vm_page.c revision 209713
1/*- 2 * Copyright (c) 1991 Regents of the University of California. 3 * All rights reserved. 4 * Copyright (c) 1998 Matthew Dillon. All Rights Reserved. 5 * 6 * This code is derived from software contributed to Berkeley by 7 * The Mach Operating System project at Carnegie-Mellon University. 8 * 9 * Redistribution and use in source and binary forms, with or without 10 * modification, are permitted provided that the following conditions 11 * are met: 12 * 1. Redistributions of source code must retain the above copyright 13 * notice, this list of conditions and the following disclaimer. 14 * 2. Redistributions in binary form must reproduce the above copyright 15 * notice, this list of conditions and the following disclaimer in the 16 * documentation and/or other materials provided with the distribution. 17 * 4. Neither the name of the University nor the names of its contributors 18 * may be used to endorse or promote products derived from this software 19 * without specific prior written permission. 20 * 21 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 22 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 23 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 24 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 25 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 26 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 27 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 28 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 29 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 30 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 31 * SUCH DAMAGE. 32 * 33 * from: @(#)vm_page.c 7.4 (Berkeley) 5/7/91 34 */ 35 36/*- 37 * Copyright (c) 1987, 1990 Carnegie-Mellon University. 38 * All rights reserved. 39 * 40 * Authors: Avadis Tevanian, Jr., Michael Wayne Young 41 * 42 * Permission to use, copy, modify and distribute this software and 43 * its documentation is hereby granted, provided that both the copyright 44 * notice and this permission notice appear in all copies of the 45 * software, derivative works or modified versions, and any portions 46 * thereof, and that both notices appear in supporting documentation. 47 * 48 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" 49 * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND 50 * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. 51 * 52 * Carnegie Mellon requests users of this software to return to 53 * 54 * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU 55 * School of Computer Science 56 * Carnegie Mellon University 57 * Pittsburgh PA 15213-3890 58 * 59 * any improvements or extensions that they make and grant Carnegie the 60 * rights to redistribute these changes. 61 */ 62 63/* 64 * GENERAL RULES ON VM_PAGE MANIPULATION 65 * 66 * - a pageq mutex is required when adding or removing a page from a 67 * page queue (vm_page_queue[]), regardless of other mutexes or the 68 * busy state of a page. 69 * 70 * - a hash chain mutex is required when associating or disassociating 71 * a page from the VM PAGE CACHE hash table (vm_page_buckets), 72 * regardless of other mutexes or the busy state of a page. 73 * 74 * - either a hash chain mutex OR a busied page is required in order 75 * to modify the page flags. A hash chain mutex must be obtained in 76 * order to busy a page. A page's flags cannot be modified by a 77 * hash chain mutex if the page is marked busy. 78 * 79 * - The object memq mutex is held when inserting or removing 80 * pages from an object (vm_page_insert() or vm_page_remove()). This 81 * is different from the object's main mutex. 82 * 83 * Generally speaking, you have to be aware of side effects when running 84 * vm_page ops. A vm_page_lookup() will return with the hash chain 85 * locked, whether it was able to lookup the page or not. vm_page_free(), 86 * vm_page_cache(), vm_page_activate(), and a number of other routines 87 * will release the hash chain mutex for you. Intermediate manipulation 88 * routines such as vm_page_flag_set() expect the hash chain to be held 89 * on entry and the hash chain will remain held on return. 90 * 91 * pageq scanning can only occur with the pageq in question locked. 92 * We have a known bottleneck with the active queue, but the cache 93 * and free queues are actually arrays already. 94 */ 95 96/* 97 * Resident memory management module. 98 */ 99 100#include <sys/cdefs.h> 101__FBSDID("$FreeBSD: head/sys/vm/vm_page.c 209713 2010-07-05 21:13:32Z kib $"); 102 103#include "opt_vm.h" 104 105#include <sys/param.h> 106#include <sys/systm.h> 107#include <sys/lock.h> 108#include <sys/kernel.h> 109#include <sys/limits.h> 110#include <sys/malloc.h> 111#include <sys/msgbuf.h> 112#include <sys/mutex.h> 113#include <sys/proc.h> 114#include <sys/sysctl.h> 115#include <sys/vmmeter.h> 116#include <sys/vnode.h> 117 118#include <vm/vm.h> 119#include <vm/pmap.h> 120#include <vm/vm_param.h> 121#include <vm/vm_kern.h> 122#include <vm/vm_object.h> 123#include <vm/vm_page.h> 124#include <vm/vm_pageout.h> 125#include <vm/vm_pager.h> 126#include <vm/vm_phys.h> 127#include <vm/vm_reserv.h> 128#include <vm/vm_extern.h> 129#include <vm/uma.h> 130#include <vm/uma_int.h> 131 132#include <machine/md_var.h> 133 134#if defined(__amd64__) || defined (__i386__) 135extern struct sysctl_oid_list sysctl__vm_pmap_children; 136#else 137SYSCTL_NODE(_vm, OID_AUTO, pmap, CTLFLAG_RD, 0, "VM/pmap parameters"); 138#endif 139 140static uint64_t pmap_tryrelock_calls; 141SYSCTL_QUAD(_vm_pmap, OID_AUTO, tryrelock_calls, CTLFLAG_RD, 142 &pmap_tryrelock_calls, 0, "Number of tryrelock calls"); 143 144static int pmap_tryrelock_restart; 145SYSCTL_INT(_vm_pmap, OID_AUTO, tryrelock_restart, CTLFLAG_RD, 146 &pmap_tryrelock_restart, 0, "Number of tryrelock restarts"); 147 148static int pmap_tryrelock_race; 149SYSCTL_INT(_vm_pmap, OID_AUTO, tryrelock_race, CTLFLAG_RD, 150 &pmap_tryrelock_race, 0, "Number of tryrelock pmap race cases"); 151 152/* 153 * Associated with page of user-allocatable memory is a 154 * page structure. 155 */ 156 157struct vpgqueues vm_page_queues[PQ_COUNT]; 158struct vpglocks vm_page_queue_lock; 159struct vpglocks vm_page_queue_free_lock; 160 161struct vpglocks pa_lock[PA_LOCK_COUNT] __aligned(CACHE_LINE_SIZE); 162 163vm_page_t vm_page_array = 0; 164int vm_page_array_size = 0; 165long first_page = 0; 166int vm_page_zero_count = 0; 167 168static int boot_pages = UMA_BOOT_PAGES; 169TUNABLE_INT("vm.boot_pages", &boot_pages); 170SYSCTL_INT(_vm, OID_AUTO, boot_pages, CTLFLAG_RD, &boot_pages, 0, 171 "number of pages allocated for bootstrapping the VM system"); 172 173static void vm_page_clear_dirty_mask(vm_page_t m, int pagebits); 174static void vm_page_queue_remove(int queue, vm_page_t m); 175static void vm_page_enqueue(int queue, vm_page_t m); 176 177/* Make sure that u_long is at least 64 bits when PAGE_SIZE is 32K. */ 178#if PAGE_SIZE == 32768 179#ifdef CTASSERT 180CTASSERT(sizeof(u_long) >= 8); 181#endif 182#endif 183 184/* 185 * Try to acquire a physical address lock while a pmap is locked. If we 186 * fail to trylock we unlock and lock the pmap directly and cache the 187 * locked pa in *locked. The caller should then restart their loop in case 188 * the virtual to physical mapping has changed. 189 */ 190int 191vm_page_pa_tryrelock(pmap_t pmap, vm_paddr_t pa, vm_paddr_t *locked) 192{ 193 vm_paddr_t lockpa; 194 uint32_t gen_count; 195 196 gen_count = pmap->pm_gen_count; 197 atomic_add_long((volatile long *)&pmap_tryrelock_calls, 1); 198 lockpa = *locked; 199 *locked = pa; 200 if (lockpa) { 201 PA_LOCK_ASSERT(lockpa, MA_OWNED); 202 if (PA_LOCKPTR(pa) == PA_LOCKPTR(lockpa)) 203 return (0); 204 PA_UNLOCK(lockpa); 205 } 206 if (PA_TRYLOCK(pa)) 207 return (0); 208 PMAP_UNLOCK(pmap); 209 atomic_add_int((volatile int *)&pmap_tryrelock_restart, 1); 210 PA_LOCK(pa); 211 PMAP_LOCK(pmap); 212 213 if (pmap->pm_gen_count != gen_count + 1) { 214 pmap->pm_retries++; 215 atomic_add_int((volatile int *)&pmap_tryrelock_race, 1); 216 return (EAGAIN); 217 } 218 return (0); 219} 220 221/* 222 * vm_set_page_size: 223 * 224 * Sets the page size, perhaps based upon the memory 225 * size. Must be called before any use of page-size 226 * dependent functions. 227 */ 228void 229vm_set_page_size(void) 230{ 231 if (cnt.v_page_size == 0) 232 cnt.v_page_size = PAGE_SIZE; 233 if (((cnt.v_page_size - 1) & cnt.v_page_size) != 0) 234 panic("vm_set_page_size: page size not a power of two"); 235} 236 237/* 238 * vm_page_blacklist_lookup: 239 * 240 * See if a physical address in this page has been listed 241 * in the blacklist tunable. Entries in the tunable are 242 * separated by spaces or commas. If an invalid integer is 243 * encountered then the rest of the string is skipped. 244 */ 245static int 246vm_page_blacklist_lookup(char *list, vm_paddr_t pa) 247{ 248 vm_paddr_t bad; 249 char *cp, *pos; 250 251 for (pos = list; *pos != '\0'; pos = cp) { 252 bad = strtoq(pos, &cp, 0); 253 if (*cp != '\0') { 254 if (*cp == ' ' || *cp == ',') { 255 cp++; 256 if (cp == pos) 257 continue; 258 } else 259 break; 260 } 261 if (pa == trunc_page(bad)) 262 return (1); 263 } 264 return (0); 265} 266 267/* 268 * vm_page_startup: 269 * 270 * Initializes the resident memory module. 