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|
/* $OpenBSD: uvm_amap.c,v 1.76 2016/07/27 14:48:56 tedu Exp $ */
/* $NetBSD: uvm_amap.c,v 1.27 2000/11/25 06:27:59 chs Exp $ */
/*
* Copyright (c) 1997 Charles D. Cranor and Washington University.
* All rights reserved.
*
* 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 AUTHOR ``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 AUTHOR 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.
*/
/*
* uvm_amap.c: amap operations
*
* this file contains functions that perform operations on amaps. see
* uvm_amap.h for a brief explanation of the role of amaps in uvm.
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/malloc.h>
#include <sys/kernel.h>
#include <sys/pool.h>
#include <sys/atomic.h>
#include <uvm/uvm.h>
#include <uvm/uvm_swap.h>
/*
* pools for allocation of vm_amap structures. note that in order to
* avoid an endless loop, the amap pool's allocator cannot allocate
* memory from an amap (it currently goes through the kernel uobj, so
* we are ok).
*/
struct pool uvm_amap_pool;
struct pool uvm_small_amap_pool[UVM_AMAP_CHUNK];
struct pool uvm_amap_chunk_pool;
LIST_HEAD(, vm_amap) amap_list;
static char amap_small_pool_names[UVM_AMAP_CHUNK][9];
/*
* local functions
*/
static struct vm_amap *amap_alloc1(int, int, int);
static __inline void amap_list_insert(struct vm_amap *);
static __inline void amap_list_remove(struct vm_amap *);
struct vm_amap_chunk *amap_chunk_get(struct vm_amap *, int, int, int);
void amap_chunk_free(struct vm_amap *, struct vm_amap_chunk *);
void amap_wiperange_chunk(struct vm_amap *, struct vm_amap_chunk *, int, int);
static __inline void
amap_list_insert(struct vm_amap *amap)
{
LIST_INSERT_HEAD(&amap_list, amap, am_list);
}
static __inline void
amap_list_remove(struct vm_amap *amap)
{
LIST_REMOVE(amap, am_list);
}
/*
* amap_chunk_get: lookup a chunk for slot. if create is non-zero,
* the chunk is created if it does not yet exist.
*
* => returns the chunk on success or NULL on error
*/
struct vm_amap_chunk *
amap_chunk_get(struct vm_amap *amap, int slot, int create, int waitf)
{
int bucket = UVM_AMAP_BUCKET(amap, slot);
int baseslot = AMAP_BASE_SLOT(slot);
int n;
struct vm_amap_chunk *chunk, *newchunk, *pchunk = NULL;
if (UVM_AMAP_SMALL(amap))
return &amap->am_small;
for (chunk = amap->am_buckets[bucket]; chunk != NULL;
chunk = TAILQ_NEXT(chunk, ac_list)) {
if (UVM_AMAP_BUCKET(amap, chunk->ac_baseslot) != bucket)
break;
if (chunk->ac_baseslot == baseslot)
return chunk;
pchunk = chunk;
}
if (!create)
return NULL;
if (amap->am_nslot - baseslot >= UVM_AMAP_CHUNK)
n = UVM_AMAP_CHUNK;
else
n = amap->am_nslot - baseslot;
newchunk = pool_get(&uvm_amap_chunk_pool, waitf | PR_ZERO);
if (newchunk == NULL)
return NULL;
if (pchunk == NULL) {
TAILQ_INSERT_TAIL(&amap->am_chunks, newchunk, ac_list);
KASSERT(amap->am_buckets[bucket] == NULL);
amap->am_buckets[bucket] = newchunk;
} else
TAILQ_INSERT_AFTER(&amap->am_chunks, pchunk, newchunk,
ac_list);
amap->am_ncused++;
newchunk->ac_baseslot = baseslot;
newchunk->ac_nslot = n;
return newchunk;
}
void
amap_chunk_free(struct vm_amap *amap, struct vm_amap_chunk *chunk)
{
int bucket = UVM_AMAP_BUCKET(amap, chunk->ac_baseslot);
struct vm_amap_chunk *nchunk;
if (UVM_AMAP_SMALL(amap))
return;
nchunk = TAILQ_NEXT(chunk, ac_list);
TAILQ_REMOVE(&amap->am_chunks, chunk, ac_list);
if (amap->am_buckets[bucket] == chunk) {
if (nchunk != NULL &&
UVM_AMAP_BUCKET(amap, nchunk->ac_baseslot) == bucket)
amap->am_buckets[bucket] = nchunk;
else
amap->am_buckets[bucket] = NULL;
}
pool_put(&uvm_amap_chunk_pool, chunk);
amap->am_ncused--;
}
#ifdef UVM_AMAP_PPREF
/*
* what is ppref? ppref is an _optional_ amap feature which is used
* to keep track of reference counts on a per-page basis. it is enabled
* when UVM_AMAP_PPREF is defined.
