freebsd-dev/sys/vm/vm_phys.c
John Baldwin 2e7838ae84 vm_phys_early_alloc: mem_index is only used under #ifdef NUMA.
Possibly mem_index should just reuse biggestone since this loop is
already reusing biggestsize.
2022-04-08 17:25:13 -07:00

1818 lines
48 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2002-2006 Rice University
* Copyright (c) 2007 Alan L. Cox <alc@cs.rice.edu>
* All rights reserved.
*
* This software was developed for the FreeBSD Project by Alan L. Cox,
* Olivier Crameri, Peter Druschel, Sitaram Iyer, and Juan Navarro.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY
* WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* Physical memory system implementation
*
* Any external functions defined by this module are only to be used by the
* virtual memory system.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include "opt_ddb.h"
#include "opt_vm.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/domainset.h>
#include <sys/lock.h>
#include <sys/kernel.h>
#include <sys/malloc.h>
#include <sys/mutex.h>
#include <sys/proc.h>
#include <sys/queue.h>
#include <sys/rwlock.h>
#include <sys/sbuf.h>
#include <sys/sysctl.h>
#include <sys/tree.h>
#include <sys/vmmeter.h>
#include <ddb/ddb.h>
#include <vm/vm.h>
#include <vm/vm_extern.h>
#include <vm/vm_param.h>
#include <vm/vm_kern.h>
#include <vm/vm_object.h>
#include <vm/vm_page.h>
#include <vm/vm_phys.h>
#include <vm/vm_pagequeue.h>
_Static_assert(sizeof(long) * NBBY >= VM_PHYSSEG_MAX,
"Too many physsegs.");
#ifdef NUMA
struct mem_affinity __read_mostly *mem_affinity;
int __read_mostly *mem_locality;
#endif
int __read_mostly vm_ndomains = 1;
domainset_t __read_mostly all_domains = DOMAINSET_T_INITIALIZER(0x1);
struct vm_phys_seg __read_mostly vm_phys_segs[VM_PHYSSEG_MAX];
int __read_mostly vm_phys_nsegs;
static struct vm_phys_seg vm_phys_early_segs[8];
static int vm_phys_early_nsegs;
struct vm_phys_fictitious_seg;
static int vm_phys_fictitious_cmp(struct vm_phys_fictitious_seg *,
struct vm_phys_fictitious_seg *);
RB_HEAD(fict_tree, vm_phys_fictitious_seg) vm_phys_fictitious_tree =
RB_INITIALIZER(&vm_phys_fictitious_tree);
struct vm_phys_fictitious_seg {
RB_ENTRY(vm_phys_fictitious_seg) node;
/* Memory region data */
vm_paddr_t start;
vm_paddr_t end;
vm_page_t first_page;
};
RB_GENERATE_STATIC(fict_tree, vm_phys_fictitious_seg, node,
vm_phys_fictitious_cmp);
static struct rwlock_padalign vm_phys_fictitious_reg_lock;
MALLOC_DEFINE(M_FICT_PAGES, "vm_fictitious", "Fictitious VM pages");
static struct vm_freelist __aligned(CACHE_LINE_SIZE)
vm_phys_free_queues[MAXMEMDOM][VM_NFREELIST][VM_NFREEPOOL]
[VM_NFREEORDER_MAX];
static int __read_mostly vm_nfreelists;
/*
* These "avail lists" are globals used to communicate boot-time physical
* memory layout to other parts of the kernel. Each physically contiguous
* region of memory is defined by a start address at an even index and an
* end address at the following odd index. Each list is terminated by a
* pair of zero entries.
*
* dump_avail tells the dump code what regions to include in a crash dump, and
* phys_avail is all of the remaining physical memory that is available for
* the vm system.
*
* Initially dump_avail and phys_avail are identical. Boot time memory
* allocations remove extents from phys_avail that may still be included
* in dumps.
*/
vm_paddr_t phys_avail[PHYS_AVAIL_COUNT];
vm_paddr_t dump_avail[PHYS_AVAIL_COUNT];
/*
* Provides the mapping from VM_FREELIST_* to free list indices (flind).
*/
static int __read_mostly vm_freelist_to_flind[VM_NFREELIST];
CTASSERT(VM_FREELIST_DEFAULT == 0);
#ifdef VM_FREELIST_DMA32
#define VM_DMA32_BOUNDARY ((vm_paddr_t)1 << 32)
#endif
/*
* Enforce the assumptions made by vm_phys_add_seg() and vm_phys_init() about
* the ordering of the free list boundaries.
*/
#if defined(VM_LOWMEM_BOUNDARY) && defined(VM_DMA32_BOUNDARY)
CTASSERT(VM_LOWMEM_BOUNDARY < VM_DMA32_BOUNDARY);
#endif
static int sysctl_vm_phys_free(SYSCTL_HANDLER_ARGS);
SYSCTL_OID(_vm, OID_AUTO, phys_free,
CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, 0,
sysctl_vm_phys_free, "A",
"Phys Free Info");
static int sysctl_vm_phys_segs(SYSCTL_HANDLER_ARGS);
SYSCTL_OID(_vm, OID_AUTO, phys_segs,
CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, 0,
sysctl_vm_phys_segs, "A",
"Phys Seg Info");
#ifdef NUMA
static int sysctl_vm_phys_locality(SYSCTL_HANDLER_ARGS);
SYSCTL_OID(_vm, OID_AUTO, phys_locality,
CTLTYPE_STRING | CTLFLAG_RD | CTLFLAG_MPSAFE, NULL, 0,
sysctl_vm_phys_locality, "A",
"Phys Locality Info");
#endif
SYSCTL_INT(_vm, OID_AUTO, ndomains, CTLFLAG_RD,
&vm_ndomains, 0, "Number of physical memory domains available.");
static void _vm_phys_create_seg(vm_paddr_t start, vm_paddr_t end, int domain);
static void vm_phys_create_seg(vm_paddr_t start, vm_paddr_t end);
static void vm_phys_split_pages(vm_page_t m, int oind, struct vm_freelist *fl,
int order, int tail);
/*
* Red-black tree helpers for vm fictitious range management.
*/
static inline int
vm_phys_fictitious_in_range(struct vm_phys_fictitious_seg *p,
struct vm_phys_fictitious_seg *range)
{
KASSERT(range->start != 0 && range->end != 0,
("Invalid range passed on search for vm_fictitious page"));
if (p->start >= range->end)
return (1);
if (p->start < range->start)
return (-1);
return (0);
}
static int
vm_phys_fictitious_cmp(struct vm_phys_fictitious_seg *p1,
struct vm_phys_fictitious_seg *p2)
{
/* Check if this is a search for a page */
if (p1->end == 0)
return (vm_phys_fictitious_in_range(p1, p2));
KASSERT(p2->end != 0,
("Invalid range passed as second parameter to vm fictitious comparison"));
/* Searching to add a new range */
if (p1->end <= p2->start)
return (-1);
if (p1->start >= p2->end)
return (1);
panic("Trying to add overlapping vm fictitious ranges:\n"
"[%#jx:%#jx] and [%#jx:%#jx]", (uintmax_t)p1->start,
(uintmax_t)p1->end, (uintmax_t)p2->start, (uintmax_t)p2->end);
}
int
vm_phys_domain_match(int prefer, vm_paddr_t low, vm_paddr_t high)
{
#ifdef NUMA
domainset_t mask;
int i;
if (vm_ndomains == 1 || mem_affinity == NULL)
return (0);
DOMAINSET_ZERO(&mask);
/*
* Check for any memory that overlaps low, high.