271 * 272 * Allocates memory for the page cells, and 273 * for the object/offset-to-page hash table headers. 274 * Each page cell is initialized and placed on the free list. 275 */ 276vm_offset_t 277vm_page_startup(vm_offset_t vaddr) 278{ 279 vm_offset_t mapped; 280 vm_paddr_t page_range; 281 vm_paddr_t new_end; 282 int i; 283 vm_paddr_t pa; 284 int nblocks; 285 vm_paddr_t last_pa; 286 char *list; 287 288 /* the biggest memory array is the second group of pages */ 289 vm_paddr_t end; 290 vm_paddr_t biggestsize; 291 vm_paddr_t low_water, high_water; 292 int biggestone; 293 294 biggestsize = 0; 295 biggestone = 0; 296 nblocks = 0; 297 vaddr = round_page(vaddr); 298 299 for (i = 0; phys_avail[i + 1]; i += 2) { 300 phys_avail[i] = round_page(phys_avail[i]); 301 phys_avail[i + 1] = trunc_page(phys_avail[i + 1]); 302 } 303 304 low_water = phys_avail[0]; 305 high_water = phys_avail[1]; 306 307 for (i = 0; phys_avail[i + 1]; i += 2) { 308 vm_paddr_t size = phys_avail[i + 1] - phys_avail[i]; 309 310 if (size > biggestsize) { 311 biggestone = i; 312 biggestsize = size; 313 } 314 if (phys_avail[i] < low_water) 315 low_water = phys_avail[i]; 316 if (phys_avail[i + 1] > high_water) 317 high_water = phys_avail[i + 1]; 318 ++nblocks; 319 } 320 321#ifdef XEN 322 low_water = 0; 323#endif 324 325 end = phys_avail[biggestone+1]; 326 327 /* 328 * Initialize the locks. 329 */ 330 mtx_init(&vm_page_queue_mtx, "vm page queue mutex", NULL, MTX_DEF | 331 MTX_RECURSE); 332 mtx_init(&vm_page_queue_free_mtx, "vm page queue free mutex", NULL, 333 MTX_DEF); 334 335 /* Setup page locks. */ 336 for (i = 0; i < PA_LOCK_COUNT; i++) 337 mtx_init(&pa_lock[i].data, "page lock", NULL, 338 MTX_DEF | MTX_RECURSE | MTX_DUPOK); 339 340 /* 341 * Initialize the queue headers for the hold queue, the active queue, 342 * and the inactive queue. 343 */ 344 for (i = 0; i < PQ_COUNT; i++) 345 TAILQ_INIT(&vm_page_queues[i].pl); 346 vm_page_queues[PQ_INACTIVE].cnt = &cnt.v_inactive_count; 347 vm_page_queues[PQ_ACTIVE].cnt = &cnt.v_active_count; 348 vm_page_queues[PQ_HOLD].cnt = &cnt.v_active_count; 349 350 /* 351 * Allocate memory for use when boot strapping the kernel memory 352 * allocator. 353 */ 354 new_end = end - (boot_pages * UMA_SLAB_SIZE); 355 new_end = trunc_page(new_end); 356 mapped = pmap_map(&vaddr, new_end, end, 357 VM_PROT_READ | VM_PROT_WRITE); 358 bzero((void *)mapped, end - new_end); 359 uma_startup((void *)mapped, boot_pages); 360 361#if defined(__amd64__) || defined(__i386__) || defined(__arm__) 362 /* 363 * Allocate a bitmap to indicate that a random physical page 364 * needs to be included in a minidump. 365 * 366 * The amd64 port needs this to indicate which direct map pages 367 * need to be dumped, via calls to dump_add_page()/dump_drop_page(). 368 * 369 * However, i386 still needs this workspace internally within the 370 * minidump code. In theory, they are not needed on i386, but are 371 * included should the sf_buf code decide to use them. 372 */ 373 page_range = phys_avail[(nblocks - 1) * 2 + 1] / PAGE_SIZE; 374 vm_page_dump_size = round_page(roundup2(page_range, NBBY) / NBBY); 375 new_end -= vm_page_dump_size; 376 vm_page_dump = (void *)(uintptr_t)pmap_map(&vaddr, new_end, 377 new_end + vm_page_dump_size, VM_PROT_READ | VM_PROT_WRITE); 378 bzero((void *)vm_page_dump, vm_page_dump_size); 379#endif 380#ifdef __amd64__ 381 /* 382 * Request that the physical pages underlying the message buffer be 383 * included in a crash dump. Since the message buffer is accessed 384 * through the direct map, they are not automatically included. 385 */ 386 pa = DMAP_TO_PHYS((vm_offset_t)msgbufp->msg_ptr); 387 last_pa = pa + round_page(MSGBUF_SIZE); 388 while (pa < last_pa) { 389 dump_add_page(pa); 390 pa += PAGE_SIZE; 391 } 392#endif 393 /* 394 * Compute the number of pages of memory that will be available for 395 * use (taking into account the overhead of a page structure per 396 * page). 397 */ 398 first_page = low_water / PAGE_SIZE; 399#ifdef VM_PHYSSEG_SPARSE 400 page_range = 0; 401 for (i = 0; phys_avail[i + 1] != 0; i += 2) 402 page_range += atop(phys_avail[i + 1] - phys_avail[i]); 403#elif defined(VM_PHYSSEG_DENSE) 404 page_range = high_water / PAGE_SIZE - first_page; 405#else 406#error "Either VM_PHYSSEG_DENSE or VM_PHYSSEG_SPARSE must be defined." 407#endif 408 end = new_end; 409 410 /* 411 * Reserve an unmapped guard page to trap access to vm_page_array[-1]. 412 */ 413 vaddr += PAGE_SIZE; 414 415 /* 416 * Initialize the mem entry structures now, and put them in the free 417 * queue. 418 */ 419 new_end = trunc_page(end - page_range * sizeof(struct vm_page)); 420 mapped = pmap_map(&vaddr, new_end, end, 421 VM_PROT_READ | VM_PROT_WRITE); 422 vm_page_array = (vm_page_t) mapped; 423#if VM_NRESERVLEVEL > 0 424 /* 425 * Allocate memory for the reservation management system's data 426 * structures. 427 */ 428 new_end = vm_reserv_startup(&vaddr, new_end, high_water); 429#endif 430#ifdef __amd64__ 431 /* 432 * pmap_map on amd64 comes out of the direct-map, not kvm like i386, 433 * so the pages must be tracked for a crashdump to include this data. 434 * This includes the vm_page_array and the early UMA bootstrap pages. 435 */ 436 for (pa = new_end; pa < phys_avail[biggestone + 1]; pa += PAGE_SIZE) 437 dump_add_page(pa); 438#endif 439 phys_avail[biggestone + 1] = new_end; 440 441 /* 442 * Clear all of the page structures 443 */ 444 bzero((caddr_t) vm_page_array, page_range * sizeof(struct vm_page)); 445 for (i = 0; i < page_range; i++) 446 vm_page_array[i].order = VM_NFREEORDER; 447 vm_page_array_size = page_range; 448 449 /* 450 * Initialize the physical memory allocator. 451 */ 452 vm_phys_init(); 453 454 /* 455 * Add every available physical page that is not blacklisted to 456 * the free lists. 457 */ 458 cnt.v_page_count = 0; 459 cnt.v_free_count = 0; 460 list = getenv("vm.blacklist"); 461 for (i = 0; phys_avail[i + 1] != 0; i += 2) { 462 pa = phys_avail[i]; 463 last_pa = phys_avail[i + 1]; 464 while (pa < last_pa) { 465 if (list != NULL && 466 vm_page_blacklist_lookup(list, pa)) 467 printf("Skipping page with pa 0x%jx\n", 468 (uintmax_t)pa); 469 else 470 vm_phys_add_page(pa); 471 pa += PAGE_SIZE; 472 } 473 } 474 freeenv(list); 475#if VM_NRESERVLEVEL > 0 476 /* 477 * Initialize the reservation management system. 478 */ 479 vm_reserv_init(); 480#endif 481 return (vaddr); 482} 483 484void 485vm_page_flag_set(vm_page_t m, unsigned short bits) 486{ 487 488 mtx_assert(&vm_page_queue_mtx, MA_OWNED); 489 /* 490 * The PG_WRITEABLE flag can only be set if the page is managed and 491 * VPO_BUSY. Currently, this flag is only set by pmap_enter(). 492 */ 493 KASSERT((bits & PG_WRITEABLE) == 0 || 494 ((m->flags & (PG_UNMANAGED | PG_FICTITIOUS)) == 0 && 495 (m->oflags & VPO_BUSY) != 0), ("PG_WRITEABLE and !VPO_BUSY")); 496 m->flags |= bits; 497} 498 499void 500vm_page_flag_clear(vm_page_t m, unsigned short bits) 501{ 502 503 mtx_assert(&vm_page_queue_mtx, MA_OWNED); 504 /* 505 * The PG_REFERENCED flag can only be cleared if the object 506 * containing the page is locked. 507 */ 508 KASSERT((bits & PG_REFERENCED) == 0 || VM_OBJECT_LOCKED(m->object), 509 ("PG_REFERENCED and !VM_OBJECT_LOCKED")); 510 m->flags &= ~bits; 511} 512 513void 514vm_page_busy(vm_page_t m) 515{ 516 517 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 518 KASSERT((m->oflags & VPO_BUSY) == 0, 519 ("vm_page_busy: page already busy!!!")); 520 m->oflags |= VPO_BUSY; 521} 522 523/* 524 * vm_page_flash: 525 * 526 * wakeup anyone waiting for the page. 527 */ 528void 529vm_page_flash(vm_page_t m) 530{ 531 532 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 533 if (m->oflags & VPO_WANTED) { 534 m->oflags &= ~VPO_WANTED; 535 wakeup(m); 536 } 537} 538 539/* 540 * vm_page_wakeup: 541 * 542 * clear the VPO_BUSY flag and wakeup anyone waiting for the 543 * page. 544 * 545 */ 546void 547vm_page_wakeup(vm_page_t m) 548{ 549 550 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 551 KASSERT(m->oflags & VPO_BUSY, ("vm_page_wakeup: page not busy!!!")); 552 m->oflags &= ~VPO_BUSY; 553 vm_page_flash(m); 554} 555 556void 557vm_page_io_start(vm_page_t m) 558{ 559 560 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 561 m->busy++; 562} 563 564void 565vm_page_io_finish(vm_page_t m) 566{ 567 568 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 569 m->busy--; 570 if (m->busy == 0) 571 vm_page_flash(m); 572} 573 574/* 575 * Keep page from being freed by the page daemon 576 * much of the same effect as wiring, except much lower 577 * overhead and should be used only for *very* temporary 578 * holding ("wiring"). 579 */ 580void 581vm_page_hold(vm_page_t mem) 582{ 583 584 vm_page_lock_assert(mem, MA_OWNED); 585 mem->hold_count++; 586} 587 588void 589vm_page_unhold(vm_page_t mem) 590{ 591 592 vm_page_lock_assert(mem, MA_OWNED); 593 --mem->hold_count; 594 KASSERT(mem->hold_count >= 0, ("vm_page_unhold: hold count < 0!!!")); 595 if (mem->hold_count == 0 && mem->queue == PQ_HOLD) 596 vm_page_free_toq(mem); 597} 598 599/* 600 * vm_page_free: 601 * 602 * Free a page. 603 */ 604void 605vm_page_free(vm_page_t m) 606{ 607 608 m->flags &= ~PG_ZERO; 609 vm_page_free_toq(m); 610} 611 612/* 613 * vm_page_free_zero: 614 * 615 * Free a page to the zerod-pages queue 616 */ 617void 618vm_page_free_zero(vm_page_t m) 619{ 620 621 m->flags |= PG_ZERO; 622 vm_page_free_toq(m); 623} 624 625/* 626 * vm_page_sleep: 627 * 628 * Sleep and release the page and page queues locks. 