4 * Copyright (c) 1991 Regents of the University of California.
7 * This code is derived from software contributed to Berkeley by
8 * The Mach Operating System project at Carnegie-Mellon University.
10 * Redistribution and use in source and binary forms, with or without
11 * modification, are permitted provided that the following conditions
13 * 1. Redistributions of source code must retain the above copyright
14 * notice, this list of conditions and the following disclaimer.
15 * 2. Redistributions in binary form must reproduce the above copyright
16 * notice, this list of conditions and the following disclaimer in the
17 * documentation and/or other materials provided with the distribution.
18 * 3. Neither the name of the University nor the names of its contributors
19 * may be used to endorse or promote products derived from this software
20 * without specific prior written permission.
22 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
23 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
24 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
25 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
26 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
27 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
28 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
29 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
30 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
31 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
34 * from: @(#)vm_page.c 7.4 (Berkeley) 5/7/91
35 * $FreeBSD: src/sys/vm/vm_page.c,v 1.147.2.18 2002/03/10 05:03:19 alc Exp $
39 * Copyright (c) 1987, 1990 Carnegie-Mellon University.
40 * All rights reserved.
42 * Authors: Avadis Tevanian, Jr., Michael Wayne Young
44 * Permission to use, copy, modify and distribute this software and
45 * its documentation is hereby granted, provided that both the copyright
46 * notice and this permission notice appear in all copies of the
47 * software, derivative works or modified versions, and any portions
48 * thereof, and that both notices appear in supporting documentation.
50 * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
51 * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
52 * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
54 * Carnegie Mellon requests users of this software to return to
56 * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
57 * School of Computer Science
58 * Carnegie Mellon University
59 * Pittsburgh PA 15213-3890
61 * any improvements or extensions that they make and grant Carnegie the
62 * rights to redistribute these changes.
65 * Resident memory management module. The module manipulates 'VM pages'.
66 * A VM page is the core building block for memory management.
69 #include <sys/param.h>
70 #include <sys/systm.h>
71 #include <sys/malloc.h>
73 #include <sys/vmmeter.h>
74 #include <sys/vnode.h>
75 #include <sys/kernel.h>
76 #include <sys/alist.h>
77 #include <sys/sysctl.h>
80 #include <vm/vm_param.h>
82 #include <vm/vm_kern.h>
84 #include <vm/vm_map.h>
85 #include <vm/vm_object.h>
86 #include <vm/vm_page.h>
87 #include <vm/vm_pageout.h>
88 #include <vm/vm_pager.h>
89 #include <vm/vm_extern.h>
90 #include <vm/swap_pager.h>
92 #include <machine/inttypes.h>
93 #include <machine/md_var.h>
94 #include <machine/specialreg.h>
96 #include <vm/vm_page2.h>
97 #include <sys/spinlock2.h>
99 #define VMACTION_HSIZE 256
100 #define VMACTION_HMASK (VMACTION_HSIZE - 1)
102 static void vm_page_queue_init(void);
103 static void vm_page_free_wakeup(void);
104 static vm_page_t vm_page_select_cache(u_short pg_color);
105 static vm_page_t _vm_page_list_find2(int basequeue, int index);
106 static void _vm_page_deactivate_locked(vm_page_t m, int athead);
109 * Array of tailq lists
111 __cachealign struct vpgqueues vm_page_queues[PQ_COUNT];
113 LIST_HEAD(vm_page_action_list, vm_page_action);
114 struct vm_page_action_list action_list[VMACTION_HSIZE];
115 static volatile int vm_pages_waiting;
117 static struct alist vm_contig_alist;
118 static struct almeta vm_contig_ameta[ALIST_RECORDS_65536];
119 static struct spinlock vm_contig_spin = SPINLOCK_INITIALIZER(&vm_contig_spin);
121 static u_long vm_dma_reserved = 0;
122 TUNABLE_ULONG("vm.dma_reserved", &vm_dma_reserved);
123 SYSCTL_ULONG(_vm, OID_AUTO, dma_reserved, CTLFLAG_RD, &vm_dma_reserved, 0,
124 "Memory reserved for DMA");
125 SYSCTL_UINT(_vm, OID_AUTO, dma_free_pages, CTLFLAG_RD,
126 &vm_contig_alist.bl_free, 0, "Memory reserved for DMA");
128 static int vm_contig_verbose = 0;
129 TUNABLE_INT("vm.contig_verbose", &vm_contig_verbose);
131 RB_GENERATE2(vm_page_rb_tree, vm_page, rb_entry, rb_vm_page_compare,
132 vm_pindex_t, pindex);
135 vm_page_queue_init(void)
139 for (i = 0; i < PQ_L2_SIZE; i++)
140 vm_page_queues[PQ_FREE+i].cnt = &vmstats.v_free_count;
141 for (i = 0; i < PQ_L2_SIZE; i++)
142 vm_page_queues[PQ_CACHE+i].cnt = &vmstats.v_cache_count;
143 for (i = 0; i < PQ_L2_SIZE; i++)
144 vm_page_queues[PQ_INACTIVE+i].cnt = &vmstats.v_inactive_count;
145 for (i = 0; i < PQ_L2_SIZE; i++)
146 vm_page_queues[PQ_ACTIVE+i].cnt = &vmstats.v_active_count;
147 for (i = 0; i < PQ_L2_SIZE; i++)
148 vm_page_queues[PQ_HOLD+i].cnt = &vmstats.v_active_count;
149 /* PQ_NONE has no queue */
151 for (i = 0; i < PQ_COUNT; i++) {
152 TAILQ_INIT(&vm_page_queues[i].pl);
153 spin_init(&vm_page_queues[i].spin);
156 for (i = 0; i < VMACTION_HSIZE; i++)
157 LIST_INIT(&action_list[i]);
161 * note: place in initialized data section? Is this necessary?
164 int vm_page_array_size = 0;
165 int vm_page_zero_count = 0;
166 vm_page_t vm_page_array = NULL;
167 vm_paddr_t vm_low_phys_reserved;
172 * Sets the page size, perhaps based upon the memory size.
173 * Must be called before any use of page-size dependent functions.
176 vm_set_page_size(void)
178 if (vmstats.v_page_size == 0)
179 vmstats.v_page_size = PAGE_SIZE;
180 if (((vmstats.v_page_size - 1) & vmstats.v_page_size) != 0)
181 panic("vm_set_page_size: page size not a power of two");
187 * Add a new page to the freelist for use by the system. New pages
188 * are added to both the head and tail of the associated free page
189 * queue in a bottom-up fashion, so both zero'd and non-zero'd page
190 * requests pull 'recent' adds (higher physical addresses) first.
192 * Beware that the page zeroing daemon will also be running soon after
193 * boot, moving pages from the head to the tail of the PQ_FREE queues.
195 * Must be called in a critical section.
198 vm_add_new_page(vm_paddr_t pa)
200 struct vpgqueues *vpq;
203 m = PHYS_TO_VM_PAGE(pa);
206 m->pc = (pa >> PAGE_SHIFT) & PQ_L2_MASK;
207 m->pat_mode = PAT_WRITE_BACK;
209 * Twist for cpu localization in addition to page coloring, so
210 * different cpus selecting by m->queue get different page colors.
212 m->pc ^= ((pa >> PAGE_SHIFT) / PQ_L2_SIZE) & PQ_L2_MASK;
213 m->pc ^= ((pa >> PAGE_SHIFT) / (PQ_L2_SIZE * PQ_L2_SIZE)) & PQ_L2_MASK;
215 * Reserve a certain number of contiguous low memory pages for
216 * contigmalloc() to use.
218 if (pa < vm_low_phys_reserved) {
219 atomic_add_int(&vmstats.v_page_count, 1);
220 atomic_add_int(&vmstats.v_dma_pages, 1);
223 atomic_add_int(&vmstats.v_wire_count, 1);
224 alist_free(&vm_contig_alist, pa >> PAGE_SHIFT, 1);
231 m->queue = m->pc + PQ_FREE;
232 KKASSERT(m->dirty == 0);
234 atomic_add_int(&vmstats.v_page_count, 1);
235 atomic_add_int(&vmstats.v_free_count, 1);
236 vpq = &vm_page_queues[m->queue];
237 if ((vpq->flipflop & 15) == 0) {
238 pmap_zero_page(VM_PAGE_TO_PHYS(m));
240 TAILQ_INSERT_TAIL(&vpq->pl, m, pageq);
241 atomic_add_int(&vm_page_zero_count, 1);
243 TAILQ_INSERT_HEAD(&vpq->pl, m, pageq);
252 * Initializes the resident memory module.
254 * Preallocates memory for critical VM structures and arrays prior to
255 * kernel_map becoming available.
257 * Memory is allocated from (virtual2_start, virtual2_end) if available,
258 * otherwise memory is allocated from (virtual_start, virtual_end).
260 * On x86-64 (virtual_start, virtual_end) is only 2GB and may not be
261 * large enough to hold vm_page_array & other structures for machines with
262 * large amounts of ram, so we want to use virtual2* when available.
265 vm_page_startup(void)
267 vm_offset_t vaddr = virtual2_start ? virtual2_start : virtual_start;
270 vm_paddr_t page_range;
277 vm_paddr_t biggestone, biggestsize;
284 vaddr = round_page(vaddr);
286 for (i = 0; phys_avail[i + 1]; i += 2) {
287 phys_avail[i] = round_page64(phys_avail[i]);
288 phys_avail[i + 1] = trunc_page64(phys_avail[i + 1]);
291 for (i = 0; phys_avail[i + 1]; i += 2) {
292 vm_paddr_t size = phys_avail[i + 1] - phys_avail[i];
294 if (size > biggestsize) {
302 end = phys_avail[biggestone+1];
303 end = trunc_page(end);
306 * Initialize the queue headers for the free queue, the active queue
307 * and the inactive queue.
309 vm_page_queue_init();
311 #if !defined(_KERNEL_VIRTUAL)
313 * VKERNELs don't support minidumps and as such don't need
316 * Allocate a bitmap to indicate that a random physical page
317 * needs to be included in a minidump.
319 * The amd64 port needs this to indicate which direct map pages
320 * need to be dumped, via calls to dump_add_page()/dump_drop_page().
322 * However, i386 still needs this workspace internally within the
323 * minidump code. In theory, they are not needed on i386, but are
324 * included should the sf_buf code decide to use them.
326 page_range = phys_avail[(nblocks - 1) * 2 + 1] / PAGE_SIZE;
327 vm_page_dump_size = round_page(roundup2(page_range, NBBY) / NBBY);
328 end -= vm_page_dump_size;
329 vm_page_dump = (void *)pmap_map(&vaddr, end, end + vm_page_dump_size,
330 VM_PROT_READ | VM_PROT_WRITE);
331 bzero((void *)vm_page_dump, vm_page_dump_size);
334 * Compute the number of pages of memory that will be available for
335 * use (taking into account the overhead of a page structure per
338 first_page = phys_avail[0] / PAGE_SIZE;
339 page_range = phys_avail[(nblocks - 1) * 2 + 1] / PAGE_SIZE - first_page;
340 npages = (total - (page_range * sizeof(struct vm_page))) / PAGE_SIZE;
342 #ifndef _KERNEL_VIRTUAL
344 * (only applies to real kernels)
346 * Initialize the contiguous reserve map. We initially reserve up
347 * to 1/4 available physical memory or 65536 pages (~256MB), whichever
350 * Once device initialization is complete we return most of the
351 * reserved memory back to the normal page queues but leave some
352 * in reserve for things like usb attachments.