*
* when enabled, an array of ints is allocated for the pprefs. this
* array is allocated only when a partial reference is added to the
* map (either by unmapping part of the amap, or gaining a reference
* to only a part of an amap). if the malloc of the array fails
* (M_NOWAIT), then we set the array pointer to PPREF_NONE to indicate
* that we tried to do ppref's but couldn't alloc the array so just
* give up (after all, this is an optional feature!).
*
* the array is divided into page sized "chunks." for chunks of length 1,
* the chunk reference count plus one is stored in that chunk's slot.
* for chunks of length > 1 the first slot contains (the reference count
* plus one) * -1. [the negative value indicates that the length is
* greater than one.] the second slot of the chunk contains the length
* of the chunk. here is an example:
*
* actual REFS: 2 2 2 2 3 1 1 0 0 0 4 4 0 1 1 1
* ppref: -3 4 x x 4 -2 2 -1 3 x -5 2 1 -2 3 x
* <----------><-><----><-------><----><-><------->
* (x = don't care)
*
* this allows us to allow one int to contain the ref count for the whole
* chunk. note that the "plus one" part is needed because a reference
* count of zero is neither positive or negative (need a way to tell
* if we've got one zero or a bunch of them).
*
* here are some in-line functions to help us.
*/
static __inline void pp_getreflen(int *, int, int *, int *);
static __inline void pp_setreflen(int *, int, int, int);
/*
* pp_getreflen: get the reference and length for a specific offset
*/
static __inline void
pp_getreflen(int *ppref, int offset, int *refp, int *lenp)
{
if (ppref[offset] > 0) { /* chunk size must be 1 */
*refp = ppref[offset] - 1; /* don't forget to adjust */
*lenp = 1;
} else {
*refp = (ppref[offset] * -1) - 1;
*lenp = ppref[offset+1];
}
}
/*
* pp_setreflen: set the reference and length for a specific offset
*/
static __inline void
pp_setreflen(int *ppref, int offset, int ref, int len)
{
if (len == 1) {
ppref[offset] = ref + 1;
} else {
ppref[offset] = (ref + 1) * -1;
ppref[offset+1] = len;
}
}
#endif
/*
* amap_init: called at boot time to init global amap data structures
*/
void
amap_init(void)
{
int i;
size_t size;
/* Initialize the vm_amap pool. */
pool_init(&uvm_amap_pool, sizeof(struct vm_amap), 0, 0, PR_WAITOK,
"amappl", NULL);
pool_setipl(&uvm_amap_pool, IPL_NONE);
pool_sethiwat(&uvm_amap_pool, 4096);
/* initialize small amap pools */
for (i = 0; i < nitems(uvm_small_amap_pool); i++) {
snprintf(amap_small_pool_names[i],
sizeof(amap_small_pool_names[0]), "amappl%d", i + 1);
size = offsetof(struct vm_amap, am_small.ac_anon) +
(i + 1) * sizeof(struct vm_anon *);
pool_init(&uvm_small_amap_pool[i], size, 0, 0, 0,
amap_small_pool_names[i], NULL);
pool_setipl(&uvm_small_amap_pool[i], IPL_NONE);
}
pool_init(&uvm_amap_chunk_pool,
sizeof(struct vm_amap_chunk) +
UVM_AMAP_CHUNK * sizeof(struct vm_anon *), 0, 0, 0,
"amapchunkpl", NULL);
pool_setipl(&uvm_amap_chunk_pool, IPL_NONE);
pool_sethiwat(&uvm_amap_chunk_pool, 4096);
}
/*
* amap_alloc1: internal function that allocates an amap, but does not
* init the overlay.
*/
static inline struct vm_amap *
amap_alloc1(int slots, int waitf, int lazyalloc)
{
struct vm_amap *amap;
struct vm_amap_chunk *chunk, *tmp;
int chunks, chunkperbucket = 1, hashshift = 0;
int buckets, i, n;
int pwaitf = (waitf & M_WAITOK) ? PR_WAITOK : PR_NOWAIT;
KASSERT(slots > 0);
/*
* Cast to unsigned so that rounding up cannot cause integer overflow
* if slots is large.
*/
chunks = roundup((unsigned int)slots, UVM_AMAP_CHUNK) / UVM_AMAP_CHUNK;
if (lazyalloc) {
/*
* Basically, the amap is a hash map where the number of
* buckets is fixed. We select the number of buckets using the
* following strategy:
*
* 1. The maximal number of entries to search in a bucket upon
* a collision should be less than or equal to
* log2(slots / UVM_AMAP_CHUNK). This is the worst-case number
* of lookups we would have if we could chunk the amap. The
* log2(n) comes from the fact that amaps are chunked by
* splitting up their vm_map_entries and organizing those
* in a binary search tree.