629 * 630 * The object containing the given page must be locked. 631 */ 632void 633vm_page_sleep(vm_page_t m, const char *msg) 634{ 635 636 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 637 if (mtx_owned(&vm_page_queue_mtx)) 638 vm_page_unlock_queues(); 639 if (mtx_owned(vm_page_lockptr(m))) 640 vm_page_unlock(m); 641 642 /* 643 * It's possible that while we sleep, the page will get 644 * unbusied and freed. If we are holding the object 645 * lock, we will assume we hold a reference to the object 646 * such that even if m->object changes, we can re-lock 647 * it. 648 */ 649 m->oflags |= VPO_WANTED; 650 msleep(m, VM_OBJECT_MTX(m->object), PVM, msg, 0); 651} 652 653/* 654 * vm_page_dirty: 655 * 656 * make page all dirty 657 */ 658void 659vm_page_dirty(vm_page_t m) 660{ 661 662 KASSERT((m->flags & PG_CACHED) == 0, 663 ("vm_page_dirty: page in cache!")); 664 KASSERT(!VM_PAGE_IS_FREE(m), 665 ("vm_page_dirty: page is free!")); 666 KASSERT(m->valid == VM_PAGE_BITS_ALL, 667 ("vm_page_dirty: page is invalid!")); 668 m->dirty = VM_PAGE_BITS_ALL; 669} 670 671/* 672 * vm_page_splay: 673 * 674 * Implements Sleator and Tarjan's top-down splay algorithm. Returns 675 * the vm_page containing the given pindex. If, however, that 676 * pindex is not found in the vm_object, returns a vm_page that is 677 * adjacent to the pindex, coming before or after it. 678 */ 679vm_page_t 680vm_page_splay(vm_pindex_t pindex, vm_page_t root) 681{ 682 struct vm_page dummy; 683 vm_page_t lefttreemax, righttreemin, y; 684 685 if (root == NULL) 686 return (root); 687 lefttreemax = righttreemin = &dummy; 688 for (;; root = y) { 689 if (pindex < root->pindex) { 690 if ((y = root->left) == NULL) 691 break; 692 if (pindex < y->pindex) { 693 /* Rotate right. */ 694 root->left = y->right; 695 y->right = root; 696 root = y; 697 if ((y = root->left) == NULL) 698 break; 699 } 700 /* Link into the new root's right tree. */ 701 righttreemin->left = root; 702 righttreemin = root; 703 } else if (pindex > root->pindex) { 704 if ((y = root->right) == NULL) 705 break; 706 if (pindex > y->pindex) { 707 /* Rotate left. */ 708 root->right = y->left; 709 y->left = root; 710 root = y; 711 if ((y = root->right) == NULL) 712 break; 713 } 714 /* Link into the new root's left tree. */ 715 lefttreemax->right = root; 716 lefttreemax = root; 717 } else 718 break; 719 } 720 /* Assemble the new root. */ 721 lefttreemax->right = root->left; 722 righttreemin->left = root->right; 723 root->left = dummy.right; 724 root->right = dummy.left; 725 return (root); 726} 727 728/* 729 * vm_page_insert: [ internal use only ] 730 * 731 * Inserts the given mem entry into the object and object list. 732 * 733 * The pagetables are not updated but will presumably fault the page 734 * in if necessary, or if a kernel page the caller will at some point 735 * enter the page into the kernel's pmap. We are not allowed to block 736 * here so we *can't* do this anyway. 737 * 738 * The object and page must be locked. 739 * This routine may not block. 740 */ 741void 742vm_page_insert(vm_page_t m, vm_object_t object, vm_pindex_t pindex) 743{ 744 vm_page_t root; 745 746 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 747 if (m->object != NULL) 748 panic("vm_page_insert: page already inserted"); 749 750 /* 751 * Record the object/offset pair in this page 752 */ 753 m->object = object; 754 m->pindex = pindex; 755 756 /* 757 * Now link into the object's ordered list of backed pages. 758 */ 759 root = object->root; 760 if (root == NULL) { 761 m->left = NULL; 762 m->right = NULL; 763 TAILQ_INSERT_TAIL(&object->memq, m, listq); 764 } else { 765 root = vm_page_splay(pindex, root); 766 if (pindex < root->pindex) { 767 m->left = root->left; 768 m->right = root; 769 root->left = NULL; 770 TAILQ_INSERT_BEFORE(root, m, listq); 771 } else if (pindex == root->pindex) 772 panic("vm_page_insert: offset already allocated"); 773 else { 774 m->right = root->right; 775 m->left = root; 776 root->right = NULL; 777 TAILQ_INSERT_AFTER(&object->memq, root, m, listq); 778 } 779 } 780 object->root = m; 781 object->generation++; 782 783 /* 784 * show that the object has one more resident page. 785 */ 786 object->resident_page_count++; 787 /* 788 * Hold the vnode until the last page is released. 789 */ 790 if (object->resident_page_count == 1 && object->type == OBJT_VNODE) 791 vhold((struct vnode *)object->handle); 792 793 /* 794 * Since we are inserting a new and possibly dirty page, 795 * update the object's OBJ_MIGHTBEDIRTY flag. 796 */ 797 if (m->flags & PG_WRITEABLE) 798 vm_object_set_writeable_dirty(object); 799} 800 801/* 802 * vm_page_remove: 803 * NOTE: used by device pager as well -wfj 804 * 805 * Removes the given mem entry from the object/offset-page 806 * table and the object page list, but do not invalidate/terminate 807 * the backing store. 808 * 809 * The object and page must be locked. 810 * The underlying pmap entry (if any) is NOT removed here. 811 * This routine may not block. 812 */ 813void 814vm_page_remove(vm_page_t m) 815{ 816 vm_object_t object; 817 vm_page_t root; 818 819 if ((m->flags & PG_UNMANAGED) == 0) 820 vm_page_lock_assert(m, MA_OWNED); 821 if ((object = m->object) == NULL) 822 return; 823 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 824 if (m->oflags & VPO_BUSY) { 825 m->oflags &= ~VPO_BUSY; 826 vm_page_flash(m); 827 } 828 829 /* 830 * Now remove from the object's list of backed pages. 831 */ 832 if (m != object->root) 833 vm_page_splay(m->pindex, object->root); 834 if (m->left == NULL) 835 root = m->right; 836 else { 837 root = vm_page_splay(m->pindex, m->left); 838 root->right = m->right; 839 } 840 object->root = root; 841 TAILQ_REMOVE(&object->memq, m, listq); 842 843 /* 844 * And show that the object has one fewer resident page. 845 */ 846 object->resident_page_count--; 847 object->generation++; 848 /* 849 * The vnode may now be recycled. 850 */ 851 if (object->resident_page_count == 0 && object->type == OBJT_VNODE) 852 vdrop((struct vnode *)object->handle); 853 854 m->object = NULL; 855} 856 857/* 858 * vm_page_lookup: 859 * 860 * Returns the page associated with the object/offset 861 * pair specified; if none is found, NULL is returned. 862 * 863 * The object must be locked. 864 * This routine may not block. 865 * This is a critical path routine 866 */ 867vm_page_t 868vm_page_lookup(vm_object_t object, vm_pindex_t pindex) 869{ 870 vm_page_t m; 871 872 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 873 if ((m = object->root) != NULL && m->pindex != pindex) { 874 m = vm_page_splay(pindex, m); 875 if ((object->root = m)->pindex != pindex) 876 m = NULL; 877 } 878 return (m); 879} 880 881/* 882 * vm_page_find_least: 883 * 884 * Returns the page associated with the object with least pindex 885 * greater than or equal to the parameter pindex, or NULL. 886 * 887 * The object must be locked. 888 * The routine may not block. 889 */ 890vm_page_t 891vm_page_find_least(vm_object_t object, vm_pindex_t pindex) 892{ 893 vm_page_t m; 894 895 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 896 if ((m = TAILQ_FIRST(&object->memq)) != NULL) { 897 if (m->pindex < pindex) { 898 m = vm_page_splay(pindex, object->root); 899 if ((object->root = m)->pindex < pindex) 900 m = TAILQ_NEXT(m, listq); 901 } 902 } 903 return (m); 904} 905 906/* 907 * Returns the given page's successor (by pindex) within the object if it is 908 * resident; if none is found, NULL is returned. 909 * 910 * The object must be locked. 911 */ 912vm_page_t 913vm_page_next(vm_page_t m) 914{ 915 vm_page_t next; 916 917 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 918 if ((next = TAILQ_NEXT(m, listq)) != NULL && 919 next->pindex != m->pindex + 1) 920 next = NULL; 921 return (next); 922} 923 924/* 925 * Returns the given page's predecessor (by pindex) within the object if it is 926 * resident; if none is found, NULL is returned. 927 * 928 * The object must be locked. 929 */ 930vm_page_t 931vm_page_prev(vm_page_t m) 932{ 933 vm_page_t prev; 934 935 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 936 if ((prev = TAILQ_PREV(m, pglist, listq)) != NULL && 937 prev->pindex != m->pindex - 1) 938 prev = NULL; 939 return (prev); 940} 941 942/* 943 * vm_page_rename: 944 * 945 * Move the given memory entry from its 946 * current object to the specified target object/offset. 947 * 948 * The object must be locked. 949 * This routine may not block. 950 * 951 * Note: swap associated with the page must be invalidated by the move. We 952 * have to do this for several reasons: (1) we aren't freeing the 953 * page, (2) we are dirtying the page, (3) the VM system is probably 954 * moving the page from object A to B, and will then later move 955 * the backing store from A to B and we can't have a conflict. 956 * 957 * Note: we *always* dirty the page. It is necessary both for the 958 * fact that we moved it, and because we may be invalidating 959 * swap. If the page is on the cache, we have to deactivate it 960 * or vm_page_dirty() will panic. Dirty pages are not allowed 961 * on the cache. 