354 vm_low_phys_reserved = (vm_paddr_t)65536 << PAGE_SHIFT;
355 if (vm_low_phys_reserved > total / 4)
356 vm_low_phys_reserved = total / 4;
357 if (vm_dma_reserved == 0) {
358 vm_dma_reserved = 16 * 1024 * 1024; /* 16MB */
359 if (vm_dma_reserved > total / 16)
360 vm_dma_reserved = total / 16;
363 alist_init(&vm_contig_alist, 65536, vm_contig_ameta,
364 ALIST_RECORDS_65536);
367 * Initialize the mem entry structures now, and put them in the free
370 new_end = trunc_page(end - page_range * sizeof(struct vm_page));
371 mapped = pmap_map(&vaddr, new_end, end, VM_PROT_READ | VM_PROT_WRITE);
372 vm_page_array = (vm_page_t)mapped;
374 #if defined(__x86_64__) && !defined(_KERNEL_VIRTUAL)
376 * since pmap_map on amd64 returns stuff out of a direct-map region,
377 * we have to manually add these pages to the minidump tracking so
378 * that they can be dumped, including the vm_page_array.
380 for (pa = new_end; pa < phys_avail[biggestone + 1]; pa += PAGE_SIZE)
385 * Clear all of the page structures
387 bzero((caddr_t) vm_page_array, page_range * sizeof(struct vm_page));
388 vm_page_array_size = page_range;
391 * Construct the free queue(s) in ascending order (by physical
392 * address) so that the first 16MB of physical memory is allocated
393 * last rather than first. On large-memory machines, this avoids
394 * the exhaustion of low physical memory before isa_dmainit has run.
396 vmstats.v_page_count = 0;
397 vmstats.v_free_count = 0;
398 for (i = 0; phys_avail[i + 1] && npages > 0; i += 2) {
403 last_pa = phys_avail[i + 1];
404 while (pa < last_pa && npages-- > 0) {
410 virtual2_start = vaddr;
412 virtual_start = vaddr;
416 * We tended to reserve a ton of memory for contigmalloc(). Now that most
417 * drivers have initialized we want to return most the remaining free
418 * reserve back to the VM page queues so they can be used for normal
421 * We leave vm_dma_reserved bytes worth of free pages in the reserve pool.
424 vm_page_startup_finish(void *dummy __unused)
433 spin_lock(&vm_contig_spin);
435 bfree = alist_free_info(&vm_contig_alist, &blk, &count);
436 if (bfree <= vm_dma_reserved / PAGE_SIZE)
442 * Figure out how much of the initial reserve we have to
443 * free in order to reach our target.
445 bfree -= vm_dma_reserved / PAGE_SIZE;
447 blk += count - bfree;
452 * Calculate the nearest power of 2 <= count.
454 for (xcount = 1; xcount <= count; xcount <<= 1)
457 blk += count - xcount;
461 * Allocate the pages from the alist, then free them to
462 * the normal VM page queues.
464 * Pages allocated from the alist are wired. We have to
465 * busy, unwire, and free them. We must also adjust
466 * vm_low_phys_reserved before freeing any pages to prevent
469 rblk = alist_alloc(&vm_contig_alist, blk, count);
471 kprintf("vm_page_startup_finish: Unable to return "
472 "dma space @0x%08x/%d -> 0x%08x\n",
476 atomic_add_int(&vmstats.v_dma_pages, -count);
477 spin_unlock(&vm_contig_spin);
479 m = PHYS_TO_VM_PAGE((vm_paddr_t)blk << PAGE_SHIFT);
480 vm_low_phys_reserved = VM_PAGE_TO_PHYS(m);
482 vm_page_busy_wait(m, FALSE, "cpgfr");
483 vm_page_unwire(m, 0);
488 spin_lock(&vm_contig_spin);
490 spin_unlock(&vm_contig_spin);
493 * Print out how much DMA space drivers have already allocated and
494 * how much is left over.
496 kprintf("DMA space used: %jdk, remaining available: %jdk\n",
497 (intmax_t)(vmstats.v_dma_pages - vm_contig_alist.bl_free) *
499 (intmax_t)vm_contig_alist.bl_free * (PAGE_SIZE / 1024));
501 SYSINIT(vm_pgend, SI_SUB_PROC0_POST, SI_ORDER_ANY,
502 vm_page_startup_finish, NULL)
506 * Scan comparison function for Red-Black tree scans. An inclusive
507 * (start,end) is expected. Other fields are not used.
510 rb_vm_page_scancmp(struct vm_page *p, void *data)
512 struct rb_vm_page_scan_info *info = data;
514 if (p->pindex < info->start_pindex)
516 if (p->pindex > info->end_pindex)
522 rb_vm_page_compare(struct vm_page *p1, struct vm_page *p2)
524 if (p1->pindex < p2->pindex)
526 if (p1->pindex > p2->pindex)
532 vm_page_init(vm_page_t m)
534 /* do nothing for now. Called from pmap_page_init() */
538 * Each page queue has its own spin lock, which is fairly optimal for
539 * allocating and freeing pages at least.
541 * The caller must hold the vm_page_spin_lock() before locking a vm_page's
542 * queue spinlock via this function. Also note that m->queue cannot change
543 * unless both the page and queue are locked.
547 _vm_page_queue_spin_lock(vm_page_t m)
552 if (queue != PQ_NONE) {
553 spin_lock(&vm_page_queues[queue].spin);
554 KKASSERT(queue == m->queue);
560 _vm_page_queue_spin_unlock(vm_page_t m)
566 if (queue != PQ_NONE)
567 spin_unlock(&vm_page_queues[queue].spin);
572 _vm_page_queues_spin_lock(u_short queue)
575 if (queue != PQ_NONE)
576 spin_lock(&vm_page_queues[queue].spin);
582 _vm_page_queues_spin_unlock(u_short queue)
585 if (queue != PQ_NONE)
586 spin_unlock(&vm_page_queues[queue].spin);
590 vm_page_queue_spin_lock(vm_page_t m)
592 _vm_page_queue_spin_lock(m);
596 vm_page_queues_spin_lock(u_short queue)
598 _vm_page_queues_spin_lock(queue);
602 vm_page_queue_spin_unlock(vm_page_t m)
604 _vm_page_queue_spin_unlock(m);
608 vm_page_queues_spin_unlock(u_short queue)
610 _vm_page_queues_spin_unlock(queue);
614 * This locks the specified vm_page and its queue in the proper order
615 * (page first, then queue). The queue may change so the caller must
620 _vm_page_and_queue_spin_lock(vm_page_t m)
622 vm_page_spin_lock(m);
623 _vm_page_queue_spin_lock(m);
628 _vm_page_and_queue_spin_unlock(vm_page_t m)
630 _vm_page_queues_spin_unlock(m->queue);
631 vm_page_spin_unlock(m);
635 vm_page_and_queue_spin_unlock(vm_page_t m)
637 _vm_page_and_queue_spin_unlock(m);
641 vm_page_and_queue_spin_lock(vm_page_t m)
643 _vm_page_and_queue_spin_lock(m);
647 * Helper function removes vm_page from its current queue.
648 * Returns the base queue the page used to be on.
650 * The vm_page and the queue must be spinlocked.
651 * This function will unlock the queue but leave the page spinlocked.
653 static __inline u_short
654 _vm_page_rem_queue_spinlocked(vm_page_t m)
656 struct vpgqueues *pq;
660 if (queue != PQ_NONE) {
661 pq = &vm_page_queues[queue];
662 TAILQ_REMOVE(&pq->pl, m, pageq);
663 atomic_add_int(pq->cnt, -1);
666 vm_page_queues_spin_unlock(queue);
667 if ((queue - m->pc) == PQ_FREE && (m->flags & PG_ZERO))
668 atomic_subtract_int(&vm_page_zero_count, 1);
669 if ((queue - m->pc) == PQ_CACHE || (queue - m->pc) == PQ_FREE)
670 return (queue - m->pc);
676 * Helper function places the vm_page on the specified queue.
678 * The vm_page must be spinlocked.
679 * This function will return with both the page and the queue locked.
682 _vm_page_add_queue_spinlocked(vm_page_t m, u_short queue, int athead)
684 struct vpgqueues *pq;
686 KKASSERT(m->queue == PQ_NONE);
688 if (queue != PQ_NONE) {
689 vm_page_queues_spin_lock(queue);
690 pq = &vm_page_queues[queue];
692 atomic_add_int(pq->cnt, 1);
696 * Put zero'd pages on the end ( where we look for zero'd pages
697 * first ) and non-zerod pages at the head.
699 if (queue - m->pc == PQ_FREE) {
700 if (m->flags & PG_ZERO) {
701 TAILQ_INSERT_TAIL(&pq->pl, m, pageq);
702 atomic_add_int(&vm_page_zero_count, 1);
704 TAILQ_INSERT_HEAD(&pq->pl, m, pageq);
707 TAILQ_INSERT_HEAD(&pq->pl, m, pageq);
709 TAILQ_INSERT_TAIL(&pq->pl, m, pageq);
711 /* leave the queue spinlocked */
716 * Wait until page is no longer PG_BUSY or (if also_m_busy is TRUE)
717 * m->busy is zero. Returns TRUE if it had to sleep, FALSE if we
718 * did not. Only one sleep call will be made before returning.
720 * This function does NOT busy the page and on return the page is not
721 * guaranteed to be available.
724 vm_page_sleep_busy(vm_page_t m, int also_m_busy, const char *msg)
732 if ((flags & PG_BUSY) == 0 &&
733 (also_m_busy == 0 || (flags & PG_SBUSY) == 0)) {
736 tsleep_interlock(m, 0);
737 if (atomic_cmpset_int(&m->flags, flags,
738 flags | PG_WANTED | PG_REFERENCED)) {
739 tsleep(m, PINTERLOCKED, msg, 0);
746 * Wait until PG_BUSY can be set, then set it. If also_m_busy is TRUE we
747 * also wait for m->busy to become 0 before setting PG_BUSY.
750 VM_PAGE_DEBUG_EXT(vm_page_busy_wait)(vm_page_t m,
751 int also_m_busy, const char *msg
759 if (flags & PG_BUSY) {
760 tsleep_interlock(m, 0);
761 if (atomic_cmpset_int(&m->flags, flags,
762 flags | PG_WANTED | PG_REFERENCED)) {
763 tsleep(m, PINTERLOCKED, msg, 0);
765 } else if (also_m_busy && (flags & PG_SBUSY)) {
766 tsleep_interlock(m, 0);
767 if (atomic_cmpset_int(&m->flags, flags,
768 flags | PG_WANTED | PG_REFERENCED)) {
769 tsleep(m, PINTERLOCKED, msg, 0);
772 if (atomic_cmpset_int(&m->flags, flags,
776 m->busy_line = lineno;
785 * Attempt to set PG_BUSY. If also_m_busy is TRUE we only succeed if m->busy
788 * Returns non-zero on failure.
