freebsd-dev/sys/kern/subr_vmem.c
Jonathan T. Looney 0766f278d8 Make UMA and malloc(9) return non-executable memory in most cases.
Most kernel memory that is allocated after boot does not need to be
executable.  There are a few exceptions.  For example, kernel modules
do need executable memory, but they don't use UMA or malloc(9).  The
BPF JIT compiler also needs executable memory and did use malloc(9)
until r317072.

(Note that a side effect of r316767 was that the "small allocation"
path in UMA on amd64 already returned non-executable memory.  This
meant that some calls to malloc(9) or the UMA zone(9) allocator could
return executable memory, while others could return non-executable
memory.  This change makes the behavior consistent.)

This change makes malloc(9) return non-executable memory unless the new
M_EXEC flag is specified.  After this change, the UMA zone(9) allocator
will always return non-executable memory, and a KASSERT will catch
attempts to use the M_EXEC flag to allocate executable memory using
uma_zalloc() or its variants.

Allocations that do need executable memory have various choices.  They
may use the M_EXEC flag to malloc(9), or they may use a different VM
interfact to obtain executable pages.

Now that malloc(9) again allows executable allocations, this change also
reverts most of r317072.

PR:		228927
Reviewed by:	alc, kib, markj, jhb (previous version)
Sponsored by:	Netflix
Differential Revision:	https://reviews.freebsd.org/D15691
2018-06-13 17:04:41 +00:00

1629 lines
38 KiB
C

/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c)2006,2007,2008,2009 YAMAMOTO Takashi,
* Copyright (c) 2013 EMC Corp.
* 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 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 AUTHOR 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.
*/
/*
* From:
* $NetBSD: vmem_impl.h,v 1.2 2013/01/29 21:26:24 para Exp $
* $NetBSD: subr_vmem.c,v 1.83 2013/03/06 11:20:10 yamt Exp $
*/
/*
* reference:
* - Magazines and Vmem: Extending the Slab Allocator
* to Many CPUs and Arbitrary Resources
* http://www.usenix.org/event/usenix01/bonwick.html
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include "opt_ddb.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/queue.h>
#include <sys/callout.h>
#include <sys/hash.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/mutex.h>
#include <sys/smp.h>
#include <sys/condvar.h>
#include <sys/sysctl.h>
#include <sys/taskqueue.h>
#include <sys/vmem.h>
#include <sys/vmmeter.h>
#include "opt_vm.h"
#include <vm/uma.h>
#include <vm/vm.h>
#include <vm/pmap.h>
#include <vm/vm_map.h>
#include <vm/vm_object.h>
#include <vm/vm_kern.h>
#include <vm/vm_extern.h>
#include <vm/vm_param.h>
#include <vm/vm_page.h>
#include <vm/vm_pageout.h>
#include <vm/vm_phys.h>
#include <vm/vm_pagequeue.h>
#include <vm/uma_int.h>
int vmem_startup_count(void);
#define VMEM_OPTORDER 5
#define VMEM_OPTVALUE (1 << VMEM_OPTORDER)
#define VMEM_MAXORDER \
(VMEM_OPTVALUE - 1 + sizeof(vmem_size_t) * NBBY - VMEM_OPTORDER)
#define VMEM_HASHSIZE_MIN 16
#define VMEM_HASHSIZE_MAX 131072
#define VMEM_QCACHE_IDX_MAX 16
#define VMEM_FITMASK (M_BESTFIT | M_FIRSTFIT)
#define VMEM_FLAGS \
(M_NOWAIT | M_WAITOK | M_USE_RESERVE | M_NOVM | M_BESTFIT | M_FIRSTFIT)
#define BT_FLAGS (M_NOWAIT | M_WAITOK | M_USE_RESERVE | M_NOVM)
#define QC_NAME_MAX 16
/*
* Data structures private to vmem.
*/
MALLOC_DEFINE(M_VMEM, "vmem", "vmem internal structures");
typedef struct vmem_btag bt_t;
TAILQ_HEAD(vmem_seglist, vmem_btag);
LIST_HEAD(vmem_freelist, vmem_btag);
LIST_HEAD(vmem_hashlist, vmem_btag);
struct qcache {
uma_zone_t qc_cache;
vmem_t *qc_vmem;
vmem_size_t qc_size;
char qc_name[QC_NAME_MAX];
};
typedef struct qcache qcache_t;
#define QC_POOL_TO_QCACHE(pool) ((qcache_t *)(pool->pr_qcache))
#define VMEM_NAME_MAX 16
/* vmem arena */
struct vmem {
struct mtx_padalign vm_lock;
struct cv vm_cv;
char vm_name[VMEM_NAME_MAX+1];
LIST_ENTRY(vmem) vm_alllist;
struct vmem_hashlist vm_hash0[VMEM_HASHSIZE_MIN];
struct vmem_freelist vm_freelist[VMEM_MAXORDER];
struct vmem_seglist vm_seglist;
struct vmem_hashlist *vm_hashlist;
vmem_size_t vm_hashsize;
/* Constant after init */
vmem_size_t vm_qcache_max;
vmem_size_t vm_quantum_mask;
vmem_size_t vm_import_quantum;
int vm_quantum_shift;
/* Written on alloc/free */
LIST_HEAD(, vmem_btag) vm_freetags;
int vm_nfreetags;
int vm_nbusytag;
vmem_size_t vm_inuse;
vmem_size_t vm_size;
vmem_size_t vm_limit;
/* Used on import. */
vmem_import_t *vm_importfn;
vmem_release_t *vm_releasefn;
void *vm_arg;
/* Space exhaustion callback. */
vmem_reclaim_t *vm_reclaimfn;
/* quantum cache */
qcache_t vm_qcache[VMEM_QCACHE_IDX_MAX];
};
/* boundary tag */
struct vmem_btag {
TAILQ_ENTRY(vmem_btag) bt_seglist;
union {
LIST_ENTRY(vmem_btag) u_freelist; /* BT_TYPE_FREE */
LIST_ENTRY(vmem_btag) u_hashlist; /* BT_TYPE_BUSY */
} bt_u;
#define bt_hashlist bt_u.u_hashlist
#define bt_freelist bt_u.u_freelist
vmem_addr_t bt_start;
vmem_size_t bt_size;
int bt_type;
};
#define BT_TYPE_SPAN 1 /* Allocated from importfn */
#define BT_TYPE_SPAN_STATIC 2 /* vmem_add() or create. */
#define BT_TYPE_FREE 3 /* Available space. */
#define BT_TYPE_BUSY 4 /* Used space. */
#define BT_ISSPAN_P(bt) ((bt)->bt_type <= BT_TYPE_SPAN_STATIC)
#define BT_END(bt) ((bt)->bt_start + (bt)->bt_size - 1)
