1 /* 2 * Copyright (c) 1994,1997 John S. Dyson 3 * All rights reserved. 4 * 5 * Redistribution and use in source and binary forms, with or without 6 * modification, are permitted provided that the following conditions 7 * are met: 8 * 1. Redistributions of source code must retain the above copyright 9 * notice immediately at the beginning of the file, without modification, 10 * this list of conditions, and the following disclaimer. 11 * 2. Absolutely no warranty of function or purpose is made by the author 12 * John S. Dyson. 13 * 14 * $FreeBSD: src/sys/kern/vfs_bio.c,v 1.242.2.20 2003/05/28 18:38:10 alc Exp $ 15 */ 16 17 /* 18 * this file contains a new buffer I/O scheme implementing a coherent 19 * VM object and buffer cache scheme. Pains have been taken to make 20 * sure that the performance degradation associated with schemes such 21 * as this is not realized. 22 * 23 * Author: John S. Dyson 24 * Significant help during the development and debugging phases 25 * had been provided by David Greenman, also of the FreeBSD core team. 26 * 27 * see man buf(9) for more info. Note that man buf(9) doesn't reflect 28 * the actual buf/bio implementation in DragonFly. 29 */ 30 31 #include <sys/param.h> 32 #include <sys/systm.h> 33 #include <sys/buf.h> 34 #include <sys/conf.h> 35 #include <sys/devicestat.h> 36 #include <sys/eventhandler.h> 37 #include <sys/lock.h> 38 #include <sys/malloc.h> 39 #include <sys/mount.h> 40 #include <sys/kernel.h> 41 #include <sys/kthread.h> 42 #include <sys/proc.h> 43 #include <sys/reboot.h> 44 #include <sys/resourcevar.h> 45 #include <sys/sysctl.h> 46 #include <sys/vmmeter.h> 47 #include <sys/vnode.h> 48 #include <sys/dsched.h> 49 #include <vm/vm.h> 50 #include <vm/vm_param.h> 51 #include <vm/vm_kern.h> 52 #include <vm/vm_pageout.h> 53 #include <vm/vm_page.h> 54 #include <vm/vm_object.h> 55 #include <vm/vm_extern.h> 56 #include <vm/vm_map.h> 57 #include <vm/vm_pager.h> 58 #include <vm/swap_pager.h> 59 60 #include <sys/buf2.h> 61 #include <sys/spinlock2.h> 62 #include <vm/vm_page2.h> 63 64 #include "opt_ddb.h" 65 #ifdef DDB 66 #include <ddb/ddb.h> 67 #endif 68 69 /* 70 * Buffer queues. 71 */ 72 enum bufq_type { 73 BQUEUE_NONE, /* not on any queue */ 74 BQUEUE_LOCKED, /* locked buffers */ 75 BQUEUE_CLEAN, /* non-B_DELWRI buffers */ 76 BQUEUE_DIRTY, /* B_DELWRI buffers */ 77 BQUEUE_DIRTY_HW, /* B_DELWRI buffers - heavy weight */ 78 BQUEUE_EMPTY, /* empty buffer headers */ 79 80 BUFFER_QUEUES /* number of buffer queues */ 81 }; 82 83 typedef enum bufq_type bufq_type_t; 84 85 #define BD_WAKE_SIZE 16384 86 #define BD_WAKE_MASK (BD_WAKE_SIZE - 1) 87 88 TAILQ_HEAD(bqueues, buf); 89 90 struct bufpcpu { 91 struct spinlock spin; 92 struct bqueues bufqueues[BUFFER_QUEUES]; 93 } __cachealign; 94 95 struct bufpcpu bufpcpu[MAXCPU]; 96 97 static MALLOC_DEFINE(M_BIOBUF, "BIO buffer", "BIO buffer"); 98 99 struct buf *buf; /* buffer header pool */ 100 101 static void vfs_clean_pages(struct buf *bp); 102 static void vfs_clean_one_page(struct buf *bp, int pageno, vm_page_t m); 103 #if 0 104 static void vfs_dirty_one_page(struct buf *bp, int pageno, vm_page_t m); 105 #endif 106 static void vfs_vmio_release(struct buf *bp); 107 static int flushbufqueues(struct buf *marker, bufq_type_t q); 108 static vm_page_t bio_page_alloc(struct buf *bp, vm_object_t obj, 109 vm_pindex_t pg, int deficit); 110 111 static void bd_signal(long totalspace); 112 static void buf_daemon(void); 113 static void buf_daemon_hw(void); 114 115 /* 116 * bogus page -- for I/O to/from partially complete buffers 117 * this is a temporary solution to the problem, but it is not 118 * really that bad. it would be better to split the buffer 119 * for input in the case of buffers partially already in memory, 120 * but the code is intricate enough already. 121 */ 122 vm_page_t bogus_page; 123 124 /* 125 * These are all static, but make the ones we export globals so we do 126 * not need to use compiler magic. 127 */ 128 long bufspace; /* atomic ops */ 129 long maxbufspace; 130 long lobufspace, hibufspace; 131 static long lorunningspace; 132 static long hirunningspace; 133 static long dirtykvaspace; /* atomic */ 134 long dirtybufspace; /* atomic (global for systat) */ 135 static long dirtybufcount; /* atomic */ 136 static long dirtybufspacehw; /* atomic */ 137 static long dirtybufcounthw; /* atomic */ 138 static long runningbufspace; /* atomic */ 139 static long runningbufcount; /* atomic */ 140 long lodirtybufspace; 141 long hidirtybufspace; 142 static int getnewbufcalls; 143 static int needsbuffer; /* atomic */ 144 static int runningbufreq; /* atomic */ 145 static int bd_request; /* atomic */ 146 static int bd_request_hw; /* atomic */ 147 static u_int bd_wake_ary[BD_WAKE_SIZE]; 148 static u_int bd_wake_index; 149 static u_int vm_cycle_point = 40; /* 23-36 will migrate more act->inact */ 150 static int debug_commit; 151 static int debug_bufbio; 152 static int debug_kvabio; 153 static long bufcache_bw = 200 * 1024 * 1024; 154 155 static struct thread *bufdaemon_td; 156 static struct thread *bufdaemonhw_td; 157 static u_int lowmempgallocs; 158 static u_int flushperqueue = 1024; 159 160 /* 161 * Sysctls for operational control of the buffer cache. 162 */ 163 SYSCTL_UINT(_vfs, OID_AUTO, flushperqueue, CTLFLAG_RW, &flushperqueue, 0, 164 "Number of buffers to flush from each per-cpu queue"); 165 SYSCTL_LONG(_vfs, OID_AUTO, lodirtybufspace, CTLFLAG_RW, &lodirtybufspace, 0, 166 "Number of dirty buffers to flush before bufdaemon becomes inactive"); 167 SYSCTL_LONG(_vfs, OID_AUTO, hidirtybufspace, CTLFLAG_RW, &hidirtybufspace, 0, 168 "High watermark used to trigger explicit flushing of dirty buffers"); 169 SYSCTL_LONG(_vfs, OID_AUTO, lorunningspace, CTLFLAG_RW, &lorunningspace, 0, 170 "Minimum amount of buffer space required for active I/O"); 171 SYSCTL_LONG(_vfs, OID_AUTO, hirunningspace, CTLFLAG_RW, &hirunningspace, 0, 172 "Maximum amount of buffer space to usable for active I/O"); 173 SYSCTL_LONG(_vfs, OID_AUTO, bufcache_bw, CTLFLAG_RW, &bufcache_bw, 0, 174 "Buffer-cache -> VM page cache transfer bandwidth"); 175 SYSCTL_UINT(_vfs, OID_AUTO, lowmempgallocs, CTLFLAG_RW, &lowmempgallocs, 0, 176 "Page allocations done during periods of very low free memory"); 177 SYSCTL_UINT(_vfs, OID_AUTO, vm_cycle_point, CTLFLAG_RW, &vm_cycle_point, 0, 178 "Recycle pages to active or inactive queue transition pt 0-64"); 179 /* 180 * Sysctls determining current state of the buffer cache. 181 */ 182 SYSCTL_LONG(_vfs, OID_AUTO, nbuf, CTLFLAG_RD, &nbuf, 0, 183 "Total number of buffers in buffer cache"); 184 SYSCTL_LONG(_vfs, OID_AUTO, dirtykvaspace, CTLFLAG_RD, &dirtykvaspace, 0, 185 "KVA reserved by dirty buffers (all)"); 186 SYSCTL_LONG(_vfs, OID_AUTO, dirtybufspace, CTLFLAG_RD, &dirtybufspace, 0, 187 "Pending bytes of dirty buffers (all)"); 188 SYSCTL_LONG(_vfs, OID_AUTO, dirtybufspacehw, CTLFLAG_RD, &dirtybufspacehw, 0, 189 "Pending bytes of dirty buffers (heavy weight)"); 190 SYSCTL_LONG(_vfs, OID_AUTO, dirtybufcount, CTLFLAG_RD, &dirtybufcount, 0, 191 "Pending number of dirty buffers"); 192 SYSCTL_LONG(_vfs, OID_AUTO, dirtybufcounthw, CTLFLAG_RD, &dirtybufcounthw, 0, 193 "Pending number of dirty buffers (heavy weight)"); 194 SYSCTL_LONG(_vfs, OID_AUTO, runningbufspace, CTLFLAG_RD, &runningbufspace, 0, 195 "I/O bytes currently in progress due to asynchronous writes"); 196 SYSCTL_LONG(_vfs, OID_AUTO, runningbufcount, CTLFLAG_RD, &runningbufcount, 0, 197 "I/O buffers currently in progress due to asynchronous writes"); 198 SYSCTL_LONG(_vfs, OID_AUTO, maxbufspace, CTLFLAG_RD, &maxbufspace, 0, 199 "Hard limit on maximum amount of memory usable for buffer space"); 200 SYSCTL_LONG(_vfs, OID_AUTO, hibufspace, CTLFLAG_RD, &hibufspace, 0, 201 "Soft limit on maximum amount of memory usable for buffer space"); 202 SYSCTL_LONG(_vfs, OID_AUTO, lobufspace, CTLFLAG_RD, &lobufspace, 0, 203 "Minimum amount of memory to reserve for system buffer space"); 204 SYSCTL_LONG(_vfs, OID_AUTO, bufspace, CTLFLAG_RD, &bufspace, 0, 205 "Amount of memory available for buffers"); 206 SYSCTL_INT(_vfs, OID_AUTO, getnewbufcalls, CTLFLAG_RD, &getnewbufcalls, 0, 207 "New buffer header acquisition requests"); 208 SYSCTL_INT(_vfs, OID_AUTO, debug_commit, CTLFLAG_RW, &debug_commit, 0, ""); 209 SYSCTL_INT(_vfs, OID_AUTO, debug_bufbio, CTLFLAG_RW, &debug_bufbio, 0, ""); 210 SYSCTL_INT(_vfs, OID_AUTO, debug_kvabio, CTLFLAG_RW, &debug_kvabio, 0, ""); 211 SYSCTL_INT(_debug_sizeof, OID_AUTO, buf, CTLFLAG_RD, 0, sizeof(struct buf), 212 "sizeof(struct buf)"); 213 214 char *buf_wmesg = BUF_WMESG; 215 216 #define VFS_BIO_NEED_ANY 0x01 /* any freeable buffer */ 217 #define VFS_BIO_NEED_UNUSED02 0x02 218 #define VFS_BIO_NEED_UNUSED04 0x04 219 #define VFS_BIO_NEED_BUFSPACE 0x08 /* wait for buf space, lo hysteresis */ 220 221 /* 222 * Called when buffer space is potentially available for recovery. 223 * getnewbuf() will block on this flag when it is unable to free 224 * sufficient buffer space. Buffer space becomes recoverable when 225 * bp's get placed back in the queues. 226 */ 227 static __inline void 228 bufspacewakeup(void) 229 { 230 /* 231 * If someone is waiting for BUF space, wake them up. Even 232 * though we haven't freed the kva space yet, the waiting 233 * process will be able to now. 234 */ 235 for (;;) { 236 int flags = needsbuffer; 237 cpu_ccfence(); 238 if ((flags & VFS_BIO_NEED_BUFSPACE) == 0) 239 break; 240 if (atomic_cmpset_int(&needsbuffer, flags, 241 flags & ~VFS_BIO_NEED_BUFSPACE)) { 242 wakeup(&needsbuffer); 243 break; 244 } 245 /* retry */ 246 } 247 } 248 249 /* 250 * runningbufwakeup: 251 * 252 * Accounting for I/O in progress. 253 * 254 */ 255 static __inline void 256 runningbufwakeup(struct buf *bp) 257 { 258 long totalspace; 259 long flags; 260 261 if ((totalspace = bp->b_runningbufspace) != 0) { 262 atomic_add_long(&runningbufspace, -totalspace); 263 atomic_add_long(&runningbufcount, -1); 264 bp->b_runningbufspace = 0; 265 266 /* 267 * see waitrunningbufspace() for limit test. 268 */ 269 for (;;) { 270 flags = runningbufreq; 271 cpu_ccfence(); 272 if (flags == 0) 273 break; 274 if (atomic_cmpset_int(&runningbufreq, flags, 0)) { 275 wakeup(&runningbufreq); 276 break; 277 } 278 /* retry */ 279 } 280 bd_signal(totalspace); 281 } 282 } 283 284 /* 285 * bufcountwakeup: 286 * 287 * Called when a buffer has been added to one of the free queues to 288 * account for the buffer and to wakeup anyone waiting for free buffers. 289 * This typically occurs when large amounts of metadata are being handled 290 * by the buffer cache ( else buffer space runs out first, usually ). 291 */ 292 static __inline void 293 bufcountwakeup(void) 294 { 295 long flags; 296 297 for (;;) { 298 flags = needsbuffer; 299 if (flags == 0) 300 break; 301 if (atomic_cmpset_int(&needsbuffer, flags, 302 (flags & ~VFS_BIO_NEED_ANY))) { 303 wakeup(&needsbuffer); 304 break; 305 } 306 /* retry */ 307 } 308 } 309 310 /* 311 * waitrunningbufspace() 312 * 313 * If runningbufspace exceeds 4/6 hirunningspace we block until 314 * runningbufspace drops to 3/6 hirunningspace. We also block if another 315 * thread blocked here in order to be fair, even if runningbufspace 316 * is now lower than the limit. 317 * 318 * The caller may be using this function to block in a tight loop, we 319 * must block while runningbufspace is greater than at least 320 * hirunningspace * 3 / 6. 321 */ 322 void 323 waitrunningbufspace(void) 324 { 325 long limit = hirunningspace * 4 / 6; 326 long flags; 327 328 while (runningbufspace > limit || runningbufreq) { 329 tsleep_interlock(&runningbufreq, 0); 330 flags = atomic_fetchadd_int(&runningbufreq, 1); 331 if (runningbufspace > limit || flags) 332 tsleep(&runningbufreq, PINTERLOCKED, "wdrn1", hz); 333 } 334 } 335 336 /* 337 * buf_dirty_count_severe: 338 * 339 * Return true if we have too many dirty buffers. 340 */ 341 int 342 buf_dirty_count_severe(void) 343 { 344 return (runningbufspace + dirtykvaspace >= hidirtybufspace || 345 dirtybufcount >= nbuf / 2); 346 } 347 348 /* 349 * Return true if the amount of running I/O is severe and BIOQ should 350 * start bursting. 351 */ 352 int 353 buf_runningbufspace_severe(void) 354 { 355 return (runningbufspace >= hirunningspace * 4 / 6); 356 } 357 358 /* 359 * vfs_buf_test_cache: 360 * 361 * Called when a buffer is extended. This function clears the B_CACHE 362 * bit if the newly extended portion of the buffer does not contain 363 * valid data. 364 * 365 * NOTE! Dirty VM pages are not processed into dirty (B_DELWRI) buffer 366 * cache buffers. The VM pages remain dirty, as someone had mmap()'d 367 * them while a clean buffer was present. 368 */ 369 static __inline__ 370 void 371 vfs_buf_test_cache(struct buf *bp, 372 vm_ooffset_t foff, vm_offset_t off, vm_offset_t size, 373 vm_page_t m) 374 { 375 if (bp->b_flags & B_CACHE) { 376 int base = (foff + off) & PAGE_MASK; 377 if (vm_page_is_valid(m, base, size) == 0) 378 bp->b_flags &= ~B_CACHE; 379 } 380 } 381 382 /* 383 * bd_speedup() 384 * 385 * Spank the buf_daemon[_hw] if the total dirty buffer space exceeds the 386 * low water mark. 387 */ 388 static __inline__ 389 void 390 bd_speedup(void) 391 { 392 if (dirtykvaspace < lodirtybufspace && dirtybufcount < nbuf / 2) 393 return; 394 395 if (bd_request == 0 && 396 (dirtykvaspace > lodirtybufspace / 2 || 397 dirtybufcount - dirtybufcounthw >= nbuf / 2)) { 398 if (atomic_fetchadd_int(&bd_request, 1) == 0) 399 wakeup(&bd_request); 400 } 401 if (bd_request_hw == 0 && 402 (dirtykvaspace > lodirtybufspace / 2 || 403 dirtybufcounthw >= nbuf / 2)) { 404 if (atomic_fetchadd_int(&bd_request_hw, 1) == 0) 405 wakeup(&bd_request_hw); 406 } 407 } 408 409 /* 410 * bd_heatup() 411 * 412 * Get the buf_daemon heated up when the number of running and dirty 413 * buffers exceeds the mid-point. 414 * 415 * Return the total number of dirty bytes past the second mid point 416 * as a measure of how much excess dirty data there is in the system. 417 */ 418 long 419 bd_heatup(void) 420 { 421 long mid1; 422 long mid2; 423 long totalspace; 424 425 mid1 = lodirtybufspace + (hidirtybufspace - lodirtybufspace) / 2; 426 427 totalspace = runningbufspace + dirtykvaspace; 428 if (totalspace >= mid1 || dirtybufcount >= nbuf / 2) { 429 bd_speedup(); 430 mid2 = mid1 + (hidirtybufspace - mid1) / 2; 431 if (totalspace >= mid2) 432 return(totalspace - mid2); 433 } 434 return(0); 435 } 436 437 /* 438 * bd_wait() 439 * 440 * Wait for the buffer cache to flush (totalspace) bytes worth of 441 * buffers, then return. 442 * 443 * Regardless this function blocks while the number of dirty buffers 444 * exceeds hidirtybufspace. 445 */ 446 void 447 bd_wait(long totalspace) 448 { 449 u_int i; 450 u_int j; 451 u_int mi; 452 int count; 453 454 if (curthread == bufdaemonhw_td || curthread == bufdaemon_td) 455 return; 456 457 while (totalspace > 0) { 458 bd_heatup(); 459 460 /* 461 * Order is important. Suppliers adjust bd_wake_index after 462 * updating runningbufspace/dirtykvaspace. We want to fetch 463 * bd_wake_index before accessing. Any error should thus 464 * be in our favor. 465 */ 466 i = atomic_fetchadd_int(&bd_wake_index, 0); 467 if (totalspace > runningbufspace + dirtykvaspace) 468 totalspace = runningbufspace + dirtykvaspace; 469 count = totalspace / MAXBSIZE; 470 if (count >= BD_WAKE_SIZE / 2) 471 count = BD_WAKE_SIZE / 2; 472 i = i + count; 473 mi = i & BD_WAKE_MASK; 474 475 /* 476 * This is not a strict interlock, so we play a bit loose 477 * with locking access to dirtybufspace*. We have to re-check 478 * bd_wake_index to ensure that it hasn't passed us. 479 */ 480 tsleep_interlock(&bd_wake_ary[mi], 0); 481 atomic_add_int(&bd_wake_ary[mi], 1); 482 j = atomic_fetchadd_int(&bd_wake_index, 0); 483 if ((int)(i - j) >= 0) 484 tsleep(&bd_wake_ary[mi], PINTERLOCKED, "flstik", hz); 485 486 totalspace = runningbufspace + dirtykvaspace - hidirtybufspace; 487 } 488 } 489 490 /* 491 * bd_signal() 492 * 493 * This function is called whenever runningbufspace or dirtykvaspace 494 * is reduced. Track threads waiting for run+dirty buffer I/O 495 * complete. 496 */ 497 static void 498 bd_signal(long totalspace) 499 { 500 u_int i; 501 502 if (totalspace > 0) { 503 if (totalspace > MAXBSIZE * BD_WAKE_SIZE) 504 totalspace = MAXBSIZE * BD_WAKE_SIZE; 505 while (totalspace > 0) { 506 i = atomic_fetchadd_int(&bd_wake_index, 1); 507 i &= BD_WAKE_MASK; 508 if (atomic_readandclear_int(&bd_wake_ary[i])) 509 wakeup(&bd_wake_ary[i]); 510 totalspace -= MAXBSIZE; 511 } 512 } 513 } 514 515 /* 516 * BIO tracking support routines. 517 * 518 * Release a ref on a bio_track. Wakeup requests are atomically released 519 * along with the last reference so bk_active will never wind up set to 520 * only 0x80000000. 521 */ 522 static 523 void 524 bio_track_rel(struct bio_track *track) 525 { 526 int active; 527 int desired; 528 529 /* 530 * Shortcut 531 */ 532 active = track->bk_active; 533 if (active == 1 && atomic_cmpset_int(&track->bk_active, 1, 0)) 534 return; 535 536 /* 537 * Full-on. Note that the wait flag is only atomically released on 538 * the 1->0 count transition. 539 * 540 * We check for a negative count transition using bit 30 since bit 31 541 * has a different meaning. 542 */ 543 for (;;) { 544 desired = (active & 0x7FFFFFFF) - 1; 545 if (desired) 546 desired |= active & 0x80000000; 547 if (atomic_cmpset_int(&track->bk_active, active, desired)) { 548 if (desired & 0x40000000) 549 panic("bio_track_rel: bad count: %p", track); 550 if (active & 0x80000000) 551 wakeup(track); 552 break; 553 } 554 active = track->bk_active; 555 } 556 } 557 558 /* 559 * Wait for the tracking count to reach 0. 