1 /* $NetBSD: uipc_socket2.c,v 1.142 2022/10/26 23:38:09 riastradh Exp $ */ 2 3 /*- 4 * Copyright (c) 2008 The NetBSD Foundation, Inc. 5 * All rights reserved. 6 * 7 * Redistribution and use in source and binary forms, with or without 8 * modification, are permitted provided that the following conditions 9 * are met: 10 * 1. Redistributions of source code must retain the above copyright 11 * notice, this list of conditions and the following disclaimer. 12 * 2. Redistributions in binary form must reproduce the above copyright 13 * notice, this list of conditions and the following disclaimer in the 14 * documentation and/or other materials provided with the distribution. 15 * 16 * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 17 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 18 * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 19 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 20 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 21 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 22 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 23 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 24 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 25 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 26 * POSSIBILITY OF SUCH DAMAGE. 27 */ 28 29 /* 30 * Copyright (c) 1982, 1986, 1988, 1990, 1993 31 * The Regents of the University of California. All rights reserved. 32 * 33 * Redistribution and use in source and binary forms, with or without 34 * modification, are permitted provided that the following conditions 35 * are met: 36 * 1. Redistributions of source code must retain the above copyright 37 * notice, this list of conditions and the following disclaimer. 38 * 2. Redistributions in binary form must reproduce the above copyright 39 * notice, this list of conditions and the following disclaimer in the 40 * documentation and/or other materials provided with the distribution. 41 * 3. Neither the name of the University nor the names of its contributors 42 * may be used to endorse or promote products derived from this software 43 * without specific prior written permission. 44 * 45 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 46 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 47 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 48 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 49 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 50 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 51 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 52 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 53 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 54 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 55 * SUCH DAMAGE. 56 * 57 * @(#)uipc_socket2.c 8.2 (Berkeley) 2/14/95 58 */ 59 60 #include <sys/cdefs.h> 61 __KERNEL_RCSID(0, "$NetBSD: uipc_socket2.c,v 1.142 2022/10/26 23:38:09 riastradh Exp $"); 62 63 #ifdef _KERNEL_OPT 64 #include "opt_ddb.h" 65 #include "opt_inet.h" 66 #include "opt_mbuftrace.h" 67 #include "opt_sb_max.h" 68 #endif 69 70 #include <sys/param.h> 71 #include <sys/systm.h> 72 #include <sys/proc.h> 73 #include <sys/file.h> 74 #include <sys/buf.h> 75 #include <sys/mbuf.h> 76 #include <sys/protosw.h> 77 #include <sys/domain.h> 78 #include <sys/poll.h> 79 #include <sys/socket.h> 80 #include <sys/socketvar.h> 81 #include <sys/signalvar.h> 82 #include <sys/kauth.h> 83 #include <sys/pool.h> 84 #include <sys/uidinfo.h> 85 86 #ifdef DDB 87 #include <sys/filedesc.h> 88 #include <ddb/db_active.h> 89 #endif 90 91 /* 92 * Primitive routines for operating on sockets and socket buffers. 93 * 94 * Connection life-cycle: 95 * 96 * Normal sequence from the active (originating) side: 97 * 98 * - soisconnecting() is called during processing of connect() call, 99 * - resulting in an eventual call to soisconnected() if/when the 100 * connection is established. 101 * 102 * When the connection is torn down during processing of disconnect(): 103 * 104 * - soisdisconnecting() is called and, 105 * - soisdisconnected() is called when the connection to the peer 106 * is totally severed. 107 * 108 * The semantics of these routines are such that connectionless protocols 109 * can call soisconnected() and soisdisconnected() only, bypassing the 110 * in-progress calls when setting up a ``connection'' takes no time. 111 * 112 * From the passive side, a socket is created with two queues of sockets: 113 * 114 * - so_q0 (0) for partial connections (i.e. connections in progress) 115 * - so_q (1) for connections already made and awaiting user acceptance. 116 * 117 * As a protocol is preparing incoming connections, it creates a socket 118 * structure queued on so_q0 by calling sonewconn(). When the connection 119 * is established, soisconnected() is called, and transfers the 120 * socket structure to so_q, making it available to accept(). 121 * 122 * If a socket is closed with sockets on either so_q0 or so_q, these 123 * sockets are dropped. 124 * 125 * Locking rules and assumptions: 126 * 127 * o socket::so_lock can change on the fly. The low level routines used 128 * to lock sockets are aware of this. When so_lock is acquired, the 129 * routine locking must check to see if so_lock still points to the 130 * lock that was acquired. If so_lock has changed in the meantime, the 131 * now irrelevant lock that was acquired must be dropped and the lock 132 * operation retried. Although not proven here, this is completely safe 133 * on a multiprocessor system, even with relaxed memory ordering, given 134 * the next two rules: 135 * 136 * o In order to mutate so_lock, the lock pointed to by the current value 137 * of so_lock must be held: i.e., the socket must be held locked by the 138 * changing thread. The thread must issue membar_release() to prevent 139 * memory accesses being reordered, and can set so_lock to the desired 140 * value. If the lock pointed to by the new value of so_lock is not 141 * held by the changing thread, the socket must then be considered 142 * unlocked. 