#if defined(DIAGNOSTIC)
static int enable_vmem_check = 1;
SYSCTL_INT(_debug, OID_AUTO, vmem_check, CTLFLAG_RWTUN,
&enable_vmem_check, 0, "Enable vmem check");
static void vmem_check(vmem_t *);
#endif
static struct callout vmem_periodic_ch;
static int vmem_periodic_interval;
static struct task vmem_periodic_wk;
static struct mtx_padalign __exclusive_cache_line vmem_list_lock;
static LIST_HEAD(, vmem) vmem_list = LIST_HEAD_INITIALIZER(vmem_list);
static uma_zone_t vmem_zone;
/* ---- misc */
#define VMEM_CONDVAR_INIT(vm, wchan) cv_init(&vm->vm_cv, wchan)
#define VMEM_CONDVAR_DESTROY(vm) cv_destroy(&vm->vm_cv)
#define VMEM_CONDVAR_WAIT(vm) cv_wait(&vm->vm_cv, &vm->vm_lock)
#define VMEM_CONDVAR_BROADCAST(vm) cv_broadcast(&vm->vm_cv)
#define VMEM_LOCK(vm) mtx_lock(&vm->vm_lock)
#define VMEM_TRYLOCK(vm) mtx_trylock(&vm->vm_lock)
#define VMEM_UNLOCK(vm) mtx_unlock(&vm->vm_lock)
#define VMEM_LOCK_INIT(vm, name) mtx_init(&vm->vm_lock, (name), NULL, MTX_DEF)
#define VMEM_LOCK_DESTROY(vm) mtx_destroy(&vm->vm_lock)
#define VMEM_ASSERT_LOCKED(vm) mtx_assert(&vm->vm_lock, MA_OWNED);
#define VMEM_ALIGNUP(addr, align) (-(-(addr) & -(align)))
#define VMEM_CROSS_P(addr1, addr2, boundary) \
((((addr1) ^ (addr2)) & -(boundary)) != 0)
#define ORDER2SIZE(order) ((order) < VMEM_OPTVALUE ? ((order) + 1) : \
(vmem_size_t)1 << ((order) - (VMEM_OPTVALUE - VMEM_OPTORDER - 1)))
#define SIZE2ORDER(size) ((size) <= VMEM_OPTVALUE ? ((size) - 1) : \
(flsl(size) + (VMEM_OPTVALUE - VMEM_OPTORDER - 2)))
/*
* Maximum number of boundary tags that may be required to satisfy an
* allocation. Two may be required to import. Another two may be
* required to clip edges.
*/
#define BT_MAXALLOC 4
/*
* Max free limits the number of locally cached boundary tags. We
* just want to avoid hitting the zone allocator for every call.
*/
#define BT_MAXFREE (BT_MAXALLOC * 8)
/* Allocator for boundary tags. */
static uma_zone_t vmem_bt_zone;
/* boot time arena storage. */
static struct vmem kernel_arena_storage;
static struct vmem buffer_arena_storage;
static struct vmem transient_arena_storage;
/* kernel and kmem arenas are aliased for backwards KPI compat. */
vmem_t *kernel_arena = &kernel_arena_storage;
#if VM_NRESERVLEVEL > 0
vmem_t *kernel_rwx_arena = NULL;
#endif
vmem_t *kmem_arena = &kernel_arena_storage;
vmem_t *buffer_arena = &buffer_arena_storage;
vmem_t *transient_arena = &transient_arena_storage;
#ifdef DEBUG_MEMGUARD
static struct vmem memguard_arena_storage;
vmem_t *memguard_arena = &memguard_arena_storage;
#endif
/*
* Fill the vmem's boundary tag cache. We guarantee that boundary tag
* allocation will not fail once bt_fill() passes. To do so we cache
* at least the maximum possible tag allocations in the arena.
*/
static int
bt_fill(vmem_t *vm, int flags)
{
bt_t *bt;
VMEM_ASSERT_LOCKED(vm);
/*
* Only allow the kernel arena and arenas derived from kernel arena to
* dip into reserve tags. They are where new tags come from.
*/
flags &= BT_FLAGS;
if (vm != kernel_arena && vm->vm_arg != kernel_arena)
flags &= ~M_USE_RESERVE;
/*
* Loop until we meet the reserve. To minimize the lock shuffle
* and prevent simultaneous fills we first try a NOWAIT regardless
* of the caller's flags. Specify M_NOVM so we don't recurse while
* holding a vmem lock.
*/
while (vm->vm_nfreetags < BT_MAXALLOC) {
bt = uma_zalloc(vmem_bt_zone,
(flags & M_USE_RESERVE) | M_NOWAIT | M_NOVM);
if (bt == NULL) {
VMEM_UNLOCK(vm);
bt = uma_zalloc(vmem_bt_zone, flags);
VMEM_LOCK(vm);
if (bt == NULL && (flags & M_NOWAIT) != 0)
break;
}
LIST_INSERT_HEAD(&vm->vm_freetags, bt, bt_freelist);
vm->vm_nfreetags++;
}
if (vm->vm_nfreetags < BT_MAXALLOC)
return ENOMEM;
return 0;
}
/*
* Pop a tag off of the freetag stack.
*/
static bt_t *
bt_alloc(vmem_t *vm)
{
bt_t *bt;
VMEM_ASSERT_LOCKED(vm);
bt = LIST_FIRST(&vm->vm_freetags);
MPASS(bt != NULL);
LIST_REMOVE(bt, bt_freelist);
vm->vm_nfreetags--;
return bt;
}
/*
* Trim the per-vmem free list. Returns with the lock released to
* avoid allocator recursions.
*/
static void
bt_freetrim(vmem_t *vm, int freelimit)
{
LIST_HEAD(, vmem_btag) freetags;
bt_t *bt;
LIST_INIT(&freetags);
VMEM_ASSERT_LOCKED(vm);
while (vm->vm_nfreetags > freelimit) {
bt = LIST_FIRST(&vm->vm_freetags);
LIST_REMOVE(bt, bt_freelist);
vm->vm_nfreetags--;
LIST_INSERT_HEAD(&freetags, bt, bt_freelist);
}
VMEM_UNLOCK(vm);
while ((bt = LIST_FIRST(&freetags)) != NULL) {
LIST_REMOVE(bt, bt_freelist);
uma_zfree(vmem_bt_zone, bt);
}
}
static inline void
bt_free(vmem_t *vm, bt_t *bt)
{
VMEM_ASSERT_LOCKED(vm);
MPASS(LIST_FIRST(&vm->vm_freetags) != bt);
LIST_INSERT_HEAD(&vm->vm_freetags, bt, bt_freelist);
vm->vm_nfreetags++;
}
/*
* freelist[0] ... [1, 1]
* freelist[1] ... [2, 2]
* :
* freelist[29] ... [30, 30]
* freelist[30] ... [31, 31]
* freelist[31] ... [32, 63]
* freelist[33] ... [64, 127]
* :
* freelist[n] ... [(1 << (n - 26)), (1 << (n - 25)) - 1]
* :
*/
static struct vmem_freelist *
bt_freehead_tofree(vmem_t *vm, vmem_size_t size)
{
const vmem_size_t qsize = size >> vm->vm_quantum_shift;
const int idx = SIZE2ORDER(qsize);
MPASS(size != 0 && qsize != 0);
MPASS((size & vm->vm_quantum_mask) == 0);
MPASS(idx >= 0);
MPASS(idx < VMEM_MAXORDER);
return &vm->vm_freelist[idx];
}
/*
* bt_freehead_toalloc: return the freelist for the given size and allocation
* strategy.
