msg_seq = c->seq;
  1299. hdr->sadb_msg_pid = c->portid;
  1300. pfkey_broadcast(skb, GFP_ATOMIC, BROADCAST_ALL, NULL, xs_net(x));
  1301. return 0;
  1302. }
  1303. static int pfkey_add(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1304. {
  1305. struct net *net = sock_net(sk);
  1306. struct xfrm_state *x;
  1307. int err;
  1308. struct km_event c;
  1309. x = pfkey_msg2xfrm_state(net, hdr, ext_hdrs);
  1310. if (IS_ERR(x))
  1311. return PTR_ERR(x);
  1312. xfrm_state_hold(x);
  1313. if (hdr->sadb_msg_type == SADB_ADD)
  1314. err = xfrm_state_add(x);
  1315. else
  1316. err = xfrm_state_update(x);
  1317. xfrm_audit_state_add(x, err ? 0 : 1, true);
  1318. if (err < 0) {
  1319. x->km.state = XFRM_STATE_DEAD;
  1320. __xfrm_state_put(x);
  1321. goto out;
  1322. }
  1323. if (hdr->sadb_msg_type == SADB_ADD)
  1324. c.event = XFRM_MSG_NEWSA;
  1325. else
  1326. c.event = XFRM_MSG_UPDSA;
  1327. c.seq = hdr->sadb_msg_seq;
  1328. c.portid = hdr->sadb_msg_pid;
  1329. km_state_notify(x, &c);
  1330. out:
  1331. xfrm_state_put(x);
  1332. return err;
  1333. }
  1334. static int pfkey_delete(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1335. {
  1336. struct net *net = sock_net(sk);
  1337. struct xfrm_state *x;
  1338. struct km_event c;
  1339. int err;
  1340. if (!ext_hdrs[SADB_EXT_SA-1] ||
  1341. !present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  1342. ext_hdrs[SADB_EXT_ADDRESS_DST-1]))
  1343. return -EINVAL;
  1344. x = pfkey_xfrm_state_lookup(net, hdr, ext_hdrs);
  1345. if (x == NULL)
  1346. return -ESRCH;
  1347. if ((err = security_xfrm_state_delete(x)))
  1348. goto out;
  1349. if (xfrm_state_kern(x)) {
  1350. err = -EPERM;
  1351. goto out;
  1352. }
  1353. err = xfrm_state_delete(x);
  1354. if (err < 0)
  1355. goto out;
  1356. c.seq = hdr->sadb_msg_seq;
  1357. c.portid = hdr->sadb_msg_pid;
  1358. c.event = XFRM_MSG_DELSA;
  1359. km_state_notify(x, &c);
  1360. out:
  1361. xfrm_audit_state_delete(x, err ? 0 : 1, true);
  1362. xfrm_state_put(x);
  1363. return err;
  1364. }
  1365. static int pfkey_get(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1366. {
  1367. struct net *net = sock_net(sk);
  1368. __u8 proto;
  1369. struct sk_buff *out_skb;
  1370. struct sadb_msg *out_hdr;
  1371. struct xfrm_state *x;
  1372. if (!ext_hdrs[SADB_EXT_SA-1] ||
  1373. !present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  1374. ext_hdrs[SADB_EXT_ADDRESS_DST-1]))
  1375. return -EINVAL;
  1376. x = pfkey_xfrm_state_lookup(net, hdr, ext_hdrs);
  1377. if (x == NULL)
  1378. return -ESRCH;
  1379. out_skb = pfkey_xfrm_state2msg(x);
  1380. proto = x->id.proto;
  1381. xfrm_state_put(x);
  1382. if (IS_ERR(out_skb))
  1383. return PTR_ERR(out_skb);
  1384. out_hdr = (struct sadb_msg *) out_skb->data;
  1385. out_hdr->sadb_msg_version = hdr->sadb_msg_version;
  1386. out_hdr->sadb_msg_type = SADB_GET;
  1387. out_hdr->sadb_msg_satype = pfkey_proto2satype(proto);
  1388. out_hdr->sadb_msg_errno = 0;
  1389. out_hdr->sadb_msg_reserved = 0;
  1390. out_hdr->sadb_msg_seq = hdr->sadb_msg_seq;
  1391. out_hdr->sadb_msg_pid = hdr->sadb_msg_pid;
  1392. pfkey_broadcast(out_skb, GFP_ATOMIC, BROADCAST_ONE, sk, sock_net(sk));
  1393. return 0;
  1394. }
  1395. static struct sk_buff *compose_sadb_supported(const struct sadb_msg *orig,
  1396. gfp_t allocation)
  1397. {
  1398. struct sk_buff *skb;
  1399. struct sadb_msg *hdr;
  1400. int len, auth_len, enc_len, i;
  1401. auth_len = xfrm_count_pfkey_auth_supported();
  1402. if (auth_len) {
  1403. auth_len *= sizeof(struct sadb_alg);
  1404. auth_len += sizeof(struct sadb_supported);
  1405. }
  1406. enc_len = xfrm_count_pfkey_enc_supported();
  1407. if (enc_len) {
  1408. enc_len *= sizeof(struct sadb_alg);
  1409. enc_len += sizeof(struct sadb_supported);
  1410. }
  1411. len = enc_len + auth_len + sizeof(struct sadb_msg);
  1412. skb = alloc_skb(len + 16, allocation);
  1413. if (!skb)
  1414. goto out_put_algs;
  1415. hdr = skb_put(skb, sizeof(*hdr));
  1416. pfkey_hdr_dup(hdr, orig);
  1417. hdr->sadb_msg_errno = 0;
  1418. hdr->sadb_msg_len = len / sizeof(uint64_t);
  1419. if (auth_len) {
  1420. struct sadb_supported *sp;
  1421. struct sadb_alg *ap;
  1422. sp = skb_put(skb, auth_len);
  1423. ap = (struct sadb_alg *) (sp + 1);
  1424. sp->sadb_supported_len = auth_len / sizeof(uint64_t);
  1425. sp->sadb_supported_exttype = SADB_EXT_SUPPORTED_AUTH;
  1426. for (i = 0; ; i++) {
  1427. struct xfrm_algo_desc *aalg = xfrm_aalg_get_byidx(i);
  1428. if (!aalg)
  1429. break;
  1430. if (!aalg->pfkey_supported)
  1431. continue;
  1432. if (aalg->available)
  1433. *ap++ = aalg->desc;
  1434. }
  1435. }
  1436. if (enc_len) {
  1437. struct sadb_supported *sp;
  1438. struct sadb_alg *ap;
  1439. sp = skb_put(skb, enc_len);
  1440. ap = (struct sadb_alg *) (sp + 1);
  1441. sp->sadb_supported_len = enc_len / sizeof(uint64_t);
  1442. sp->sadb_supported_exttype = SADB_EXT_SUPPORTED_ENCRYPT;
  1443. for (i = 0; ; i++) {
  1444. struct xfrm_algo_desc *ealg = xfrm_ealg_get_byidx(i);
  1445. if (!ealg)
  1446. break;
  1447. if (!ealg->pfkey_supported)
  1448. continue;
  1449. if (ealg->available)
  1450. *ap++ = ealg->desc;
  1451. }
  1452. }
  1453. out_put_algs:
  1454. return skb;
  1455. }
  1456. static int pfkey_register(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1457. {
  1458. struct pfkey_sock *pfk = pfkey_sk(sk);
  1459. struct sk_buff *supp_skb;
  1460. if (hdr->sadb_msg_satype > SADB_SATYPE_MAX)
  1461. return -EINVAL;
  1462. if (hdr->sadb_msg_satype != SADB_SATYPE_UNSPEC) {
  1463. if (pfk->registered&(1<<hdr->sadb_msg_satype))
  1464. return -EEXIST;
  1465. pfk->registered |= (1<<hdr->sadb_msg_satype);
  1466. }
  1467. mutex_lock(&pfkey_mutex);
  1468. xfrm_probe_algs();
  1469. supp_skb = compose_sadb_supported(hdr, GFP_KERNEL | __GFP_ZERO);
  1470. mutex_unlock(&pfkey_mutex);
  1471. if (!supp_skb) {
  1472. if (hdr->sadb_msg_satype != SADB_SATYPE_UNSPEC)
  1473. pfk->registered &= ~(1<<hdr->sadb_msg_satype);
  1474. return -ENOBUFS;
  1475. }
  1476. pfkey_broadcast(supp_skb, GFP_KERNEL, BROADCAST_REGISTERED, sk,
  1477. sock_net(sk));
  1478. return 0;
  1479. }
  1480. static int unicast_flush_resp(struct sock *sk, const struct sadb_msg *ihdr)
  1481. {
  1482. struct sk_buff *skb;
  1483. struct sadb_msg *hdr;
  1484. skb = alloc_skb(sizeof(struct sadb_msg) + 16, GFP_ATOMIC);
  1485. if (!skb)
  1486. return -ENOBUFS;
  1487. hdr = skb_put_data(skb, ihdr, sizeof(struct sadb_msg));
  1488. hdr->sadb_msg_errno = (uint8_t) 0;
  1489. hdr->sadb_msg_len = (sizeof(struct sadb_msg) / sizeof(uint64_t));
  1490. return pfkey_broadcast(skb, GFP_ATOMIC, BROADCAST_ONE, sk,
  1491. sock_net(sk));
  1492. }
  1493. static int key_notify_sa_flush(const struct km_event *c)
  1494. {
  1495. struct sk_buff *skb;
  1496. struct sadb_msg *hdr;
  1497. skb = alloc_skb(sizeof(struct sadb_msg) + 16, GFP_ATOMIC);
  1498. if (!skb)
  1499. return -ENOBUFS;
  1500. hdr = skb_put(skb, sizeof(struct sadb_msg));
  1501. hdr->sadb_msg_satype = pfkey_proto2satype(c->data.proto);
  1502. hdr->sadb_msg_type = SADB_FLUSH;
  1503. hdr->sadb_msg_seq = c->seq;
  1504. hdr->sadb_msg_pid = c->portid;
  1505. hdr->sadb_msg_version = PF_KEY_V2;
  1506. hdr->sadb_msg_errno = (uint8_t) 0;
  1507. hdr->sadb_msg_len = (sizeof(struct sadb_msg) / sizeof(uint64_t));
  1508. hdr->sadb_msg_reserved = 0;
  1509. pfkey_broadcast(skb, GFP_ATOMIC, BROADCAST_ALL, NULL, c->net);
  1510. return 0;
  1511. }
  1512. static int pfkey_flush(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1513. {
  1514. struct net *net = sock_net(sk);
  1515. unsigned int proto;
  1516. struct km_event c;
  1517. int err, err2;
  1518. proto = pfkey_satype2proto(hdr->sadb_msg_satype);
  1519. if (proto == 0)
  1520. return -EINVAL;
  1521. err = xfrm_state_flush(net, proto, true);
  1522. err2 = unicast_flush_resp(sk, hdr);
  1523. if (err || err2) {
  1524. if (err == -ESRCH) /* empty table - go quietly */
  1525. err = 0;
  1526. return err ? err : err2;
  1527. }
  1528. c.data.proto = proto;
  1529. c.seq = hdr->sadb_msg_seq;
  1530. c.portid = hdr->sadb_msg_pid;
  1531. c.event = XFRM_MSG_FLUSHSA;
  1532. c.net = net;
  1533. km_state_notify(NULL, &c);
  1534. return 0;
  1535. }
  1536. static int dump_sa(struct xfrm_state *x, int count, void *ptr)
  1537. {
  1538. struct pfkey_sock *pfk = ptr;
  1539. struct sk_buff *out_skb;
  1540. struct sadb_msg *out_hdr;
  1541. if (!pfkey_can_dump(&pfk->sk))
  1542. return -ENOBUFS;
  1543. out_skb = pfkey_xfrm_state2msg(x);
  1544. if (IS_ERR(out_skb))
  1545. return PTR_ERR(out_skb);
  1546. out_hdr = (struct sadb_msg *) out_skb->data;
  1547. out_hdr->sadb_msg_version = pfk->dump.msg_version;
  1548. out_hdr->sadb_msg_type = SADB_DUMP;
  1549. out_hdr->sadb_msg_satype = pfkey_proto2satype(x->id.proto);
  1550. out_hdr->sadb_msg_errno = 0;
  1551. out_hdr->sadb_msg_reserved = 0;
  1552. out_hdr->sadb_msg_seq = count + 1;
  1553. out_hdr->sadb_msg_pid = pfk->dump.msg_portid;
  1554. if (pfk->dump.skb)
  1555. pfkey_broadcast(pfk->dump.skb, GFP_ATOMIC, BROADCAST_ONE,
  1556. &pfk->sk, sock_net(&pfk->sk));
  1557. pfk->dump.skb = out_skb;
  1558. return 0;
  1559. }
  1560. static int pfkey_dump_sa(struct pfkey_sock *pfk)
  1561. {
  1562. struct net *net = sock_net(&pfk->sk);
  1563. return xfrm_state_walk(net, &pfk->dump.u.state, dump_sa, (void *) pfk);
  1564. }
  1565. static void pfkey_dump_sa_done(struct pfkey_sock *pfk)
  1566. {
  1567. struct net *net = sock_net(&pfk->sk);
