mem.c revision 50dfb7ee4ada4c9aa30bd18c1b5d9b04be765669
/*
* Copyright (C) 1997, 1998, 1999 Internet Software Consortium.
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND INTERNET SOFTWARE CONSORTIUM DISCLAIMS
* ALL WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL INTERNET SOFTWARE
* CONSORTIUM BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL
* DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
* PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS
* ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS
* SOFTWARE.
*/
#include <config.h>
#include <stdio.h>
#include <stdlib.h>
#include <stddef.h>
#include <string.h>
#include <limits.h>
#include <isc/assertions.h>
#include <isc/error.h>
#include <isc/mem.h>
#ifndef ISC_SINGLETHREADED
#include <isc/mutex.h>
#include "util.h"
#else
#define LOCK(l)
#define UNLOCK(l)
#endif
#ifndef ISC_MEM_FILL
/*
* XXXMPA
* We want this on during development to catch:
* 1. some reference after free bugs.
* 2. some failure to initalise bugs.
*/
#define ISC_MEM_FILL 1
#endif
/*
* Types.
*/
typedef struct {
void * next;
} element;
typedef struct {
size_t size;
/*
* This structure must be ALIGNMENT_SIZE bytes.
*/
} size_info;
struct stats {
unsigned long gets;
unsigned long totalgets;
unsigned long blocks;
unsigned long freefrags;
};
#define MEM_MAGIC 0x4D656d43U /* MemC. */
#define VALID_CONTEXT(c) ((c) != NULL && (c)->magic == MEM_MAGIC)
struct isc_mem {
unsigned int magic;
isc_mutex_t lock;
isc_memalloc_t memalloc;
isc_memfree_t memfree;
void * arg;
size_t max_size;
size_t mem_target;
element ** freelists;
element * basic_blocks;
unsigned char ** basic_table;
unsigned int basic_table_count;
unsigned int basic_table_size;
unsigned char * lowest;
unsigned char * highest;
struct stats * stats;
size_t quota;
size_t total;
ISC_LIST(isc_mempool_t) pools;
};
#define MEMPOOL_MAGIC 0x4D454d70U /* MEMp. */
#define VALID_MEMPOOL(c) ((c) != NULL && (c)->magic == MEMPOOL_MAGIC)
struct isc_mempool {
/* always unlocked */
unsigned int magic; /* magic number */
isc_mutex_t *lock; /* optional lock */
isc_mem_t *mctx; /* our memory context */
/* locked via the memory context's lock */
ISC_LINK(isc_mempool_t) link; /* next pool in this mem context */
/* optionally locked from here down */
element *items; /* low water item list */
size_t size; /* size of each item on this pool */
unsigned int maxalloc; /* max number of items allowed */
unsigned int allocated; /* # of items currently given out */
unsigned int freecount; /* # of items on reserved list */
unsigned int freemax; /* # of items allowed on free list */
unsigned int fillcount; /* # of items to fetch on each fill */
/* Stats only. */
unsigned int gets; /* # of requests to this pool */
};
/* Forward. */
static inline size_t quantize(size_t);
static inline void mem_putunlocked(isc_mem_t *, void *, size_t);
static inline void * mem_getunlocked(isc_mem_t *, size_t);
/* Constants. */
#define DEF_MAX_SIZE 1100
#define DEF_MEM_TARGET 4096
#define ALIGNMENT_SIZE sizeof (void *)
#define NUM_BASIC_BLOCKS 64 /* must be > 1 */
#define TABLE_INCREMENT 1024
/* Private Inline-able. */
static inline size_t
quantize(size_t size) {
int temp;
/*
* Round up the result in order to get a size big
* enough to satisfy the request and be aligned on ALIGNMENT_SIZE
* byte boundaries.