560 * 561 * Use atomic ops such that the wait flag is only set atomically when 562 * bk_active is non-zero. 563 */ 564 int 565 bio_track_wait(struct bio_track *track, int slp_flags, int slp_timo) 566 { 567 int active; 568 int desired; 569 int error; 570 571 /* 572 * Shortcut 573 */ 574 if (track->bk_active == 0) 575 return(0); 576 577 /* 578 * Full-on. Note that the wait flag may only be atomically set if 579 * the active count is non-zero. 580 * 581 * NOTE: We cannot optimize active == desired since a wakeup could 582 * clear active prior to our tsleep_interlock(). 583 */ 584 error = 0; 585 while ((active = track->bk_active) != 0) { 586 cpu_ccfence(); 587 desired = active | 0x80000000; 588 tsleep_interlock(track, slp_flags); 589 if (atomic_cmpset_int(&track->bk_active, active, desired)) { 590 error = tsleep(track, slp_flags | PINTERLOCKED, 591 "trwait", slp_timo); 592 if (error) 593 break; 594 } 595 } 596 return (error); 597 } 598 599 /* 600 * bufinit: 601 * 602 * Load time initialisation of the buffer cache, called from machine 603 * dependant initialization code. 604 */ 605 static 606 void 607 bufinit(void *dummy __unused) 608 { 609 struct bufpcpu *pcpu; 610 struct buf *bp; 611 vm_offset_t bogus_offset; 612 int i; 613 int j; 614 long n; 615 616 /* next, make a null set of free lists */ 617 for (i = 0; i < ncpus; ++i) { 618 pcpu = &bufpcpu[i]; 619 spin_init(&pcpu->spin, "bufinit"); 620 for (j = 0; j < BUFFER_QUEUES; j++) 621 TAILQ_INIT(&pcpu->bufqueues[j]); 622 } 623 624 /* 625 * Finally, initialize each buffer header and stick on empty q. 626 * Each buffer gets its own KVA reservation. 627 */ 628 i = 0; 629 pcpu = &bufpcpu[i]; 630 631 for (n = 0; n < nbuf; n++) { 632 bp = &buf[n]; 633 bzero(bp, sizeof *bp); 634 bp->b_flags = B_INVAL; /* we're just an empty header */ 635 bp->b_cmd = BUF_CMD_DONE; 636 bp->b_qindex = BQUEUE_EMPTY; 637 bp->b_qcpu = i; 638 bp->b_kvabase = (void *)(vm_map_min(buffer_map) + 639 MAXBSIZE * n); 640 bp->b_kvasize = MAXBSIZE; 641 initbufbio(bp); 642 xio_init(&bp->b_xio); 643 buf_dep_init(bp); 644 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 645 bp, b_freelist); 646 647 i = (i + 1) % ncpus; 648 pcpu = &bufpcpu[i]; 649 } 650 651 /* 652 * maxbufspace is the absolute maximum amount of buffer space we are 653 * allowed to reserve in KVM and in real terms. The absolute maximum 654 * is nominally used by buf_daemon. hibufspace is the nominal maximum 655 * used by most other processes. The differential is required to 656 * ensure that buf_daemon is able to run when other processes might 657 * be blocked waiting for buffer space. 658 * 659 * Calculate hysteresis (lobufspace, hibufspace). Don't make it 660 * too large or we might lockup a cpu for too long a period of 661 * time in our tight loop. 662 */ 663 maxbufspace = nbuf * NBUFCALCSIZE; 664 hibufspace = lmax(3 * maxbufspace / 4, maxbufspace - MAXBSIZE * 10); 665 lobufspace = hibufspace * 7 / 8; 666 if (hibufspace - lobufspace > 64 * 1024 * 1024) 667 lobufspace = hibufspace - 64 * 1024 * 1024; 668 if (lobufspace > hibufspace - MAXBSIZE) 669 lobufspace = hibufspace - MAXBSIZE; 670 671 lorunningspace = 512 * 1024; 672 /* hirunningspace -- see below */ 673 674 /* 675 * Reduce the chance of a deadlock occuring by limiting the number 676 * of delayed-write dirty buffers we allow to stack up. 677 * 678 * We don't want too much actually queued to the device at once 679 * (XXX this needs to be per-mount!), because the buffers will 680 * wind up locked for a very long period of time while the I/O 681 * drains. 682 */ 683 hidirtybufspace = hibufspace / 2; /* dirty + running */ 684 hirunningspace = hibufspace / 16; /* locked & queued to device */ 685 if (hirunningspace < 1024 * 1024) 686 hirunningspace = 1024 * 1024; 687 688 dirtykvaspace = 0; 689 dirtybufspace = 0; 690 dirtybufspacehw = 0; 691 692 lodirtybufspace = hidirtybufspace / 2; 693 694 /* 695 * Maximum number of async ops initiated per buf_daemon loop. This is 696 * somewhat of a hack at the moment, we really need to limit ourselves 697 * based on the number of bytes of I/O in-transit that were initiated 698 * from buf_daemon. 699 */ 700 701 bogus_offset = kmem_alloc_pageable(kernel_map, PAGE_SIZE, 702 VM_SUBSYS_BOGUS); 703 vm_object_hold(kernel_object); 704 bogus_page = vm_page_alloc(kernel_object, 705 (bogus_offset >> PAGE_SHIFT), 706 VM_ALLOC_NORMAL); 707 vm_object_drop(kernel_object); 708 vmstats.v_wire_count++; 709 710 } 711 712 SYSINIT(do_bufinit, SI_BOOT2_MACHDEP, SI_ORDER_FIRST, bufinit, NULL); 713 714 /* 715 * Initialize the embedded bio structures, typically used by 716 * deprecated code which tries to allocate its own struct bufs. 717 */ 718 void 719 initbufbio(struct buf *bp) 720 { 721 bp->b_bio1.bio_buf = bp; 722 bp->b_bio1.bio_prev = NULL; 723 bp->b_bio1.bio_offset = NOOFFSET; 724 bp->b_bio1.bio_next = &bp->b_bio2; 725 bp->b_bio1.bio_done = NULL; 726 bp->b_bio1.bio_flags = 0; 727 728 bp->b_bio2.bio_buf = bp; 729 bp->b_bio2.bio_prev = &bp->b_bio1; 730 bp->b_bio2.bio_offset = NOOFFSET; 731 bp->b_bio2.bio_next = NULL; 732 bp->b_bio2.bio_done = NULL; 733 bp->b_bio2.bio_flags = 0; 734 735 BUF_LOCKINIT(bp); 736 } 737 738 /* 739 * Reinitialize the embedded bio structures as well as any additional 740 * translation cache layers. 741 */ 742 void 743 reinitbufbio(struct buf *bp) 744 { 745 struct bio *bio; 746 747 for (bio = &bp->b_bio1; bio; bio = bio->bio_next) { 748 bio->bio_done = NULL; 749 bio->bio_offset = NOOFFSET; 750 } 751 } 752 753 /* 754 * Undo the effects of an initbufbio(). 755 */ 756 void 757 uninitbufbio(struct buf *bp) 758 { 759 dsched_buf_exit(bp); 760 BUF_LOCKFREE(bp); 761 } 762 763 /* 764 * Push another BIO layer onto an existing BIO and return it. The new 765 * BIO layer may already exist, holding cached translation data. 766 */ 767 struct bio * 768 push_bio(struct bio *bio) 769 { 770 struct bio *nbio; 771 772 if ((nbio = bio->bio_next) == NULL) { 773 int index = bio - &bio->bio_buf->b_bio_array[0]; 774 if (index >= NBUF_BIO - 1) { 775 panic("push_bio: too many layers %d for bp %p", 776 index, bio->bio_buf); 777 } 778 nbio = &bio->bio_buf->b_bio_array[index + 1]; 779 bio->bio_next = nbio; 780 nbio->bio_prev = bio; 781 nbio->bio_buf = bio->bio_buf; 782 nbio->bio_offset = NOOFFSET; 783 nbio->bio_done = NULL; 784 nbio->bio_next = NULL; 785 } 786 KKASSERT(nbio->bio_done == NULL); 787 return(nbio); 788 } 789 790 /* 791 * Pop a BIO translation layer, returning the previous layer. The 792 * must have been previously pushed. 793 */ 794 struct bio * 795 pop_bio(struct bio *bio) 796 { 797 return(bio->bio_prev); 798 } 799 800 void 801 clearbiocache(struct bio *bio) 802 { 803 while (bio) { 804 bio->bio_offset = NOOFFSET; 805 bio = bio->bio_next; 806 } 807 } 808 809 /* 810 * Remove the buffer from the appropriate free list. 811 * (caller must be locked) 812 */ 813 static __inline void 814 _bremfree(struct buf *bp) 815 { 816 struct bufpcpu *pcpu = &bufpcpu[bp->b_qcpu]; 817 818 if (bp->b_qindex != BQUEUE_NONE) { 819 KASSERT(BUF_LOCKINUSE(bp), ("bremfree: bp %p not locked", bp)); 820 TAILQ_REMOVE(&pcpu->bufqueues[bp->b_qindex], bp, b_freelist); 821 bp->b_qindex = BQUEUE_NONE; 822 } else { 823 if (!BUF_LOCKINUSE(bp)) 824 panic("bremfree: removing a buffer not on a queue"); 825 } 826 } 827 828 /* 829 * bremfree() - must be called with a locked buffer 830 */ 831 void 832 bremfree(struct buf *bp) 833 { 834 struct bufpcpu *pcpu = &bufpcpu[bp->b_qcpu]; 835 836 spin_lock(&pcpu->spin); 837 _bremfree(bp); 838 spin_unlock(&pcpu->spin); 839 } 840 841 /* 842 * bremfree_locked - must be called with pcpu->spin locked 843 */ 844 static void 845 bremfree_locked(struct buf *bp) 846 { 847 _bremfree(bp); 848 } 849 850 /* 851 * This version of bread issues any required I/O asyncnronously and 852 * makes a callback on completion. 853 * 854 * The callback must check whether BIO_DONE is set in the bio and issue 855 * the bpdone(bp, 0) if it isn't. The callback is responsible for clearing 856 * BIO_DONE and disposing of the I/O (bqrelse()ing it). 857 */ 858 void 859 breadcb(struct vnode *vp, off_t loffset, int size, int bflags, 860 void (*func)(struct bio *), void *arg) 861 { 862 struct buf *bp; 863 864 bp = getblk(vp, loffset, size, 0, 0); 865 866 /* if not found in cache, do some I/O */ 867 if ((bp->b_flags & B_CACHE) == 0) { 868 bp->b_flags &= ~(B_ERROR | B_EINTR | B_INVAL | B_NOTMETA); 869 bp->b_flags |= bflags; 870 bp->b_cmd = BUF_CMD_READ; 871 bp->b_bio1.bio_done = func; 872 bp->b_bio1.bio_caller_info1.ptr = arg; 873 vfs_busy_pages(vp, bp); 874 BUF_KERNPROC(bp); 875 vn_strategy(vp, &bp->b_bio1); 876 } else if (func) { 877 /* 878 * Since we are issuing the callback synchronously it cannot 879 * race the BIO_DONE, so no need for atomic ops here. 880 */ 881 /*bp->b_bio1.bio_done = func;*/ 882 bp->b_bio1.bio_caller_info1.ptr = arg; 883 bp->b_bio1.bio_flags |= BIO_DONE; 884 func(&bp->b_bio1); 885 } else { 886 bqrelse(bp); 887 } 888 } 889 890 /* 891 * breadnx() - Terminal function for bread() and breadn(). 892 * 893 * This function will start asynchronous I/O on read-ahead blocks as well 894 * as satisfy the primary request. 895 * 896 * We must clear B_ERROR and B_INVAL prior to initiating I/O. If B_CACHE is 897 * set, the buffer is valid and we do not have to do anything. 898 */ 899 int 900 breadnx(struct vnode *vp, off_t loffset, int size, int bflags, 901 off_t *raoffset, int *rabsize, 902 int cnt, struct buf **bpp) 903 { 904 struct buf *bp, *rabp; 905 int i; 906 int rv = 0, readwait = 0; 907 int blkflags = (bflags & B_KVABIO) ? GETBLK_KVABIO : 0; 908 909 if (*bpp) 910 bp = *bpp; 911 else 912 *bpp = bp = getblk(vp, loffset, size, blkflags, 0); 913 914 /* if not found in cache, do some I/O */ 915 if ((bp->b_flags & B_CACHE) == 0) { 916 bp->b_flags &= ~(B_ERROR | B_EINTR | B_INVAL | B_NOTMETA); 917 bp->b_flags |= bflags; 918 bp->b_cmd = BUF_CMD_READ; 919 bp->b_bio1.bio_done = biodone_sync; 920 bp->b_bio1.bio_flags |= BIO_SYNC; 921 vfs_busy_pages(vp, bp); 922 vn_strategy(vp, &bp->b_bio1); 923 ++readwait; 924 } 925 926 for (i = 0; i < cnt; i++, raoffset++, rabsize++) { 927 if (inmem(vp, *raoffset)) 928 continue; 929 rabp = getblk(vp, *raoffset, *rabsize, GETBLK_KVABIO, 0); 930 931 if ((rabp->b_flags & B_CACHE) == 0) { 932 rabp->b_flags &= ~(B_ERROR | B_EINTR | 933 B_INVAL | B_NOTMETA); 934 rabp->b_flags |= (bflags & ~B_KVABIO); 935 rabp->b_cmd = BUF_CMD_READ; 936 vfs_busy_pages(vp, rabp); 937 BUF_KERNPROC(rabp); 938 vn_strategy(vp, &rabp->b_bio1); 939 } else { 940 brelse(rabp); 941 } 942 } 943 if (readwait) 944 rv = biowait(&bp->b_bio1, "biord"); 945 return (rv); 946 } 947 948 /* 949 * bwrite: 950 * 951 * Synchronous write, waits for completion. 952 * 953 * Write, release buffer on completion. (Done by iodone 954 * if async). Do not bother writing anything if the buffer 955 * is invalid. 956 * 957 * Note that we set B_CACHE here, indicating that buffer is 958 * fully valid and thus cacheable. This is true even of NFS 959 * now so we set it generally. This could be set either here 960 * or in biodone() since the I/O is synchronous. We put it 961 * here. 962 */ 963 int 964 bwrite(struct buf *bp) 965 { 966 int error; 967 968 if (bp->b_flags & B_INVAL) { 969 brelse(bp); 970 return (0); 971 } 972 if (BUF_LOCKINUSE(bp) == 0) 973 panic("bwrite: buffer is not busy???"); 974 975 /* 976 * NOTE: We no longer mark the buffer clear prior to the vn_strategy() 977 * call because it will remove the buffer from the vnode's 978 * dirty buffer list prematurely and possibly cause filesystem 979 * checks to race buffer flushes. This is now handled in 980 * bpdone(). 981 * 982 * bundirty(bp); REMOVED 983 */ 984 985 bp->b_flags &= ~(B_ERROR | B_EINTR); 986 bp->b_flags |= B_CACHE; 987 bp->b_cmd = BUF_CMD_WRITE; 988 bp->b_error = 0; 989 bp->b_bio1.bio_done = biodone_sync; 990 bp->b_bio1.bio_flags |= BIO_SYNC; 991 vfs_busy_pages(bp->b_vp, bp); 992 993 /* 994 * Normal bwrites pipeline writes. NOTE: b_bufsize is only 995 * valid for vnode-backed buffers. 996 */ 997 bsetrunningbufspace(bp, bp->b_bufsize); 998 vn_strategy(bp->b_vp, &bp->b_bio1); 999 error = biowait(&bp->b_bio1, "biows"); 1000 brelse(bp); 1001 1002 return (error); 1003 } 1004 1005 /* 1006 * bawrite: 1007 * 1008 * Asynchronous write. Start output on a buffer, but do not wait for 1009 * it to complete. The buffer is released when the output completes. 1010 * 1011 * bwrite() ( or the VOP routine anyway ) is responsible for handling 1012 * B_INVAL buffers. Not us. 1013 */ 1014 void 1015 bawrite(struct buf *bp) 1016 { 1017 if (bp->b_flags & B_INVAL) { 1018 brelse(bp); 1019 return; 1020 } 1021 if (BUF_LOCKINUSE(bp) == 0) 1022 panic("bawrite: buffer is not busy???"); 1023 1024 /* 1025 * NOTE: We no longer mark the buffer clear prior to the vn_strategy() 1026 * call because it will remove the buffer from the vnode's 1027 * dirty buffer list prematurely and possibly cause filesystem 1028 * checks to race buffer flushes. This is now handled in 1029 * bpdone(). 1030 * 1031 * bundirty(bp); REMOVED 1032 */ 1033 bp->b_flags &= ~(B_ERROR | B_EINTR); 1034 bp->b_flags |= B_CACHE; 1035 bp->b_cmd = BUF_CMD_WRITE; 1036 bp->b_error = 0; 1037 KKASSERT(bp->b_bio1.bio_done == NULL); 1038 vfs_busy_pages(bp->b_vp, bp); 1039 1040 /* 1041 * Normal bwrites pipeline writes. NOTE: b_bufsize is only 1042 * valid for vnode-backed buffers. 1043 */ 1044 bsetrunningbufspace(bp, bp->b_bufsize); 1045 BUF_KERNPROC(bp); 1046 vn_strategy(bp->b_vp, &bp->b_bio1); 1047 } 1048 1049 /* 1050 * bdwrite: 1051 * 1052 * Delayed write. (Buffer is marked dirty). Do not bother writing 1053 * anything if the buffer is marked invalid. 1054 * 1055 * Note that since the buffer must be completely valid, we can safely 1056 * set B_CACHE. In fact, we have to set B_CACHE here rather then in 1057 * biodone() in order to prevent getblk from writing the buffer 1058 * out synchronously. 1059 */ 1060 void 1061 bdwrite(struct buf *bp) 1062 { 1063 if (BUF_LOCKINUSE(bp) == 0) 1064 panic("bdwrite: buffer is not busy"); 1065 1066 if (bp->b_flags & B_INVAL) { 1067 brelse(bp); 1068 return; 1069 } 1070 bdirty(bp); 1071 1072 dsched_buf_enter(bp); /* might stack */ 1073 1074 /* 1075 * Set B_CACHE, indicating that the buffer is fully valid. This is 1076 * true even of NFS now. 1077 */ 1078 bp->b_flags |= B_CACHE; 1079 1080 /* 1081 * This bmap keeps the system from needing to do the bmap later, 1082 * perhaps when the system is attempting to do a sync. Since it 1083 * is likely that the indirect block -- or whatever other datastructure 1084 * that the filesystem needs is still in memory now, it is a good 1085 * thing to do this. Note also, that if the pageout daemon is 1086 * requesting a sync -- there might not be enough memory to do 1087 * the bmap then... So, this is important to do. 1088 */ 1089 if (bp->b_bio2.bio_offset == NOOFFSET) { 1090 VOP_BMAP(bp->b_vp, bp->b_loffset, &bp->b_bio2.bio_offset, 1091 NULL, NULL, BUF_CMD_WRITE); 1092 } 1093 1094 /* 1095 * Because the underlying pages may still be mapped and 1096 * writable trying to set the dirty buffer (b_dirtyoff/end) 1097 * range here will be inaccurate. 1098 * 1099 * However, we must still clean the pages to satisfy the 1100 * vnode_pager and pageout daemon, so they think the pages 1101 * have been "cleaned". What has really occured is that 1102 * they've been earmarked for later writing by the buffer 1103 * cache. 1104 * 1105 * So we get the b_dirtyoff/end update but will not actually 1106 * depend on it (NFS that is) until the pages are busied for 1107 * writing later on. 1108 */ 1109 vfs_clean_pages(bp); 1110 bqrelse(bp); 1111 1112 /* 1113 * note: we cannot initiate I/O from a bdwrite even if we wanted to, 1114 * due to the softdep code. 1115 */ 1116 } 1117 1118 /* 1119 * Fake write - return pages to VM system as dirty, leave the buffer clean. 1120 * This is used by tmpfs. 1121 * 1122 * It is important for any VFS using this routine to NOT use it for 1123 * IO_SYNC or IO_ASYNC operations which occur when the system really 1124 * wants to flush VM pages to backing store. 1125 */ 1126 void 1127 buwrite(struct buf *bp) 1128 { 1129 vm_page_t m; 1130 int i; 1131 1132 /* 1133 * Only works for VMIO buffers. If the buffer is already 1134 * marked for delayed-write we can't avoid the bdwrite(). 1135 */ 1136 if ((bp->b_flags & B_VMIO) == 0 || (bp->b_flags & B_DELWRI)) { 1137 bdwrite(bp); 1138 return; 1139 } 1140 1141 /* 1142 * Mark as needing a commit. 1143 */ 1144 for (i = 0; i < bp->b_xio.xio_npages; i++) { 1145 m = bp->b_xio.xio_pages[i]; 1146 vm_page_need_commit(m); 1147 } 1148 bqrelse(bp); 1149 } 1150 1151 /* 1152 * bdirty: 1153 * 1154 * Turn buffer into delayed write request by marking it B_DELWRI. 1155 * B_RELBUF and B_NOCACHE must be cleared. 1156 * 1157 * We reassign the buffer to itself to properly update it in the 1158 * dirty/clean lists. 1159 * 1160 * Must be called from a critical section. 1161 * The buffer must be on BQUEUE_NONE. 1162 */ 1163 void 1164 bdirty(struct buf *bp) 1165 { 1166 KASSERT(bp->b_qindex == BQUEUE_NONE, 1167 ("bdirty: buffer %p still on queue %d", bp, bp->b_qindex)); 1168 if (bp->b_flags & B_NOCACHE) { 1169 kprintf("bdirty: clearing B_NOCACHE on buf %p\n", bp); 1170 bp->b_flags &= ~B_NOCACHE; 1171 } 1172 if (bp->b_flags & B_INVAL) { 1173 kprintf("bdirty: warning, dirtying invalid buffer %p\n", bp); 1174 } 1175 bp->b_flags &= ~B_RELBUF; 1176 1177 if ((bp->b_flags & B_DELWRI) == 0) { 1178 lwkt_gettoken(&bp->b_vp->v_token); 1179 bp->b_flags |= B_DELWRI; 1180 reassignbuf(bp); 1181 lwkt_reltoken(&bp->b_vp->v_token); 1182 1183 atomic_add_long(&dirtybufcount, 1); 1184 atomic_add_long(&dirtykvaspace, bp->b_kvasize); 1185 atomic_add_long(&dirtybufspace, bp->b_bufsize); 1186 if (bp->b_flags & B_HEAVY) { 1187 atomic_add_long(&dirtybufcounthw, 1); 1188 atomic_add_long(&dirtybufspacehw, bp->b_bufsize); 1189 } 1190 bd_heatup(); 1191 } 1192 } 1193 1194 /* 1195 * Set B_HEAVY, indicating that this is a heavy-weight buffer that 1196 * needs to be flushed with a different buf_daemon thread to avoid 1197 * deadlocks. B_HEAVY also imposes restrictions in getnewbuf(). 