143 * 144 * o If so_lock is mutated, and the previous lock referred to by so_lock 145 * could still be visible to other threads in the system (e.g. via file 146 * descriptor or protocol-internal reference), then the old lock must 147 * remain valid until the socket and/or protocol control block has been 148 * torn down. 149 * 150 * o If a socket has a non-NULL so_head value (i.e. is in the process of 151 * connecting), then locking the socket must also lock the socket pointed 152 * to by so_head: their lock pointers must match. 153 * 154 * o If a socket has connections in progress (so_q, so_q0 not empty) then 155 * locking the socket must also lock the sockets attached to both queues. 156 * Again, their lock pointers must match. 157 * 158 * o Beyond the initial lock assignment in socreate(), assigning locks to 159 * sockets is the responsibility of the individual protocols / protocol 160 * domains. 161 */ 162 163 static pool_cache_t socket_cache; 164 u_long sb_max = SB_MAX;/* maximum socket buffer size */ 165 static u_long sb_max_adj; /* adjusted sb_max */ 166 167 void 168 soisconnecting(struct socket *so) 169 { 170 171 KASSERT(solocked(so)); 172 173 so->so_state &= ~(SS_ISCONNECTED|SS_ISDISCONNECTING); 174 so->so_state |= SS_ISCONNECTING; 175 } 176 177 void 178 soisconnected(struct socket *so) 179 { 180 struct socket *head; 181 182 head = so->so_head; 183 184 KASSERT(solocked(so)); 185 KASSERT(head == NULL || solocked2(so, head)); 186 187 so->so_state &= ~(SS_ISCONNECTING | SS_ISDISCONNECTING); 188 so->so_state |= SS_ISCONNECTED; 189 if (head && so->so_onq == &head->so_q0) { 190 if ((so->so_options & SO_ACCEPTFILTER) == 0) { 191 /* 192 * Re-enqueue and wake up any waiters, e.g. 193 * processes blocking on accept(). 194 */ 195 soqremque(so, 0); 196 soqinsque(head, so, 1); 197 sorwakeup(head); 198 cv_broadcast(&head->so_cv); 199 } else { 200 so->so_upcall = 201 head->so_accf->so_accept_filter->accf_callback; 202 so->so_upcallarg = head->so_accf->so_accept_filter_arg; 203 so->so_rcv.sb_flags |= SB_UPCALL; 204 so->so_options &= ~SO_ACCEPTFILTER; 205 (*so->so_upcall)(so, so->so_upcallarg, 206 POLLIN|POLLRDNORM, M_DONTWAIT); 207 } 208 } else { 209 cv_broadcast(&so->so_cv); 210 sorwakeup(so); 211 sowwakeup(so); 212 } 213 } 214 215 void 216 soisdisconnecting(struct socket *so) 217 { 218 219 KASSERT(solocked(so)); 220 221 so->so_state &= ~SS_ISCONNECTING; 222 so->so_state |= (SS_ISDISCONNECTING|SS_CANTRCVMORE|SS_CANTSENDMORE); 223 cv_broadcast(&so->so_cv); 224 sowwakeup(so); 225 sorwakeup(so); 226 } 227 228 void 229 soisdisconnected(struct socket *so) 230 { 231 232 KASSERT(solocked(so)); 233 234 so->so_state &= ~(SS_ISCONNECTING|SS_ISCONNECTED|SS_ISDISCONNECTING); 235 so->so_state |= (SS_CANTRCVMORE|SS_CANTSENDMORE|SS_ISDISCONNECTED); 236 cv_broadcast(&so->so_cv); 237 sowwakeup(so); 238 sorwakeup(so); 239 } 240 241 void 242 soinit2(void) 243 { 244 245 socket_cache = pool_cache_init(sizeof(struct socket), 0, 0, 0, 246 "socket", NULL, IPL_SOFTNET, NULL, NULL, NULL); 247 } 248 249 /* 250 * sonewconn: accept a new connection. 251 * 252 * When an attempt at a new connection is noted on a socket which accepts 253 * connections, sonewconn(9) is called. If the connection is possible 254 * (subject to space constraints, etc) then we allocate a new structure, 255 * properly linked into the data structure of the original socket. 256 * 257 * => If 'soready' is true, then socket will become ready for accept() i.e. 258 * inserted into the so_q queue, SS_ISCONNECTED set and waiters awoken. 259 * => May be called from soft-interrupt context. 260 * => Listening socket should be locked. 261 * => Returns the new socket locked. 262 */ 263 struct socket * 264 sonewconn(struct socket *head, bool soready) 265 { 266 struct socket *so; 267 int soqueue, error; 268 269 KASSERT(solocked(head)); 270 271 if (head->so_qlen + head->so_q0len > 3 * head->so_qlimit / 2) { 272 /* 273 * Listen queue overflow. If there is an accept filter 274 * active, pass through the oldest cxn it's handling. 275 */ 276 if (head->so_accf == NULL) { 277 return NULL; 278 } else { 279 struct socket *so2, *next; 280 281 /* Pass the oldest connection waiting in the 282 accept filter */ 283 for (so2 = TAILQ_FIRST(&head->so_q0); 284 so2 != NULL; so2 = next) { 285 next = TAILQ_NEXT(so2, so_qe); 286 if (so2->so_upcall == NULL) { 287 continue; 288 } 289 so2->so_upcall = NULL; 290 so2->so_upcallarg = NULL; 291 so2->so_options &= ~SO_ACCEPTFILTER; 292 so2->so_rcv.sb_flags &= ~SB_UPCALL; 293 soisconnected(so2); 294 break; 295 } 296 297 /* If nothing was nudged out of the acept filter, bail 298 * out; otherwise proceed allocating the socket. */ 299 if (so2 == NULL) { 300 return NULL; 301 } 302 } 303 } 304 if ((head->so_options & SO_ACCEPTFILTER) != 0) { 305 soready = false; 306 } 307 soqueue = soready ? 1 : 0; 308 309 if ((so = soget(false)) == NULL) { 310 return NULL; 311 } 312 so->so_type = head->so_type; 313 so->so_options = head->so_options & ~SO_ACCEPTCONN; 314 so->so_linger = head->so_linger; 315 so->so_state = head->so_state | SS_NOFDREF; 316 so->so_proto = head->so_proto; 317 so->so_timeo = head->so_timeo; 318 so->so_pgid = head->so_pgid; 319 so->so_send = head->so_send; 320 so->so_receive = head->so_receive; 321 so->so_uidinfo = head->so_uidinfo; 322 so->so_egid = head->so_egid; 323 so->so_cpid = head->so_cpid; 324 325 /* 326 * Share the lock with the listening-socket, it may get unshared 327 * once the connection is complete. 328 * 329 * so_lock is stable while we hold the socket locked, so no 330 * need for atomic_load_* here. 331 */ 332 mutex_obj_hold(head->so_lock); 333 so->so_lock = head->so_lock; 334 335 /* 336 * Reserve the space for socket buffers. 337 */ 338 #ifdef MBUFTRACE 339 so->so_mowner = head->so_mowner; 340 so->so_rcv.sb_mowner = head->so_rcv.sb_mowner; 341 so->so_snd.sb_mowner = head->so_snd.sb_mowner; 342 #endif 343 if (soreserve(so, head->so_snd.sb_hiwat, head->so_rcv.sb_hiwat)) { 344 goto out; 345 } 346 so->so_snd.sb_lowat = head->so_snd.sb_lowat; 347 so->so_rcv.sb_lowat = head->so_rcv.sb_lowat; 348 so->so_rcv.sb_timeo = head->so_rcv.sb_timeo; 349 so->so_snd.sb_timeo = head->so_snd.sb_timeo; 350 so->so_rcv.sb_flags |= head->so_rcv.sb_flags & (SB_AUTOSIZE | SB_ASYNC); 351 so->so_snd.sb_flags |= head->so_snd.sb_flags & (SB_AUTOSIZE | SB_ASYNC); 352 353 /* 354 * Finally, perform the protocol attach. Note: a new socket 355 * lock may be assigned at this point (if so, it will be held). 