791 VM_PAGE_DEBUG_EXT(vm_page_busy_try)(vm_page_t m, int also_m_busy
801 if (also_m_busy && (flags & PG_SBUSY))
803 if (atomic_cmpset_int(&m->flags, flags, flags | PG_BUSY)) {
806 m->busy_line = lineno;
814 * Clear the PG_BUSY flag and return non-zero to indicate to the caller
815 * that a wakeup() should be performed.
817 * The vm_page must be spinlocked and will remain spinlocked on return.
818 * The related queue must NOT be spinlocked (which could deadlock us).
824 _vm_page_wakeup(vm_page_t m)
831 if (atomic_cmpset_int(&m->flags, flags,
832 flags & ~(PG_BUSY | PG_WANTED))) {
836 return(flags & PG_WANTED);
840 * Clear the PG_BUSY flag and wakeup anyone waiting for the page. This
841 * is typically the last call you make on a page before moving onto
845 vm_page_wakeup(vm_page_t m)
847 KASSERT(m->flags & PG_BUSY, ("vm_page_wakeup: page not busy!!!"));
848 vm_page_spin_lock(m);
849 if (_vm_page_wakeup(m)) {
850 vm_page_spin_unlock(m);
853 vm_page_spin_unlock(m);
858 * Holding a page keeps it from being reused. Other parts of the system
859 * can still disassociate the page from its current object and free it, or
860 * perform read or write I/O on it and/or otherwise manipulate the page,
861 * but if the page is held the VM system will leave the page and its data
862 * intact and not reuse the page for other purposes until the last hold
863 * reference is released. (see vm_page_wire() if you want to prevent the
864 * page from being disassociated from its object too).
866 * The caller must still validate the contents of the page and, if necessary,
867 * wait for any pending I/O (e.g. vm_page_sleep_busy() loop) to complete
868 * before manipulating the page.
870 * XXX get vm_page_spin_lock() here and move FREE->HOLD if necessary
873 vm_page_hold(vm_page_t m)
875 vm_page_spin_lock(m);
876 atomic_add_int(&m->hold_count, 1);
877 if (m->queue - m->pc == PQ_FREE) {
878 _vm_page_queue_spin_lock(m);
879 _vm_page_rem_queue_spinlocked(m);
880 _vm_page_add_queue_spinlocked(m, PQ_HOLD + m->pc, 0);
881 _vm_page_queue_spin_unlock(m);
883 vm_page_spin_unlock(m);
887 * The opposite of vm_page_hold(). A page can be freed while being held,
888 * which places it on the PQ_HOLD queue. If we are able to busy the page
889 * after the hold count drops to zero we will move the page to the
890 * appropriate PQ_FREE queue by calling vm_page_free_toq().
893 vm_page_unhold(vm_page_t m)
895 vm_page_spin_lock(m);
896 atomic_add_int(&m->hold_count, -1);
897 if (m->hold_count == 0 && m->queue - m->pc == PQ_HOLD) {
898 _vm_page_queue_spin_lock(m);
899 _vm_page_rem_queue_spinlocked(m);
900 _vm_page_add_queue_spinlocked(m, PQ_FREE + m->pc, 0);
901 _vm_page_queue_spin_unlock(m);
903 vm_page_spin_unlock(m);
909 * Create a fictitious page with the specified physical address and
910 * memory attribute. The memory attribute is the only the machine-
911 * dependent aspect of a fictitious page that must be initialized.
915 vm_page_initfake(vm_page_t m, vm_paddr_t paddr, vm_memattr_t memattr)
918 if ((m->flags & PG_FICTITIOUS) != 0) {
920 * The page's memattr might have changed since the
921 * previous initialization. Update the pmap to the
926 m->phys_addr = paddr;
928 /* Fictitious pages don't use "segind". */
929 /* Fictitious pages don't use "order" or "pool". */
930 m->flags = PG_FICTITIOUS | PG_UNMANAGED | PG_BUSY;
934 pmap_page_set_memattr(m, memattr);
938 * Inserts the given vm_page into the object and object list.
940 * The pagetables are not updated but will presumably fault the page
941 * in if necessary, or if a kernel page the caller will at some point
942 * enter the page into the kernel's pmap. We are not allowed to block
943 * here so we *can't* do this anyway.
945 * This routine may not block.
946 * This routine must be called with the vm_object held.
947 * This routine must be called with a critical section held.
949 * This routine returns TRUE if the page was inserted into the object
950 * successfully, and FALSE if the page already exists in the object.
953 vm_page_insert(vm_page_t m, vm_object_t object, vm_pindex_t pindex)
955 ASSERT_LWKT_TOKEN_HELD_EXCL(vm_object_token(object));
956 if (m->object != NULL)
957 panic("vm_page_insert: already inserted");
959 object->generation++;
962 * Record the object/offset pair in this page and add the
963 * pv_list_count of the page to the object.
965 * The vm_page spin lock is required for interactions with the pmap.
967 vm_page_spin_lock(m);
970 if (vm_page_rb_tree_RB_INSERT(&object->rb_memq, m)) {
973 vm_page_spin_unlock(m);
976 ++object->resident_page_count;
977 ++mycpu->gd_vmtotal.t_rm;
978 /* atomic_add_int(&object->agg_pv_list_count, m->md.pv_list_count); */
979 vm_page_spin_unlock(m);
982 * Since we are inserting a new and possibly dirty page,
983 * update the object's OBJ_WRITEABLE and OBJ_MIGHTBEDIRTY flags.
985 if ((m->valid & m->dirty) ||
986 (m->flags & (PG_WRITEABLE | PG_NEED_COMMIT)))
987 vm_object_set_writeable_dirty(object);
990 * Checks for a swap assignment and sets PG_SWAPPED if appropriate.
992 swap_pager_page_inserted(m);
997 * Removes the given vm_page_t from the (object,index) table
999 * The underlying pmap entry (if any) is NOT removed here.
1000 * This routine may not block.
1002 * The page must be BUSY and will remain BUSY on return.
1003 * No other requirements.
1005 * NOTE: FreeBSD side effect was to unbusy the page on return. We leave
1009 vm_page_remove(vm_page_t m)
1013 if (m->object == NULL) {
1017 if ((m->flags & PG_BUSY) == 0)
1018 panic("vm_page_remove: page not busy");
1022 vm_object_hold(object);
1025 * Remove the page from the object and update the object.
1027 * The vm_page spin lock is required for interactions with the pmap.
1029 vm_page_spin_lock(m);
1030 vm_page_rb_tree_RB_REMOVE(&object->rb_memq, m);
1031 --object->resident_page_count;
1032 --mycpu->gd_vmtotal.t_rm;
1033 /* atomic_add_int(&object->agg_pv_list_count, -m->md.pv_list_count); */
1035 vm_page_spin_unlock(m);
1037 object->generation++;
1039 vm_object_drop(object);
1043 * Locate and return the page at (object, pindex), or NULL if the
1044 * page could not be found.
1046 * The caller must hold the vm_object token.
1049 vm_page_lookup(vm_object_t object, vm_pindex_t pindex)
1054 * Search the hash table for this object/offset pair
1056 ASSERT_LWKT_TOKEN_HELD(vm_object_token(object));
1057 m = vm_page_rb_tree_RB_LOOKUP(&object->rb_memq, pindex);
1058 KKASSERT(m == NULL || (m->object == object && m->pindex == pindex));
1063 VM_PAGE_DEBUG_EXT(vm_page_lookup_busy_wait)(struct vm_object *object,
1065 int also_m_busy, const char *msg
1071 ASSERT_LWKT_TOKEN_HELD(vm_object_token(object));
1072 m = vm_page_rb_tree_RB_LOOKUP(&object->rb_memq, pindex);
1074 KKASSERT(m->object == object && m->pindex == pindex);
1077 if (flags & PG_BUSY) {
1078 tsleep_interlock(m, 0);
1079 if (atomic_cmpset_int(&m->flags, flags,
1080 flags | PG_WANTED | PG_REFERENCED)) {
1081 tsleep(m, PINTERLOCKED, msg, 0);
1082 m = vm_page_rb_tree_RB_LOOKUP(&object->rb_memq,
1085 } else if (also_m_busy && (flags & PG_SBUSY)) {
1086 tsleep_interlock(m, 0);
1087 if (atomic_cmpset_int(&m->flags, flags,
1088 flags | PG_WANTED | PG_REFERENCED)) {
1089 tsleep(m, PINTERLOCKED, msg, 0);
1090 m = vm_page_rb_tree_RB_LOOKUP(&object->rb_memq,
1093 } else if (atomic_cmpset_int(&m->flags, flags,
1095 #ifdef VM_PAGE_DEBUG
1096 m->busy_func = func;
1097 m->busy_line = lineno;
1106 * Attempt to lookup and busy a page.
1108 * Returns NULL if the page could not be found
1110 * Returns a vm_page and error == TRUE if the page exists but could not
1113 * Returns a vm_page and error == FALSE on success.
1116 VM_PAGE_DEBUG_EXT(vm_page_lookup_busy_try)(struct vm_object *object,
1118 int also_m_busy, int *errorp
1124 ASSERT_LWKT_TOKEN_HELD(vm_object_token(object));
1125 m = vm_page_rb_tree_RB_LOOKUP(&object->rb_memq, pindex);
1128 KKASSERT(m->object == object && m->pindex == pindex);
1131 if (flags & PG_BUSY) {
1135 if (also_m_busy && (flags & PG_SBUSY)) {
1139 if (atomic_cmpset_int(&m->flags, flags, flags | PG_BUSY)) {
1140 #ifdef VM_PAGE_DEBUG
1141 m->busy_func = func;
1142 m->busy_line = lineno;
1151 * Caller must hold the related vm_object
1154 vm_page_next(vm_page_t m)
1158 next = vm_page_rb_tree_RB_NEXT(m);
1159 if (next && next->pindex != m->pindex + 1)
1167 * Move the given vm_page from its current object to the specified
1168 * target object/offset. The page must be busy and will remain so
1171 * new_object must be held.
1172 * This routine might block. XXX ?
1174 * NOTE: Swap associated with the page must be invalidated by the move. We
1175 * have to do this for several reasons: (1) we aren't freeing the
1176 * page, (2) we are dirtying the page, (3) the VM system is probably
1177 * moving the page from object A to B, and will then later move
1178 * the backing store from A to B and we can't have a conflict.
1180 * NOTE: We *always* dirty the page. It is necessary both for the
1181 * fact that we moved it, and because we may be invalidating
1182 * swap. If the page is on the cache, we have to deactivate it
1183 * or vm_page_dirty() will panic. Dirty pages are not allowed
1187 vm_page_rename(vm_page_t m, vm_object_t new_object, vm_pindex_t new_pindex)
1189 KKASSERT(m->flags & PG_BUSY);
1190 ASSERT_LWKT_TOKEN_HELD_EXCL(vm_object_token(new_object));
1192 ASSERT_LWKT_TOKEN_HELD_EXCL(vm_object_token(m->object));
1195 if (vm_page_insert(m, new_object, new_pindex) == FALSE) {
1196 panic("vm_page_rename: target exists (%p,%"PRIu64")",
1197 new_object, new_pindex);
1199 if (m->queue - m->pc == PQ_CACHE)
1200 vm_page_deactivate(m);
1205 * vm_page_unqueue() without any wakeup. This routine is used when a page
1206 * is being moved between queues or otherwise is to remain BUSYied by the
1209 * This routine may not block.