  1568. xfrm_state_walk_done(&pfk->dump.u.state, net);
  1569. }
  1570. static int pfkey_dump(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1571. {
  1572. u8 proto;
  1573. struct xfrm_address_filter *filter = NULL;
  1574. struct pfkey_sock *pfk = pfkey_sk(sk);
  1575. mutex_lock(&pfk->dump_lock);
  1576. if (pfk->dump.dump != NULL) {
  1577. mutex_unlock(&pfk->dump_lock);
  1578. return -EBUSY;
  1579. }
  1580. proto = pfkey_satype2proto(hdr->sadb_msg_satype);
  1581. if (proto == 0) {
  1582. mutex_unlock(&pfk->dump_lock);
  1583. return -EINVAL;
  1584. }
  1585. if (ext_hdrs[SADB_X_EXT_FILTER - 1]) {
  1586. struct sadb_x_filter *xfilter = ext_hdrs[SADB_X_EXT_FILTER - 1];
  1587. if ((xfilter->sadb_x_filter_splen >
  1588. (sizeof(xfrm_address_t) << 3)) ||
  1589. (xfilter->sadb_x_filter_dplen >
  1590. (sizeof(xfrm_address_t) << 3))) {
  1591. mutex_unlock(&pfk->dump_lock);
  1592. return -EINVAL;
  1593. }
  1594. filter = kmalloc_obj(*filter);
  1595. if (filter == NULL) {
  1596. mutex_unlock(&pfk->dump_lock);
  1597. return -ENOMEM;
  1598. }
  1599. memcpy(&filter->saddr, &xfilter->sadb_x_filter_saddr,
  1600. sizeof(xfrm_address_t));
  1601. memcpy(&filter->daddr, &xfilter->sadb_x_filter_daddr,
  1602. sizeof(xfrm_address_t));
  1603. filter->family = xfilter->sadb_x_filter_family;
  1604. filter->splen = xfilter->sadb_x_filter_splen;
  1605. filter->dplen = xfilter->sadb_x_filter_dplen;
  1606. }
  1607. pfk->dump.msg_version = hdr->sadb_msg_version;
  1608. pfk->dump.msg_portid = hdr->sadb_msg_pid;
  1609. pfk->dump.dump = pfkey_dump_sa;
  1610. pfk->dump.done = pfkey_dump_sa_done;
  1611. xfrm_state_walk_init(&pfk->dump.u.state, proto, filter);
  1612. mutex_unlock(&pfk->dump_lock);
  1613. return pfkey_do_dump(pfk);
  1614. }
  1615. static int pfkey_promisc(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1616. {
  1617. struct pfkey_sock *pfk = pfkey_sk(sk);
  1618. int satype = hdr->sadb_msg_satype;
  1619. bool reset_errno = false;
  1620. if (hdr->sadb_msg_len == (sizeof(*hdr) / sizeof(uint64_t))) {
  1621. reset_errno = true;
  1622. if (satype != 0 && satype != 1)
  1623. return -EINVAL;
  1624. pfk->promisc = satype;
  1625. }
  1626. if (reset_errno && skb_cloned(skb))
  1627. skb = skb_copy(skb, GFP_KERNEL);
  1628. else
  1629. skb = skb_clone(skb, GFP_KERNEL);
  1630. if (reset_errno && skb) {
  1631. struct sadb_msg *new_hdr = (struct sadb_msg *) skb->data;
  1632. new_hdr->sadb_msg_errno = 0;
  1633. }
  1634. pfkey_broadcast(skb, GFP_KERNEL, BROADCAST_ALL, NULL, sock_net(sk));
  1635. return 0;
  1636. }
  1637. static int check_reqid(struct xfrm_policy *xp, int dir, int count, void *ptr)
  1638. {
  1639. int i;
  1640. u32 reqid = *(u32*)ptr;
  1641. for (i=0; i<xp->xfrm_nr; i++) {
  1642. if (xp->xfrm_vec[i].reqid == reqid)
  1643. return -EEXIST;
  1644. }
  1645. return 0;
  1646. }
  1647. static u32 gen_reqid(struct net *net)
  1648. {
  1649. struct xfrm_policy_walk walk;
  1650. u32 start;
  1651. int rc;
  1652. static u32 reqid = IPSEC_MANUAL_REQID_MAX;
  1653. start = reqid;
  1654. do {
  1655. ++reqid;
  1656. if (reqid == 0)
  1657. reqid = IPSEC_MANUAL_REQID_MAX+1;
  1658. xfrm_policy_walk_init(&walk, XFRM_POLICY_TYPE_MAIN);
  1659. rc = xfrm_policy_walk(net, &walk, check_reqid, (void*)&reqid);
  1660. xfrm_policy_walk_done(&walk, net);
  1661. if (rc != -EEXIST)
  1662. return reqid;
  1663. } while (reqid != start);
  1664. return 0;
  1665. }
  1666. static int
  1667. parse_ipsecrequest(struct xfrm_policy *xp, struct sadb_x_policy *pol,
  1668. struct sadb_x_ipsecrequest *rq)
  1669. {
  1670. struct net *net = xp_net(xp);
  1671. struct xfrm_tmpl *t = xp->xfrm_vec + xp->xfrm_nr;
  1672. int mode;
  1673. if (xp->xfrm_nr >= XFRM_MAX_DEPTH)
  1674. return -ELOOP;
  1675. if (rq->sadb_x_ipsecrequest_mode == 0)
  1676. return -EINVAL;
  1677. if (!xfrm_id_proto_valid(rq->sadb_x_ipsecrequest_proto))
  1678. return -EINVAL;
  1679. t->id.proto = rq->sadb_x_ipsecrequest_proto;
  1680. if ((mode = pfkey_mode_to_xfrm(rq->sadb_x_ipsecrequest_mode)) < 0)
  1681. return -EINVAL;
  1682. t->mode = mode;
  1683. if (rq->sadb_x_ipsecrequest_level == IPSEC_LEVEL_USE) {
  1684. if ((mode == XFRM_MODE_TUNNEL || mode == XFRM_MODE_BEET) &&
  1685. pol->sadb_x_policy_dir == IPSEC_DIR_OUTBOUND)
  1686. return -EINVAL;
  1687. t->optional = 1;
  1688. } else if (rq->sadb_x_ipsecrequest_level == IPSEC_LEVEL_UNIQUE) {
  1689. t->reqid = rq->sadb_x_ipsecrequest_reqid;
  1690. if (t->reqid > IPSEC_MANUAL_REQID_MAX)
  1691. t->reqid = 0;
  1692. if (!t->reqid && !(t->reqid = gen_reqid(net)))
  1693. return -ENOBUFS;
  1694. }
  1695. /* addresses present only in tunnel mode */
  1696. if (t->mode == XFRM_MODE_TUNNEL) {
  1697. int err;
  1698. err = parse_sockaddr_pair(
  1699. (struct sockaddr *)(rq + 1),
  1700. rq->sadb_x_ipsecrequest_len - sizeof(*rq),
  1701. &t->saddr, &t->id.daddr, &t->encap_family);
  1702. if (err)
  1703. return err;
  1704. } else
  1705. t->encap_family = xp->family;
  1706. /* No way to set this via kame pfkey */
  1707. t->allalgs = 1;
  1708. xp->xfrm_nr++;
  1709. return 0;
  1710. }
  1711. static int
  1712. parse_ipsecrequests(struct xfrm_policy *xp, struct sadb_x_policy *pol)
  1713. {
  1714. int err;
  1715. int len = pol->sadb_x_policy_len*8 - sizeof(struct sadb_x_policy);
  1716. struct sadb_x_ipsecrequest *rq = (void*)(pol+1);
  1717. if (pol->sadb_x_policy_len * 8 < sizeof(struct sadb_x_policy))
  1718. return -EINVAL;
  1719. while (len >= sizeof(*rq)) {
  1720. if (len < rq->sadb_x_ipsecrequest_len ||
  1721. rq->sadb_x_ipsecrequest_len < sizeof(*rq))
  1722. return -EINVAL;
  1723. if ((err = parse_ipsecrequest(xp, pol, rq)) < 0)
  1724. return err;
  1725. len -= rq->sadb_x_ipsecrequest_len;
  1726. rq = (void*)((u8*)rq + rq->sadb_x_ipsecrequest_len);
  1727. }
  1728. return 0;
  1729. }
  1730. static inline int pfkey_xfrm_policy2sec_ctx_size(const struct xfrm_policy *xp)
  1731. {
  1732. struct xfrm_sec_ctx *xfrm_ctx = xp->security;
  1733. if (xfrm_ctx) {
  1734. int len = sizeof(struct sadb_x_sec_ctx);
  1735. len += xfrm_ctx->ctx_len;
  1736. return PFKEY_ALIGN8(len);
  1737. }
  1738. return 0;
  1739. }
  1740. static int pfkey_xfrm_policy2msg_size(const struct xfrm_policy *xp)
  1741. {
  1742. const struct xfrm_tmpl *t;
  1743. int sockaddr_size = pfkey_sockaddr_size(xp->family);
  1744. int socklen = 0;
  1745. int i;
  1746. for (i=0; i<xp->xfrm_nr; i++) {
  1747. t = xp->xfrm_vec + i;
  1748. socklen += pfkey_sockaddr_len(t->encap_family);
  1749. }
  1750. return sizeof(struct sadb_msg) +
  1751. (sizeof(struct sadb_lifetime) * 3) +
  1752. (sizeof(struct sadb_address) * 2) +
  1753. (sockaddr_size * 2) +
  1754. sizeof(struct sadb_x_policy) +
  1755. (xp->xfrm_nr * sizeof(struct sadb_x_ipsecrequest)) +
  1756. (socklen * 2) +
  1757. pfkey_xfrm_policy2sec_ctx_size(xp);
  1758. }
  1759. static struct sk_buff * pfkey_xfrm_policy2msg_prep(const struct xfrm_policy *xp)
  1760. {
  1761. struct sk_buff *skb;
  1762. int size;
  1763. size = pfkey_xfrm_policy2msg_size(xp);
  1764. skb = alloc_skb(size + 16, GFP_ATOMIC);
  1765. if (skb == NULL)
  1766. return ERR_PTR(-ENOBUFS);
  1767. return skb;
  1768. }
  1769. static int pfkey_xfrm_policy2msg(struct sk_buff *skb, const struct xfrm_policy *xp, int dir)
  1770. {
  1771. struct sadb_msg *hdr;
  1772. struct sadb_address *addr;
  1773. struct sadb_lifetime *lifetime;
  1774. struct sadb_x_policy *pol;
  1775. struct sadb_x_sec_ctx *sec_ctx;
  1776. struct xfrm_sec_ctx *xfrm_ctx;
  1777. int i;
  1778. int size;
  1779. int sockaddr_size = pfkey_sockaddr_size(xp->family);
  1780. int socklen = pfkey_sockaddr_len(xp->family);
  1781. size = pfkey_xfrm_policy2msg_size(xp);
  1782. /* call should fill header later */
  1783. hdr = skb_put(skb, sizeof(struct sadb_msg));
  1784. memset(hdr, 0, size); /* XXX do we need this ? */
  1785. /* src address */
  1786. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  1787. addr->sadb_address_len =
  1788. (sizeof(struct sadb_address)+sockaddr_size)/
  1789. sizeof(uint64_t);
  1790. addr->sadb_address_exttype = SADB_EXT_ADDRESS_SRC;
  1791. addr->sadb_address_proto = pfkey_proto_from_xfrm(xp->selector.proto);
  1792. addr->sadb_address_prefixlen = xp->selector.prefixlen_s;
  1793. addr->sadb_address_reserved = 0;
  1794. if (!pfkey_sockaddr_fill(&xp->selector.saddr,
  1795. xp->selector.sport,
  1796. (struct sockaddr *) (addr + 1),
  1797. xp->family))
  1798. BUG();
  1799. /* dst address */
  1800. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  1801. addr->sadb_address_len =
  1802. (sizeof(struct sadb_address)+sockaddr_size)/
  1803. sizeof(uint64_t);
  1804. addr->sadb_address_exttype = SADB_EXT_ADDRESS_DST;
  1805. addr->sadb_address_proto = pfkey_proto_from_xfrm(xp->selector.proto);
  1806. addr->sadb_address_prefixlen = xp->selector.prefixlen_d;
  1807. addr->sadb_address_reserved = 0;
  1808. pfkey_sockaddr_fill(&xp->selector.daddr, xp->selector.dport,
  1809. (struct sockaddr *) (addr + 1),
  1810. xp->family);
  1811. /* hard time */
  1812. lifetime = skb_put(skb, sizeof(struct sadb_lifetime));
  1813. lifetime->sadb_lifetime_len =
  1814. sizeof(struct sadb_lifetime)/sizeof(uint64_t);
  1815. lifetime->sadb_lifetime_exttype = SADB_EXT_LIFETIME_HARD;
  1816. lifetime->sadb_lifetime_allocations = _X2KEY(xp->lft.hard_packet_limit);
  1817. lifetime->sadb_lifetime_bytes = _X2KEY(xp->lft.hard_byte_limit);
  1818. lifetime->sadb_lifetime_addtime = xp->lft.hard_add_expires_seconds;