356 */ 357 error = (*so->so_proto->pr_usrreqs->pr_attach)(so, 0); 358 if (error) { 359 out: 360 KASSERT(solocked(so)); 361 KASSERT(so->so_accf == NULL); 362 soput(so); 363 364 /* Note: the listening socket shall stay locked. */ 365 KASSERT(solocked(head)); 366 return NULL; 367 } 368 KASSERT(solocked2(head, so)); 369 370 /* 371 * Insert into the queue. If ready, update the connection status 372 * and wake up any waiters, e.g. processes blocking on accept(). 373 */ 374 soqinsque(head, so, soqueue); 375 if (soready) { 376 so->so_state |= SS_ISCONNECTED; 377 sorwakeup(head); 378 cv_broadcast(&head->so_cv); 379 } 380 return so; 381 } 382 383 struct socket * 384 soget(bool waitok) 385 { 386 struct socket *so; 387 388 so = pool_cache_get(socket_cache, (waitok ? PR_WAITOK : PR_NOWAIT)); 389 if (__predict_false(so == NULL)) 390 return (NULL); 391 memset(so, 0, sizeof(*so)); 392 TAILQ_INIT(&so->so_q0); 393 TAILQ_INIT(&so->so_q); 394 cv_init(&so->so_cv, "socket"); 395 cv_init(&so->so_rcv.sb_cv, "netio"); 396 cv_init(&so->so_snd.sb_cv, "netio"); 397 selinit(&so->so_rcv.sb_sel); 398 selinit(&so->so_snd.sb_sel); 399 so->so_rcv.sb_so = so; 400 so->so_snd.sb_so = so; 401 return so; 402 } 403 404 void 405 soput(struct socket *so) 406 { 407 408 KASSERT(!cv_has_waiters(&so->so_cv)); 409 KASSERT(!cv_has_waiters(&so->so_rcv.sb_cv)); 410 KASSERT(!cv_has_waiters(&so->so_snd.sb_cv)); 411 seldestroy(&so->so_rcv.sb_sel); 412 seldestroy(&so->so_snd.sb_sel); 413 mutex_obj_free(so->so_lock); 414 cv_destroy(&so->so_cv); 415 cv_destroy(&so->so_rcv.sb_cv); 416 cv_destroy(&so->so_snd.sb_cv); 417 pool_cache_put(socket_cache, so); 418 } 419 420 /* 421 * soqinsque: insert socket of a new connection into the specified 422 * accept queue of the listening socket (head). 423 * 424 * q = 0: queue of partial connections 425 * q = 1: queue of incoming connections 426 */ 427 void 428 soqinsque(struct socket *head, struct socket *so, int q) 429 { 430 KASSERT(q == 0 || q == 1); 431 KASSERT(solocked2(head, so)); 432 KASSERT(so->so_onq == NULL); 433 KASSERT(so->so_head == NULL); 434 435 so->so_head = head; 436 if (q == 0) { 437 head->so_q0len++; 438 so->so_onq = &head->so_q0; 439 } else { 440 head->so_qlen++; 441 so->so_onq = &head->so_q; 442 } 443 TAILQ_INSERT_TAIL(so->so_onq, so, so_qe); 444 } 445 446 /* 447 * soqremque: remove socket from the specified queue. 448 * 449 * => Returns true if socket was removed from the specified queue. 450 * => False if socket was not removed (because it was in other queue). 451 */ 452 bool 453 soqremque(struct socket *so, int q) 454 { 455 struct socket *head = so->so_head; 456 457 KASSERT(q == 0 || q == 1); 458 KASSERT(solocked(so)); 459 KASSERT(so->so_onq != NULL); 460 KASSERT(head != NULL); 461 462 if (q == 0) { 463 if (so->so_onq != &head->so_q0) 464 return false; 465 head->so_q0len--; 466 } else { 467 if (so->so_onq != &head->so_q) 468 return false; 469 head->so_qlen--; 470 } 471 KASSERT(solocked2(so, head)); 472 TAILQ_REMOVE(so->so_onq, so, so_qe); 473 so->so_onq = NULL; 474 so->so_head = NULL; 475 return true; 476 } 477 478 /* 479 * socantsendmore: indicates that no more data will be sent on the 480 * socket; it would normally be applied to a socket when the user 481 * informs the system that no more data is to be sent, by the protocol 482 * code (in case pr_shutdown()). 483 */ 484 void 485 socantsendmore(struct socket *so) 486 { 487 KASSERT(solocked(so)); 488 489 so->so_state |= SS_CANTSENDMORE; 490 sowwakeup(so); 491 } 492 493 /* 494 * socantrcvmore(): indicates that no more data will be received and 495 * will normally be applied to the socket by a protocol when it detects 496 * that the peer will send no more data. Data queued for reading in 497 * the socket may yet be read. 498 */ 499 void 500 socantrcvmore(struct socket *so) 501 { 502 KASSERT(solocked(so)); 503 504 so->so_state |= SS_CANTRCVMORE; 505 sorwakeup(so); 506 } 507 508 /* 509 * soroverflow(): indicates that data was attempted to be sent 510 * but the receiving buffer overflowed. 511 */ 512 void 513 soroverflow(struct socket *so) 514 { 515 KASSERT(solocked(so)); 516 517 so->so_rcv.sb_overflowed++; 518 if (so->so_options & SO_RERROR) { 519 so->so_rerror = ENOBUFS; 520 sorwakeup(so); 521 } 522 } 523 524 /* 525 * Wait for data to arrive at/drain from a socket buffer. 526 */ 527 int 528 sbwait(struct sockbuf *sb) 529 { 530 struct socket *so; 531 kmutex_t *lock; 532 int error; 533 534 so = sb->sb_so; 535 536 KASSERT(solocked(so)); 537 538 sb->sb_flags |= SB_NOTIFY; 539 lock = so->so_lock; 540 if ((sb->sb_flags & SB_NOINTR) != 0) 541 error = cv_timedwait(&sb->sb_cv, lock, sb->sb_timeo); 542 else 543 error = cv_timedwait_sig(&sb->sb_cv, lock, sb->sb_timeo); 544 if (__predict_false(lock != atomic_load_relaxed(&so->so_lock))) 545 solockretry(so, lock); 546 return error; 547 } 548 549 /* 550 * Wakeup processes waiting on a socket buffer. 551 * Do asynchronous notification via SIGIO 552 * if the socket buffer has the SB_ASYNC flag set. 553 */ 554 void 555 sowakeup(struct socket *so, struct sockbuf *sb, int code) 556 { 557 int band; 558 559 KASSERT(solocked(so)); 560 KASSERT(sb->sb_so == so); 561 562 switch (code) { 563 case POLL_IN: 564 band = POLLIN|POLLRDNORM; 565 break; 566 567 case POLL_OUT: 568 band = POLLOUT|POLLWRNORM; 569 break; 570 571 case POLL_HUP: 572 band = POLLHUP; 573 break; 574 575 default: 576 band = 0; 577 #ifdef DIAGNOSTIC 578 printf("bad siginfo code %d in socket notification.