1212 vm_page_unqueue_nowakeup(vm_page_t m)
1214 vm_page_and_queue_spin_lock(m);
1215 (void)_vm_page_rem_queue_spinlocked(m);
1216 vm_page_spin_unlock(m);
1220 * vm_page_unqueue() - Remove a page from its queue, wakeup the pagedemon
1223 * This routine may not block.
1226 vm_page_unqueue(vm_page_t m)
1230 vm_page_and_queue_spin_lock(m);
1231 queue = _vm_page_rem_queue_spinlocked(m);
1232 if (queue == PQ_FREE || queue == PQ_CACHE) {
1233 vm_page_spin_unlock(m);
1234 pagedaemon_wakeup();
1236 vm_page_spin_unlock(m);
1241 * vm_page_list_find()
1243 * Find a page on the specified queue with color optimization.
1245 * The page coloring optimization attempts to locate a page that does
1246 * not overload other nearby pages in the object in the cpu's L1 or L2
1247 * caches. We need this optimization because cpu caches tend to be
1248 * physical caches, while object spaces tend to be virtual.
1250 * On MP systems each PQ_FREE and PQ_CACHE color queue has its own spinlock
1251 * and the algorithm is adjusted to localize allocations on a per-core basis.
1252 * This is done by 'twisting' the colors.
1254 * The page is returned spinlocked and removed from its queue (it will
1255 * be on PQ_NONE), or NULL. The page is not PG_BUSY'd. The caller
1256 * is responsible for dealing with the busy-page case (usually by
1257 * deactivating the page and looping).
1259 * NOTE: This routine is carefully inlined. A non-inlined version
1260 * is available for outside callers but the only critical path is
1261 * from within this source file.
1263 * NOTE: This routine assumes that the vm_pages found in PQ_CACHE and PQ_FREE
1264 * represent stable storage, allowing us to order our locks vm_page
1265 * first, then queue.
1269 _vm_page_list_find(int basequeue, int index, boolean_t prefer_zero)
1275 m = TAILQ_LAST(&vm_page_queues[basequeue+index].pl, pglist);
1277 m = TAILQ_FIRST(&vm_page_queues[basequeue+index].pl);
1279 m = _vm_page_list_find2(basequeue, index);
1282 vm_page_and_queue_spin_lock(m);
1283 if (m->queue == basequeue + index) {
1284 _vm_page_rem_queue_spinlocked(m);
1285 /* vm_page_t spin held, no queue spin */
1288 vm_page_and_queue_spin_unlock(m);
1294 _vm_page_list_find2(int basequeue, int index)
1298 struct vpgqueues *pq;
1300 pq = &vm_page_queues[basequeue];
1303 * Note that for the first loop, index+i and index-i wind up at the
1304 * same place. Even though this is not totally optimal, we've already
1305 * blown it by missing the cache case so we do not care.
1307 for (i = PQ_L2_SIZE / 2; i > 0; --i) {
1309 m = TAILQ_FIRST(&pq[(index + i) & PQ_L2_MASK].pl);
1311 _vm_page_and_queue_spin_lock(m);
1313 basequeue + ((index + i) & PQ_L2_MASK)) {
1314 _vm_page_rem_queue_spinlocked(m);
1317 _vm_page_and_queue_spin_unlock(m);
1320 m = TAILQ_FIRST(&pq[(index - i) & PQ_L2_MASK].pl);
1322 _vm_page_and_queue_spin_lock(m);
1324 basequeue + ((index - i) & PQ_L2_MASK)) {
1325 _vm_page_rem_queue_spinlocked(m);
1328 _vm_page_and_queue_spin_unlock(m);
1338 * Returns a vm_page candidate for allocation. The page is not busied so
1339 * it can move around. The caller must busy the page (and typically
1340 * deactivate it if it cannot be busied!)
1342 * Returns a spinlocked vm_page that has been removed from its queue.
1345 vm_page_list_find(int basequeue, int index, boolean_t prefer_zero)
1347 return(_vm_page_list_find(basequeue, index, prefer_zero));
1351 * Find a page on the cache queue with color optimization, remove it
1352 * from the queue, and busy it. The returned page will not be spinlocked.
1354 * A candidate failure will be deactivated. Candidates can fail due to
1355 * being busied by someone else, in which case they will be deactivated.
1357 * This routine may not block.
1361 vm_page_select_cache(u_short pg_color)
1366 m = _vm_page_list_find(PQ_CACHE, pg_color & PQ_L2_MASK, FALSE);
1370 * (m) has been removed from its queue and spinlocked
1372 if (vm_page_busy_try(m, TRUE)) {
1373 _vm_page_deactivate_locked(m, 0);
1374 vm_page_spin_unlock(m);
1377 * We successfully busied the page
1379 if ((m->flags & (PG_UNMANAGED | PG_NEED_COMMIT)) == 0 &&
1380 m->hold_count == 0 &&
1381 m->wire_count == 0 &&
1382 (m->dirty & m->valid) == 0) {
1383 vm_page_spin_unlock(m);
1384 pagedaemon_wakeup();
1389 * The page cannot be recycled, deactivate it.
1391 _vm_page_deactivate_locked(m, 0);
1392 if (_vm_page_wakeup(m)) {
1393 vm_page_spin_unlock(m);
1396 vm_page_spin_unlock(m);
1404 * Find a free or zero page, with specified preference. We attempt to
1405 * inline the nominal case and fall back to _vm_page_select_free()
1406 * otherwise. A busied page is removed from the queue and returned.
1408 * This routine may not block.
1410 static __inline vm_page_t
1411 vm_page_select_free(u_short pg_color, boolean_t prefer_zero)
1416 m = _vm_page_list_find(PQ_FREE, pg_color & PQ_L2_MASK,
1420 if (vm_page_busy_try(m, TRUE)) {
1422 * Various mechanisms such as a pmap_collect can
1423 * result in a busy page on the free queue. We
1424 * have to move the page out of the way so we can
1425 * retry the allocation. If the other thread is not
1426 * allocating the page then m->valid will remain 0 and
1427 * the pageout daemon will free the page later on.
1429 * Since we could not busy the page, however, we
1430 * cannot make assumptions as to whether the page
1431 * will be allocated by the other thread or not,
1432 * so all we can do is deactivate it to move it out
1433 * of the way. In particular, if the other thread
1434 * wires the page it may wind up on the inactive
1435 * queue and the pageout daemon will have to deal
1436 * with that case too.
1438 _vm_page_deactivate_locked(m, 0);
1439 vm_page_spin_unlock(m);
1442 * Theoretically if we are able to busy the page
1443 * atomic with the queue removal (using the vm_page
1444 * lock) nobody else should be able to mess with the
1447 KKASSERT((m->flags & (PG_UNMANAGED |
1448 PG_NEED_COMMIT)) == 0);
1449 KKASSERT(m->hold_count == 0);
1450 KKASSERT(m->wire_count == 0);
1451 vm_page_spin_unlock(m);
1452 pagedaemon_wakeup();
1454 /* return busied and removed page */
1462 * This implements a per-cpu cache of free, zero'd, ready-to-go pages.
1463 * The idea is to populate this cache prior to acquiring any locks so
1464 * we don't wind up potentially zeroing VM pages (under heavy loads) while
1465 * holding potentialy contending locks.
1467 * Note that we allocate the page uninserted into anything and use a pindex
1468 * of 0, the vm_page_alloc() will effectively add gd_cpuid so these
1469 * allocations should wind up being uncontended. However, we still want
1470 * to rove across PQ_L2_SIZE.
1473 vm_page_pcpu_cache(void)
1476 globaldata_t gd = mycpu;
1479 if (gd->gd_vmpg_count < GD_MINVMPG) {
1481 while (gd->gd_vmpg_count < GD_MAXVMPG) {
1482 m = vm_page_alloc(NULL, ticks & ~ncpus2_mask,
1483 VM_ALLOC_NULL_OK | VM_ALLOC_NORMAL |
1484 VM_ALLOC_NULL_OK | VM_ALLOC_ZERO);
1485 if (gd->gd_vmpg_count < GD_MAXVMPG) {
1486 if ((m->flags & PG_ZERO) == 0) {
1487 pmap_zero_page(VM_PAGE_TO_PHYS(m));
1488 vm_page_flag_set(m, PG_ZERO);
1490 gd->gd_vmpg_array[gd->gd_vmpg_count++] = m;
1503 * Allocate and return a memory cell associated with this VM object/offset
1504 * pair. If object is NULL an unassociated page will be allocated.
1506 * The returned page will be busied and removed from its queues. This
1507 * routine can block and may return NULL if a race occurs and the page
1508 * is found to already exist at the specified (object, pindex).
1510 * VM_ALLOC_NORMAL allow use of cache pages, nominal free drain
1511 * VM_ALLOC_QUICK like normal but cannot use cache
1512 * VM_ALLOC_SYSTEM greater free drain
1513 * VM_ALLOC_INTERRUPT allow free list to be completely drained
1514 * VM_ALLOC_ZERO advisory request for pre-zero'd page only
1515 * VM_ALLOC_FORCE_ZERO advisory request for pre-zero'd page only
1516 * VM_ALLOC_NULL_OK ok to return NULL on insertion collision
1517 * (see vm_page_grab())
1518 * VM_ALLOC_USE_GD ok to use per-gd cache
1520 * The object must be held if not NULL
1521 * This routine may not block
1523 * Additional special handling is required when called from an interrupt
1524 * (VM_ALLOC_INTERRUPT). We are not allowed to mess with the page cache
1528 vm_page_alloc(vm_object_t object, vm_pindex_t pindex, int page_req)
1530 globaldata_t gd = mycpu;
1537 * Special per-cpu free VM page cache. The pages are pre-busied
1538 * and pre-zerod for us.
1540 if (gd->gd_vmpg_count && (page_req & VM_ALLOC_USE_GD)) {
1542 if (gd->gd_vmpg_count) {
1543 m = gd->gd_vmpg_array[--gd->gd_vmpg_count];
1553 * Cpu twist - cpu localization algorithm
1556 pg_color = gd->gd_cpuid + (pindex & ~ncpus_fit_mask) +
1557 (object->pg_color & ~ncpus_fit_mask);
1559 pg_color = gd->gd_cpuid + (pindex & ~ncpus_fit_mask);
1562 (VM_ALLOC_NORMAL|VM_ALLOC_QUICK|
1563 VM_ALLOC_INTERRUPT|VM_ALLOC_SYSTEM));
1566 * Certain system threads (pageout daemon, buf_daemon's) are
1567 * allowed to eat deeper into the free page list.