  1819. lifetime->sadb_lifetime_usetime = xp->lft.hard_use_expires_seconds;
  1820. /* soft time */
  1821. lifetime = skb_put(skb, sizeof(struct sadb_lifetime));
  1822. lifetime->sadb_lifetime_len =
  1823. sizeof(struct sadb_lifetime)/sizeof(uint64_t);
  1824. lifetime->sadb_lifetime_exttype = SADB_EXT_LIFETIME_SOFT;
  1825. lifetime->sadb_lifetime_allocations = _X2KEY(xp->lft.soft_packet_limit);
  1826. lifetime->sadb_lifetime_bytes = _X2KEY(xp->lft.soft_byte_limit);
  1827. lifetime->sadb_lifetime_addtime = xp->lft.soft_add_expires_seconds;
  1828. lifetime->sadb_lifetime_usetime = xp->lft.soft_use_expires_seconds;
  1829. /* current time */
  1830. lifetime = skb_put(skb, sizeof(struct sadb_lifetime));
  1831. lifetime->sadb_lifetime_len =
  1832. sizeof(struct sadb_lifetime)/sizeof(uint64_t);
  1833. lifetime->sadb_lifetime_exttype = SADB_EXT_LIFETIME_CURRENT;
  1834. lifetime->sadb_lifetime_allocations = xp->curlft.packets;
  1835. lifetime->sadb_lifetime_bytes = xp->curlft.bytes;
  1836. lifetime->sadb_lifetime_addtime = xp->curlft.add_time;
  1837. lifetime->sadb_lifetime_usetime = xp->curlft.use_time;
  1838. pol = skb_put(skb, sizeof(struct sadb_x_policy));
  1839. pol->sadb_x_policy_len = sizeof(struct sadb_x_policy)/sizeof(uint64_t);
  1840. pol->sadb_x_policy_exttype = SADB_X_EXT_POLICY;
  1841. pol->sadb_x_policy_type = IPSEC_POLICY_DISCARD;
  1842. if (xp->action == XFRM_POLICY_ALLOW) {
  1843. if (xp->xfrm_nr)
  1844. pol->sadb_x_policy_type = IPSEC_POLICY_IPSEC;
  1845. else
  1846. pol->sadb_x_policy_type = IPSEC_POLICY_NONE;
  1847. }
  1848. pol->sadb_x_policy_dir = dir+1;
  1849. pol->sadb_x_policy_reserved = 0;
  1850. pol->sadb_x_policy_id = xp->index;
  1851. pol->sadb_x_policy_priority = xp->priority;
  1852. for (i=0; i<xp->xfrm_nr; i++) {
  1853. const struct xfrm_tmpl *t = xp->xfrm_vec + i;
  1854. struct sadb_x_ipsecrequest *rq;
  1855. int req_size;
  1856. int mode;
  1857. req_size = sizeof(struct sadb_x_ipsecrequest);
  1858. if (t->mode == XFRM_MODE_TUNNEL) {
  1859. socklen = pfkey_sockaddr_len(t->encap_family);
  1860. req_size += socklen * 2;
  1861. } else {
  1862. size -= 2*socklen;
  1863. }
  1864. rq = skb_put(skb, req_size);
  1865. pol->sadb_x_policy_len += req_size/8;
  1866. memset(rq, 0, sizeof(*rq));
  1867. rq->sadb_x_ipsecrequest_len = req_size;
  1868. rq->sadb_x_ipsecrequest_proto = t->id.proto;
  1869. if ((mode = pfkey_mode_from_xfrm(t->mode)) < 0)
  1870. return -EINVAL;
  1871. rq->sadb_x_ipsecrequest_mode = mode;
  1872. rq->sadb_x_ipsecrequest_level = IPSEC_LEVEL_REQUIRE;
  1873. if (t->reqid)
  1874. rq->sadb_x_ipsecrequest_level = IPSEC_LEVEL_UNIQUE;
  1875. if (t->optional)
  1876. rq->sadb_x_ipsecrequest_level = IPSEC_LEVEL_USE;
  1877. rq->sadb_x_ipsecrequest_reqid = t->reqid;
  1878. if (t->mode == XFRM_MODE_TUNNEL) {
  1879. u8 *sa = (void *)(rq + 1);
  1880. pfkey_sockaddr_fill(&t->saddr, 0,
  1881. (struct sockaddr *)sa,
  1882. t->encap_family);
  1883. pfkey_sockaddr_fill(&t->id.daddr, 0,
  1884. (struct sockaddr *) (sa + socklen),
  1885. t->encap_family);
  1886. }
  1887. }
  1888. /* security context */
  1889. if ((xfrm_ctx = xp->security)) {
  1890. int ctx_size = pfkey_xfrm_policy2sec_ctx_size(xp);
  1891. sec_ctx = skb_put(skb, ctx_size);
  1892. sec_ctx->sadb_x_sec_len = ctx_size / sizeof(uint64_t);
  1893. sec_ctx->sadb_x_sec_exttype = SADB_X_EXT_SEC_CTX;
  1894. sec_ctx->sadb_x_ctx_doi = xfrm_ctx->ctx_doi;
  1895. sec_ctx->sadb_x_ctx_alg = xfrm_ctx->ctx_alg;
  1896. sec_ctx->sadb_x_ctx_len = xfrm_ctx->ctx_len;
  1897. memcpy(sec_ctx + 1, xfrm_ctx->ctx_str,
  1898. xfrm_ctx->ctx_len);
  1899. }
  1900. hdr->sadb_msg_len = size / sizeof(uint64_t);
  1901. hdr->sadb_msg_reserved = refcount_read(&xp->refcnt);
  1902. return 0;
  1903. }
  1904. static int key_notify_policy(struct xfrm_policy *xp, int dir, const struct km_event *c)
  1905. {
  1906. struct sk_buff *out_skb;
  1907. struct sadb_msg *out_hdr;
  1908. int err;
  1909. out_skb = pfkey_xfrm_policy2msg_prep(xp);
  1910. if (IS_ERR(out_skb))
  1911. return PTR_ERR(out_skb);
  1912. err = pfkey_xfrm_policy2msg(out_skb, xp, dir);
  1913. if (err < 0) {
  1914. kfree_skb(out_skb);
  1915. return err;
  1916. }
  1917. out_hdr = (struct sadb_msg *) out_skb->data;
  1918. out_hdr->sadb_msg_version = PF_KEY_V2;
  1919. if (c->data.byid && c->event == XFRM_MSG_DELPOLICY)
  1920. out_hdr->sadb_msg_type = SADB_X_SPDDELETE2;
  1921. else
  1922. out_hdr->sadb_msg_type = event2poltype(c->event);
  1923. out_hdr->sadb_msg_errno = 0;
  1924. out_hdr->sadb_msg_seq = c->seq;
  1925. out_hdr->sadb_msg_pid = c->portid;
  1926. pfkey_broadcast(out_skb, GFP_ATOMIC, BROADCAST_ALL, NULL, xp_net(xp));
  1927. return 0;
  1928. }
  1929. static int pfkey_spdadd(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  1930. {
  1931. struct net *net = sock_net(sk);
  1932. int err = 0;
  1933. struct sadb_lifetime *lifetime;
  1934. struct sadb_address *sa;
  1935. struct sadb_x_policy *pol;
  1936. struct xfrm_policy *xp;
  1937. struct km_event c;
  1938. struct sadb_x_sec_ctx *sec_ctx;
  1939. if (!present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  1940. ext_hdrs[SADB_EXT_ADDRESS_DST-1]) ||
  1941. !ext_hdrs[SADB_X_EXT_POLICY-1])
  1942. return -EINVAL;
  1943. pol = ext_hdrs[SADB_X_EXT_POLICY-1];
  1944. if (pol->sadb_x_policy_type > IPSEC_POLICY_IPSEC)
  1945. return -EINVAL;
  1946. if (!pol->sadb_x_policy_dir || pol->sadb_x_policy_dir >= IPSEC_DIR_MAX)
  1947. return -EINVAL;
  1948. xp = xfrm_policy_alloc(net, GFP_KERNEL);
  1949. if (xp == NULL)
  1950. return -ENOBUFS;
  1951. xp->action = (pol->sadb_x_policy_type == IPSEC_POLICY_DISCARD ?
  1952. XFRM_POLICY_BLOCK : XFRM_POLICY_ALLOW);
  1953. xp->priority = pol->sadb_x_policy_priority;
  1954. sa = ext_hdrs[SADB_EXT_ADDRESS_SRC-1];
  1955. xp->family = pfkey_sadb_addr2xfrm_addr(sa, &xp->selector.saddr);
  1956. xp->selector.family = xp->family;
  1957. xp->selector.prefixlen_s = sa->sadb_address_prefixlen;
  1958. xp->selector.proto = pfkey_proto_to_xfrm(sa->sadb_address_proto);
  1959. xp->selector.sport = ((struct sockaddr_in *)(sa+1))->sin_port;
  1960. if (xp->selector.sport)
  1961. xp->selector.sport_mask = htons(0xffff);
  1962. sa = ext_hdrs[SADB_EXT_ADDRESS_DST-1];
  1963. pfkey_sadb_addr2xfrm_addr(sa, &xp->selector.daddr);
  1964. xp->selector.prefixlen_d = sa->sadb_address_prefixlen;
  1965. /* Amusing, we set this twice. KAME apps appear to set same value
  1966. * in both addresses.
  1967. */
  1968. xp->selector.proto = pfkey_proto_to_xfrm(sa->sadb_address_proto);
  1969. xp->selector.dport = ((struct sockaddr_in *)(sa+1))->sin_port;
  1970. if (xp->selector.dport)
  1971. xp->selector.dport_mask = htons(0xffff);
  1972. sec_ctx = ext_hdrs[SADB_X_EXT_SEC_CTX - 1];
  1973. if (sec_ctx != NULL) {
  1974. struct xfrm_user_sec_ctx *uctx = pfkey_sadb2xfrm_user_sec_ctx(sec_ctx, GFP_KERNEL);
  1975. if (!uctx) {
  1976. err = -ENOBUFS;
  1977. goto out;
  1978. }
  1979. err = security_xfrm_policy_alloc(&xp->security, uctx, GFP_KERNEL);
  1980. kfree(uctx);
  1981. if (err)
  1982. goto out;
  1983. }
  1984. xp->lft.soft_byte_limit = XFRM_INF;
  1985. xp->lft.hard_byte_limit = XFRM_INF;
  1986. xp->lft.soft_packet_limit = XFRM_INF;
  1987. xp->lft.hard_packet_limit = XFRM_INF;
  1988. if ((lifetime = ext_hdrs[SADB_EXT_LIFETIME_HARD-1]) != NULL) {
  1989. xp->lft.hard_packet_limit = _KEY2X(lifetime->sadb_lifetime_allocations);
  1990. xp->lft.hard_byte_limit = _KEY2X(lifetime->sadb_lifetime_bytes);
  1991. xp->lft.hard_add_expires_seconds = lifetime->sadb_lifetime_addtime;
  1992. xp->lft.hard_use_expires_seconds = lifetime->sadb_lifetime_usetime;
  1993. }
  1994. if ((lifetime = ext_hdrs[SADB_EXT_LIFETIME_SOFT-1]) != NULL) {
  1995. xp->lft.soft_packet_limit = _KEY2X(lifetime->sadb_lifetime_allocations);
  1996. xp->lft.soft_byte_limit = _KEY2X(lifetime->sadb_lifetime_bytes);
  1997. xp->lft.soft_add_expires_seconds = lifetime->sadb_lifetime_addtime;
  1998. xp->lft.soft_use_expires_seconds = lifetime->sadb_lifetime_usetime;
  1999. }
  2000. xp->xfrm_nr = 0;
  2001. if (pol->sadb_x_policy_type == IPSEC_POLICY_IPSEC &&
  2002. (err = parse_ipsecrequests(xp, pol)) < 0)
  2003. goto out;
  2004. err = xfrm_policy_insert(pol->sadb_x_policy_dir-1, xp,
  2005. hdr->sadb_msg_type != SADB_X_SPDUPDATE);
  2006. xfrm_audit_policy_add(xp, err ? 0 : 1, true);
  2007. if (err)
  2008. goto out;
  2009. if (hdr->sadb_msg_type == SADB_X_SPDUPDATE)
  2010. c.event = XFRM_MSG_UPDPOLICY;
  2011. else
  2012. c.event = XFRM_MSG_NEWPOLICY;
  2013. c.seq = hdr->sadb_msg_seq;
  2014. c.portid = hdr->sadb_msg_pid;
  2015. km_policy_notify(xp, pol->sadb_x_policy_dir-1, &c);
  2016. xfrm_pol_put(xp);
  2017. return 0;
  2018. out:
  2019. xp->walk.dead = 1;
  2020. xfrm_policy_destroy(xp);
  2021. return err;
  2022. }
  2023. static int pfkey_spddelete(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  2024. {
  2025. struct net *net = sock_net(sk);
  2026. int err;
  2027. struct sadb_address *sa;
  2028. struct sadb_x_policy *pol;
  2029. struct xfrm_policy *xp;
  2030. struct xfrm_selector sel;
  2031. struct km_event c;
  2032. struct sadb_x_sec_ctx *sec_ctx;
  2033. struct xfrm_sec_ctx *pol_ctx = NULL;
  2034. if (!present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC-1],
  2035. ext_hdrs[SADB_EXT_ADDRESS_DST-1]) ||
  2036. !ext_hdrs[SADB_X_EXT_POLICY-1])
  2037. return -EINVAL;
  2038. pol = ext_hdrs[SADB_X_EXT_POLICY-1];
  2039. if (!pol->sadb_x_policy_dir || pol->sadb_x_policy_dir >= IPSEC_DIR_MAX)