1198 */ 1199 void 1200 bheavy(struct buf *bp) 1201 { 1202 if ((bp->b_flags & B_HEAVY) == 0) { 1203 bp->b_flags |= B_HEAVY; 1204 if (bp->b_flags & B_DELWRI) { 1205 atomic_add_long(&dirtybufcounthw, 1); 1206 atomic_add_long(&dirtybufspacehw, bp->b_bufsize); 1207 } 1208 } 1209 } 1210 1211 /* 1212 * bundirty: 1213 * 1214 * Clear B_DELWRI for buffer. 1215 * 1216 * Must be called from a critical section. 1217 * 1218 * The buffer is typically on BQUEUE_NONE but there is one case in 1219 * brelse() that calls this function after placing the buffer on 1220 * a different queue. 1221 */ 1222 void 1223 bundirty(struct buf *bp) 1224 { 1225 if (bp->b_flags & B_DELWRI) { 1226 lwkt_gettoken(&bp->b_vp->v_token); 1227 bp->b_flags &= ~B_DELWRI; 1228 reassignbuf(bp); 1229 lwkt_reltoken(&bp->b_vp->v_token); 1230 1231 atomic_add_long(&dirtybufcount, -1); 1232 atomic_add_long(&dirtykvaspace, -bp->b_kvasize); 1233 atomic_add_long(&dirtybufspace, -bp->b_bufsize); 1234 if (bp->b_flags & B_HEAVY) { 1235 atomic_add_long(&dirtybufcounthw, -1); 1236 atomic_add_long(&dirtybufspacehw, -bp->b_bufsize); 1237 } 1238 bd_signal(bp->b_bufsize); 1239 } 1240 /* 1241 * Since it is now being written, we can clear its deferred write flag. 1242 */ 1243 bp->b_flags &= ~B_DEFERRED; 1244 } 1245 1246 /* 1247 * Set the b_runningbufspace field, used to track how much I/O is 1248 * in progress at any given moment. 1249 */ 1250 void 1251 bsetrunningbufspace(struct buf *bp, int bytes) 1252 { 1253 bp->b_runningbufspace = bytes; 1254 if (bytes) { 1255 atomic_add_long(&runningbufspace, bytes); 1256 atomic_add_long(&runningbufcount, 1); 1257 } 1258 } 1259 1260 /* 1261 * brelse: 1262 * 1263 * Release a busy buffer and, if requested, free its resources. The 1264 * buffer will be stashed in the appropriate bufqueue[] allowing it 1265 * to be accessed later as a cache entity or reused for other purposes. 1266 */ 1267 void 1268 brelse(struct buf *bp) 1269 { 1270 struct bufpcpu *pcpu; 1271 #ifdef INVARIANTS 1272 int saved_flags = bp->b_flags; 1273 #endif 1274 1275 KASSERT(!(bp->b_flags & (B_CLUSTER|B_PAGING)), 1276 ("brelse: inappropriate B_PAGING or B_CLUSTER bp %p", bp)); 1277 1278 /* 1279 * If B_NOCACHE is set we are being asked to destroy the buffer and 1280 * its backing store. Clear B_DELWRI. 1281 * 1282 * B_NOCACHE is set in two cases: (1) when the caller really wants 1283 * to destroy the buffer and backing store and (2) when the caller 1284 * wants to destroy the buffer and backing store after a write 1285 * completes. 1286 */ 1287 if ((bp->b_flags & (B_NOCACHE|B_DELWRI)) == (B_NOCACHE|B_DELWRI)) { 1288 bundirty(bp); 1289 } 1290 1291 if ((bp->b_flags & (B_INVAL | B_DELWRI)) == B_DELWRI) { 1292 /* 1293 * A re-dirtied buffer is only subject to destruction 1294 * by B_INVAL. B_ERROR and B_NOCACHE are ignored. 1295 */ 1296 /* leave buffer intact */ 1297 } else if ((bp->b_flags & (B_NOCACHE | B_INVAL | B_ERROR)) || 1298 (bp->b_bufsize <= 0)) { 1299 /* 1300 * Either a failed read or we were asked to free or not 1301 * cache the buffer. This path is reached with B_DELWRI 1302 * set only if B_INVAL is already set. B_NOCACHE governs 1303 * backing store destruction. 1304 * 1305 * NOTE: HAMMER will set B_LOCKED in buf_deallocate if the 1306 * buffer cannot be immediately freed. 1307 */ 1308 bp->b_flags |= B_INVAL; 1309 if (LIST_FIRST(&bp->b_dep) != NULL) 1310 buf_deallocate(bp); 1311 if (bp->b_flags & B_DELWRI) { 1312 atomic_add_long(&dirtybufcount, -1); 1313 atomic_add_long(&dirtykvaspace, -bp->b_kvasize); 1314 atomic_add_long(&dirtybufspace, -bp->b_bufsize); 1315 if (bp->b_flags & B_HEAVY) { 1316 atomic_add_long(&dirtybufcounthw, -1); 1317 atomic_add_long(&dirtybufspacehw, 1318 -bp->b_bufsize); 1319 } 1320 bd_signal(bp->b_bufsize); 1321 } 1322 bp->b_flags &= ~(B_DELWRI | B_CACHE); 1323 } 1324 1325 /* 1326 * We must clear B_RELBUF if B_DELWRI or B_LOCKED is set, 1327 * or if b_refs is non-zero. 1328 * 1329 * If vfs_vmio_release() is called with either bit set, the 1330 * underlying pages may wind up getting freed causing a previous 1331 * write (bdwrite()) to get 'lost' because pages associated with 1332 * a B_DELWRI bp are marked clean. Pages associated with a 1333 * B_LOCKED buffer may be mapped by the filesystem. 1334 * 1335 * If we want to release the buffer ourselves (rather then the 1336 * originator asking us to release it), give the originator a 1337 * chance to countermand the release by setting B_LOCKED. 1338 * 1339 * We still allow the B_INVAL case to call vfs_vmio_release(), even 1340 * if B_DELWRI is set. 1341 * 1342 * If B_DELWRI is not set we may have to set B_RELBUF if we are low 1343 * on pages to return pages to the VM page queues. 1344 */ 1345 if ((bp->b_flags & (B_DELWRI | B_LOCKED)) || bp->b_refs) { 1346 bp->b_flags &= ~B_RELBUF; 1347 } else if (vm_paging_min()) { 1348 if (LIST_FIRST(&bp->b_dep) != NULL) 1349 buf_deallocate(bp); /* can set B_LOCKED */ 1350 if (bp->b_flags & (B_DELWRI | B_LOCKED)) 1351 bp->b_flags &= ~B_RELBUF; 1352 else 1353 bp->b_flags |= B_RELBUF; 1354 } 1355 1356 /* 1357 * Make sure b_cmd is clear. It may have already been cleared by 1358 * biodone(). 1359 * 1360 * At this point destroying the buffer is governed by the B_INVAL 1361 * or B_RELBUF flags. 1362 */ 1363 bp->b_cmd = BUF_CMD_DONE; 1364 dsched_buf_exit(bp); 1365 1366 /* 1367 * VMIO buffer rundown. Make sure the VM page array is restored 1368 * after an I/O may have replaces some of the pages with bogus pages 1369 * in order to not destroy dirty pages in a fill-in read. 1370 * 1371 * Note that due to the code above, if a buffer is marked B_DELWRI 1372 * then the B_RELBUF and B_NOCACHE bits will always be clear. 1373 * B_INVAL may still be set, however. 1374 * 1375 * For clean buffers, B_INVAL or B_RELBUF will destroy the buffer 1376 * but not the backing store. B_NOCACHE will destroy the backing 1377 * store. 1378 * 1379 * Note that dirty NFS buffers contain byte-granular write ranges 1380 * and should not be destroyed w/ B_INVAL even if the backing store 1381 * is left intact. 1382 */ 1383 if (bp->b_flags & B_VMIO) { 1384 /* 1385 * Rundown for VMIO buffers which are not dirty NFS buffers. 1386 */ 1387 int i, j, resid; 1388 vm_page_t m; 1389 off_t foff; 1390 vm_pindex_t poff; 1391 vm_object_t obj; 1392 struct vnode *vp; 1393 1394 vp = bp->b_vp; 1395 1396 /* 1397 * Get the base offset and length of the buffer. Note that 1398 * in the VMIO case if the buffer block size is not 1399 * page-aligned then b_data pointer may not be page-aligned. 1400 * But our b_xio.xio_pages array *IS* page aligned. 1401 * 1402 * block sizes less then DEV_BSIZE (usually 512) are not 1403 * supported due to the page granularity bits (m->valid, 1404 * m->dirty, etc...). 1405 * 1406 * See man buf(9) for more information 1407 */ 1408 1409 resid = bp->b_bufsize; 1410 foff = bp->b_loffset; 1411 1412 for (i = 0; i < bp->b_xio.xio_npages; i++) { 1413 m = bp->b_xio.xio_pages[i]; 1414 1415 /* 1416 * If we hit a bogus page, fixup *all* of them 1417 * now. Note that we left these pages wired 1418 * when we removed them so they had better exist, 1419 * and they cannot be ripped out from under us so 1420 * no critical section protection is necessary. 1421 */ 1422 if (m == bogus_page) { 1423 obj = vp->v_object; 1424 poff = OFF_TO_IDX(bp->b_loffset); 1425 1426 vm_object_hold(obj); 1427 for (j = i; j < bp->b_xio.xio_npages; j++) { 1428 vm_page_t mtmp; 1429 1430 mtmp = bp->b_xio.xio_pages[j]; 1431 if (mtmp == bogus_page) { 1432 if ((bp->b_flags & B_HASBOGUS) == 0) 1433 panic("brelse: bp %p corrupt bogus", bp); 1434 mtmp = vm_page_lookup(obj, poff + j); 1435 if (!mtmp) 1436 panic("brelse: bp %p page %d missing", bp, j); 1437 bp->b_xio.xio_pages[j] = mtmp; 1438 } 1439 } 1440 vm_object_drop(obj); 1441 1442 if ((bp->b_flags & B_HASBOGUS) || 1443 (bp->b_flags & B_INVAL) == 0) { 1444 pmap_qenter_noinval( 1445 trunc_page((vm_offset_t)bp->b_data), 1446 bp->b_xio.xio_pages, 1447 bp->b_xio.xio_npages); 1448 bp->b_flags &= ~B_HASBOGUS; 1449 bp->b_flags |= B_KVABIO; 1450 bkvareset(bp); 1451 } 1452 m = bp->b_xio.xio_pages[i]; 1453 } 1454 1455 /* 1456 * Invalidate the backing store if B_NOCACHE is set 1457 * (e.g. used with vinvalbuf()). If this is NFS 1458 * we impose a requirement that the block size be 1459 * a multiple of PAGE_SIZE and create a temporary 1460 * hack to basically invalidate the whole page. The 1461 * problem is that NFS uses really odd buffer sizes 1462 * especially when tracking piecemeal writes and 1463 * it also vinvalbuf()'s a lot, which would result 1464 * in only partial page validation and invalidation 1465 * here. If the file page is mmap()'d, however, 1466 * all the valid bits get set so after we invalidate 1467 * here we would end up with weird m->valid values 1468 * like 0xfc. nfs_getpages() can't handle this so 1469 * we clear all the valid bits for the NFS case 1470 * instead of just some of them. 1471 * 1472 * The real bug is the VM system having to set m->valid 1473 * to VM_PAGE_BITS_ALL for faulted-in pages, which 1474 * itself is an artifact of the whole 512-byte 1475 * granular mess that exists to support odd block 1476 * sizes and UFS meta-data block sizes (e.g. 6144). 1477 * A complete rewrite is required. 1478 * 1479 * XXX 1480 */ 1481 if (bp->b_flags & (B_NOCACHE|B_ERROR)) { 1482 int poffset = foff & PAGE_MASK; 1483 int presid; 1484 1485 presid = PAGE_SIZE - poffset; 1486 if (bp->b_vp->v_tag == VT_NFS && 1487 bp->b_vp->v_type == VREG) { 1488 ; /* entire page */ 1489 } else if (presid > resid) { 1490 presid = resid; 1491 } 1492 KASSERT(presid >= 0, ("brelse: extra page")); 1493 vm_page_set_invalid(m, poffset, presid); 1494 1495 /* 1496 * Also make sure any swap cache is removed 1497 * as it is now stale (HAMMER in particular 1498 * uses B_NOCACHE to deal with buffer 1499 * aliasing). 1500 */ 1501 swap_pager_unswapped(m); 1502 } 1503 resid -= PAGE_SIZE - (foff & PAGE_MASK); 1504 foff = (foff + PAGE_SIZE) & ~(off_t)PAGE_MASK; 1505 } 1506 if (bp->b_flags & (B_INVAL | B_RELBUF)) 1507 vfs_vmio_release(bp); 1508 } else { 1509 /* 1510 * Rundown for non-VMIO buffers. 1511 * 1512 * XXX With B_MALLOC buffers removed, there should no longer 1513 * be any situation where brelse() is called on a non B_VMIO 1514 * buffer. Recommend assertion here. XXX 1515 */ 1516 if (bp->b_flags & (B_INVAL | B_RELBUF)) { 1517 if (bp->b_bufsize) 1518 allocbuf(bp, 0); 1519 KKASSERT (LIST_FIRST(&bp->b_dep) == NULL); 1520 if (bp->b_vp) 1521 brelvp(bp); 1522 } 1523 } 1524 1525 if (bp->b_qindex != BQUEUE_NONE) 1526 panic("brelse: free buffer onto another queue???"); 1527 1528 /* 1529 * Figure out the correct queue to place the cleaned up buffer on. 1530 * Buffers placed in the EMPTY or EMPTYKVA had better already be 1531 * disassociated from their vnode. 1532 * 1533 * Return the buffer to its original pcpu area 1534 */ 1535 pcpu = &bufpcpu[bp->b_qcpu]; 1536 spin_lock(&pcpu->spin); 1537 1538 if (bp->b_flags & B_LOCKED) { 1539 /* 1540 * Buffers that are locked are placed in the locked queue 1541 * immediately, regardless of their state. 1542 */ 1543 bp->b_qindex = BQUEUE_LOCKED; 1544 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1545 bp, b_freelist); 1546 } else if (bp->b_bufsize == 0) { 1547 /* 1548 * Buffers with no memory. Due to conditionals near the top 1549 * of brelse() such buffers should probably already be 1550 * marked B_INVAL and disassociated from their vnode. 1551 */ 1552 bp->b_flags |= B_INVAL; 1553 KASSERT(bp->b_vp == NULL, 1554 ("bp1 %p flags %08x/%08x vnode %p " 1555 "unexpectededly still associated!", 1556 bp, saved_flags, bp->b_flags, bp->b_vp)); 1557 KKASSERT((bp->b_flags & B_HASHED) == 0); 1558 bp->b_qindex = BQUEUE_EMPTY; 1559 TAILQ_INSERT_HEAD(&pcpu->bufqueues[bp->b_qindex], 1560 bp, b_freelist); 1561 } else if (bp->b_flags & (B_INVAL | B_NOCACHE | B_RELBUF)) { 1562 /* 1563 * Buffers with junk contents. Again these buffers had better 1564 * already be disassociated from their vnode. 1565 */ 1566 KASSERT(bp->b_vp == NULL, 1567 ("bp2 %p flags %08x/%08x vnode %p unexpectededly " 1568 "still associated!", 1569 bp, saved_flags, bp->b_flags, bp->b_vp)); 1570 KKASSERT((bp->b_flags & B_HASHED) == 0); 1571 bp->b_flags |= B_INVAL; 1572 bp->b_qindex = BQUEUE_CLEAN; 1573 TAILQ_INSERT_HEAD(&pcpu->bufqueues[bp->b_qindex], 1574 bp, b_freelist); 1575 } else { 1576 /* 1577 * Remaining buffers. These buffers are still associated with 1578 * their vnode. 1579 */ 1580 switch(bp->b_flags & (B_DELWRI|B_HEAVY)) { 1581 case B_DELWRI: 1582 bp->b_qindex = BQUEUE_DIRTY; 1583 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1584 bp, b_freelist); 1585 break; 1586 case B_DELWRI | B_HEAVY: 1587 bp->b_qindex = BQUEUE_DIRTY_HW; 1588 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1589 bp, b_freelist); 1590 break; 1591 default: 1592 /* 1593 * NOTE: Buffers are always placed at the end of the 1594 * queue. If B_AGE is not set the buffer will cycle 1595 * through the queue twice. 1596 */ 1597 bp->b_qindex = BQUEUE_CLEAN; 1598 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1599 bp, b_freelist); 1600 break; 1601 } 1602 } 1603 spin_unlock(&pcpu->spin); 1604 1605 /* 1606 * If B_INVAL, clear B_DELWRI. We've already placed the buffer 1607 * on the correct queue but we have not yet unlocked it. 1608 */ 1609 if ((bp->b_flags & (B_INVAL|B_DELWRI)) == (B_INVAL|B_DELWRI)) 1610 bundirty(bp); 1611 1612 /* 1613 * The bp is on an appropriate queue unless locked. If it is not 1614 * locked or dirty we can wakeup threads waiting for buffer space. 1615 * 1616 * We've already handled the B_INVAL case ( B_DELWRI will be clear 1617 * if B_INVAL is set ). 1618 */ 1619 if ((bp->b_flags & (B_LOCKED|B_DELWRI)) == 0) 1620 bufcountwakeup(); 1621 1622 /* 1623 * Something we can maybe free or reuse 1624 */ 1625 if (bp->b_bufsize || bp->b_kvasize) 1626 bufspacewakeup(); 1627 1628 /* 1629 * Clean up temporary flags and unlock the buffer. 1630 */ 1631 bp->b_flags &= ~(B_NOCACHE | B_RELBUF | B_DIRECT); 1632 BUF_UNLOCK(bp); 1633 } 1634 1635 /* 1636 * bqrelse: 1637 * 1638 * Release a buffer back to the appropriate queue but do not try to free 1639 * it. The buffer is expected to be used again soon. 1640 * 1641 * bqrelse() is used by bdwrite() to requeue a delayed write, and used by 1642 * biodone() to requeue an async I/O on completion. It is also used when 1643 * known good buffers need to be requeued but we think we may need the data 1644 * again soon. 1645 * 1646 * XXX we should be able to leave the B_RELBUF hint set on completion. 1647 */ 1648 void 1649 bqrelse(struct buf *bp) 1650 { 1651 struct bufpcpu *pcpu; 1652 1653 KASSERT(!(bp->b_flags & (B_CLUSTER|B_PAGING)), 1654 ("bqrelse: inappropriate B_PAGING or B_CLUSTER bp %p", bp)); 1655 1656 if (bp->b_qindex != BQUEUE_NONE) 1657 panic("bqrelse: free buffer onto another queue???"); 1658 1659 buf_act_advance(bp); 1660 1661 pcpu = &bufpcpu[bp->b_qcpu]; 1662 spin_lock(&pcpu->spin); 1663 1664 if (bp->b_flags & B_LOCKED) { 1665 /* 1666 * Locked buffers are released to the locked queue. However, 1667 * if the buffer is dirty it will first go into the dirty 1668 * queue and later on after the I/O completes successfully it 1669 * will be released to the locked queue. 1670 */ 1671 bp->b_qindex = BQUEUE_LOCKED; 1672 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1673 bp, b_freelist); 1674 } else if (bp->b_flags & B_DELWRI) { 1675 bp->b_qindex = (bp->b_flags & B_HEAVY) ? 1676 BQUEUE_DIRTY_HW : BQUEUE_DIRTY; 1677 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1678 bp, b_freelist); 1679 } else if (vm_paging_min()) { 1680 /* 1681 * We are too low on memory, we have to try to free the 1682 * buffer (most importantly: the wired pages making up its 1683 * backing store) *now*. 1684 */ 1685 spin_unlock(&pcpu->spin); 1686 brelse(bp); 1687 return; 1688 } else { 1689 bp->b_qindex = BQUEUE_CLEAN; 1690 TAILQ_INSERT_TAIL(&pcpu->bufqueues[bp->b_qindex], 1691 bp, b_freelist); 1692 } 1693 spin_unlock(&pcpu->spin); 1694 1695 /* 1696 * We have now placed the buffer on the proper queue, but have yet 1697 * to unlock it. 1698 */ 1699 if ((bp->b_flags & B_LOCKED) == 0 && 1700 ((bp->b_flags & B_INVAL) || (bp->b_flags & B_DELWRI) == 0)) { 1701 bufcountwakeup(); 1702 } 1703 1704 /* 1705 * Something we can maybe free or reuse. 1706 */ 1707 if (bp->b_bufsize && !(bp->b_flags & B_DELWRI)) 1708 bufspacewakeup(); 1709 1710 /* 1711 * Final cleanup and unlock. Clear bits that are only used while a 1712 * buffer is actively locked. 1713 */ 1714 bp->b_flags &= ~(B_NOCACHE | B_RELBUF); 1715 dsched_buf_exit(bp); 1716 BUF_UNLOCK(bp); 1717 } 1718 1719 /* 1720 * Hold a buffer, preventing it from being reused. This will prevent 1721 * normal B_RELBUF operations on the buffer but will not prevent B_INVAL 1722 * operations. If a B_INVAL operation occurs the buffer will remain held 1723 * but the underlying pages may get ripped out. 1724 * 1725 * These functions are typically used in VOP_READ/VOP_WRITE functions 1726 * to hold a buffer during a copyin or copyout, preventing deadlocks 1727 * or recursive lock panics when read()/write() is used over mmap()'d 1728 * space. 