*
* For M_FIRSTFIT, return the list in which any blocks are large enough
* for the requested size. otherwise, return the list which can have blocks
* large enough for the requested size.
*/
static struct vmem_freelist *
bt_freehead_toalloc(vmem_t *vm, vmem_size_t size, int strat)
{
const vmem_size_t qsize = size >> vm->vm_quantum_shift;
int idx = SIZE2ORDER(qsize);
MPASS(size != 0 && qsize != 0);
MPASS((size & vm->vm_quantum_mask) == 0);
if (strat == M_FIRSTFIT && ORDER2SIZE(idx) != qsize) {
idx++;
/* check too large request? */
}
MPASS(idx >= 0);
MPASS(idx < VMEM_MAXORDER);
return &vm->vm_freelist[idx];
}
/* ---- boundary tag hash */
static struct vmem_hashlist *
bt_hashhead(vmem_t *vm, vmem_addr_t addr)
{
struct vmem_hashlist *list;
unsigned int hash;
hash = hash32_buf(&addr, sizeof(addr), 0);
list = &vm->vm_hashlist[hash % vm->vm_hashsize];
return list;
}
static bt_t *
bt_lookupbusy(vmem_t *vm, vmem_addr_t addr)
{
struct vmem_hashlist *list;
bt_t *bt;
VMEM_ASSERT_LOCKED(vm);
list = bt_hashhead(vm, addr);
LIST_FOREACH(bt, list, bt_hashlist) {
if (bt->bt_start == addr) {
break;
}
}
return bt;
}
static void
bt_rembusy(vmem_t *vm, bt_t *bt)
{
VMEM_ASSERT_LOCKED(vm);
MPASS(vm->vm_nbusytag > 0);
vm->vm_inuse -= bt->bt_size;
vm->vm_nbusytag--;
LIST_REMOVE(bt, bt_hashlist);
}
static void
bt_insbusy(vmem_t *vm, bt_t *bt)
{
struct vmem_hashlist *list;
VMEM_ASSERT_LOCKED(vm);
MPASS(bt->bt_type == BT_TYPE_BUSY);
list = bt_hashhead(vm, bt->bt_start);
LIST_INSERT_HEAD(list, bt, bt_hashlist);
vm->vm_nbusytag++;
vm->vm_inuse += bt->bt_size;
}
/* ---- boundary tag list */
static void
bt_remseg(vmem_t *vm, bt_t *bt)
{
TAILQ_REMOVE(&vm->vm_seglist, bt, bt_seglist);
bt_free(vm, bt);
}
static void
bt_insseg(vmem_t *vm, bt_t *bt, bt_t *prev)
{
TAILQ_INSERT_AFTER(&vm->vm_seglist, prev, bt, bt_seglist);
}
static void
bt_insseg_tail(vmem_t *vm, bt_t *bt)
{
TAILQ_INSERT_TAIL(&vm->vm_seglist, bt, bt_seglist);
}
static void
bt_remfree(vmem_t *vm, bt_t *bt)
{
MPASS(bt->bt_type == BT_TYPE_FREE);
LIST_REMOVE(bt, bt_freelist);
}
static void
bt_insfree(vmem_t *vm, bt_t *bt)
{
struct vmem_freelist *list;
list = bt_freehead_tofree(vm, bt->bt_size);
LIST_INSERT_HEAD(list, bt, bt_freelist);
}
/* ---- vmem internal functions */
/*
* Import from the arena into the quantum cache in UMA.
*/
static int
qc_import(void *arg, void **store, int cnt, int domain, int flags)
{
qcache_t *qc;
vmem_addr_t addr;
int i;
qc = arg;
if ((flags & VMEM_FITMASK) == 0)
flags |= M_BESTFIT;
for (i = 0; i < cnt; i++) {
if (vmem_xalloc(qc->qc_vmem, qc->qc_size, 0, 0, 0,
VMEM_ADDR_MIN, VMEM_ADDR_MAX, flags, &addr) != 0)
break;
store[i] = (void *)addr;
/* Only guarantee one allocation. */
flags &= ~M_WAITOK;
flags |= M_NOWAIT;
}
return i;
}
/*
* Release memory from the UMA cache to the arena.
*/
static void
qc_release(void *arg, void **store, int cnt)
{
qcache_t *qc;
int i;
qc = arg;
for (i = 0; i < cnt; i++)
vmem_xfree(qc->qc_vmem, (vmem_addr_t)store[i], qc->qc_size);
}
static void
qc_init(vmem_t *vm, vmem_size_t qcache_max)
{
qcache_t *qc;
vmem_size_t size;
int qcache_idx_max;
int i;
MPASS((qcache_max & vm->vm_quantum_mask) == 0);
qcache_idx_max = MIN(qcache_max >> vm->vm_quantum_shift,
VMEM_QCACHE_IDX_MAX);
vm->vm_qcache_max = qcache_idx_max << vm->vm_quantum_shift;
for (i = 0; i < qcache_idx_max; i++) {
qc = &vm->vm_qcache[i];
size = (i + 1) << vm->vm_quantum_shift;
snprintf(qc->qc_name, sizeof(qc->qc_name), "%s-%zu",
vm->vm_name, size);
qc->qc_vmem = vm;
qc->qc_size = size;
qc->qc_cache = uma_zcache_create(qc->qc_name, size,
NULL, NULL, NULL, NULL, qc_import, qc_release, qc,
UMA_ZONE_VM);
MPASS(qc->qc_cache);
}
}
static void
qc_destroy(vmem_t *vm)
{
int qcache_idx_max;
int i;
qcache_idx_max = vm->vm_qcache_max >> vm->vm_quantum_shift;
for (i = 0; i < qcache_idx_max; i++)
uma_zdestroy(vm->vm_qcache[i].qc_cache);
}
static void
qc_drain(vmem_t *vm)
{
int qcache_idx_max;
int i;
qcache_idx_max = vm->vm_qcache_max >> vm->vm_quantum_shift;
for (i = 0; i < qcache_idx_max; i++)
zone_drain(vm->vm_qcache[i].qc_cache);
}
#ifndef UMA_MD_SMALL_ALLOC
static struct mtx_padalign __exclusive_cache_line vmem_bt_lock;
/*
* vmem_bt_alloc: Allocate a new page of boundary tags.
