keysock.c revision 1.62.2.1
1 1.62.2.1 pgoyette /* $NetBSD: keysock.c,v 1.62.2.1 2018/03/22 01:44:51 pgoyette Exp $ */ 2 1.1 jonathan /* $FreeBSD: src/sys/netipsec/keysock.c,v 1.3.2.1 2003/01/24 05:11:36 sam Exp $ */ 3 1.1 jonathan /* $KAME: keysock.c,v 1.25 2001/08/13 20:07:41 itojun Exp $ */ 4 1.1 jonathan 5 1.1 jonathan /* 6 1.1 jonathan * Copyright (C) 1995, 1996, 1997, and 1998 WIDE Project. 7 1.1 jonathan * All rights reserved. 8 1.1 jonathan * 9 1.1 jonathan * Redistribution and use in source and binary forms, with or without 10 1.1 jonathan * modification, are permitted provided that the following conditions 11 1.1 jonathan * are met: 12 1.1 jonathan * 1. Redistributions of source code must retain the above copyright 13 1.1 jonathan * notice, this list of conditions and the following disclaimer. 14 1.1 jonathan * 2. Redistributions in binary form must reproduce the above copyright 15 1.1 jonathan * notice, this list of conditions and the following disclaimer in the 16 1.1 jonathan * documentation and/or other materials provided with the distribution. 17 1.1 jonathan * 3. Neither the name of the project nor the names of its contributors 18 1.1 jonathan * may be used to endorse or promote products derived from this software 19 1.1 jonathan * without specific prior written permission. 20 1.1 jonathan * 21 1.1 jonathan * THIS SOFTWARE IS PROVIDED BY THE PROJECT AND CONTRIBUTORS ``AS IS'' AND 22 1.1 jonathan * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 23 1.1 jonathan * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 24 1.1 jonathan * ARE DISCLAIMED. IN NO EVENT SHALL THE PROJECT OR CONTRIBUTORS BE LIABLE 25 1.1 jonathan * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 26 1.1 jonathan * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 27 1.1 jonathan * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 28 1.1 jonathan * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 29 1.1 jonathan * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 30 1.1 jonathan * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 31 1.1 jonathan * SUCH DAMAGE. 32 1.1 jonathan */ 33 1.1 jonathan 34 1.1 jonathan #include <sys/cdefs.h> 35 1.62.2.1 pgoyette __KERNEL_RCSID(0, "$NetBSD: keysock.c,v 1.62.2.1 2018/03/22 01:44:51 pgoyette Exp $"); 36 1.1 jonathan 37 1.1 jonathan /* This code has derived from sys/net/rtsock.c on FreeBSD2.2.5 */ 38 1.1 jonathan 39 1.1 jonathan #include <sys/types.h> 40 1.1 jonathan #include <sys/param.h> 41 1.1 jonathan #include <sys/domain.h> 42 1.1 jonathan #include <sys/errno.h> 43 1.1 jonathan #include <sys/kernel.h> 44 1.23 rmind #include <sys/kmem.h> 45 1.1 jonathan #include <sys/mbuf.h> 46 1.1 jonathan #include <sys/protosw.h> 47 1.1 jonathan #include <sys/signalvar.h> 48 1.1 jonathan #include <sys/socket.h> 49 1.1 jonathan #include <sys/socketvar.h> 50 1.1 jonathan #include <sys/sysctl.h> 51 1.1 jonathan #include <sys/systm.h> 52 1.55 ozaki #include <sys/cpu.h> 53 1.57 ozaki #include <sys/syslog.h> 54 1.1 jonathan 55 1.1 jonathan #include <net/raw_cb.h> 56 1.1 jonathan #include <net/route.h> 57 1.1 jonathan 58 1.1 jonathan #include <net/pfkeyv2.h> 59 1.1 jonathan #include <netipsec/key.h> 60 1.1 jonathan #include <netipsec/keysock.h> 61 1.1 jonathan #include <netipsec/key_debug.h> 62 1.1 jonathan 63 1.15 thorpej #include <netipsec/ipsec_private.h> 64 1.1 jonathan 65 1.1 jonathan struct key_cb { 66 1.1 jonathan int key_count; 67 1.1 jonathan int any_count; 68 1.1 jonathan }; 