\n", code); 579 #endif 580 break; 581 } 582 583 sb->sb_flags &= ~SB_NOTIFY; 584 selnotify(&sb->sb_sel, band, NOTE_SUBMIT); 585 cv_broadcast(&sb->sb_cv); 586 if (sb->sb_flags & SB_ASYNC) 587 fownsignal(so->so_pgid, SIGIO, code, band, so); 588 if (sb->sb_flags & SB_UPCALL) 589 (*so->so_upcall)(so, so->so_upcallarg, band, M_DONTWAIT); 590 } 591 592 /* 593 * Reset a socket's lock pointer. Wake all threads waiting on the 594 * socket's condition variables so that they can restart their waits 595 * using the new lock. The existing lock must be held. 596 * 597 * Caller must have issued membar_release before this. 598 */ 599 void 600 solockreset(struct socket *so, kmutex_t *lock) 601 { 602 603 KASSERT(solocked(so)); 604 605 so->so_lock = lock; 606 cv_broadcast(&so->so_snd.sb_cv); 607 cv_broadcast(&so->so_rcv.sb_cv); 608 cv_broadcast(&so->so_cv); 609 } 610 611 /* 612 * Socket buffer (struct sockbuf) utility routines. 613 * 614 * Each socket contains two socket buffers: one for sending data and 615 * one for receiving data. Each buffer contains a queue of mbufs, 616 * information about the number of mbufs and amount of data in the 617 * queue, and other fields allowing poll() statements and notification 618 * on data availability to be implemented. 619 * 620 * Data stored in a socket buffer is maintained as a list of records. 621 * Each record is a list of mbufs chained together with the m_next 622 * field. Records are chained together with the m_nextpkt field. The upper 623 * level routine soreceive() expects the following conventions to be 624 * observed when placing information in the receive buffer: 625 * 626 * 1. If the protocol requires each message be preceded by the sender's 627 * name, then a record containing that name must be present before 628 * any associated data (mbuf's must be of type MT_SONAME). 629 * 2. If the protocol supports the exchange of ``access rights'' (really 630 * just additional data associated with the message), and there are 631 * ``rights'' to be received, then a record containing this data 632 * should be present (mbuf's must be of type MT_CONTROL). 633 * 3. If a name or rights record exists, then it must be followed by 634 * a data record, perhaps of zero length. 635 * 636 * Before using a new socket structure it is first necessary to reserve 637 * buffer space to the socket, by calling sbreserve(). This should commit 638 * some of the available buffer space in the system buffer pool for the 639 * socket (currently, it does nothing but enforce limits). The space 640 * should be released by calling sbrelease() when the socket is destroyed. 641 */ 642 643 int 644 sb_max_set(u_long new_sbmax) 645 { 646 int s; 647 648 if (new_sbmax < (16 * 1024)) 649 return (EINVAL); 650 651 s = splsoftnet(); 652 sb_max = new_sbmax; 653 sb_max_adj = (u_quad_t)new_sbmax * MCLBYTES / (MSIZE + MCLBYTES); 654 splx(s); 655 656 return (0); 657 } 658 659 int 660 soreserve(struct socket *so, u_long sndcc, u_long rcvcc) 661 { 662 KASSERT(so->so_pcb == NULL || solocked(so)); 663 664 /* 665 * there's at least one application (a configure script of screen) 666 * which expects a fifo is writable even if it has "some" bytes 667 * in its buffer. 668 * so we want to make sure (hiwat - lowat) >= (some bytes). 669 * 670 * PIPE_BUF here is an arbitrary value chosen as (some bytes) above. 671 * we expect it's large enough for such applications. 672 */ 673 u_long lowat = MAX(sock_loan_thresh, MCLBYTES); 674 u_long hiwat = lowat + PIPE_BUF; 675 676 if (sndcc < hiwat) 677 sndcc = hiwat; 678 if (sbreserve(&so->so_snd, sndcc, so) == 0) 679 goto bad; 680 if (sbreserve(&so->so_rcv, rcvcc, so) == 0) 681 goto bad2; 682 if (so->so_rcv.sb_lowat == 0) 683 so->so_rcv.sb_lowat = 1; 684 if (so->so_snd.sb_lowat == 0) 685 so->so_snd.sb_lowat = lowat; 686 if (so->so_snd.sb_lowat > so->so_snd.sb_hiwat) 687 so->so_snd.sb_lowat = so->so_snd.sb_hiwat; 688 return (0); 689 bad2: 690 sbrelease(&so->so_snd, so); 691 bad: 692 return (ENOBUFS); 693 } 694 695 /* 696 * Allot mbufs to a sockbuf. 697 * Attempt to scale mbmax so that mbcnt doesn't become limiting 698 * if buffering efficiency is near the normal case. 699 */ 700 int 701 sbreserve(struct sockbuf *sb, u_long cc, struct socket *so) 702 { 703 struct lwp *l = curlwp; /* XXX */ 704 rlim_t maxcc; 705 struct uidinfo *uidinfo; 706 707 KASSERT(so->so_pcb == NULL || solocked(so)); 708 KASSERT(sb->sb_so == so); 709 KASSERT(sb_max_adj != 0); 710 711 if (cc == 0 || cc > sb_max_adj) 712 return (0); 713 714 maxcc = l->l_proc->p_rlimit[RLIMIT_SBSIZE].rlim_cur; 715 716 uidinfo = so->so_uidinfo; 717 if (!chgsbsize(uidinfo, &sb->sb_hiwat, cc, maxcc)) 718 return 0; 719 sb->sb_mbmax = uimin(cc * 2, sb_max); 720 if (sb->sb_lowat > sb->sb_hiwat) 721 sb->sb_lowat = sb->sb_hiwat; 722 723 return (1); 724 } 725 726 /* 727 * Free mbufs held by a socket, and reserved mbuf space. We do not assert 728 * that the socket is held locked here: see sorflush(). 729 */ 730 void 731 sbrelease(struct sockbuf *sb, struct socket *so) 732 { 733 734 KASSERT(sb->sb_so == so); 735 736 sbflush(sb); 737 (void)chgsbsize(so->so_uidinfo, &sb->sb_hiwat, 0, RLIM_INFINITY); 738 sb->sb_mbmax = 0; 739 } 740 741 /* 742 * Routines to add and remove 743 * data from an mbuf queue. 744 * 745 * The routines sbappend() or sbappendrecord() are normally called to 746 * append new mbufs to a socket buffer, after checking that adequate 747 * space is available, comparing the function sbspace() with the amount 748 * of data to be added. sbappendrecord() differs from sbappend() in 749 * that data supplied is treated as the beginning of a new record. 750 * To place a sender's address, optional access rights, and data in a 751 * socket receive buffer, sbappendaddr() should be used. To place 752 * access rights and data in a socket receive buffer, sbappendrights() 753 * should be used. In either case, the new data begins a new record. 