*/
temp = size + (ALIGNMENT_SIZE - 1);
return (temp - temp % ALIGNMENT_SIZE);
}
/* Private. */
static void *
default_memalloc(void *arg, size_t size) {
(void)arg;
return (malloc(size));
}
static void
default_memfree(void *arg, void *ptr) {
(void)arg;
free(ptr);
}
/* Public. */
isc_result_t
isc_mem_createx(size_t init_max_size, size_t target_size,
isc_memalloc_t memalloc, isc_memfree_t memfree, void *arg,
isc_mem_t **ctxp)
{
isc_mem_t *ctx;
REQUIRE(ctxp != NULL && *ctxp == NULL);
REQUIRE(memalloc != NULL);
REQUIRE(memfree != NULL);
ctx = (memalloc)(arg, sizeof *ctx);
if (ctx == NULL)
return (ISC_R_NOMEMORY);
if (init_max_size == 0)
ctx->max_size = DEF_MAX_SIZE;
else
ctx->max_size = init_max_size;
if (target_size == 0)
ctx->mem_target = DEF_MEM_TARGET;
else
ctx->mem_target = target_size;
ctx->memalloc = memalloc;
ctx->memfree = memfree;
ctx->arg = arg;
ctx->freelists = (memalloc)(arg, ctx->max_size * sizeof (element *));
if (ctx->freelists == NULL) {
(memfree)(arg, ctx);
return (ISC_R_NOMEMORY);
}
memset(ctx->freelists, 0,
ctx->max_size * sizeof (element *));
ctx->stats = (memalloc)(arg,
(ctx->max_size+1) * sizeof (struct stats));
if (ctx->stats == NULL) {
(memfree)(arg, ctx->freelists);
(memfree)(arg, ctx);
return (ISC_R_NOMEMORY);
}
memset(ctx->stats, 0, (ctx->max_size + 1) * sizeof (struct stats));
ctx->basic_blocks = NULL;
ctx->basic_table = NULL;
ctx->basic_table_count = 0;
ctx->basic_table_size = 0;
ctx->lowest = NULL;
ctx->highest = NULL;
if (isc_mutex_init(&ctx->lock) != ISC_R_SUCCESS) {
(memfree)(arg, ctx->stats);
(memfree)(arg, ctx->freelists);
(memfree)(arg, ctx);
UNEXPECTED_ERROR(__FILE__, __LINE__,
"isc_mutex_init() failed");
return (ISC_R_UNEXPECTED);
}
ctx->quota = 0;
ctx->total = 0;
ctx->magic = MEM_MAGIC;
ISC_LIST_INIT(ctx->pools);
*ctxp = ctx;
return (ISC_R_SUCCESS);
}
isc_result_t
isc_mem_create(size_t init_max_size, size_t target_size,
isc_mem_t **ctxp)
{
return (isc_mem_createx(init_max_size, target_size,
default_memalloc, default_memfree, NULL,
ctxp));
}
void
isc_mem_destroy(isc_mem_t **ctxp) {
unsigned int i;
isc_mem_t *ctx;
REQUIRE(ctxp != NULL);
ctx = *ctxp;
REQUIRE(VALID_CONTEXT(ctx));
ctx->magic = 0;
INSIST(ISC_LIST_EMPTY(ctx->pools));
for (i = 0; i <= ctx->max_size; i++)
INSIST(ctx->stats[i].gets == 0);
for (i = 0; i < ctx->basic_table_count; i++)
(ctx->memfree)(ctx->arg, ctx->basic_table[i]);
(ctx->memfree)(ctx->arg, ctx->freelists);
(ctx->memfree)(ctx->arg, ctx->stats);
(ctx->memfree)(ctx->arg, ctx->basic_table);
(void)isc_mutex_destroy(&ctx->lock);
(ctx->memfree)(ctx->arg, ctx);
*ctxp = NULL;
}
isc_result_t
isc_mem_restore(isc_mem_t *ctx) {
isc_result_t result;
result = isc_mutex_init(&ctx->lock);
if (result != ISC_R_SUCCESS)
ctx->magic = 0;
return (result);
}
static void
more_basic_blocks(isc_mem_t *ctx) {
void *new;
unsigned char *curr, *next;
unsigned char *first, *last;
unsigned char **table;
unsigned int table_size;
size_t increment;
int i;
/* Require: we hold the context lock. */
/*
* Did we hit the quota for this context?