*
* On architectures with uma_small_alloc there is no recursion; no address
* space need be allocated to allocate boundary tags. For the others, we
* must handle recursion. Boundary tags are necessary to allocate new
* boundary tags.
*
* UMA guarantees that enough tags are held in reserve to allocate a new
* page of kva. We dip into this reserve by specifying M_USE_RESERVE only
* when allocating the page to hold new boundary tags. In this way the
* reserve is automatically filled by the allocation that uses the reserve.
*
* We still have to guarantee that the new tags are allocated atomically since
* many threads may try concurrently. The bt_lock provides this guarantee.
* We convert WAITOK allocations to NOWAIT and then handle the blocking here
* on failure. It's ok to return NULL for a WAITOK allocation as UMA will
* loop again after checking to see if we lost the race to allocate.
*
* There is a small race between vmem_bt_alloc() returning the page and the
* zone lock being acquired to add the page to the zone. For WAITOK
* allocations we just pause briefly. NOWAIT may experience a transient
* failure. To alleviate this we permit a small number of simultaneous
* fills to proceed concurrently so NOWAIT is less likely to fail unless
* we are really out of KVA.
*/
static void *
vmem_bt_alloc(uma_zone_t zone, vm_size_t bytes, int domain, uint8_t *pflag,
int wait)
{
vmem_addr_t addr;
*pflag = UMA_SLAB_KERNEL;
/*
* Single thread boundary tag allocation so that the address space
* and memory are added in one atomic operation.
*/
mtx_lock(&vmem_bt_lock);
if (vmem_xalloc(vm_dom[domain].vmd_kernel_arena, bytes, 0, 0, 0,
VMEM_ADDR_MIN, VMEM_ADDR_MAX,
M_NOWAIT | M_NOVM | M_USE_RESERVE | M_BESTFIT, &addr) == 0) {
if (kmem_back_domain(domain, kernel_object, addr, bytes,
M_NOWAIT | M_USE_RESERVE) == 0) {
mtx_unlock(&vmem_bt_lock);
return ((void *)addr);
}
vmem_xfree(vm_dom[domain].vmd_kernel_arena, addr, bytes);
mtx_unlock(&vmem_bt_lock);
/*
* Out of memory, not address space. This may not even be
* possible due to M_USE_RESERVE page allocation.
*/
if (wait & M_WAITOK)
vm_wait_domain(domain);
return (NULL);
}
mtx_unlock(&vmem_bt_lock);
/*
* We're either out of address space or lost a fill race.
*/
if (wait & M_WAITOK)
pause("btalloc", 1);
return (NULL);
}
/*
* How many pages do we need to startup_alloc.
*/
int
vmem_startup_count(void)
{
return (howmany(BT_MAXALLOC,
UMA_SLAB_SPACE / sizeof(struct vmem_btag)));
}
#endif
void
vmem_startup(void)
{
mtx_init(&vmem_list_lock, "vmem list lock", NULL, MTX_DEF);
vmem_zone = uma_zcreate("vmem",
sizeof(struct vmem), NULL, NULL, NULL, NULL,
UMA_ALIGN_PTR, UMA_ZONE_VM);
vmem_bt_zone = uma_zcreate("vmem btag",
sizeof(struct vmem_btag), NULL, NULL, NULL, NULL,
UMA_ALIGN_PTR, UMA_ZONE_VM | UMA_ZONE_NOFREE);
#ifndef UMA_MD_SMALL_ALLOC
mtx_init(&vmem_bt_lock, "btag lock", NULL, MTX_DEF);
uma_prealloc(vmem_bt_zone, BT_MAXALLOC);
/*
* Reserve enough tags to allocate new tags. We allow multiple
* CPUs to attempt to allocate new tags concurrently to limit
* false restarts in UMA.
*/
uma_zone_reserve(vmem_bt_zone, BT_MAXALLOC * (mp_ncpus + 1) / 2);
uma_zone_set_allocf(vmem_bt_zone, vmem_bt_alloc);
#endif
}
/* ---- rehash */
static int
vmem_rehash(vmem_t *vm, vmem_size_t newhashsize)
{
bt_t *bt;
int i;
struct vmem_hashlist *newhashlist;
struct vmem_hashlist *oldhashlist;
vmem_size_t oldhashsize;
MPASS(newhashsize > 0);
newhashlist = malloc(sizeof(struct vmem_hashlist) * newhashsize,
M_VMEM, M_NOWAIT);
if (newhashlist == NULL)
return ENOMEM;
for (i = 0; i < newhashsize; i++) {
LIST_INIT(&newhashlist[i]);
}
VMEM_LOCK(vm);
oldhashlist = vm->vm_hashlist;
oldhashsize = vm->vm_hashsize;
vm->vm_hashlist = newhashlist;
vm->vm_hashsize = newhashsize;
if (oldhashlist == NULL) {
VMEM_UNLOCK(vm);
return 0;
}
for (i = 0; i < oldhashsize; i++) {
while ((bt = LIST_FIRST(&oldhashlist[i])) != NULL) {
bt_rembusy(vm, bt);
bt_insbusy(vm, bt);
}
}
VMEM_UNLOCK(vm);
if (oldhashlist != vm->vm_hash0) {
free(oldhashlist, M_VMEM);
}
return 0;
}
static void
vmem_periodic_kick(void *dummy)
{
taskqueue_enqueue(taskqueue_thread, &vmem_periodic_wk);
}
static void
vmem_periodic(void *unused, int pending)
{
vmem_t *vm;
vmem_size_t desired;
vmem_size_t current;
mtx_lock(&vmem_list_lock);
LIST_FOREACH(vm, &vmem_list, vm_alllist) {
#ifdef DIAGNOSTIC
/* Convenient time to verify vmem state. */
if (enable_vmem_check == 1) {
VMEM_LOCK(vm);
vmem_check(vm);
VMEM_UNLOCK(vm);
}
#endif
desired = 1 << flsl(vm->vm_nbusytag);
desired = MIN(MAX(desired, VMEM_HASHSIZE_MIN),
VMEM_HASHSIZE_MAX);
current = vm->vm_hashsize;
/* Grow in powers of two. Shrink less aggressively. */
if (desired >= current * 2 || desired * 4 <= current)
vmem_rehash(vm, desired);
/*
* Periodically wake up threads waiting for resources,
* so they could ask for reclamation again.