754 * Note that unlike sbappend() and sbappendrecord(), these routines check 755 * for the caller that there will be enough space to store the data. 756 * Each fails if there is not enough space, or if it cannot find mbufs 757 * to store additional information in. 758 * 759 * Reliable protocols may use the socket send buffer to hold data 760 * awaiting acknowledgement. Data is normally copied from a socket 761 * send buffer in a protocol with m_copym for output to a peer, 762 * and then removing the data from the socket buffer with sbdrop() 763 * or sbdroprecord() when the data is acknowledged by the peer. 764 */ 765 766 #ifdef SOCKBUF_DEBUG 767 void 768 sblastrecordchk(struct sockbuf *sb, const char *where) 769 { 770 struct mbuf *m = sb->sb_mb; 771 772 KASSERT(solocked(sb->sb_so)); 773 774 while (m && m->m_nextpkt) 775 m = m->m_nextpkt; 776 777 if (m != sb->sb_lastrecord) { 778 printf("sblastrecordchk: sb_mb %p sb_lastrecord %p last %p\n", 779 sb->sb_mb, sb->sb_lastrecord, m); 780 printf("packet chain:\n"); 781 for (m = sb->sb_mb; m != NULL; m = m->m_nextpkt) 782 printf("\t%p\n", m); 783 panic("sblastrecordchk from %s", where); 784 } 785 } 786 787 void 788 sblastmbufchk(struct sockbuf *sb, const char *where) 789 { 790 struct mbuf *m = sb->sb_mb; 791 struct mbuf *n; 792 793 KASSERT(solocked(sb->sb_so)); 794 795 while (m && m->m_nextpkt) 796 m = m->m_nextpkt; 797 798 while (m && m->m_next) 799 m = m->m_next; 800 801 if (m != sb->sb_mbtail) { 802 printf("sblastmbufchk: sb_mb %p sb_mbtail %p last %p\n", 803 sb->sb_mb, sb->sb_mbtail, m); 804 printf("packet tree:\n"); 805 for (m = sb->sb_mb; m != NULL; m = m->m_nextpkt) { 806 printf("\t"); 807 for (n = m; n != NULL; n = n->m_next) 808 printf("%p ", n); 809 printf("\n"); 810 } 811 panic("sblastmbufchk from %s", where); 812 } 813 } 814 #endif /* SOCKBUF_DEBUG */ 815 816 /* 817 * Link a chain of records onto a socket buffer 818 */ 819 #define SBLINKRECORDCHAIN(sb, m0, mlast) \ 820 do { \ 821 if ((sb)->sb_lastrecord != NULL) \ 822 (sb)->sb_lastrecord->m_nextpkt = (m0); \ 823 else \ 824 (sb)->sb_mb = (m0); \ 825 (sb)->sb_lastrecord = (mlast); \ 826 } while (/*CONSTCOND*/0) 827 828 829 #define SBLINKRECORD(sb, m0) \ 830 SBLINKRECORDCHAIN(sb, m0, m0) 831 832 /* 833 * Append mbuf chain m to the last record in the 834 * socket buffer sb. The additional space associated 835 * the mbuf chain is recorded in sb. Empty mbufs are 836 * discarded and mbufs are compacted where possible. 837 */ 838 void 839 sbappend(struct sockbuf *sb, struct mbuf *m) 840 { 841 struct mbuf *n; 842 843 KASSERT(solocked(sb->sb_so)); 844 845 if (m == NULL) 846 return; 847 848 #ifdef MBUFTRACE 849 m_claimm(m, sb->sb_mowner); 850 #endif 851 852 SBLASTRECORDCHK(sb, "sbappend 1"); 853 854 if ((n = sb->sb_lastrecord) != NULL) { 855 /* 856 * XXX Would like to simply use sb_mbtail here, but 857 * XXX I need to verify that I won't miss an EOR that 858 * XXX way. 859 */ 860 do { 861 if (n->m_flags & M_EOR) { 862 sbappendrecord(sb, m); /* XXXXXX!!!! */ 863 return; 864 } 865 } while (n->m_next && (n = n->m_next)); 866 } else { 867 /* 868 * If this is the first record in the socket buffer, it's 869 * also the last record. 870 */ 871 sb->sb_lastrecord = m; 872 } 873 sbcompress(sb, m, n); 874 SBLASTRECORDCHK(sb, "sbappend 2"); 875 } 876 877 /* 878 * This version of sbappend() should only be used when the caller 879 * absolutely knows that there will never be more than one record 880 * in the socket buffer, that is, a stream protocol (such as TCP). 881 */ 882 void 883 sbappendstream(struct sockbuf *sb, struct mbuf *m) 884 { 885 886 KASSERT(solocked(sb->sb_so)); 887 KDASSERT(m->m_nextpkt == NULL); 888 KASSERT(sb->sb_mb == sb->sb_lastrecord); 889 890 SBLASTMBUFCHK(sb, __func__); 891 892 #ifdef MBUFTRACE 893 m_claimm(m, sb->sb_mowner); 894 #endif 895 896 sbcompress(sb, m, sb->sb_mbtail); 897 898 sb->sb_lastrecord = sb->sb_mb; 899 SBLASTRECORDCHK(sb, __func__); 900 } 901 902 #ifdef SOCKBUF_DEBUG 903 void 904 sbcheck(struct sockbuf *sb) 905 { 906 struct mbuf *m, *m2; 907 u_long len, mbcnt; 908 909 KASSERT(solocked(sb->sb_so)); 910 911 len = 0; 912 mbcnt = 0; 913 for (m = sb->sb_mb; m; m = m->m_nextpkt) { 914 for (m2 = m; m2 != NULL; m2 = m2->m_next) { 915 len += m2->m_len; 916 mbcnt += MSIZE; 917 if (m2->m_flags & M_EXT) 918 mbcnt += m2->m_ext.ext_size; 919 if (m2->m_nextpkt != NULL) 920 panic("sbcheck nextpkt"); 921 } 922 } 923 if (len != sb->sb_cc || mbcnt != sb->sb_mbcnt) { 924 printf("cc %lu != %lu || mbcnt %lu != %lu\n", len, sb->sb_cc, 925 mbcnt, sb->sb_mbcnt); 926 panic("sbcheck"); 927 } 928 } 929 #endif 930 931 /* 932 * As above, except the mbuf chain 933 * begins a new record. 934 */ 935 void 936 sbappendrecord(struct sockbuf *sb, struct mbuf *m0) 937 { 938 struct mbuf *m; 939 940 KASSERT(solocked(sb->sb_so)); 941 942 if (m0 == NULL) 943 return; 944 945 #ifdef MBUFTRACE 946 m_claimm(m0, sb->sb_mowner); 947 #endif 948 /* 949 * Put the first mbuf on the queue. 950 * Note this permits zero length records. 951 */ 952 sballoc(sb, m0); 953 SBLASTRECORDCHK(sb, "sbappendrecord 1"); 954 SBLINKRECORD(sb, m0); 955 m = m0->m_next; 956 m0->m_next = 0; 957 if (m && (m0->m_flags & M_EOR)) { 958 m0->m_flags &= ~M_EOR; 959 m->m_flags |= M_EOR; 960 } 961 sbcompress(sb, m, m0); 962 SBLASTRECORDCHK(sb, "sbappendrecord 2"); 963 } 964 965 /* 966 * As above except that OOB data 967 * is inserted at the beginning of the sockbuf, 968 * but after any other OOB data. 969 */ 970 void 971 sbinsertoob(struct sockbuf *sb, struct mbuf *m0) 972 { 973 struct mbuf *m, **mp; 974 975 KASSERT(solocked(sb->sb_so)); 976 977 if (m0 == NULL) 978 return; 979 980 SBLASTRECORDCHK(sb, "sbinsertoob 1"); 981 982 for (mp = &sb->sb_mb; (m = *mp) != NULL; mp = &((*mp)->m_nextpkt)) { 983 again: 984 switch (m->m_type) { 985 986 case MT_OOBDATA: 987 continue; /* WANT next train */ 988 989 case MT_CONTROL: 990 if ((m = m->m_next) != NULL) 991 goto again; /* inspect THIS train further */ 992 } 993 break; 994 } 995 /* 996 * Put the first mbuf on the queue. 997 * Note this permits zero length records. 998 */ 999 sballoc(sb, m0); 1000 m0->m_nextpkt = *mp; 1001 if (*mp == NULL) { 1002 /* m0 is actually the new tail */ 1003 sb->sb_lastrecord = m0; 1004 } 1005 *mp = m0; 1006 m = m0->m_next; 1007 m0->m_next = 0; 1008 if (m && (m0->m_flags & M_EOR)) { 1009 m0->m_flags &= ~M_EOR; 1010 m->m_flags |= M_EOR; 1011 } 1012 sbcompress(sb, m, m0); 1013 SBLASTRECORDCHK(sb, "sbinsertoob 2"); 1014 } 1015 1016 /* 1017 * Append address and data, and optionally, control (ancillary) data 1018 * to the receive queue of a socket. If present, 1019 * m0 must include a packet header with total length. 