962 */ 963void 964vm_page_rename(vm_page_t m, vm_object_t new_object, vm_pindex_t new_pindex) 965{ 966 967 vm_page_remove(m); 968 vm_page_insert(m, new_object, new_pindex); 969 vm_page_dirty(m); 970} 971 972/* 973 * Convert all of the given object's cached pages that have a 974 * pindex within the given range into free pages. If the value 975 * zero is given for "end", then the range's upper bound is 976 * infinity. If the given object is backed by a vnode and it 977 * transitions from having one or more cached pages to none, the 978 * vnode's hold count is reduced. 979 */ 980void 981vm_page_cache_free(vm_object_t object, vm_pindex_t start, vm_pindex_t end) 982{ 983 vm_page_t m, m_next; 984 boolean_t empty; 985 986 mtx_lock(&vm_page_queue_free_mtx); 987 if (__predict_false(object->cache == NULL)) { 988 mtx_unlock(&vm_page_queue_free_mtx); 989 return; 990 } 991 m = object->cache = vm_page_splay(start, object->cache); 992 if (m->pindex < start) { 993 if (m->right == NULL) 994 m = NULL; 995 else { 996 m_next = vm_page_splay(start, m->right); 997 m_next->left = m; 998 m->right = NULL; 999 m = object->cache = m_next; 1000 } 1001 } 1002 1003 /* 1004 * At this point, "m" is either (1) a reference to the page 1005 * with the least pindex that is greater than or equal to 1006 * "start" or (2) NULL. 1007 */ 1008 for (; m != NULL && (m->pindex < end || end == 0); m = m_next) { 1009 /* 1010 * Find "m"'s successor and remove "m" from the 1011 * object's cache. 1012 */ 1013 if (m->right == NULL) { 1014 object->cache = m->left; 1015 m_next = NULL; 1016 } else { 1017 m_next = vm_page_splay(start, m->right); 1018 m_next->left = m->left; 1019 object->cache = m_next; 1020 } 1021 /* Convert "m" to a free page. */ 1022 m->object = NULL; 1023 m->valid = 0; 1024 /* Clear PG_CACHED and set PG_FREE. */ 1025 m->flags ^= PG_CACHED | PG_FREE; 1026 KASSERT((m->flags & (PG_CACHED | PG_FREE)) == PG_FREE, 1027 ("vm_page_cache_free: page %p has inconsistent flags", m)); 1028 cnt.v_cache_count--; 1029 cnt.v_free_count++; 1030 } 1031 empty = object->cache == NULL; 1032 mtx_unlock(&vm_page_queue_free_mtx); 1033 if (object->type == OBJT_VNODE && empty) 1034 vdrop(object->handle); 1035} 1036 1037/* 1038 * Returns the cached page that is associated with the given 1039 * object and offset. If, however, none exists, returns NULL. 1040 * 1041 * The free page queue must be locked. 1042 */ 1043static inline vm_page_t 1044vm_page_cache_lookup(vm_object_t object, vm_pindex_t pindex) 1045{ 1046 vm_page_t m; 1047 1048 mtx_assert(&vm_page_queue_free_mtx, MA_OWNED); 1049 if ((m = object->cache) != NULL && m->pindex != pindex) { 1050 m = vm_page_splay(pindex, m); 1051 if ((object->cache = m)->pindex != pindex) 1052 m = NULL; 1053 } 1054 return (m); 1055} 1056 1057/* 1058 * Remove the given cached page from its containing object's 1059 * collection of cached pages. 1060 * 1061 * The free page queue must be locked. 1062 */ 1063void 1064vm_page_cache_remove(vm_page_t m) 1065{ 1066 vm_object_t object; 1067 vm_page_t root; 1068 1069 mtx_assert(&vm_page_queue_free_mtx, MA_OWNED); 1070 KASSERT((m->flags & PG_CACHED) != 0, 1071 ("vm_page_cache_remove: page %p is not cached", m)); 1072 object = m->object; 1073 if (m != object->cache) { 1074 root = vm_page_splay(m->pindex, object->cache); 1075 KASSERT(root == m, 1076 ("vm_page_cache_remove: page %p is not cached in object %p", 1077 m, object)); 1078 } 1079 if (m->left == NULL) 1080 root = m->right; 1081 else if (m->right == NULL) 1082 root = m->left; 1083 else { 1084 root = vm_page_splay(m->pindex, m->left); 1085 root->right = m->right; 1086 } 1087 object->cache = root; 1088 m->object = NULL; 1089 cnt.v_cache_count--; 1090} 1091 1092/* 1093 * Transfer all of the cached pages with offset greater than or 1094 * equal to 'offidxstart' from the original object's cache to the 1095 * new object's cache. However, any cached pages with offset 1096 * greater than or equal to the new object's size are kept in the 1097 * original object. Initially, the new object's cache must be 1098 * empty. Offset 'offidxstart' in the original object must 1099 * correspond to offset zero in the new object. 1100 * 1101 * The new object must be locked. 1102 */ 1103void 1104vm_page_cache_transfer(vm_object_t orig_object, vm_pindex_t offidxstart, 1105 vm_object_t new_object) 1106{ 1107 vm_page_t m, m_next; 1108 1109 /* 1110 * Insertion into an object's collection of cached pages 1111 * requires the object to be locked. In contrast, removal does 1112 * not. 1113 */ 1114 VM_OBJECT_LOCK_ASSERT(new_object, MA_OWNED); 1115 KASSERT(new_object->cache == NULL, 1116 ("vm_page_cache_transfer: object %p has cached pages", 1117 new_object)); 1118 mtx_lock(&vm_page_queue_free_mtx); 1119 if ((m = orig_object->cache) != NULL) { 1120 /* 1121 * Transfer all of the pages with offset greater than or 1122 * equal to 'offidxstart' from the original object's 1123 * cache to the new object's cache. 1124 */ 1125 m = vm_page_splay(offidxstart, m); 1126 if (m->pindex < offidxstart) { 1127 orig_object->cache = m; 1128 new_object->cache = m->right; 1129 m->right = NULL; 1130 } else { 1131 orig_object->cache = m->left; 1132 new_object->cache = m; 1133 m->left = NULL; 1134 } 1135 while ((m = new_object->cache) != NULL) { 1136 if ((m->pindex - offidxstart) >= new_object->size) { 1137 /* 1138 * Return all of the cached pages with 1139 * offset greater than or equal to the 1140 * new object's size to the original 1141 * object's cache. 1142 */ 1143 new_object->cache = m->left; 1144 m->left = orig_object->cache; 1145 orig_object->cache = m; 1146 break; 1147 } 1148 m_next = vm_page_splay(m->pindex, m->right); 1149 /* Update the page's object and offset. */ 1150 m->object = new_object; 1151 m->pindex -= offidxstart; 1152 if (m_next == NULL) 1153 break; 1154 m->right = NULL; 1155 m_next->left = m; 1156 new_object->cache = m_next; 1157 } 1158 KASSERT(new_object->cache == NULL || 1159 new_object->type == OBJT_SWAP, 1160 ("vm_page_cache_transfer: object %p's type is incompatible" 1161 " with cached pages", new_object)); 1162 } 1163 mtx_unlock(&vm_page_queue_free_mtx); 1164} 1165 1166/* 1167 * vm_page_alloc: 1168 * 1169 * Allocate and return a memory cell associated 1170 * with this VM object/offset pair. 1171 * 1172 * The caller must always specify an allocation class. 1173 * 1174 * allocation classes: 1175 * VM_ALLOC_NORMAL normal process request 1176 * VM_ALLOC_SYSTEM system *really* needs a page 1177 * VM_ALLOC_INTERRUPT interrupt time request 1178 * 1179 * optional allocation flags: 1180 * VM_ALLOC_ZERO prefer a zeroed page 1181 * VM_ALLOC_WIRED wire the allocated page 1182 * VM_ALLOC_NOOBJ page is not associated with a vm object 1183 * VM_ALLOC_NOBUSY do not set the page busy 1184 * VM_ALLOC_IFCACHED return page only if it is cached 1185 * VM_ALLOC_IFNOTCACHED return NULL, do not reactivate if the page 1186 * is cached 1187 * 1188 * This routine may not sleep. 1189 */ 1190vm_page_t 1191vm_page_alloc(vm_object_t object, vm_pindex_t pindex, int req) 1192{ 1193 struct vnode *vp = NULL; 1194 vm_object_t m_object; 1195 vm_page_t m; 1196 int flags, page_req; 1197 1198 page_req = req & VM_ALLOC_CLASS_MASK; 1199 KASSERT(curthread->td_intr_nesting_level == 0 || 1200 page_req == VM_ALLOC_INTERRUPT, 1201 ("vm_page_alloc(NORMAL|SYSTEM) in interrupt context")); 1202 1203 if ((req & VM_ALLOC_NOOBJ) == 0) { 1204 KASSERT(object != NULL, 1205 ("vm_page_alloc: NULL object.")); 1206 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 1207 } 1208 1209 /* 1210 * The pager is allowed to eat deeper into the free page list. 1211 */ 1212 if ((curproc == pageproc) && (page_req != VM_ALLOC_INTERRUPT)) { 1213 page_req = VM_ALLOC_SYSTEM; 1214 }; 1215 1216 mtx_lock(&vm_page_queue_free_mtx); 1217 if (cnt.v_free_count + cnt.v_cache_count > cnt.v_free_reserved || 1218 (page_req == VM_ALLOC_SYSTEM && 1219 cnt.v_free_count + cnt.v_cache_count > cnt.v_interrupt_free_min) || 1220 (page_req == VM_ALLOC_INTERRUPT && 1221 cnt.v_free_count + cnt.v_cache_count > 0)) { 1222 /* 1223 * Allocate from the free queue if the number of free pages 1224 * exceeds the minimum for the request class. 1225 */ 1226 if (object != NULL && 1227 (m = vm_page_cache_lookup(object, pindex)) != NULL) { 1228 if ((req & VM_ALLOC_IFNOTCACHED) != 0) { 1229 mtx_unlock(&vm_page_queue_free_mtx); 1230 return (NULL); 1231 } 1232 if (vm_phys_unfree_page(m)) 1233 vm_phys_set_pool(VM_FREEPOOL_DEFAULT, m, 0); 1234#if VM_NRESERVLEVEL > 0 1235 else if (!vm_reserv_reactivate_page(m)) 1236#else 1237 else 1238#endif 1239 panic("vm_page_alloc: cache page %p is missing" 1240 " from the free queue", m); 1241 } else if ((req & VM_ALLOC_IFCACHED) != 0) { 1242 mtx_unlock(&vm_page_queue_free_mtx); 1243 return (NULL); 1244#if VM_NRESERVLEVEL > 0 1245 } else if (object == NULL || object->type == OBJT_DEVICE || 1246 object->type == OBJT_SG || 1247 (object->flags & OBJ_COLORED) == 0 || 1248 (m = vm_reserv_alloc_page(object, pindex)) == NULL) { 1249#else 1250 } else { 1251#endif 1252 m = vm_phys_alloc_pages(object != NULL ? 