1569 if (curthread->td_flags & TDF_SYSTHREAD)
1570 page_req |= VM_ALLOC_SYSTEM;
1573 if (vmstats.v_free_count > vmstats.v_free_reserved ||
1574 ((page_req & VM_ALLOC_INTERRUPT) && vmstats.v_free_count > 0) ||
1575 ((page_req & VM_ALLOC_SYSTEM) && vmstats.v_cache_count == 0 &&
1576 vmstats.v_free_count > vmstats.v_interrupt_free_min)
1579 * The free queue has sufficient free pages to take one out.
1581 if (page_req & (VM_ALLOC_ZERO | VM_ALLOC_FORCE_ZERO))
1582 m = vm_page_select_free(pg_color, TRUE);
1584 m = vm_page_select_free(pg_color, FALSE);
1585 } else if (page_req & VM_ALLOC_NORMAL) {
1587 * Allocatable from the cache (non-interrupt only). On
1588 * success, we must free the page and try again, thus
1589 * ensuring that vmstats.v_*_free_min counters are replenished.
1592 if (curthread->td_preempted) {
1593 kprintf("vm_page_alloc(): warning, attempt to allocate"
1594 " cache page from preempting interrupt\n");
1597 m = vm_page_select_cache(pg_color);
1600 m = vm_page_select_cache(pg_color);
1603 * On success move the page into the free queue and loop.
1605 * Only do this if we can safely acquire the vm_object lock,
1606 * because this is effectively a random page and the caller
1607 * might be holding the lock shared, we don't want to
1611 KASSERT(m->dirty == 0,
1612 ("Found dirty cache page %p", m));
1613 if ((obj = m->object) != NULL) {
1614 if (vm_object_hold_try(obj)) {
1615 vm_page_protect(m, VM_PROT_NONE);
1617 /* m->object NULL here */
1618 vm_object_drop(obj);
1620 vm_page_deactivate(m);
1624 vm_page_protect(m, VM_PROT_NONE);
1631 * On failure return NULL
1633 #if defined(DIAGNOSTIC)
1634 if (vmstats.v_cache_count > 0)
1635 kprintf("vm_page_alloc(NORMAL): missing pages on cache queue: %d\n", vmstats.v_cache_count);
1637 vm_pageout_deficit++;
1638 pagedaemon_wakeup();
1642 * No pages available, wakeup the pageout daemon and give up.
1644 vm_pageout_deficit++;
1645 pagedaemon_wakeup();
1650 * v_free_count can race so loop if we don't find the expected
1657 * Good page found. The page has already been busied for us and
1658 * removed from its queues.
1660 KASSERT(m->dirty == 0,
1661 ("vm_page_alloc: free/cache page %p was dirty", m));
1662 KKASSERT(m->queue == PQ_NONE);
1668 * Initialize the structure, inheriting some flags but clearing
1669 * all the rest. The page has already been busied for us.
1671 vm_page_flag_clear(m, ~(PG_ZERO | PG_BUSY | PG_SBUSY));
1672 KKASSERT(m->wire_count == 0);
1673 KKASSERT(m->busy == 0);
1678 * Caller must be holding the object lock (asserted by
1679 * vm_page_insert()).
1681 * NOTE: Inserting a page here does not insert it into any pmaps
1682 * (which could cause us to block allocating memory).
1684 * NOTE: If no object an unassociated page is allocated, m->pindex
1685 * can be used by the caller for any purpose.
1688 if (vm_page_insert(m, object, pindex) == FALSE) {
1690 if ((page_req & VM_ALLOC_NULL_OK) == 0)
1691 panic("PAGE RACE %p[%ld]/%p",
1692 object, (long)pindex, m);
1700 * Don't wakeup too often - wakeup the pageout daemon when
1701 * we would be nearly out of memory.
1703 pagedaemon_wakeup();
1706 * A PG_BUSY page is returned.
1712 * Attempt to allocate contiguous physical memory with the specified
1716 vm_page_alloc_contig(vm_paddr_t low, vm_paddr_t high,
1717 unsigned long alignment, unsigned long boundary,
1718 unsigned long size, vm_memattr_t memattr)
1724 alignment >>= PAGE_SHIFT;
1727 boundary >>= PAGE_SHIFT;
1730 size = (size + PAGE_MASK) >> PAGE_SHIFT;
1732 spin_lock(&vm_contig_spin);
1733 blk = alist_alloc(&vm_contig_alist, 0, size);
1734 if (blk == ALIST_BLOCK_NONE) {
1735 spin_unlock(&vm_contig_spin);
1737 kprintf("vm_page_alloc_contig: %ldk nospace\n",
1738 (size + PAGE_MASK) * (PAGE_SIZE / 1024));
1742 if (high && ((vm_paddr_t)(blk + size) << PAGE_SHIFT) > high) {
1743 alist_free(&vm_contig_alist, blk, size);
1744 spin_unlock(&vm_contig_spin);
1746 kprintf("vm_page_alloc_contig: %ldk high "
1748 (size + PAGE_MASK) * (PAGE_SIZE / 1024),
1753 spin_unlock(&vm_contig_spin);
1754 if (vm_contig_verbose) {
1755 kprintf("vm_page_alloc_contig: %016jx/%ldk\n",
1756 (intmax_t)(vm_paddr_t)blk << PAGE_SHIFT,
1757 (size + PAGE_MASK) * (PAGE_SIZE / 1024));
1760 m = PHYS_TO_VM_PAGE((vm_paddr_t)blk << PAGE_SHIFT);
1761 if (memattr != VM_MEMATTR_DEFAULT)
1762 for (i = 0;i < size;i++)
1763 pmap_page_set_memattr(&m[i], memattr);
1768 * Free contiguously allocated pages. The pages will be wired but not busy.
1769 * When freeing to the alist we leave them wired and not busy.
1772 vm_page_free_contig(vm_page_t m, unsigned long size)
1774 vm_paddr_t pa = VM_PAGE_TO_PHYS(m);
1775 vm_pindex_t start = pa >> PAGE_SHIFT;
1776 vm_pindex_t pages = (size + PAGE_MASK) >> PAGE_SHIFT;
1778 if (vm_contig_verbose) {
1779 kprintf("vm_page_free_contig: %016jx/%ldk\n",
1780 (intmax_t)pa, size / 1024);
1782 if (pa < vm_low_phys_reserved) {
1783 KKASSERT(pa + size <= vm_low_phys_reserved);
1784 spin_lock(&vm_contig_spin);
1785 alist_free(&vm_contig_alist, start, pages);
1786 spin_unlock(&vm_contig_spin);
1789 vm_page_busy_wait(m, FALSE, "cpgfr");
1790 vm_page_unwire(m, 0);
1801 * Wait for sufficient free memory for nominal heavy memory use kernel
1804 * WARNING! Be sure never to call this in any vm_pageout code path, which
1805 * will trivially deadlock the system.
1808 vm_wait_nominal(void)
1810 while (vm_page_count_min(0))
1815 * Test if vm_wait_nominal() would block.
1818 vm_test_nominal(void)
1820 if (vm_page_count_min(0))
1826 * Block until free pages are available for allocation, called in various
1827 * places before memory allocations.
1829 * The caller may loop if vm_page_count_min() == FALSE so we cannot be
1830 * more generous then that.
1836 * never wait forever
1840 lwkt_gettoken(&vm_token);
1842 if (curthread == pagethread) {
1844 * The pageout daemon itself needs pages, this is bad.
1846 if (vm_page_count_min(0)) {
1847 vm_pageout_pages_needed = 1;
1848 tsleep(&vm_pageout_pages_needed, 0, "VMWait", timo);
1852 * Wakeup the pageout daemon if necessary and wait.
1854 * Do not wait indefinitely for the target to be reached,
1855 * as load might prevent it from being reached any time soon.
1856 * But wait a little to try to slow down page allocations
1857 * and to give more important threads (the pagedaemon)
1858 * allocation priority.
1860 if (vm_page_count_target()) {
1861 if (vm_pages_needed == 0) {
1862 vm_pages_needed = 1;
1863 wakeup(&vm_pages_needed);
1865 ++vm_pages_waiting; /* SMP race ok */
1866 tsleep(&vmstats.v_free_count, 0, "vmwait", timo);
1869 lwkt_reltoken(&vm_token);
1873 * Block until free pages are available for allocation
1875 * Called only from vm_fault so that processes page faulting can be
1879 vm_wait_pfault(void)
1882 * Wakeup the pageout daemon if necessary and wait.
1884 * Do not wait indefinitely for the target to be reached,
1885 * as load might prevent it from being reached any time soon.
1886 * But wait a little to try to slow down page allocations
1887 * and to give more important threads (the pagedaemon)
1888 * allocation priority.
1890 if (vm_page_count_min(0)) {
1891 lwkt_gettoken(&vm_token);
1892 while (vm_page_count_severe()) {
1893 if (vm_page_count_target()) {
1894 if (vm_pages_needed == 0) {
1895 vm_pages_needed = 1;
1896 wakeup(&vm_pages_needed);
1898 ++vm_pages_waiting; /* SMP race ok */
1899 tsleep(&vmstats.v_free_count, 0, "pfault", hz);
1902 lwkt_reltoken(&vm_token);
1907 * Put the specified page on the active list (if appropriate). Ensure
1908 * that act_count is at least ACT_INIT but do not otherwise mess with it.
1910 * The caller should be holding the page busied ? XXX
1911 * This routine may not block.
1914 vm_page_activate(vm_page_t m)
1918 vm_page_spin_lock(m);
1919 if (m->queue - m->pc != PQ_ACTIVE) {
1920 _vm_page_queue_spin_lock(m);
1921 oqueue = _vm_page_rem_queue_spinlocked(m);
1922 /* page is left spinlocked, queue is unlocked */
1924 if (oqueue == PQ_CACHE)
1925 mycpu->gd_cnt.v_reactivated++;
1926 if (m->wire_count == 0 && (m->flags & PG_UNMANAGED) == 0) {
1927 if (m->act_count < ACT_INIT)
1928 m->act_count = ACT_INIT;
1929 _vm_page_add_queue_spinlocked(m, PQ_ACTIVE + m->pc, 0);
1931 _vm_page_and_queue_spin_unlock(m);
1932 if (oqueue == PQ_CACHE || oqueue == PQ_FREE)
1933 pagedaemon_wakeup();
1935 if (m->act_count < ACT_INIT)
1936 m->act_count = ACT_INIT;
1937 vm_page_spin_unlock(m);
1942 * Helper routine for vm_page_free_toq() and vm_page_cache(). This
1943 * routine is called when a page has been added to the cache or free
1946 * This routine may not block.
1948 static __inline void
1949 vm_page_free_wakeup(void)
1952 * If the pageout daemon itself needs pages, then tell it that
1953 * there are some free.
1955 if (vm_pageout_pages_needed &&
1956 vmstats.v_cache_count + vmstats.v_free_count >=
1957 vmstats.v_pageout_free_min
1959 vm_pageout_pages_needed = 0;
1960 wakeup(&vm_pageout_pages_needed);
1964 * Wakeup processes that are waiting on memory.