*
* 2. The maximal number of entries in a bucket must be a
* power of two.
*
* The maximal number of entries per bucket is used to hash
* a slot to a bucket.
*
* In the future, this strategy could be refined to make it
* even harder/impossible that the total amount of KVA needed
* for the hash buckets of all amaps to exceed the maximal
* amount of KVA memory reserved for amaps.
*/
chunkperbucket = 1 << hashshift;
while ((1 << chunkperbucket) * 2 <= chunks) {
hashshift++;
chunkperbucket = 1 << hashshift;
}
}
if (slots > UVM_AMAP_CHUNK)
amap = pool_get(&uvm_amap_pool, pwaitf);
else
amap = pool_get(&uvm_small_amap_pool[slots - 1],
pwaitf | PR_ZERO);
if (amap == NULL)
return(NULL);
amap->am_ref = 1;
amap->am_flags = 0;
#ifdef UVM_AMAP_PPREF
amap->am_ppref = NULL;
#endif
amap->am_nslot = slots;
amap->am_nused = 0;
if (UVM_AMAP_SMALL(amap)) {
amap->am_small.ac_nslot = slots;
return (amap);
}
amap->am_ncused = 0;
TAILQ_INIT(&amap->am_chunks);
amap->am_hashshift = hashshift;
amap->am_buckets = NULL;
buckets = howmany(chunks, chunkperbucket);
amap->am_buckets = mallocarray(buckets, sizeof(*amap->am_buckets),
M_UVMAMAP, waitf | (lazyalloc ? M_ZERO : 0));
if (amap->am_buckets == NULL)
goto fail1;
if (!lazyalloc) {
for (i = 0; i < buckets; i++) {
if (i == buckets - 1) {
n = slots % UVM_AMAP_CHUNK;
if (n == 0)
n = UVM_AMAP_CHUNK;
} else
n = UVM_AMAP_CHUNK;
chunk = pool_get(&uvm_amap_chunk_pool,
PR_ZERO | pwaitf);
if (chunk == NULL)
goto fail1;
amap->am_buckets[i] = chunk;
amap->am_ncused++;
chunk->ac_baseslot = i * UVM_AMAP_CHUNK;
chunk->ac_nslot = n;
TAILQ_INSERT_TAIL(&amap->am_chunks, chunk, ac_list);
}
}
return(amap);
fail1:
free(amap->am_buckets, M_UVMAMAP, 0);
TAILQ_FOREACH_SAFE(chunk, &amap->am_chunks, ac_list, tmp)
pool_put(&uvm_amap_chunk_pool, chunk);
pool_put(&uvm_amap_pool, amap);
return (NULL);
}
/*
* amap_alloc: allocate an amap to manage "sz" bytes of anonymous VM
*
* => caller should ensure sz is a multiple of PAGE_SIZE
* => reference count to new amap is set to one
*/
struct vm_amap *
amap_alloc(vaddr_t sz, int waitf, int lazyalloc)
{
struct vm_amap *amap;
size_t slots;
AMAP_B2SLOT(slots, sz); /* load slots */
if (slots > INT_MAX)
return (NULL);
amap = amap_alloc1(slots, waitf, lazyalloc);
if (amap)
amap_list_insert(amap);
return(amap);
}
/*
* amap_free: free an amap
*
* => the amap should have a zero reference count and be empty
*/
void
amap_free(struct vm_amap *amap)
{
struct vm_amap_chunk *chunk, *tmp;
KASSERT(amap->am_ref == 0 && amap->am_nused == 0);
KASSERT((amap->am_flags & AMAP_SWAPOFF) == 0);
#ifdef UVM_AMAP_PPREF
if (amap->am_ppref && amap->am_ppref != PPREF_NONE)
free(amap->am_ppref, M_UVMAMAP, 0);
#endif
if (UVM_AMAP_SMALL(amap))
pool_put(&uvm_small_amap_pool[amap->am_nslot - 1], amap);
else {
TAILQ_FOREACH_SAFE(chunk, &amap->am_chunks, ac_list, tmp)
pool_put(&uvm_amap_chunk_pool, chunk);
free(amap->am_buckets, M_UVMAMAP, 0);
pool_put(&uvm_amap_pool, amap);
}
}
/*
* amap_wipeout: wipeout all anon's in an amap; then free the amap!