*/
VMEM_CONDVAR_BROADCAST(vm);
}
mtx_unlock(&vmem_list_lock);
callout_reset(&vmem_periodic_ch, vmem_periodic_interval,
vmem_periodic_kick, NULL);
}
static void
vmem_start_callout(void *unused)
{
TASK_INIT(&vmem_periodic_wk, 0, vmem_periodic, NULL);
vmem_periodic_interval = hz * 10;
callout_init(&vmem_periodic_ch, 1);
callout_reset(&vmem_periodic_ch, vmem_periodic_interval,
vmem_periodic_kick, NULL);
}
SYSINIT(vfs, SI_SUB_CONFIGURE, SI_ORDER_ANY, vmem_start_callout, NULL);
static void
vmem_add1(vmem_t *vm, vmem_addr_t addr, vmem_size_t size, int type)
{
bt_t *btspan;
bt_t *btfree;
MPASS(type == BT_TYPE_SPAN || type == BT_TYPE_SPAN_STATIC);
MPASS((size & vm->vm_quantum_mask) == 0);
btspan = bt_alloc(vm);
btspan->bt_type = type;
btspan->bt_start = addr;
btspan->bt_size = size;
bt_insseg_tail(vm, btspan);
btfree = bt_alloc(vm);
btfree->bt_type = BT_TYPE_FREE;
btfree->bt_start = addr;
btfree->bt_size = size;
bt_insseg(vm, btfree, btspan);
bt_insfree(vm, btfree);
vm->vm_size += size;
}
static void
vmem_destroy1(vmem_t *vm)
{
bt_t *bt;
/*
* Drain per-cpu quantum caches.
*/
qc_destroy(vm);
/*
* The vmem should now only contain empty segments.
*/
VMEM_LOCK(vm);
MPASS(vm->vm_nbusytag == 0);
while ((bt = TAILQ_FIRST(&vm->vm_seglist)) != NULL)
bt_remseg(vm, bt);
if (vm->vm_hashlist != NULL && vm->vm_hashlist != vm->vm_hash0)
free(vm->vm_hashlist, M_VMEM);
bt_freetrim(vm, 0);
VMEM_CONDVAR_DESTROY(vm);
VMEM_LOCK_DESTROY(vm);
uma_zfree(vmem_zone, vm);
}
static int
vmem_import(vmem_t *vm, vmem_size_t size, vmem_size_t align, int flags)
{
vmem_addr_t addr;
int error;
if (vm->vm_importfn == NULL)
return (EINVAL);
/*
* To make sure we get a span that meets the alignment we double it
* and add the size to the tail. This slightly overestimates.
*/
if (align != vm->vm_quantum_mask + 1)
size = (align * 2) + size;
size = roundup(size, vm->vm_import_quantum);
if (vm->vm_limit != 0 && vm->vm_limit < vm->vm_size + size)
return (ENOMEM);
/*
* Hide MAXALLOC tags so we're guaranteed to be able to add this
* span and the tag we want to allocate from it.
*/
MPASS(vm->vm_nfreetags >= BT_MAXALLOC);
vm->vm_nfreetags -= BT_MAXALLOC;
VMEM_UNLOCK(vm);
error = (vm->vm_importfn)(vm->vm_arg, size, flags, &addr);
VMEM_LOCK(vm);
vm->vm_nfreetags += BT_MAXALLOC;
if (error)
return (ENOMEM);
vmem_add1(vm, addr, size, BT_TYPE_SPAN);
return 0;
}
/*
* vmem_fit: check if a bt can satisfy the given restrictions.
*
* it's a caller's responsibility to ensure the region is big enough
* before calling us.
*/
static int
vmem_fit(const bt_t *bt, vmem_size_t size, vmem_size_t align,
vmem_size_t phase, vmem_size_t nocross, vmem_addr_t minaddr,
vmem_addr_t maxaddr, vmem_addr_t *addrp)
{
vmem_addr_t start;
vmem_addr_t end;
MPASS(size > 0);
MPASS(bt->bt_size >= size); /* caller's responsibility */
/*
* XXX assumption: vmem_addr_t and vmem_size_t are
* unsigned integer of the same size.
*/
start = bt->bt_start;
if (start < minaddr) {
start = minaddr;
}
end = BT_END(bt);
if (end > maxaddr)
end = maxaddr;
if (start > end)
return (ENOMEM);
start = VMEM_ALIGNUP(start - phase, align) + phase;
if (start < bt->bt_start)
start += align;
if (VMEM_CROSS_P(start, start + size - 1, nocross)) {
MPASS(align < nocross);
start = VMEM_ALIGNUP(start - phase, nocross) + phase;
}
if (start <= end && end - start >= size - 1) {
MPASS((start & (align - 1)) == phase);
MPASS(!VMEM_CROSS_P(start, start + size - 1, nocross));
MPASS(minaddr <= start);
MPASS(maxaddr == 0 || start + size - 1 <= maxaddr);
MPASS(bt->bt_start <= start);
MPASS(BT_END(bt) - start >= size - 1);
*addrp = start;
return (0);
}
return (ENOMEM);
}
/*
* vmem_clip: Trim the boundary tag edges to the requested start and size.
*/
static void
vmem_clip(vmem_t *vm, bt_t *bt, vmem_addr_t start, vmem_size_t size)
{
bt_t *btnew;
bt_t *btprev;
VMEM_ASSERT_LOCKED(vm);
MPASS(bt->bt_type == BT_TYPE_FREE);
MPASS(bt->bt_size >= size);
bt_remfree(vm, bt);
if (bt->bt_start != start) {
btprev = bt_alloc(vm);
btprev->bt_type = BT_TYPE_FREE;
btprev->bt_start = bt->bt_start;
btprev->bt_size = start - bt->bt_start;
bt->bt_start = start;
bt->bt_size -= btprev->bt_size;
bt_insfree(vm, btprev);
bt_insseg(vm, btprev,
TAILQ_PREV(bt, vmem_seglist, bt_seglist));
}
MPASS(bt->bt_start == start);
if (bt->bt_size != size && bt->bt_size - size > vm->vm_quantum_mask) {
/* split */
btnew = bt_alloc(vm);
btnew->bt_type = BT_TYPE_BUSY;
btnew->bt_start = bt->bt_start;
btnew->bt_size = size;
bt->bt_start = bt->bt_start + size;
bt->bt_size -= size;
bt_insfree(vm, bt);
bt_insseg(vm, btnew,
TAILQ_PREV(bt, vmem_seglist, bt_seglist));
bt_insbusy(vm, btnew);
bt = btnew;
} else {
bt->bt_type = BT_TYPE_BUSY;
bt_insbusy(vm, bt);
}
MPASS(bt->bt_size >= size);
bt->bt_type = BT_TYPE_BUSY;
}
/* ---- vmem API */
void
vmem_set_import(vmem_t *vm, vmem_import_t *importfn,
vmem_release_t *releasefn, void *arg, vmem_size_t import_quantum)
{
VMEM_LOCK(vm);
vm->vm_importfn = importfn;
vm->vm_releasefn = releasefn;
vm->vm_arg = arg;
vm->vm_import_quantum = import_quantum;
VMEM_UNLOCK(vm);
}
void
vmem_set_limit(vmem_t *vm, vmem_size_t limit)
{
VMEM_LOCK(vm);
vm->vm_limit = limit;
VMEM_UNLOCK(vm);
}
void
vmem_set_reclaim(vmem_t *vm, vmem_reclaim_t *reclaimfn)
{
VMEM_LOCK(vm);
vm->vm_reclaimfn = reclaimfn;
VMEM_UNLOCK(vm);
}
/*
* vmem_init: Initializes vmem arena.