69 1.1 jonathan static struct key_cb key_cb; 70 1.1 jonathan 71 1.11 christos static struct sockaddr key_dst = { 72 1.11 christos .sa_len = 2, 73 1.11 christos .sa_family = PF_KEY, 74 1.11 christos }; 75 1.11 christos static struct sockaddr key_src = { 76 1.11 christos .sa_len = 2, 77 1.11 christos .sa_family = PF_KEY, 78 1.11 christos }; 79 1.1 jonathan 80 1.49 riastrad static const struct protosw keysw[]; 81 1.5 jonathan 82 1.17 dsl static int key_sendup0(struct rawcb *, struct mbuf *, int, int); 83 1.1 jonathan 84 1.19 joerg int key_registered_sb_max = (2048 * MHLEN); /* XXX arbitrary */ 85 1.5 jonathan 86 1.59 ozaki static kmutex_t *key_so_mtx; 87 1.61 ozaki static struct rawcbhead key_rawcb; 88 1.59 ozaki 89 1.59 ozaki void 90 1.59 ozaki key_init_so(void) 91 1.59 ozaki { 92 1.59 ozaki 93 1.59 ozaki key_so_mtx = mutex_obj_alloc(MUTEX_DEFAULT, IPL_NONE); 94 1.59 ozaki } 95 1.59 ozaki 96 1.61 ozaki static void 97 1.61 ozaki key_pr_init(void) 98 1.61 ozaki { 99 1.61 ozaki 100 1.61 ozaki LIST_INIT(&key_rawcb); 101 1.61 ozaki } 102 1.61 ozaki 103 1.1 jonathan /* 104 1.1 jonathan * key_output() 105 1.1 jonathan */ 106 1.49 riastrad static int 107 1.49 riastrad key_output(struct mbuf *m, struct socket *so) 108 1.1 jonathan { 109 1.1 jonathan struct sadb_msg *msg; 110 1.1 jonathan int len, error = 0; 111 1.1 jonathan int s; 112 1.1 jonathan 113 1.53 ozaki KASSERT(m != NULL); 114 1.1 jonathan 115 1.15 thorpej { 116 1.15 thorpej uint64_t *ps = PFKEY_STAT_GETREF(); 117 1.15 thorpej ps[PFKEY_STAT_OUT_TOTAL]++; 118 1.15 thorpej ps[PFKEY_STAT_OUT_BYTES] += m->m_pkthdr.len; 119 1.15 thorpej PFKEY_STAT_PUTREF(); 120 1.15 thorpej } 121 1.1 jonathan 122 1.1 jonathan len = m->m_pkthdr.len; 123 1.1 jonathan if (len < sizeof(struct sadb_msg)) { 124 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_OUT_TOOSHORT); 125 1.1 jonathan error = EINVAL; 126 1.1 jonathan goto end; 127 1.1 jonathan } 128 1.1 jonathan 129 1.1 jonathan if (m->m_len < sizeof(struct sadb_msg)) { 130 1.1 jonathan if ((m = m_pullup(m, sizeof(struct sadb_msg))) == 0) { 131 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_OUT_NOMEM); 132 1.1 jonathan error = ENOBUFS; 133 1.1 jonathan goto end; 134 1.1 jonathan } 135 1.1 jonathan } 136 1.1 jonathan 137 1.53 ozaki KASSERT((m->m_flags & M_PKTHDR) != 0); 138 1.1 jonathan 139 1.52 ozaki if (KEYDEBUG_ON(KEYDEBUG_KEY_DUMP)) 140 1.62 christos kdebug_mbuf(__func__, m); 141 1.1 jonathan 142 1.1 jonathan msg = mtod(m, struct sadb_msg *); 143 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_OUT_MSGTYPE + msg->sadb_msg_type); 144 1.1 jonathan if (len != PFKEY_UNUNIT64(msg->sadb_msg_len)) { 145 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_OUT_INVLEN); 146 1.1 jonathan error = EINVAL; 147 1.1 jonathan goto end; 148 1.1 jonathan } 149 1.1 jonathan 150 1.1 jonathan /*XXX giant lock*/ 151 1.1 jonathan s = splsoftnet(); 152 1.1 jonathan error = key_parse(m, so); 153 1.1 jonathan m = NULL; 154 1.1 jonathan splx(s); 155 1.1 jonathan end: 156 1.1 jonathan if (m) 157 1.1 jonathan m_freem(m); 158 1.1 jonathan return error; 159 1.1 jonathan } 160 1.1 jonathan 161 1.1 jonathan /* 162 1.1 jonathan * send message to the socket. 