1253 VM_FREEPOOL_DEFAULT : VM_FREEPOOL_DIRECT, 0); 1254#if VM_NRESERVLEVEL > 0 1255 if (m == NULL && vm_reserv_reclaim_inactive()) { 1256 m = vm_phys_alloc_pages(object != NULL ? 1257 VM_FREEPOOL_DEFAULT : VM_FREEPOOL_DIRECT, 1258 0); 1259 } 1260#endif 1261 } 1262 } else { 1263 /* 1264 * Not allocatable, give up. 1265 */ 1266 mtx_unlock(&vm_page_queue_free_mtx); 1267 atomic_add_int(&vm_pageout_deficit, 1); 1268 pagedaemon_wakeup(); 1269 return (NULL); 1270 } 1271 1272 /* 1273 * At this point we had better have found a good page. 1274 */ 1275 1276 KASSERT(m != NULL, ("vm_page_alloc: missing page")); 1277 KASSERT(m->queue == PQ_NONE, 1278 ("vm_page_alloc: page %p has unexpected queue %d", m, m->queue)); 1279 KASSERT(m->wire_count == 0, ("vm_page_alloc: page %p is wired", m)); 1280 KASSERT(m->hold_count == 0, ("vm_page_alloc: page %p is held", m)); 1281 KASSERT(m->busy == 0, ("vm_page_alloc: page %p is busy", m)); 1282 KASSERT(m->dirty == 0, ("vm_page_alloc: page %p is dirty", m)); 1283 KASSERT(pmap_page_get_memattr(m) == VM_MEMATTR_DEFAULT, 1284 ("vm_page_alloc: page %p has unexpected memattr %d", m, 1285 pmap_page_get_memattr(m))); 1286 if ((m->flags & PG_CACHED) != 0) { 1287 KASSERT(m->valid != 0, 1288 ("vm_page_alloc: cached page %p is invalid", m)); 1289 if (m->object == object && m->pindex == pindex) 1290 cnt.v_reactivated++; 1291 else 1292 m->valid = 0; 1293 m_object = m->object; 1294 vm_page_cache_remove(m); 1295 if (m_object->type == OBJT_VNODE && m_object->cache == NULL) 1296 vp = m_object->handle; 1297 } else { 1298 KASSERT(VM_PAGE_IS_FREE(m), 1299 ("vm_page_alloc: page %p is not free", m)); 1300 KASSERT(m->valid == 0, 1301 ("vm_page_alloc: free page %p is valid", m)); 1302 cnt.v_free_count--; 1303 } 1304 1305 /* 1306 * Initialize structure. Only the PG_ZERO flag is inherited. 1307 */ 1308 flags = 0; 1309 if (m->flags & PG_ZERO) { 1310 vm_page_zero_count--; 1311 if (req & VM_ALLOC_ZERO) 1312 flags = PG_ZERO; 1313 } 1314 if (object == NULL || object->type == OBJT_PHYS) 1315 flags |= PG_UNMANAGED; 1316 m->flags = flags; 1317 if (req & (VM_ALLOC_NOBUSY | VM_ALLOC_NOOBJ)) 1318 m->oflags = 0; 1319 else 1320 m->oflags = VPO_BUSY; 1321 if (req & VM_ALLOC_WIRED) { 1322 atomic_add_int(&cnt.v_wire_count, 1); 1323 m->wire_count = 1; 1324 } 1325 m->act_count = 0; 1326 mtx_unlock(&vm_page_queue_free_mtx); 1327 1328 if (object != NULL) { 1329 /* Ignore device objects; the pager sets "memattr" for them. */ 1330 if (object->memattr != VM_MEMATTR_DEFAULT && 1331 object->type != OBJT_DEVICE && object->type != OBJT_SG) 1332 pmap_page_set_memattr(m, object->memattr); 1333 vm_page_insert(m, object, pindex); 1334 } else 1335 m->pindex = pindex; 1336 1337 /* 1338 * The following call to vdrop() must come after the above call 1339 * to vm_page_insert() in case both affect the same object and 1340 * vnode. Otherwise, the affected vnode's hold count could 1341 * temporarily become zero. 1342 */ 1343 if (vp != NULL) 1344 vdrop(vp); 1345 1346 /* 1347 * Don't wakeup too often - wakeup the pageout daemon when 1348 * we would be nearly out of memory. 1349 */ 1350 if (vm_paging_needed()) 1351 pagedaemon_wakeup(); 1352 1353 return (m); 1354} 1355 1356/* 1357 * vm_wait: (also see VM_WAIT macro) 1358 * 1359 * Block until free pages are available for allocation 1360 * - Called in various places before memory allocations. 1361 */ 1362void 1363vm_wait(void) 1364{ 1365 1366 mtx_lock(&vm_page_queue_free_mtx); 1367 if (curproc == pageproc) { 1368 vm_pageout_pages_needed = 1; 1369 msleep(&vm_pageout_pages_needed, &vm_page_queue_free_mtx, 1370 PDROP | PSWP, "VMWait", 0); 1371 } else { 1372 if (!vm_pages_needed) { 1373 vm_pages_needed = 1; 1374 wakeup(&vm_pages_needed); 1375 } 1376 msleep(&cnt.v_free_count, &vm_page_queue_free_mtx, PDROP | PVM, 1377 "vmwait", 0); 1378 } 1379} 1380 1381/* 1382 * vm_waitpfault: (also see VM_WAITPFAULT macro) 1383 * 1384 * Block until free pages are available for allocation 1385 * - Called only in vm_fault so that processes page faulting 1386 * can be easily tracked. 1387 * - Sleeps at a lower priority than vm_wait() so that vm_wait()ing 1388 * processes will be able to grab memory first. Do not change 1389 * this balance without careful testing first. 1390 */ 1391void 1392vm_waitpfault(void) 1393{ 1394 1395 mtx_lock(&vm_page_queue_free_mtx); 1396 if (!vm_pages_needed) { 1397 vm_pages_needed = 1; 1398 wakeup(&vm_pages_needed); 1399 } 1400 msleep(&cnt.v_free_count, &vm_page_queue_free_mtx, PDROP | PUSER, 1401 "pfault", 0); 1402} 1403 1404/* 1405 * vm_page_requeue: 1406 * 1407 * Move the given page to the tail of its present page queue. 1408 * 1409 * The page queues must be locked. 1410 */ 1411void 1412vm_page_requeue(vm_page_t m) 1413{ 1414 struct vpgqueues *vpq; 1415 int queue; 1416 1417 mtx_assert(&vm_page_queue_mtx, MA_OWNED); 1418 queue = m->queue; 1419 KASSERT(queue != PQ_NONE, 1420 ("vm_page_requeue: page %p is not queued", m)); 1421 vpq = &vm_page_queues[queue]; 1422 TAILQ_REMOVE(&vpq->pl, m, pageq); 1423 TAILQ_INSERT_TAIL(&vpq->pl, m, pageq); 1424} 1425 1426/* 1427 * vm_page_queue_remove: 1428 * 1429 * Remove the given page from the specified queue. 1430 * 1431 * The page and page queues must be locked. 1432 */ 1433static __inline void 1434vm_page_queue_remove(int queue, vm_page_t m) 1435{ 1436 struct vpgqueues *pq; 1437 1438 mtx_assert(&vm_page_queue_mtx, MA_OWNED); 1439 vm_page_lock_assert(m, MA_OWNED); 1440 pq = &vm_page_queues[queue]; 1441 TAILQ_REMOVE(&pq->pl, m, pageq); 1442 (*pq->cnt)--; 1443} 1444 1445/* 1446 * vm_pageq_remove: 1447 * 1448 * Remove a page from its queue. 1449 * 1450 * The given page must be locked. 1451 * This routine may not block. 1452 */ 1453void 1454vm_pageq_remove(vm_page_t m) 1455{ 1456 int queue; 1457 1458 vm_page_lock_assert(m, MA_OWNED); 1459 if ((queue = m->queue) != PQ_NONE) { 1460 vm_page_lock_queues(); 1461 m->queue = PQ_NONE; 1462 vm_page_queue_remove(queue, m); 1463 vm_page_unlock_queues(); 1464 } 1465} 1466 1467/* 1468 * vm_page_enqueue: 1469 * 1470 * Add the given page to the specified queue. 1471 * 1472 * The page queues must be locked. 1473 */ 1474static void 1475vm_page_enqueue(int queue, vm_page_t m) 1476{ 1477 struct vpgqueues *vpq; 1478 1479 vpq = &vm_page_queues[queue]; 1480 m->queue = queue; 1481 TAILQ_INSERT_TAIL(&vpq->pl, m, pageq); 1482 ++*vpq->cnt; 1483} 1484 1485/* 1486 * vm_page_activate: 1487 * 1488 * Put the specified page on the active list (if appropriate). 1489 * Ensure that act_count is at least ACT_INIT but do not otherwise 1490 * mess with it. 1491 * 1492 * The page must be locked. 1493 * This routine may not block. 1494 */ 1495void 1496vm_page_activate(vm_page_t m) 1497{ 1498 int queue; 1499 1500 vm_page_lock_assert(m, MA_OWNED); 1501 if ((queue = m->queue) != PQ_ACTIVE) { 1502 if (m->wire_count == 0 && (m->flags & PG_UNMANAGED) == 0) { 1503 if (m->act_count < ACT_INIT) 1504 m->act_count = ACT_INIT; 1505 vm_page_lock_queues(); 1506 if (queue != PQ_NONE) 1507 vm_page_queue_remove(queue, m); 1508 vm_page_enqueue(PQ_ACTIVE, m); 1509 vm_page_unlock_queues(); 1510 } else 1511 KASSERT(queue == PQ_NONE, 1512 ("vm_page_activate: wired page %p is queued", m)); 1513 } else { 1514 if (m->act_count < ACT_INIT) 1515 m->act_count = ACT_INIT; 1516 } 1517} 1518 1519/* 1520 * vm_page_free_wakeup: 1521 * 1522 * Helper routine for vm_page_free_toq() and vm_page_cache(). This 1523 * routine is called when a page has been added to the cache or free 1524 * queues. 1525 * 1526 * The page queues must be locked. 1527 * This routine may not block. 1528 */ 1529static inline void 1530vm_page_free_wakeup(void) 1531{ 1532 1533 mtx_assert(&vm_page_queue_free_mtx, MA_OWNED); 1534 /* 1535 * if pageout daemon needs pages, then tell it that there are 1536 * some free. 1537 */ 1538 if (vm_pageout_pages_needed && 1539 cnt.v_cache_count + cnt.v_free_count >= cnt.v_pageout_free_min) { 1540 wakeup(&vm_pageout_pages_needed); 1541 vm_pageout_pages_needed = 0; 1542 } 1543 /* 1544 * wakeup processes that are waiting on memory if we hit a 1545 * high water mark. And wakeup scheduler process if we have 1546 * lots of memory. this process will swapin processes. 1547 */ 1548 if (vm_pages_needed && !vm_page_count_min()) { 1549 vm_pages_needed = 0; 1550 wakeup(&cnt.v_free_count); 1551 } 1552} 1553 1554/* 1555 * vm_page_free_toq: 1556 * 1557 * Returns the given page to the free list, 1558 * disassociating it with any VM object. 1559 * 1560 * Object and page must be locked prior to entry. 1561 * This routine may not block. 1562 */ 1563 1564void 1565vm_page_free_toq(vm_page_t m) 1566{ 1567 1568 if ((m->flags & PG_UNMANAGED) == 0) { 1569 vm_page_lock_assert(m, MA_OWNED); 1570 KASSERT(!pmap_page_is_mapped(m), 1571 ("vm_page_free_toq: freeing mapped page %p", m)); 1572 } 1573 PCPU_INC(cnt.v_tfree); 1574 1575 if (m->busy || VM_PAGE_IS_FREE(m)) { 1576 printf( 1577 "vm_page_free: pindex(%lu), busy(%d), VPO_BUSY(%d), hold(%d)\n", 1578 (u_long)m->pindex, m->busy, (m->oflags & VPO_BUSY) ? 1 : 0, 1579 m->hold_count); 1580 if (VM_PAGE_IS_FREE(m)) 1581 panic("vm_page_free: freeing free page"); 1582 else 1583 panic("vm_page_free: freeing busy page"); 1584 } 1585 1586 /* 1587 * unqueue, then remove page. Note that we cannot destroy 1588 * the page here because we do not want to call the pager's 1589 * callback routine until after we've put the page on the 1590 * appropriate free queue. 