*/
vmem_t *
vmem_init(vmem_t *vm, const char *name, vmem_addr_t base, vmem_size_t size,
vmem_size_t quantum, vmem_size_t qcache_max, int flags)
{
int i;
MPASS(quantum > 0);
MPASS((quantum & (quantum - 1)) == 0);
bzero(vm, sizeof(*vm));
VMEM_CONDVAR_INIT(vm, name);
VMEM_LOCK_INIT(vm, name);
vm->vm_nfreetags = 0;
LIST_INIT(&vm->vm_freetags);
strlcpy(vm->vm_name, name, sizeof(vm->vm_name));
vm->vm_quantum_mask = quantum - 1;
vm->vm_quantum_shift = flsl(quantum) - 1;
vm->vm_nbusytag = 0;
vm->vm_size = 0;
vm->vm_limit = 0;
vm->vm_inuse = 0;
qc_init(vm, qcache_max);
TAILQ_INIT(&vm->vm_seglist);
for (i = 0; i < VMEM_MAXORDER; i++) {
LIST_INIT(&vm->vm_freelist[i]);
}
memset(&vm->vm_hash0, 0, sizeof(vm->vm_hash0));
vm->vm_hashsize = VMEM_HASHSIZE_MIN;
vm->vm_hashlist = vm->vm_hash0;
if (size != 0) {
if (vmem_add(vm, base, size, flags) != 0) {
vmem_destroy1(vm);
return NULL;
}
}
mtx_lock(&vmem_list_lock);
LIST_INSERT_HEAD(&vmem_list, vm, vm_alllist);
mtx_unlock(&vmem_list_lock);
return vm;
}
/*
* vmem_create: create an arena.
*/
vmem_t *
vmem_create(const char *name, vmem_addr_t base, vmem_size_t size,
vmem_size_t quantum, vmem_size_t qcache_max, int flags)
{
vmem_t *vm;
vm = uma_zalloc(vmem_zone, flags & (M_WAITOK|M_NOWAIT));
if (vm == NULL)
return (NULL);
if (vmem_init(vm, name, base, size, quantum, qcache_max,
flags) == NULL)
return (NULL);
return (vm);
}
void
vmem_destroy(vmem_t *vm)
{
mtx_lock(&vmem_list_lock);
LIST_REMOVE(vm, vm_alllist);
mtx_unlock(&vmem_list_lock);
vmem_destroy1(vm);
}
vmem_size_t
vmem_roundup_size(vmem_t *vm, vmem_size_t size)
{
return (size + vm->vm_quantum_mask) & ~vm->vm_quantum_mask;
}
/*
* vmem_alloc: allocate resource from the arena.
*/
int
vmem_alloc(vmem_t *vm, vmem_size_t size, int flags, vmem_addr_t *addrp)
{
const int strat __unused = flags & VMEM_FITMASK;
qcache_t *qc;
flags &= VMEM_FLAGS;
MPASS(size > 0);
MPASS(strat == M_BESTFIT || strat == M_FIRSTFIT);
if ((flags & M_NOWAIT) == 0)
WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, "vmem_alloc");
if (size <= vm->vm_qcache_max) {
qc = &vm->vm_qcache[(size - 1) >> vm->vm_quantum_shift];
*addrp = (vmem_addr_t)uma_zalloc(qc->qc_cache, flags);
if (*addrp == 0)
return (ENOMEM);
return (0);
}
return vmem_xalloc(vm, size, 0, 0, 0, VMEM_ADDR_MIN, VMEM_ADDR_MAX,
flags, addrp);
}
int
vmem_xalloc(vmem_t *vm, const vmem_size_t size0, vmem_size_t align,
const vmem_size_t phase, const vmem_size_t nocross,
const vmem_addr_t minaddr, const vmem_addr_t maxaddr, int flags,
vmem_addr_t *addrp)
{
const vmem_size_t size = vmem_roundup_size(vm, size0);
struct vmem_freelist *list;
struct vmem_freelist *first;
struct vmem_freelist *end;
vmem_size_t avail;
bt_t *bt;
int error;
int strat;
flags &= VMEM_FLAGS;
strat = flags & VMEM_FITMASK;
MPASS(size0 > 0);
MPASS(size > 0);
MPASS(strat == M_BESTFIT || strat == M_FIRSTFIT);
MPASS((flags & (M_NOWAIT|M_WAITOK)) != (M_NOWAIT|M_WAITOK));
if ((flags & M_NOWAIT) == 0)
WITNESS_WARN(WARN_GIANTOK | WARN_SLEEPOK, NULL, "vmem_xalloc");
MPASS((align & vm->vm_quantum_mask) == 0);
MPASS((align & (align - 1)) == 0);
MPASS((phase & vm->vm_quantum_mask) == 0);
MPASS((nocross & vm->vm_quantum_mask) == 0);
MPASS((nocross & (nocross - 1)) == 0);
MPASS((align == 0 && phase == 0) || phase < align);
MPASS(nocross == 0 || nocross >= size);
MPASS(minaddr <= maxaddr);
MPASS(!VMEM_CROSS_P(phase, phase + size - 1, nocross));
if (align == 0)
align = vm->vm_quantum_mask + 1;
*addrp = 0;
end = &vm->vm_freelist[VMEM_MAXORDER];
/*
* choose a free block from which we allocate.
*/
first = bt_freehead_toalloc(vm, size, strat);
VMEM_LOCK(vm);
for (;;) {
/*
* Make sure we have enough tags to complete the
* operation.