  2040. return -EINVAL;
  2041. memset(&sel, 0, sizeof(sel));
  2042. sa = ext_hdrs[SADB_EXT_ADDRESS_SRC-1];
  2043. sel.family = pfkey_sadb_addr2xfrm_addr(sa, &sel.saddr);
  2044. sel.prefixlen_s = sa->sadb_address_prefixlen;
  2045. sel.proto = pfkey_proto_to_xfrm(sa->sadb_address_proto);
  2046. sel.sport = ((struct sockaddr_in *)(sa+1))->sin_port;
  2047. if (sel.sport)
  2048. sel.sport_mask = htons(0xffff);
  2049. sa = ext_hdrs[SADB_EXT_ADDRESS_DST-1];
  2050. pfkey_sadb_addr2xfrm_addr(sa, &sel.daddr);
  2051. sel.prefixlen_d = sa->sadb_address_prefixlen;
  2052. sel.proto = pfkey_proto_to_xfrm(sa->sadb_address_proto);
  2053. sel.dport = ((struct sockaddr_in *)(sa+1))->sin_port;
  2054. if (sel.dport)
  2055. sel.dport_mask = htons(0xffff);
  2056. sec_ctx = ext_hdrs[SADB_X_EXT_SEC_CTX - 1];
  2057. if (sec_ctx != NULL) {
  2058. struct xfrm_user_sec_ctx *uctx = pfkey_sadb2xfrm_user_sec_ctx(sec_ctx, GFP_KERNEL);
  2059. if (!uctx)
  2060. return -ENOMEM;
  2061. err = security_xfrm_policy_alloc(&pol_ctx, uctx, GFP_KERNEL);
  2062. kfree(uctx);
  2063. if (err)
  2064. return err;
  2065. }
  2066. xp = xfrm_policy_bysel_ctx(net, &dummy_mark, 0, XFRM_POLICY_TYPE_MAIN,
  2067. pol->sadb_x_policy_dir - 1, &sel, pol_ctx,
  2068. 1, &err);
  2069. security_xfrm_policy_free(pol_ctx);
  2070. if (xp == NULL)
  2071. return -ENOENT;
  2072. xfrm_audit_policy_delete(xp, err ? 0 : 1, true);
  2073. if (err)
  2074. goto out;
  2075. c.seq = hdr->sadb_msg_seq;
  2076. c.portid = hdr->sadb_msg_pid;
  2077. c.data.byid = 0;
  2078. c.event = XFRM_MSG_DELPOLICY;
  2079. km_policy_notify(xp, pol->sadb_x_policy_dir-1, &c);
  2080. out:
  2081. xfrm_pol_put(xp);
  2082. return err;
  2083. }
  2084. static int key_pol_get_resp(struct sock *sk, struct xfrm_policy *xp, const struct sadb_msg *hdr, int dir)
  2085. {
  2086. int err;
  2087. struct sk_buff *out_skb;
  2088. struct sadb_msg *out_hdr;
  2089. err = 0;
  2090. out_skb = pfkey_xfrm_policy2msg_prep(xp);
  2091. if (IS_ERR(out_skb)) {
  2092. err = PTR_ERR(out_skb);
  2093. goto out;
  2094. }
  2095. err = pfkey_xfrm_policy2msg(out_skb, xp, dir);
  2096. if (err < 0) {
  2097. kfree_skb(out_skb);
  2098. goto out;
  2099. }
  2100. out_hdr = (struct sadb_msg *) out_skb->data;
  2101. out_hdr->sadb_msg_version = hdr->sadb_msg_version;
  2102. out_hdr->sadb_msg_type = hdr->sadb_msg_type;
  2103. out_hdr->sadb_msg_satype = 0;
  2104. out_hdr->sadb_msg_errno = 0;
  2105. out_hdr->sadb_msg_seq = hdr->sadb_msg_seq;
  2106. out_hdr->sadb_msg_pid = hdr->sadb_msg_pid;
  2107. pfkey_broadcast(out_skb, GFP_ATOMIC, BROADCAST_ONE, sk, xp_net(xp));
  2108. err = 0;
  2109. out:
  2110. return err;
  2111. }
  2112. static int pfkey_sockaddr_pair_size(sa_family_t family)
  2113. {
  2114. return PFKEY_ALIGN8(pfkey_sockaddr_len(family) * 2);
  2115. }
  2116. static int parse_sockaddr_pair(struct sockaddr *sa, int ext_len,
  2117. xfrm_address_t *saddr, xfrm_address_t *daddr,
  2118. u16 *family)
  2119. {
  2120. int af, socklen;
  2121. if (ext_len < 2 || ext_len < pfkey_sockaddr_pair_size(sa->sa_family))
  2122. return -EINVAL;
  2123. af = pfkey_sockaddr_extract(sa, saddr);
  2124. if (!af)
  2125. return -EINVAL;
  2126. socklen = pfkey_sockaddr_len(af);
  2127. if (pfkey_sockaddr_extract((struct sockaddr *) (((u8 *)sa) + socklen),
  2128. daddr) != af)
  2129. return -EINVAL;
  2130. *family = af;
  2131. return 0;
  2132. }
  2133. #ifdef CONFIG_NET_KEY_MIGRATE
  2134. static int ipsecrequests_to_migrate(struct sadb_x_ipsecrequest *rq1, int len,
  2135. struct xfrm_migrate *m)
  2136. {
  2137. int err;
  2138. struct sadb_x_ipsecrequest *rq2;
  2139. int mode;
  2140. if (len < sizeof(*rq1) ||
  2141. len < rq1->sadb_x_ipsecrequest_len ||
  2142. rq1->sadb_x_ipsecrequest_len < sizeof(*rq1))
  2143. return -EINVAL;
  2144. /* old endoints */
  2145. err = parse_sockaddr_pair((struct sockaddr *)(rq1 + 1),
  2146. rq1->sadb_x_ipsecrequest_len - sizeof(*rq1),
  2147. &m->old_saddr, &m->old_daddr,
  2148. &m->old_family);
  2149. if (err)
  2150. return err;
  2151. rq2 = (struct sadb_x_ipsecrequest *)((u8 *)rq1 + rq1->sadb_x_ipsecrequest_len);
  2152. len -= rq1->sadb_x_ipsecrequest_len;
  2153. if (len <= sizeof(*rq2) ||
  2154. len < rq2->sadb_x_ipsecrequest_len ||
  2155. rq2->sadb_x_ipsecrequest_len < sizeof(*rq2))
  2156. return -EINVAL;
  2157. /* new endpoints */
  2158. err = parse_sockaddr_pair((struct sockaddr *)(rq2 + 1),
  2159. rq2->sadb_x_ipsecrequest_len - sizeof(*rq2),
  2160. &m->new_saddr, &m->new_daddr,
  2161. &m->new_family);
  2162. if (err)
  2163. return err;
  2164. if (rq1->sadb_x_ipsecrequest_proto != rq2->sadb_x_ipsecrequest_proto ||
  2165. rq1->sadb_x_ipsecrequest_mode != rq2->sadb_x_ipsecrequest_mode ||
  2166. rq1->sadb_x_ipsecrequest_reqid != rq2->sadb_x_ipsecrequest_reqid)
  2167. return -EINVAL;
  2168. m->proto = rq1->sadb_x_ipsecrequest_proto;
  2169. if ((mode = pfkey_mode_to_xfrm(rq1->sadb_x_ipsecrequest_mode)) < 0)
  2170. return -EINVAL;
  2171. m->mode = mode;
  2172. m->reqid = rq1->sadb_x_ipsecrequest_reqid;
  2173. return ((int)(rq1->sadb_x_ipsecrequest_len +
  2174. rq2->sadb_x_ipsecrequest_len));
  2175. }
  2176. static int pfkey_migrate(struct sock *sk, struct sk_buff *skb,
  2177. const struct sadb_msg *hdr, void * const *ext_hdrs)
  2178. {
  2179. int i, len, ret, err = -EINVAL;
  2180. u8 dir;
  2181. struct sadb_address *sa;
  2182. struct sadb_x_kmaddress *kma;
  2183. struct sadb_x_policy *pol;
  2184. struct sadb_x_ipsecrequest *rq;
  2185. struct xfrm_selector sel;
  2186. struct xfrm_migrate m[XFRM_MAX_DEPTH];
  2187. struct xfrm_kmaddress k;
  2188. struct net *net = sock_net(sk);
  2189. if (!present_and_same_family(ext_hdrs[SADB_EXT_ADDRESS_SRC - 1],
  2190. ext_hdrs[SADB_EXT_ADDRESS_DST - 1]) ||
  2191. !ext_hdrs[SADB_X_EXT_POLICY - 1]) {
  2192. err = -EINVAL;
  2193. goto out;
  2194. }
  2195. kma = ext_hdrs[SADB_X_EXT_KMADDRESS - 1];
  2196. pol = ext_hdrs[SADB_X_EXT_POLICY - 1];
  2197. if (pol->sadb_x_policy_dir >= IPSEC_DIR_MAX) {
  2198. err = -EINVAL;
  2199. goto out;
  2200. }
  2201. if (kma) {
  2202. /* convert sadb_x_kmaddress to xfrm_kmaddress */
  2203. k.reserved = kma->sadb_x_kmaddress_reserved;
  2204. ret = parse_sockaddr_pair((struct sockaddr *)(kma + 1),
  2205. 8*(kma->sadb_x_kmaddress_len) - sizeof(*kma),
  2206. &k.local, &k.remote, &k.family);
  2207. if (ret < 0) {
  2208. err = ret;
  2209. goto out;
  2210. }
  2211. }
  2212. dir = pol->sadb_x_policy_dir - 1;
  2213. memset(&sel, 0, sizeof(sel));
  2214. /* set source address info of selector */
  2215. sa = ext_hdrs[SADB_EXT_ADDRESS_SRC - 1];
  2216. sel.family = pfkey_sadb_addr2xfrm_addr(sa, &sel.saddr);
  2217. sel.prefixlen_s = sa->sadb_address_prefixlen;
  2218. sel.proto = pfkey_proto_to_xfrm(sa->sadb_address_proto);
  2219. sel.sport = ((struct sockaddr_in *)(sa + 1))->sin_port;
  2220. if (sel.sport)
  2221. sel.sport_mask = htons(0xffff);
  2222. /* set destination address info of selector */
  2223. sa = ext_hdrs[SADB_EXT_ADDRESS_DST - 1];
  2224. pfkey_sadb_addr2xfrm_addr(sa, &sel.daddr);
  2225. sel.prefixlen_d = sa->sadb_address_prefixlen;
  2226. sel.proto = pfkey_proto_to_xfrm(sa->sadb_address_proto);
  2227. sel.dport = ((struct sockaddr_in *)(sa + 1))->sin_port;
  2228. if (sel.dport)
  2229. sel.dport_mask = htons(0xffff);
  2230. rq = (struct sadb_x_ipsecrequest *)(pol + 1);
  2231. /* extract ipsecrequests */
  2232. i = 0;
  2233. len = pol->sadb_x_policy_len * 8 - sizeof(struct sadb_x_policy);
  2234. while (len > 0 && i < XFRM_MAX_DEPTH) {
  2235. ret = ipsecrequests_to_migrate(rq, len, &m[i]);
  2236. if (ret < 0) {
  2237. err = ret;
  2238. goto out;
  2239. } else {
  2240. rq = (struct sadb_x_ipsecrequest *)((u8 *)rq + ret);
  2241. len -= ret;
  2242. i++;
  2243. }
  2244. }
  2245. if (!i || len > 0) {
  2246. err = -EINVAL;
  2247. goto out;
  2248. }
  2249. return xfrm_migrate(&sel, dir, XFRM_POLICY_TYPE_MAIN, m, i,
  2250. kma ? &k : NULL, net, NULL, 0, NULL, NULL);
  2251. out:
  2252. return err;
  2253. }
  2254. #else
  2255. static int pfkey_migrate(struct sock *sk, struct sk_buff *skb,
  2256. const struct sadb_msg *hdr, void * const *ext_hdrs)
  2257. {
  2258. return -ENOPROTOOPT;
  2259. }
  2260. #endif
  2261. static int pfkey_spdget(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  2262. {
  2263. struct net *net = sock_net(sk);
  2264. unsigned int dir;
  2265. int err = 0, delete;
  2266. struct sadb_x_policy *pol;
  2267. struct xfrm_policy *xp;
  2268. struct km_event c;
  2269. if ((pol = ext_hdrs[SADB_X_EXT_POLICY-1]) == NULL)
  2270. return -EINVAL;
  2271. dir = xfrm_policy_id2dir(pol->sadb_x_policy_id);
  2272. if (dir >= XFRM_POLICY_MAX)
  2273. return -EINVAL;
  2274. delete = (hdr->sadb_msg_type == SADB_X_SPDDELETE2);
  2275. xp = xfrm_policy_byid(net, &dummy_mark, 0, XFRM_POLICY_TYPE_MAIN,
  2276. dir, pol->sadb_x_policy_id, delete, &err);
  2277. if (xp == NULL)
  2278. return -ENOENT;
  2279. if (delete) {
  2280. xfrm_audit_policy_delete(xp, err ? 0 : 1, true);
  2281. if (err)
  2282. goto out;
  2283. c.seq = hdr->sadb_msg_seq;
  2284. c.portid = hdr->sadb_msg_pid;
  2285. c.data.byid = 1;
  2286. c.event = XFRM_MSG_DELPOLICY;
  2287. km_policy_notify(xp, dir, &c);
  2288. } else {
  2289. err = key_pol_get_resp(sk, xp, hdr, dir);
  2290. }
  2291. out:
  2292. xfrm_pol_put(xp);
  2293. return err;
  2294. }
  2295. static int dump_sp(struct xfrm_policy *xp, int dir, int count, void *ptr)
  2296. {
  2297. struct pfkey_sock *pfk = ptr;