*
* => called from amap_unref when the final reference to an amap is
* discarded (i.e. when reference count == 1)
*/
void
amap_wipeout(struct vm_amap *amap)
{
int slot;
struct vm_anon *anon;
struct vm_amap_chunk *chunk;
KASSERT(amap->am_ref == 0);
if (__predict_false((amap->am_flags & AMAP_SWAPOFF) != 0)) {
/* amap_swap_off will call us again. */
return;
}
amap_list_remove(amap);
AMAP_CHUNK_FOREACH(chunk, amap) {
int i, refs, map = chunk->ac_usedmap;
for (i = ffs(map); i != 0; i = ffs(map)) {
slot = i - 1;
map ^= 1 << slot;
anon = chunk->ac_anon[slot];
if (anon == NULL || anon->an_ref == 0)
panic("amap_wipeout: corrupt amap");
refs = --anon->an_ref;
if (refs == 0) {
/*
* we had the last reference to a vm_anon.
* free it.
*/
uvm_anfree(anon);
}
}
}
/* now we free the map */
amap->am_ref = 0; /* ... was one */
amap->am_nused = 0;
amap_free(amap); /* will free amap */
}
/*
* amap_copy: ensure that a map entry's "needs_copy" flag is false
* by copying the amap if necessary.
*
* => an entry with a null amap pointer will get a new (blank) one.
* => if canchunk is true, then we may clip the entry into a chunk
* => "startva" and "endva" are used only if canchunk is true. they are
* used to limit chunking (e.g. if you have a large space that you
* know you are going to need to allocate amaps for, there is no point
* in allowing that to be chunked)
*/
void
amap_copy(struct vm_map *map, struct vm_map_entry *entry, int waitf,
boolean_t canchunk, vaddr_t startva, vaddr_t endva)
{
struct vm_amap *amap, *srcamap;
int slots, lcv, lazyalloc = 0;
vaddr_t chunksize;
int i, j, k, n, srcslot;
struct vm_amap_chunk *chunk = NULL, *srcchunk = NULL;
/* is there a map to copy? if not, create one from scratch. */
if (entry->aref.ar_amap == NULL) {
/*
* check to see if we have a large amap that we can
* chunk. we align startva/endva to chunk-sized
* boundaries and then clip to them.
*
* if we cannot chunk the amap, allocate it in a way
* that makes it grow or shrink dynamically with
* the number of slots.
*/
if (atop(entry->end - entry->start) >= UVM_AMAP_LARGE) {
if (canchunk) {
/* convert slots to bytes */
chunksize = UVM_AMAP_CHUNK << PAGE_SHIFT;
startva = (startva / chunksize) * chunksize;
endva = roundup(endva, chunksize);
UVM_MAP_CLIP_START(map, entry, startva);
/* watch out for endva wrap-around! */
if (endva >= startva)
UVM_MAP_CLIP_END(map, entry, endva);
} else
lazyalloc = 1;
}
entry->aref.ar_pageoff = 0;
entry->aref.ar_amap = amap_alloc(entry->end - entry->start,
waitf, lazyalloc);
if (entry->aref.ar_amap != NULL)
entry->etype &= ~UVM_ET_NEEDSCOPY;
return;
}
/*
* first check and see if we are the only map entry
* referencing the amap we currently have. if so, then we can
* just take it over rather than copying it. the value can only
* be one if we have the only reference to the amap
*/
if (entry->aref.ar_amap->am_ref == 1) {
entry->etype &= ~UVM_ET_NEEDSCOPY;
return;
}
/* looks like we need to copy the map. */
AMAP_B2SLOT(slots, entry->end - entry->start);
if (!UVM_AMAP_SMALL(entry->aref.ar_amap) &&
entry->aref.ar_amap->am_hashshift != 0)
lazyalloc = 1;
amap = amap_alloc1(slots, waitf, lazyalloc);
if (amap == NULL)
return;
srcamap = entry->aref.ar_amap;
/*
* need to double check reference count now. the reference count
* could have changed while we were in malloc. if the reference count
* dropped down to one we take over the old map rather than
* copying the amap.
*/
if (srcamap->am_ref == 1) { /* take it over? */
entry->etype &= ~UVM_ET_NEEDSCOPY;
amap->am_ref--; /* drop final reference to map */
amap_free(amap); /* dispose of new (unused) amap */
return;
}
/* we must copy it now. */
for (lcv = 0; lcv < slots; lcv += n) {
srcslot = entry->aref.ar_pageoff + lcv;
i = UVM_AMAP_SLOTIDX(lcv);
j = UVM_AMAP_SLOTIDX(srcslot);
n = UVM_AMAP_CHUNK;
if (i > j)
n -= i;
else
n -= j;
if (lcv + n > slots)
n = slots - lcv;
srcchunk = amap_chunk_get(srcamap, srcslot, 0, PR_NOWAIT);
if (srcchunk == NULL)
continue;
chunk = amap_chunk_get(amap, lcv, 1, PR_NOWAIT);
if (chunk == NULL) {
amap->am_ref = 0;
amap_wipeout(amap);
return;
}
for (k = 0; k < n; i++, j++, k++) {
chunk->ac_anon[i] = srcchunk->ac_anon[j];
if (chunk->ac_anon[i] == NULL)
continue;
chunk->ac_usedmap |= (1 << i);
chunk->ac_anon[i]->an_ref++;
amap->am_nused++;
}
}
/*
* drop our reference to the old amap (srcamap).