1591 */ 1592 if ((m->flags & PG_UNMANAGED) == 0) 1593 vm_pageq_remove(m); 1594 vm_page_remove(m); 1595 1596 /* 1597 * If fictitious remove object association and 1598 * return, otherwise delay object association removal. 1599 */ 1600 if ((m->flags & PG_FICTITIOUS) != 0) { 1601 return; 1602 } 1603 1604 m->valid = 0; 1605 vm_page_undirty(m); 1606 1607 if (m->wire_count != 0) { 1608 if (m->wire_count > 1) { 1609 panic("vm_page_free: invalid wire count (%d), pindex: 0x%lx", 1610 m->wire_count, (long)m->pindex); 1611 } 1612 panic("vm_page_free: freeing wired page"); 1613 } 1614 if (m->hold_count != 0) { 1615 m->flags &= ~PG_ZERO; 1616 vm_page_lock_queues(); 1617 vm_page_enqueue(PQ_HOLD, m); 1618 vm_page_unlock_queues(); 1619 } else { 1620 /* 1621 * Restore the default memory attribute to the page. 1622 */ 1623 if (pmap_page_get_memattr(m) != VM_MEMATTR_DEFAULT) 1624 pmap_page_set_memattr(m, VM_MEMATTR_DEFAULT); 1625 1626 /* 1627 * Insert the page into the physical memory allocator's 1628 * cache/free page queues. 1629 */ 1630 mtx_lock(&vm_page_queue_free_mtx); 1631 m->flags |= PG_FREE; 1632 cnt.v_free_count++; 1633#if VM_NRESERVLEVEL > 0 1634 if (!vm_reserv_free_page(m)) 1635#else 1636 if (TRUE) 1637#endif 1638 vm_phys_free_pages(m, 0); 1639 if ((m->flags & PG_ZERO) != 0) 1640 ++vm_page_zero_count; 1641 else 1642 vm_page_zero_idle_wakeup(); 1643 vm_page_free_wakeup(); 1644 mtx_unlock(&vm_page_queue_free_mtx); 1645 } 1646} 1647 1648/* 1649 * vm_page_wire: 1650 * 1651 * Mark this page as wired down by yet 1652 * another map, removing it from paging queues 1653 * as necessary. 1654 * 1655 * If the page is fictitious, then its wire count must remain one. 1656 * 1657 * The page must be locked. 1658 * This routine may not block. 1659 */ 1660void 1661vm_page_wire(vm_page_t m) 1662{ 1663 1664 /* 1665 * Only bump the wire statistics if the page is not already wired, 1666 * and only unqueue the page if it is on some queue (if it is unmanaged 1667 * it is already off the queues). 1668 */ 1669 vm_page_lock_assert(m, MA_OWNED); 1670 if ((m->flags & PG_FICTITIOUS) != 0) { 1671 KASSERT(m->wire_count == 1, 1672 ("vm_page_wire: fictitious page %p's wire count isn't one", 1673 m)); 1674 return; 1675 } 1676 if (m->wire_count == 0) { 1677 if ((m->flags & PG_UNMANAGED) == 0) 1678 vm_pageq_remove(m); 1679 atomic_add_int(&cnt.v_wire_count, 1); 1680 } 1681 m->wire_count++; 1682 KASSERT(m->wire_count != 0, ("vm_page_wire: wire_count overflow m=%p", m)); 1683} 1684 1685/* 1686 * vm_page_unwire: 1687 * 1688 * Release one wiring of the specified page, potentially enabling it to be 1689 * paged again. If paging is enabled, then the value of the parameter 1690 * "activate" determines to which queue the page is added. If "activate" is 1691 * non-zero, then the page is added to the active queue. Otherwise, it is 1692 * added to the inactive queue. 1693 * 1694 * However, unless the page belongs to an object, it is not enqueued because 1695 * it cannot be paged out. 1696 * 1697 * If a page is fictitious, then its wire count must alway be one. 1698 * 1699 * A managed page must be locked. 1700 */ 1701void 1702vm_page_unwire(vm_page_t m, int activate) 1703{ 1704 1705 if ((m->flags & PG_UNMANAGED) == 0) 1706 vm_page_lock_assert(m, MA_OWNED); 1707 if ((m->flags & PG_FICTITIOUS) != 0) { 1708 KASSERT(m->wire_count == 1, 1709 ("vm_page_unwire: fictitious page %p's wire count isn't one", m)); 1710 return; 1711 } 1712 if (m->wire_count > 0) { 1713 m->wire_count--; 1714 if (m->wire_count == 0) { 1715 atomic_subtract_int(&cnt.v_wire_count, 1); 1716 if ((m->flags & PG_UNMANAGED) != 0 || 1717 m->object == NULL) 1718 return; 1719 vm_page_lock_queues(); 1720 if (activate) 1721 vm_page_enqueue(PQ_ACTIVE, m); 1722 else { 1723 vm_page_flag_clear(m, PG_WINATCFLS); 1724 vm_page_enqueue(PQ_INACTIVE, m); 1725 } 1726 vm_page_unlock_queues(); 1727 } 1728 } else 1729 panic("vm_page_unwire: page %p's wire count is zero", m); 1730} 1731 1732/* 1733 * Move the specified page to the inactive queue. 1734 * 1735 * Many pages placed on the inactive queue should actually go 1736 * into the cache, but it is difficult to figure out which. What 1737 * we do instead, if the inactive target is well met, is to put 1738 * clean pages at the head of the inactive queue instead of the tail. 1739 * This will cause them to be moved to the cache more quickly and 1740 * if not actively re-referenced, reclaimed more quickly. If we just 1741 * stick these pages at the end of the inactive queue, heavy filesystem 1742 * meta-data accesses can cause an unnecessary paging load on memory bound 1743 * processes. This optimization causes one-time-use metadata to be 1744 * reused more quickly. 1745 * 1746 * Normally athead is 0 resulting in LRU operation. athead is set 1747 * to 1 if we want this page to be 'as if it were placed in the cache', 1748 * except without unmapping it from the process address space. 1749 * 1750 * This routine may not block. 1751 */ 1752static inline void 1753_vm_page_deactivate(vm_page_t m, int athead) 1754{ 1755 int queue; 1756 1757 vm_page_lock_assert(m, MA_OWNED); 1758 1759 /* 1760 * Ignore if already inactive. 1761 */ 1762 if ((queue = m->queue) == PQ_INACTIVE) 1763 return; 1764 if (m->wire_count == 0 && (m->flags & PG_UNMANAGED) == 0) { 1765 vm_page_lock_queues(); 1766 vm_page_flag_clear(m, PG_WINATCFLS); 1767 if (queue != PQ_NONE) 1768 vm_page_queue_remove(queue, m); 1769 if (athead) 1770 TAILQ_INSERT_HEAD(&vm_page_queues[PQ_INACTIVE].pl, m, 1771 pageq); 1772 else 1773 TAILQ_INSERT_TAIL(&vm_page_queues[PQ_INACTIVE].pl, m, 1774 pageq); 1775 m->queue = PQ_INACTIVE; 1776 cnt.v_inactive_count++; 1777 vm_page_unlock_queues(); 1778 } 1779} 1780 1781/* 1782 * Move the specified page to the inactive queue. 1783 * 1784 * The page must be locked. 1785 */ 1786void 1787vm_page_deactivate(vm_page_t m) 1788{ 1789 1790 _vm_page_deactivate(m, 0); 1791} 1792 1793/* 1794 * vm_page_try_to_cache: 1795 * 1796 * Returns 0 on failure, 1 on success 1797 */ 1798int 1799vm_page_try_to_cache(vm_page_t m) 1800{ 1801 1802 vm_page_lock_assert(m, MA_OWNED); 1803 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 1804 if (m->dirty || m->hold_count || m->busy || m->wire_count || 1805 (m->oflags & VPO_BUSY) || (m->flags & PG_UNMANAGED)) 1806 return (0); 1807 pmap_remove_all(m); 1808 if (m->dirty) 1809 return (0); 1810 vm_page_cache(m); 1811 return (1); 1812} 1813 1814/* 1815 * vm_page_try_to_free() 1816 * 1817 * Attempt to free the page. If we cannot free it, we do nothing. 1818 * 1 is returned on success, 0 on failure. 1819 */ 1820int 1821vm_page_try_to_free(vm_page_t m) 1822{ 1823 1824 vm_page_lock_assert(m, MA_OWNED); 1825 if (m->object != NULL) 1826 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 1827 if (m->dirty || m->hold_count || m->busy || m->wire_count || 1828 (m->oflags & VPO_BUSY) || (m->flags & PG_UNMANAGED)) 1829 return (0); 1830 pmap_remove_all(m); 1831 if (m->dirty) 1832 return (0); 1833 vm_page_free(m); 1834 return (1); 1835} 1836 1837/* 1838 * vm_page_cache 1839 * 1840 * Put the specified page onto the page cache queue (if appropriate). 1841 * 1842 * This routine may not block. 1843 */ 1844void 1845vm_page_cache(vm_page_t m) 1846{ 1847 vm_object_t object; 1848 vm_page_t root; 1849 1850 vm_page_lock_assert(m, MA_OWNED); 1851 object = m->object; 1852 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 1853 if ((m->flags & PG_UNMANAGED) || (m->oflags & VPO_BUSY) || m->busy || 1854 m->hold_count || m->wire_count) 1855 panic("vm_page_cache: attempting to cache busy page"); 1856 pmap_remove_all(m); 1857 if (m->dirty != 0) 1858 panic("vm_page_cache: page %p is dirty", m); 1859 if (m->valid == 0 || object->type == OBJT_DEFAULT || 1860 (object->type == OBJT_SWAP && 1861 !vm_pager_has_page(object, m->pindex, NULL, NULL))) { 1862 /* 1863 * Hypothesis: A cache-elgible page belonging to a 1864 * default object or swap object but without a backing 1865 * store must be zero filled. 1866 */ 1867 vm_page_free(m); 1868 return; 1869 } 1870 KASSERT((m->flags & PG_CACHED) == 0, 1871 ("vm_page_cache: page %p is already cached", m)); 1872 PCPU_INC(cnt.v_tcached); 1873 1874 /* 1875 * Remove the page from the paging queues. 1876 */ 1877 vm_pageq_remove(m); 1878 1879 /* 1880 * Remove the page from the object's collection of resident 1881 * pages. 1882 */ 1883 if (m != object->root) 1884 vm_page_splay(m->pindex, object->root); 1885 if (m->left == NULL) 1886 root = m->right; 1887 else { 1888 root = vm_page_splay(m->pindex, m->left); 1889 root->right = m->right; 1890 } 1891 object->root = root; 1892 TAILQ_REMOVE(&object->memq, m, listq); 1893 object->resident_page_count--; 1894 object->generation++; 1895 1896 /* 1897 * Restore the default memory attribute to the page. 1898 */ 1899 if (pmap_page_get_memattr(m) != VM_MEMATTR_DEFAULT) 1900 pmap_page_set_memattr(m, VM_MEMATTR_DEFAULT); 1901 1902 /* 1903 * Insert the page into the object's collection of cached pages 1904 * and the physical memory allocator's cache/free page queues. 