*/
increment = NUM_BASIC_BLOCKS * ctx->mem_target;
if (ctx->quota != 0 && ctx->total + increment > ctx->quota)
return;
INSIST(ctx->basic_table_count <= ctx->basic_table_size);
if (ctx->basic_table_count == ctx->basic_table_size) {
table_size = ctx->basic_table_size + TABLE_INCREMENT;
table = (ctx->memalloc)(ctx->arg,
table_size * sizeof (unsigned char *));
if (table == NULL)
return;
if (ctx->basic_table_size != 0) {
memcpy(table, ctx->basic_table,
ctx->basic_table_size *
sizeof (unsigned char *));
(ctx->memfree)(ctx->arg, ctx->basic_table);
}
ctx->basic_table = table;
ctx->basic_table_size = table_size;
}
new = (ctx->memalloc)(ctx->arg, NUM_BASIC_BLOCKS * ctx->mem_target);
if (new == NULL)
return;
ctx->total += increment;
ctx->basic_table[ctx->basic_table_count] = new;
ctx->basic_table_count++;
curr = new;
next = curr + ctx->mem_target;
for (i = 0; i < (NUM_BASIC_BLOCKS - 1); i++) {
((element *)curr)->next = next;
curr = next;
next += ctx->mem_target;
}
/*
* curr is now pointing at the last block in the
* array.
*/
((element *)curr)->next = NULL;
first = new;
last = first + NUM_BASIC_BLOCKS * ctx->mem_target - 1;
if (first < ctx->lowest || ctx->lowest == NULL)
ctx->lowest = first;
if (last > ctx->highest)
ctx->highest = last;
ctx->basic_blocks = new;
}
void *
__isc_mem_get(isc_mem_t *ctx, size_t size)
{
void *ret;
REQUIRE(size > 0);
REQUIRE(VALID_CONTEXT(ctx));
LOCK(&ctx->lock);
ret = mem_getunlocked(ctx, size);
UNLOCK(&ctx->lock);
return (ret);
}
static inline void *
mem_getunlocked(isc_mem_t *ctx, size_t size)
{
size_t new_size = quantize(size);
void *ret;
if (size >= ctx->max_size || new_size >= ctx->max_size) {
/* memget() was called on something beyond our upper limit. */
if (ctx->quota != 0 && ctx->total + size > ctx->quota) {
ret = NULL;
goto done;
}
ret = (ctx->memalloc)(ctx->arg, size);
if (ret != NULL) {
ctx->total += size;
ctx->stats[ctx->max_size].gets++;
ctx->stats[ctx->max_size].totalgets++;
}
goto done;
}
/*
* If there are no blocks in the free list for this size, get a chunk
* of memory and then break it up into "new_size"-sized blocks, adding
* them to the free list.
*/
if (ctx->freelists[new_size] == NULL) {
int i, frags;
size_t total_size;
void *new;
unsigned char *curr, *next;
if (ctx->basic_blocks == NULL) {
more_basic_blocks(ctx);
if (ctx->basic_blocks == NULL) {
ret = NULL;
goto done;
}
}
total_size = ctx->mem_target;
new = ctx->basic_blocks;
ctx->basic_blocks = ctx->basic_blocks->next;
frags = total_size / new_size;
ctx->stats[new_size].blocks++;
ctx->stats[new_size].freefrags += frags;
/* Set up a linked-list of blocks of size "new_size". */
curr = new;
next = curr + new_size;
for (i = 0; i < (frags - 1); i++) {
((element *)curr)->next = next;
curr = next;
next += new_size;
}
/* curr is now pointing at the last block in the array. */
((element *)curr)->next = NULL;
ctx->freelists[new_size] = new;
}
/* The free list uses the "rounded-up" size "new_size": */
ret = ctx->freelists[new_size];
ctx->freelists[new_size] = ctx->freelists[new_size]->next;
/*
* The stats[] uses the _actual_ "size" requested by the
* caller, with the caveat (in the code above) that "size" >= the
* max. size (max_size) ends up getting recorded as a call to
* max_size.