163 1.1 jonathan */ 164 1.1 jonathan static int 165 1.11 christos key_sendup0( 166 1.11 christos struct rawcb *rp, 167 1.11 christos struct mbuf *m, 168 1.11 christos int promisc, 169 1.11 christos int sbprio 170 1.11 christos ) 171 1.1 jonathan { 172 1.1 jonathan int error; 173 1.5 jonathan int ok; 174 1.1 jonathan 175 1.1 jonathan if (promisc) { 176 1.1 jonathan struct sadb_msg *pmsg; 177 1.1 jonathan 178 1.1 jonathan M_PREPEND(m, sizeof(struct sadb_msg), M_DONTWAIT); 179 1.1 jonathan if (m && m->m_len < sizeof(struct sadb_msg)) 180 1.1 jonathan m = m_pullup(m, sizeof(struct sadb_msg)); 181 1.1 jonathan if (!m) { 182 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_NOMEM); 183 1.1 jonathan return ENOBUFS; 184 1.1 jonathan } 185 1.1 jonathan m->m_pkthdr.len += sizeof(*pmsg); 186 1.1 jonathan 187 1.1 jonathan pmsg = mtod(m, struct sadb_msg *); 188 1.18 cegger memset(pmsg, 0, sizeof(*pmsg)); 189 1.1 jonathan pmsg->sadb_msg_version = PF_KEY_V2; 190 1.1 jonathan pmsg->sadb_msg_type = SADB_X_PROMISC; 191 1.1 jonathan pmsg->sadb_msg_len = PFKEY_UNIT64(m->m_pkthdr.len); 192 1.1 jonathan /* pid and seq? */ 193 1.1 jonathan 194 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_MSGTYPE + pmsg->sadb_msg_type); 195 1.1 jonathan } 196 1.1 jonathan 197 1.5 jonathan if (sbprio == 0) 198 1.5 jonathan ok = sbappendaddr(&rp->rcb_socket->so_rcv, 199 1.5 jonathan (struct sockaddr *)&key_src, m, NULL); 200 1.5 jonathan else 201 1.5 jonathan ok = sbappendaddrchain(&rp->rcb_socket->so_rcv, 202 1.5 jonathan (struct sockaddr *)&key_src, m, sbprio); 203 1.5 jonathan 204 1.56 ozaki if (!ok) { 205 1.57 ozaki log(LOG_WARNING, 206 1.57 ozaki "%s: couldn't send PF_KEY message to the socket\n", 207 1.57 ozaki __func__); 208 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_NOMEM); 209 1.1 jonathan m_freem(m); 210 1.62.2.1 pgoyette soroverflow(rp->rcb_socket); 211 1.1 jonathan error = ENOBUFS; 212 1.62.2.1 pgoyette } else { 213 1.62.2.1 pgoyette sorwakeup(rp->rcb_socket); 214 1.1 jonathan error = 0; 215 1.62.2.1 pgoyette } 216 1.1 jonathan return error; 217 1.1 jonathan } 218 1.1 jonathan 219 1.1 jonathan /* XXX this interface should be obsoleted. */ 220 1.1 jonathan int 221 1.14 degroote key_sendup(struct socket *so, struct sadb_msg *msg, u_int len, 222 1.14 degroote int target) /*target of the resulting message*/ 223 1.1 jonathan { 224 1.1 jonathan struct mbuf *m, *n, *mprev; 225 1.1 jonathan int tlen; 226 1.1 jonathan 227 1.53 ozaki KASSERT(so != NULL); 228 1.53 ozaki KASSERT(msg != NULL); 229 1.1 jonathan 230 1.52 ozaki if (KEYDEBUG_ON(KEYDEBUG_KEY_DUMP)) { 231 1.1 jonathan printf("key_sendup: \n"); 232 1.52 ozaki kdebug_sadb(msg); 233 1.52 ozaki } 234 1.1 jonathan 235 1.1 jonathan /* 236 1.1 jonathan * we increment statistics here, just in case we have ENOBUFS 237 1.1 jonathan * in this function. 238 1.1 jonathan */ 239 1.15 thorpej { 240 1.15 thorpej uint64_t *ps = PFKEY_STAT_GETREF(); 241 1.15 thorpej ps[PFKEY_STAT_IN_TOTAL]++; 242 1.15 thorpej ps[PFKEY_STAT_IN_BYTES] += len; 243 1.15 thorpej ps[PFKEY_STAT_IN_MSGTYPE + msg->sadb_msg_type]++; 244 1.15 thorpej PFKEY_STAT_PUTREF(); 245 1.15 thorpej } 246 1.1 jonathan 247 1.1 jonathan /* 248 1.1 jonathan * Get mbuf chain whenever possible (not clusters), 249 1.1 jonathan * to save socket buffer. We'll be generating many SADB_ACQUIRE 250 1.1 jonathan * messages to listening key sockets. If we simply allocate clusters, 251 1.1 jonathan * sbappendaddr() will raise ENOBUFS due to too little sbspace(). 252 1.1 jonathan * sbspace() computes # of actual data bytes AND mbuf region. 253 1.1 jonathan * 254 1.1 jonathan * TODO: SADB_ACQUIRE filters should be implemented. 