1020 * Returns 0 if no space in sockbuf or insufficient mbufs. 1021 */ 1022 int 1023 sbappendaddr(struct sockbuf *sb, const struct sockaddr *asa, struct mbuf *m0, 1024 struct mbuf *control) 1025 { 1026 struct mbuf *m, *n, *nlast; 1027 int space, len; 1028 1029 KASSERT(solocked(sb->sb_so)); 1030 1031 space = asa->sa_len; 1032 1033 if (m0 != NULL) { 1034 if ((m0->m_flags & M_PKTHDR) == 0) 1035 panic("sbappendaddr"); 1036 space += m0->m_pkthdr.len; 1037 #ifdef MBUFTRACE 1038 m_claimm(m0, sb->sb_mowner); 1039 #endif 1040 } 1041 for (n = control; n; n = n->m_next) { 1042 space += n->m_len; 1043 MCLAIM(n, sb->sb_mowner); 1044 if (n->m_next == NULL) /* keep pointer to last control buf */ 1045 break; 1046 } 1047 if (space > sbspace(sb)) 1048 return (0); 1049 m = m_get(M_DONTWAIT, MT_SONAME); 1050 if (m == NULL) 1051 return (0); 1052 MCLAIM(m, sb->sb_mowner); 1053 /* 1054 * XXX avoid 'comparison always true' warning which isn't easily 1055 * avoided. 1056 */ 1057 len = asa->sa_len; 1058 if (len > MLEN) { 1059 MEXTMALLOC(m, asa->sa_len, M_NOWAIT); 1060 if ((m->m_flags & M_EXT) == 0) { 1061 m_free(m); 1062 return (0); 1063 } 1064 } 1065 m->m_len = asa->sa_len; 1066 memcpy(mtod(m, void *), asa, asa->sa_len); 1067 if (n) 1068 n->m_next = m0; /* concatenate data to control */ 1069 else 1070 control = m0; 1071 m->m_next = control; 1072 1073 SBLASTRECORDCHK(sb, "sbappendaddr 1"); 1074 1075 for (n = m; n->m_next != NULL; n = n->m_next) 1076 sballoc(sb, n); 1077 sballoc(sb, n); 1078 nlast = n; 1079 SBLINKRECORD(sb, m); 1080 1081 sb->sb_mbtail = nlast; 1082 SBLASTMBUFCHK(sb, "sbappendaddr"); 1083 SBLASTRECORDCHK(sb, "sbappendaddr 2"); 1084 1085 return (1); 1086 } 1087 1088 /* 1089 * Helper for sbappendchainaddr: prepend a struct sockaddr* to 1090 * an mbuf chain. 1091 */ 1092 static inline struct mbuf * 1093 m_prepend_sockaddr(struct sockbuf *sb, struct mbuf *m0, 1094 const struct sockaddr *asa) 1095 { 1096 struct mbuf *m; 1097 const int salen = asa->sa_len; 1098 1099 KASSERT(solocked(sb->sb_so)); 1100 1101 /* only the first in each chain need be a pkthdr */ 1102 m = m_gethdr(M_DONTWAIT, MT_SONAME); 1103 if (m == NULL) 1104 return NULL; 1105 MCLAIM(m, sb->sb_mowner); 1106 #ifdef notyet 1107 if (salen > MHLEN) { 1108 MEXTMALLOC(m, salen, M_NOWAIT); 1109 if ((m->m_flags & M_EXT) == 0) { 1110 m_free(m); 1111 return NULL; 1112 } 1113 } 1114 #else 1115 KASSERT(salen <= MHLEN); 1116 #endif 1117 m->m_len = salen; 1118 memcpy(mtod(m, void *), asa, salen); 1119 m->m_next = m0; 1120 m->m_pkthdr.len = salen + m0->m_pkthdr.len; 1121 1122 return m; 1123 } 1124 1125 int 1126 sbappendaddrchain(struct sockbuf *sb, const struct sockaddr *asa, 1127 struct mbuf *m0, int sbprio) 1128 { 1129 struct mbuf *m, *n, *n0, *nlast; 1130 int error; 1131 1132 KASSERT(solocked(sb->sb_so)); 1133 1134 /* 1135 * XXX sbprio reserved for encoding priority of this* request: 1136 * SB_PRIO_NONE --> honour normal sb limits 1137 * SB_PRIO_ONESHOT_OVERFLOW --> if socket has any space, 1138 * take whole chain. Intended for large requests 1139 * that should be delivered atomically (all, or none). 1140 * SB_PRIO_OVERDRAFT -- allow a small (2*MLEN) overflow 1141 * over normal socket limits, for messages indicating 1142 * buffer overflow in earlier normal/lower-priority messages 1143 * SB_PRIO_BESTEFFORT --> ignore limits entirely. 1144 * Intended for kernel-generated messages only. 1145 * Up to generator to avoid total mbuf resource exhaustion. 1146 */ 1147 (void)sbprio; 1148 1149 if (m0 && (m0->m_flags & M_PKTHDR) == 0) 1150 panic("sbappendaddrchain"); 1151 1152 #ifdef notyet 1153 space = sbspace(sb); 1154 1155 /* 1156 * Enforce SB_PRIO_* limits as described above. 1157 */ 1158 #endif 1159 1160 n0 = NULL; 1161 nlast = NULL; 1162 for (m = m0; m; m = m->m_nextpkt) { 1163 struct mbuf *np; 1164 1165 #ifdef MBUFTRACE 1166 m_claimm(m, sb->sb_mowner); 1167 #endif 1168 1169 /* Prepend sockaddr to this record (m) of input chain m0 */ 1170 n = m_prepend_sockaddr(sb, m, asa); 1171 if (n == NULL) { 1172 error = ENOBUFS; 1173 goto bad; 1174 } 1175 1176 /* Append record (asa+m) to end of new chain n0 */ 1177 if (n0 == NULL) { 1178 n0 = n; 1179 } else { 1180 nlast->m_nextpkt = n; 1181 } 1182 /* Keep track of last record on new chain */ 1183 nlast = n; 1184 1185 for (np = n; np; np = np->m_next) 1186 sballoc(sb, np); 1187 } 1188 1189 SBLASTRECORDCHK(sb, "sbappendaddrchain 1"); 1190 1191 /* Drop the entire chain of (asa+m) records onto the socket */ 1192 SBLINKRECORDCHAIN(sb, n0, nlast); 1193 1194 SBLASTRECORDCHK(sb, "sbappendaddrchain 2"); 1195 1196 for (m = nlast; m->m_next; m = m->m_next) 1197 ; 1198 sb->sb_mbtail = m; 1199 SBLASTMBUFCHK(sb, "sbappendaddrchain"); 1200 1201 return (1); 1202 1203 bad: 1204 /* 1205 * On error, free the prepended addreseses. For consistency 1206 * with sbappendaddr(), leave it to our caller to free 1207 * the input record chain passed to us as m0. 1208 */ 1209 while ((n = n0) != NULL) { 1210 struct mbuf *np; 1211 1212 /* Undo the sballoc() of this record */ 1213 for (np = n; np; np = np->m_next) 1214 sbfree(sb, np); 1215 1216 n0 = n->m_nextpkt; /* iterate at next prepended address */ 1217 np = m_free(n); /* free prepended address (not data) */ 1218 } 1219 return error; 1220 } 1221 1222 1223 int 1224 sbappendcontrol(struct sockbuf *sb, struct mbuf *m0, struct mbuf *control) 1225 { 1226 struct mbuf *m, *mlast, *n; 1227 int space; 1228 1229 KASSERT(solocked(sb->sb_so)); 1230 1231 space = 0; 1232 if (control == NULL) 1233 panic("sbappendcontrol"); 1234 for (m = control; ; m = m->m_next) { 1235 space += m->m_len; 1236 MCLAIM(m, sb->sb_mowner); 1237 if (m->m_next == NULL) 1238 break; 1239 } 1240 n = m; /* save pointer to last control buffer */ 1241 for (m = m0; m; m = m->m_next) { 1242 MCLAIM(m, sb->sb_mowner); 1243 space += m->m_len; 1244 } 1245 if (space > sbspace(sb)) 1246 return (0); 1247 n->m_next = m0; /* concatenate data to control */ 1248 1249 SBLASTRECORDCHK(sb, "sbappendcontrol 1"); 1250 1251 for (m = control; m->m_next != NULL; m = m->m_next) 1252 sballoc(sb, m); 1253 sballoc(sb, m); 1254 mlast = m; 1255 SBLINKRECORD(sb, control); 1256 1257 sb->sb_mbtail = mlast; 1258 SBLASTMBUFCHK(sb, "sbappendcontrol"); 1259 SBLASTRECORDCHK(sb, "sbappendcontrol 2"); 1260 1261 return (1); 1262 } 1263 1264 /* 1265 * Compress mbuf chain m into the socket 1266 * buffer sb following mbuf n. If n 1267 * is null, the buffer is presumed empty. 