*/
for (i = 0; mem_affinity[i].end != 0; i++)
if (mem_affinity[i].start <= high &&
mem_affinity[i].end >= low)
DOMAINSET_SET(mem_affinity[i].domain, &mask);
if (prefer != -1 && DOMAINSET_ISSET(prefer, &mask))
return (prefer);
if (DOMAINSET_EMPTY(&mask))
panic("vm_phys_domain_match: Impossible constraint");
return (DOMAINSET_FFS(&mask) - 1);
#else
return (0);
#endif
}
/*
* Outputs the state of the physical memory allocator, specifically,
* the amount of physical memory in each free list.
*/
static int
sysctl_vm_phys_free(SYSCTL_HANDLER_ARGS)
{
struct sbuf sbuf;
struct vm_freelist *fl;
int dom, error, flind, oind, pind;
error = sysctl_wire_old_buffer(req, 0);
if (error != 0)
return (error);
sbuf_new_for_sysctl(&sbuf, NULL, 128 * vm_ndomains, req);
for (dom = 0; dom < vm_ndomains; dom++) {
sbuf_printf(&sbuf,"\nDOMAIN %d:\n", dom);
for (flind = 0; flind < vm_nfreelists; flind++) {
sbuf_printf(&sbuf, "\nFREE LIST %d:\n"
"\n ORDER (SIZE) | NUMBER"
"\n ", flind);
for (pind = 0; pind < VM_NFREEPOOL; pind++)
sbuf_printf(&sbuf, " | POOL %d", pind);
sbuf_printf(&sbuf, "\n-- ");
for (pind = 0; pind < VM_NFREEPOOL; pind++)
sbuf_printf(&sbuf, "-- -- ");
sbuf_printf(&sbuf, "--\n");
for (oind = VM_NFREEORDER - 1; oind >= 0; oind--) {
sbuf_printf(&sbuf, " %2d (%6dK)", oind,
1 << (PAGE_SHIFT - 10 + oind));
for (pind = 0; pind < VM_NFREEPOOL; pind++) {
fl = vm_phys_free_queues[dom][flind][pind];
sbuf_printf(&sbuf, " | %6d",
fl[oind].lcnt);
}
sbuf_printf(&sbuf, "\n");
}
}
}
error = sbuf_finish(&sbuf);
sbuf_delete(&sbuf);
return (error);
}
/*
* Outputs the set of physical memory segments.
*/
static int
sysctl_vm_phys_segs(SYSCTL_HANDLER_ARGS)
{
struct sbuf sbuf;
struct vm_phys_seg *seg;
int error, segind;
error = sysctl_wire_old_buffer(req, 0);
if (error != 0)
return (error);
sbuf_new_for_sysctl(&sbuf, NULL, 128, req);
for (segind = 0; segind < vm_phys_nsegs; segind++) {
sbuf_printf(&sbuf, "\nSEGMENT %d:\n\n", segind);
seg = &vm_phys_segs[segind];
sbuf_printf(&sbuf, "start: %#jx\n",
(uintmax_t)seg->start);
sbuf_printf(&sbuf, "end: %#jx\n",
(uintmax_t)seg->end);
sbuf_printf(&sbuf, "domain: %d\n", seg->domain);
sbuf_printf(&sbuf, "free list: %p\n", seg->free_queues);
}
error = sbuf_finish(&sbuf);
sbuf_delete(&sbuf);
return (error);
}
/*
* Return affinity, or -1 if there's no affinity information.
*/
int
vm_phys_mem_affinity(int f, int t)
{
#ifdef NUMA
if (mem_locality == NULL)
return (-1);
if (f >= vm_ndomains || t >= vm_ndomains)
return (-1);
return (mem_locality[f * vm_ndomains + t]);
#else
return (-1);
#endif
}
#ifdef NUMA
/*
* Outputs the VM locality table.
*/
static int
sysctl_vm_phys_locality(SYSCTL_HANDLER_ARGS)
{
struct sbuf sbuf;
int error, i, j;
error = sysctl_wire_old_buffer(req, 0);
if (error != 0)
return (error);
sbuf_new_for_sysctl(&sbuf, NULL, 128, req);
sbuf_printf(&sbuf, "\n");
for (i = 0; i < vm_ndomains; i++) {
sbuf_printf(&sbuf, "%d: ", i);
for (j = 0; j < vm_ndomains; j++) {
sbuf_printf(&sbuf, "%d ", vm_phys_mem_affinity(i, j));
}
sbuf_printf(&sbuf, "\n");
}
error = sbuf_finish(&sbuf);
sbuf_delete(&sbuf);
return (error);
}
#endif
static void
vm_freelist_add(struct vm_freelist *fl, vm_page_t m, int order, int tail)
{
m->order = order;
if (tail)
TAILQ_INSERT_TAIL(&fl[order].pl, m, listq);
else
TAILQ_INSERT_HEAD(&fl[order].pl, m, listq);
fl[order].lcnt++;
}
static void
vm_freelist_rem(struct vm_freelist *fl, vm_page_t m, int order)
{
TAILQ_REMOVE(&fl[order].pl, m, listq);
fl[order].lcnt--;
m->order = VM_NFREEORDER;
}
/*
* Create a physical memory segment.
*/
static void
_vm_phys_create_seg(vm_paddr_t start, vm_paddr_t end, int domain)
{
struct vm_phys_seg *seg;
KASSERT(vm_phys_nsegs < VM_PHYSSEG_MAX,
("vm_phys_create_seg: increase VM_PHYSSEG_MAX"));
KASSERT(domain >= 0 && domain < vm_ndomains,
("vm_phys_create_seg: invalid domain provided"));
seg = &vm_phys_segs[vm_phys_nsegs++];
while (seg > vm_phys_segs && (seg - 1)->start >= end) {
*seg = *(seg - 1);
seg--;
}
seg->start = start;
seg->end = end;
seg->domain = domain;
}
static void
vm_phys_create_seg(vm_paddr_t start, vm_paddr_t end)
{
#ifdef NUMA
int i;
if (mem_affinity == NULL) {
_vm_phys_create_seg(start, end, 0);
return;
}
for (i = 0;; i++) {
if (mem_affinity[i].end == 0)
panic("Reached end of affinity info");
if (mem_affinity[i].end <= start)
continue;
if (mem_affinity[i].start > start)
panic("No affinity info for start %jx",
(uintmax_t)start);
if (mem_affinity[i].end >= end) {
_vm_phys_create_seg(start, end,
mem_affinity[i].domain);
break;
}
_vm_phys_create_seg(start, mem_affinity[i].end,
mem_affinity[i].domain);
start = mem_affinity[i].end;
}
#else
_vm_phys_create_seg(start, end, 0);
#endif
}
/*
* Add a physical memory segment.
*/
void
vm_phys_add_seg(vm_paddr_t start, vm_paddr_t end)
{
vm_paddr_t paddr;
KASSERT((start & PAGE_MASK) == 0,
("vm_phys_define_seg: start is not page aligned"));
KASSERT((end & PAGE_MASK) == 0,
("vm_phys_define_seg: end is not page aligned"));
/*
* Split the physical memory segment if it spans two or more free
* list boundaries.