255 1.1 jonathan */ 256 1.1 jonathan tlen = len; 257 1.1 jonathan m = mprev = NULL; 258 1.1 jonathan while (tlen > 0) { 259 1.27 christos int mlen; 260 1.1 jonathan if (tlen == len) { 261 1.1 jonathan MGETHDR(n, M_DONTWAIT, MT_DATA); 262 1.27 christos mlen = MHLEN; 263 1.1 jonathan } else { 264 1.1 jonathan MGET(n, M_DONTWAIT, MT_DATA); 265 1.27 christos mlen = MLEN; 266 1.1 jonathan } 267 1.1 jonathan if (!n) { 268 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_NOMEM); 269 1.1 jonathan return ENOBUFS; 270 1.1 jonathan } 271 1.27 christos n->m_len = mlen; 272 1.1 jonathan if (tlen >= MCLBYTES) { /*XXX better threshold? */ 273 1.1 jonathan MCLGET(n, M_DONTWAIT); 274 1.1 jonathan if ((n->m_flags & M_EXT) == 0) { 275 1.1 jonathan m_free(n); 276 1.1 jonathan m_freem(m); 277 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_NOMEM); 278 1.1 jonathan return ENOBUFS; 279 1.1 jonathan } 280 1.1 jonathan n->m_len = MCLBYTES; 281 1.1 jonathan } 282 1.1 jonathan 283 1.1 jonathan if (tlen < n->m_len) 284 1.1 jonathan n->m_len = tlen; 285 1.1 jonathan n->m_next = NULL; 286 1.1 jonathan if (m == NULL) 287 1.1 jonathan m = mprev = n; 288 1.1 jonathan else { 289 1.1 jonathan mprev->m_next = n; 290 1.1 jonathan mprev = n; 291 1.1 jonathan } 292 1.1 jonathan tlen -= n->m_len; 293 1.1 jonathan n = NULL; 294 1.1 jonathan } 295 1.1 jonathan m->m_pkthdr.len = len; 296 1.50 ozaki m_reset_rcvif(m); 297 1.13 degroote m_copyback(m, 0, len, msg); 298 1.1 jonathan 299 1.1 jonathan /* avoid duplicated statistics */ 300 1.15 thorpej { 301 1.15 thorpej uint64_t *ps = PFKEY_STAT_GETREF(); 302 1.15 thorpej ps[PFKEY_STAT_IN_TOTAL]--; 303 1.15 thorpej ps[PFKEY_STAT_IN_BYTES] -= len; 304 1.15 thorpej ps[PFKEY_STAT_IN_MSGTYPE + msg->sadb_msg_type]--; 305 1.15 thorpej PFKEY_STAT_PUTREF(); 306 1.15 thorpej } 307 1.1 jonathan 308 1.1 jonathan return key_sendup_mbuf(so, m, target); 309 1.1 jonathan } 310 1.1 jonathan 311 1.1 jonathan /* so can be NULL if target != KEY_SENDUP_ONE */ 312 1.60 ozaki static int 313 1.60 ozaki _key_sendup_mbuf(struct socket *so, struct mbuf *m, 314 1.14 degroote int target/*, sbprio */) 315 1.1 jonathan { 316 1.1 jonathan struct mbuf *n; 317 1.1 jonathan struct keycb *kp; 318 1.1 jonathan int sendup; 319 1.1 jonathan struct rawcb *rp; 320 1.1 jonathan int error = 0; 321 1.5 jonathan int sbprio = 0; /* XXX should be a parameter */ 322 1.1 jonathan 323 1.53 ozaki KASSERT(m != NULL); 324 1.54 ozaki KASSERT(so != NULL || target != KEY_SENDUP_ONE); 325 1.7 perry 326 1.5 jonathan /* 327 1.5 jonathan * RFC 2367 says ACQUIRE and other kernel-generated messages 328 1.5 jonathan * are special. We treat all KEY_SENDUP_REGISTERED messages 329 1.5 jonathan * as special, delivering them to all registered sockets 330 1.5 jonathan * even if the socket is at or above its so->so_rcv.sb_max limits. 331 1.5 jonathan * The only constraint is that the so_rcv data fall below 332 1.5 jonathan * key_registered_sb_max. 333 1.5 jonathan * Doing that check here avoids reworking every key_sendup_mbuf() 334 1.5 jonathan * in the short term. . The rework will be done after a technical 335 1.5 jonathan * conensus that this approach is appropriate. 