  2298. struct sk_buff *out_skb;
  2299. struct sadb_msg *out_hdr;
  2300. int err;
  2301. if (!pfkey_can_dump(&pfk->sk))
  2302. return -ENOBUFS;
  2303. out_skb = pfkey_xfrm_policy2msg_prep(xp);
  2304. if (IS_ERR(out_skb))
  2305. return PTR_ERR(out_skb);
  2306. err = pfkey_xfrm_policy2msg(out_skb, xp, dir);
  2307. if (err < 0) {
  2308. kfree_skb(out_skb);
  2309. return err;
  2310. }
  2311. out_hdr = (struct sadb_msg *) out_skb->data;
  2312. out_hdr->sadb_msg_version = pfk->dump.msg_version;
  2313. out_hdr->sadb_msg_type = SADB_X_SPDDUMP;
  2314. out_hdr->sadb_msg_satype = SADB_SATYPE_UNSPEC;
  2315. out_hdr->sadb_msg_errno = 0;
  2316. out_hdr->sadb_msg_seq = count + 1;
  2317. out_hdr->sadb_msg_pid = pfk->dump.msg_portid;
  2318. if (pfk->dump.skb)
  2319. pfkey_broadcast(pfk->dump.skb, GFP_ATOMIC, BROADCAST_ONE,
  2320. &pfk->sk, sock_net(&pfk->sk));
  2321. pfk->dump.skb = out_skb;
  2322. return 0;
  2323. }
  2324. static int pfkey_dump_sp(struct pfkey_sock *pfk)
  2325. {
  2326. struct net *net = sock_net(&pfk->sk);
  2327. return xfrm_policy_walk(net, &pfk->dump.u.policy, dump_sp, (void *) pfk);
  2328. }
  2329. static void pfkey_dump_sp_done(struct pfkey_sock *pfk)
  2330. {
  2331. struct net *net = sock_net((struct sock *)pfk);
  2332. xfrm_policy_walk_done(&pfk->dump.u.policy, net);
  2333. }
  2334. static int pfkey_spddump(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  2335. {
  2336. struct pfkey_sock *pfk = pfkey_sk(sk);
  2337. mutex_lock(&pfk->dump_lock);
  2338. if (pfk->dump.dump != NULL) {
  2339. mutex_unlock(&pfk->dump_lock);
  2340. return -EBUSY;
  2341. }
  2342. pfk->dump.msg_version = hdr->sadb_msg_version;
  2343. pfk->dump.msg_portid = hdr->sadb_msg_pid;
  2344. pfk->dump.dump = pfkey_dump_sp;
  2345. pfk->dump.done = pfkey_dump_sp_done;
  2346. xfrm_policy_walk_init(&pfk->dump.u.policy, XFRM_POLICY_TYPE_MAIN);
  2347. mutex_unlock(&pfk->dump_lock);
  2348. return pfkey_do_dump(pfk);
  2349. }
  2350. static int key_notify_policy_flush(const struct km_event *c)
  2351. {
  2352. struct sk_buff *skb_out;
  2353. struct sadb_msg *hdr;
  2354. skb_out = alloc_skb(sizeof(struct sadb_msg) + 16, GFP_ATOMIC);
  2355. if (!skb_out)
  2356. return -ENOBUFS;
  2357. hdr = skb_put(skb_out, sizeof(struct sadb_msg));
  2358. hdr->sadb_msg_type = SADB_X_SPDFLUSH;
  2359. hdr->sadb_msg_seq = c->seq;
  2360. hdr->sadb_msg_pid = c->portid;
  2361. hdr->sadb_msg_version = PF_KEY_V2;
  2362. hdr->sadb_msg_errno = (uint8_t) 0;
  2363. hdr->sadb_msg_satype = SADB_SATYPE_UNSPEC;
  2364. hdr->sadb_msg_len = (sizeof(struct sadb_msg) / sizeof(uint64_t));
  2365. hdr->sadb_msg_reserved = 0;
  2366. pfkey_broadcast(skb_out, GFP_ATOMIC, BROADCAST_ALL, NULL, c->net);
  2367. return 0;
  2368. }
  2369. static int pfkey_spdflush(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr, void * const *ext_hdrs)
  2370. {
  2371. struct net *net = sock_net(sk);
  2372. struct km_event c;
  2373. int err, err2;
  2374. err = xfrm_policy_flush(net, XFRM_POLICY_TYPE_MAIN, true);
  2375. err2 = unicast_flush_resp(sk, hdr);
  2376. if (err || err2) {
  2377. if (err == -ESRCH) /* empty table - old silent behavior */
  2378. return 0;
  2379. return err;
  2380. }
  2381. c.data.type = XFRM_POLICY_TYPE_MAIN;
  2382. c.event = XFRM_MSG_FLUSHPOLICY;
  2383. c.portid = hdr->sadb_msg_pid;
  2384. c.seq = hdr->sadb_msg_seq;
  2385. c.net = net;
  2386. km_policy_notify(NULL, 0, &c);
  2387. return 0;
  2388. }
  2389. typedef int (*pfkey_handler)(struct sock *sk, struct sk_buff *skb,
  2390. const struct sadb_msg *hdr, void * const *ext_hdrs);
  2391. static const pfkey_handler pfkey_funcs[SADB_MAX + 1] = {
  2392. [SADB_RESERVED] = pfkey_reserved,
  2393. [SADB_GETSPI] = pfkey_getspi,
  2394. [SADB_UPDATE] = pfkey_add,
  2395. [SADB_ADD] = pfkey_add,
  2396. [SADB_DELETE] = pfkey_delete,
  2397. [SADB_GET] = pfkey_get,
  2398. [SADB_ACQUIRE] = pfkey_acquire,
  2399. [SADB_REGISTER] = pfkey_register,
  2400. [SADB_EXPIRE] = NULL,
  2401. [SADB_FLUSH] = pfkey_flush,
  2402. [SADB_DUMP] = pfkey_dump,
  2403. [SADB_X_PROMISC] = pfkey_promisc,
  2404. [SADB_X_PCHANGE] = NULL,
  2405. [SADB_X_SPDUPDATE] = pfkey_spdadd,
  2406. [SADB_X_SPDADD] = pfkey_spdadd,
  2407. [SADB_X_SPDDELETE] = pfkey_spddelete,
  2408. [SADB_X_SPDGET] = pfkey_spdget,
  2409. [SADB_X_SPDACQUIRE] = NULL,
  2410. [SADB_X_SPDDUMP] = pfkey_spddump,
  2411. [SADB_X_SPDFLUSH] = pfkey_spdflush,
  2412. [SADB_X_SPDSETIDX] = pfkey_spdadd,
  2413. [SADB_X_SPDDELETE2] = pfkey_spdget,
  2414. [SADB_X_MIGRATE] = pfkey_migrate,
  2415. };
  2416. static int pfkey_process(struct sock *sk, struct sk_buff *skb, const struct sadb_msg *hdr)
  2417. {
  2418. void *ext_hdrs[SADB_EXT_MAX];
  2419. int err;
  2420. /* Non-zero return value of pfkey_broadcast() does not always signal
  2421. * an error and even on an actual error we may still want to process
  2422. * the message so rather ignore the return value.
  2423. */
  2424. pfkey_broadcast(skb_clone(skb, GFP_KERNEL), GFP_KERNEL,
  2425. BROADCAST_PROMISC_ONLY, NULL, sock_net(sk));
  2426. memset(ext_hdrs, 0, sizeof(ext_hdrs));
  2427. err = parse_exthdrs(skb, hdr, ext_hdrs);
  2428. if (!err) {
  2429. err = -EOPNOTSUPP;
  2430. if (pfkey_funcs[hdr->sadb_msg_type])
  2431. err = pfkey_funcs[hdr->sadb_msg_type](sk, skb, hdr, ext_hdrs);
  2432. }
  2433. return err;
  2434. }
  2435. static struct sadb_msg *pfkey_get_base_msg(struct sk_buff *skb, int *errp)
  2436. {
  2437. struct sadb_msg *hdr = NULL;
  2438. if (skb->len < sizeof(*hdr)) {
  2439. *errp = -EMSGSIZE;
  2440. } else {
  2441. hdr = (struct sadb_msg *) skb->data;
  2442. if (hdr->sadb_msg_version != PF_KEY_V2 ||
  2443. hdr->sadb_msg_reserved != 0 ||
  2444. (hdr->sadb_msg_type <= SADB_RESERVED ||
  2445. hdr->sadb_msg_type > SADB_MAX)) {
  2446. hdr = NULL;
  2447. *errp = -EINVAL;
  2448. } else if (hdr->sadb_msg_len != (skb->len /
  2449. sizeof(uint64_t)) ||
  2450. hdr->sadb_msg_len < (sizeof(struct sadb_msg) /
  2451. sizeof(uint64_t))) {
  2452. hdr = NULL;
  2453. *errp = -EMSGSIZE;
  2454. } else {
  2455. *errp = 0;
  2456. }
  2457. }
  2458. return hdr;
  2459. }
  2460. static inline int aalg_tmpl_set(const struct xfrm_tmpl *t,
  2461. const struct xfrm_algo_desc *d)
  2462. {
  2463. unsigned int id = d->desc.sadb_alg_id;
  2464. if (id >= sizeof(t->aalgos) * 8)
  2465. return 0;
  2466. return (t->aalgos >> id) & 1;
  2467. }
  2468. static inline int ealg_tmpl_set(const struct xfrm_tmpl *t,
  2469. const struct xfrm_algo_desc *d)
  2470. {
  2471. unsigned int id = d->desc.sadb_alg_id;
  2472. if (id >= sizeof(t->ealgos) * 8)
  2473. return 0;
  2474. return (t->ealgos >> id) & 1;
  2475. }
  2476. static int count_ah_combs(const struct xfrm_tmpl *t)
  2477. {
  2478. int i, sz = 0;
  2479. for (i = 0; ; i++) {
  2480. const struct xfrm_algo_desc *aalg = xfrm_aalg_get_byidx(i);
  2481. if (!aalg)
  2482. break;
  2483. if (!aalg->pfkey_supported)
  2484. continue;
  2485. if (aalg_tmpl_set(t, aalg))
  2486. sz += sizeof(struct sadb_comb);
  2487. }
  2488. return sz + sizeof(struct sadb_prop);
  2489. }
  2490. static int count_esp_combs(const struct xfrm_tmpl *t)
  2491. {
  2492. int i, k, sz = 0;
  2493. for (i = 0; ; i++) {
  2494. const struct xfrm_algo_desc *ealg = xfrm_ealg_get_byidx(i);
  2495. if (!ealg)
  2496. break;
  2497. if (!ealg->pfkey_supported)
  2498. continue;
  2499. if (!(ealg_tmpl_set(t, ealg)))
  2500. continue;
  2501. for (k = 1; ; k++) {
  2502. const struct xfrm_algo_desc *aalg = xfrm_aalg_get_byidx(k);
  2503. if (!aalg)
  2504. break;
  2505. if (!aalg->pfkey_supported)
  2506. continue;
  2507. if (aalg_tmpl_set(t, aalg))
  2508. sz += sizeof(struct sadb_comb);
  2509. }
  2510. }
  2511. return sz + sizeof(struct sadb_prop);
  2512. }
  2513. static int dump_ah_combs(struct sk_buff *skb, const struct xfrm_tmpl *t)
  2514. {
  2515. struct sadb_prop *p;
  2516. int sz = 0;
  2517. int i;
  2518. p = skb_put(skb, sizeof(struct sadb_prop));
  2519. p->sadb_prop_len = sizeof(struct sadb_prop)/8;
  2520. p->sadb_prop_exttype = SADB_EXT_PROPOSAL;
  2521. p->sadb_prop_replay = 32;
  2522. memset(p->sadb_prop_reserved, 0, sizeof(p->sadb_prop_reserved));
  2523. for (i = 0; ; i++) {
  2524. const struct xfrm_algo_desc *aalg = xfrm_aalg_get_byidx(i);
  2525. if (!aalg)
  2526. break;
  2527. if (!aalg->pfkey_supported)
  2528. continue;
  2529. if (aalg_tmpl_set(t, aalg) && aalg->available) {
  2530. struct sadb_comb *c;
  2531. c = skb_put_zero(skb, sizeof(struct sadb_comb));
  2532. p->sadb_prop_len += sizeof(struct sadb_comb)/8;
  2533. c->sadb_comb_auth = aalg->desc.sadb_alg_id;
  2534. c->sadb_comb_auth_minbits = aalg->desc.sadb_alg_minbits;
  2535. c->sadb_comb_auth_maxbits = aalg->desc.sadb_alg_maxbits;
  2536. c->sadb_comb_hard_addtime = 24*60*60;
  2537. c->sadb_comb_soft_addtime = 20*60*60;
  2538. c->sadb_comb_hard_usetime = 8*60*60;
  2539. c->sadb_comb_soft_usetime = 7*60*60;
  2540. sz += sizeof(*c);
  2541. }
  2542. }
  2543. return sz + sizeof(*p);
  2544. }
  2545. static int dump_esp_combs(struct sk_buff *skb, const struct xfrm_tmpl *t)
  2546. {
  2547. struct sadb_prop *p;
  2548. int sz = 0;
  2549. int i, k;
  2550. p = skb_put(skb, sizeof(struct sadb_prop));
  2551. p->sadb_prop_len = sizeof(struct sadb_prop)/8;
  2552. p->sadb_prop_exttype = SADB_EXT_PROPOSAL;
  2553. p->sadb_prop_replay = 32;
  2554. memset(p->sadb_prop_reserved, 0, sizeof(p->sadb_prop_reserved));
  2555. for (i=0; ; i++) {
  2556. const struct xfrm_algo_desc *ealg = xfrm_ealg_get_byidx(i);
  2557. if (!ealg)