*/
paddr = start;
#ifdef VM_FREELIST_LOWMEM
if (paddr < VM_LOWMEM_BOUNDARY && end > VM_LOWMEM_BOUNDARY) {
vm_phys_create_seg(paddr, VM_LOWMEM_BOUNDARY);
paddr = VM_LOWMEM_BOUNDARY;
}
#endif
#ifdef VM_FREELIST_DMA32
if (paddr < VM_DMA32_BOUNDARY && end > VM_DMA32_BOUNDARY) {
vm_phys_create_seg(paddr, VM_DMA32_BOUNDARY);
paddr = VM_DMA32_BOUNDARY;
}
#endif
vm_phys_create_seg(paddr, end);
}
/*
* Initialize the physical memory allocator.
*
* Requires that vm_page_array is initialized!
*/
void
vm_phys_init(void)
{
struct vm_freelist *fl;
struct vm_phys_seg *end_seg, *prev_seg, *seg, *tmp_seg;
u_long npages;
int dom, flind, freelist, oind, pind, segind;
/*
* Compute the number of free lists, and generate the mapping from the
* manifest constants VM_FREELIST_* to the free list indices.
*
* Initially, the entries of vm_freelist_to_flind[] are set to either
* 0 or 1 to indicate which free lists should be created.
*/
npages = 0;
for (segind = vm_phys_nsegs - 1; segind >= 0; segind--) {
seg = &vm_phys_segs[segind];
#ifdef VM_FREELIST_LOWMEM
if (seg->end <= VM_LOWMEM_BOUNDARY)
vm_freelist_to_flind[VM_FREELIST_LOWMEM] = 1;
else
#endif
#ifdef VM_FREELIST_DMA32
if (
#ifdef VM_DMA32_NPAGES_THRESHOLD
/*
* Create the DMA32 free list only if the amount of
* physical memory above physical address 4G exceeds the
* given threshold.
*/
npages > VM_DMA32_NPAGES_THRESHOLD &&
#endif
seg->end <= VM_DMA32_BOUNDARY)
vm_freelist_to_flind[VM_FREELIST_DMA32] = 1;
else
#endif
{
npages += atop(seg->end - seg->start);
vm_freelist_to_flind[VM_FREELIST_DEFAULT] = 1;
}
}
/* Change each entry into a running total of the free lists. */
for (freelist = 1; freelist < VM_NFREELIST; freelist++) {
vm_freelist_to_flind[freelist] +=
vm_freelist_to_flind[freelist - 1];
}
vm_nfreelists = vm_freelist_to_flind[VM_NFREELIST - 1];
KASSERT(vm_nfreelists > 0, ("vm_phys_init: no free lists"));
/* Change each entry into a free list index. */
for (freelist = 0; freelist < VM_NFREELIST; freelist++)
vm_freelist_to_flind[freelist]--;
/*
* Initialize the first_page and free_queues fields of each physical
* memory segment.
*/
#ifdef VM_PHYSSEG_SPARSE
npages = 0;
#endif
for (segind = 0; segind < vm_phys_nsegs; segind++) {
seg = &vm_phys_segs[segind];
#ifdef VM_PHYSSEG_SPARSE
seg->first_page = &vm_page_array[npages];
npages += atop(seg->end - seg->start);
#else
seg->first_page = PHYS_TO_VM_PAGE(seg->start);
#endif
#ifdef VM_FREELIST_LOWMEM
if (seg->end <= VM_LOWMEM_BOUNDARY) {
flind = vm_freelist_to_flind[VM_FREELIST_LOWMEM];
KASSERT(flind >= 0,
("vm_phys_init: LOWMEM flind < 0"));
} else
#endif
#ifdef VM_FREELIST_DMA32
if (seg->end <= VM_DMA32_BOUNDARY) {
flind = vm_freelist_to_flind[VM_FREELIST_DMA32];
KASSERT(flind >= 0,
("vm_phys_init: DMA32 flind < 0"));
} else
#endif
{
flind = vm_freelist_to_flind[VM_FREELIST_DEFAULT];
KASSERT(flind >= 0,
("vm_phys_init: DEFAULT flind < 0"));
}
seg->free_queues = &vm_phys_free_queues[seg->domain][flind];
}
/*
* Coalesce physical memory segments that are contiguous and share the
* same per-domain free queues.
*/
prev_seg = vm_phys_segs;
seg = &vm_phys_segs[1];
end_seg = &vm_phys_segs[vm_phys_nsegs];
while (seg < end_seg) {
if (prev_seg->end == seg->start &&
prev_seg->free_queues == seg->free_queues) {
prev_seg->end = seg->end;
KASSERT(prev_seg->domain == seg->domain,
("vm_phys_init: free queues cannot span domains"));
vm_phys_nsegs--;
end_seg--;
for (tmp_seg = seg; tmp_seg < end_seg; tmp_seg++)
*tmp_seg = *(tmp_seg + 1);
} else {
prev_seg = seg;
seg++;
}
}
/*
* Initialize the free queues.
*/
for (dom = 0; dom < vm_ndomains; dom++) {
for (flind = 0; flind < vm_nfreelists; flind++) {
for (pind = 0; pind < VM_NFREEPOOL; pind++) {
fl = vm_phys_free_queues[dom][flind][pind];
for (oind = 0; oind < VM_NFREEORDER; oind++)
TAILQ_INIT(&fl[oind].pl);
}
}
}
rw_init(&vm_phys_fictitious_reg_lock, "vmfctr");
}
/*
* Register info about the NUMA topology of the system.
*
* Invoked by platform-dependent code prior to vm_phys_init().
*/
void
vm_phys_register_domains(int ndomains, struct mem_affinity *affinity,
int *locality)
{
#ifdef NUMA
int d, i;
/*
* For now the only override value that we support is 1, which
* effectively disables NUMA-awareness in the allocators.
*/
d = 0;
TUNABLE_INT_FETCH("vm.numa.disabled", &d);
if (d)
ndomains = 1;
if (ndomains > 1) {
vm_ndomains = ndomains;
mem_affinity = affinity;
mem_locality = locality;
}
for (i = 0; i < vm_ndomains; i++)
DOMAINSET_SET(i, &all_domains);
#else
(void)ndomains;
(void)affinity;
(void)locality;
#endif
}
/*
* Split a contiguous, power of two-sized set of physical pages.
*
* When this function is called by a page allocation function, the caller
* should request insertion at the head unless the order [order, oind) queues
* are known to be empty. The objective being to reduce the likelihood of
* long-term fragmentation by promoting contemporaneous allocation and
* (hopefully) deallocation.
*/
static __inline void
vm_phys_split_pages(vm_page_t m, int oind, struct vm_freelist *fl, int order,
int tail)
{
vm_page_t m_buddy;
while (oind > order) {
oind--;
m_buddy = &m[1 << oind];
KASSERT(m_buddy->order == VM_NFREEORDER,
("vm_phys_split_pages: page %p has unexpected order %d",
m_buddy, m_buddy->order));
vm_freelist_add(fl, m_buddy, oind, tail);
}
}
/*
* Add the physical pages [m, m + npages) at the end of a power-of-two aligned
* and sized set to the specified free list.