1729 * 1730 * NOTE: bqhold() requires that the buffer be locked at the time of the 1731 * hold. bqdrop() has no requirements other than the buffer having 1732 * previously been held. 1733 */ 1734 void 1735 bqhold(struct buf *bp) 1736 { 1737 atomic_add_int(&bp->b_refs, 1); 1738 } 1739 1740 void 1741 bqdrop(struct buf *bp) 1742 { 1743 KKASSERT(bp->b_refs > 0); 1744 atomic_add_int(&bp->b_refs, -1); 1745 } 1746 1747 /* 1748 * Return backing pages held by the buffer 'bp' back to the VM system. 1749 * This routine is called when the bp is invalidated, released, or 1750 * reused. 1751 * 1752 * The KVA mapping (b_data) for the underlying pages is removed by 1753 * this function. 1754 * 1755 * WARNING! This routine is integral to the low memory critical path 1756 * when a buffer is B_RELBUF'd. If the system has a severe page 1757 * deficit we need to get the page(s) onto the PQ_FREE or PQ_CACHE 1758 * queues so they can be reused in the current pageout daemon 1759 * pass. 1760 */ 1761 static void 1762 vfs_vmio_release(struct buf *bp) 1763 { 1764 int i; 1765 vm_page_t m; 1766 1767 for (i = 0; i < bp->b_xio.xio_npages; i++) { 1768 m = bp->b_xio.xio_pages[i]; 1769 bp->b_xio.xio_pages[i] = NULL; 1770 1771 /* 1772 * We need to own the page in order to safely unwire it. 1773 */ 1774 vm_page_busy_wait(m, FALSE, "vmiopg"); 1775 1776 /* 1777 * The VFS is telling us this is not a meta-data buffer 1778 * even if it is backed by a block device. 1779 */ 1780 if (bp->b_flags & B_NOTMETA) 1781 vm_page_flag_set(m, PG_NOTMETA); 1782 1783 /* 1784 * This is a very important bit of code. We try to track 1785 * VM page use whether the pages are wired into the buffer 1786 * cache or not. While wired into the buffer cache the 1787 * bp tracks the act_count. 1788 * 1789 * We can choose to place unwired pages on the inactive 1790 * queue (0) or active queue (1). If we place too many 1791 * on the active queue the queue will cycle the act_count 1792 * on pages we'd like to keep, just from single-use pages 1793 * (such as when doing a tar-up or file scan). 1794 */ 1795 if (bp->b_act_count < vm_cycle_point) 1796 vm_page_unwire(m, 0); 1797 else 1798 vm_page_unwire(m, 1); 1799 1800 /* 1801 * If the wire_count has dropped to 0 we may need to take 1802 * further action before unbusying the page. 1803 * 1804 * WARNING: vm_page_try_*() also checks PG_NEED_COMMIT for us. 1805 */ 1806 if (m->wire_count == 0) { 1807 if (bp->b_flags & B_DIRECT) { 1808 /* 1809 * Attempt to free the page if B_DIRECT is 1810 * set, the caller does not desire the page 1811 * to be cached. 1812 */ 1813 vm_page_wakeup(m); 1814 vm_page_try_to_free(m); 1815 } else if ((bp->b_flags & (B_NOTMETA | B_TTC)) || 1816 vm_paging_min()) { 1817 /* 1818 * Attempt to move the page to PQ_CACHE 1819 * if B_NOTMETA is set. This flag is set 1820 * by HAMMER to remove one of the two pages 1821 * present when double buffering is enabled. 1822 * 1823 * Attempt to move the page to PQ_CACHE 1824 * If we have a severe page deficit. This 1825 * will cause buffer cache operations related 1826 * to pageouts to recycle the related pages 1827 * in order to avoid a low memory deadlock. 1828 */ 1829 m->act_count = bp->b_act_count; 1830 vm_page_try_to_cache(m); 1831 } else { 1832 /* 1833 * Nominal case, leave the page on the 1834 * queue the original unwiring placed it on 1835 * (active or inactive). 1836 */ 1837 m->act_count = bp->b_act_count; 1838 vm_page_wakeup(m); 1839 } 1840 } else { 1841 vm_page_wakeup(m); 1842 } 1843 } 1844 1845 /* 1846 * Zero out the pmap pte's for the mapping, but don't bother 1847 * invalidating the TLB. The range will be properly invalidating 1848 * when new pages are entered into the mapping. 1849 * 1850 * This in particular reduces tmpfs tear-down overhead and reduces 1851 * buffer cache re-use overhead (one invalidation sequence instead 1852 * of two per re-use). 1853 */ 1854 pmap_qremove_noinval(trunc_page((vm_offset_t) bp->b_data), 1855 bp->b_xio.xio_npages); 1856 CPUMASK_ASSZERO(bp->b_cpumask); 1857 if (bp->b_bufsize) { 1858 atomic_add_long(&bufspace, -bp->b_bufsize); 1859 bp->b_bufsize = 0; 1860 bufspacewakeup(); 1861 } 1862 bp->b_xio.xio_npages = 0; 1863 bp->b_flags &= ~(B_VMIO | B_TTC); 1864 KKASSERT (LIST_FIRST(&bp->b_dep) == NULL); 1865 if (bp->b_vp) 1866 brelvp(bp); 1867 } 1868 1869 /* 1870 * Find and initialize a new buffer header, freeing up existing buffers 1871 * in the bufqueues as necessary. The new buffer is returned locked. 1872 * 1873 * Important: B_INVAL is not set. If the caller wishes to throw the 1874 * buffer away, the caller must set B_INVAL prior to calling brelse(). 1875 * 1876 * We block if: 1877 * We have insufficient buffer headers 1878 * We have insufficient buffer space 1879 * 1880 * To avoid VFS layer recursion we do not flush dirty buffers ourselves. 1881 * Instead we ask the buf daemon to do it for us. We attempt to 1882 * avoid piecemeal wakeups of the pageout daemon. 1883 */ 1884 struct buf * 1885 getnewbuf(int blkflags, int slptimeo, int size, int maxsize) 1886 { 1887 struct bufpcpu *pcpu; 1888 struct buf *bp; 1889 struct buf *nbp; 1890 int nqindex; 1891 int nqcpu; 1892 int slpflags = (blkflags & GETBLK_PCATCH) ? PCATCH : 0; 1893 int maxloops = 200000; 1894 int restart_reason = 0; 1895 struct buf *restart_bp = NULL; 1896 static char flushingbufs[MAXCPU]; 1897 char *flushingp; 1898 1899 /* 1900 * We can't afford to block since we might be holding a vnode lock, 1901 * which may prevent system daemons from running. We deal with 1902 * low-memory situations by proactively returning memory and running 1903 * async I/O rather then sync I/O. 1904 */ 1905 1906 ++getnewbufcalls; 1907 nqcpu = mycpu->gd_cpuid; 1908 flushingp = &flushingbufs[nqcpu]; 1909 restart: 1910 if (bufspace < lobufspace) 1911 *flushingp = 0; 1912 1913 if (debug_bufbio && --maxloops == 0) 1914 panic("getnewbuf, excessive loops on cpu %d restart %d (%p)", 1915 mycpu->gd_cpuid, restart_reason, restart_bp); 1916 1917 /* 1918 * Setup for scan. If we do not have enough free buffers, 1919 * we setup a degenerate case that immediately fails. Note 1920 * that if we are specially marked process, we are allowed to 1921 * dip into our reserves. 1922 * 1923 * The scanning sequence is nominally: EMPTY->CLEAN 1924 */ 1925 pcpu = &bufpcpu[nqcpu]; 1926 spin_lock(&pcpu->spin); 1927 1928 /* 1929 * Prime the scan for this cpu. Locate the first buffer to 1930 * check. If we are flushing buffers we must skip the 1931 * EMPTY queue. 1932 */ 1933 nqindex = BQUEUE_EMPTY; 1934 nbp = TAILQ_FIRST(&pcpu->bufqueues[BQUEUE_EMPTY]); 1935 if (nbp == NULL || *flushingp) { 1936 nqindex = BQUEUE_CLEAN; 1937 nbp = TAILQ_FIRST(&pcpu->bufqueues[BQUEUE_CLEAN]); 1938 } 1939 1940 /* 1941 * Run scan, possibly freeing data and/or kva mappings on the fly, 1942 * depending. 1943 * 1944 * WARNING! spin is held! 1945 */ 1946 while ((bp = nbp) != NULL) { 1947 int qindex = nqindex; 1948 1949 nbp = TAILQ_NEXT(bp, b_freelist); 1950 1951 /* 1952 * BQUEUE_CLEAN - B_AGE special case. If not set the bp 1953 * cycles through the queue twice before being selected. 1954 */ 1955 if (qindex == BQUEUE_CLEAN && 1956 (bp->b_flags & B_AGE) == 0 && nbp) { 1957 bp->b_flags |= B_AGE; 1958 TAILQ_REMOVE(&pcpu->bufqueues[qindex], 1959 bp, b_freelist); 1960 TAILQ_INSERT_TAIL(&pcpu->bufqueues[qindex], 1961 bp, b_freelist); 1962 continue; 1963 } 1964 1965 /* 1966 * Calculate next bp ( we can only use it if we do not block 1967 * or do other fancy things ). 1968 */ 1969 if (nbp == NULL) { 1970 switch(qindex) { 1971 case BQUEUE_EMPTY: 1972 nqindex = BQUEUE_CLEAN; 1973 if ((nbp = TAILQ_FIRST(&pcpu->bufqueues[BQUEUE_CLEAN]))) 1974 break; 1975 /* fall through */ 1976 case BQUEUE_CLEAN: 1977 /* 1978 * nbp is NULL. 1979 */ 1980 break; 1981 } 1982 } 1983 1984 /* 1985 * Sanity Checks 1986 */ 1987 KASSERT(bp->b_qindex == qindex, 1988 ("getnewbuf: inconsistent queue %d bp %p", qindex, bp)); 1989 1990 /* 1991 * Note: we no longer distinguish between VMIO and non-VMIO 1992 * buffers. 1993 */ 1994 KASSERT((bp->b_flags & B_DELWRI) == 0, 1995 ("delwri buffer %p found in queue %d", bp, qindex)); 1996 1997 /* 1998 * Do not try to reuse a buffer with a non-zero b_refs. 1999 * This is an unsynchronized test. A synchronized test 2000 * is also performed after we lock the buffer. 2001 */ 2002 if (bp->b_refs) 2003 continue; 2004 2005 /* 2006 * Start freeing the bp. This is somewhat involved. nbp 2007 * remains valid only for BQUEUE_EMPTY bp's. Buffers 2008 * on the clean list must be disassociated from their 2009 * current vnode. Buffers on the empty lists have 2010 * already been disassociated. 2011 * 2012 * b_refs is checked after locking along with queue changes. 2013 * We must check here to deal with zero->nonzero transitions 2014 * made by the owner of the buffer lock, which is used by 2015 * VFS's to hold the buffer while issuing an unlocked 2016 * uiomove()s. We cannot invalidate the buffer's pages 2017 * for this case. Once we successfully lock a buffer the 2018 * only 0->1 transitions of b_refs will occur via findblk(). 2019 * 2020 * We must also check for queue changes after successful 2021 * locking as the current lock holder may dispose of the 2022 * buffer and change its queue. 2023 */ 2024 if (BUF_LOCK(bp, LK_EXCLUSIVE | LK_NOWAIT) != 0) { 2025 spin_unlock(&pcpu->spin); 2026 tsleep(&bd_request, 0, "gnbxxx", (hz + 99) / 100); 2027 restart_reason = 1; 2028 restart_bp = bp; 2029 goto restart; 2030 } 2031 if (bp->b_qindex != qindex || bp->b_refs) { 2032 spin_unlock(&pcpu->spin); 2033 BUF_UNLOCK(bp); 2034 restart_reason = 2; 2035 restart_bp = bp; 2036 goto restart; 2037 } 2038 bremfree_locked(bp); 2039 spin_unlock(&pcpu->spin); 2040 2041 /* 2042 * Dependancies must be handled before we disassociate the 2043 * vnode. 2044 * 2045 * NOTE: HAMMER will set B_LOCKED if the buffer cannot 2046 * be immediately disassociated. HAMMER then becomes 2047 * responsible for releasing the buffer. 2048 * 2049 * NOTE: spin is UNLOCKED now. 2050 */ 2051 if (LIST_FIRST(&bp->b_dep) != NULL) { 2052 buf_deallocate(bp); 2053 if (bp->b_flags & B_LOCKED) { 2054 bqrelse(bp); 2055 restart_reason = 3; 2056 restart_bp = bp; 2057 goto restart; 2058 } 2059 KKASSERT(LIST_FIRST(&bp->b_dep) == NULL); 2060 } 2061 2062 /* 2063 * CLEAN buffers have content or associations that must be 2064 * cleaned out if not repurposing. 2065 */ 2066 if (qindex == BQUEUE_CLEAN) { 2067 if (bp->b_flags & B_VMIO) 2068 vfs_vmio_release(bp); 2069 if (bp->b_vp) 2070 brelvp(bp); 2071 } 2072 2073 /* 2074 * NOTE: nbp is now entirely invalid. We can only restart 2075 * the scan from this point on. 2076 * 2077 * Get the rest of the buffer freed up. b_kva* is still 2078 * valid after this operation. 2079 */ 2080 KASSERT(bp->b_vp == NULL, 2081 ("bp3 %p flags %08x vnode %p qindex %d " 2082 "unexpectededly still associated!", 2083 bp, bp->b_flags, bp->b_vp, qindex)); 2084 KKASSERT((bp->b_flags & B_HASHED) == 0); 2085 2086 if (bp->b_bufsize) 2087 allocbuf(bp, 0); 2088 2089 if (bp->b_flags & (B_VNDIRTY | B_VNCLEAN | B_HASHED)) { 2090 kprintf("getnewbuf: caught bug vp queue " 2091 "%p/%08x qidx %d\n", 2092 bp, bp->b_flags, qindex); 2093 brelvp(bp); 2094 } 2095 bp->b_flags = B_BNOCLIP; 2096 bp->b_cmd = BUF_CMD_DONE; 2097 bp->b_vp = NULL; 2098 bp->b_error = 0; 2099 bp->b_resid = 0; 2100 bp->b_bcount = 0; 2101 bp->b_xio.xio_npages = 0; 2102 bp->b_dirtyoff = bp->b_dirtyend = 0; 2103 bp->b_act_count = ACT_INIT; 2104 reinitbufbio(bp); 2105 KKASSERT(LIST_FIRST(&bp->b_dep) == NULL); 2106 buf_dep_init(bp); 2107 if (blkflags & GETBLK_BHEAVY) 2108 bp->b_flags |= B_HEAVY; 2109 2110 if (bufspace >= hibufspace) 2111 *flushingp = 1; 2112 if (bufspace < lobufspace) 2113 *flushingp = 0; 2114 if (*flushingp) { 2115 bp->b_flags |= B_INVAL; 2116 brelse(bp); 2117 restart_reason = 5; 2118 restart_bp = bp; 2119 goto restart; 2120 } 2121 2122 /* 2123 * b_refs can transition to a non-zero value while we hold 2124 * the buffer locked due to a findblk(). Our brelvp() above 2125 * interlocked any future possible transitions due to 2126 * findblk()s. 2127 * 2128 * If we find b_refs to be non-zero we can destroy the 2129 * buffer's contents but we cannot yet reuse the buffer. 2130 */ 2131 if (bp->b_refs) { 2132 bp->b_flags |= B_INVAL; 2133 brelse(bp); 2134 restart_reason = 6; 2135 restart_bp = bp; 2136 2137 goto restart; 2138 } 2139 2140 /* 2141 * We found our buffer! 2142 */ 2143 break; 2144 } 2145 2146 /* 2147 * If we exhausted our list, iterate other cpus. If that fails, 2148 * sleep as appropriate. We may have to wakeup various daemons 2149 * and write out some dirty buffers. 2150 * 2151 * Generally we are sleeping due to insufficient buffer space. 2152 * 2153 * NOTE: spin is held if bp is NULL, else it is not held. 2154 */ 2155 if (bp == NULL) { 2156 int flags; 2157 char *waitmsg; 2158 2159 spin_unlock(&pcpu->spin); 2160 2161 nqcpu = (nqcpu + 1) % ncpus; 2162 if (nqcpu != mycpu->gd_cpuid) { 2163 restart_reason = 7; 2164 restart_bp = bp; 2165 goto restart; 2166 } 2167 2168 if (bufspace >= hibufspace) { 2169 waitmsg = "bufspc"; 2170 flags = VFS_BIO_NEED_BUFSPACE; 2171 } else { 2172 waitmsg = "newbuf"; 2173 flags = VFS_BIO_NEED_ANY; 2174 } 2175 2176 bd_speedup(); /* heeeelp */ 2177 atomic_set_int(&needsbuffer, flags); 2178 while (needsbuffer & flags) { 2179 int value; 2180 2181 tsleep_interlock(&needsbuffer, 0); 2182 value = atomic_fetchadd_int(&needsbuffer, 0); 2183 if (value & flags) { 2184 if (tsleep(&needsbuffer, PINTERLOCKED|slpflags, 2185 waitmsg, slptimeo)) { 2186 return (NULL); 2187 } 2188 } 2189 } 2190 } else { 2191 /* 2192 * We finally have a valid bp. Reset b_data. 2193 * 2194 * (spin is not held) 2195 */ 2196 bp->b_data = bp->b_kvabase; 2197 } 2198 return(bp); 2199 } 2200 2201 /* 2202 * buf_daemon: 2203 * 2204 * Buffer flushing daemon. Buffers are normally flushed by the 2205 * update daemon but if it cannot keep up this process starts to 2206 * take the load in an attempt to prevent getnewbuf() from blocking. 2207 * 2208 * Once a flush is initiated it does not stop until the number 2209 * of buffers falls below lodirtybuffers, but we will wake up anyone 2210 * waiting at the mid-point. 2211 */ 2212 static struct kproc_desc buf_kp = { 2213 "bufdaemon", 2214 buf_daemon, 2215 &bufdaemon_td 2216 }; 2217 SYSINIT(bufdaemon, SI_SUB_KTHREAD_BUF, SI_ORDER_FIRST, 2218 kproc_start, &buf_kp); 2219 2220 static struct kproc_desc bufhw_kp = { 2221 "bufdaemon_hw", 2222 buf_daemon_hw, 2223 &bufdaemonhw_td 2224 }; 2225 SYSINIT(bufdaemon_hw, SI_SUB_KTHREAD_BUF, SI_ORDER_FIRST, 2226 kproc_start, &bufhw_kp); 2227 2228 static void 2229 buf_daemon1(struct thread *td, int queue, int (*buf_limit_fn)(long), 2230 int *bd_req) 2231 { 2232 long limit; 2233 struct buf *marker; 2234 2235 marker = kmalloc(sizeof(*marker), M_BIOBUF, M_WAITOK | M_ZERO); 2236 marker->b_flags |= B_MARKER; 2237 marker->b_qindex = BQUEUE_NONE; 2238 marker->b_qcpu = 0; 2239 2240 /* 2241 * This process needs to be suspended prior to shutdown sync. 2242 */ 2243 EVENTHANDLER_REGISTER(shutdown_pre_sync, shutdown_kproc, 2244 td, SHUTDOWN_PRI_LAST); 2245 curthread->td_flags |= TDF_SYSTHREAD; 2246 2247 /* 2248 * This process is allowed to take the buffer cache to the limit 2249 */ 2250 for (;;) { 2251 kproc_suspend_loop(); 2252 2253 /* 2254 * Do the flush as long as the number of dirty buffers 2255 * (including those running) exceeds lodirtybufspace. 2256 * 2257 * When flushing limit running I/O to hirunningspace 2258 * Do the flush. Limit the amount of in-transit I/O we 2259 * allow to build up, otherwise we would completely saturate 2260 * the I/O system. Wakeup any waiting processes before we 2261 * normally would so they can run in parallel with our drain. 2262 * 2263 * Our aggregate normal+HW lo water mark is lodirtybufspace, 2264 * but because we split the operation into two threads we 2265 * have to cut it in half for each thread. 2266 */ 2267 waitrunningbufspace(); 2268 limit = lodirtybufspace / 2; 2269 while (buf_limit_fn(limit)) { 2270 if (flushbufqueues(marker, queue) == 0) 2271 break; 2272 if (runningbufspace < hirunningspace) 2273 continue; 2274 waitrunningbufspace(); 2275 } 2276 2277 /* 2278 * We reached our low water mark, reset the 2279 * request and sleep until we are needed again. 2280 * The sleep is just so the suspend code works. 2281 */ 2282 tsleep_interlock(bd_req, 0); 2283 if (atomic_swap_int(bd_req, 0) == 0) 2284 tsleep(bd_req, PINTERLOCKED, "psleep", hz); 2285 } 2286 /* NOT REACHED */ 2287 /*kfree(marker, M_BIOBUF);*/ 2288 } 2289 2290 static int 2291 buf_daemon_limit(long limit) 2292 { 2293 return (runningbufspace + dirtykvaspace > limit || 2294 dirtybufcount - dirtybufcounthw >= nbuf / 2); 2295 } 2296 2297 static int 2298 buf_daemon_hw_limit(long limit) 2299 { 2300 return (runningbufspace + dirtykvaspace > limit || 2301 dirtybufcounthw >= nbuf / 2); 2302 } 2303 2304 static void 2305 buf_daemon(void) 2306 { 2307 buf_daemon1(bufdaemon_td, BQUEUE_DIRTY, buf_daemon_limit, 2308 &bd_request); 2309 } 2310 2311 static void 2312 buf_daemon_hw(void) 2313 { 2314 buf_daemon1(bufdaemonhw_td, BQUEUE_DIRTY_HW, buf_daemon_hw_limit, 2315 &bd_request_hw); 2316 } 2317 2318 /* 2319 * Flush up to (flushperqueue) buffers in the dirty queue. Each cpu has a 2320 * localized version of the queue. Each call made to this function iterates 2321 * to another cpu. It is desireable to flush several buffers from the same 2322 * cpu's queue at once, as these are likely going to be linear. 2323 * 2324 * We must be careful to free up B_INVAL buffers instead of write them, which 2325 * NFS is particularly sensitive to. 2326 * 2327 * B_RELBUF may only be set by VFSs. We do set B_AGE to indicate that we 2328 * really want to try to get the buffer out and reuse it due to the write 2329 * load on the machine. 