1268 */ 1269 void 1270 sbcompress(struct sockbuf *sb, struct mbuf *m, struct mbuf *n) 1271 { 1272 int eor; 1273 struct mbuf *o; 1274 1275 KASSERT(solocked(sb->sb_so)); 1276 1277 eor = 0; 1278 while (m) { 1279 eor |= m->m_flags & M_EOR; 1280 if (m->m_len == 0 && 1281 (eor == 0 || 1282 (((o = m->m_next) || (o = n)) && 1283 o->m_type == m->m_type))) { 1284 if (sb->sb_lastrecord == m) 1285 sb->sb_lastrecord = m->m_next; 1286 m = m_free(m); 1287 continue; 1288 } 1289 if (n && (n->m_flags & M_EOR) == 0 && 1290 /* M_TRAILINGSPACE() checks buffer writeability */ 1291 m->m_len <= MCLBYTES / 4 && /* XXX Don't copy too much */ 1292 m->m_len <= M_TRAILINGSPACE(n) && 1293 n->m_type == m->m_type) { 1294 memcpy(mtod(n, char *) + n->m_len, mtod(m, void *), 1295 (unsigned)m->m_len); 1296 n->m_len += m->m_len; 1297 sb->sb_cc += m->m_len; 1298 m = m_free(m); 1299 continue; 1300 } 1301 if (n) 1302 n->m_next = m; 1303 else 1304 sb->sb_mb = m; 1305 sb->sb_mbtail = m; 1306 sballoc(sb, m); 1307 n = m; 1308 m->m_flags &= ~M_EOR; 1309 m = m->m_next; 1310 n->m_next = 0; 1311 } 1312 if (eor) { 1313 if (n) 1314 n->m_flags |= eor; 1315 else 1316 printf("semi-panic: sbcompress\n"); 1317 } 1318 SBLASTMBUFCHK(sb, __func__); 1319 } 1320 1321 /* 1322 * Free all mbufs in a sockbuf. 1323 * Check that all resources are reclaimed. 1324 */ 1325 void 1326 sbflush(struct sockbuf *sb) 1327 { 1328 1329 KASSERT(solocked(sb->sb_so)); 1330 KASSERT((sb->sb_flags & SB_LOCK) == 0); 1331 1332 while (sb->sb_mbcnt) 1333 sbdrop(sb, (int)sb->sb_cc); 1334 1335 KASSERT(sb->sb_cc == 0); 1336 KASSERT(sb->sb_mb == NULL); 1337 KASSERT(sb->sb_mbtail == NULL); 1338 KASSERT(sb->sb_lastrecord == NULL); 1339 } 1340 1341 /* 1342 * Drop data from (the front of) a sockbuf. 1343 */ 1344 void 1345 sbdrop(struct sockbuf *sb, int len) 1346 { 1347 struct mbuf *m, *next; 1348 1349 KASSERT(solocked(sb->sb_so)); 1350 1351 next = (m = sb->sb_mb) ? m->m_nextpkt : NULL; 1352 while (len > 0) { 1353 if (m == NULL) { 1354 if (next == NULL) 1355 panic("sbdrop(%p,%d): cc=%lu", 1356 sb, len, sb->sb_cc); 1357 m = next; 1358 next = m->m_nextpkt; 1359 continue; 1360 } 1361 if (m->m_len > len) { 1362 m->m_len -= len; 1363 m->m_data += len; 1364 sb->sb_cc -= len; 1365 break; 1366 } 1367 len -= m->m_len; 1368 sbfree(sb, m); 1369 m = m_free(m); 1370 } 1371 while (m && m->m_len == 0) { 1372 sbfree(sb, m); 1373 m = m_free(m); 1374 } 1375 if (m) { 1376 sb->sb_mb = m; 1377 m->m_nextpkt = next; 1378 } else 1379 sb->sb_mb = next; 1380 /* 1381 * First part is an inline SB_EMPTY_FIXUP(). Second part 1382 * makes sure sb_lastrecord is up-to-date if we dropped 1383 * part of the last record. 1384 */ 1385 m = sb->sb_mb; 1386 if (m == NULL) { 1387 sb->sb_mbtail = NULL; 1388 sb->sb_lastrecord = NULL; 1389 } else if (m->m_nextpkt == NULL) 1390 sb->sb_lastrecord = m; 1391 } 1392 1393 /* 1394 * Drop a record off the front of a sockbuf 1395 * and move the next record to the front. 1396 */ 1397 void 1398 sbdroprecord(struct sockbuf *sb) 1399 { 1400 struct mbuf *m, *mn; 1401 1402 KASSERT(solocked(sb->sb_so)); 1403 1404 m = sb->sb_mb; 1405 if (m) { 1406 sb->sb_mb = m->m_nextpkt; 1407 do { 1408 sbfree(sb, m); 1409 mn = m_free(m); 1410 } while ((m = mn) != NULL); 1411 } 1412 SB_EMPTY_FIXUP(sb); 1413 } 1414 1415 /* 1416 * Create a "control" mbuf containing the specified data 1417 * with the specified type for presentation on a socket buffer. 1418 */ 1419 struct mbuf * 1420 sbcreatecontrol1(void **p, int size, int type, int level, int flags) 1421 { 1422 struct cmsghdr *cp; 1423 struct mbuf *m; 1424 int space = CMSG_SPACE(size); 1425 1426 if ((flags & M_DONTWAIT) && space > MCLBYTES) { 1427 printf("%s: message too large %d\n", __func__, space); 1428 return NULL; 1429 } 1430 1431 if ((m = m_get(flags, MT_CONTROL)) == NULL) 1432 return NULL; 1433 if (space > MLEN) { 1434 if (space > MCLBYTES) 1435 MEXTMALLOC(m, space, M_WAITOK); 1436 else 1437 MCLGET(m, flags); 1438 if ((m->m_flags & M_EXT) == 0) { 1439 m_free(m); 1440 return NULL; 1441 } 1442 } 1443 cp = mtod(m, struct cmsghdr *); 1444 *p = CMSG_DATA(cp); 1445 m->m_len = space; 1446 cp->cmsg_len = CMSG_LEN(size); 1447 cp->cmsg_level = level; 1448 cp->cmsg_type = type; 1449 1450 memset(cp + 1, 0, CMSG_LEN(0) - sizeof(*cp)); 1451 memset((uint8_t *)*p + size, 0, CMSG_ALIGN(size) - size); 1452 1453 return m; 1454 } 1455 1456 struct mbuf * 1457 sbcreatecontrol(void *p, int size, int type, int level) 1458 { 1459 struct mbuf *m; 1460 void *v; 1461 1462 m = sbcreatecontrol1(&v, size, type, level, M_DONTWAIT); 1463 if (m == NULL) 1464 return NULL; 1465 memcpy(v, p, size); 1466 return m; 1467 } 1468 1469 void 1470 solockretry(struct socket *so, kmutex_t *lock) 1471 { 1472 1473 while (lock != atomic_load_relaxed(&so->so_lock)) { 1474 mutex_exit(lock); 1475 lock = atomic_load_consume(&so->so_lock); 1476 mutex_enter(lock); 1477 } 1478 } 1479 1480 bool 1481 solocked(const struct socket *so) 1482 { 1483 1484 /* 1485 * Used only for diagnostic assertions, so so_lock should be 1486 * stable at this point, hence on need for atomic_load_*. 1487 */ 1488 return mutex_owned(so->so_lock); 1489 } 1490 1491 bool 1492 solocked2(const struct socket *so1, const struct socket *so2) 1493 { 1494 const kmutex_t *lock; 1495 1496 /* 1497 * Used only for diagnostic assertions, so so_lock should be 1498 * stable at this point, hence on need for atomic_load_*. 1499 */ 1500 lock = so1->so_lock; 1501 if (lock != so2->so_lock) 1502 return false; 1503 return mutex_owned(lock); 1504 } 1505 1506 /* 1507 * sosetlock: assign a default lock to a new socket. 