*
* When this function is called by a page allocation function, the caller
* should request insertion at the head unless the lower-order queues are
* known to be empty. The objective being to reduce the likelihood of long-
* term fragmentation by promoting contemporaneous allocation and (hopefully)
* deallocation.
*
* The physical page m's buddy must not be free.
*/
static void
vm_phys_enq_range(vm_page_t m, u_int npages, struct vm_freelist *fl, int tail)
{
u_int n;
int order;
KASSERT(npages > 0, ("vm_phys_enq_range: npages is 0"));
KASSERT(((VM_PAGE_TO_PHYS(m) + npages * PAGE_SIZE) &
((PAGE_SIZE << (fls(npages) - 1)) - 1)) == 0,
("vm_phys_enq_range: page %p and npages %u are misaligned",
m, npages));
do {
KASSERT(m->order == VM_NFREEORDER,
("vm_phys_enq_range: page %p has unexpected order %d",
m, m->order));
order = ffs(npages) - 1;
KASSERT(order < VM_NFREEORDER,
("vm_phys_enq_range: order %d is out of range", order));
vm_freelist_add(fl, m, order, tail);
n = 1 << order;
m += n;
npages -= n;
} while (npages > 0);
}
/*
* Set the pool for a contiguous, power of two-sized set of physical pages.
*/
static void
vm_phys_set_pool(int pool, vm_page_t m, int order)
{
vm_page_t m_tmp;
for (m_tmp = m; m_tmp < &m[1 << order]; m_tmp++)
m_tmp->pool = pool;
}
/*
* Tries to allocate the specified number of pages from the specified pool
* within the specified domain. Returns the actual number of allocated pages
* and a pointer to each page through the array ma[].
*
* The returned pages may not be physically contiguous. However, in contrast
* to performing multiple, back-to-back calls to vm_phys_alloc_pages(..., 0),
* calling this function once to allocate the desired number of pages will
* avoid wasted time in vm_phys_split_pages().
*
* The free page queues for the specified domain must be locked.
*/
int
vm_phys_alloc_npages(int domain, int pool, int npages, vm_page_t ma[])
{
struct vm_freelist *alt, *fl;
vm_page_t m;
int avail, end, flind, freelist, i, need, oind, pind;
KASSERT(domain >= 0 && domain < vm_ndomains,
("vm_phys_alloc_npages: domain %d is out of range", domain));
KASSERT(pool < VM_NFREEPOOL,
("vm_phys_alloc_npages: pool %d is out of range", pool));
KASSERT(npages <= 1 << (VM_NFREEORDER - 1),
("vm_phys_alloc_npages: npages %d is out of range", npages));
vm_domain_free_assert_locked(VM_DOMAIN(domain));
i = 0;
for (freelist = 0; freelist < VM_NFREELIST; freelist++) {
flind = vm_freelist_to_flind[freelist];
if (flind < 0)
continue;
fl = vm_phys_free_queues[domain][flind][pool];
for (oind = 0; oind < VM_NFREEORDER; oind++) {
while ((m = TAILQ_FIRST(&fl[oind].pl)) != NULL) {
vm_freelist_rem(fl, m, oind);
avail = 1 << oind;
need = imin(npages - i, avail);
for (end = i + need; i < end;)
ma[i++] = m++;
if (need < avail) {
/*
* Return excess pages to fl. Its
* order [0, oind) queues are empty.
*/
vm_phys_enq_range(m, avail - need, fl,
1);
return (npages);
} else if (i == npages)
return (npages);
}
}
for (oind = VM_NFREEORDER - 1; oind >= 0; oind--) {
for (pind = 0; pind < VM_NFREEPOOL; pind++) {
alt = vm_phys_free_queues[domain][flind][pind];
while ((m = TAILQ_FIRST(&alt[oind].pl)) !=
NULL) {
vm_freelist_rem(alt, m, oind);
vm_phys_set_pool(pool, m, oind);
avail = 1 << oind;
need = imin(npages - i, avail);
for (end = i + need; i < end;)
ma[i++] = m++;
if (need < avail) {
/*
* Return excess pages to fl.
* Its order [0, oind) queues
* are empty.
*/
vm_phys_enq_range(m, avail -
need, fl, 1);
return (npages);
} else if (i == npages)
return (npages);
}
}
}
}
return (i);
}
/*
* Allocate a contiguous, power of two-sized set of physical pages
* from the free lists.
*
* The free page queues must be locked.
*/
vm_page_t
vm_phys_alloc_pages(int domain, int pool, int order)
{
vm_page_t m;
int freelist;
for (freelist = 0; freelist < VM_NFREELIST; freelist++) {
m = vm_phys_alloc_freelist_pages(domain, freelist, pool, order);
if (m != NULL)
return (m);
}
return (NULL);
}
/*
* Allocate a contiguous, power of two-sized set of physical pages from the
* specified free list. The free list must be specified using one of the
* manifest constants VM_FREELIST_*.
*
* The free page queues must be locked.
*/
vm_page_t
vm_phys_alloc_freelist_pages(int domain, int freelist, int pool, int order)
{
struct vm_freelist *alt, *fl;
vm_page_t m;
int oind, pind, flind;
KASSERT(domain >= 0 && domain < vm_ndomains,
("vm_phys_alloc_freelist_pages: domain %d is out of range",
domain));
KASSERT(freelist < VM_NFREELIST,
("vm_phys_alloc_freelist_pages: freelist %d is out of range",
freelist));
KASSERT(pool < VM_NFREEPOOL,
("vm_phys_alloc_freelist_pages: pool %d is out of range", pool));
KASSERT(order < VM_NFREEORDER,
("vm_phys_alloc_freelist_pages: order %d is out of range", order));
flind = vm_freelist_to_flind[freelist];
/* Check if freelist is present */
if (flind < 0)
return (NULL);
vm_domain_free_assert_locked(VM_DOMAIN(domain));
fl = &vm_phys_free_queues[domain][flind][pool][0];
for (oind = order; oind < VM_NFREEORDER; oind++) {
m = TAILQ_FIRST(&fl[oind].pl);
if (m != NULL) {
vm_freelist_rem(fl, m, oind);
/* The order [order, oind) queues are empty. */
vm_phys_split_pages(m, oind, fl, order, 1);
return (m);
}
}
/*
* The given pool was empty. Find the largest
* contiguous, power-of-two-sized set of pages in any
* pool. Transfer these pages to the given pool, and
* use them to satisfy the allocation.
*/
for (oind = VM_NFREEORDER - 1; oind >= order; oind--) {
for (pind = 0; pind < VM_NFREEPOOL; pind++) {
alt = &vm_phys_free_queues[domain][flind][pind][0];
m = TAILQ_FIRST(&alt[oind].pl);
if (m != NULL) {
vm_freelist_rem(alt, m, oind);
vm_phys_set_pool(pool, m, oind);
/* The order [order, oind) queues are empty. */
vm_phys_split_pages(m, oind, fl, order, 1);
return (m);
}
}
}
return (NULL);
}
/*
* Find the vm_page corresponding to the given physical address.