*/
ctx->stats[size].gets++;
ctx->stats[size].totalgets++;
ctx->stats[new_size].freefrags--;
done:
#if ISC_MEM_FILL
if (ret != NULL)
memset(ret, 0xbe, new_size); /* Mnemonic for "beef". */
#endif
return (ret);
}
void
__isc_mem_put(isc_mem_t *ctx, void *mem, size_t size)
{
REQUIRE(size > 0);
REQUIRE(VALID_CONTEXT(ctx));
LOCK(&ctx->lock);
mem_putunlocked(ctx, mem, size);
UNLOCK(&ctx->lock);
}
static inline void
mem_putunlocked(isc_mem_t *ctx, void *mem, size_t size)
{
size_t new_size = quantize(size);
#if ISC_MEM_FILL
memset(mem, 0xde, new_size); /* Mnemonic for "dead". */
#endif
if (size == ctx->max_size || new_size >= ctx->max_size) {
/* memput() called on something beyond our upper limit */
(ctx->memfree)(ctx->arg, mem);
INSIST(ctx->stats[ctx->max_size].gets != 0);
ctx->stats[ctx->max_size].gets--;
INSIST(size <= ctx->total);
ctx->total -= size;
return;
}
/* The free list uses the "rounded-up" size "new_size": */
((element *)mem)->next = ctx->freelists[new_size];
ctx->freelists[new_size] = (element *)mem;
/*
* The stats[] uses the _actual_ "size" requested by the
* caller, with the caveat (in the code above) that "size" >= the
* max. size (max_size) ends up getting recorded as a call to
* max_size.
*/
INSIST(ctx->stats[size].gets != 0);
ctx->stats[size].gets--;
ctx->stats[new_size].freefrags++;
}
void *
__isc_mem_getdebug(isc_mem_t *ctx, size_t size, const char *file, int line) {
void *ptr;
ptr = __isc_mem_get(ctx, size);
fprintf(stderr, "%s:%d: mem_get(%p, %lu) -> %p\n", file, line,
ctx, (unsigned long)size, ptr);
return (ptr);
}
void
__isc_mem_putdebug(isc_mem_t *ctx, void *ptr, size_t size, const char *file,
int line)
{
fprintf(stderr, "%s:%d: mem_put(%p, %p, %lu)\n", file, line,
ctx, ptr, (unsigned long)size);
__isc_mem_put(ctx, ptr, size);
}
/*
* Print the stats[] on the stream "out" with suitable formatting.
*/
void
isc_mem_stats(isc_mem_t *ctx, FILE *out)
{
size_t i;
const struct stats *s;
const isc_mempool_t *pool;
REQUIRE(VALID_CONTEXT(ctx));
LOCK(&ctx->lock);
if (ctx->freelists != NULL) {
for (i = 1; i <= ctx->max_size; i++) {
s = &ctx->stats[i];
if (s->totalgets == 0 && s->gets == 0)
continue;
fprintf(out, "%s%5d: %11lu gets, %11lu rem",
(i == ctx->max_size) ? ">=" : " ",
i, s->totalgets, s->gets);
if (s->blocks != 0)
fprintf(out, " (%lu bl, %lu ff)",
s->blocks, s->freefrags);
fputc('\n', out);
}
}
/*
* Note that since a pool can be locked now, these stats might be
* somewhat off if the pool is in active use at the time the stats
* are dumped. The link fields are protected by the isc_mem_t's
* lock, however, so walking this list and extracting integers from
* stats fields is always safe.
*/
pool = ISC_LIST_HEAD(ctx->pools);
if (pool != NULL) {
fprintf(out, "[Pool statistics]\n");
fprintf(out, "%10s %10s %10s %10s %10s %10s %10s %1s\n",
"size", "maxalloc", "allocated", "freecount",
"freemax", "fillcount", "gets", "L");
}
while (pool != NULL) {
fprintf(out, "%10u %10u %10u %10u %10u %10u %10u %s\n",
pool->size, pool->maxalloc, pool->allocated,
pool->freecount, pool->freemax, pool->fillcount,
pool->gets,
(pool->lock == NULL ? "N" : "Y"));
pool = ISC_LIST_NEXT(pool, link);
}
UNLOCK(&ctx->lock);
}
isc_boolean_t
isc_mem_valid(isc_mem_t *ctx, void *ptr) {
unsigned char *cp = ptr;
isc_boolean_t result = ISC_FALSE;
REQUIRE(VALID_CONTEXT(ctx));
LOCK(&ctx->lock);
if (ctx->lowest != NULL && cp >= ctx->lowest && cp <= ctx->highest)
result = ISC_TRUE;
UNLOCK(&ctx->lock);
return (result);
}
/*
* Replacements for malloc() and free().