336 1.5 jonathan */ 337 1.5 jonathan if (target == KEY_SENDUP_REGISTERED) { 338 1.5 jonathan sbprio = SB_PRIO_BESTEFFORT; 339 1.5 jonathan } 340 1.1 jonathan 341 1.15 thorpej { 342 1.15 thorpej uint64_t *ps = PFKEY_STAT_GETREF(); 343 1.15 thorpej ps[PFKEY_STAT_IN_TOTAL]++; 344 1.15 thorpej ps[PFKEY_STAT_IN_BYTES] += m->m_pkthdr.len; 345 1.15 thorpej PFKEY_STAT_PUTREF(); 346 1.15 thorpej } 347 1.1 jonathan if (m->m_len < sizeof(struct sadb_msg)) { 348 1.1 jonathan #if 1 349 1.1 jonathan m = m_pullup(m, sizeof(struct sadb_msg)); 350 1.1 jonathan if (m == NULL) { 351 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_NOMEM); 352 1.1 jonathan return ENOBUFS; 353 1.1 jonathan } 354 1.1 jonathan #else 355 1.1 jonathan /* don't bother pulling it up just for stats */ 356 1.1 jonathan #endif 357 1.1 jonathan } 358 1.1 jonathan if (m->m_len >= sizeof(struct sadb_msg)) { 359 1.1 jonathan struct sadb_msg *msg; 360 1.1 jonathan msg = mtod(m, struct sadb_msg *); 361 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_MSGTYPE + msg->sadb_msg_type); 362 1.1 jonathan } 363 1.1 jonathan 364 1.61 ozaki LIST_FOREACH(rp, &key_rawcb, rcb_list) 365 1.1 jonathan { 366 1.5 jonathan struct socket * kso = rp->rcb_socket; 367 1.1 jonathan if (rp->rcb_proto.sp_family != PF_KEY) 368 1.1 jonathan continue; 369 1.1 jonathan if (rp->rcb_proto.sp_protocol 370 1.1 jonathan && rp->rcb_proto.sp_protocol != PF_KEY_V2) { 371 1.1 jonathan continue; 372 1.1 jonathan } 373 1.1 jonathan 374 1.1 jonathan kp = (struct keycb *)rp; 375 1.1 jonathan 376 1.1 jonathan /* 377 1.1 jonathan * If you are in promiscuous mode, and when you get broadcasted 378 1.1 jonathan * reply, you'll get two PF_KEY messages. 379 1.1 jonathan * (based on pf_key (at) inner.net message on 14 Oct 1998) 380 1.1 jonathan */ 381 1.1 jonathan if (((struct keycb *)rp)->kp_promisc) { 382 1.1 jonathan if ((n = m_copy(m, 0, (int)M_COPYALL)) != NULL) { 383 1.5 jonathan (void)key_sendup0(rp, n, 1, 0); 384 1.1 jonathan n = NULL; 385 1.1 jonathan } 386 1.1 jonathan } 387 1.1 jonathan 388 1.1 jonathan /* the exact target will be processed later */ 389 1.1 jonathan if (so && sotorawcb(so) == rp) 390 1.1 jonathan continue; 391 1.1 jonathan 392 1.1 jonathan sendup = 0; 393 1.1 jonathan switch (target) { 394 1.1 jonathan case KEY_SENDUP_ONE: 395 1.1 jonathan /* the statement has no effect */ 396 1.1 jonathan if (so && sotorawcb(so) == rp) 397 1.1 jonathan sendup++; 398 1.1 jonathan break; 399 1.1 jonathan case KEY_SENDUP_ALL: 400 1.1 jonathan sendup++; 401 1.1 jonathan break; 402 1.1 jonathan case KEY_SENDUP_REGISTERED: 403 1.5 jonathan if (kp->kp_registered) { 404 1.5 jonathan if (kso->so_rcv.sb_cc <= key_registered_sb_max) 405 1.5 jonathan sendup++; 406 1.5 jonathan else 407 1.5 jonathan printf("keysock: " 408 1.5 jonathan "registered sendup dropped, " 409 1.5 jonathan "sb_cc %ld max %d\n", 410 1.5 jonathan kso->so_rcv.sb_cc, 411 1.5 jonathan key_registered_sb_max); 412 1.5 jonathan } 413 1.1 jonathan break; 414 1.1 jonathan } 415 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_MSGTARGET + target); 416 1.1 jonathan 417 1.1 jonathan if (!sendup) 418 1.1 jonathan continue; 419 1.1 jonathan 420 1.1 jonathan if ((n = m_copy(m, 0, (int)M_COPYALL)) == NULL) { 421 1.1 jonathan m_freem(m); 422 1.15 thorpej PFKEY_STATINC(PFKEY_STAT_IN_NOMEM); 423 1.1 jonathan return ENOBUFS; 424 1.1 jonathan } 425 1.1 jonathan 426 1.5 jonathan if ((error = key_sendup0(rp, n, 0, 0)) != 0) { 427 1.1 jonathan m_freem(m); 428 1.1 jonathan return error; 429 1.1 jonathan } 430 1.1 jonathan 431 1.1 jonathan n = NULL; 432 1.1 jonathan } 433 1.1 jonathan 434 1.5 jonathan /* The 'later' time for processing the exact target has arrived */ 435 1.1 jonathan if (so) { 436 1.5 jonathan error = key_sendup0(sotorawcb(so), m, 0, sbprio); 437 1.1 jonathan m = NULL; 438 1.1 jonathan } else { 439 1.1 jonathan error = 0; 440 1.1 jonathan m_freem(m); 