*/
vm_page_t
vm_phys_paddr_to_vm_page(vm_paddr_t pa)
{
struct vm_phys_seg *seg;
int segind;
for (segind = 0; segind < vm_phys_nsegs; segind++) {
seg = &vm_phys_segs[segind];
if (pa >= seg->start && pa < seg->end)
return (&seg->first_page[atop(pa - seg->start)]);
}
return (NULL);
}
vm_page_t
vm_phys_fictitious_to_vm_page(vm_paddr_t pa)
{
struct vm_phys_fictitious_seg tmp, *seg;
vm_page_t m;
m = NULL;
tmp.start = pa;
tmp.end = 0;
rw_rlock(&vm_phys_fictitious_reg_lock);
seg = RB_FIND(fict_tree, &vm_phys_fictitious_tree, &tmp);
rw_runlock(&vm_phys_fictitious_reg_lock);
if (seg == NULL)
return (NULL);
m = &seg->first_page[atop(pa - seg->start)];
KASSERT((m->flags & PG_FICTITIOUS) != 0, ("%p not fictitious", m));
return (m);
}
static inline void
vm_phys_fictitious_init_range(vm_page_t range, vm_paddr_t start,
long page_count, vm_memattr_t memattr)
{
long i;
bzero(range, page_count * sizeof(*range));
for (i = 0; i < page_count; i++) {
vm_page_initfake(&range[i], start + PAGE_SIZE * i, memattr);
range[i].oflags &= ~VPO_UNMANAGED;
range[i].busy_lock = VPB_UNBUSIED;
}
}
int
vm_phys_fictitious_reg_range(vm_paddr_t start, vm_paddr_t end,
vm_memattr_t memattr)
{
struct vm_phys_fictitious_seg *seg;
vm_page_t fp;
long page_count;
#ifdef VM_PHYSSEG_DENSE
long pi, pe;
long dpage_count;
#endif
KASSERT(start < end,
("Start of segment isn't less than end (start: %jx end: %jx)",
(uintmax_t)start, (uintmax_t)end));
page_count = (end - start) / PAGE_SIZE;
#ifdef VM_PHYSSEG_DENSE
pi = atop(start);
pe = atop(end);
if (pi >= first_page && (pi - first_page) < vm_page_array_size) {
fp = &vm_page_array[pi - first_page];
if ((pe - first_page) > vm_page_array_size) {
/*
* We have a segment that starts inside
* of vm_page_array, but ends outside of it.
*
* Use vm_page_array pages for those that are
* inside of the vm_page_array range, and
* allocate the remaining ones.
*/
dpage_count = vm_page_array_size - (pi - first_page);
vm_phys_fictitious_init_range(fp, start, dpage_count,
memattr);
page_count -= dpage_count;
start += ptoa(dpage_count);
goto alloc;
}
/*
* We can allocate the full range from vm_page_array,
* so there's no need to register the range in the tree.
*/
vm_phys_fictitious_init_range(fp, start, page_count, memattr);
return (0);
} else if (pe > first_page && (pe - first_page) < vm_page_array_size) {
/*
* We have a segment that ends inside of vm_page_array,
* but starts outside of it.
*/
fp = &vm_page_array[0];
dpage_count = pe - first_page;
vm_phys_fictitious_init_range(fp, ptoa(first_page), dpage_count,
memattr);
end -= ptoa(dpage_count);
page_count -= dpage_count;
goto alloc;
} else if (pi < first_page && pe > (first_page + vm_page_array_size)) {
/*
* Trying to register a fictitious range that expands before
* and after vm_page_array.
*/
return (EINVAL);
} else {
alloc:
#endif
fp = malloc(page_count * sizeof(struct vm_page), M_FICT_PAGES,
M_WAITOK);
#ifdef VM_PHYSSEG_DENSE
}
#endif
vm_phys_fictitious_init_range(fp, start, page_count, memattr);
seg = malloc(sizeof(*seg), M_FICT_PAGES, M_WAITOK | M_ZERO);
seg->start = start;
seg->end = end;
seg->first_page = fp;
rw_wlock(&vm_phys_fictitious_reg_lock);
RB_INSERT(fict_tree, &vm_phys_fictitious_tree, seg);
rw_wunlock(&vm_phys_fictitious_reg_lock);
return (0);
}
void
vm_phys_fictitious_unreg_range(vm_paddr_t start, vm_paddr_t end)
{
struct vm_phys_fictitious_seg *seg, tmp;
#ifdef VM_PHYSSEG_DENSE
long pi, pe;
#endif
KASSERT(start < end,
("Start of segment isn't less than end (start: %jx end: %jx)",
(uintmax_t)start, (uintmax_t)end));
#ifdef VM_PHYSSEG_DENSE
pi = atop(start);
pe = atop(end);
if (pi >= first_page && (pi - first_page) < vm_page_array_size) {
if ((pe - first_page) <= vm_page_array_size) {
/*
* This segment was allocated using vm_page_array
* only, there's nothing to do since those pages
* were never added to the tree.
*/
return;
}
/*
* We have a segment that starts inside
* of vm_page_array, but ends outside of it.
*
* Calculate how many pages were added to the
* tree and free them.
*/
start = ptoa(first_page + vm_page_array_size);
} else if (pe > first_page && (pe - first_page) < vm_page_array_size) {
/*
* We have a segment that ends inside of vm_page_array,
* but starts outside of it.
*/
end = ptoa(first_page);
} else if (pi < first_page && pe > (first_page + vm_page_array_size)) {
/* Since it's not possible to register such a range, panic. */
panic(
"Unregistering not registered fictitious range [%#jx:%#jx]",
(uintmax_t)start, (uintmax_t)end);
}
#endif
tmp.start = start;
tmp.end = 0;
rw_wlock(&vm_phys_fictitious_reg_lock);
seg = RB_FIND(fict_tree, &vm_phys_fictitious_tree, &tmp);
if (seg->start != start || seg->end != end) {
rw_wunlock(&vm_phys_fictitious_reg_lock);
panic(
"Unregistering not registered fictitious range [%#jx:%#jx]",
(uintmax_t)start, (uintmax_t)end);
}
RB_REMOVE(fict_tree, &vm_phys_fictitious_tree, seg);
rw_wunlock(&vm_phys_fictitious_reg_lock);
free(seg->first_page, M_FICT_PAGES);
free(seg, M_FICT_PAGES);
}
/*
* Free a contiguous, power of two-sized set of physical pages.
*
* The free page queues must be locked.
*/
void
vm_phys_free_pages(vm_page_t m, int order)
{
struct vm_freelist *fl;
struct vm_phys_seg *seg;
vm_paddr_t pa;
vm_page_t m_buddy;
KASSERT(m->order == VM_NFREEORDER,
("vm_phys_free_pages: page %p has unexpected order %d",
m, m->order));
KASSERT(m->pool < VM_NFREEPOOL,
("vm_phys_free_pages: page %p has unexpected pool %d",
m, m->pool));
KASSERT(order < VM_NFREEORDER,
("vm_phys_free_pages: order %d is out of range", order));
seg = &vm_phys_segs[m->segind];
vm_domain_free_assert_locked(VM_DOMAIN(seg->domain));
if (order < VM_NFREEORDER - 1) {
pa = VM_PAGE_TO_PHYS(m);
do {
pa ^= ((vm_paddr_t)1 << (PAGE_SHIFT + order));
if (pa < seg->start || pa >= seg->end)
break;
m_buddy = &seg->first_page[atop(pa - seg->start)];
if (m_buddy->order != order)
break;
fl = (*seg->free_queues)[m_buddy->pool];
vm_freelist_rem(fl, m_buddy, order);
if (m_buddy->pool != m->pool)
vm_phys_set_pool(m->pool, m_buddy, order);
order++;
pa &= ~(((vm_paddr_t)1 << (PAGE_SHIFT + order)) - 1);
m = &seg->first_page[atop(pa - seg->start)];
} while (order < VM_NFREEORDER - 1);
}
fl = (*seg->free_queues)[m->pool];
vm_freelist_add(fl, m, order, 1);
}
/*
* Return the largest possible order of a set of pages starting at m.