1905 */ 1906 m->flags &= ~PG_ZERO; 1907 mtx_lock(&vm_page_queue_free_mtx); 1908 m->flags |= PG_CACHED; 1909 cnt.v_cache_count++; 1910 root = object->cache; 1911 if (root == NULL) { 1912 m->left = NULL; 1913 m->right = NULL; 1914 } else { 1915 root = vm_page_splay(m->pindex, root); 1916 if (m->pindex < root->pindex) { 1917 m->left = root->left; 1918 m->right = root; 1919 root->left = NULL; 1920 } else if (__predict_false(m->pindex == root->pindex)) 1921 panic("vm_page_cache: offset already cached"); 1922 else { 1923 m->right = root->right; 1924 m->left = root; 1925 root->right = NULL; 1926 } 1927 } 1928 object->cache = m; 1929#if VM_NRESERVLEVEL > 0 1930 if (!vm_reserv_free_page(m)) { 1931#else 1932 if (TRUE) { 1933#endif 1934 vm_phys_set_pool(VM_FREEPOOL_CACHE, m, 0); 1935 vm_phys_free_pages(m, 0); 1936 } 1937 vm_page_free_wakeup(); 1938 mtx_unlock(&vm_page_queue_free_mtx); 1939 1940 /* 1941 * Increment the vnode's hold count if this is the object's only 1942 * cached page. Decrement the vnode's hold count if this was 1943 * the object's only resident page. 1944 */ 1945 if (object->type == OBJT_VNODE) { 1946 if (root == NULL && object->resident_page_count != 0) 1947 vhold(object->handle); 1948 else if (root != NULL && object->resident_page_count == 0) 1949 vdrop(object->handle); 1950 } 1951} 1952 1953/* 1954 * vm_page_dontneed 1955 * 1956 * Cache, deactivate, or do nothing as appropriate. This routine 1957 * is typically used by madvise() MADV_DONTNEED. 1958 * 1959 * Generally speaking we want to move the page into the cache so 1960 * it gets reused quickly. However, this can result in a silly syndrome 1961 * due to the page recycling too quickly. Small objects will not be 1962 * fully cached. On the otherhand, if we move the page to the inactive 1963 * queue we wind up with a problem whereby very large objects 1964 * unnecessarily blow away our inactive and cache queues. 1965 * 1966 * The solution is to move the pages based on a fixed weighting. We 1967 * either leave them alone, deactivate them, or move them to the cache, 1968 * where moving them to the cache has the highest weighting. 1969 * By forcing some pages into other queues we eventually force the 1970 * system to balance the queues, potentially recovering other unrelated 1971 * space from active. The idea is to not force this to happen too 1972 * often. 1973 */ 1974void 1975vm_page_dontneed(vm_page_t m) 1976{ 1977 int dnw; 1978 int head; 1979 1980 vm_page_lock_assert(m, MA_OWNED); 1981 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 1982 dnw = PCPU_GET(dnweight); 1983 PCPU_INC(dnweight); 1984 1985 /* 1986 * Occasionally leave the page alone. 1987 */ 1988 if ((dnw & 0x01F0) == 0 || m->queue == PQ_INACTIVE) { 1989 if (m->act_count >= ACT_INIT) 1990 --m->act_count; 1991 return; 1992 } 1993 1994 /* 1995 * Clear any references to the page. Otherwise, the page daemon will 1996 * immediately reactivate the page. 1997 * 1998 * Perform the pmap_clear_reference() first. Otherwise, a concurrent 1999 * pmap operation, such as pmap_remove(), could clear a reference in 2000 * the pmap and set PG_REFERENCED on the page before the 2001 * pmap_clear_reference() had completed. Consequently, the page would 2002 * appear referenced based upon an old reference that occurred before 2003 * this function ran. 2004 */ 2005 pmap_clear_reference(m); 2006 vm_page_lock_queues(); 2007 vm_page_flag_clear(m, PG_REFERENCED); 2008 vm_page_unlock_queues(); 2009 2010 if (m->dirty == 0 && pmap_is_modified(m)) 2011 vm_page_dirty(m); 2012 2013 if (m->dirty || (dnw & 0x0070) == 0) { 2014 /* 2015 * Deactivate the page 3 times out of 32. 2016 */ 2017 head = 0; 2018 } else { 2019 /* 2020 * Cache the page 28 times out of every 32. Note that 2021 * the page is deactivated instead of cached, but placed 2022 * at the head of the queue instead of the tail. 2023 */ 2024 head = 1; 2025 } 2026 _vm_page_deactivate(m, head); 2027} 2028 2029/* 2030 * Grab a page, waiting until we are waken up due to the page 2031 * changing state. We keep on waiting, if the page continues 2032 * to be in the object. If the page doesn't exist, first allocate it 2033 * and then conditionally zero it. 2034 * 2035 * This routine may block. 2036 */ 2037vm_page_t 2038vm_page_grab(vm_object_t object, vm_pindex_t pindex, int allocflags) 2039{ 2040 vm_page_t m; 2041 u_int count; 2042 2043 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 2044retrylookup: 2045 if ((m = vm_page_lookup(object, pindex)) != NULL) { 2046 if ((m->oflags & VPO_BUSY) != 0 || 2047 ((allocflags & VM_ALLOC_IGN_SBUSY) == 0 && m->busy != 0)) { 2048 if ((allocflags & VM_ALLOC_RETRY) != 0) { 2049 /* 2050 * Reference the page before unlocking and 2051 * sleeping so that the page daemon is less 2052 * likely to reclaim it. 2053 */ 2054 vm_page_lock_queues(); 2055 vm_page_flag_set(m, PG_REFERENCED); 2056 } 2057 vm_page_sleep(m, "pgrbwt"); 2058 if ((allocflags & VM_ALLOC_RETRY) == 0) 2059 return (NULL); 2060 goto retrylookup; 2061 } else { 2062 if ((allocflags & VM_ALLOC_WIRED) != 0) { 2063 vm_page_lock(m); 2064 vm_page_wire(m); 2065 vm_page_unlock(m); 2066 } 2067 if ((allocflags & VM_ALLOC_NOBUSY) == 0) 2068 vm_page_busy(m); 2069 return (m); 2070 } 2071 } 2072 m = vm_page_alloc(object, pindex, allocflags & ~(VM_ALLOC_RETRY | 2073 VM_ALLOC_IGN_SBUSY | VM_ALLOC_COUNT_MASK)); 2074 if (m == NULL) { 2075 VM_OBJECT_UNLOCK(object); 2076 count = (u_int)allocflags >> VM_ALLOC_COUNT_SHIFT; 2077 if (count > 0) 2078 atomic_add_int(&vm_pageout_deficit, count); 2079 VM_WAIT; 2080 VM_OBJECT_LOCK(object); 2081 if ((allocflags & VM_ALLOC_RETRY) == 0) 2082 return (NULL); 2083 goto retrylookup; 2084 } else if (m->valid != 0) 2085 return (m); 2086 if (allocflags & VM_ALLOC_ZERO && (m->flags & PG_ZERO) == 0) 2087 pmap_zero_page(m); 2088 return (m); 2089} 2090 2091/* 2092 * Mapping function for valid bits or for dirty bits in 2093 * a page. May not block. 2094 * 2095 * Inputs are required to range within a page. 2096 */ 2097int 2098vm_page_bits(int base, int size) 2099{ 2100 int first_bit; 2101 int last_bit; 2102 2103 KASSERT( 2104 base + size <= PAGE_SIZE, 2105 ("vm_page_bits: illegal base/size %d/%d", base, size) 2106 ); 2107 2108 if (size == 0) /* handle degenerate case */ 2109 return (0); 2110 2111 first_bit = base >> DEV_BSHIFT; 2112 last_bit = (base + size - 1) >> DEV_BSHIFT; 2113 2114 return ((2 << last_bit) - (1 << first_bit)); 2115} 2116 2117/* 2118 * vm_page_set_valid: 2119 * 2120 * Sets portions of a page valid. The arguments are expected 2121 * to be DEV_BSIZE aligned but if they aren't the bitmap is inclusive 2122 * of any partial chunks touched by the range. The invalid portion of 2123 * such chunks will be zeroed. 2124 * 2125 * (base + size) must be less then or equal to PAGE_SIZE. 2126 */ 2127void 2128vm_page_set_valid(vm_page_t m, int base, int size) 2129{ 2130 int endoff, frag; 2131 2132 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2133 if (size == 0) /* handle degenerate case */ 2134 return; 2135 2136 /* 2137 * If the base is not DEV_BSIZE aligned and the valid 2138 * bit is clear, we have to zero out a portion of the 2139 * first block. 2140 */ 2141 if ((frag = base & ~(DEV_BSIZE - 1)) != base && 2142 (m->valid & (1 << (base >> DEV_BSHIFT))) == 0) 2143 pmap_zero_page_area(m, frag, base - frag); 2144 2145 /* 2146 * If the ending offset is not DEV_BSIZE aligned and the 2147 * valid bit is clear, we have to zero out a portion of 2148 * the last block. 2149 */ 2150 endoff = base + size; 2151 if ((frag = endoff & ~(DEV_BSIZE - 1)) != endoff && 2152 (m->valid & (1 << (endoff >> DEV_BSHIFT))) == 0) 2153 pmap_zero_page_area(m, endoff, 2154 DEV_BSIZE - (endoff & (DEV_BSIZE - 1))); 2155 2156 /* 2157 * Assert that no previously invalid block that is now being validated 2158 * is already dirty. 2159 */ 2160 KASSERT((~m->valid & vm_page_bits(base, size) & m->dirty) == 0, 2161 ("vm_page_set_valid: page %p is dirty", m)); 2162 2163 /* 2164 * Set valid bits inclusive of any overlap. 2165 */ 2166 m->valid |= vm_page_bits(base, size); 2167} 2168 2169/* 2170 * Clear the given bits from the specified page's dirty field. 2171 */ 2172static __inline void 2173vm_page_clear_dirty_mask(vm_page_t m, int pagebits) 2174{ 2175 2176 /* 2177 * If the object is locked and the page is neither VPO_BUSY nor 2178 * PG_WRITEABLE, then the page's dirty field cannot possibly be 2179 * modified by a concurrent pmap operation. 2180 */ 2181 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2182 if ((m->oflags & VPO_BUSY) == 0 && (m->flags & PG_WRITEABLE) == 0) 2183 m->dirty &= ~pagebits; 2184 else { 2185 vm_page_lock_queues(); 2186 m->dirty &= ~pagebits; 2187 vm_page_unlock_queues(); 2188 } 2189} 2190 2191/* 2192 * vm_page_set_validclean: 2193 * 2194 * Sets portions of a page valid and clean. The arguments are expected 2195 * to be DEV_BSIZE aligned but if they aren't the bitmap is inclusive 2196 * of any partial chunks touched by the range. The invalid portion of 2197 * such chunks will be zero'd. 2198 * 2199 * This routine may not block. 2200 * 2201 * (base + size) must be less then or equal to PAGE_SIZE. 2202 */ 2203void 2204vm_page_set_validclean(vm_page_t m, int base, int size) 2205{ 2206 u_long oldvalid; 2207 int endoff, frag, pagebits; 2208 2209 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2210 if (size == 0) /* handle degenerate case */ 2211 return; 2212 2213 /* 2214 * If the base is not DEV_BSIZE aligned and the valid 2215 * bit is clear, we have to zero out a portion of the 2216 * first block. 