* we know that the reference count on srcamap is greater than
* one (we checked above), so there is no way we could drop
* the count to zero. [and no need to worry about freeing it]
*/
srcamap->am_ref--;
if (srcamap->am_ref == 1 && (srcamap->am_flags & AMAP_SHARED) != 0)
srcamap->am_flags &= ~AMAP_SHARED; /* clear shared flag */
#ifdef UVM_AMAP_PPREF
if (srcamap->am_ppref && srcamap->am_ppref != PPREF_NONE) {
amap_pp_adjref(srcamap, entry->aref.ar_pageoff,
(entry->end - entry->start) >> PAGE_SHIFT, -1);
}
#endif
/* install new amap. */
entry->aref.ar_pageoff = 0;
entry->aref.ar_amap = amap;
entry->etype &= ~UVM_ET_NEEDSCOPY;
amap_list_insert(amap);
}
/*
* amap_cow_now: resolve all copy-on-write faults in an amap now for fork(2)
*
* called during fork(2) when the parent process has a wired map
* entry. in that case we want to avoid write-protecting pages
* in the parent's map (e.g. like what you'd do for a COW page)
* so we resolve the COW here.
*
* => assume parent's entry was wired, thus all pages are resident.
* => caller passes child's map/entry in to us
* => XXXCDC: out of memory should cause fork to fail, but there is
* currently no easy way to do this (needs fix)
*/
void
amap_cow_now(struct vm_map *map, struct vm_map_entry *entry)
{
struct vm_amap *amap = entry->aref.ar_amap;
int slot;
struct vm_anon *anon, *nanon;
struct vm_page *pg, *npg;
struct vm_amap_chunk *chunk;
/*
* note that if we wait, we must ReStart the "lcv" for loop because
* some other process could reorder the anon's in the
* am_anon[] array on us.
*/
ReStart:
AMAP_CHUNK_FOREACH(chunk, amap) {
int i, map = chunk->ac_usedmap;
for (i = ffs(map); i != 0; i = ffs(map)) {
slot = i - 1;
map ^= 1 << slot;
anon = chunk->ac_anon[slot];
pg = anon->an_page;
/* page must be resident since parent is wired */
if (pg == NULL)
panic("amap_cow_now: non-resident wired page"
" in anon %p", anon);
/*
* if the anon ref count is one, we are safe (the child
* has exclusive access to the page).
*/
if (anon->an_ref <= 1)
continue;
/*
* if the page is busy then we have to wait for
* it and then restart.
*/
if (pg->pg_flags & PG_BUSY) {
atomic_setbits_int(&pg->pg_flags, PG_WANTED);
UVM_WAIT(pg, FALSE, "cownow", 0);
goto ReStart;
}
/* ok, time to do a copy-on-write to a new anon */
nanon = uvm_analloc();
if (nanon) {
npg = uvm_pagealloc(NULL, 0, nanon, 0);
} else
npg = NULL; /* XXX: quiet gcc warning */
if (nanon == NULL || npg == NULL) {
/* out of memory */
/*
* XXXCDC: we should cause fork to fail, but
* we can't ...
*/
if (nanon) {
uvm_anfree(nanon);
}
uvm_wait("cownowpage");
goto ReStart;
}
/*
* got it... now we can copy the data and replace anon
* with our new one...
*/
uvm_pagecopy(pg, npg); /* old -> new */
anon->an_ref--; /* can't drop to zero */
chunk->ac_anon[slot] = nanon; /* replace */
/*
* drop PG_BUSY on new page ... since we have had its
* owner locked the whole time it can't be
* PG_RELEASED | PG_WANTED.