*/
static int
max_order(vm_page_t m)
{
/*
* Unsigned "min" is used here so that "order" is assigned
* "VM_NFREEORDER - 1" when "m"'s physical address is zero
* or the low-order bits of its physical address are zero
* because the size of a physical address exceeds the size of
* a long.
*/
return (min(ffsl(VM_PAGE_TO_PHYS(m) >> PAGE_SHIFT) - 1,
VM_NFREEORDER - 1));
}
/*
* Free a contiguous, arbitrarily sized set of physical pages, without
* merging across set boundaries.
*
* The free page queues must be locked.
*/
void
vm_phys_enqueue_contig(vm_page_t m, u_long npages)
{
struct vm_freelist *fl;
struct vm_phys_seg *seg;
vm_page_t m_end;
int order;
/*
* Avoid unnecessary coalescing by freeing the pages in the largest
* possible power-of-two-sized subsets.
*/
vm_domain_free_assert_locked(vm_pagequeue_domain(m));
seg = &vm_phys_segs[m->segind];
fl = (*seg->free_queues)[m->pool];
m_end = m + npages;
/* Free blocks of increasing size. */
while ((order = max_order(m)) < VM_NFREEORDER - 1 &&
m + (1 << order) <= m_end) {
KASSERT(seg == &vm_phys_segs[m->segind],
("%s: page range [%p,%p) spans multiple segments",
__func__, m_end - npages, m));
vm_freelist_add(fl, m, order, 1);
m += 1 << order;
}
/* Free blocks of maximum size. */
while (m + (1 << order) <= m_end) {
KASSERT(seg == &vm_phys_segs[m->segind],
("%s: page range [%p,%p) spans multiple segments",
__func__, m_end - npages, m));
vm_freelist_add(fl, m, order, 1);
m += 1 << order;
}
/* Free blocks of diminishing size. */
while (m < m_end) {
KASSERT(seg == &vm_phys_segs[m->segind],
("%s: page range [%p,%p) spans multiple segments",
__func__, m_end - npages, m));
order = flsl(m_end - m) - 1;
vm_freelist_add(fl, m, order, 1);
m += 1 << order;
}
}
/*
* Free a contiguous, arbitrarily sized set of physical pages.
*
* The free page queues must be locked.
*/
void
vm_phys_free_contig(vm_page_t m, u_long npages)
{
int order_start, order_end;
vm_page_t m_start, m_end;
vm_domain_free_assert_locked(vm_pagequeue_domain(m));
m_start = m;
order_start = max_order(m_start);
if (order_start < VM_NFREEORDER - 1)
m_start += 1 << order_start;
m_end = m + npages;
order_end = max_order(m_end);
if (order_end < VM_NFREEORDER - 1)
m_end -= 1 << order_end;
/*
* Avoid unnecessary coalescing by freeing the pages at the start and
* end of the range last.
*/
if (m_start < m_end)
vm_phys_enqueue_contig(m_start, m_end - m_start);
if (order_start < VM_NFREEORDER - 1)
vm_phys_free_pages(m, order_start);
if (order_end < VM_NFREEORDER - 1)
vm_phys_free_pages(m_end, order_end);
}
/*
* Scan physical memory between the specified addresses "low" and "high" for a
* run of contiguous physical pages that satisfy the specified conditions, and
* return the lowest page in the run. The specified "alignment" determines
* the alignment of the lowest physical page in the run. If the specified
* "boundary" is non-zero, then the run of physical pages cannot span a
* physical address that is a multiple of "boundary".
*
* "npages" must be greater than zero. Both "alignment" and "boundary" must
* be a power of two.
*/
vm_page_t
vm_phys_scan_contig(int domain, u_long npages, vm_paddr_t low, vm_paddr_t high,
u_long alignment, vm_paddr_t boundary, int options)
{
vm_paddr_t pa_end;
vm_page_t m_end, m_run, m_start;
struct vm_phys_seg *seg;
int segind;
KASSERT(npages > 0, ("npages is 0"));
KASSERT(powerof2(alignment), ("alignment is not a power of 2"));
KASSERT(powerof2(boundary), ("boundary is not a power of 2"));
if (low >= high)
return (NULL);
for (segind = 0; segind < vm_phys_nsegs; segind++) {
seg = &vm_phys_segs[segind];
if (seg->domain != domain)
continue;
if (seg->start >= high)
break;
if (low >= seg->end)
continue;
if (low <= seg->start)
m_start = seg->first_page;
else
m_start = &seg->first_page[atop(low - seg->start)];
if (high < seg->end)
pa_end = high;
else
pa_end = seg->end;
if (pa_end - VM_PAGE_TO_PHYS(m_start) < ptoa(npages))
continue;
m_end = &seg->first_page[atop(pa_end - seg->start)];
m_run = vm_page_scan_contig(npages, m_start, m_end,
alignment, boundary, options);
if (m_run != NULL)
return (m_run);
}
return (NULL);
}
/*
* Search for the given physical page "m" in the free lists. If the search
* succeeds, remove "m" from the free lists and return TRUE. Otherwise, return
* FALSE, indicating that "m" is not in the free lists.
*
* The free page queues must be locked.
*/
boolean_t
vm_phys_unfree_page(vm_page_t m)
{
struct vm_freelist *fl;
struct vm_phys_seg *seg;
vm_paddr_t pa, pa_half;
vm_page_t m_set, m_tmp;
int order;
/*
* First, find the contiguous, power of two-sized set of free
* physical pages containing the given physical page "m" and
* assign it to "m_set".
*/
seg = &vm_phys_segs[m->segind];
vm_domain_free_assert_locked(VM_DOMAIN(seg->domain));
for (m_set = m, order = 0; m_set->order == VM_NFREEORDER &&
order < VM_NFREEORDER - 1; ) {
order++;
pa = m->phys_addr & (~(vm_paddr_t)0 << (PAGE_SHIFT + order));
if (pa >= seg->start)
m_set = &seg->first_page[atop(pa - seg->start)];
else
return (FALSE);
}
if (m_set->order < order)
return (FALSE);
if (m_set->order == VM_NFREEORDER)
return (FALSE);
KASSERT(m_set->order < VM_NFREEORDER,
("vm_phys_unfree_page: page %p has unexpected order %d",
m_set, m_set->order));
/*
* Next, remove "m_set" from the free lists. Finally, extract
* "m" from "m_set" using an iterative algorithm: While "m_set"
* is larger than a page, shrink "m_set" by returning the half
* of "m_set" that does not contain "m" to the free lists.