2330 * 2331 * We must lock the buffer in order to check its validity before we can mess 2332 * with its contents. spin isn't enough. 2333 */ 2334 static int 2335 flushbufqueues(struct buf *marker, bufq_type_t q) 2336 { 2337 struct bufpcpu *pcpu; 2338 struct buf *bp; 2339 int r = 0; 2340 u_int loops = flushperqueue; 2341 int lcpu = marker->b_qcpu; 2342 2343 KKASSERT(marker->b_qindex == BQUEUE_NONE); 2344 KKASSERT(marker->b_flags & B_MARKER); 2345 2346 again: 2347 /* 2348 * Spinlock needed to perform operations on the queue and may be 2349 * held through a non-blocking BUF_LOCK(), but cannot be held when 2350 * BUF_UNLOCK()ing or through any other major operation. 2351 */ 2352 pcpu = &bufpcpu[marker->b_qcpu]; 2353 spin_lock(&pcpu->spin); 2354 marker->b_qindex = q; 2355 TAILQ_INSERT_HEAD(&pcpu->bufqueues[q], marker, b_freelist); 2356 bp = marker; 2357 2358 while ((bp = TAILQ_NEXT(bp, b_freelist)) != NULL) { 2359 /* 2360 * NOTE: spinlock is always held at the top of the loop 2361 */ 2362 if (bp->b_flags & B_MARKER) 2363 continue; 2364 if ((bp->b_flags & B_DELWRI) == 0) { 2365 kprintf("Unexpected clean buffer %p\n", bp); 2366 continue; 2367 } 2368 if (BUF_LOCK(bp, LK_EXCLUSIVE | LK_NOWAIT)) 2369 continue; 2370 KKASSERT(bp->b_qcpu == marker->b_qcpu && bp->b_qindex == q); 2371 2372 /* 2373 * Once the buffer is locked we will have no choice but to 2374 * unlock the spinlock around a later BUF_UNLOCK and re-set 2375 * bp = marker when looping. Move the marker now to make 2376 * things easier. 2377 */ 2378 TAILQ_REMOVE(&pcpu->bufqueues[q], marker, b_freelist); 2379 TAILQ_INSERT_AFTER(&pcpu->bufqueues[q], bp, marker, b_freelist); 2380 2381 /* 2382 * Must recheck B_DELWRI after successfully locking 2383 * the buffer. 2384 */ 2385 if ((bp->b_flags & B_DELWRI) == 0) { 2386 spin_unlock(&pcpu->spin); 2387 BUF_UNLOCK(bp); 2388 spin_lock(&pcpu->spin); 2389 bp = marker; 2390 continue; 2391 } 2392 2393 /* 2394 * Remove the buffer from its queue. We still own the 2395 * spinlock here. 2396 */ 2397 _bremfree(bp); 2398 2399 /* 2400 * Disposing of an invalid buffer counts as a flush op 2401 */ 2402 if (bp->b_flags & B_INVAL) { 2403 spin_unlock(&pcpu->spin); 2404 brelse(bp); 2405 goto doloop; 2406 } 2407 2408 /* 2409 * Release the spinlock for the more complex ops we 2410 * are now going to do. 2411 */ 2412 spin_unlock(&pcpu->spin); 2413 lwkt_yield(); 2414 2415 /* 2416 * This is a bit messy 2417 */ 2418 if (LIST_FIRST(&bp->b_dep) != NULL && 2419 (bp->b_flags & B_DEFERRED) == 0 && 2420 buf_countdeps(bp, 0)) { 2421 spin_lock(&pcpu->spin); 2422 TAILQ_INSERT_TAIL(&pcpu->bufqueues[q], bp, b_freelist); 2423 bp->b_qindex = q; 2424 bp->b_flags |= B_DEFERRED; 2425 spin_unlock(&pcpu->spin); 2426 BUF_UNLOCK(bp); 2427 spin_lock(&pcpu->spin); 2428 bp = marker; 2429 continue; 2430 } 2431 2432 /* 2433 * spinlock not held here. 2434 * 2435 * If the buffer has a dependancy, buf_checkwrite() must 2436 * also return 0 for us to be able to initate the write. 2437 * 2438 * If the buffer is flagged B_ERROR it may be requeued 2439 * over and over again, we try to avoid a live lock. 2440 */ 2441 if (LIST_FIRST(&bp->b_dep) != NULL && buf_checkwrite(bp)) { 2442 brelse(bp); 2443 } else if (bp->b_flags & B_ERROR) { 2444 tsleep(bp, 0, "bioer", 1); 2445 bp->b_flags &= ~B_AGE; 2446 cluster_awrite(bp); 2447 } else { 2448 bp->b_flags |= B_AGE | B_KVABIO; 2449 cluster_awrite(bp); 2450 } 2451 /* bp invalid but needs to be NULL-tested if we break out */ 2452 doloop: 2453 spin_lock(&pcpu->spin); 2454 ++r; 2455 if (--loops == 0) 2456 break; 2457 bp = marker; 2458 } 2459 /* bp is invalid here but can be NULL-tested to advance */ 2460 2461 TAILQ_REMOVE(&pcpu->bufqueues[q], marker, b_freelist); 2462 marker->b_qindex = BQUEUE_NONE; 2463 spin_unlock(&pcpu->spin); 2464 2465 /* 2466 * Advance the marker to be fair. 2467 */ 2468 marker->b_qcpu = (marker->b_qcpu + 1) % ncpus; 2469 if (bp == NULL) { 2470 if (marker->b_qcpu != lcpu) 2471 goto again; 2472 } 2473 2474 return (r); 2475 } 2476 2477 /* 2478 * inmem: 2479 * 2480 * Returns true if no I/O is needed to access the associated VM object. 2481 * This is like findblk except it also hunts around in the VM system for 2482 * the data. 2483 * 2484 * Note that we ignore vm_page_free() races from interrupts against our 2485 * lookup, since if the caller is not protected our return value will not 2486 * be any more valid then otherwise once we exit the critical section. 2487 */ 2488 int 2489 inmem(struct vnode *vp, off_t loffset) 2490 { 2491 vm_object_t obj; 2492 vm_offset_t toff, tinc, size; 2493 vm_page_t m; 2494 int res = 1; 2495 2496 if (findblk(vp, loffset, FINDBLK_TEST)) 2497 return 1; 2498 if (vp->v_mount == NULL) 2499 return 0; 2500 if ((obj = vp->v_object) == NULL) 2501 return 0; 2502 2503 size = PAGE_SIZE; 2504 if (size > vp->v_mount->mnt_stat.f_iosize) 2505 size = vp->v_mount->mnt_stat.f_iosize; 2506 2507 vm_object_hold(obj); 2508 for (toff = 0; toff < vp->v_mount->mnt_stat.f_iosize; toff += tinc) { 2509 m = vm_page_lookup(obj, OFF_TO_IDX(loffset + toff)); 2510 if (m == NULL) { 2511 res = 0; 2512 break; 2513 } 2514 tinc = size; 2515 if (tinc > PAGE_SIZE - ((toff + loffset) & PAGE_MASK)) 2516 tinc = PAGE_SIZE - ((toff + loffset) & PAGE_MASK); 2517 if (vm_page_is_valid(m, 2518 (vm_offset_t) ((toff + loffset) & PAGE_MASK), tinc) == 0) { 2519 res = 0; 2520 break; 2521 } 2522 } 2523 vm_object_drop(obj); 2524 return (res); 2525 } 2526 2527 /* 2528 * findblk: 2529 * 2530 * Locate and return the specified buffer. Unless flagged otherwise, 2531 * a locked buffer will be returned if it exists or NULL if it does not. 2532 * 2533 * findblk()'d buffers are still on the bufqueues and if you intend 2534 * to use your (locked NON-TEST) buffer you need to bremfree(bp) 2535 * and possibly do other stuff to it. 2536 * 2537 * FINDBLK_TEST - Do not lock the buffer. The caller is responsible 2538 * for locking the buffer and ensuring that it remains 2539 * the desired buffer after locking. 2540 * 2541 * FINDBLK_NBLOCK - Lock the buffer non-blocking. If we are unable 2542 * to acquire the lock we return NULL, even if the 2543 * buffer exists. 2544 * 2545 * FINDBLK_REF - Returns the buffer ref'd, which prevents normal 2546 * reuse by getnewbuf() but does not prevent 2547 * disassociation (B_INVAL). Used to avoid deadlocks 2548 * against random (vp,loffset)s due to reassignment. 2549 * 2550 * FINDBLK_KVABIO - Only applicable when returning a locked buffer. 2551 * Indicates that the caller supports B_KVABIO. 2552 * 2553 * (0) - Lock the buffer blocking. 2554 */ 2555 struct buf * 2556 findblk(struct vnode *vp, off_t loffset, int flags) 2557 { 2558 struct buf *bp; 2559 int lkflags; 2560 2561 lkflags = LK_EXCLUSIVE; 2562 if (flags & FINDBLK_NBLOCK) 2563 lkflags |= LK_NOWAIT; 2564 2565 for (;;) { 2566 /* 2567 * Lookup. Ref the buf while holding v_token to prevent 2568 * reuse (but does not prevent diassociation). 2569 */ 2570 lwkt_gettoken_shared(&vp->v_token); 2571 bp = buf_rb_hash_RB_LOOKUP(&vp->v_rbhash_tree, loffset); 2572 if (bp == NULL) { 2573 lwkt_reltoken(&vp->v_token); 2574 return(NULL); 2575 } 2576 bqhold(bp); 2577 lwkt_reltoken(&vp->v_token); 2578 2579 /* 2580 * If testing only break and return bp, do not lock. 2581 */ 2582 if (flags & FINDBLK_TEST) 2583 break; 2584 2585 /* 2586 * Lock the buffer, return an error if the lock fails. 2587 * (only FINDBLK_NBLOCK can cause the lock to fail). 2588 */ 2589 if (BUF_LOCK(bp, lkflags)) { 2590 atomic_subtract_int(&bp->b_refs, 1); 2591 /* bp = NULL; not needed */ 2592 return(NULL); 2593 } 2594 2595 /* 2596 * Revalidate the locked buf before allowing it to be 2597 * returned. 2598 * 2599 * B_KVABIO is only set/cleared when locking. When 2600 * clearing B_KVABIO, we must ensure that the buffer 2601 * is synchronized to all cpus. 2602 */ 2603 if (bp->b_vp == vp && bp->b_loffset == loffset) { 2604 if (flags & FINDBLK_KVABIO) 2605 bp->b_flags |= B_KVABIO; 2606 else 2607 bkvasync_all(bp); 2608 break; 2609 } 2610 atomic_subtract_int(&bp->b_refs, 1); 2611 BUF_UNLOCK(bp); 2612 } 2613 2614 /* 2615 * Success 2616 */ 2617 if ((flags & FINDBLK_REF) == 0) 2618 atomic_subtract_int(&bp->b_refs, 1); 2619 return(bp); 2620 } 2621 2622 /* 2623 * getcacheblk: 2624 * 2625 * Similar to getblk() except only returns the buffer if it is 2626 * B_CACHE and requires no other manipulation. Otherwise NULL 2627 * is returned. NULL is also returned if GETBLK_NOWAIT is set 2628 * and the getblk() would block. 2629 * 2630 * If B_RAM is set the buffer might be just fine, but we return 2631 * NULL anyway because we want the code to fall through to the 2632 * cluster read to issue more read-aheads. Otherwise read-ahead breaks. 2633 * 2634 * If blksize is 0 the buffer cache buffer must already be fully 2635 * cached. 2636 * 2637 * If blksize is non-zero getblk() will be used, allowing a buffer 2638 * to be reinstantiated from its VM backing store. The buffer must 2639 * still be fully cached after reinstantiation to be returned. 2640 */ 2641 struct buf * 2642 getcacheblk(struct vnode *vp, off_t loffset, int blksize, int blkflags) 2643 { 2644 struct buf *bp; 2645 int fndflags = 0; 2646 2647 if (blkflags & GETBLK_NOWAIT) 2648 fndflags |= FINDBLK_NBLOCK; 2649 if (blkflags & GETBLK_KVABIO) 2650 fndflags |= FINDBLK_KVABIO; 2651 2652 if (blksize) { 2653 bp = getblk(vp, loffset, blksize, blkflags, 0); 2654 if (bp) { 2655 if ((bp->b_flags & (B_INVAL | B_CACHE)) == B_CACHE) { 2656 bp->b_flags &= ~B_AGE; 2657 if (bp->b_flags & B_RAM) { 2658 bqrelse(bp); 2659 bp = NULL; 2660 } 2661 } else { 2662 brelse(bp); 2663 bp = NULL; 2664 } 2665 } 2666 } else { 2667 bp = findblk(vp, loffset, fndflags); 2668 if (bp) { 2669 if ((bp->b_flags & (B_INVAL | B_CACHE | B_RAM)) == 2670 B_CACHE) { 2671 bp->b_flags &= ~B_AGE; 2672 bremfree(bp); 2673 } else { 2674 BUF_UNLOCK(bp); 2675 bp = NULL; 2676 } 2677 } 2678 } 2679 return (bp); 2680 } 2681 2682 /* 2683 * getblk: 2684 * 2685 * Get a block given a specified block and offset into a file/device. 2686 * B_INVAL may or may not be set on return. The caller should clear 2687 * B_INVAL prior to initiating a READ. 2688 * 2689 * IT IS IMPORTANT TO UNDERSTAND THAT IF YOU CALL GETBLK() AND B_CACHE 2690 * IS NOT SET, YOU MUST INITIALIZE THE RETURNED BUFFER, ISSUE A READ, 2691 * OR SET B_INVAL BEFORE RETIRING IT. If you retire a getblk'd buffer 2692 * without doing any of those things the system will likely believe 2693 * the buffer to be valid (especially if it is not B_VMIO), and the 2694 * next getblk() will return the buffer with B_CACHE set. 2695 * 2696 * For a non-VMIO buffer, B_CACHE is set to the opposite of B_INVAL for 2697 * an existing buffer. 2698 * 2699 * For a VMIO buffer, B_CACHE is modified according to the backing VM. 2700 * If getblk()ing a previously 0-sized invalid buffer, B_CACHE is set 2701 * and then cleared based on the backing VM. If the previous buffer is 2702 * non-0-sized but invalid, B_CACHE will be cleared. 2703 * 2704 * If getblk() must create a new buffer, the new buffer is returned with 2705 * both B_INVAL and B_CACHE clear unless it is a VMIO buffer, in which 2706 * case it is returned with B_INVAL clear and B_CACHE set based on the 2707 * backing VM. 2708 * 2709 * getblk() also forces a bwrite() for any B_DELWRI buffer whos 2710 * B_CACHE bit is clear. 2711 * 2712 * What this means, basically, is that the caller should use B_CACHE to 2713 * determine whether the buffer is fully valid or not and should clear 2714 * B_INVAL prior to issuing a read. If the caller intends to validate 2715 * the buffer by loading its data area with something, the caller needs 2716 * to clear B_INVAL. If the caller does this without issuing an I/O, 2717 * the caller should set B_CACHE ( as an optimization ), else the caller 2718 * should issue the I/O and biodone() will set B_CACHE if the I/O was 2719 * a write attempt or if it was a successfull read. If the caller 2720 * intends to issue a READ, the caller must clear B_INVAL and B_ERROR 2721 * prior to issuing the READ. biodone() will *not* clear B_INVAL. 2722 * 2723 * getblk flags: 2724 * 2725 * GETBLK_PCATCH - catch signal if blocked, can cause NULL return 2726 * GETBLK_BHEAVY - heavy-weight buffer cache buffer 2727 */ 2728 struct buf * 2729 getblk(struct vnode *vp, off_t loffset, int size, int blkflags, int slptimeo) 2730 { 2731 struct buf *bp; 2732 int slpflags = (blkflags & GETBLK_PCATCH) ? PCATCH : 0; 2733 int error; 2734 int lkflags; 2735 2736 if (size > MAXBSIZE) 2737 panic("getblk: size(%d) > MAXBSIZE(%d)", size, MAXBSIZE); 2738 if (vp->v_object == NULL) 2739 panic("getblk: vnode %p has no object!", vp); 2740 2741 /* 2742 * NOTE: findblk does not try to resolve KVABIO in REF-only mode. 2743 * we still have to handle that ourselves. 2744 */ 2745 loop: 2746 if ((bp = findblk(vp, loffset, FINDBLK_REF | FINDBLK_TEST)) != NULL) { 2747 /* 2748 * The buffer was found in the cache, but we need to lock it. 2749 * We must acquire a ref on the bp to prevent reuse, but 2750 * this will not prevent disassociation (brelvp()) so we 2751 * must recheck (vp,loffset) after acquiring the lock. 2752 * 2753 * Without the ref the buffer could potentially be reused 2754 * before we acquire the lock and create a deadlock 2755 * situation between the thread trying to reuse the buffer 2756 * and us due to the fact that we would wind up blocking 2757 * on a random (vp,loffset). 2758 */ 2759 if (BUF_LOCK(bp, LK_EXCLUSIVE | LK_NOWAIT)) { 2760 if (blkflags & GETBLK_NOWAIT) { 2761 bqdrop(bp); 2762 return(NULL); 2763 } 2764 lkflags = LK_EXCLUSIVE | LK_SLEEPFAIL; 2765 if (blkflags & GETBLK_PCATCH) 2766 lkflags |= LK_PCATCH; 2767 error = BUF_TIMELOCK(bp, lkflags, "getblk", slptimeo); 2768 if (error) { 2769 bqdrop(bp); 2770 if (error == ENOLCK) 2771 goto loop; 2772 return (NULL); 2773 } 2774 /* buffer may have changed on us */ 2775 } 2776 bqdrop(bp); 2777 2778 /* 2779 * Once the buffer has been locked, make sure we didn't race 2780 * a buffer recyclement. Buffers that are no longer hashed 2781 * will have b_vp == NULL, so this takes care of that check 2782 * as well. 2783 */ 2784 if (bp->b_vp != vp || bp->b_loffset != loffset) { 2785 #if 0 2786 kprintf("Warning buffer %p (vp %p loffset %lld) " 2787 "was recycled\n", 2788 bp, vp, (long long)loffset); 2789 #endif 2790 BUF_UNLOCK(bp); 2791 goto loop; 2792 } 2793 2794 /* 2795 * If SZMATCH any pre-existing buffer must be of the requested 2796 * size or NULL is returned. The caller absolutely does not 2797 * want getblk() to bwrite() the buffer on a size mismatch. 2798 */ 2799 if ((blkflags & GETBLK_SZMATCH) && size != bp->b_bcount) { 2800 BUF_UNLOCK(bp); 2801 return(NULL); 2802 } 2803 2804 /* 2805 * All vnode-based buffers must be backed by a VM object. 2806 * 2807 * Set B_KVABIO for any incidental work, we will fix it 2808 * up later. 2809 */ 2810 KKASSERT(bp->b_flags & B_VMIO); 2811 KKASSERT(bp->b_cmd == BUF_CMD_DONE); 2812 bp->b_flags &= ~B_AGE; 2813 bp->b_flags |= B_KVABIO; 2814 2815 /* 2816 * Make sure that B_INVAL buffers do not have a cached 2817 * block number translation. 2818 */ 2819 if ((bp->b_flags & B_INVAL) && 2820 (bp->b_bio2.bio_offset != NOOFFSET)) { 2821 kprintf("Warning invalid buffer %p (vp %p loffset %lld)" 2822 " did not have cleared bio_offset cache\n", 2823 bp, vp, (long long)loffset); 2824 clearbiocache(&bp->b_bio2); 2825 } 2826 2827 /* 2828 * The buffer is locked. B_CACHE is cleared if the buffer is 2829 * invalid. 2830 * 2831 * After the bremfree(), disposals must use b[q]relse(). 2832 */ 2833 if (bp->b_flags & B_INVAL) 2834 bp->b_flags &= ~B_CACHE; 2835 bremfree(bp); 2836 2837 /* 2838 * Any size inconsistancy with a dirty buffer or a buffer 2839 * with a softupdates dependancy must be resolved. Resizing 2840 * the buffer in such circumstances can lead to problems. 2841 * 2842 * Dirty or dependant buffers are written synchronously. 2843 * Other types of buffers are simply released and 2844 * reconstituted as they may be backed by valid, dirty VM 2845 * pages (but not marked B_DELWRI). 2846 * 2847 * NFS NOTE: NFS buffers which straddle EOF are oddly-sized 2848 * and may be left over from a prior truncation (and thus 2849 * no longer represent the actual EOF point), so we 2850 * definitely do not want to B_NOCACHE the backing store. 2851 */ 2852 if (size != bp->b_bcount) { 2853 if (bp->b_flags & B_DELWRI) { 2854 bp->b_flags |= B_RELBUF; 2855 bwrite(bp); 2856 } else if (LIST_FIRST(&bp->b_dep)) { 2857 bp->b_flags |= B_RELBUF; 2858 bwrite(bp); 2859 } else { 2860 bp->b_flags |= B_RELBUF; 2861 brelse(bp); 2862 } 2863 goto loop; 2864 } 2865 KKASSERT(size <= bp->b_kvasize); 2866 KASSERT(bp->b_loffset != NOOFFSET, 2867 ("getblk: no buffer offset")); 2868 2869 /* 2870 * A buffer with B_DELWRI set and B_CACHE clear must 2871 * be committed before we can return the buffer in 2872 * order to prevent the caller from issuing a read 2873 * ( due to B_CACHE not being set ) and overwriting 2874 * it. 2875 * 2876 * Most callers, including NFS and FFS, need this to 2877 * operate properly either because they assume they 2878 * can issue a read if B_CACHE is not set, or because 2879 * ( for example ) an uncached B_DELWRI might loop due 2880 * to softupdates re-dirtying the buffer. In the latter 2881 * case, B_CACHE is set after the first write completes, 2882 * preventing further loops. 2883 * 2884 * NOTE! b*write() sets B_CACHE. If we cleared B_CACHE 2885 * above while extending the buffer, we cannot allow the 2886 * buffer to remain with B_CACHE set after the write 2887 * completes or it will represent a corrupt state. To 2888 * deal with this we set B_NOCACHE to scrap the buffer 2889 * after the write. 