  2558. break;
  2559. if (!ealg->pfkey_supported)
  2560. continue;
  2561. if (!(ealg_tmpl_set(t, ealg) && ealg->available))
  2562. continue;
  2563. for (k = 1; ; k++) {
  2564. struct sadb_comb *c;
  2565. const struct xfrm_algo_desc *aalg = xfrm_aalg_get_byidx(k);
  2566. if (!aalg)
  2567. break;
  2568. if (!aalg->pfkey_supported)
  2569. continue;
  2570. if (!(aalg_tmpl_set(t, aalg) && aalg->available))
  2571. continue;
  2572. c = skb_put(skb, sizeof(struct sadb_comb));
  2573. memset(c, 0, sizeof(*c));
  2574. p->sadb_prop_len += sizeof(struct sadb_comb)/8;
  2575. c->sadb_comb_auth = aalg->desc.sadb_alg_id;
  2576. c->sadb_comb_auth_minbits = aalg->desc.sadb_alg_minbits;
  2577. c->sadb_comb_auth_maxbits = aalg->desc.sadb_alg_maxbits;
  2578. c->sadb_comb_encrypt = ealg->desc.sadb_alg_id;
  2579. c->sadb_comb_encrypt_minbits = ealg->desc.sadb_alg_minbits;
  2580. c->sadb_comb_encrypt_maxbits = ealg->desc.sadb_alg_maxbits;
  2581. c->sadb_comb_hard_addtime = 24*60*60;
  2582. c->sadb_comb_soft_addtime = 20*60*60;
  2583. c->sadb_comb_hard_usetime = 8*60*60;
  2584. c->sadb_comb_soft_usetime = 7*60*60;
  2585. sz += sizeof(*c);
  2586. }
  2587. }
  2588. return sz + sizeof(*p);
  2589. }
  2590. static int key_notify_policy_expire(struct xfrm_policy *xp, const struct km_event *c)
  2591. {
  2592. return 0;
  2593. }
  2594. static int key_notify_sa_expire(struct xfrm_state *x, const struct km_event *c)
  2595. {
  2596. struct sk_buff *out_skb;
  2597. struct sadb_msg *out_hdr;
  2598. int hard;
  2599. int hsc;
  2600. hard = c->data.hard;
  2601. if (hard)
  2602. hsc = 2;
  2603. else
  2604. hsc = 1;
  2605. out_skb = pfkey_xfrm_state2msg_expire(x, hsc);
  2606. if (IS_ERR(out_skb))
  2607. return PTR_ERR(out_skb);
  2608. out_hdr = (struct sadb_msg *) out_skb->data;
  2609. out_hdr->sadb_msg_version = PF_KEY_V2;
  2610. out_hdr->sadb_msg_type = SADB_EXPIRE;
  2611. out_hdr->sadb_msg_satype = pfkey_proto2satype(x->id.proto);
  2612. out_hdr->sadb_msg_errno = 0;
  2613. out_hdr->sadb_msg_reserved = 0;
  2614. out_hdr->sadb_msg_seq = 0;
  2615. out_hdr->sadb_msg_pid = 0;
  2616. pfkey_broadcast(out_skb, GFP_ATOMIC, BROADCAST_REGISTERED, NULL,
  2617. xs_net(x));
  2618. return 0;
  2619. }
  2620. static int pfkey_send_notify(struct xfrm_state *x, const struct km_event *c)
  2621. {
  2622. struct net *net = x ? xs_net(x) : c->net;
  2623. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  2624. if (atomic_read(&net_pfkey->socks_nr) == 0)
  2625. return 0;
  2626. switch (c->event) {
  2627. case XFRM_MSG_EXPIRE:
  2628. return key_notify_sa_expire(x, c);
  2629. case XFRM_MSG_DELSA:
  2630. case XFRM_MSG_NEWSA:
  2631. case XFRM_MSG_UPDSA:
  2632. return key_notify_sa(x, c);
  2633. case XFRM_MSG_FLUSHSA:
  2634. return key_notify_sa_flush(c);
  2635. case XFRM_MSG_NEWAE: /* not yet supported */
  2636. break;
  2637. default:
  2638. pr_err("pfkey: Unknown SA event %d\n", c->event);
  2639. break;
  2640. }
  2641. return 0;
  2642. }
  2643. static int pfkey_send_policy_notify(struct xfrm_policy *xp, int dir, const struct km_event *c)
  2644. {
  2645. if (xp && xp->type != XFRM_POLICY_TYPE_MAIN)
  2646. return 0;
  2647. switch (c->event) {
  2648. case XFRM_MSG_POLEXPIRE:
  2649. return key_notify_policy_expire(xp, c);
  2650. case XFRM_MSG_DELPOLICY:
  2651. case XFRM_MSG_NEWPOLICY:
  2652. case XFRM_MSG_UPDPOLICY:
  2653. return key_notify_policy(xp, dir, c);
  2654. case XFRM_MSG_FLUSHPOLICY:
  2655. if (c->data.type != XFRM_POLICY_TYPE_MAIN)
  2656. break;
  2657. return key_notify_policy_flush(c);
  2658. default:
  2659. pr_err("pfkey: Unknown policy event %d\n", c->event);
  2660. break;
  2661. }
  2662. return 0;
  2663. }
  2664. static u32 get_acqseq(void)
  2665. {
  2666. u32 res;
  2667. static atomic_t acqseq;
  2668. do {
  2669. res = atomic_inc_return(&acqseq);
  2670. } while (!res);
  2671. return res;
  2672. }
  2673. static bool pfkey_is_alive(const struct km_event *c)
  2674. {
  2675. struct netns_pfkey *net_pfkey = net_generic(c->net, pfkey_net_id);
  2676. struct sock *sk;
  2677. bool is_alive = false;
  2678. rcu_read_lock();
  2679. sk_for_each_rcu(sk, &net_pfkey->table) {
  2680. if (pfkey_sk(sk)->registered) {
  2681. is_alive = true;
  2682. break;
  2683. }
  2684. }
  2685. rcu_read_unlock();
  2686. return is_alive;
  2687. }
  2688. static int pfkey_send_acquire(struct xfrm_state *x, struct xfrm_tmpl *t, struct xfrm_policy *xp)
  2689. {
  2690. struct sk_buff *skb;
  2691. struct sadb_msg *hdr;
  2692. struct sadb_address *addr;
  2693. struct sadb_x_policy *pol;
  2694. int sockaddr_size;
  2695. int size;
  2696. struct sadb_x_sec_ctx *sec_ctx;
  2697. struct xfrm_sec_ctx *xfrm_ctx;
  2698. int ctx_size = 0;
  2699. int alg_size = 0;
  2700. sockaddr_size = pfkey_sockaddr_size(x->props.family);
  2701. if (!sockaddr_size)
  2702. return -EINVAL;
  2703. size = sizeof(struct sadb_msg) +
  2704. (sizeof(struct sadb_address) * 2) +
  2705. (sockaddr_size * 2) +
  2706. sizeof(struct sadb_x_policy);
  2707. if (x->id.proto == IPPROTO_AH)
  2708. alg_size = count_ah_combs(t);
  2709. else if (x->id.proto == IPPROTO_ESP)
  2710. alg_size = count_esp_combs(t);
  2711. if ((xfrm_ctx = x->security)) {
  2712. ctx_size = PFKEY_ALIGN8(xfrm_ctx->ctx_len);
  2713. size += sizeof(struct sadb_x_sec_ctx) + ctx_size;
  2714. }
  2715. skb = alloc_skb(size + alg_size + 16, GFP_ATOMIC);
  2716. if (skb == NULL)
  2717. return -ENOMEM;
  2718. hdr = skb_put(skb, sizeof(struct sadb_msg));
  2719. hdr->sadb_msg_version = PF_KEY_V2;
  2720. hdr->sadb_msg_type = SADB_ACQUIRE;
  2721. hdr->sadb_msg_satype = pfkey_proto2satype(x->id.proto);
  2722. hdr->sadb_msg_len = size / sizeof(uint64_t);
  2723. hdr->sadb_msg_errno = 0;
  2724. hdr->sadb_msg_reserved = 0;
  2725. hdr->sadb_msg_seq = x->km.seq = get_acqseq();
  2726. hdr->sadb_msg_pid = 0;
  2727. /* src address */
  2728. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  2729. addr->sadb_address_len =
  2730. (sizeof(struct sadb_address)+sockaddr_size)/
  2731. sizeof(uint64_t);
  2732. addr->sadb_address_exttype = SADB_EXT_ADDRESS_SRC;
  2733. addr->sadb_address_proto = 0;
  2734. addr->sadb_address_reserved = 0;
  2735. addr->sadb_address_prefixlen =
  2736. pfkey_sockaddr_fill_zero_tail(&x->props.saddr, 0,
  2737. (struct sockaddr *)(addr + 1),
  2738. x->props.family);
  2739. if (!addr->sadb_address_prefixlen)
  2740. BUG();
  2741. /* dst address */
  2742. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  2743. addr->sadb_address_len =
  2744. (sizeof(struct sadb_address)+sockaddr_size)/
  2745. sizeof(uint64_t);
  2746. addr->sadb_address_exttype = SADB_EXT_ADDRESS_DST;
  2747. addr->sadb_address_proto = 0;
  2748. addr->sadb_address_reserved = 0;
  2749. addr->sadb_address_prefixlen =
  2750. pfkey_sockaddr_fill_zero_tail(&x->id.daddr, 0,
  2751. (struct sockaddr *)(addr + 1),
  2752. x->props.family);
  2753. if (!addr->sadb_address_prefixlen)
  2754. BUG();
  2755. pol = skb_put(skb, sizeof(struct sadb_x_policy));
  2756. pol->sadb_x_policy_len = sizeof(struct sadb_x_policy)/sizeof(uint64_t);
  2757. pol->sadb_x_policy_exttype = SADB_X_EXT_POLICY;
  2758. pol->sadb_x_policy_type = IPSEC_POLICY_IPSEC;
  2759. pol->sadb_x_policy_dir = XFRM_POLICY_OUT + 1;
  2760. pol->sadb_x_policy_reserved = 0;
  2761. pol->sadb_x_policy_id = xp->index;
  2762. pol->sadb_x_policy_priority = xp->priority;
  2763. /* Set sadb_comb's. */
  2764. alg_size = 0;
  2765. if (x->id.proto == IPPROTO_AH)
  2766. alg_size = dump_ah_combs(skb, t);
  2767. else if (x->id.proto == IPPROTO_ESP)
  2768. alg_size = dump_esp_combs(skb, t);
  2769. hdr->sadb_msg_len += alg_size / 8;
  2770. /* security context */
  2771. if (xfrm_ctx) {
  2772. sec_ctx = skb_put(skb,
  2773. sizeof(struct sadb_x_sec_ctx) + ctx_size);
  2774. sec_ctx->sadb_x_sec_len =
  2775. (sizeof(struct sadb_x_sec_ctx) + ctx_size) / sizeof(uint64_t);
  2776. sec_ctx->sadb_x_sec_exttype = SADB_X_EXT_SEC_CTX;
  2777. sec_ctx->sadb_x_ctx_doi = xfrm_ctx->ctx_doi;
  2778. sec_ctx->sadb_x_ctx_alg = xfrm_ctx->ctx_alg;
  2779. sec_ctx->sadb_x_ctx_len = xfrm_ctx->ctx_len;
  2780. memcpy(sec_ctx + 1, xfrm_ctx->ctx_str,
  2781. xfrm_ctx->ctx_len);
  2782. }
  2783. return pfkey_broadcast(skb, GFP_ATOMIC, BROADCAST_REGISTERED, NULL,
  2784. xs_net(x));
  2785. }
  2786. static struct xfrm_policy *pfkey_compile_policy(struct sock *sk, int opt,
  2787. u8 *data, int len, int *dir)
  2788. {
  2789. struct net *net = sock_net(sk);
  2790. struct xfrm_policy *xp;
  2791. struct sadb_x_policy *pol = (struct sadb_x_policy*)data;
  2792. struct sadb_x_sec_ctx *sec_ctx;
  2793. switch (sk->sk_family) {
  2794. case AF_INET:
  2795. if (opt != IP_IPSEC_POLICY) {
  2796. *dir = -EOPNOTSUPP;
  2797. return NULL;
  2798. }
  2799. break;
  2800. #if IS_ENABLED(CONFIG_IPV6)
  2801. case AF_INET6:
  2802. if (opt != IPV6_IPSEC_POLICY) {
  2803. *dir = -EOPNOTSUPP;
  2804. return NULL;
  2805. }
  2806. break;
  2807. #endif
  2808. default:
  2809. *dir = -EINVAL;
  2810. return NULL;
  2811. }
  2812. *dir = -EINVAL;
  2813. if (len < sizeof(struct sadb_x_policy) ||
  2814. pol->sadb_x_policy_len*8 > len ||
  2815. pol->sadb_x_policy_type > IPSEC_POLICY_BYPASS ||
  2816. (!pol->sadb_x_policy_dir || pol->sadb_x_policy_dir > IPSEC_DIR_OUTBOUND))
  2817. return NULL;
  2818. xp = xfrm_policy_alloc(net, GFP_ATOMIC);
  2819. if (xp == NULL) {
  2820. *dir = -ENOBUFS;
  2821. return NULL;
  2822. }
  2823. xp->action = (pol->sadb_x_policy_type == IPSEC_POLICY_DISCARD ?