*/
fl = (*seg->free_queues)[m_set->pool];
order = m_set->order;
vm_freelist_rem(fl, m_set, order);
while (order > 0) {
order--;
pa_half = m_set->phys_addr ^ (1 << (PAGE_SHIFT + order));
if (m->phys_addr < pa_half)
m_tmp = &seg->first_page[atop(pa_half - seg->start)];
else {
m_tmp = m_set;
m_set = &seg->first_page[atop(pa_half - seg->start)];
}
vm_freelist_add(fl, m_tmp, order, 0);
}
KASSERT(m_set == m, ("vm_phys_unfree_page: fatal inconsistency"));
return (TRUE);
}
/*
* Allocate a run of contiguous physical pages from the specified free list
* table.
*/
static vm_page_t
vm_phys_alloc_queues_contig(
struct vm_freelist (*queues)[VM_NFREEPOOL][VM_NFREEORDER_MAX],
u_long npages, vm_paddr_t low, vm_paddr_t high,
u_long alignment, vm_paddr_t boundary)
{
struct vm_phys_seg *seg;
struct vm_freelist *fl;
vm_paddr_t pa, pa_end, size;
vm_page_t m, m_ret;
u_long npages_end;
int oind, order, pind;
KASSERT(npages > 0, ("npages is 0"));
KASSERT(powerof2(alignment), ("alignment is not a power of 2"));
KASSERT(powerof2(boundary), ("boundary is not a power of 2"));
/* Compute the queue that is the best fit for npages. */
order = flsl(npages - 1);
/* Search for a run satisfying the specified conditions. */
size = npages << PAGE_SHIFT;
for (oind = min(order, VM_NFREEORDER - 1); oind < VM_NFREEORDER;
oind++) {
for (pind = 0; pind < VM_NFREEPOOL; pind++) {
fl = (*queues)[pind];
TAILQ_FOREACH(m_ret, &fl[oind].pl, listq) {
/*
* Determine if the address range starting at pa
* is within the given range, satisfies the
* given alignment, and does not cross the given
* boundary.
*/
pa = VM_PAGE_TO_PHYS(m_ret);
pa_end = pa + size;
if (pa < low || pa_end > high ||
!vm_addr_ok(pa, size, alignment, boundary))
continue;
/*
* Is the size of this allocation request
* no more than the largest block size?
*/
if (order < VM_NFREEORDER)
goto done;
/*
* Determine if the address range is valid
* (without overflow in pa_end calculation)
* and fits within the segment.
*/
seg = &vm_phys_segs[m_ret->segind];
if (pa_end < pa || seg->end < pa_end)
continue;
/*
* Determine if a series of free oind-blocks
* starting here can satisfy the allocation
* request.
*/
do {
pa += 1 <<
(PAGE_SHIFT + VM_NFREEORDER - 1);
if (pa >= pa_end)
goto done;
} while (VM_NFREEORDER - 1 == seg->first_page[
atop(pa - seg->start)].order);
/*
* Determine if an additional series of free
* blocks of diminishing size can help to
* satisfy the allocation request.
*/
for (;;) {
m = &seg->first_page[
atop(pa - seg->start)];
if (m->order == VM_NFREEORDER ||
pa + (2 << (PAGE_SHIFT + m->order))
<= pa_end)
break;
pa += 1 << (PAGE_SHIFT + m->order);
if (pa >= pa_end)
goto done;
}
}
}
}
return (NULL);
done:
for (m = m_ret; m < &m_ret[npages]; m = &m[1 << oind]) {
fl = (*queues)[m->pool];
oind = m->order;
vm_freelist_rem(fl, m, oind);
if (m->pool != VM_FREEPOOL_DEFAULT)
vm_phys_set_pool(VM_FREEPOOL_DEFAULT, m, oind);
}
/* Return excess pages to the free lists. */
npages_end = roundup2(npages, 1 << oind);
if (npages < npages_end) {
fl = (*queues)[VM_FREEPOOL_DEFAULT];
vm_phys_enq_range(&m_ret[npages], npages_end - npages, fl, 0);
}
return (m_ret);
}
/*
* Allocate a contiguous set of physical pages of the given size
* "npages" from the free lists. All of the physical pages must be at
* or above the given physical address "low" and below the given
* physical address "high". The given value "alignment" determines the
* alignment of the first physical page in the set. If the given value
* "boundary" is non-zero, then the set of physical pages cannot cross
* any physical address boundary that is a multiple of that value. Both
* "alignment" and "boundary" must be a power of two.
*/
vm_page_t
vm_phys_alloc_contig(int domain, u_long npages, vm_paddr_t low, vm_paddr_t high,
u_long alignment, vm_paddr_t boundary)
{
vm_paddr_t pa_end, pa_start;
vm_page_t m_run;
struct vm_phys_seg *seg;
struct vm_freelist (*queues)[VM_NFREEPOOL][VM_NFREEORDER_MAX];
int segind;
KASSERT(npages > 0, ("npages is 0"));
KASSERT(powerof2(alignment), ("alignment is not a power of 2"));
KASSERT(powerof2(boundary), ("boundary is not a power of 2"));
vm_domain_free_assert_locked(VM_DOMAIN(domain));
if (low >= high)
return (NULL);
queues = NULL;
m_run = NULL;
for (segind = vm_phys_nsegs - 1; segind >= 0; segind--) {
seg = &vm_phys_segs[segind];
if (seg->start >= high || seg->domain != domain)
continue;
if (low >= seg->end)
break;
if (low <= seg->start)
pa_start = seg->start;
else
pa_start = low;
if (high < seg->end)
pa_end = high;
else
pa_end = seg->end;
if (pa_end - pa_start < ptoa(npages))
continue;
/*
* If a previous segment led to a search using
* the same free lists as would this segment, then
* we've actually already searched within this
* too. So skip it.
*/
if (seg->free_queues == queues)
continue;
queues = seg->free_queues;
m_run = vm_phys_alloc_queues_contig(queues, npages,
low, high, alignment, boundary);
if (m_run != NULL)
break;
}
return (m_run);
}
/*
* Return the index of the first unused slot which may be the terminating
* entry.
*/
static int
vm_phys_avail_count(void)
{
int i;
for (i = 0; phys_avail[i + 1]; i += 2)
continue;
if (i > PHYS_AVAIL_ENTRIES)
panic("Improperly terminated phys_avail %d entries", i);
return (i);
}
/*
* Assert that a phys_avail entry is valid.
*/
static void
vm_phys_avail_check(int i)
{
if (phys_avail[i] & PAGE_MASK)
panic("Unaligned phys_avail[%d]: %#jx", i,
(intmax_t)phys_avail[i]);
if (phys_avail[i+1] & PAGE_MASK)
panic("Unaligned phys_avail[%d + 1]: %#jx", i,
(intmax_t)phys_avail[i]);
if (phys_avail[i + 1] < phys_avail[i])
panic("phys_avail[%d] start %#jx < end %#jx", i,
(intmax_t)phys_avail[i], (intmax_t)phys_avail[i+1]);
}
/*
* Return the index of an overlapping phys_avail entry or -1.
*/
#ifdef NUMA
static int
vm_phys_avail_find(vm_paddr_t pa)
{
int i;
for (i = 0; phys_avail[i + 1]; i += 2)
if (phys_avail[i] <= pa && phys_avail[i + 1] > pa)
return (i);
return (-1);
}
#endif
/*
* Return the index of the largest entry.