441 1.1 jonathan } 442 1.1 jonathan return error; 443 1.1 jonathan } 444 1.1 jonathan 445 1.60 ozaki int 446 1.60 ozaki key_sendup_mbuf(struct socket *so, struct mbuf *m, 447 1.60 ozaki int target/*, sbprio */) 448 1.60 ozaki { 449 1.60 ozaki int error; 450 1.60 ozaki 451 1.60 ozaki if (so == NULL) 452 1.60 ozaki mutex_enter(key_so_mtx); 453 1.60 ozaki else 454 1.60 ozaki KASSERT(solocked(so)); 455 1.60 ozaki 456 1.60 ozaki error = _key_sendup_mbuf(so, m, target); 457 1.60 ozaki 458 1.60 ozaki if (so == NULL) 459 1.60 ozaki mutex_exit(key_so_mtx); 460 1.60 ozaki return error; 461 1.60 ozaki } 462 1.60 ozaki 463 1.23 rmind static int 464 1.23 rmind key_attach(struct socket *so, int proto) 465 1.23 rmind { 466 1.23 rmind struct keycb *kp; 467 1.23 rmind int s, error; 468 1.23 rmind 469 1.23 rmind KASSERT(sotorawcb(so) == NULL); 470 1.23 rmind kp = kmem_zalloc(sizeof(*kp), KM_SLEEP); 471 1.25 rmind kp->kp_raw.rcb_len = sizeof(*kp); 472 1.23 rmind so->so_pcb = kp; 473 1.23 rmind 474 1.23 rmind s = splsoftnet(); 475 1.59 ozaki 476 1.59 ozaki KASSERT(so->so_lock == NULL); 477 1.59 ozaki mutex_obj_hold(key_so_mtx); 478 1.59 ozaki so->so_lock = key_so_mtx; 479 1.59 ozaki solock(so); 480 1.59 ozaki 481 1.61 ozaki error = raw_attach(so, proto, &key_rawcb); 482 1.23 rmind if (error) { 483 1.23 rmind PFKEY_STATINC(PFKEY_STAT_SOCKERR); 484 1.23 rmind kmem_free(kp, sizeof(*kp)); 485 1.23 rmind so->so_pcb = NULL; 486 1.23 rmind goto out; 487 1.23 rmind } 488 1.23 rmind 489 1.23 rmind kp->kp_promisc = kp->kp_registered = 0; 490 1.23 rmind 491 1.23 rmind if (kp->kp_raw.rcb_proto.sp_protocol == PF_KEY) /* XXX: AF_KEY */ 492 1.23 rmind key_cb.key_count++; 493 1.23 rmind key_cb.any_count++; 494 1.23 rmind kp->kp_raw.rcb_laddr = &key_src; 495 1.23 rmind kp->kp_raw.rcb_faddr = &key_dst; 496 1.23 rmind soisconnected(so); 497 1.23 rmind so->so_options |= SO_USELOOPBACK; 498 1.23 rmind out: 499 1.23 rmind KASSERT(solocked(so)); 500 1.23 rmind splx(s); 501 1.23 rmind return error; 502 1.23 rmind } 503 1.23 rmind 504 1.23 rmind static void 505 1.23 rmind key_detach(struct socket *so) 506 1.23 rmind { 507 1.23 rmind struct keycb *kp = (struct keycb *)sotorawcb(so); 508 1.23 rmind int s; 509 1.23 rmind 510 1.55 ozaki KASSERT(!cpu_softintr_p()); 511 1.23 rmind KASSERT(solocked(so)); 512 1.23 rmind KASSERT(kp != NULL); 513 1.23 rmind 514 1.23 rmind s = splsoftnet(); 515 1.23 rmind if (kp->kp_raw.rcb_proto.sp_protocol == PF_KEY) /* XXX: AF_KEY */ 516 1.23 rmind key_cb.key_count--; 517 1.23 rmind key_cb.any_count--; 518 1.23 rmind key_freereg(so); 519 1.23 rmind raw_detach(so); 520 1.23 rmind splx(s); 521 1.23 rmind } 522 1.23 rmind 523 1.28 rtr static int 524 1.46 rtr key_accept(struct socket *so, struct sockaddr *nam) 525 1.35 rtr { 526 1.35 rtr KASSERT(solocked(so)); 527 1.35 rtr 528 1.35 rtr panic("key_accept"); 529 1.39 rtr 530 1.35 rtr return EOPNOTSUPP; 531 1.35 rtr } 532 1.35 rtr 533 1.35 rtr static int 534 1.45 rtr key_bind(struct socket *so, struct sockaddr *nam, struct lwp *l) 535 1.37 rtr { 536 1.37 rtr KASSERT(solocked(so)); 537 1.37 rtr 538 1.37 rtr return EOPNOTSUPP; 539 1.37 rtr } 540 1.37 rtr 541 1.37 rtr static int 542 1.40 rtr key_listen(struct socket *so, struct lwp *l) 543 1.37 rtr { 544 1.37 rtr KASSERT(solocked(so)); 545 1.37 rtr 546 1.37 rtr return EOPNOTSUPP; 547 1.37 rtr } 548 1.37 rtr 549 1.37 rtr static int 550 1.48 rtr key_connect(struct socket *so, struct sockaddr *nam, struct lwp *l) 551 1.38 rtr { 552 1.38 rtr