1966 * Generally speaking we want to wakeup stuck processes as soon as
1967 * possible. !vm_page_count_min(0) is the absolute minimum point
1968 * where we can do this. Wait a bit longer to reduce degenerate
1969 * re-blocking (vm_page_free_hysteresis). The target check is just
1970 * to make sure the min-check w/hysteresis does not exceed the
1973 if (vm_pages_waiting) {
1974 if (!vm_page_count_min(vm_page_free_hysteresis) ||
1975 !vm_page_count_target()) {
1976 vm_pages_waiting = 0;
1977 wakeup(&vmstats.v_free_count);
1978 ++mycpu->gd_cnt.v_ppwakeups;
1981 if (!vm_page_count_target()) {
1983 * Plenty of pages are free, wakeup everyone.
1985 vm_pages_waiting = 0;
1986 wakeup(&vmstats.v_free_count);
1987 ++mycpu->gd_cnt.v_ppwakeups;
1988 } else if (!vm_page_count_min(0)) {
1990 * Some pages are free, wakeup someone.
1992 int wcount = vm_pages_waiting;
1995 vm_pages_waiting = wcount;
1996 wakeup_one(&vmstats.v_free_count);
1997 ++mycpu->gd_cnt.v_ppwakeups;
2004 * Returns the given page to the PQ_FREE or PQ_HOLD list and disassociates
2005 * it from its VM object.
2007 * The vm_page must be PG_BUSY on entry. PG_BUSY will be released on
2008 * return (the page will have been freed).
2011 vm_page_free_toq(vm_page_t m)
2013 mycpu->gd_cnt.v_tfree++;
2014 KKASSERT((m->flags & PG_MAPPED) == 0);
2015 KKASSERT(m->flags & PG_BUSY);
2017 if (m->busy || ((m->queue - m->pc) == PQ_FREE)) {
2018 kprintf("vm_page_free: pindex(%lu), busy(%d), "
2019 "PG_BUSY(%d), hold(%d)\n",
2020 (u_long)m->pindex, m->busy,
2021 ((m->flags & PG_BUSY) ? 1 : 0), m->hold_count);
2022 if ((m->queue - m->pc) == PQ_FREE)
2023 panic("vm_page_free: freeing free page");
2025 panic("vm_page_free: freeing busy page");
2029 * Remove from object, spinlock the page and its queues and
2030 * remove from any queue. No queue spinlock will be held
2031 * after this section (because the page was removed from any
2035 vm_page_and_queue_spin_lock(m);
2036 _vm_page_rem_queue_spinlocked(m);
2039 * No further management of fictitious pages occurs beyond object
2040 * and queue removal.
2042 if ((m->flags & PG_FICTITIOUS) != 0) {
2043 vm_page_spin_unlock(m);
2051 if (m->wire_count != 0) {
2052 if (m->wire_count > 1) {
2054 "vm_page_free: invalid wire count (%d), pindex: 0x%lx",
2055 m->wire_count, (long)m->pindex);
2057 panic("vm_page_free: freeing wired page");
2061 * Clear the UNMANAGED flag when freeing an unmanaged page.
2062 * Clear the NEED_COMMIT flag
2064 if (m->flags & PG_UNMANAGED)
2065 vm_page_flag_clear(m, PG_UNMANAGED);
2066 if (m->flags & PG_NEED_COMMIT)
2067 vm_page_flag_clear(m, PG_NEED_COMMIT);
2069 if (m->hold_count != 0) {
2070 vm_page_flag_clear(m, PG_ZERO);
2071 _vm_page_add_queue_spinlocked(m, PQ_HOLD + m->pc, 0);
2073 _vm_page_add_queue_spinlocked(m, PQ_FREE + m->pc, 0);
2077 * This sequence allows us to clear PG_BUSY while still holding
2078 * its spin lock, which reduces contention vs allocators. We
2079 * must not leave the queue locked or _vm_page_wakeup() may
2082 _vm_page_queue_spin_unlock(m);
2083 if (_vm_page_wakeup(m)) {
2084 vm_page_spin_unlock(m);
2087 vm_page_spin_unlock(m);
2089 vm_page_free_wakeup();
2093 * vm_page_free_fromq_fast()
2095 * Remove a non-zero page from one of the free queues; the page is removed for
2096 * zeroing, so do not issue a wakeup.
2099 vm_page_free_fromq_fast(void)
2105 for (i = 0; i < PQ_L2_SIZE; ++i) {
2106 m = vm_page_list_find(PQ_FREE, qi, FALSE);
2107 /* page is returned spinlocked and removed from its queue */
2109 if (vm_page_busy_try(m, TRUE)) {
2111 * We were unable to busy the page, deactivate
2114 _vm_page_deactivate_locked(m, 0);
2115 vm_page_spin_unlock(m);
2116 } else if (m->flags & PG_ZERO) {
2118 * The page is PG_ZERO, requeue it and loop
2120 _vm_page_add_queue_spinlocked(m,
2123 vm_page_queue_spin_unlock(m);
2124 if (_vm_page_wakeup(m)) {
2125 vm_page_spin_unlock(m);
2128 vm_page_spin_unlock(m);
2132 * The page is not PG_ZERO'd so return it.
2134 vm_page_spin_unlock(m);
2135 KKASSERT((m->flags & (PG_UNMANAGED |
2136 PG_NEED_COMMIT)) == 0);
2137 KKASSERT(m->hold_count == 0);
2138 KKASSERT(m->wire_count == 0);
2143 qi = (qi + PQ_PRIME2) & PQ_L2_MASK;
2149 * vm_page_unmanage()
2151 * Prevent PV management from being done on the page. The page is
2152 * removed from the paging queues as if it were wired, and as a
2153 * consequence of no longer being managed the pageout daemon will not
2154 * touch it (since there is no way to locate the pte mappings for the
2155 * page). madvise() calls that mess with the pmap will also no longer
2156 * operate on the page.
2158 * Beyond that the page is still reasonably 'normal'. Freeing the page
2159 * will clear the flag.
2161 * This routine is used by OBJT_PHYS objects - objects using unswappable
2162 * physical memory as backing store rather then swap-backed memory and
2163 * will eventually be extended to support 4MB unmanaged physical
2166 * Caller must be holding the page busy.
2169 vm_page_unmanage(vm_page_t m)
2171 KKASSERT(m->flags & PG_BUSY);
2172 if ((m->flags & PG_UNMANAGED) == 0) {
2173 if (m->wire_count == 0)
2176 vm_page_flag_set(m, PG_UNMANAGED);
2180 * Mark this page as wired down by yet another map, removing it from
2181 * paging queues as necessary.
2183 * Caller must be holding the page busy.
2186 vm_page_wire(vm_page_t m)
2189 * Only bump the wire statistics if the page is not already wired,
2190 * and only unqueue the page if it is on some queue (if it is unmanaged
2191 * it is already off the queues). Don't do anything with fictitious
2192 * pages because they are always wired.
2194 KKASSERT(m->flags & PG_BUSY);
2195 if ((m->flags & PG_FICTITIOUS) == 0) {
2196 if (atomic_fetchadd_int(&m->wire_count, 1) == 0) {
2197 if ((m->flags & PG_UNMANAGED) == 0)
2199 atomic_add_int(&vmstats.v_wire_count, 1);
2201 KASSERT(m->wire_count != 0,
2202 ("vm_page_wire: wire_count overflow m=%p", m));
2207 * Release one wiring of this page, potentially enabling it to be paged again.
2209 * Many pages placed on the inactive queue should actually go
2210 * into the cache, but it is difficult to figure out which. What
2211 * we do instead, if the inactive target is well met, is to put
2212 * clean pages at the head of the inactive queue instead of the tail.
2213 * This will cause them to be moved to the cache more quickly and
2214 * if not actively re-referenced, freed more quickly. If we just
2215 * stick these pages at the end of the inactive queue, heavy filesystem
2216 * meta-data accesses can cause an unnecessary paging load on memory bound
2217 * processes. This optimization causes one-time-use metadata to be
2218 * reused more quickly.
2220 * Pages marked PG_NEED_COMMIT are always activated and never placed on
2221 * the inactive queue. This helps the pageout daemon determine memory
2222 * pressure and act on out-of-memory situations more quickly.
2224 * BUT, if we are in a low-memory situation we have no choice but to
2225 * put clean pages on the cache queue.
2227 * A number of routines use vm_page_unwire() to guarantee that the page
2228 * will go into either the inactive or active queues, and will NEVER
2229 * be placed in the cache - for example, just after dirtying a page.
2230 * dirty pages in the cache are not allowed.
2232 * This routine may not block.
2235 vm_page_unwire(vm_page_t m, int activate)
2237 KKASSERT(m->flags & PG_BUSY);
2238 if (m->flags & PG_FICTITIOUS) {
2240 } else if (m->wire_count <= 0) {
2241 panic("vm_page_unwire: invalid wire count: %d", m->wire_count);
2243 if (atomic_fetchadd_int(&m->wire_count, -1) == 1) {
2244 atomic_add_int(&vmstats.v_wire_count, -1);
2245 if (m->flags & PG_UNMANAGED) {
2247 } else if (activate || (m->flags & PG_NEED_COMMIT)) {
2248 vm_page_spin_lock(m);
2249 _vm_page_add_queue_spinlocked(m,
2250 PQ_ACTIVE + m->pc, 0);
2251 _vm_page_and_queue_spin_unlock(m);
2253 vm_page_spin_lock(m);
2254 vm_page_flag_clear(m, PG_WINATCFLS);
2255 _vm_page_add_queue_spinlocked(m,
2256 PQ_INACTIVE + m->pc, 0);
2257 ++vm_swapcache_inactive_heuristic;
2258 _vm_page_and_queue_spin_unlock(m);
2265 * Move the specified page to the inactive queue. If the page has
2266 * any associated swap, the swap is deallocated.
2268 * Normally athead is 0 resulting in LRU operation. athead is set
2269 * to 1 if we want this page to be 'as if it were placed in the cache',
2270 * except without unmapping it from the process address space.
2272 * vm_page's spinlock must be held on entry and will remain held on return.
2273 * This routine may not block.
2276 _vm_page_deactivate_locked(vm_page_t m, int athead)
2281 * Ignore if already inactive.
2283 if (m->queue - m->pc == PQ_INACTIVE)
2285 _vm_page_queue_spin_lock(m);
2286 oqueue = _vm_page_rem_queue_spinlocked(m);
2288 if (m->wire_count == 0 && (m->flags & PG_UNMANAGED) == 0) {
2289 if (oqueue == PQ_CACHE)
2290 mycpu->gd_cnt.v_reactivated++;
2291 vm_page_flag_clear(m, PG_WINATCFLS);
2292 _vm_page_add_queue_spinlocked(m, PQ_INACTIVE + m->pc, athead);
2294 ++vm_swapcache_inactive_heuristic;
2296 /* NOTE: PQ_NONE if condition not taken */
2297 _vm_page_queue_spin_unlock(m);
2298 /* leaves vm_page spinlocked */
2302 * Attempt to deactivate a page.
2307 vm_page_deactivate(vm_page_t m)
2309 vm_page_spin_lock(m);
2310 _vm_page_deactivate_locked(m, 0);
2311 vm_page_spin_unlock(m);
2315 vm_page_deactivate_locked(vm_page_t m)
2317 _vm_page_deactivate_locked(m, 0);
2321 * Attempt to move a page to PQ_CACHE.