*/
int
vm_phys_avail_largest(void)
{
vm_paddr_t sz, largesz;
int largest;
int i;
largest = 0;
largesz = 0;
for (i = 0; phys_avail[i + 1]; i += 2) {
sz = vm_phys_avail_size(i);
if (sz > largesz) {
largesz = sz;
largest = i;
}
}
return (largest);
}
vm_paddr_t
vm_phys_avail_size(int i)
{
return (phys_avail[i + 1] - phys_avail[i]);
}
/*
* Split an entry at the address 'pa'. Return zero on success or errno.
*/
static int
vm_phys_avail_split(vm_paddr_t pa, int i)
{
int cnt;
vm_phys_avail_check(i);
if (pa <= phys_avail[i] || pa >= phys_avail[i + 1])
panic("vm_phys_avail_split: invalid address");
cnt = vm_phys_avail_count();
if (cnt >= PHYS_AVAIL_ENTRIES)
return (ENOSPC);
memmove(&phys_avail[i + 2], &phys_avail[i],
(cnt - i) * sizeof(phys_avail[0]));
phys_avail[i + 1] = pa;
phys_avail[i + 2] = pa;
vm_phys_avail_check(i);
vm_phys_avail_check(i+2);
return (0);
}
/*
* Check if a given physical address can be included as part of a crash dump.
*/
bool
vm_phys_is_dumpable(vm_paddr_t pa)
{
vm_page_t m;
int i;
if ((m = vm_phys_paddr_to_vm_page(pa)) != NULL)
return ((m->flags & PG_NODUMP) == 0);
for (i = 0; dump_avail[i] != 0 || dump_avail[i + 1] != 0; i += 2) {
if (pa >= dump_avail[i] && pa < dump_avail[i + 1])
return (true);
}
return (false);
}
void
vm_phys_early_add_seg(vm_paddr_t start, vm_paddr_t end)
{
struct vm_phys_seg *seg;
if (vm_phys_early_nsegs == -1)
panic("%s: called after initialization", __func__);
if (vm_phys_early_nsegs == nitems(vm_phys_early_segs))
panic("%s: ran out of early segments", __func__);
seg = &vm_phys_early_segs[vm_phys_early_nsegs++];
seg->start = start;
seg->end = end;
}
/*
* This routine allocates NUMA node specific memory before the page
* allocator is bootstrapped.
*/
vm_paddr_t
vm_phys_early_alloc(int domain, size_t alloc_size)
{
#ifdef NUMA
int mem_index;
#endif
int i, biggestone;
vm_paddr_t pa, mem_start, mem_end, size, biggestsize, align;
KASSERT(domain == -1 || (domain >= 0 && domain < vm_ndomains),
("%s: invalid domain index %d", __func__, domain));
/*
* Search the mem_affinity array for the biggest address
* range in the desired domain. This is used to constrain
* the phys_avail selection below.
*/
biggestsize = 0;
mem_start = 0;
mem_end = -1;
#ifdef NUMA
mem_index = 0;
if (mem_affinity != NULL) {
for (i = 0;; i++) {
size = mem_affinity[i].end - mem_affinity[i].start;
if (size == 0)
break;
if (domain != -1 && mem_affinity[i].domain != domain)
continue;
if (size > biggestsize) {
mem_index = i;
biggestsize = size;
}
}
mem_start = mem_affinity[mem_index].start;
mem_end = mem_affinity[mem_index].end;
}
#endif
/*
* Now find biggest physical segment in within the desired
* numa domain.
*/
biggestsize = 0;
biggestone = 0;
for (i = 0; phys_avail[i + 1] != 0; i += 2) {
/* skip regions that are out of range */
if (phys_avail[i+1] - alloc_size < mem_start ||
phys_avail[i+1] > mem_end)
continue;
size = vm_phys_avail_size(i);
if (size > biggestsize) {
biggestone = i;
biggestsize = size;
}
}
alloc_size = round_page(alloc_size);
/*
* Grab single pages from the front to reduce fragmentation.
*/
if (alloc_size == PAGE_SIZE) {
pa = phys_avail[biggestone];
phys_avail[biggestone] += PAGE_SIZE;
vm_phys_avail_check(biggestone);
return (pa);
}
/*
* Naturally align large allocations.
*/
align = phys_avail[biggestone + 1] & (alloc_size - 1);
if (alloc_size + align > biggestsize)
panic("cannot find a large enough size\n");
if (align != 0 &&
vm_phys_avail_split(phys_avail[biggestone + 1] - align,
biggestone) != 0)
/* Wasting memory. */
phys_avail[biggestone + 1] -= align;
phys_avail[biggestone + 1] -= alloc_size;
vm_phys_avail_check(biggestone);
pa = phys_avail[biggestone + 1];
return (pa);
}
void
vm_phys_early_startup(void)
{
struct vm_phys_seg *seg;
int i;
for (i = 0; phys_avail[i + 1] != 0; i += 2) {
phys_avail[i] = round_page(phys_avail[i]);
phys_avail[i + 1] = trunc_page(phys_avail[i + 1]);
}
for (i = 0; i < vm_phys_early_nsegs; i++) {
seg = &vm_phys_early_segs[i];
vm_phys_add_seg(seg->start, seg->end);
}
vm_phys_early_nsegs = -1;
#ifdef NUMA
/* Force phys_avail to be split by domain. */
if (mem_affinity != NULL) {
int idx;
for (i = 0; mem_affinity[i].end != 0; i++) {
idx = vm_phys_avail_find(mem_affinity[i].start);
if (idx != -1 &&
phys_avail[idx] != mem_affinity[i].start)
vm_phys_avail_split(mem_affinity[i].start, idx);
idx = vm_phys_avail_find(mem_affinity[i].end);
if (idx != -1 &&
phys_avail[idx] != mem_affinity[i].end)
vm_phys_avail_split(mem_affinity[i].end, idx);
}
}
#endif
}
#ifdef DDB
/*
* Show the number of physical pages in each of the free lists.
*/
DB_SHOW_COMMAND(freepages, db_show_freepages)
{
struct vm_freelist *fl;
int flind, oind, pind, dom;
for (dom = 0; dom < vm_ndomains; dom++) {
db_printf("DOMAIN: %d\n", dom);
for (flind = 0; flind < vm_nfreelists; flind++) {
db_printf("FREE LIST %d:\n"
"\n ORDER (SIZE) | NUMBER"
"\n ", flind);
for (pind = 0; pind < VM_NFREEPOOL; pind++)
db_printf(" | POOL %d", pind);
db_printf("\n-- ");
for (pind = 0; pind < VM_NFREEPOOL; pind++)
db_printf("-- -- ");
db_printf("--\n");
for (oind = VM_NFREEORDER - 1; oind >= 0; oind--) {
db_printf(" %2.2d (%6.6dK)", oind,
1 << (PAGE_SHIFT - 10 + oind));
for (pind = 0; pind < VM_NFREEPOOL; pind++) {
fl = vm_phys_free_queues[dom][flind][pind];
db_printf(" | %6.6d", fl[oind].lcnt);
}
db_printf("\n");
}
db_printf("\n");
}
db_printf("\n");
}
}
#endif