*/
if (vm->vm_nfreetags < BT_MAXALLOC &&
bt_fill(vm, flags) != 0) {
error = ENOMEM;
break;
}
/*
* Scan freelists looking for a tag that satisfies the
* allocation. If we're doing BESTFIT we may encounter
* sizes below the request. If we're doing FIRSTFIT we
* inspect only the first element from each list.
*/
for (list = first; list < end; list++) {
LIST_FOREACH(bt, list, bt_freelist) {
if (bt->bt_size >= size) {
error = vmem_fit(bt, size, align, phase,
nocross, minaddr, maxaddr, addrp);
if (error == 0) {
vmem_clip(vm, bt, *addrp, size);
goto out;
}
}
/* FIRST skips to the next list. */
if (strat == M_FIRSTFIT)
break;
}
}
/*
* Retry if the fast algorithm failed.
*/
if (strat == M_FIRSTFIT) {
strat = M_BESTFIT;
first = bt_freehead_toalloc(vm, size, strat);
continue;
}
/*
* XXX it is possible to fail to meet restrictions with the
* imported region. It is up to the user to specify the
* import quantum such that it can satisfy any allocation.
*/
if (vmem_import(vm, size, align, flags) == 0)
continue;
/*
* Try to free some space from the quantum cache or reclaim
* functions if available.
*/
if (vm->vm_qcache_max != 0 || vm->vm_reclaimfn != NULL) {
avail = vm->vm_size - vm->vm_inuse;
VMEM_UNLOCK(vm);
if (vm->vm_qcache_max != 0)
qc_drain(vm);
if (vm->vm_reclaimfn != NULL)
vm->vm_reclaimfn(vm, flags);
VMEM_LOCK(vm);
/* If we were successful retry even NOWAIT. */
if (vm->vm_size - vm->vm_inuse > avail)
continue;
}
if ((flags & M_NOWAIT) != 0) {
error = ENOMEM;
break;
}
VMEM_CONDVAR_WAIT(vm);
}
out:
VMEM_UNLOCK(vm);
if (error != 0 && (flags & M_NOWAIT) == 0)
panic("failed to allocate waiting allocation\n");
return (error);
}
/*
* vmem_free: free the resource to the arena.
*/
void
vmem_free(vmem_t *vm, vmem_addr_t addr, vmem_size_t size)
{
qcache_t *qc;
MPASS(size > 0);
if (size <= vm->vm_qcache_max) {
qc = &vm->vm_qcache[(size - 1) >> vm->vm_quantum_shift];
uma_zfree(qc->qc_cache, (void *)addr);
} else
vmem_xfree(vm, addr, size);
}
void
vmem_xfree(vmem_t *vm, vmem_addr_t addr, vmem_size_t size)
{
bt_t *bt;
bt_t *t;
MPASS(size > 0);
VMEM_LOCK(vm);
bt = bt_lookupbusy(vm, addr);
MPASS(bt != NULL);
MPASS(bt->bt_start == addr);
MPASS(bt->bt_size == vmem_roundup_size(vm, size) ||
bt->bt_size - vmem_roundup_size(vm, size) <= vm->vm_quantum_mask);
MPASS(bt->bt_type == BT_TYPE_BUSY);
bt_rembusy(vm, bt);
bt->bt_type = BT_TYPE_FREE;
/* coalesce */
t = TAILQ_NEXT(bt, bt_seglist);
if (t != NULL && t->bt_type == BT_TYPE_FREE) {
MPASS(BT_END(bt) < t->bt_start); /* YYY */
bt->bt_size += t->bt_size;
bt_remfree(vm, t);
bt_remseg(vm, t);
}
t = TAILQ_PREV(bt, vmem_seglist, bt_seglist);
if (t != NULL && t->bt_type == BT_TYPE_FREE) {
MPASS(BT_END(t) < bt->bt_start); /* YYY */
bt->bt_size += t->bt_size;
bt->bt_start = t->bt_start;
bt_remfree(vm, t);
bt_remseg(vm, t);
}
t = TAILQ_PREV(bt, vmem_seglist, bt_seglist);
MPASS(t != NULL);
MPASS(BT_ISSPAN_P(t) || t->bt_type == BT_TYPE_BUSY);
if (vm->vm_releasefn != NULL && t->bt_type == BT_TYPE_SPAN &&
t->bt_size == bt->bt_size) {
vmem_addr_t spanaddr;
vmem_size_t spansize;
MPASS(t->bt_start == bt->bt_start);
spanaddr = bt->bt_start;
spansize = bt->bt_size;
bt_remseg(vm, bt);
bt_remseg(vm, t);
vm->vm_size -= spansize;
VMEM_CONDVAR_BROADCAST(vm);
bt_freetrim(vm, BT_MAXFREE);
(*vm->vm_releasefn)(vm->vm_arg, spanaddr, spansize);
} else {
bt_insfree(vm, bt);
VMEM_CONDVAR_BROADCAST(vm);
bt_freetrim(vm, BT_MAXFREE);
}
}
/*
* vmem_add:
*
*/
int
vmem_add(vmem_t *vm, vmem_addr_t addr, vmem_size_t size, int flags)
{
int error;
error = 0;
flags &= VMEM_FLAGS;
VMEM_LOCK(vm);
if (vm->vm_nfreetags >= BT_MAXALLOC || bt_fill(vm, flags) == 0)
vmem_add1(vm, addr, size, BT_TYPE_SPAN_STATIC);
else
error = ENOMEM;
VMEM_UNLOCK(vm);
return (error);
}
/*
* vmem_size: information about arenas size
*/
vmem_size_t
vmem_size(vmem_t *vm, int typemask)
{
int i;
switch (typemask) {
case VMEM_ALLOC:
return vm->vm_inuse;
case VMEM_FREE:
return vm->vm_size - vm->vm_inuse;
case VMEM_FREE|VMEM_ALLOC:
return vm->vm_size;
case VMEM_MAXFREE:
VMEM_LOCK(vm);
for (i = VMEM_MAXORDER - 1; i >= 0; i--) {
if (LIST_EMPTY(&vm->vm_freelist[i]))
continue;
VMEM_UNLOCK(vm);
return ((vmem_size_t)ORDER2SIZE(i) <<
vm->vm_quantum_shift);
}
VMEM_UNLOCK(vm);
return (0);
default:
panic("vmem_size");
}
}
/* ---- debug */
#if defined(DDB) || defined(DIAGNOSTIC)
static void bt_dump(const bt_t *, int (*)(const char *, ...)
__printflike(1, 2));
static const char *
bt_type_string(int type)
{
switch (type) {
case BT_TYPE_BUSY:
return "busy";
case BT_TYPE_FREE:
return "free";
case BT_TYPE_SPAN:
return "span";
case BT_TYPE_SPAN_STATIC:
return "static span";
default:
break;
}
return "BOGUS";
}
static void
bt_dump(const bt_t *bt, int (*pr)(const char *, ...))