2323 * Returns 0 on failure, 1 on success
2325 * The page should NOT be busied by the caller. This function will validate
2326 * whether the page can be safely moved to the cache.
2329 vm_page_try_to_cache(vm_page_t m)
2331 vm_page_spin_lock(m);
2332 if (vm_page_busy_try(m, TRUE)) {
2333 vm_page_spin_unlock(m);
2336 if (m->dirty || m->hold_count || m->wire_count ||
2337 (m->flags & (PG_UNMANAGED | PG_NEED_COMMIT))) {
2338 if (_vm_page_wakeup(m)) {
2339 vm_page_spin_unlock(m);
2342 vm_page_spin_unlock(m);
2346 vm_page_spin_unlock(m);
2349 * Page busied by us and no longer spinlocked. Dirty pages cannot
2350 * be moved to the cache.
2352 vm_page_test_dirty(m);
2353 if (m->dirty || (m->flags & PG_NEED_COMMIT)) {
2362 * Attempt to free the page. If we cannot free it, we do nothing.
2363 * 1 is returned on success, 0 on failure.
2368 vm_page_try_to_free(vm_page_t m)
2370 vm_page_spin_lock(m);
2371 if (vm_page_busy_try(m, TRUE)) {
2372 vm_page_spin_unlock(m);
2377 * The page can be in any state, including already being on the free
2378 * queue. Check to see if it really can be freed.
2380 if (m->dirty || /* can't free if it is dirty */
2381 m->hold_count || /* or held (XXX may be wrong) */
2382 m->wire_count || /* or wired */
2383 (m->flags & (PG_UNMANAGED | /* or unmanaged */
2384 PG_NEED_COMMIT)) || /* or needs a commit */
2385 m->queue - m->pc == PQ_FREE || /* already on PQ_FREE */
2386 m->queue - m->pc == PQ_HOLD) { /* already on PQ_HOLD */
2387 if (_vm_page_wakeup(m)) {
2388 vm_page_spin_unlock(m);
2391 vm_page_spin_unlock(m);
2395 vm_page_spin_unlock(m);
2398 * We can probably free the page.
2400 * Page busied by us and no longer spinlocked. Dirty pages will
2401 * not be freed by this function. We have to re-test the
2402 * dirty bit after cleaning out the pmaps.
2404 vm_page_test_dirty(m);
2405 if (m->dirty || (m->flags & PG_NEED_COMMIT)) {
2409 vm_page_protect(m, VM_PROT_NONE);
2410 if (m->dirty || (m->flags & PG_NEED_COMMIT)) {
2421 * Put the specified page onto the page cache queue (if appropriate).
2423 * The page must be busy, and this routine will release the busy and
2424 * possibly even free the page.
2427 vm_page_cache(vm_page_t m)
2429 if ((m->flags & (PG_UNMANAGED | PG_NEED_COMMIT)) ||
2430 m->busy || m->wire_count || m->hold_count) {
2431 kprintf("vm_page_cache: attempting to cache busy/held page\n");
2437 * Already in the cache (and thus not mapped)
2439 if ((m->queue - m->pc) == PQ_CACHE) {
2440 KKASSERT((m->flags & PG_MAPPED) == 0);
2446 * Caller is required to test m->dirty, but note that the act of
2447 * removing the page from its maps can cause it to become dirty
2448 * on an SMP system due to another cpu running in usermode.
2451 panic("vm_page_cache: caching a dirty page, pindex: %ld",
2456 * Remove all pmaps and indicate that the page is not
2457 * writeable or mapped. Our vm_page_protect() call may
2458 * have blocked (especially w/ VM_PROT_NONE), so recheck
2461 vm_page_protect(m, VM_PROT_NONE);
2462 if ((m->flags & (PG_UNMANAGED | PG_MAPPED)) ||
2463 m->busy || m->wire_count || m->hold_count) {
2465 } else if (m->dirty || (m->flags & PG_NEED_COMMIT)) {
2466 vm_page_deactivate(m);
2469 _vm_page_and_queue_spin_lock(m);
2470 _vm_page_rem_queue_spinlocked(m);
2471 _vm_page_add_queue_spinlocked(m, PQ_CACHE + m->pc, 0);
2472 _vm_page_queue_spin_unlock(m);
2473 if (_vm_page_wakeup(m)) {
2474 vm_page_spin_unlock(m);
2477 vm_page_spin_unlock(m);
2479 vm_page_free_wakeup();
2484 * vm_page_dontneed()
2486 * Cache, deactivate, or do nothing as appropriate. This routine
2487 * is typically used by madvise() MADV_DONTNEED.
2489 * Generally speaking we want to move the page into the cache so
2490 * it gets reused quickly. However, this can result in a silly syndrome
2491 * due to the page recycling too quickly. Small objects will not be
2492 * fully cached. On the otherhand, if we move the page to the inactive
2493 * queue we wind up with a problem whereby very large objects
2494 * unnecessarily blow away our inactive and cache queues.
2496 * The solution is to move the pages based on a fixed weighting. We
2497 * either leave them alone, deactivate them, or move them to the cache,
2498 * where moving them to the cache has the highest weighting.
2499 * By forcing some pages into other queues we eventually force the
2500 * system to balance the queues, potentially recovering other unrelated
2501 * space from active. The idea is to not force this to happen too
2504 * The page must be busied.
2507 vm_page_dontneed(vm_page_t m)
2509 static int dnweight;
2516 * occassionally leave the page alone
2518 if ((dnw & 0x01F0) == 0 ||
2519 m->queue - m->pc == PQ_INACTIVE ||
2520 m->queue - m->pc == PQ_CACHE
2522 if (m->act_count >= ACT_INIT)
2528 * If vm_page_dontneed() is inactivating a page, it must clear
2529 * the referenced flag; otherwise the pagedaemon will see references
2530 * on the page in the inactive queue and reactivate it. Until the
2531 * page can move to the cache queue, madvise's job is not done.
2533 vm_page_flag_clear(m, PG_REFERENCED);
2534 pmap_clear_reference(m);
2537 vm_page_test_dirty(m);
2539 if (m->dirty || (dnw & 0x0070) == 0) {
2541 * Deactivate the page 3 times out of 32.
2546 * Cache the page 28 times out of every 32. Note that
2547 * the page is deactivated instead of cached, but placed
2548 * at the head of the queue instead of the tail.
2552 vm_page_spin_lock(m);
2553 _vm_page_deactivate_locked(m, head);
2554 vm_page_spin_unlock(m);
2558 * These routines manipulate the 'soft busy' count for a page. A soft busy
2559 * is almost like PG_BUSY except that it allows certain compatible operations
2560 * to occur on the page while it is busy. For example, a page undergoing a
2561 * write can still be mapped read-only.
2563 * Because vm_pages can overlap buffers m->busy can be > 1. m->busy is only
2564 * adjusted while the vm_page is PG_BUSY so the flash will occur when the
2565 * busy bit is cleared.
2568 vm_page_io_start(vm_page_t m)
2570 KASSERT(m->flags & PG_BUSY, ("vm_page_io_start: page not busy!!!"));
2571 atomic_add_char(&m->busy, 1);
2572 vm_page_flag_set(m, PG_SBUSY);
2576 vm_page_io_finish(vm_page_t m)
2578 KASSERT(m->flags & PG_BUSY, ("vm_page_io_finish: page not busy!!!"));
2579 atomic_subtract_char(&m->busy, 1);
2581 vm_page_flag_clear(m, PG_SBUSY);
2585 * Indicate that a clean VM page requires a filesystem commit and cannot
2586 * be reused. Used by tmpfs.
2589 vm_page_need_commit(vm_page_t m)
2591 vm_page_flag_set(m, PG_NEED_COMMIT);
2592 vm_object_set_writeable_dirty(m->object);
2596 vm_page_clear_commit(vm_page_t m)
2598 vm_page_flag_clear(m, PG_NEED_COMMIT);
2602 * Grab a page, blocking if it is busy and allocating a page if necessary.
2603 * A busy page is returned or NULL. The page may or may not be valid and
2604 * might not be on a queue (the caller is responsible for the disposition of
2607 * If VM_ALLOC_ZERO is specified and the grab must allocate a new page, the
2608 * page will be zero'd and marked valid.
2610 * If VM_ALLOC_FORCE_ZERO is specified the page will be zero'd and marked
2611 * valid even if it already exists.
2613 * If VM_ALLOC_RETRY is specified this routine will never return NULL. Also
2614 * note that VM_ALLOC_NORMAL must be specified if VM_ALLOC_RETRY is specified.
2615 * VM_ALLOC_NULL_OK is implied when VM_ALLOC_RETRY is specified.
2617 * This routine may block, but if VM_ALLOC_RETRY is not set then NULL is
2618 * always returned if we had blocked.
2620 * This routine may not be called from an interrupt.
2622 * PG_ZERO is *ALWAYS* cleared by this routine.
2624 * No other requirements.
2627 vm_page_grab(vm_object_t object, vm_pindex_t pindex, int allocflags)
2633 KKASSERT(allocflags &
2634 (VM_ALLOC_NORMAL|VM_ALLOC_INTERRUPT|VM_ALLOC_SYSTEM));
2635 vm_object_hold_shared(object);
2637 m = vm_page_lookup_busy_try(object, pindex, TRUE, &error);
2639 vm_page_sleep_busy(m, TRUE, "pgrbwt");
2640 if ((allocflags & VM_ALLOC_RETRY) == 0) {
2645 } else if (m == NULL) {
2647 vm_object_upgrade(object);
2650 if (allocflags & VM_ALLOC_RETRY)
2651 allocflags |= VM_ALLOC_NULL_OK;
2652 m = vm_page_alloc(object, pindex,
2653 allocflags & ~VM_ALLOC_RETRY);
2657 if ((allocflags & VM_ALLOC_RETRY) == 0)
2666 * If VM_ALLOC_ZERO an invalid page will be zero'd and set valid.
2668 * If VM_ALLOC_FORCE_ZERO the page is unconditionally zero'd and set
2669 * valid even if already valid.
2671 if (m->valid == 0) {
2672 if (allocflags & (VM_ALLOC_ZERO | VM_ALLOC_FORCE_ZERO)) {
2673 if ((m->flags & PG_ZERO) == 0)
2674 pmap_zero_page(VM_PAGE_TO_PHYS(m));
2675 m->valid = VM_PAGE_BITS_ALL;
2677 } else if (allocflags & VM_ALLOC_FORCE_ZERO) {
2678 pmap_zero_page(VM_PAGE_TO_PHYS(m));
2679 m->valid = VM_PAGE_BITS_ALL;
2681 vm_page_flag_clear(m, PG_ZERO);
2683 vm_object_drop(object);
2688 * Mapping function for valid bits or for dirty bits in
2689 * a page. May not block.
2691 * Inputs are required to range within a page.