*/
atomic_clearbits_int(&npg->pg_flags, PG_BUSY|PG_FAKE);
UVM_PAGE_OWN(npg, NULL);
uvm_lock_pageq();
uvm_pageactivate(npg);
uvm_unlock_pageq();
}
}
}
/*
* amap_splitref: split a single reference into two separate references
*
* => called from uvm_map's clip routines
*/
void
amap_splitref(struct vm_aref *origref, struct vm_aref *splitref, vaddr_t offset)
{
int leftslots;
AMAP_B2SLOT(leftslots, offset);
if (leftslots == 0)
panic("amap_splitref: split at zero offset");
/* now: we have a valid am_mapped array. */
if (origref->ar_amap->am_nslot - origref->ar_pageoff - leftslots <= 0)
panic("amap_splitref: map size check failed");
#ifdef UVM_AMAP_PPREF
/* establish ppref before we add a duplicate reference to the amap */
if (origref->ar_amap->am_ppref == NULL)
amap_pp_establish(origref->ar_amap);
#endif
splitref->ar_amap = origref->ar_amap;
splitref->ar_amap->am_ref++; /* not a share reference */
splitref->ar_pageoff = origref->ar_pageoff + leftslots;
}
#ifdef UVM_AMAP_PPREF
/*
* amap_pp_establish: add a ppref array to an amap, if possible
*/
void
amap_pp_establish(struct vm_amap *amap)
{
amap->am_ppref = mallocarray(amap->am_nslot, sizeof(int),
M_UVMAMAP, M_NOWAIT|M_ZERO);
/* if we fail then we just won't use ppref for this amap */
if (amap->am_ppref == NULL) {
amap->am_ppref = PPREF_NONE; /* not using it */
return;
}
/* init ppref */
pp_setreflen(amap->am_ppref, 0, amap->am_ref, amap->am_nslot);
}
/*
* amap_pp_adjref: adjust reference count to a part of an amap using the
* per-page reference count array.
*
* => caller must check that ppref != PPREF_NONE before calling
*/
void
amap_pp_adjref(struct vm_amap *amap, int curslot, vsize_t slotlen, int adjval)
{
int stopslot, *ppref, lcv, prevlcv;
int ref, len, prevref, prevlen;
stopslot = curslot + slotlen;
ppref = amap->am_ppref;
prevlcv = 0;
/*
* first advance to the correct place in the ppref array,
* fragment if needed.
*/
for (lcv = 0 ; lcv < curslot ; lcv += len) {
pp_getreflen(ppref, lcv, &ref, &len);
if (lcv + len > curslot) { /* goes past start? */
pp_setreflen(ppref, lcv, ref, curslot - lcv);
pp_setreflen(ppref, curslot, ref, len - (curslot -lcv));
len = curslot - lcv; /* new length of entry @ lcv */
}
prevlcv = lcv;
}
if (lcv != 0)
pp_getreflen(ppref, prevlcv, &prevref, &prevlen);
else {
/* Ensure that the "prevref == ref" test below always
* fails, since we're starting from the beginning of
* the ppref array; that is, there is no previous
* chunk.
*/
prevref = -1;
prevlen = 0;
}
/*
* now adjust reference counts in range. merge the first
* changed entry with the last unchanged entry if possible.
*/
if (lcv != curslot)
panic("amap_pp_adjref: overshot target");
for (/* lcv already set */; lcv < stopslot ; lcv += len) {
pp_getreflen(ppref, lcv, &ref, &len);
if (lcv + len > stopslot) { /* goes past end? */
pp_setreflen(ppref, lcv, ref, stopslot - lcv);
pp_setreflen(ppref, stopslot, ref,
len - (stopslot - lcv));
len = stopslot - lcv;
}
ref += adjval;
if (ref < 0)
panic("amap_pp_adjref: negative reference count");
if (lcv == prevlcv + prevlen && ref == prevref) {
pp_setreflen(ppref, prevlcv, ref, prevlen + len);
} else {
pp_setreflen(ppref, lcv, ref, len);
}
if (ref == 0)
amap_wiperange(amap, lcv, len);
}
}
void
amap_wiperange_chunk(struct vm_amap *amap, struct vm_amap_chunk *chunk,
int slotoff, int slots)
{
int curslot, i, map;
int startbase, endbase;
struct vm_anon *anon;
startbase = AMAP_BASE_SLOT(slotoff);
endbase = AMAP_BASE_SLOT(slotoff + slots - 1);
map = chunk->ac_usedmap;
if (startbase == chunk->ac_baseslot)
map &= ~((1 << (slotoff - startbase)) - 1);
if (endbase == chunk->ac_baseslot)
map &= (1 << (slotoff + slots - endbase)) - 1;
for (i = ffs(map); i != 0; i = ffs(map)) {
int refs;
curslot = i - 1;
map ^= 1 << curslot;
chunk->ac_usedmap ^= 1 << curslot;
anon = chunk->ac_anon[curslot];
/* remove it from the amap */
chunk->ac_anon[curslot] = NULL;
amap->am_nused--;
/* drop anon reference count */
refs = --anon->an_ref;
if (refs == 0) {
/*
* we just eliminated the last reference to an
* anon. free it.
*/
uvm_anfree(anon);
}
}
}
/*
* amap_wiperange: wipe out a range of an amap
* [different from amap_wipeout because the amap is kept intact]
*/
void
amap_wiperange(struct vm_amap *amap, int slotoff, int slots)
{
int bucket, startbucket, endbucket;
struct vm_amap_chunk *chunk, *nchunk;
startbucket = UVM_AMAP_BUCKET(amap, slotoff);
endbucket = UVM_AMAP_BUCKET(amap, slotoff + slots - 1);
/*
* we can either traverse the amap by am_chunks or by am_buckets
* depending on which is cheaper. decide now.