  2824. XFRM_POLICY_BLOCK : XFRM_POLICY_ALLOW);
  2825. xp->lft.soft_byte_limit = XFRM_INF;
  2826. xp->lft.hard_byte_limit = XFRM_INF;
  2827. xp->lft.soft_packet_limit = XFRM_INF;
  2828. xp->lft.hard_packet_limit = XFRM_INF;
  2829. xp->family = sk->sk_family;
  2830. xp->xfrm_nr = 0;
  2831. if (pol->sadb_x_policy_type == IPSEC_POLICY_IPSEC &&
  2832. (*dir = parse_ipsecrequests(xp, pol)) < 0)
  2833. goto out;
  2834. /* security context too */
  2835. if (len >= (pol->sadb_x_policy_len*8 +
  2836. sizeof(struct sadb_x_sec_ctx))) {
  2837. char *p = (char *)pol;
  2838. struct xfrm_user_sec_ctx *uctx;
  2839. p += pol->sadb_x_policy_len*8;
  2840. sec_ctx = (struct sadb_x_sec_ctx *)p;
  2841. if (len < pol->sadb_x_policy_len*8 +
  2842. sec_ctx->sadb_x_sec_len*8) {
  2843. *dir = -EINVAL;
  2844. goto out;
  2845. }
  2846. if ((*dir = verify_sec_ctx_len(p)))
  2847. goto out;
  2848. uctx = pfkey_sadb2xfrm_user_sec_ctx(sec_ctx, GFP_ATOMIC);
  2849. *dir = security_xfrm_policy_alloc(&xp->security, uctx, GFP_ATOMIC);
  2850. kfree(uctx);
  2851. if (*dir)
  2852. goto out;
  2853. }
  2854. *dir = pol->sadb_x_policy_dir-1;
  2855. return xp;
  2856. out:
  2857. xp->walk.dead = 1;
  2858. xfrm_policy_destroy(xp);
  2859. return NULL;
  2860. }
  2861. static int pfkey_send_new_mapping(struct xfrm_state *x, xfrm_address_t *ipaddr, __be16 sport)
  2862. {
  2863. struct sk_buff *skb;
  2864. struct sadb_msg *hdr;
  2865. struct sadb_sa *sa;
  2866. struct sadb_address *addr;
  2867. struct sadb_x_nat_t_port *n_port;
  2868. int sockaddr_size;
  2869. int size;
  2870. __u8 satype = (x->id.proto == IPPROTO_ESP ? SADB_SATYPE_ESP : 0);
  2871. struct xfrm_encap_tmpl *natt = NULL;
  2872. sockaddr_size = pfkey_sockaddr_size(x->props.family);
  2873. if (!sockaddr_size)
  2874. return -EINVAL;
  2875. if (!satype)
  2876. return -EINVAL;
  2877. if (!x->encap)
  2878. return -EINVAL;
  2879. natt = x->encap;
  2880. /* Build an SADB_X_NAT_T_NEW_MAPPING message:
  2881. *
  2882. * HDR | SA | ADDRESS_SRC (old addr) | NAT_T_SPORT (old port) |
  2883. * ADDRESS_DST (new addr) | NAT_T_DPORT (new port)
  2884. */
  2885. size = sizeof(struct sadb_msg) +
  2886. sizeof(struct sadb_sa) +
  2887. (sizeof(struct sadb_address) * 2) +
  2888. (sockaddr_size * 2) +
  2889. (sizeof(struct sadb_x_nat_t_port) * 2);
  2890. skb = alloc_skb(size + 16, GFP_ATOMIC);
  2891. if (skb == NULL)
  2892. return -ENOMEM;
  2893. hdr = skb_put(skb, sizeof(struct sadb_msg));
  2894. hdr->sadb_msg_version = PF_KEY_V2;
  2895. hdr->sadb_msg_type = SADB_X_NAT_T_NEW_MAPPING;
  2896. hdr->sadb_msg_satype = satype;
  2897. hdr->sadb_msg_len = size / sizeof(uint64_t);
  2898. hdr->sadb_msg_errno = 0;
  2899. hdr->sadb_msg_reserved = 0;
  2900. hdr->sadb_msg_seq = x->km.seq;
  2901. hdr->sadb_msg_pid = 0;
  2902. /* SA */
  2903. sa = skb_put(skb, sizeof(struct sadb_sa));
  2904. sa->sadb_sa_len = sizeof(struct sadb_sa)/sizeof(uint64_t);
  2905. sa->sadb_sa_exttype = SADB_EXT_SA;
  2906. sa->sadb_sa_spi = x->id.spi;
  2907. sa->sadb_sa_replay = 0;
  2908. sa->sadb_sa_state = 0;
  2909. sa->sadb_sa_auth = 0;
  2910. sa->sadb_sa_encrypt = 0;
  2911. sa->sadb_sa_flags = 0;
  2912. /* ADDRESS_SRC (old addr) */
  2913. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  2914. addr->sadb_address_len =
  2915. (sizeof(struct sadb_address)+sockaddr_size)/
  2916. sizeof(uint64_t);
  2917. addr->sadb_address_exttype = SADB_EXT_ADDRESS_SRC;
  2918. addr->sadb_address_proto = 0;
  2919. addr->sadb_address_reserved = 0;
  2920. addr->sadb_address_prefixlen =
  2921. pfkey_sockaddr_fill_zero_tail(&x->props.saddr, 0,
  2922. (struct sockaddr *)(addr + 1),
  2923. x->props.family);
  2924. if (!addr->sadb_address_prefixlen)
  2925. BUG();
  2926. /* NAT_T_SPORT (old port) */
  2927. n_port = skb_put(skb, sizeof(*n_port));
  2928. n_port->sadb_x_nat_t_port_len = sizeof(*n_port)/sizeof(uint64_t);
  2929. n_port->sadb_x_nat_t_port_exttype = SADB_X_EXT_NAT_T_SPORT;
  2930. n_port->sadb_x_nat_t_port_port = natt->encap_sport;
  2931. n_port->sadb_x_nat_t_port_reserved = 0;
  2932. /* ADDRESS_DST (new addr) */
  2933. addr = skb_put(skb, sizeof(struct sadb_address) + sockaddr_size);
  2934. addr->sadb_address_len =
  2935. (sizeof(struct sadb_address)+sockaddr_size)/
  2936. sizeof(uint64_t);
  2937. addr->sadb_address_exttype = SADB_EXT_ADDRESS_DST;
  2938. addr->sadb_address_proto = 0;
  2939. addr->sadb_address_reserved = 0;
  2940. addr->sadb_address_prefixlen =
  2941. pfkey_sockaddr_fill_zero_tail(ipaddr, 0,
  2942. (struct sockaddr *)(addr + 1),
  2943. x->props.family);
  2944. if (!addr->sadb_address_prefixlen)
  2945. BUG();
  2946. /* NAT_T_DPORT (new port) */
  2947. n_port = skb_put(skb, sizeof(*n_port));
  2948. n_port->sadb_x_nat_t_port_len = sizeof(*n_port)/sizeof(uint64_t);
  2949. n_port->sadb_x_nat_t_port_exttype = SADB_X_EXT_NAT_T_DPORT;
  2950. n_port->sadb_x_nat_t_port_port = sport;
  2951. n_port->sadb_x_nat_t_port_reserved = 0;
  2952. return pfkey_broadcast(skb, GFP_ATOMIC, BROADCAST_REGISTERED, NULL,
  2953. xs_net(x));
  2954. }
  2955. #ifdef CONFIG_NET_KEY_MIGRATE
  2956. static int set_sadb_address(struct sk_buff *skb, int sasize, int type,
  2957. const struct xfrm_selector *sel)
  2958. {
  2959. struct sadb_address *addr;
  2960. addr = skb_put(skb, sizeof(struct sadb_address) + sasize);
  2961. addr->sadb_address_len = (sizeof(struct sadb_address) + sasize)/8;
  2962. addr->sadb_address_exttype = type;
  2963. addr->sadb_address_proto = sel->proto;
  2964. addr->sadb_address_reserved = 0;
  2965. switch (type) {
  2966. case SADB_EXT_ADDRESS_SRC:
  2967. addr->sadb_address_prefixlen = sel->prefixlen_s;
  2968. pfkey_sockaddr_fill_zero_tail(&sel->saddr, 0,
  2969. (struct sockaddr *)(addr + 1),
  2970. sel->family);
  2971. break;
  2972. case SADB_EXT_ADDRESS_DST:
  2973. addr->sadb_address_prefixlen = sel->prefixlen_d;
  2974. pfkey_sockaddr_fill_zero_tail(&sel->daddr, 0,
  2975. (struct sockaddr *)(addr + 1),
  2976. sel->family);
  2977. break;
  2978. default:
  2979. return -EINVAL;
  2980. }
  2981. return 0;
  2982. }
  2983. static int set_sadb_kmaddress(struct sk_buff *skb, const struct xfrm_kmaddress *k)
  2984. {
  2985. struct sadb_x_kmaddress *kma;
  2986. u8 *sa;
  2987. int family = k->family;
  2988. int socklen = pfkey_sockaddr_len(family);
  2989. int size_req;
  2990. size_req = (sizeof(struct sadb_x_kmaddress) +
  2991. pfkey_sockaddr_pair_size(family));
  2992. kma = skb_put_zero(skb, size_req);
  2993. kma->sadb_x_kmaddress_len = size_req / 8;
  2994. kma->sadb_x_kmaddress_exttype = SADB_X_EXT_KMADDRESS;
  2995. kma->sadb_x_kmaddress_reserved = k->reserved;
  2996. sa = (u8 *)(kma + 1);
  2997. if (!pfkey_sockaddr_fill(&k->local, 0, (struct sockaddr *)sa, family) ||
  2998. !pfkey_sockaddr_fill(&k->remote, 0, (struct sockaddr *)(sa+socklen), family))
  2999. return -EINVAL;
  3000. return 0;
  3001. }
  3002. static int set_ipsecrequest(struct sk_buff *skb,
  3003. uint8_t proto, uint8_t mode, int level,
  3004. uint32_t reqid, sa_family_t family,
  3005. const xfrm_address_t *src, const xfrm_address_t *dst)
  3006. {
  3007. struct sadb_x_ipsecrequest *rq;
  3008. u8 *sa;
  3009. int socklen = pfkey_sockaddr_len(family);
  3010. int size_req;
  3011. size_req = sizeof(struct sadb_x_ipsecrequest) +
  3012. pfkey_sockaddr_pair_size(family);
  3013. rq = skb_put_zero(skb, size_req);
  3014. rq->sadb_x_ipsecrequest_len = size_req;
  3015. rq->sadb_x_ipsecrequest_proto = proto;
  3016. rq->sadb_x_ipsecrequest_mode = mode;
  3017. rq->sadb_x_ipsecrequest_level = level;
  3018. rq->sadb_x_ipsecrequest_reqid = reqid;
  3019. sa = (u8 *) (rq + 1);
  3020. if (!pfkey_sockaddr_fill(src, 0, (struct sockaddr *)sa, family) ||
  3021. !pfkey_sockaddr_fill(dst, 0, (struct sockaddr *)(sa + socklen), family))
  3022. return -EINVAL;
  3023. return 0;
  3024. }
  3025. #endif
  3026. #ifdef CONFIG_NET_KEY_MIGRATE
  3027. static int pfkey_send_migrate(const struct xfrm_selector *sel, u8 dir, u8 type,
  3028. const struct xfrm_migrate *m, int num_bundles,
  3029. const struct xfrm_kmaddress *k,
  3030. const struct xfrm_encap_tmpl *encap)
  3031. {
  3032. int i;
  3033. int sasize_sel;
  3034. int size = 0;
  3035. int size_pol = 0;
  3036. struct sk_buff *skb;
  3037. struct sadb_msg *hdr;
  3038. struct sadb_x_policy *pol;
  3039. const struct xfrm_migrate *mp;
  3040. if (type != XFRM_POLICY_TYPE_MAIN)
  3041. return 0;
  3042. if (num_bundles <= 0 || num_bundles > XFRM_MAX_DEPTH)
  3043. return -EINVAL;
  3044. if (k != NULL) {
  3045. /* addresses for KM */
  3046. size += PFKEY_ALIGN8(sizeof(struct sadb_x_kmaddress) +
  3047. pfkey_sockaddr_pair_size(k->family));
  3048. }
  3049. /* selector */
  3050. sasize_sel = pfkey_sockaddr_size(sel->family);
  3051. if (!sasize_sel)
  3052. return -EINVAL;
  3053. size += (sizeof(struct sadb_address) + sasize_sel) * 2;
  3054. /* policy info */
  3055. size_pol += sizeof(struct sadb_x_policy);
  3056. /* ipsecrequests */
  3057. for (i = 0, mp = m; i < num_bundles; i++, mp++) {
  3058. int pair_size;
  3059. pair_size = pfkey_sockaddr_pair_size(mp->old_family);
  3060. if (!pair_size)
  3061. return -EINVAL;
  3062. size_pol += sizeof(struct sadb_x_ipsecrequest) + pair_size;
  3063. pair_size = pfkey_sockaddr_pair_size(mp->new_family);
  3064. if (!pair_size)
  3065. return -EINVAL;
  3066. size_pol += sizeof(struct sadb_x_ipsecrequest) + pair_size;
  3067. }
  3068. size += sizeof(struct sadb_msg) + size_pol;
  3069. /* alloc buffer */
  3070. skb = alloc_skb(size, GFP_ATOMIC);