2217 */ 2218 if ((frag = base & ~(DEV_BSIZE - 1)) != base && 2219 (m->valid & (1 << (base >> DEV_BSHIFT))) == 0) 2220 pmap_zero_page_area(m, frag, base - frag); 2221 2222 /* 2223 * If the ending offset is not DEV_BSIZE aligned and the 2224 * valid bit is clear, we have to zero out a portion of 2225 * the last block. 2226 */ 2227 endoff = base + size; 2228 if ((frag = endoff & ~(DEV_BSIZE - 1)) != endoff && 2229 (m->valid & (1 << (endoff >> DEV_BSHIFT))) == 0) 2230 pmap_zero_page_area(m, endoff, 2231 DEV_BSIZE - (endoff & (DEV_BSIZE - 1))); 2232 2233 /* 2234 * Set valid, clear dirty bits. If validating the entire 2235 * page we can safely clear the pmap modify bit. We also 2236 * use this opportunity to clear the VPO_NOSYNC flag. If a process 2237 * takes a write fault on a MAP_NOSYNC memory area the flag will 2238 * be set again. 2239 * 2240 * We set valid bits inclusive of any overlap, but we can only 2241 * clear dirty bits for DEV_BSIZE chunks that are fully within 2242 * the range. 2243 */ 2244 oldvalid = m->valid; 2245 pagebits = vm_page_bits(base, size); 2246 m->valid |= pagebits; 2247#if 0 /* NOT YET */ 2248 if ((frag = base & (DEV_BSIZE - 1)) != 0) { 2249 frag = DEV_BSIZE - frag; 2250 base += frag; 2251 size -= frag; 2252 if (size < 0) 2253 size = 0; 2254 } 2255 pagebits = vm_page_bits(base, size & (DEV_BSIZE - 1)); 2256#endif 2257 if (base == 0 && size == PAGE_SIZE) { 2258 /* 2259 * The page can only be modified within the pmap if it is 2260 * mapped, and it can only be mapped if it was previously 2261 * fully valid. 2262 */ 2263 if (oldvalid == VM_PAGE_BITS_ALL) 2264 /* 2265 * Perform the pmap_clear_modify() first. Otherwise, 2266 * a concurrent pmap operation, such as 2267 * pmap_protect(), could clear a modification in the 2268 * pmap and set the dirty field on the page before 2269 * pmap_clear_modify() had begun and after the dirty 2270 * field was cleared here. 2271 */ 2272 pmap_clear_modify(m); 2273 m->dirty = 0; 2274 m->oflags &= ~VPO_NOSYNC; 2275 } else if (oldvalid != VM_PAGE_BITS_ALL) 2276 m->dirty &= ~pagebits; 2277 else 2278 vm_page_clear_dirty_mask(m, pagebits); 2279} 2280 2281void 2282vm_page_clear_dirty(vm_page_t m, int base, int size) 2283{ 2284 2285 vm_page_clear_dirty_mask(m, vm_page_bits(base, size)); 2286} 2287 2288/* 2289 * vm_page_set_invalid: 2290 * 2291 * Invalidates DEV_BSIZE'd chunks within a page. Both the 2292 * valid and dirty bits for the effected areas are cleared. 2293 * 2294 * May not block. 2295 */ 2296void 2297vm_page_set_invalid(vm_page_t m, int base, int size) 2298{ 2299 int bits; 2300 2301 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2302 KASSERT((m->oflags & VPO_BUSY) == 0, 2303 ("vm_page_set_invalid: page %p is busy", m)); 2304 bits = vm_page_bits(base, size); 2305 if (m->valid == VM_PAGE_BITS_ALL && bits != 0) 2306 pmap_remove_all(m); 2307 KASSERT(!pmap_page_is_mapped(m), 2308 ("vm_page_set_invalid: page %p is mapped", m)); 2309 m->valid &= ~bits; 2310 m->dirty &= ~bits; 2311 m->object->generation++; 2312} 2313 2314/* 2315 * vm_page_zero_invalid() 2316 * 2317 * The kernel assumes that the invalid portions of a page contain 2318 * garbage, but such pages can be mapped into memory by user code. 2319 * When this occurs, we must zero out the non-valid portions of the 2320 * page so user code sees what it expects. 2321 * 2322 * Pages are most often semi-valid when the end of a file is mapped 2323 * into memory and the file's size is not page aligned. 2324 */ 2325void 2326vm_page_zero_invalid(vm_page_t m, boolean_t setvalid) 2327{ 2328 int b; 2329 int i; 2330 2331 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2332 /* 2333 * Scan the valid bits looking for invalid sections that 2334 * must be zerod. Invalid sub-DEV_BSIZE'd areas ( where the 2335 * valid bit may be set ) have already been zerod by 2336 * vm_page_set_validclean(). 2337 */ 2338 for (b = i = 0; i <= PAGE_SIZE / DEV_BSIZE; ++i) { 2339 if (i == (PAGE_SIZE / DEV_BSIZE) || 2340 (m->valid & (1 << i)) 2341 ) { 2342 if (i > b) { 2343 pmap_zero_page_area(m, 2344 b << DEV_BSHIFT, (i - b) << DEV_BSHIFT); 2345 } 2346 b = i + 1; 2347 } 2348 } 2349 2350 /* 2351 * setvalid is TRUE when we can safely set the zero'd areas 2352 * as being valid. We can do this if there are no cache consistancy 2353 * issues. e.g. it is ok to do with UFS, but not ok to do with NFS. 2354 */ 2355 if (setvalid) 2356 m->valid = VM_PAGE_BITS_ALL; 2357} 2358 2359/* 2360 * vm_page_is_valid: 2361 * 2362 * Is (partial) page valid? Note that the case where size == 0 2363 * will return FALSE in the degenerate case where the page is 2364 * entirely invalid, and TRUE otherwise. 2365 * 2366 * May not block. 2367 */ 2368int 2369vm_page_is_valid(vm_page_t m, int base, int size) 2370{ 2371 int bits = vm_page_bits(base, size); 2372 2373 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2374 if (m->valid && ((m->valid & bits) == bits)) 2375 return 1; 2376 else 2377 return 0; 2378} 2379 2380/* 2381 * update dirty bits from pmap/mmu. May not block. 2382 */ 2383void 2384vm_page_test_dirty(vm_page_t m) 2385{ 2386 2387 VM_OBJECT_LOCK_ASSERT(m->object, MA_OWNED); 2388 if (m->dirty != VM_PAGE_BITS_ALL && pmap_is_modified(m)) 2389 vm_page_dirty(m); 2390} 2391 2392int so_zerocp_fullpage = 0; 2393 2394/* 2395 * Replace the given page with a copy. The copied page assumes 2396 * the portion of the given page's "wire_count" that is not the 2397 * responsibility of this copy-on-write mechanism. 2398 * 2399 * The object containing the given page must have a non-zero 2400 * paging-in-progress count and be locked. 2401 */ 2402void 2403vm_page_cowfault(vm_page_t m) 2404{ 2405 vm_page_t mnew; 2406 vm_object_t object; 2407 vm_pindex_t pindex; 2408 2409 mtx_assert(&vm_page_queue_mtx, MA_NOTOWNED); 2410 vm_page_lock_assert(m, MA_OWNED); 2411 object = m->object; 2412 VM_OBJECT_LOCK_ASSERT(object, MA_OWNED); 2413 KASSERT(object->paging_in_progress != 0, 2414 ("vm_page_cowfault: object %p's paging-in-progress count is zero.", 2415 object)); 2416 pindex = m->pindex; 2417 2418 retry_alloc: 2419 pmap_remove_all(m); 2420 vm_page_remove(m); 2421 mnew = vm_page_alloc(object, pindex, VM_ALLOC_NORMAL | VM_ALLOC_NOBUSY); 2422 if (mnew == NULL) { 2423 vm_page_insert(m, object, pindex); 2424 vm_page_unlock(m); 2425 VM_OBJECT_UNLOCK(object); 2426 VM_WAIT; 2427 VM_OBJECT_LOCK(object); 2428 if (m == vm_page_lookup(object, pindex)) { 2429 vm_page_lock(m); 2430 goto retry_alloc; 2431 } else { 2432 /* 2433 * Page disappeared during the wait. 2434 */ 2435 return; 2436 } 2437 } 2438 2439 if (m->cow == 0) { 2440 /* 2441 * check to see if we raced with an xmit complete when 2442 * waiting to allocate a page. If so, put things back 2443 * the way they were 2444 */ 2445 vm_page_unlock(m); 2446 vm_page_lock(mnew); 2447 vm_page_free(mnew); 2448 vm_page_unlock(mnew); 2449 vm_page_insert(m, object, pindex); 2450 } else { /* clear COW & copy page */ 2451 if (!so_zerocp_fullpage) 2452 pmap_copy_page(m, mnew); 2453 mnew->valid = VM_PAGE_BITS_ALL; 2454 vm_page_dirty(mnew); 2455 mnew->wire_count = m->wire_count - m->cow; 2456 m->wire_count = m->cow; 2457 vm_page_unlock(m); 2458 } 2459} 2460 2461void 2462vm_page_cowclear(vm_page_t m) 2463{ 2464 2465 vm_page_lock_assert(m, MA_OWNED); 2466 if (m->cow) { 2467 m->cow--; 2468 /* 2469 * let vm_fault add back write permission lazily 2470 */ 2471 } 2472 /* 2473 * sf_buf_free() will free the page, so we needn't do it here 2474 */ 2475} 2476 2477int 2478vm_page_cowsetup(vm_page_t m) 2479{ 2480 2481 vm_page_lock_assert(m, MA_OWNED); 2482 if ((m->flags & (PG_FICTITIOUS | PG_UNMANAGED)) != 0 || 2483 m->cow == USHRT_MAX - 1 || !VM_OBJECT_TRYLOCK(m->object)) 2484 return (EBUSY); 2485 m->cow++; 2486 pmap_remove_write(m); 2487 VM_OBJECT_UNLOCK(m->object); 2488 return (0); 2489} 2490 2491#include "opt_ddb.h" 2492#ifdef DDB 2493#include <sys/kernel.h> 2494 2495#include <ddb/ddb.h> 2496 2497DB_SHOW_COMMAND(page, vm_page_print_page_info) 2498{ 2499 db_printf("cnt.v_free_count: %d\n", cnt.v_free_count); 2500 db_printf("cnt.v_cache_count: %d\n", cnt.v_cache_count); 2501 db_printf("cnt.v_inactive_count: %d\n", cnt.v_inactive_count); 2502 db_printf("cnt.v_active_count: %d\n", cnt.v_active_count); 2503 db_printf("cnt.v_wire_count: %d\n", cnt.v_wire_count); 2504 db_printf("cnt.v_free_reserved: %d\n", cnt.v_free_reserved); 2505 db_printf("cnt.v_free_min: %d\n", cnt.v_free_min); 2506 db_printf("cnt.v_free_target: %d\n", cnt.v_free_target); 2507 db_printf("cnt.v_cache_min: %d\n", cnt.v_cache_min); 2508 db_printf("cnt.v_inactive_target: %d\n", cnt.v_inactive_target); 2509} 2510 2511DB_SHOW_COMMAND(pageq, vm_page_print_pageq_info) 2512{ 2513 2514 db_printf("PQ_FREE:"); 2515 db_printf(" %d", cnt.v_free_count); 2516 db_printf("\n"); 2517 2518 db_printf("PQ_CACHE:"); 2519 db_printf(" %d", cnt.v_cache_count); 2520 db_printf("\n"); 2521 2522 db_printf("PQ_ACTIVE: %d, PQ_INACTIVE: %d\n", 2523 *vm_page_queues[PQ_ACTIVE].cnt, 2524 *vm_page_queues[PQ_INACTIVE].cnt); 2525} 2526#endif /* DDB */ 2527