*/
if (UVM_AMAP_SMALL(amap))
amap_wiperange_chunk(amap, &amap->am_small, slotoff, slots);
else if (endbucket + 1 - startbucket >= amap->am_ncused) {
TAILQ_FOREACH_SAFE(chunk, &amap->am_chunks, ac_list, nchunk) {
if (chunk->ac_baseslot + chunk->ac_nslot <= slotoff)
continue;
if (chunk->ac_baseslot >= slotoff + slots)
continue;
amap_wiperange_chunk(amap, chunk, slotoff, slots);
if (chunk->ac_usedmap == 0)
amap_chunk_free(amap, chunk);
}
} else {
for (bucket = startbucket; bucket <= endbucket; bucket++) {
for (chunk = amap->am_buckets[bucket]; chunk != NULL;
chunk = nchunk) {
nchunk = TAILQ_NEXT(chunk, ac_list);
if (UVM_AMAP_BUCKET(amap, chunk->ac_baseslot) !=
bucket)
break;
if (chunk->ac_baseslot + chunk->ac_nslot <=
slotoff)
continue;
if (chunk->ac_baseslot >= slotoff + slots)
continue;
amap_wiperange_chunk(amap, chunk, slotoff,
slots);
if (chunk->ac_usedmap == 0)
amap_chunk_free(amap, chunk);
}
}
}
}
#endif
/*
* amap_swap_off: pagein anonymous pages in amaps and drop swap slots.
*
* => note that we don't always traverse all anons.
* eg. amaps being wiped out, released anons.
* => return TRUE if failed.
*/
boolean_t
amap_swap_off(int startslot, int endslot)
{
struct vm_amap *am;
struct vm_amap *am_next;
boolean_t rv = FALSE;
for (am = LIST_FIRST(&amap_list); am != NULL && !rv; am = am_next) {
int i, map;
struct vm_amap_chunk *chunk;
again:
AMAP_CHUNK_FOREACH(chunk, am) {
map = chunk->ac_usedmap;
for (i = ffs(map); i != 0; i = ffs(map)) {
int swslot;
int slot = i - 1;
struct vm_anon *anon;
map ^= 1 << slot;
anon = chunk->ac_anon[slot];
swslot = anon->an_swslot;
if (swslot < startslot || endslot <= swslot) {
continue;
}
am->am_flags |= AMAP_SWAPOFF;
rv = uvm_anon_pagein(anon);
am->am_flags &= ~AMAP_SWAPOFF;
if (rv || amap_refs(am) == 0)
goto nextamap;
goto again;
}
}
nextamap:
am_next = LIST_NEXT(am, am_list);
if (amap_refs(am) == 0)
amap_wipeout(am);
}
return rv;
}
/*
* amap_lookup: look up a page in an amap
*/
struct vm_anon *
amap_lookup(struct vm_aref *aref, vaddr_t offset)
{
int slot;
struct vm_amap *amap = aref->ar_amap;
struct vm_amap_chunk *chunk;
AMAP_B2SLOT(slot, offset);
slot += aref->ar_pageoff;
if (slot >= amap->am_nslot)
panic("amap_lookup: offset out of range");
chunk = amap_chunk_get(amap, slot, 0, PR_NOWAIT);
if (chunk == NULL)
return NULL;
return chunk->ac_anon[UVM_AMAP_SLOTIDX(slot)];
}
/*
* amap_lookups: look up a range of pages in an amap
*
* => XXXCDC: this interface is biased toward array-based amaps. fix.
*/
void
amap_lookups(struct vm_aref *aref, vaddr_t offset,
struct vm_anon **anons, int npages)
{
int i, lcv, n, slot;
struct vm_amap *amap = aref->ar_amap;
struct vm_amap_chunk *chunk = NULL;
AMAP_B2SLOT(slot, offset);
slot += aref->ar_pageoff;
if ((slot + (npages - 1)) >= amap->am_nslot)
panic("amap_lookups: offset out of range");
for (i = 0, lcv = slot; lcv < slot + npages; i += n, lcv += n) {
n = UVM_AMAP_CHUNK - UVM_AMAP_SLOTIDX(lcv);
if (lcv + n > slot + npages)
n = slot + npages - lcv;
chunk = amap_chunk_get(amap, lcv, 0, PR_NOWAIT);
if (chunk == NULL)
memset(&anons[i], 0, n * sizeof(*anons));
else
memcpy(&anons[i],
&chunk->ac_anon[UVM_AMAP_SLOTIDX(lcv)],
n * sizeof(*anons));
}
}
/*
* amap_populate: ensure that the amap can store an anon for the page at
* offset. This function can sleep until memory to store the anon is
* available.