2890 * 2891 * XXX Should this be B_RELBUF instead of B_NOCACHE? 2892 * I'm not even sure this state is still possible 2893 * now that getblk() writes out any dirty buffers 2894 * on size changes. 2895 * 2896 * We might be able to do something fancy, like setting 2897 * B_CACHE in bwrite() except if B_DELWRI is already set, 2898 * so the below call doesn't set B_CACHE, but that gets real 2899 * confusing. This is much easier. 2900 */ 2901 if ((bp->b_flags & (B_CACHE|B_DELWRI)) == B_DELWRI) { 2902 kprintf("getblk: Warning, bp %p loff=%jx DELWRI set " 2903 "and CACHE clear, b_flags %08x\n", 2904 bp, (uintmax_t)bp->b_loffset, bp->b_flags); 2905 bp->b_flags |= B_NOCACHE; 2906 bwrite(bp); 2907 goto loop; 2908 } 2909 } else { 2910 /* 2911 * Buffer is not in-core, create new buffer. The buffer 2912 * returned by getnewbuf() is locked. Note that the returned 2913 * buffer is also considered valid (not marked B_INVAL). 2914 * 2915 * Calculating the offset for the I/O requires figuring out 2916 * the block size. We use DEV_BSIZE for VBLK or VCHR and 2917 * the mount's f_iosize otherwise. If the vnode does not 2918 * have an associated mount we assume that the passed size is 2919 * the block size. 2920 * 2921 * Note that vn_isdisk() cannot be used here since it may 2922 * return a failure for numerous reasons. Note that the 2923 * buffer size may be larger then the block size (the caller 2924 * will use block numbers with the proper multiple). Beware 2925 * of using any v_* fields which are part of unions. In 2926 * particular, in DragonFly the mount point overloading 2927 * mechanism uses the namecache only and the underlying 2928 * directory vnode is not a special case. 2929 */ 2930 int bsize, maxsize; 2931 2932 if (vp->v_type == VBLK || vp->v_type == VCHR) 2933 bsize = DEV_BSIZE; 2934 else if (vp->v_mount) 2935 bsize = vp->v_mount->mnt_stat.f_iosize; 2936 else 2937 bsize = size; 2938 2939 maxsize = size + (loffset & PAGE_MASK); 2940 maxsize = imax(maxsize, bsize); 2941 2942 bp = getnewbuf(blkflags, slptimeo, size, maxsize); 2943 if (bp == NULL) { 2944 if (slpflags || slptimeo) 2945 return NULL; 2946 goto loop; 2947 } 2948 2949 /* 2950 * Atomically insert the buffer into the hash, so that it can 2951 * be found by findblk(). 2952 * 2953 * If bgetvp() returns non-zero a collision occured, and the 2954 * bp will not be associated with the vnode. 2955 * 2956 * Make sure the translation layer has been cleared. 2957 */ 2958 bp->b_loffset = loffset; 2959 bp->b_bio2.bio_offset = NOOFFSET; 2960 /* bp->b_bio2.bio_next = NULL; */ 2961 2962 if (bgetvp(vp, bp, size)) { 2963 bp->b_flags |= B_INVAL; 2964 brelse(bp); 2965 goto loop; 2966 } 2967 2968 /* 2969 * All vnode-based buffers must be backed by a VM object. 2970 * 2971 * Set B_KVABIO for incidental work 2972 */ 2973 KKASSERT(vp->v_object != NULL); 2974 bp->b_flags |= B_VMIO | B_KVABIO; 2975 KKASSERT(bp->b_cmd == BUF_CMD_DONE); 2976 2977 allocbuf(bp, size); 2978 } 2979 2980 /* 2981 * Do the nasty smp broadcast (if the buffer needs it) when KVABIO 2982 * is not supported. 2983 */ 2984 if (bp && (blkflags & GETBLK_KVABIO) == 0) { 2985 bkvasync_all(bp); 2986 } 2987 return (bp); 2988 } 2989 2990 /* 2991 * regetblk(bp) 2992 * 2993 * Reacquire a buffer that was previously released to the locked queue, 2994 * or reacquire a buffer which is interlocked by having bioops->io_deallocate 2995 * set B_LOCKED (which handles the acquisition race). 2996 * 2997 * To this end, either B_LOCKED must be set or the dependancy list must be 2998 * non-empty. 2999 */ 3000 void 3001 regetblk(struct buf *bp) 3002 { 3003 KKASSERT((bp->b_flags & B_LOCKED) || LIST_FIRST(&bp->b_dep) != NULL); 3004 BUF_LOCK(bp, LK_EXCLUSIVE | LK_RETRY); 3005 bremfree(bp); 3006 } 3007 3008 /* 3009 * allocbuf: 3010 * 3011 * This code constitutes the buffer memory from either anonymous system 3012 * memory (in the case of non-VMIO operations) or from an associated 3013 * VM object (in the case of VMIO operations). This code is able to 3014 * resize a buffer up or down. 3015 * 3016 * Note that this code is tricky, and has many complications to resolve 3017 * deadlock or inconsistant data situations. Tread lightly!!! 3018 * There are B_CACHE and B_DELWRI interactions that must be dealt with by 3019 * the caller. Calling this code willy nilly can result in the loss of 3020 * data. 3021 * 3022 * allocbuf() only adjusts B_CACHE for VMIO buffers. getblk() deals with 3023 * B_CACHE for the non-VMIO case. 3024 * 3025 * This routine does not need to be called from a critical section but you 3026 * must own the buffer. 3027 */ 3028 void 3029 allocbuf(struct buf *bp, int size) 3030 { 3031 vm_page_t m; 3032 int newbsize; 3033 int desiredpages; 3034 int i; 3035 3036 if (BUF_LOCKINUSE(bp) == 0) 3037 panic("allocbuf: buffer not busy"); 3038 3039 if (bp->b_kvasize < size) 3040 panic("allocbuf: buffer too small"); 3041 3042 KKASSERT(bp->b_flags & B_VMIO); 3043 3044 newbsize = roundup2(size, DEV_BSIZE); 3045 desiredpages = ((int)(bp->b_loffset & PAGE_MASK) + 3046 newbsize + PAGE_MASK) >> PAGE_SHIFT; 3047 KKASSERT(desiredpages <= XIO_INTERNAL_PAGES); 3048 3049 /* 3050 * Set B_CACHE initially if buffer is 0 length or will become 3051 * 0-length. 3052 */ 3053 if (size == 0 || bp->b_bufsize == 0) 3054 bp->b_flags |= B_CACHE; 3055 3056 if (newbsize < bp->b_bufsize) { 3057 /* 3058 * DEV_BSIZE aligned new buffer size is less then the 3059 * DEV_BSIZE aligned existing buffer size. Figure out 3060 * if we have to remove any pages. 3061 */ 3062 if (desiredpages < bp->b_xio.xio_npages) { 3063 for (i = desiredpages; i < bp->b_xio.xio_npages; i++) { 3064 /* 3065 * the page is not freed here -- it 3066 * is the responsibility of 3067 * vnode_pager_setsize 3068 */ 3069 m = bp->b_xio.xio_pages[i]; 3070 KASSERT(m != bogus_page, 3071 ("allocbuf: bogus page found")); 3072 vm_page_busy_wait(m, TRUE, "biodep"); 3073 bp->b_xio.xio_pages[i] = NULL; 3074 vm_page_unwire(m, 0); 3075 vm_page_wakeup(m); 3076 } 3077 pmap_qremove_noinval((vm_offset_t) 3078 trunc_page((vm_offset_t)bp->b_data) + 3079 (desiredpages << PAGE_SHIFT), 3080 (bp->b_xio.xio_npages - desiredpages)); 3081 bp->b_xio.xio_npages = desiredpages; 3082 3083 /* 3084 * Don't bother invalidating the pmap changes 3085 * (which wastes global SMP invalidation IPIs) 3086 * when setting the size to 0. This case occurs 3087 * when called via getnewbuf() during buffer 3088 * recyclement. 3089 */ 3090 if (desiredpages == 0) { 3091 CPUMASK_ASSZERO(bp->b_cpumask); 3092 } else { 3093 bkvareset(bp); 3094 } 3095 } 3096 } else if (size > bp->b_bcount) { 3097 /* 3098 * We are growing the buffer, possibly in a 3099 * byte-granular fashion. 3100 */ 3101 struct vnode *vp; 3102 vm_object_t obj; 3103 vm_offset_t toff; 3104 vm_offset_t tinc; 3105 3106 /* 3107 * Step 1, bring in the VM pages from the object, 3108 * allocating them if necessary. We must clear 3109 * B_CACHE if these pages are not valid for the 3110 * range covered by the buffer. 3111 */ 3112 vp = bp->b_vp; 3113 obj = vp->v_object; 3114 3115 vm_object_hold(obj); 3116 while (bp->b_xio.xio_npages < desiredpages) { 3117 vm_page_t m; 3118 vm_pindex_t pi; 3119 int error; 3120 3121 pi = OFF_TO_IDX(bp->b_loffset) + 3122 bp->b_xio.xio_npages; 3123 3124 /* 3125 * Blocking on m->busy_count might lead to a 3126 * deadlock: 3127 * 3128 * vm_fault->getpages->cluster_read->allocbuf 3129 */ 3130 m = vm_page_lookup_busy_try(obj, pi, FALSE, 3131 &error); 3132 if (error) { 3133 vm_page_sleep_busy(m, FALSE, "pgtblk"); 3134 continue; 3135 } 3136 if (m == NULL) { 3137 /* 3138 * note: must allocate system pages 3139 * since blocking here could intefere 3140 * with paging I/O, no matter which 3141 * process we are. 3142 */ 3143 m = bio_page_alloc(bp, obj, pi, 3144 desiredpages - 3145 bp->b_xio.xio_npages); 3146 if (m) { 3147 vm_page_wire(m); 3148 vm_page_wakeup(m); 3149 bp->b_flags &= ~B_CACHE; 3150 bp->b_xio.xio_pages[bp->b_xio.xio_npages] = m; 3151 ++bp->b_xio.xio_npages; 3152 } 3153 continue; 3154 } 3155 3156 /* 3157 * We found a page and were able to busy it. 3158 */ 3159 vm_page_wire(m); 3160 vm_page_wakeup(m); 3161 bp->b_xio.xio_pages[bp->b_xio.xio_npages] = m; 3162 ++bp->b_xio.xio_npages; 3163 if (bp->b_act_count < m->act_count) 3164 bp->b_act_count = m->act_count; 3165 } 3166 vm_object_drop(obj); 3167 3168 /* 3169 * Step 2. We've loaded the pages into the buffer, 3170 * we have to figure out if we can still have B_CACHE 3171 * set. Note that B_CACHE is set according to the 3172 * byte-granular range ( bcount and size ), not the 3173 * aligned range ( newbsize ). 3174 * 3175 * The VM test is against m->valid, which is DEV_BSIZE 3176 * aligned. Needless to say, the validity of the data 3177 * needs to also be DEV_BSIZE aligned. Note that this 3178 * fails with NFS if the server or some other client 3179 * extends the file's EOF. If our buffer is resized, 3180 * B_CACHE may remain set! XXX 3181 */ 3182 3183 toff = bp->b_bcount; 3184 tinc = PAGE_SIZE - ((bp->b_loffset + toff) & PAGE_MASK); 3185 3186 while ((bp->b_flags & B_CACHE) && toff < size) { 3187 vm_pindex_t pi; 3188 3189 if (tinc > (size - toff)) 3190 tinc = size - toff; 3191 3192 pi = ((bp->b_loffset & PAGE_MASK) + toff) >> 3193 PAGE_SHIFT; 3194 3195 vfs_buf_test_cache( 3196 bp, 3197 bp->b_loffset, 3198 toff, 3199 tinc, 3200 bp->b_xio.xio_pages[pi] 3201 ); 3202 toff += tinc; 3203 tinc = PAGE_SIZE; 3204 } 3205 3206 /* 3207 * Step 3, fixup the KVM pmap. Remember that 3208 * bp->b_data is relative to bp->b_loffset, but 3209 * bp->b_loffset may be offset into the first page. 3210 */ 3211 bp->b_data = (caddr_t)trunc_page((vm_offset_t)bp->b_data); 3212 pmap_qenter_noinval((vm_offset_t)bp->b_data, 3213 bp->b_xio.xio_pages, bp->b_xio.xio_npages); 3214 bp->b_data = (caddr_t)((vm_offset_t)bp->b_data | 3215 (vm_offset_t)(bp->b_loffset & PAGE_MASK)); 3216 bkvareset(bp); 3217 } 3218 atomic_add_long(&bufspace, newbsize - bp->b_bufsize); 3219 3220 /* adjust space use on already-dirty buffer */ 3221 if (bp->b_flags & B_DELWRI) { 3222 /* dirtykvaspace unchanged */ 3223 atomic_add_long(&dirtybufspace, newbsize - bp->b_bufsize); 3224 if (bp->b_flags & B_HEAVY) { 3225 atomic_add_long(&dirtybufspacehw, 3226 newbsize - bp->b_bufsize); 3227 } 3228 } 3229 bp->b_bufsize = newbsize; /* actual buffer allocation */ 3230 bp->b_bcount = size; /* requested buffer size */ 3231 bufspacewakeup(); 3232 } 3233 3234 /* 3235 * biowait: 3236 * 3237 * Wait for buffer I/O completion, returning error status. B_EINTR 3238 * is converted into an EINTR error but not cleared (since a chain 3239 * of biowait() calls may occur). 3240 * 3241 * On return bpdone() will have been called but the buffer will remain 3242 * locked and will not have been brelse()'d. 3243 * 3244 * NOTE! If a timeout is specified and ETIMEDOUT occurs the I/O is 3245 * likely still in progress on return. 3246 * 3247 * NOTE! This operation is on a BIO, not a BUF. 3248 * 3249 * NOTE! BIO_DONE is cleared by vn_strategy() 3250 */ 3251 static __inline int 3252 _biowait(struct bio *bio, const char *wmesg, int to) 3253 { 3254 struct buf *bp = bio->bio_buf; 3255 u_int32_t flags; 3256 u_int32_t nflags; 3257 int error; 3258 3259 KKASSERT(bio == &bp->b_bio1); 3260 for (;;) { 3261 flags = bio->bio_flags; 3262 if (flags & BIO_DONE) 3263 break; 3264 nflags = flags | BIO_WANT; 3265 tsleep_interlock(bio, 0); 3266 if (atomic_cmpset_int(&bio->bio_flags, flags, nflags)) { 3267 if (wmesg) 3268 error = tsleep(bio, PINTERLOCKED, wmesg, to); 3269 else if (bp->b_cmd == BUF_CMD_READ) 3270 error = tsleep(bio, PINTERLOCKED, "biord", to); 3271 else 3272 error = tsleep(bio, PINTERLOCKED, "biowr", to); 3273 if (error) { 3274 kprintf("tsleep error biowait %d\n", error); 3275 return (error); 3276 } 3277 } 3278 } 3279 3280 /* 3281 * Finish up. 3282 */ 3283 KKASSERT(bp->b_cmd == BUF_CMD_DONE); 3284 bio->bio_flags &= ~(BIO_DONE | BIO_SYNC); 3285 if (bp->b_flags & B_EINTR) 3286 return (EINTR); 3287 if (bp->b_flags & B_ERROR) 3288 return (bp->b_error ? bp->b_error : EIO); 3289 return (0); 3290 } 3291 3292 int 3293 biowait(struct bio *bio, const char *wmesg) 3294 { 3295 return(_biowait(bio, wmesg, 0)); 3296 } 3297 3298 int 3299 biowait_timeout(struct bio *bio, const char *wmesg, int to) 3300 { 3301 return(_biowait(bio, wmesg, to)); 3302 } 3303 3304 /* 3305 * This associates a tracking count with an I/O. vn_strategy() and 3306 * dev_dstrategy() do this automatically but there are a few cases 3307 * where a vnode or device layer is bypassed when a block translation 3308 * is cached. In such cases bio_start_transaction() may be called on 3309 * the bypassed layers so the system gets an I/O in progress indication 3310 * for those higher layers. 3311 */ 3312 void 3313 bio_start_transaction(struct bio *bio, struct bio_track *track) 3314 { 3315 bio->bio_track = track; 3316 bio_track_ref(track); 3317 dsched_buf_enter(bio->bio_buf); /* might stack */ 3318 } 3319 3320 /* 3321 * Initiate I/O on a vnode. 3322 * 3323 * SWAPCACHE OPERATION: 3324 * 3325 * Real buffer cache buffers have a non-NULL bp->b_vp. Unfortunately 3326 * devfs also uses b_vp for fake buffers so we also have to check 3327 * that B_PAGING is 0. In this case the passed 'vp' is probably the 3328 * underlying block device. The swap assignments are related to the 3329 * buffer cache buffer's b_vp, not the passed vp. 3330 * 3331 * The passed vp == bp->b_vp only in the case where the strategy call 3332 * is made on the vp itself for its own buffers (a regular file or 3333 * block device vp). The filesystem usually then re-calls vn_strategy() 3334 * after translating the request to an underlying device. 3335 * 3336 * Cluster buffers set B_CLUSTER and the passed vp is the vp of the 3337 * underlying buffer cache buffers. 3338 * 3339 * We can only deal with page-aligned buffers at the moment, because 3340 * we can't tell what the real dirty state for pages straddling a buffer 3341 * are. 3342 * 3343 * In order to call swap_pager_strategy() we must provide the VM object 3344 * and base offset for the underlying buffer cache pages so it can find 3345 * the swap blocks. 3346 */ 3347 void 3348 vn_strategy(struct vnode *vp, struct bio *bio) 3349 { 3350 struct bio_track *track; 3351 struct buf *bp = bio->bio_buf; 3352 3353 KKASSERT(bp->b_cmd != BUF_CMD_DONE); 3354 3355 /* 3356 * Set when an I/O is issued on the bp. Cleared by consumers 3357 * (aka HAMMER), allowing the consumer to determine if I/O had 3358 * actually occurred. 3359 */ 3360 bp->b_flags |= B_IOISSUED; 3361 3362 /* 3363 * Handle the swapcache intercept. 3364 * 3365 * NOTE: The swapcache itself always supports KVABIO and will 3366 * do the right thing if its underlying devices do not. 3367 */ 3368 if (vn_cache_strategy(vp, bio)) 3369 return; 3370 3371 /* 3372 * If the vnode does not support KVABIO and the buffer is using 3373 * KVABIO, we must synchronize b_data to all cpus before dispatching. 3374 */ 3375 if ((vp->v_flag & VKVABIO) == 0 && (bp->b_flags & B_KVABIO)) 3376 bkvasync_all(bp); 3377 3378 /* 3379 * Otherwise do the operation through the filesystem 3380 */ 3381 if (bp->b_cmd == BUF_CMD_READ) 3382 track = &vp->v_track_read; 3383 else 3384 track = &vp->v_track_write; 3385 KKASSERT((bio->bio_flags & BIO_DONE) == 0); 3386 bio->bio_track = track; 3387 bio_track_ref(track); 3388 dsched_buf_enter(bp); /* might stack */ 3389 vop_strategy(*vp->v_ops, vp, bio); 3390 } 3391 3392 /* 3393 * vn_cache_strategy() 3394 * 3395 * Returns 1 if the interrupt was successful, 0 if not. 3396 * 3397 * NOTE: This function supports the KVABIO API wherein b_data might not 3398 * be synchronized to the current cpu. 3399 */ 3400 static void vn_cache_strategy_callback(struct bio *bio); 3401 3402 int 3403 vn_cache_strategy(struct vnode *vp, struct bio *bio) 3404 { 3405 struct buf *bp = bio->bio_buf; 3406 struct bio *nbio; 3407 vm_object_t object; 3408 vm_page_t m; 3409 int i; 3410 3411 /* 3412 * Stop using swapcache if paniced, dumping, or dumped 3413 */ 3414 if (panicstr || dumping) 3415 return(0); 3416 3417 /* 3418 * Is this buffer cache buffer suitable for reading from 3419 * the swap cache? 3420 */ 3421 if (vm_swapcache_read_enable == 0 || 3422 bp->b_cmd != BUF_CMD_READ || 3423 ((bp->b_flags & B_CLUSTER) == 0 && 3424 (bp->b_vp == NULL || (bp->b_flags & B_PAGING))) || 3425 ((int)bp->b_loffset & PAGE_MASK) != 0 || 3426 (bp->b_bcount & PAGE_MASK) != 0) { 3427 return(0); 3428 } 3429 3430 /* 3431 * Figure out the original VM object (it will match the underlying 3432 * VM pages). Note that swap cached data uses page indices relative 3433 * to that object, not relative to bio->bio_offset. 3434 */ 3435 if (bp->b_flags & B_CLUSTER) 3436 object = vp->v_object; 3437 else 3438 object = bp->b_vp->v_object; 3439 3440 /* 3441 * In order to be able to use the swap cache all underlying VM 3442 * pages must be marked as such, and we can't have any bogus pages. 3443 */ 3444 for (i = 0; i < bp->b_xio.xio_npages; ++i) { 3445 m = bp->b_xio.xio_pages[i]; 3446 if ((m->flags & PG_SWAPPED) == 0) 3447 break; 3448 if (m == bogus_page) 3449 break; 3450 } 3451 3452 /* 3453 * If we are good then issue the I/O using swap_pager_strategy(). 3454 * 3455 * We can only do this if the buffer actually supports object-backed 3456 * I/O. If it doesn't npages will be 0. 