1508 */ 1509 void 1510 sosetlock(struct socket *so) 1511 { 1512 if (so->so_lock == NULL) { 1513 kmutex_t *lock = softnet_lock; 1514 1515 so->so_lock = lock; 1516 mutex_obj_hold(lock); 1517 mutex_enter(lock); 1518 } 1519 KASSERT(solocked(so)); 1520 } 1521 1522 /* 1523 * Set lock on sockbuf sb; sleep if lock is already held. 1524 * Unless SB_NOINTR is set on sockbuf, sleep is interruptible. 1525 * Returns error without lock if sleep is interrupted. 1526 */ 1527 int 1528 sblock(struct sockbuf *sb, int wf) 1529 { 1530 struct socket *so; 1531 kmutex_t *lock; 1532 int error; 1533 1534 KASSERT(solocked(sb->sb_so)); 1535 1536 for (;;) { 1537 if (__predict_true((sb->sb_flags & SB_LOCK) == 0)) { 1538 sb->sb_flags |= SB_LOCK; 1539 return 0; 1540 } 1541 if (wf != M_WAITOK) 1542 return EWOULDBLOCK; 1543 so = sb->sb_so; 1544 lock = so->so_lock; 1545 if ((sb->sb_flags & SB_NOINTR) != 0) { 1546 cv_wait(&so->so_cv, lock); 1547 error = 0; 1548 } else 1549 error = cv_wait_sig(&so->so_cv, lock); 1550 if (__predict_false(lock != atomic_load_relaxed(&so->so_lock))) 1551 solockretry(so, lock); 1552 if (error != 0) 1553 return error; 1554 } 1555 } 1556 1557 void 1558 sbunlock(struct sockbuf *sb) 1559 { 1560 struct socket *so; 1561 1562 so = sb->sb_so; 1563 1564 KASSERT(solocked(so)); 1565 KASSERT((sb->sb_flags & SB_LOCK) != 0); 1566 1567 sb->sb_flags &= ~SB_LOCK; 1568 cv_broadcast(&so->so_cv); 1569 } 1570 1571 int 1572 sowait(struct socket *so, bool catch_p, int timo) 1573 { 1574 kmutex_t *lock; 1575 int error; 1576 1577 KASSERT(solocked(so)); 1578 KASSERT(catch_p || timo != 0); 1579 1580 lock = so->so_lock; 1581 if (catch_p) 1582 error = cv_timedwait_sig(&so->so_cv, lock, timo); 1583 else 1584 error = cv_timedwait(&so->so_cv, lock, timo); 1585 if (__predict_false(lock != atomic_load_relaxed(&so->so_lock))) 1586 solockretry(so, lock); 1587 return error; 1588 } 1589 1590 #ifdef DDB 1591 1592 /* 1593 * Currently, sofindproc() is used only from DDB. It could be used from others 1594 * by using db_mutex_enter() 1595 */ 1596 1597 static inline int 1598 db_mutex_enter(kmutex_t *mtx) 1599 { 1600 int rv; 1601 1602 if (!db_active) { 1603 mutex_enter(mtx); 1604 rv = 1; 1605 } else 1606 rv = mutex_tryenter(mtx); 1607 1608 return rv; 1609 } 1610 1611 int 1612 sofindproc(struct socket *so, int all, void (*pr)(const char *, ...)) 1613 { 1614 proc_t *p; 1615 filedesc_t *fdp; 1616 fdtab_t *dt; 1617 fdfile_t *ff; 1618 file_t *fp = NULL; 1619 int found = 0; 1620 int i, t; 1621 1622 if (so == NULL) 1623 return 0; 1624 1625 t = db_mutex_enter(&proc_lock); 1626 if (!t) { 1627 pr("could not acquire proc_lock mutex\n"); 1628 return 0; 1629 } 1630 PROCLIST_FOREACH(p, &allproc) { 1631 if (p->p_stat == SIDL) 1632 continue; 1633 fdp = p->p_fd; 1634 t = db_mutex_enter(&fdp->fd_lock); 1635 if (!t) { 1636 pr("could not acquire fd_lock mutex\n"); 1637 continue; 1638 } 1639 dt = atomic_load_consume(&fdp->fd_dt); 1640 for (i = 0; i < dt->dt_nfiles; i++) { 1641 ff = dt->dt_ff[i]; 1642 if (ff == NULL) 1643 continue; 1644 1645 fp = atomic_load_consume(&ff->ff_file); 1646 if (fp == NULL) 1647 continue; 1648 1649 t = db_mutex_enter(&fp->f_lock); 1650 if (!t) { 1651 pr("could not acquire f_lock mutex\n"); 1652 continue; 1653 } 1654 if ((struct socket *)fp->f_data != so) { 1655 mutex_exit(&fp->f_lock); 1656 continue; 1657 } 1658 found++; 1659 if (pr) 1660 pr("socket %p: owner %s(pid=%d)\n", 1661 so, p->p_comm, p->p_pid); 1662 mutex_exit(&fp->f_lock); 1663 if (all == 0) 1664 break; 1665 } 1666 mutex_exit(&fdp->fd_lock); 1667 if (all == 0 && found != 0) 1668 break; 1669 } 1670 mutex_exit(&proc_lock); 1671 1672 return found; 1673 } 1674 1675 void 1676 socket_print(const char *modif, void (*pr)(const char *, ...)) 1677 { 1678 file_t *fp; 1679 struct socket *so; 1680 struct sockbuf *sb_snd, *sb_rcv; 1681 struct mbuf *m_rec, *m; 1682 bool opt_v = false; 1683 bool opt_m = false; 1684 bool opt_a = false; 1685 bool opt_p = false; 1686 int nrecs, nmbufs; 1687 char ch; 1688 const char *family; 1689 1690 while ( (ch = *(modif++)) != '\0') { 1691 switch (ch) { 1692 case 'v': 1693 opt_v = true; 1694 break; 1695 case 'm': 1696 opt_m = true; 1697 break; 1698 case 'a': 1699 opt_a = true; 1700 break; 1701 case 'p': 1702 opt_p = true; 1703 break; 1704 } 1705 } 1706 if (opt_v == false && pr) 1707 (pr)("Ignore empty sockets. use /v to print all.\n"); 1708 if (opt_p == true && pr) 1709 (pr)("Don't search owner process.\n"); 1710 1711 LIST_FOREACH(fp, &filehead, f_list) { 1712 if (fp->f_type != DTYPE_SOCKET) 1713 continue; 1714 so = (struct socket *)fp->f_data; 1715 if (so == NULL) 1716 continue; 1717 1718 if (so->so_proto->pr_domain->dom_family == AF_INET) 1719 family = "INET"; 1720 #ifdef INET6 1721 else if (so->so_proto->pr_domain->dom_family == AF_INET6) 1722 family = "INET6"; 1723 #endif 1724 else if (so->so_proto->pr_domain->dom_family == pseudo_AF_KEY) 1725 family = "KEY"; 1726 else if (so->so_proto->pr_domain->dom_family == AF_ROUTE) 1727 family = "ROUTE"; 1728 else 1729 continue; 1730 1731 sb_snd = &so->so_snd; 1732 sb_rcv = &so->so_rcv; 1733 1734 if (opt_v != true && 1735 sb_snd->sb_cc == 0 && sb_rcv->sb_cc == 0) 1736 continue; 1737 1738 pr("---SOCKET %p: type %s\n", so, family); 1739 if (opt_p != true) 1740 sofindproc(so, opt_a == true ? 1 : 0, pr); 1741 pr("Send Buffer Bytes: %d [bytes]\n", sb_snd->sb_cc); 1742 pr("Send Buffer mbufs:\n"); 1743 m_rec = m = sb_snd->sb_mb; 1744 nrecs = 0; 1745 nmbufs = 0; 1746 while (m_rec) { 1747 nrecs++; 1748 if (opt_m == true) 1749 pr(" mbuf chain %p\n", m_rec); 1750 while (m) { 1751 nmbufs++; 1752 m = m->m_next; 1753 } 1754 m_rec = m = m_rec->m_nextpkt; 1755 } 1756 pr(" Total %d records, %d mbufs.\n", nrecs, nmbufs); 1757 1758 pr("Recv Buffer Usage: %d [bytes]\n", sb_rcv->sb_cc); 1759 pr("Recv Buffer mbufs:\n"); 1760 m_rec = m = sb_rcv->sb_mb; 1761 nrecs = 0; 1762 nmbufs = 0; 1763 while (m_rec) { 1764 nrecs++; 1765 if (opt_m == true) 1766 pr(" mbuf chain %p\n", m_rec); 1767 while (m) { 1768 nmbufs++; 1769 m = m->m_next; 1770 } 1771 m_rec = m = m_rec->m_nextpkt; 1772 } 1773 pr(" Total %d records, %d mbufs.\n", nrecs, nmbufs); 1774 } 1775 } 1776 #endif /* DDB */ 1777