2697 vm_page_bits(int base, int size)
2703 base + size <= PAGE_SIZE,
2704 ("vm_page_bits: illegal base/size %d/%d", base, size)
2707 if (size == 0) /* handle degenerate case */
2710 first_bit = base >> DEV_BSHIFT;
2711 last_bit = (base + size - 1) >> DEV_BSHIFT;
2713 return ((2 << last_bit) - (1 << first_bit));
2717 * Sets portions of a page valid and clean. The arguments are expected
2718 * to be DEV_BSIZE aligned but if they aren't the bitmap is inclusive
2719 * of any partial chunks touched by the range. The invalid portion of
2720 * such chunks will be zero'd.
2722 * NOTE: When truncating a buffer vnode_pager_setsize() will automatically
2723 * align base to DEV_BSIZE so as not to mark clean a partially
2724 * truncated device block. Otherwise the dirty page status might be
2727 * This routine may not block.
2729 * (base + size) must be less then or equal to PAGE_SIZE.
2732 _vm_page_zero_valid(vm_page_t m, int base, int size)
2737 if (size == 0) /* handle degenerate case */
2741 * If the base is not DEV_BSIZE aligned and the valid
2742 * bit is clear, we have to zero out a portion of the
2746 if ((frag = base & ~(DEV_BSIZE - 1)) != base &&
2747 (m->valid & (1 << (base >> DEV_BSHIFT))) == 0
2749 pmap_zero_page_area(
2757 * If the ending offset is not DEV_BSIZE aligned and the
2758 * valid bit is clear, we have to zero out a portion of
2762 endoff = base + size;
2764 if ((frag = endoff & ~(DEV_BSIZE - 1)) != endoff &&
2765 (m->valid & (1 << (endoff >> DEV_BSHIFT))) == 0
2767 pmap_zero_page_area(
2770 DEV_BSIZE - (endoff & (DEV_BSIZE - 1))
2776 * Set valid, clear dirty bits. If validating the entire
2777 * page we can safely clear the pmap modify bit. We also
2778 * use this opportunity to clear the PG_NOSYNC flag. If a process
2779 * takes a write fault on a MAP_NOSYNC memory area the flag will
2782 * We set valid bits inclusive of any overlap, but we can only
2783 * clear dirty bits for DEV_BSIZE chunks that are fully within
2786 * Page must be busied?
2787 * No other requirements.
2790 vm_page_set_valid(vm_page_t m, int base, int size)
2792 _vm_page_zero_valid(m, base, size);
2793 m->valid |= vm_page_bits(base, size);
2798 * Set valid bits and clear dirty bits.
2800 * NOTE: This function does not clear the pmap modified bit.
2801 * Also note that e.g. NFS may use a byte-granular base
2804 * WARNING: Page must be busied? But vfs_clean_one_page() will call
2805 * this without necessarily busying the page (via bdwrite()).
2806 * So for now vm_token must also be held.
2808 * No other requirements.
2811 vm_page_set_validclean(vm_page_t m, int base, int size)
2815 _vm_page_zero_valid(m, base, size);
2816 pagebits = vm_page_bits(base, size);
2817 m->valid |= pagebits;
2818 m->dirty &= ~pagebits;
2819 if (base == 0 && size == PAGE_SIZE) {
2820 /*pmap_clear_modify(m);*/
2821 vm_page_flag_clear(m, PG_NOSYNC);
2826 * Set valid & dirty. Used by buwrite()
2828 * WARNING: Page must be busied? But vfs_dirty_one_page() will
2829 * call this function in buwrite() so for now vm_token must
2832 * No other requirements.
2835 vm_page_set_validdirty(vm_page_t m, int base, int size)
2839 pagebits = vm_page_bits(base, size);
2840 m->valid |= pagebits;
2841 m->dirty |= pagebits;
2843 vm_object_set_writeable_dirty(m->object);
2849 * NOTE: This function does not clear the pmap modified bit.
2850 * Also note that e.g. NFS may use a byte-granular base
2853 * Page must be busied?
2854 * No other requirements.
2857 vm_page_clear_dirty(vm_page_t m, int base, int size)
2859 m->dirty &= ~vm_page_bits(base, size);
2860 if (base == 0 && size == PAGE_SIZE) {
2861 /*pmap_clear_modify(m);*/
2862 vm_page_flag_clear(m, PG_NOSYNC);
2867 * Make the page all-dirty.
2869 * Also make sure the related object and vnode reflect the fact that the
2870 * object may now contain a dirty page.
2872 * Page must be busied?
2873 * No other requirements.
2876 vm_page_dirty(vm_page_t m)
2879 int pqtype = m->queue - m->pc;
2881 KASSERT(pqtype != PQ_CACHE && pqtype != PQ_FREE,
2882 ("vm_page_dirty: page in free/cache queue!"));
2883 if (m->dirty != VM_PAGE_BITS_ALL) {
2884 m->dirty = VM_PAGE_BITS_ALL;
2886 vm_object_set_writeable_dirty(m->object);
2891 * Invalidates DEV_BSIZE'd chunks within a page. Both the
2892 * valid and dirty bits for the effected areas are cleared.
2894 * Page must be busied?
2896 * No other requirements.
2899 vm_page_set_invalid(vm_page_t m, int base, int size)
2903 bits = vm_page_bits(base, size);
2906 m->object->generation++;
2910 * The kernel assumes that the invalid portions of a page contain
2911 * garbage, but such pages can be mapped into memory by user code.
2912 * When this occurs, we must zero out the non-valid portions of the
2913 * page so user code sees what it expects.
2915 * Pages are most often semi-valid when the end of a file is mapped
2916 * into memory and the file's size is not page aligned.
2918 * Page must be busied?
2919 * No other requirements.
2922 vm_page_zero_invalid(vm_page_t m, boolean_t setvalid)
2928 * Scan the valid bits looking for invalid sections that
2929 * must be zerod. Invalid sub-DEV_BSIZE'd areas ( where the
2930 * valid bit may be set ) have already been zerod by
2931 * vm_page_set_validclean().
2933 for (b = i = 0; i <= PAGE_SIZE / DEV_BSIZE; ++i) {
2934 if (i == (PAGE_SIZE / DEV_BSIZE) ||
2935 (m->valid & (1 << i))
2938 pmap_zero_page_area(
2941 (i - b) << DEV_BSHIFT
2949 * setvalid is TRUE when we can safely set the zero'd areas
2950 * as being valid. We can do this if there are no cache consistency
2951 * issues. e.g. it is ok to do with UFS, but not ok to do with NFS.
2954 m->valid = VM_PAGE_BITS_ALL;
2958 * Is a (partial) page valid? Note that the case where size == 0
2959 * will return FALSE in the degenerate case where the page is entirely
2960 * invalid, and TRUE otherwise.
2963 * No other requirements.
2966 vm_page_is_valid(vm_page_t m, int base, int size)
2968 int bits = vm_page_bits(base, size);
2970 if (m->valid && ((m->valid & bits) == bits))
2977 * update dirty bits from pmap/mmu. May not block.
2979 * Caller must hold the page busy
2982 vm_page_test_dirty(vm_page_t m)
2984 if ((m->dirty != VM_PAGE_BITS_ALL) && pmap_is_modified(m)) {
2990 * Register an action, associating it with its vm_page
2993 vm_page_register_action(vm_page_action_t action, vm_page_event_t event)
2995 struct vm_page_action_list *list;
2998 hv = (int)((intptr_t)action->m >> 8) & VMACTION_HMASK;
2999 list = &action_list[hv];
3001 lwkt_gettoken(&vm_token);
3002 vm_page_flag_set(action->m, PG_ACTIONLIST);
3003 action->event = event;
3004 LIST_INSERT_HEAD(list, action, entry);
3005 lwkt_reltoken(&vm_token);
3009 * Unregister an action, disassociating it from its related vm_page
3012 vm_page_unregister_action(vm_page_action_t action)
3014 struct vm_page_action_list *list;
3017 lwkt_gettoken(&vm_token);
3018 if (action->event != VMEVENT_NONE) {
3019 action->event = VMEVENT_NONE;
3020 LIST_REMOVE(action, entry);
3022 hv = (int)((intptr_t)action->m >> 8) & VMACTION_HMASK;
3023 list = &action_list[hv];
3024 if (LIST_EMPTY(list))
3025 vm_page_flag_clear(action->m, PG_ACTIONLIST);
3027 lwkt_reltoken(&vm_token);
3031 * Issue an event on a VM page. Corresponding action structures are
3032 * removed from the page's list and called.
3034 * If the vm_page has no more pending action events we clear its
3035 * PG_ACTIONLIST flag.
3038 vm_page_event_internal(vm_page_t m, vm_page_event_t event)
3040 struct vm_page_action_list *list;
3041 struct vm_page_action *scan;
3042 struct vm_page_action *next;
3046 hv = (int)((intptr_t)m >> 8) & VMACTION_HMASK;
3047 list = &action_list[hv];
3050 lwkt_gettoken(&vm_token);
3051 LIST_FOREACH_MUTABLE(scan, list, entry, next) {
3053 if (scan->event == event) {
3054 scan->event = VMEVENT_NONE;
3055 LIST_REMOVE(scan, entry);
3056 scan->func(m, scan);
3064 vm_page_flag_clear(m, PG_ACTIONLIST);
3065 lwkt_reltoken(&vm_token);
3068 #include "opt_ddb.h"
3070 #include <sys/kernel.h>
3072 #include <ddb/ddb.h>
3074 DB_SHOW_COMMAND(page, vm_page_print_page_info)
3076 db_printf("vmstats.v_free_count: %d\n", vmstats.v_free_count);
3077 db_printf("vmstats.v_cache_count: %d\n", vmstats.v_cache_count);
3078 db_printf("vmstats.v_inactive_count: %d\n", vmstats.v_inactive_count);
3079 db_printf("vmstats.v_active_count: %d\n", vmstats.v_active_count);
3080 db_printf("vmstats.v_wire_count: %d\n", vmstats.v_wire_count);
3081 db_printf("vmstats.v_free_reserved: %d\n", vmstats.v_free_reserved);
3082 db_printf("vmstats.v_free_min: %d\n", vmstats.v_free_min);
3083 db_printf("vmstats.v_free_target: %d\n", vmstats.v_free_target);
3084 db_printf("vmstats.v_cache_min: %d\n", vmstats.v_cache_min);
3085 db_printf("vmstats.v_inactive_target: %d\n", vmstats.v_inactive_target);
3088 DB_SHOW_COMMAND(pageq, vm_page_print_pageq_info)
3091 db_printf("PQ_FREE:");
3092 for(i=0;i<PQ_L2_SIZE;i++) {
3093 db_printf(" %d", vm_page_queues[PQ_FREE + i].lcnt);
3097 db_printf("PQ_CACHE:");
3098 for(i=0;i<PQ_L2_SIZE;i++) {
3099 db_printf(" %d", vm_page_queues[PQ_CACHE + i].lcnt);
3103 db_printf("PQ_ACTIVE:");
3104 for(i=0;i<PQ_L2_SIZE;i++) {
3105 db_printf(" %d", vm_page_queues[PQ_ACTIVE + i].lcnt);
3109 db_printf("PQ_INACTIVE:");
3110 for(i=0;i<PQ_L2_SIZE;i++) {
3111 db_printf(" %d", vm_page_queues[PQ_INACTIVE + i].lcnt);