*/
void
amap_populate(struct vm_aref *aref, vaddr_t offset)
{
int slot;
struct vm_amap *amap = aref->ar_amap;
struct vm_amap_chunk *chunk;
AMAP_B2SLOT(slot, offset);
slot += aref->ar_pageoff;
if (slot >= amap->am_nslot)
panic("amap_populate: offset out of range");
chunk = amap_chunk_get(amap, slot, 1, PR_WAITOK);
KASSERT(chunk != NULL);
}
/*
* amap_add: add (or replace) a page to an amap
*
* => returns 0 if adding the page was successful or 1 when not.
*/
int
amap_add(struct vm_aref *aref, vaddr_t offset, struct vm_anon *anon,
boolean_t replace)
{
int slot;
struct vm_amap *amap = aref->ar_amap;
struct vm_amap_chunk *chunk;
AMAP_B2SLOT(slot, offset);
slot += aref->ar_pageoff;
if (slot >= amap->am_nslot)
panic("amap_add: offset out of range");
chunk = amap_chunk_get(amap, slot, 1, PR_NOWAIT);
if (chunk == NULL)
return 1;
slot = UVM_AMAP_SLOTIDX(slot);
if (replace) {
if (chunk->ac_anon[slot] == NULL)
panic("amap_add: replacing null anon");
if (chunk->ac_anon[slot]->an_page != NULL &&
(amap->am_flags & AMAP_SHARED) != 0) {
pmap_page_protect(chunk->ac_anon[slot]->an_page,
PROT_NONE);
/*
* XXX: suppose page is supposed to be wired somewhere?
*/
}
} else { /* !replace */
if (chunk->ac_anon[slot] != NULL)
panic("amap_add: slot in use");
chunk->ac_usedmap |= 1 << slot;
amap->am_nused++;
}
chunk->ac_anon[slot] = anon;
return 0;
}
/*
* amap_unadd: remove a page from an amap
*/
void
amap_unadd(struct vm_aref *aref, vaddr_t offset)
{
int slot;
struct vm_amap *amap = aref->ar_amap;
struct vm_amap_chunk *chunk;
AMAP_B2SLOT(slot, offset);
slot += aref->ar_pageoff;
if (slot >= amap->am_nslot)
panic("amap_unadd: offset out of range");
chunk = amap_chunk_get(amap, slot, 0, PR_NOWAIT);
if (chunk == NULL)
panic("amap_unadd: chunk for slot %d not present", slot);
slot = UVM_AMAP_SLOTIDX(slot);
if (chunk->ac_anon[slot] == NULL)
panic("amap_unadd: nothing there");
chunk->ac_anon[slot] = NULL;
chunk->ac_usedmap &= ~(1 << slot);
amap->am_nused--;
if (chunk->ac_usedmap == 0)
amap_chunk_free(amap, chunk);
}
/*
* amap_ref: gain a reference to an amap
*
* => "offset" and "len" are in units of pages
* => called at fork time to gain the child's reference
*/
void
amap_ref(struct vm_amap *amap, vaddr_t offset, vsize_t len, int flags)
{
amap->am_ref++;
if (flags & AMAP_SHARED)
amap->am_flags |= AMAP_SHARED;
#ifdef UVM_AMAP_PPREF
if (amap->am_ppref == NULL && (flags & AMAP_REFALL) == 0 &&
len != amap->am_nslot)
amap_pp_establish(amap);
if (amap->am_ppref && amap->am_ppref != PPREF_NONE) {
if (flags & AMAP_REFALL)
amap_pp_adjref(amap, 0, amap->am_nslot, 1);
else
amap_pp_adjref(amap, offset, len, 1);
}
#endif
}
/*
* amap_unref: remove a reference to an amap
*
* => caller must remove all pmap-level references to this amap before
* dropping the reference
* => called from uvm_unmap_detach [only] ... note that entry is no
* longer part of a map
*/
void
amap_unref(struct vm_amap *amap, vaddr_t offset, vsize_t len, boolean_t all)
{
/* if we are the last reference, free the amap and return. */
if (amap->am_ref-- == 1) {
amap_wipeout(amap); /* drops final ref and frees */
return;
}
/* otherwise just drop the reference count(s) */
if (amap->am_ref == 1 && (amap->am_flags & AMAP_SHARED) != 0)
amap->am_flags &= ~AMAP_SHARED; /* clear shared flag */
#ifdef UVM_AMAP_PPREF
if (amap->am_ppref == NULL && all == 0 && len != amap->am_nslot)
amap_pp_establish(amap);
if (amap->am_ppref && amap->am_ppref != PPREF_NONE) {
if (all)
amap_pp_adjref(amap, 0, amap->am_nslot, -1);
else
amap_pp_adjref(amap, offset, len, -1);
}
#endif
}
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