3457 */ 3458 if (i && i == bp->b_xio.xio_npages) { 3459 m = bp->b_xio.xio_pages[0]; 3460 nbio = push_bio(bio); 3461 nbio->bio_done = vn_cache_strategy_callback; 3462 nbio->bio_offset = ptoa(m->pindex); 3463 KKASSERT(m->object == object); 3464 swap_pager_strategy(object, nbio); 3465 return(1); 3466 } 3467 return(0); 3468 } 3469 3470 /* 3471 * This is a bit of a hack but since the vn_cache_strategy() function can 3472 * override a VFS's strategy function we must make sure that the bio, which 3473 * is probably bio2, doesn't leak an unexpected offset value back to the 3474 * filesystem. The filesystem (e.g. UFS) might otherwise assume that the 3475 * bio went through its own file strategy function and the the bio2 offset 3476 * is a cached disk offset when, in fact, it isn't. 3477 */ 3478 static void 3479 vn_cache_strategy_callback(struct bio *bio) 3480 { 3481 bio->bio_offset = NOOFFSET; 3482 biodone(pop_bio(bio)); 3483 } 3484 3485 /* 3486 * bpdone: 3487 * 3488 * Finish I/O on a buffer after all BIOs have been processed. 3489 * Called when the bio chain is exhausted or by biowait. If called 3490 * by biowait, elseit is typically 0. 3491 * 3492 * bpdone is also responsible for setting B_CACHE in a B_VMIO bp. 3493 * In a non-VMIO bp, B_CACHE will be set on the next getblk() 3494 * assuming B_INVAL is clear. 3495 * 3496 * For the VMIO case, we set B_CACHE if the op was a read and no 3497 * read error occured, or if the op was a write. B_CACHE is never 3498 * set if the buffer is invalid or otherwise uncacheable. 3499 * 3500 * bpdone does not mess with B_INVAL, allowing the I/O routine or the 3501 * initiator to leave B_INVAL set to brelse the buffer out of existance 3502 * in the biodone routine. 3503 * 3504 * bpdone is responsible for calling bundirty() on the buffer after a 3505 * successful write. We previously did this prior to initiating the 3506 * write under the assumption that the buffer might be dirtied again 3507 * while the write was in progress, however doing it before-hand creates 3508 * a race condition prior to the call to vn_strategy() where the 3509 * filesystem may not be aware that a dirty buffer is present. 3510 * It should not be possible for the buffer or its underlying pages to 3511 * be redirtied prior to bpdone()'s unbusying of the underlying VM 3512 * pages. 3513 */ 3514 void 3515 bpdone(struct buf *bp, int elseit) 3516 { 3517 buf_cmd_t cmd; 3518 3519 KASSERT(BUF_LOCKINUSE(bp), ("bpdone: bp %p not busy", bp)); 3520 KASSERT(bp->b_cmd != BUF_CMD_DONE, 3521 ("bpdone: bp %p already done!", bp)); 3522 3523 /* 3524 * No more BIOs are left. All completion functions have been dealt 3525 * with, now we clean up the buffer. 3526 */ 3527 cmd = bp->b_cmd; 3528 bp->b_cmd = BUF_CMD_DONE; 3529 3530 /* 3531 * Only reads and writes are processed past this point. 3532 */ 3533 if (cmd != BUF_CMD_READ && cmd != BUF_CMD_WRITE) { 3534 if (cmd == BUF_CMD_FREEBLKS) 3535 bp->b_flags |= B_NOCACHE; 3536 if (elseit) 3537 brelse(bp); 3538 return; 3539 } 3540 3541 /* 3542 * A failed write must re-dirty the buffer unless B_INVAL 3543 * was set. 3544 * 3545 * A successful write must clear the dirty flag. This is done after 3546 * the write to ensure that the buffer remains on the vnode's dirty 3547 * list for filesystem interlocks / checks until the write is actually 3548 * complete. HAMMER2 is sensitive to this issue. 3549 * 3550 * Only applicable to normal buffers (with VPs). vinum buffers may 3551 * not have a vp. 3552 * 3553 * Must be done prior to calling buf_complete() as the callback might 3554 * re-dirty the buffer. 3555 */ 3556 if (cmd == BUF_CMD_WRITE) { 3557 if ((bp->b_flags & (B_ERROR | B_INVAL)) == B_ERROR) { 3558 bp->b_flags &= ~B_NOCACHE; 3559 if (bp->b_vp) 3560 bdirty(bp); 3561 } else { 3562 if (bp->b_vp) 3563 bundirty(bp); 3564 } 3565 } 3566 3567 /* 3568 * Warning: softupdates may re-dirty the buffer, and HAMMER can do 3569 * a lot worse. XXX - move this above the clearing of b_cmd 3570 */ 3571 if (LIST_FIRST(&bp->b_dep) != NULL) 3572 buf_complete(bp); 3573 3574 if (bp->b_flags & B_VMIO) { 3575 int i; 3576 vm_ooffset_t foff; 3577 vm_page_t m; 3578 vm_object_t obj; 3579 int iosize; 3580 struct vnode *vp = bp->b_vp; 3581 3582 obj = vp->v_object; 3583 3584 #if defined(VFS_BIO_DEBUG) 3585 if (vp->v_auxrefs == 0) 3586 panic("bpdone: zero vnode hold count"); 3587 if ((vp->v_flag & VOBJBUF) == 0) 3588 panic("bpdone: vnode is not setup for merged cache"); 3589 #endif 3590 3591 foff = bp->b_loffset; 3592 KASSERT(foff != NOOFFSET, ("bpdone: no buffer offset")); 3593 KASSERT(obj != NULL, ("bpdone: missing VM object")); 3594 3595 #if defined(VFS_BIO_DEBUG) 3596 if (obj->paging_in_progress < bp->b_xio.xio_npages) { 3597 kprintf("bpdone: paging in progress(%d) < " 3598 "bp->b_xio.xio_npages(%d)\n", 3599 obj->paging_in_progress, 3600 bp->b_xio.xio_npages); 3601 } 3602 #endif 3603 3604 /* 3605 * Set B_CACHE if the op was a normal read and no error 3606 * occured. B_CACHE is set for writes in the b*write() 3607 * routines. 3608 */ 3609 iosize = bp->b_bcount - bp->b_resid; 3610 if (cmd == BUF_CMD_READ && 3611 (bp->b_flags & (B_INVAL|B_NOCACHE|B_ERROR)) == 0) { 3612 bp->b_flags |= B_CACHE; 3613 } 3614 3615 vm_object_hold(obj); 3616 for (i = 0; i < bp->b_xio.xio_npages; i++) { 3617 int resid; 3618 int isbogus; 3619 3620 resid = ((foff + PAGE_SIZE) & ~(off_t)PAGE_MASK) - foff; 3621 if (resid > iosize) 3622 resid = iosize; 3623 3624 /* 3625 * cleanup bogus pages, restoring the originals. Since 3626 * the originals should still be wired, we don't have 3627 * to worry about interrupt/freeing races destroying 3628 * the VM object association. 3629 */ 3630 m = bp->b_xio.xio_pages[i]; 3631 if (m == bogus_page) { 3632 if ((bp->b_flags & B_HASBOGUS) == 0) 3633 panic("bpdone: bp %p corrupt bogus", bp); 3634 m = vm_page_lookup(obj, OFF_TO_IDX(foff)); 3635 if (m == NULL) 3636 panic("bpdone: page disappeared"); 3637 bp->b_xio.xio_pages[i] = m; 3638 isbogus = 1; 3639 } else { 3640 isbogus = 0; 3641 } 3642 #if defined(VFS_BIO_DEBUG) 3643 if (OFF_TO_IDX(foff) != m->pindex) { 3644 kprintf("bpdone: foff(%lu)/m->pindex(%ld) " 3645 "mismatch\n", 3646 (unsigned long)foff, (long)m->pindex); 3647 } 3648 #endif 3649 3650 /* 3651 * In the write case, the valid and clean bits are 3652 * already changed correctly (see bdwrite()), so we 3653 * only need to do this here in the read case. 3654 */ 3655 vm_page_busy_wait(m, FALSE, "bpdpgw"); 3656 if (cmd == BUF_CMD_READ && isbogus == 0 && resid > 0) 3657 vfs_clean_one_page(bp, i, m); 3658 3659 /* 3660 * when debugging new filesystems or buffer I/O 3661 * methods, this is the most common error that pops 3662 * up. if you see this, you have not set the page 3663 * busy flag correctly!!! 3664 */ 3665 if ((m->busy_count & PBUSY_MASK) == 0) { 3666 kprintf("bpdone: page busy < 0, " 3667 "pindex: %d, foff: 0x(%x,%x), " 3668 "resid: %d, index: %d\n", 3669 (int) m->pindex, (int)(foff >> 32), 3670 (int) foff & 0xffffffff, resid, i); 3671 if (!vn_isdisk(vp, NULL)) 3672 kprintf(" iosize: %ld, loffset: %lld, " 3673 "flags: 0x%08x, npages: %d\n", 3674 bp->b_vp->v_mount->mnt_stat.f_iosize, 3675 (long long)bp->b_loffset, 3676 bp->b_flags, bp->b_xio.xio_npages); 3677 else 3678 kprintf(" VDEV, loffset: %lld, flags: 0x%08x, npages: %d\n", 3679 (long long)bp->b_loffset, 3680 bp->b_flags, bp->b_xio.xio_npages); 3681 kprintf(" valid: 0x%x, dirty: 0x%x, " 3682 "wired: %d\n", 3683 m->valid, m->dirty, 3684 m->wire_count); 3685 panic("bpdone: page busy < 0"); 3686 } 3687 vm_page_io_finish(m); 3688 vm_page_wakeup(m); 3689 vm_object_pip_wakeup(obj); 3690 foff = (foff + PAGE_SIZE) & ~(off_t)PAGE_MASK; 3691 iosize -= resid; 3692 } 3693 if (bp->b_flags & B_HASBOGUS) { 3694 pmap_qenter_noinval(trunc_page((vm_offset_t)bp->b_data), 3695 bp->b_xio.xio_pages, 3696 bp->b_xio.xio_npages); 3697 bp->b_flags &= ~B_HASBOGUS; 3698 bkvareset(bp); 3699 } 3700 vm_object_drop(obj); 3701 } 3702 3703 /* 3704 * Finish up by releasing the buffer. There are no more synchronous 3705 * or asynchronous completions, those were handled by bio_done 3706 * callbacks. 3707 */ 3708 if (elseit) { 3709 if (bp->b_flags & (B_NOCACHE|B_INVAL|B_ERROR|B_RELBUF)) 3710 brelse(bp); 3711 else 3712 bqrelse(bp); 3713 } 3714 } 3715 3716 /* 3717 * Normal biodone. 3718 */ 3719 void 3720 biodone(struct bio *bio) 3721 { 3722 struct buf *bp = bio->bio_buf; 3723 3724 runningbufwakeup(bp); 3725 3726 /* 3727 * Run up the chain of BIO's. Leave b_cmd intact for the duration. 3728 */ 3729 while (bio) { 3730 biodone_t *done_func; 3731 struct bio_track *track; 3732 3733 /* 3734 * BIO tracking. Most but not all BIOs are tracked. 3735 */ 3736 if ((track = bio->bio_track) != NULL) { 3737 bio_track_rel(track); 3738 bio->bio_track = NULL; 3739 } 3740 3741 /* 3742 * A bio_done function terminates the loop. The function 3743 * will be responsible for any further chaining and/or 3744 * buffer management. 3745 * 3746 * WARNING! The done function can deallocate the buffer! 3747 */ 3748 if ((done_func = bio->bio_done) != NULL) { 3749 bio->bio_done = NULL; 3750 done_func(bio); 3751 return; 3752 } 3753 bio = bio->bio_prev; 3754 } 3755 3756 /* 3757 * If we've run out of bio's do normal [a]synchronous completion. 3758 */ 3759 bpdone(bp, 1); 3760 } 3761 3762 /* 3763 * Synchronous biodone - this terminates a synchronous BIO. 3764 * 3765 * bpdone() is called with elseit=FALSE, leaving the buffer completed 3766 * but still locked. The caller must brelse() the buffer after waiting 3767 * for completion. 3768 */ 3769 void 3770 biodone_sync(struct bio *bio) 3771 { 3772 struct buf *bp = bio->bio_buf; 3773 int flags; 3774 int nflags; 3775 3776 KKASSERT(bio == &bp->b_bio1); 3777 bpdone(bp, 0); 3778 3779 for (;;) { 3780 flags = bio->bio_flags; 3781 nflags = (flags | BIO_DONE) & ~BIO_WANT; 3782 3783 if (atomic_cmpset_int(&bio->bio_flags, flags, nflags)) { 3784 if (flags & BIO_WANT) 3785 wakeup(bio); 3786 break; 3787 } 3788 } 3789 } 3790 3791 /* 3792 * vfs_unbusy_pages: 3793 * 3794 * This routine is called in lieu of iodone in the case of 3795 * incomplete I/O. This keeps the busy status for pages 3796 * consistant. 3797 */ 3798 void 3799 vfs_unbusy_pages(struct buf *bp) 3800 { 3801 int i; 3802 3803 runningbufwakeup(bp); 3804 3805 if (bp->b_flags & B_VMIO) { 3806 struct vnode *vp = bp->b_vp; 3807 vm_object_t obj; 3808 3809 obj = vp->v_object; 3810 vm_object_hold(obj); 3811 3812 for (i = 0; i < bp->b_xio.xio_npages; i++) { 3813 vm_page_t m = bp->b_xio.xio_pages[i]; 3814 3815 /* 3816 * When restoring bogus changes the original pages 3817 * should still be wired, so we are in no danger of 3818 * losing the object association and do not need 3819 * critical section protection particularly. 3820 */ 3821 if (m == bogus_page) { 3822 m = vm_page_lookup(obj, OFF_TO_IDX(bp->b_loffset) + i); 3823 if (!m) { 3824 panic("vfs_unbusy_pages: page missing"); 3825 } 3826 bp->b_xio.xio_pages[i] = m; 3827 } 3828 vm_page_busy_wait(m, FALSE, "bpdpgw"); 3829 vm_page_io_finish(m); 3830 vm_page_wakeup(m); 3831 vm_object_pip_wakeup(obj); 3832 } 3833 if (bp->b_flags & B_HASBOGUS) { 3834 pmap_qenter_noinval(trunc_page((vm_offset_t)bp->b_data), 3835 bp->b_xio.xio_pages, 3836 bp->b_xio.xio_npages); 3837 bp->b_flags &= ~B_HASBOGUS; 3838 bkvareset(bp); 3839 } 3840 vm_object_drop(obj); 3841 } 3842 } 3843 3844 /* 3845 * vfs_busy_pages: 3846 * 3847 * This routine is called before a device strategy routine. 3848 * It is used to tell the VM system that paging I/O is in 3849 * progress, and treat the pages associated with the buffer 3850 * almost as being PBUSY_LOCKED. Also the object 'paging_in_progress' 3851 * flag is handled to make sure that the object doesn't become 3852 * inconsistant. 3853 * 3854 * Since I/O has not been initiated yet, certain buffer flags 3855 * such as B_ERROR or B_INVAL may be in an inconsistant state 3856 * and should be ignored. 3857 */ 3858 void 3859 vfs_busy_pages(struct vnode *vp, struct buf *bp) 3860 { 3861 int i, bogus; 3862 struct lwp *lp = curthread->td_lwp; 3863 3864 /* 3865 * The buffer's I/O command must already be set. If reading, 3866 * B_CACHE must be 0 (double check against callers only doing 3867 * I/O when B_CACHE is 0). 3868 */ 3869 KKASSERT(bp->b_cmd != BUF_CMD_DONE); 3870 KKASSERT(bp->b_cmd == BUF_CMD_WRITE || (bp->b_flags & B_CACHE) == 0); 3871 3872 if (bp->b_flags & B_VMIO) { 3873 vm_object_t obj; 3874 3875 obj = vp->v_object; 3876 KASSERT(bp->b_loffset != NOOFFSET, 3877 ("vfs_busy_pages: no buffer offset")); 3878 3879 /* 3880 * Busy all the pages. We have to busy them all at once 3881 * to avoid deadlocks. 3882 */ 3883 retry: 3884 for (i = 0; i < bp->b_xio.xio_npages; i++) { 3885 vm_page_t m = bp->b_xio.xio_pages[i]; 3886 3887 if (vm_page_busy_try(m, FALSE)) { 3888 vm_page_sleep_busy(m, FALSE, "vbpage"); 3889 while (--i >= 0) 3890 vm_page_wakeup(bp->b_xio.xio_pages[i]); 3891 goto retry; 3892 } 3893 } 3894 3895 /* 3896 * Setup for I/O, soft-busy the page right now because 3897 * the next loop may block. 3898 */ 3899 for (i = 0; i < bp->b_xio.xio_npages; i++) { 3900 vm_page_t m = bp->b_xio.xio_pages[i]; 3901 3902 if ((bp->b_flags & B_CLUSTER) == 0) { 3903 vm_object_pip_add(obj, 1); 3904 vm_page_io_start(m); 3905 } 3906 } 3907 3908 /* 3909 * Adjust protections for I/O and do bogus-page mapping. 3910 * Assume that vm_page_protect() can block (it can block 3911 * if VM_PROT_NONE, don't take any chances regardless). 3912 * 3913 * In particular note that for writes we must incorporate 3914 * page dirtyness from the VM system into the buffer's 3915 * dirty range. 3916 * 3917 * For reads we theoretically must incorporate page dirtyness 3918 * from the VM system to determine if the page needs bogus 3919 * replacement, but we shortcut the test by simply checking 3920 * that all m->valid bits are set, indicating that the page 3921 * is fully valid and does not need to be re-read. For any 3922 * VM system dirtyness the page will also be fully valid 3923 * since it was mapped at one point. 3924 */ 3925 bogus = 0; 3926 for (i = 0; i < bp->b_xio.xio_npages; i++) { 3927 vm_page_t m = bp->b_xio.xio_pages[i]; 3928 3929 if (bp->b_cmd == BUF_CMD_WRITE) { 3930 /* 3931 * When readying a vnode-backed buffer for 3932 * a write we must zero-fill any invalid 3933 * portions of the backing VM pages, mark 3934 * it valid and clear related dirty bits. 3935 * 3936 * vfs_clean_one_page() incorporates any 3937 * VM dirtyness and updates the b_dirtyoff 3938 * range (after we've made the page RO). 3939 * 3940 * It is also expected that the pmap modified 3941 * bit has already been cleared by the 3942 * vm_page_protect(). We may not be able 3943 * to clear all dirty bits for a page if it 3944 * was also memory mapped (NFS). 3945 * 3946 * Finally be sure to unassign any swap-cache 3947 * backing store as it is now stale. 3948 */ 3949 vm_page_protect(m, VM_PROT_READ); 3950 vfs_clean_one_page(bp, i, m); 3951 swap_pager_unswapped(m); 3952 } else if (m->valid == VM_PAGE_BITS_ALL) { 3953 /* 3954 * When readying a vnode-backed buffer for 3955 * read we must replace any dirty pages with 3956 * a bogus page so dirty data is not destroyed 3957 * when filling gaps. 3958 * 3959 * To avoid testing whether the page is 3960 * dirty we instead test that the page was 3961 * at some point mapped (m->valid fully 3962 * valid) with the understanding that 3963 * this also covers the dirty case. 3964 */ 3965 bp->b_xio.xio_pages[i] = bogus_page; 3966 bp->b_flags |= B_HASBOGUS; 3967 bogus++; 3968 } else if (m->valid & m->dirty) { 3969 /* 3970 * This case should not occur as partial 3971 * dirtyment can only happen if the buffer 3972 * is B_CACHE, and this code is not entered 3973 * if the buffer is B_CACHE. 3974 */ 3975 kprintf("Warning: vfs_busy_pages - page not " 3976 "fully valid! loff=%jx bpf=%08x " 3977 "idx=%d val=%02x dir=%02x\n", 3978 (uintmax_t)bp->b_loffset, bp->b_flags, 3979 i, m->valid, m->dirty); 3980 vm_page_protect(m, VM_PROT_NONE); 3981 } else { 3982 /* 3983 * The page is not valid and can be made 3984 * part of the read. 3985 */ 3986 vm_page_protect(m, VM_PROT_NONE); 3987 } 3988 vm_page_wakeup(m); 3989 } 3990 if (bogus) { 3991 pmap_qenter_noinval(trunc_page((vm_offset_t)bp->b_data), 3992 bp->b_xio.xio_pages, 3993 bp->b_xio.xio_npages); 3994 bkvareset(bp); 3995 } 3996 } 3997 3998 /* 3999 * This is the easiest place to put the process accounting for the I/O 4000 * for now. 4001 */ 4002 if (lp != NULL) { 4003 if (bp->b_cmd == BUF_CMD_READ) 4004 lp->lwp_ru.ru_inblock++; 4005 else 4006 lp->lwp_ru.ru_oublock++; 4007 } 4008 } 4009 4010 /* 4011 * Tell the VM system that the pages associated with this buffer 4012 * are clean. This is used for delayed writes where the data is 4013 * going to go to disk eventually without additional VM intevention. 4014 * 4015 * NOTE: While we only really need to clean through to b_bcount, we 4016 * just go ahead and clean through to b_bufsize. 4017 */ 4018 static void 4019 vfs_clean_pages(struct buf *bp) 4020 { 4021 vm_page_t m; 4022 int i; 4023 4024 if ((bp->b_flags & B_VMIO) == 0) 4025 return; 4026 4027 KASSERT(bp->b_loffset != NOOFFSET, 4028 ("vfs_clean_pages: no buffer offset")); 4029 4030 for (i = 0; i < bp->b_xio.xio_npages; i++) { 4031 m = bp->b_xio.xio_pages[i]; 4032 vfs_clean_one_page(bp, i, m); 4033 } 4034 } 4035 4036 /* 4037 * vfs_clean_one_page: 4038 * 4039 * Set the valid bits and clear the dirty bits in a page within a 4040 * buffer. The range is restricted to the buffer's size and the 4041 * buffer's logical offset might index into the first page. 4042 * 4043 * The caller has busied or soft-busied the page and it is not mapped, 4044 * test and incorporate the dirty bits into b_dirtyoff/end before 4045 * clearing them. Note that we need to clear the pmap modified bits 4046 * after determining the the page was dirty, vm_page_set_validclean() 4047 * does not do it for us. 4048 * 4049 * This routine is typically called after a read completes (dirty should 4050 * be zero in that case as we are not called on bogus-replace pages), 4051 * or before a write is initiated. 