{
(*pr)("\t%p: %jx %jx, %d(%s)\n",
bt, (intmax_t)bt->bt_start, (intmax_t)bt->bt_size,
bt->bt_type, bt_type_string(bt->bt_type));
}
static void
vmem_dump(const vmem_t *vm , int (*pr)(const char *, ...) __printflike(1, 2))
{
const bt_t *bt;
int i;
(*pr)("vmem %p '%s'\n", vm, vm->vm_name);
TAILQ_FOREACH(bt, &vm->vm_seglist, bt_seglist) {
bt_dump(bt, pr);
}
for (i = 0; i < VMEM_MAXORDER; i++) {
const struct vmem_freelist *fl = &vm->vm_freelist[i];
if (LIST_EMPTY(fl)) {
continue;
}
(*pr)("freelist[%d]\n", i);
LIST_FOREACH(bt, fl, bt_freelist) {
bt_dump(bt, pr);
}
}
}
#endif /* defined(DDB) || defined(DIAGNOSTIC) */
#if defined(DDB)
#include <ddb/ddb.h>
static bt_t *
vmem_whatis_lookup(vmem_t *vm, vmem_addr_t addr)
{
bt_t *bt;
TAILQ_FOREACH(bt, &vm->vm_seglist, bt_seglist) {
if (BT_ISSPAN_P(bt)) {
continue;
}
if (bt->bt_start <= addr && addr <= BT_END(bt)) {
return bt;
}
}
return NULL;
}
void
vmem_whatis(vmem_addr_t addr, int (*pr)(const char *, ...))
{
vmem_t *vm;
LIST_FOREACH(vm, &vmem_list, vm_alllist) {
bt_t *bt;
bt = vmem_whatis_lookup(vm, addr);
if (bt == NULL) {
continue;
}
(*pr)("%p is %p+%zu in VMEM '%s' (%s)\n",
(void *)addr, (void *)bt->bt_start,
(vmem_size_t)(addr - bt->bt_start), vm->vm_name,
(bt->bt_type == BT_TYPE_BUSY) ? "allocated" : "free");
}
}
void
vmem_printall(const char *modif, int (*pr)(const char *, ...))
{
const vmem_t *vm;
LIST_FOREACH(vm, &vmem_list, vm_alllist) {
vmem_dump(vm, pr);
}
}
void
vmem_print(vmem_addr_t addr, const char *modif, int (*pr)(const char *, ...))
{
const vmem_t *vm = (const void *)addr;
vmem_dump(vm, pr);
}
DB_SHOW_COMMAND(vmemdump, vmemdump)
{
if (!have_addr) {
db_printf("usage: show vmemdump <addr>\n");
return;
}
vmem_dump((const vmem_t *)addr, db_printf);
}
DB_SHOW_ALL_COMMAND(vmemdump, vmemdumpall)
{
const vmem_t *vm;
LIST_FOREACH(vm, &vmem_list, vm_alllist)
vmem_dump(vm, db_printf);
}
DB_SHOW_COMMAND(vmem, vmem_summ)
{
const vmem_t *vm = (const void *)addr;
const bt_t *bt;
size_t ft[VMEM_MAXORDER], ut[VMEM_MAXORDER];
size_t fs[VMEM_MAXORDER], us[VMEM_MAXORDER];
int ord;
if (!have_addr) {
db_printf("usage: show vmem <addr>\n");
return;
}
db_printf("vmem %p '%s'\n", vm, vm->vm_name);
db_printf("\tquantum:\t%zu\n", vm->vm_quantum_mask + 1);
db_printf("\tsize:\t%zu\n", vm->vm_size);
db_printf("\tinuse:\t%zu\n", vm->vm_inuse);
db_printf("\tfree:\t%zu\n", vm->vm_size - vm->vm_inuse);
db_printf("\tbusy tags:\t%d\n", vm->vm_nbusytag);
db_printf("\tfree tags:\t%d\n", vm->vm_nfreetags);
memset(&ft, 0, sizeof(ft));
memset(&ut, 0, sizeof(ut));
memset(&fs, 0, sizeof(fs));
memset(&us, 0, sizeof(us));
TAILQ_FOREACH(bt, &vm->vm_seglist, bt_seglist) {
ord = SIZE2ORDER(bt->bt_size >> vm->vm_quantum_shift);
if (bt->bt_type == BT_TYPE_BUSY) {
ut[ord]++;
us[ord] += bt->bt_size;
} else if (bt->bt_type == BT_TYPE_FREE) {
ft[ord]++;
fs[ord] += bt->bt_size;
}
}
db_printf("\t\t\tinuse\tsize\t\tfree\tsize\n");
for (ord = 0; ord < VMEM_MAXORDER; ord++) {
if (ut[ord] == 0 && ft[ord] == 0)
continue;
db_printf("\t%-15zu %zu\t%-15zu %zu\t%-16zu\n",
ORDER2SIZE(ord) << vm->vm_quantum_shift,
ut[ord], us[ord], ft[ord], fs[ord]);
}
}
DB_SHOW_ALL_COMMAND(vmem, vmem_summall)
{
const vmem_t *vm;
LIST_FOREACH(vm, &vmem_list, vm_alllist)
vmem_summ((db_expr_t)vm, TRUE, count, modif);
}
#endif /* defined(DDB) */
#define vmem_printf printf
#if defined(DIAGNOSTIC)
static bool
vmem_check_sanity(vmem_t *vm)
{
const bt_t *bt, *bt2;
MPASS(vm != NULL);
TAILQ_FOREACH(bt, &vm->vm_seglist, bt_seglist) {
if (bt->bt_start > BT_END(bt)) {
printf("corrupted tag\n");
bt_dump(bt, vmem_printf);
return false;
}
}
TAILQ_FOREACH(bt, &vm->vm_seglist, bt_seglist) {
TAILQ_FOREACH(bt2, &vm->vm_seglist, bt_seglist) {
if (bt == bt2) {
continue;
}
if (BT_ISSPAN_P(bt) != BT_ISSPAN_P(bt2)) {
continue;
}
if (bt->bt_start <= BT_END(bt2) &&
bt2->bt_start <= BT_END(bt)) {
printf("overwrapped tags\n");
bt_dump(bt, vmem_printf);
bt_dump(bt2, vmem_printf);
return false;
}
}
}
return true;
}
static void
vmem_check(vmem_t *vm)
{
if (!vmem_check_sanity(vm)) {
panic("insanity vmem %p", vm);
}
}
#endif /* defined(DIAGNOSTIC) */