  3071. if (skb == NULL)
  3072. return -ENOMEM;
  3073. hdr = skb_put(skb, sizeof(struct sadb_msg));
  3074. hdr->sadb_msg_version = PF_KEY_V2;
  3075. hdr->sadb_msg_type = SADB_X_MIGRATE;
  3076. hdr->sadb_msg_satype = pfkey_proto2satype(m->proto);
  3077. hdr->sadb_msg_len = size / 8;
  3078. hdr->sadb_msg_errno = 0;
  3079. hdr->sadb_msg_reserved = 0;
  3080. hdr->sadb_msg_seq = 0;
  3081. hdr->sadb_msg_pid = 0;
  3082. /* Addresses to be used by KM for negotiation, if ext is available */
  3083. if (k != NULL && (set_sadb_kmaddress(skb, k) < 0))
  3084. goto err;
  3085. /* selector src */
  3086. set_sadb_address(skb, sasize_sel, SADB_EXT_ADDRESS_SRC, sel);
  3087. /* selector dst */
  3088. set_sadb_address(skb, sasize_sel, SADB_EXT_ADDRESS_DST, sel);
  3089. /* policy information */
  3090. pol = skb_put(skb, sizeof(struct sadb_x_policy));
  3091. pol->sadb_x_policy_len = size_pol / 8;
  3092. pol->sadb_x_policy_exttype = SADB_X_EXT_POLICY;
  3093. pol->sadb_x_policy_type = IPSEC_POLICY_IPSEC;
  3094. pol->sadb_x_policy_dir = dir + 1;
  3095. pol->sadb_x_policy_reserved = 0;
  3096. pol->sadb_x_policy_id = 0;
  3097. pol->sadb_x_policy_priority = 0;
  3098. for (i = 0, mp = m; i < num_bundles; i++, mp++) {
  3099. /* old ipsecrequest */
  3100. int mode = pfkey_mode_from_xfrm(mp->mode);
  3101. if (mode < 0)
  3102. goto err;
  3103. if (set_ipsecrequest(skb, mp->proto, mode,
  3104. (mp->reqid ? IPSEC_LEVEL_UNIQUE : IPSEC_LEVEL_REQUIRE),
  3105. mp->reqid, mp->old_family,
  3106. &mp->old_saddr, &mp->old_daddr) < 0)
  3107. goto err;
  3108. /* new ipsecrequest */
  3109. if (set_ipsecrequest(skb, mp->proto, mode,
  3110. (mp->reqid ? IPSEC_LEVEL_UNIQUE : IPSEC_LEVEL_REQUIRE),
  3111. mp->reqid, mp->new_family,
  3112. &mp->new_saddr, &mp->new_daddr) < 0)
  3113. goto err;
  3114. }
  3115. /* broadcast migrate message to sockets */
  3116. pfkey_broadcast(skb, GFP_ATOMIC, BROADCAST_ALL, NULL, &init_net);
  3117. return 0;
  3118. err:
  3119. kfree_skb(skb);
  3120. return -EINVAL;
  3121. }
  3122. #else
  3123. static int pfkey_send_migrate(const struct xfrm_selector *sel, u8 dir, u8 type,
  3124. const struct xfrm_migrate *m, int num_bundles,
  3125. const struct xfrm_kmaddress *k,
  3126. const struct xfrm_encap_tmpl *encap)
  3127. {
  3128. return -ENOPROTOOPT;
  3129. }
  3130. #endif
  3131. static int pfkey_sendmsg(struct socket *sock, struct msghdr *msg, size_t len)
  3132. {
  3133. struct sock *sk = sock->sk;
  3134. struct sk_buff *skb = NULL;
  3135. struct sadb_msg *hdr = NULL;
  3136. int err;
  3137. struct net *net = sock_net(sk);
  3138. err = -EOPNOTSUPP;
  3139. if (msg->msg_flags & MSG_OOB)
  3140. goto out;
  3141. err = -EMSGSIZE;
  3142. if ((unsigned int)len > sk->sk_sndbuf - 32)
  3143. goto out;
  3144. err = -ENOBUFS;
  3145. skb = alloc_skb(len, GFP_KERNEL);
  3146. if (skb == NULL)
  3147. goto out;
  3148. err = -EFAULT;
  3149. if (memcpy_from_msg(skb_put(skb,len), msg, len))
  3150. goto out;
  3151. hdr = pfkey_get_base_msg(skb, &err);
  3152. if (!hdr)
  3153. goto out;
  3154. mutex_lock(&net->xfrm.xfrm_cfg_mutex);
  3155. err = pfkey_process(sk, skb, hdr);
  3156. mutex_unlock(&net->xfrm.xfrm_cfg_mutex);
  3157. out:
  3158. if (err && hdr && pfkey_error(hdr, err, sk) == 0)
  3159. err = 0;
  3160. kfree_skb(skb);
  3161. return err ? : len;
  3162. }
  3163. static int pfkey_recvmsg(struct socket *sock, struct msghdr *msg, size_t len,
  3164. int flags)
  3165. {
  3166. struct sock *sk = sock->sk;
  3167. struct pfkey_sock *pfk = pfkey_sk(sk);
  3168. struct sk_buff *skb;
  3169. int copied, err;
  3170. err = -EINVAL;
  3171. if (flags & ~(MSG_PEEK|MSG_DONTWAIT|MSG_TRUNC|MSG_CMSG_COMPAT))
  3172. goto out;
  3173. skb = skb_recv_datagram(sk, flags, &err);
  3174. if (skb == NULL)
  3175. goto out;
  3176. copied = skb->len;
  3177. if (copied > len) {
  3178. msg->msg_flags |= MSG_TRUNC;
  3179. copied = len;
  3180. }
  3181. skb_reset_transport_header(skb);
  3182. err = skb_copy_datagram_msg(skb, 0, msg, copied);
  3183. if (err)
  3184. goto out_free;
  3185. sock_recv_cmsgs(msg, sk, skb);
  3186. err = (flags & MSG_TRUNC) ? skb->len : copied;
  3187. if (pfk->dump.dump != NULL &&
  3188. 3 * atomic_read(&sk->sk_rmem_alloc) <= sk->sk_rcvbuf)
  3189. pfkey_do_dump(pfk);
  3190. out_free:
  3191. skb_free_datagram(sk, skb);
  3192. out:
  3193. return err;
  3194. }
  3195. static const struct proto_ops pfkey_ops = {
  3196. .family = PF_KEY,
  3197. .owner = THIS_MODULE,
  3198. /* Operations that make no sense on pfkey sockets. */
  3199. .bind = sock_no_bind,
  3200. .connect = sock_no_connect,
  3201. .socketpair = sock_no_socketpair,
  3202. .accept = sock_no_accept,
  3203. .getname = sock_no_getname,
  3204. .ioctl = sock_no_ioctl,
  3205. .listen = sock_no_listen,
  3206. .shutdown = sock_no_shutdown,
  3207. .mmap = sock_no_mmap,
  3208. /* Now the operations that really occur. */
  3209. .release = pfkey_release,
  3210. .poll = datagram_poll,
  3211. .sendmsg = pfkey_sendmsg,
  3212. .recvmsg = pfkey_recvmsg,
  3213. };
  3214. static const struct net_proto_family pfkey_family_ops = {
  3215. .family = PF_KEY,
  3216. .create = pfkey_create,
  3217. .owner = THIS_MODULE,
  3218. };
  3219. #ifdef CONFIG_PROC_FS
  3220. static int pfkey_seq_show(struct seq_file *f, void *v)
  3221. {
  3222. struct sock *s = sk_entry(v);
  3223. if (v == SEQ_START_TOKEN)
  3224. seq_printf(f ,"sk RefCnt Rmem Wmem User Inode\n");
  3225. else
  3226. seq_printf(f, "%pK %-6d %-6u %-6u %-6u %-6lu\n",
  3227. s,
  3228. refcount_read(&s->sk_refcnt),
  3229. sk_rmem_alloc_get(s),
  3230. sk_wmem_alloc_get(s),
  3231. from_kuid_munged(seq_user_ns(f), sk_uid(s)),
  3232. sock_i_ino(s)
  3233. );
  3234. return 0;
  3235. }
  3236. static void *pfkey_seq_start(struct seq_file *f, loff_t *ppos)
  3237. __acquires(rcu)
  3238. {
  3239. struct net *net = seq_file_net(f);
  3240. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  3241. rcu_read_lock();
  3242. return seq_hlist_start_head_rcu(&net_pfkey->table, *ppos);
  3243. }
  3244. static void *pfkey_seq_next(struct seq_file *f, void *v, loff_t *ppos)
  3245. {
  3246. struct net *net = seq_file_net(f);
  3247. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  3248. return seq_hlist_next_rcu(v, &net_pfkey->table, ppos);
  3249. }
  3250. static void pfkey_seq_stop(struct seq_file *f, void *v)
  3251. __releases(rcu)
  3252. {
  3253. rcu_read_unlock();
  3254. }
  3255. static const struct seq_operations pfkey_seq_ops = {
  3256. .start = pfkey_seq_start,
  3257. .next = pfkey_seq_next,
  3258. .stop = pfkey_seq_stop,
  3259. .show = pfkey_seq_show,
  3260. };
  3261. static int __net_init pfkey_init_proc(struct net *net)
  3262. {
  3263. struct proc_dir_entry *e;
  3264. e = proc_create_net("pfkey", 0, net->proc_net, &pfkey_seq_ops,
  3265. sizeof(struct seq_net_private));
  3266. if (e == NULL)
  3267. return -ENOMEM;
  3268. return 0;
  3269. }
  3270. static void __net_exit pfkey_exit_proc(struct net *net)
  3271. {
  3272. remove_proc_entry("pfkey", net->proc_net);
  3273. }
  3274. #else
  3275. static inline int pfkey_init_proc(struct net *net)
  3276. {
  3277. return 0;
  3278. }
  3279. static inline void pfkey_exit_proc(struct net *net)
  3280. {
  3281. }
  3282. #endif
  3283. static struct xfrm_mgr pfkeyv2_mgr =
  3284. {
  3285. .notify = pfkey_send_notify,
  3286. .acquire = pfkey_send_acquire,
  3287. .compile_policy = pfkey_compile_policy,
  3288. .new_mapping = pfkey_send_new_mapping,
  3289. .notify_policy = pfkey_send_policy_notify,
  3290. .migrate = pfkey_send_migrate,
  3291. .is_alive = pfkey_is_alive,
  3292. };
  3293. static int __net_init pfkey_net_init(struct net *net)
  3294. {
  3295. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  3296. int rv;
  3297. INIT_HLIST_HEAD(&net_pfkey->table);
  3298. atomic_set(&net_pfkey->socks_nr, 0);
  3299. rv = pfkey_init_proc(net);
  3300. return rv;
  3301. }
  3302. static void __net_exit pfkey_net_exit(struct net *net)
  3303. {
  3304. struct netns_pfkey *net_pfkey = net_generic(net, pfkey_net_id);
  3305. pfkey_exit_proc(net);
  3306. WARN_ON(!hlist_empty(&net_pfkey->table));
  3307. }
  3308. static struct pernet_operations pfkey_net_ops = {
  3309. .init = pfkey_net_init,
  3310. .exit = pfkey_net_exit,
  3311. .id = &pfkey_net_id,
  3312. .size = sizeof(struct netns_pfkey),
  3313. };
  3314. static void __exit ipsec_pfkey_exit(void)
  3315. {
  3316. xfrm_unregister_km(&pfkeyv2_mgr);
  3317. sock_unregister(PF_KEY);
  3318. unregister_pernet_subsys(&pfkey_net_ops);
  3319. proto_unregister(&key_proto);
  3320. }
  3321. static int __init ipsec_pfkey_init(void)
  3322. {
  3323. int err = proto_register(&key_proto, 0);
  3324. pr_warn_once("PFKEY is deprecated and scheduled to be removed in 2027, "
  3325. "please contact the netdev mailing list\n");
  3326. if (err != 0)
  3327. goto out;
  3328. err = register_pernet_subsys(&pfkey_net_ops);
  3329. if (err != 0)
  3330. goto out_unregister_key_proto;
  3331. err = sock_register(&pfkey_family_ops);
  3332. if (err != 0)
  3333. goto out_unregister_pernet;
  3334. xfrm_register_km(&pfkeyv2_mgr);
  3335. out:
  3336. return err;
  3337. out_unregister_pernet:
  3338. unregister_pernet_subsys(&pfkey_net_ops);
  3339. out_unregister_key_proto:
  3340. proto_unregister(&key_proto);
  3341. goto out;
  3342. }
  3343. module_init(ipsec_pfkey_init);
  3344. module_exit(ipsec_pfkey_exit);
  3345. MODULE_DESCRIPTION("PF_KEY socket helpers");
  3346. MODULE_LICENSE("GPL");
  3347. MODULE_ALIAS_NETPROTO(PF_KEY);