4052 */ 4053 static void 4054 vfs_clean_one_page(struct buf *bp, int pageno, vm_page_t m) 4055 { 4056 int bcount; 4057 int xoff; 4058 int soff; 4059 int eoff; 4060 4061 /* 4062 * Calculate offset range within the page but relative to buffer's 4063 * loffset. loffset might be offset into the first page. 4064 */ 4065 xoff = (int)bp->b_loffset & PAGE_MASK; /* loffset offset into pg 0 */ 4066 bcount = bp->b_bcount + xoff; /* offset adjusted */ 4067 4068 if (pageno == 0) { 4069 soff = xoff; 4070 eoff = PAGE_SIZE; 4071 } else { 4072 soff = (pageno << PAGE_SHIFT); 4073 eoff = soff + PAGE_SIZE; 4074 } 4075 if (eoff > bcount) 4076 eoff = bcount; 4077 if (soff >= eoff) 4078 return; 4079 4080 /* 4081 * Test dirty bits and adjust b_dirtyoff/end. 4082 * 4083 * If dirty pages are incorporated into the bp any prior 4084 * B_NEEDCOMMIT state (NFS) must be cleared because the 4085 * caller has not taken into account the new dirty data. 4086 * 4087 * If the page was memory mapped the dirty bits might go beyond the 4088 * end of the buffer, but we can't really make the assumption that 4089 * a file EOF straddles the buffer (even though this is the case for 4090 * NFS if B_NEEDCOMMIT is also set). So for the purposes of clearing 4091 * B_NEEDCOMMIT we only test the dirty bits covered by the buffer. 4092 * This also saves some console spam. 4093 * 4094 * When clearing B_NEEDCOMMIT we must also clear B_CLUSTEROK, 4095 * NFS can handle huge commits but not huge writes. 4096 */ 4097 vm_page_test_dirty(m); 4098 if (m->dirty) { 4099 if ((bp->b_flags & B_NEEDCOMMIT) && 4100 (m->dirty & vm_page_bits(soff & PAGE_MASK, eoff - soff))) { 4101 if (debug_commit) 4102 kprintf("Warning: vfs_clean_one_page: bp %p " 4103 "loff=%jx,%d flgs=%08x clr B_NEEDCOMMIT" 4104 " cmd %d vd %02x/%02x x/s/e %d %d %d " 4105 "doff/end %d %d\n", 4106 bp, (uintmax_t)bp->b_loffset, bp->b_bcount, 4107 bp->b_flags, bp->b_cmd, 4108 m->valid, m->dirty, xoff, soff, eoff, 4109 bp->b_dirtyoff, bp->b_dirtyend); 4110 bp->b_flags &= ~(B_NEEDCOMMIT | B_CLUSTEROK); 4111 if (debug_commit) 4112 print_backtrace(-1); 4113 } 4114 /* 4115 * Only clear the pmap modified bits if ALL the dirty bits 4116 * are set, otherwise the system might mis-clear portions 4117 * of a page. 4118 */ 4119 if (m->dirty == VM_PAGE_BITS_ALL && 4120 (bp->b_flags & B_NEEDCOMMIT) == 0) { 4121 pmap_clear_modify(m); 4122 } 4123 if (bp->b_dirtyoff > soff - xoff) 4124 bp->b_dirtyoff = soff - xoff; 4125 if (bp->b_dirtyend < eoff - xoff) 4126 bp->b_dirtyend = eoff - xoff; 4127 } 4128 4129 /* 4130 * Set related valid bits, clear related dirty bits. 4131 * Does not mess with the pmap modified bit. 4132 * 4133 * WARNING! We cannot just clear all of m->dirty here as the 4134 * buffer cache buffers may use a DEV_BSIZE'd aligned 4135 * block size, or have an odd size (e.g. NFS at file EOF). 4136 * The putpages code can clear m->dirty to 0. 4137 * 4138 * If a VOP_WRITE generates a buffer cache buffer which 4139 * covers the same space as mapped writable pages the 4140 * buffer flush might not be able to clear all the dirty 4141 * bits and still require a putpages from the VM system 4142 * to finish it off. 4143 * 4144 * WARNING! vm_page_set_validclean() currently assumes vm_token 4145 * is held. The page might not be busied (bdwrite() case). 4146 * XXX remove this comment once we've validated that this 4147 * is no longer an issue. 4148 */ 4149 vm_page_set_validclean(m, soff & PAGE_MASK, eoff - soff); 4150 } 4151 4152 #if 0 4153 /* 4154 * Similar to vfs_clean_one_page() but sets the bits to valid and dirty. 4155 * The page data is assumed to be valid (there is no zeroing here). 4156 */ 4157 static void 4158 vfs_dirty_one_page(struct buf *bp, int pageno, vm_page_t m) 4159 { 4160 int bcount; 4161 int xoff; 4162 int soff; 4163 int eoff; 4164 4165 /* 4166 * Calculate offset range within the page but relative to buffer's 4167 * loffset. loffset might be offset into the first page. 4168 */ 4169 xoff = (int)bp->b_loffset & PAGE_MASK; /* loffset offset into pg 0 */ 4170 bcount = bp->b_bcount + xoff; /* offset adjusted */ 4171 4172 if (pageno == 0) { 4173 soff = xoff; 4174 eoff = PAGE_SIZE; 4175 } else { 4176 soff = (pageno << PAGE_SHIFT); 4177 eoff = soff + PAGE_SIZE; 4178 } 4179 if (eoff > bcount) 4180 eoff = bcount; 4181 if (soff >= eoff) 4182 return; 4183 vm_page_set_validdirty(m, soff & PAGE_MASK, eoff - soff); 4184 } 4185 #endif 4186 4187 /* 4188 * vfs_bio_clrbuf: 4189 * 4190 * Clear a buffer. This routine essentially fakes an I/O, so we need 4191 * to clear B_ERROR and B_INVAL. 4192 * 4193 * Note that while we only theoretically need to clear through b_bcount, 4194 * we go ahead and clear through b_bufsize. 4195 */ 4196 void 4197 vfs_bio_clrbuf(struct buf *bp) 4198 { 4199 int i, mask = 0; 4200 caddr_t sa, ea; 4201 KKASSERT(bp->b_flags & B_VMIO); 4202 4203 bp->b_flags &= ~(B_INVAL | B_EINTR | B_ERROR); 4204 bkvasync(bp); 4205 4206 if ((bp->b_xio.xio_npages == 1) && (bp->b_bufsize < PAGE_SIZE) && 4207 (bp->b_loffset & PAGE_MASK) == 0) { 4208 mask = (1 << (bp->b_bufsize / DEV_BSIZE)) - 1; 4209 if ((bp->b_xio.xio_pages[0]->valid & mask) == mask) { 4210 bp->b_resid = 0; 4211 return; 4212 } 4213 if ((bp->b_xio.xio_pages[0]->valid & mask) == 0) { 4214 bzero(bp->b_data, bp->b_bufsize); 4215 bp->b_xio.xio_pages[0]->valid |= mask; 4216 bp->b_resid = 0; 4217 return; 4218 } 4219 } 4220 sa = bp->b_data; 4221 for(i = 0; i < bp->b_xio.xio_npages; i++, sa=ea) { 4222 int j = ((vm_offset_t)sa & PAGE_MASK) / DEV_BSIZE; 4223 ea = (caddr_t)trunc_page((vm_offset_t)sa + PAGE_SIZE); 4224 ea = (caddr_t)(vm_offset_t)ulmin( 4225 (u_long)(vm_offset_t)ea, 4226 (u_long)(vm_offset_t)bp->b_data + bp->b_bufsize); 4227 mask = ((1 << ((ea - sa) / DEV_BSIZE)) - 1) << j; 4228 if ((bp->b_xio.xio_pages[i]->valid & mask) == mask) 4229 continue; 4230 if ((bp->b_xio.xio_pages[i]->valid & mask) == 0) { 4231 bzero(sa, ea - sa); 4232 } else { 4233 for (; sa < ea; sa += DEV_BSIZE, j++) { 4234 if ((bp->b_xio.xio_pages[i]->valid & 4235 (1<<j)) == 0) { 4236 bzero(sa, DEV_BSIZE); 4237 } 4238 } 4239 } 4240 bp->b_xio.xio_pages[i]->valid |= mask; 4241 } 4242 bp->b_resid = 0; 4243 } 4244 4245 /* 4246 * Allocate a page for a buffer cache buffer. 4247 * 4248 * If NULL is returned the caller is expected to retry (typically check if 4249 * the page already exists on retry before trying to allocate one). 4250 * 4251 * NOTE! Low-memory handling is dealt with in b[q]relse(), not here. This 4252 * function will use the system reserve with the hope that the page 4253 * allocations can be returned to PQ_CACHE/PQ_FREE when the caller 4254 * is done with the buffer. 4255 * 4256 * NOTE! However, TMPFS is a special case because flushing a dirty buffer 4257 * to TMPFS doesn't clean the page. For TMPFS, only the pagedaemon 4258 * is capable of retiring pages (to swap). For TMPFS we don't dig 4259 * into the system reserve because doing so could stall out pretty 4260 * much every process running on the system. 4261 */ 4262 static 4263 vm_page_t 4264 bio_page_alloc(struct buf *bp, vm_object_t obj, vm_pindex_t pg, int deficit) 4265 { 4266 int vmflags = VM_ALLOC_NORMAL | VM_ALLOC_NULL_OK; 4267 vm_page_t p; 4268 4269 ASSERT_LWKT_TOKEN_HELD(vm_object_token(obj)); 4270 4271 /* 4272 * Avoid localized page-queue exhaustion by rotating the effective 4273 * cpu-base for the BIO page allocation. Remember we are trying to 4274 * avoid contention, so we want all the cpus to be in lockstep with 4275 * different cpuids. Really serious contention in the kernel page 4276 * allocator can occur without this. 4277 * 4278 * This is kinda anti-NUMA, but localizing file data is a really hard 4279 * call. It works great in some situations (temporary files in tmpfs), 4280 * and horribly in other situations. 4281 * 4282 * XXX add some NUMA relocalization (2 zones or 4 zones). 4283 */ 4284 vmflags |= VM_ALLOC_CPU((mycpu->gd_cpuid + (u_short)ticks) % ncpus); 4285 4286 /* 4287 * Try a normal allocation first. 4288 */ 4289 p = vm_page_alloc(obj, pg, vmflags); 4290 if (p) 4291 return(p); 4292 if (vm_page_lookup(obj, pg)) 4293 return(NULL); 4294 vm_pageout_deficit += deficit; 4295 4296 /* 4297 * Try again, digging into the system reserve. 4298 * 4299 * Trying to recover pages from the buffer cache here can deadlock 4300 * against other threads trying to busy underlying pages so we 4301 * depend on the code in brelse() and bqrelse() to free/cache the 4302 * underlying buffer cache pages when memory is low. 4303 */ 4304 if (curthread->td_flags & TDF_SYSTHREAD) 4305 vmflags |= VM_ALLOC_SYSTEM | VM_ALLOC_INTERRUPT; 4306 else if (bp->b_vp && bp->b_vp->v_tag == VT_TMPFS) 4307 vmflags |= 0; 4308 else 4309 vmflags |= VM_ALLOC_SYSTEM; 4310 4311 /*recoverbufpages();*/ 4312 p = vm_page_alloc(obj, pg, vmflags); 4313 if (p) 4314 return(p); 4315 if (vm_page_lookup(obj, pg)) 4316 return(NULL); 4317 4318 /* 4319 * Wait for memory to free up and try again 4320 */ 4321 if (vm_paging_severe()) 4322 ++lowmempgallocs; 4323 vm_wait(hz / 20 + 1); 4324 4325 p = vm_page_alloc(obj, pg, vmflags); 4326 if (p) 4327 return(p); 4328 if (vm_page_lookup(obj, pg)) 4329 return(NULL); 4330 4331 /* 4332 * Ok, now we are really in trouble. 4333 */ 4334 if (bootverbose) { 4335 static struct krate biokrate = { .freq = 1 }; 4336 krateprintf(&biokrate, 4337 "Warning: bio_page_alloc: memory exhausted " 4338 "during buffer cache page allocation from %s\n", 4339 curthread->td_comm); 4340 } 4341 if (curthread->td_flags & TDF_SYSTHREAD) 4342 vm_wait(hz / 20 + 1); 4343 else 4344 vm_wait(hz / 2 + 1); 4345 return (NULL); 4346 } 4347 4348 /* 4349 * The buffer's mapping has changed. Adjust the buffer's memory 4350 * synchronization. The caller is the exclusive holder of the buffer 4351 * and has set or cleared B_KVABIO according to preference. 4352 * 4353 * WARNING! If the caller is using B_KVABIO mode, this function will 4354 * not map the data to the current cpu. The caller must also 4355 * call bkvasync(bp). 4356 */ 4357 void 4358 bkvareset(struct buf *bp) 4359 { 4360 if (bp->b_flags & B_KVABIO) { 4361 CPUMASK_ASSZERO(bp->b_cpumask); 4362 } else { 4363 CPUMASK_ORMASK(bp->b_cpumask, smp_active_mask); 4364 smp_invltlb(); 4365 cpu_invltlb(); 4366 } 4367 } 4368 4369 /* 4370 * The buffer will be used by the caller on the caller's cpu, synchronize 4371 * its data to the current cpu. Caller must control the buffer by holding 4372 * its lock, but calling cpu does not necessarily have to be the owner of 4373 * the lock (i.e. HAMMER2's concurrent I/O accessors). 4374 * 4375 * If B_KVABIO is not set, the buffer is already fully synchronized. 4376 */ 4377 void 4378 bkvasync(struct buf *bp) 4379 { 4380 int cpuid = mycpu->gd_cpuid; 4381 char *bdata; 4382 4383 if ((bp->b_flags & B_KVABIO) && 4384 CPUMASK_TESTBIT(bp->b_cpumask, cpuid) == 0) { 4385 bdata = bp->b_data; 4386 while (bdata < bp->b_data + bp->b_bufsize) { 4387 cpu_invlpg(bdata); 4388 bdata += PAGE_SIZE - 4389 ((intptr_t)bdata & PAGE_MASK); 4390 } 4391 ATOMIC_CPUMASK_ORBIT(bp->b_cpumask, cpuid); 4392 } 4393 } 4394 4395 /* 4396 * The buffer will be used by a subsystem that does not understand 4397 * the KVABIO API. Make sure its data is synchronized to all cpus. 4398 * 4399 * If B_KVABIO is not set, the buffer is already fully synchronized. 4400 * 4401 * NOTE! This is the only safe way to clear B_KVABIO on a buffer. 4402 */ 4403 void 4404 bkvasync_all(struct buf *bp) 4405 { 4406 if (debug_kvabio > 0) { 4407 --debug_kvabio; 4408 print_backtrace(10); 4409 } 4410 4411 if ((bp->b_flags & B_KVABIO) && 4412 CPUMASK_CMPMASKNEQ(bp->b_cpumask, smp_active_mask)) { 4413 smp_invltlb(); 4414 cpu_invltlb(); 4415 ATOMIC_CPUMASK_ORMASK(bp->b_cpumask, smp_active_mask); 4416 } 4417 bp->b_flags &= ~B_KVABIO; 4418 } 4419 4420 /* 4421 * Scan all buffers in the system and issue the callback. 4422 */ 4423 int 4424 scan_all_buffers(int (*callback)(struct buf *, void *), void *info) 4425 { 4426 int count = 0; 4427 int error; 4428 long n; 4429 4430 for (n = 0; n < nbuf; ++n) { 4431 if ((error = callback(&buf[n], info)) < 0) { 4432 count = error; 4433 break; 4434 } 4435 count += error; 4436 } 4437 return (count); 4438 } 4439 4440 /* 4441 * nestiobuf_iodone: biodone callback for nested buffers and propagate 4442 * completion to the master buffer. 4443 */ 4444 static void 4445 nestiobuf_iodone(struct bio *bio) 4446 { 4447 struct bio *mbio; 4448 struct buf *mbp, *bp; 4449 struct devstat *stats; 4450 int error; 4451 int donebytes; 4452 4453 bp = bio->bio_buf; 4454 mbio = bio->bio_caller_info1.ptr; 4455 stats = bio->bio_caller_info2.ptr; 4456 mbp = mbio->bio_buf; 4457 4458 KKASSERT(bp->b_bcount <= bp->b_bufsize); 4459 KKASSERT(mbp != bp); 4460 4461 error = bp->b_error; 4462 if (bp->b_error == 0 && 4463 (bp->b_bcount < bp->b_bufsize || bp->b_resid > 0)) { 4464 /* 4465 * Not all got transfered, raise an error. We have no way to 4466 * propagate these conditions to mbp. 4467 */ 4468 error = EIO; 4469 } 4470 4471 donebytes = bp->b_bufsize; 4472 4473 relpbuf(bp, NULL); 4474 4475 nestiobuf_done(mbio, donebytes, error, stats); 4476 } 4477 4478 void 4479 nestiobuf_done(struct bio *mbio, int donebytes, int error, struct devstat *stats) 4480 { 4481 struct buf *mbp; 4482 4483 mbp = mbio->bio_buf; 4484 4485 KKASSERT((int)(intptr_t)mbio->bio_driver_info > 0); 4486 4487 /* 4488 * If an error occured, propagate it to the master buffer. 4489 * 4490 * Several biodone()s may wind up running concurrently so 4491 * use an atomic op to adjust b_flags. 4492 */ 4493 if (error) { 4494 mbp->b_error = error; 4495 atomic_set_int(&mbp->b_flags, B_ERROR); 4496 } 4497 4498 /* 4499 * Decrement the operations in progress counter and terminate the 4500 * I/O if this was the last bit. 4501 */ 4502 if (atomic_fetchadd_int((int *)&mbio->bio_driver_info, -1) == 1) { 4503 mbp->b_resid = 0; 4504 if (stats) 4505 devstat_end_transaction_buf(stats, mbp); 4506 biodone(mbio); 4507 } 4508 } 4509 4510 /* 4511 * Initialize a nestiobuf for use. Set an initial count of 1 to prevent 4512 * the mbio from being biodone()'d while we are still adding sub-bios to 4513 * it. 4514 */ 4515 void 4516 nestiobuf_init(struct bio *bio) 4517 { 4518 bio->bio_driver_info = (void *)1; 4519 } 4520 4521 /* 4522 * The BIOs added to the nestedio have already been started, remove the 4523 * count that placeheld our mbio and biodone() it if the count would 4524 * transition to 0. 4525 */ 4526 void 4527 nestiobuf_start(struct bio *mbio) 4528 { 4529 struct buf *mbp = mbio->bio_buf; 4530 4531 /* 4532 * Decrement the operations in progress counter and terminate the 4533 * I/O if this was the last bit. 4534 */ 4535 if (atomic_fetchadd_int((int *)&mbio->bio_driver_info, -1) == 1) { 4536 if (mbp->b_flags & B_ERROR) 4537 mbp->b_resid = mbp->b_bcount; 4538 else 4539 mbp->b_resid = 0; 4540 biodone(mbio); 4541 } 4542 } 4543 4544 /* 4545 * Set an intermediate error prior to calling nestiobuf_start() 4546 */ 4547 void 4548 nestiobuf_error(struct bio *mbio, int error) 4549 { 4550 struct buf *mbp = mbio->bio_buf; 4551 4552 if (error) { 4553 mbp->b_error = error; 4554 atomic_set_int(&mbp->b_flags, B_ERROR); 4555 } 4556 } 4557 4558 /* 4559 * nestiobuf_add: setup a "nested" buffer. 4560 * 4561 * => 'mbp' is a "master" buffer which is being divided into sub pieces. 4562 * => 'bp' should be a buffer allocated by getiobuf. 4563 * => 'offset' is a byte offset in the master buffer. 4564 * => 'size' is a size in bytes of this nested buffer. 4565 */ 4566 void 4567 nestiobuf_add(struct bio *mbio, struct buf *bp, int offset, size_t size, struct devstat *stats) 4568 { 4569 struct buf *mbp = mbio->bio_buf; 4570 struct vnode *vp = mbp->b_vp; 4571 4572 KKASSERT(mbp->b_bcount >= offset + size); 4573 4574 atomic_add_int((int *)&mbio->bio_driver_info, 1); 4575 4576 /* kernel needs to own the lock for it to be released in biodone */ 4577 BUF_KERNPROC(bp); 4578 bp->b_vp = vp; 4579 bp->b_cmd = mbp->b_cmd; 4580 bp->b_bio1.bio_done = nestiobuf_iodone; 4581 bp->b_data = (char *)mbp->b_data + offset; 4582 bp->b_resid = bp->b_bcount = size; 4583 bp->b_bufsize = bp->b_bcount; 4584 4585 bp->b_bio1.bio_track = NULL; 4586 bp->b_bio1.bio_caller_info1.ptr = mbio; 4587 bp->b_bio1.bio_caller_info2.ptr = stats; 4588 } 4589 4590 #ifdef DDB 4591 4592 DB_SHOW_COMMAND(buffer, db_show_buffer) 4593 { 4594 /* get args */ 4595 struct buf *bp = (struct buf *)addr; 4596 4597 if (!have_addr) { 4598 db_printf("usage: show buffer <addr>\n"); 4599 return; 4600 } 4601 4602 db_printf("b_flags = 0x%pb%i\n", PRINT_BUF_FLAGS, bp->b_flags); 4603 db_printf("b_cmd = %d\n", bp->b_cmd); 4604 db_printf("b_error = %d, b_bufsize = %d, b_bcount = %d, " 4605 "b_resid = %d\n, b_data = %p, " 4606 "bio_offset(disk) = %lld, bio_offset(phys) = %lld\n", 4607 bp->b_error, bp->b_bufsize, bp->b_bcount, bp->b_resid, 4608 bp->b_data, 4609 (long long)bp->b_bio2.bio_offset, 4610 (long long)(bp->b_bio2.bio_next ? 4611 bp->b_bio2.bio_next->bio_offset : (off_t)-1)); 4612 if (bp->b_xio.xio_npages) { 4613 int i; 4614 db_printf("b_xio.xio_npages = %d, pages(OBJ, IDX, PA): ", 4615 bp->b_xio.xio_npages); 4616 for (i = 0; i < bp->b_xio.xio_npages; i++) { 4617 vm_page_t m; 4618 m = bp->b_xio.xio_pages[i]; 4619 db_printf("(%p, 0x%lx, 0x%lx)", (void *)m->object, 4620 (u_long)m->pindex, (u_long)VM_PAGE_TO_PHYS(m)); 4621 if ((i + 1) < bp->b_xio.xio_npages) 4622 db_printf(","); 4623 } 4624 db_printf("\n"); 4625 } 4626 } 4627 #endif /* DDB */ 4628