KASSERT(solocked(so)); 553 1.38 rtr 554 1.38 rtr return EOPNOTSUPP; 555 1.38 rtr } 556 1.38 rtr 557 1.38 rtr static int 558 1.43 rtr key_connect2(struct socket *so, struct socket *so2) 559 1.43 rtr { 560 1.43 rtr KASSERT(solocked(so)); 561 1.43 rtr 562 1.43 rtr return EOPNOTSUPP; 563 1.43 rtr } 564 1.43 rtr 565 1.43 rtr static int 566 1.39 rtr key_disconnect(struct socket *so) 567 1.39 rtr { 568 1.39 rtr struct rawcb *rp = sotorawcb(so); 569 1.39 rtr int s; 570 1.39 rtr 571 1.39 rtr KASSERT(solocked(so)); 572 1.39 rtr KASSERT(rp != NULL); 573 1.39 rtr 574 1.39 rtr s = splsoftnet(); 575 1.39 rtr soisdisconnected(so); 576 1.39 rtr raw_disconnect(rp); 577 1.39 rtr splx(s); 578 1.39 rtr 579 1.39 rtr return 0; 580 1.39 rtr } 581 1.39 rtr 582 1.39 rtr static int 583 1.39 rtr key_shutdown(struct socket *so) 584 1.39 rtr { 585 1.39 rtr int s; 586 1.39 rtr 587 1.39 rtr KASSERT(solocked(so)); 588 1.39 rtr 589 1.39 rtr /* 590 1.39 rtr * Mark the connection as being incapable of further input. 591 1.39 rtr */ 592 1.39 rtr s = splsoftnet(); 593 1.39 rtr socantsendmore(so); 594 1.39 rtr splx(s); 595 1.39 rtr 596 1.39 rtr return 0; 597 1.39 rtr } 598 1.39 rtr 599 1.39 rtr static int 600 1.39 rtr key_abort(struct socket *so) 601 1.39 rtr { 602 1.39 rtr KASSERT(solocked(so)); 603 1.39 rtr 604 1.39 rtr panic("key_abort"); 605 1.39 rtr 606 1.39 rtr return EOPNOTSUPP; 607 1.39 rtr } 608 1.39 rtr 609 1.39 rtr static int 610 1.29 rtr key_ioctl(struct socket *so, u_long cmd, void *nam, struct ifnet *ifp) 611 1.28 rtr { 612 1.28 rtr return EOPNOTSUPP; 613 1.28 rtr } 614 1.28 rtr 615 1.30 rtr static int 616 1.30 rtr key_stat(struct socket *so, struct stat *ub) 617 1.30 rtr { 618 1.33 rtr KASSERT(solocked(so)); 619 1.33 rtr 620 1.32 rtr return 0; 621 1.30 rtr } 622 1.30 rtr 623 1.34 rtr static int 624 1.46 rtr key_peeraddr(struct socket *so, struct sockaddr *nam) 625 1.34 rtr { 626 1.34 rtr struct rawcb *rp = sotorawcb(so); 627 1.34 rtr 628 1.34 rtr KASSERT(solocked(so)); 629 1.34 rtr KASSERT(rp != NULL); 630 1.34 rtr KASSERT(nam != NULL); 631 1.34 rtr 632 1.34 rtr if (rp->rcb_faddr == NULL) 633 1.34 rtr return ENOTCONN; 634 1.34 rtr 635 1.34 rtr raw_setpeeraddr(rp, nam); 636 1.34 rtr return 0; 637 1.34 rtr } 638 1.34 rtr 639 1.34 rtr static int 640 1.46 rtr key_sockaddr(struct socket *so, struct sockaddr *nam) 641 1.34 rtr { 642 1.34 rtr struct rawcb *rp = sotorawcb(so); 643 1.34 rtr 644 1.34 rtr KASSERT(solocked(so)); 645 1.34 rtr KASSERT(rp != NULL); 646 1.34 rtr KASSERT(nam != NULL); 647 1.34 rtr 648 1.34 rtr if (rp->rcb_faddr == NULL) 649 1.34 rtr return ENOTCONN; 650 1.34 rtr 651 1.34 rtr raw_setsockaddr(rp, nam); 652 1.34 rtr return 0; 653 1.34 rtr } 654 1.34 rtr 655 1.36 rtr static int 656 1.42 rtr key_rcvd(struct socket *so, int flags, struct lwp *l) 657 1.42 rtr { 658 1.42 rtr KASSERT(solocked(so)); 659 1.42 rtr 660 1.42 rtr return EOPNOTSUPP; 661 1.42 rtr } 662 1.42 rtr 663 1.42 rtr static int 664 1.36 rtr key_recvoob(struct socket *so, struct mbuf *m, int flags) 665 1.36 rtr { 666 1.36 rtr KASSERT(solocked(so)); 667 1.36 rtr 668 1.36 rtr return EOPNOTSUPP; 669 1.36 rtr } 670 1.36 rtr 671 1.36 rtr static int 672 1.48 rtr key_send(struct socket *so, struct mbuf *m, struct sockaddr *nam, 673 1.41 rtr struct mbuf *control, struct lwp *l) 674 1.41 rtr { 675 1.41 rtr int error = 0; 676 1.41 rtr int s; 677 1.41 rtr 678 1.41 rtr KASSERT(solocked(so)); 679 1.49 riastrad KASSERT(so->so_proto == &keysw[0]); 680 1.41 rtr 681 1.41 rtr s = splsoftnet(); 682 1.49 riastrad error = raw_send(so, m, nam, control, l, &key_output); 683 1.41 rtr splx(s); 684 1.41 rtr 685 1.41 rtr return error; 686 1.41 rtr } 687 1.41 rtr 688 1.41 rtr static int 689 1.36 rtr key_sendoob(struct socket *so, struct mbuf *m, struct mbuf *control) 690 1.36 rtr { 691 1.36 rtr KASSERT(solocked(so)); 692 1.36 rtr 693 1.36 rtr m_freem(m); 694 1.36 rtr m_freem(control); 695 1.36 rtr 696 1.36 rtr return EOPNOTSUPP; 697 1.36 rtr } 698 1.36 rtr 699 1.43 rtr static int 700 1.43 rtr key_purgeif(struct socket *so, struct ifnet *ifa) 701 1.43 rtr { 702 1.43 rtr 703 1.43 rtr panic("key_purgeif"); 704 1.43 rtr 705 1.43 rtr return EOPNOTSUPP; 706 1.43 rtr } 707 1.43 rtr 708 1.1 jonathan /* 709 1.1 jonathan * Definitions of protocols supported in the KEY domain. 710 1.1 jonathan */ 711 1.1 jonathan 712 1.6 matt DOMAIN_DEFINE(keydomain); 713 1.1 jonathan 714 1.24 rmind PR_WRAP_USRREQS(key) 715 1.24 rmind #define key_attach key_attach_wrapper 716 1.24 rmind #define key_detach key_detach_wrapper 717 1.35 rtr #define key_accept key_accept_wrapper 718 1.37 rtr #define key_bind key_bind_wrapper 719 1.37 rtr #define key_listen key_listen_wrapper 720 1.38 rtr #define key_connect key_connect_wrapper 721 1.43 rtr #define key_connect2 key_connect2_wrapper 722 1.39 rtr #define key_disconnect key_disconnect_wrapper 723 1.39 rtr #define key_shutdown key_shutdown_wrapper 724 1.39 rtr #define key_abort key_abort_wrapper 725 1.28 rtr #define key_ioctl key_ioctl_wrapper 726 1.30 rtr #define key_stat key_stat_wrapper 727 1.34 rtr #define key_peeraddr key_peeraddr_wrapper 728 1.34 rtr #define key_sockaddr key_sockaddr_wrapper 729 1.42 rtr #define key_rcvd key_rcvd_wrapper 730 1.36 rtr #define key_recvoob key_recvoob_wrapper 731 1.41 rtr #define key_send key_send_wrapper 732 1.36 rtr #define key_sendoob key_sendoob_wrapper 733 1.43 rtr #define key_purgeif key_purgeif_wrapper 734 1.22 rmind 735 1.49 riastrad static const struct pr_usrreqs key_usrreqs = { 736 1.23 rmind .pr_attach = key_attach, 737 1.23 rmind .pr_detach = key_detach, 738 1.35 rtr .pr_accept = key_accept, 739 1.37 rtr .pr_bind = key_bind, 740 1.37 rtr .pr_listen = key_listen, 741 1.38 rtr .pr_connect = key_connect, 742 1.43 rtr .pr_connect2 = key_connect2, 743 1.39 rtr .pr_disconnect = key_disconnect, 744 1.39 rtr .pr_shutdown = key_shutdown, 745 1.39 rtr .pr_abort = key_abort, 746 1.28 rtr .pr_ioctl = key_ioctl, 747 1.30 rtr .pr_stat = key_stat, 748 1.34 rtr .pr_peeraddr = key_peeraddr, 749 1.34 rtr .pr_sockaddr = key_sockaddr, 750 1.42 rtr .pr_rcvd = key_rcvd, 751 1.36 rtr .pr_recvoob = key_recvoob, 752 1.41 rtr .pr_send = key_send, 753 1.36 rtr .pr_sendoob = key_sendoob, 754 1.43 rtr .pr_purgeif = key_purgeif, 755 1.22 rmind }; 756 1.22 rmind 757 1.49 riastrad static const struct protosw keysw[] = { 758 1.10 matt { 759 1.10 matt .pr_type = SOCK_RAW, 760 1.10 matt .pr_domain = &keydomain, 761 1.10 matt .pr_protocol = PF_KEY_V2, 762 1.10 matt .pr_flags = PR_ATOMIC|PR_ADDR, 763 1.10 matt .pr_ctlinput = raw_ctlinput, 764 1.22 rmind .pr_usrreqs = &key_usrreqs, 765 1.61 ozaki .pr_init = key_pr_init, 766 1.10 matt } 767 1.1 jonathan }; 768 1.1 jonathan 769 1.10 matt struct domain keydomain = { 770 1.10 matt .dom_family = PF_KEY, 771 1.10 matt .dom_name = "key", 772 1.10 matt .dom_init = key_init, 773 1.10 matt .dom_protosw = keysw, 774 1.10 matt .dom_protoswNPROTOSW = &keysw[__arraycount(keysw)], 775 1.10 matt }; 776
Indexes created Thu Oct 02 01:09:59 GMT 2025