*/
void *
isc_mem_allocate(isc_mem_t *ctx, size_t size) {
size_info *si;
size += ALIGNMENT_SIZE;
si = isc_mem_get(ctx, size);
if (si == NULL)
return (NULL);
si->size = size;
return (&si[1]);
}
void
isc_mem_free(isc_mem_t *ctx, void *ptr) {
size_info *si;
si = &(((size_info *)ptr)[-1]);
isc_mem_put(ctx, si, si->size);
}
/*
* Other useful things.
*/
char *
isc_mem_strdup(isc_mem_t *mctx, const char *s) {
size_t len;
char *ns;
len = strlen(s);
ns = isc_mem_allocate(mctx, len + 1);
if (ns == NULL)
return (NULL);
strncpy(ns, s, len + 1);
return (ns);
}
/*
* Quotas
*/
void
isc_mem_setquota(isc_mem_t *ctx, size_t quota) {
REQUIRE(VALID_CONTEXT(ctx));
LOCK(&ctx->lock);
ctx->quota = quota;
UNLOCK(&ctx->lock);
}
size_t
isc_mem_getquota(isc_mem_t *ctx) {
size_t quota;
REQUIRE(VALID_CONTEXT(ctx));
LOCK(&ctx->lock);
quota = ctx->quota;
UNLOCK(&ctx->lock);
return (quota);
}
#ifdef ISC_MEMCLUSTER_LEGACY
/*
* Public Legacy.
*/
static isc_mem_t *default_context = NULL;
int
meminit(size_t init_max_size, size_t target_size) {
/* need default_context lock here */
if (default_context != NULL)
return (-1);
return (isc_mem_create(init_max_size, target_size, &default_context));
}
isc_mem_t *
mem_default_context(void) {
/* need default_context lock here */
if (default_context == NULL && meminit(0, 0) == -1)
return (NULL);
return (default_context);
}
void *
__memget(size_t size) {
/* need default_context lock here */
if (default_context == NULL && meminit(0, 0) == -1)
return (NULL);
return (__mem_get(default_context, size));
}
void
__memput(void *mem, size_t size) {
/* need default_context lock here */
REQUIRE(default_context != NULL);
__mem_put(default_context, mem, size);
}
void *
__memget_debug(size_t size, const char *file, int line) {
void *ptr;
ptr = __memget(size);
fprintf(stderr, "%s:%d: memget(%lu) -> %p\n", file, line,
(unsigned long)size, ptr);
return (ptr);
}
void
__memput_debug(void *ptr, size_t size, const char *file, int line) {
fprintf(stderr, "%s:%d: memput(%p, %lu)\n", file, line,
ptr, (unsigned long)size);
__memput(ptr, size);
}
int
memvalid(void *ptr) {
/* need default_context lock here */
REQUIRE(default_context != NULL);
return (mem_valid(default_context, ptr));
}
void
memstats(FILE *out) {
/* need default_context lock here */
REQUIRE(default_context != NULL);
mem_stats(default_context, out);
}
#endif /* ISC_MEMCLUSTER_LEGACY */
/*
* Memory pool stuff
*/
#if 0
/*
* Free all but "n" items from the pool's free list. If n == 0, all items
* will be returned to the mctx.
*/
static void
mempool_release(isc_mempool_t *mpctx, unsigned int n)
{
isc_mem_t *mctx;
element *item;
element *next;
unsigned int count;
mctx = mpctx->mctx;
if (mpctx->freecount <= n)
return;
INSIST(mpctx->items != NULL);
item = mpctx->items;
for (count = 0 ; count < n ; count++) {
item = item->next;
INSIST(item != NULL);
}
/*
* All remaining items are to be freed. Lock the context once,
* free them all, and unlock the context.
*/
LOCK(&mctx->lock);
do {
next = item->next;
mem_putunlocked(mctx, item, mpctx->size);
INSIST(mpctx->freecount > 0);
mpctx->freecount--;
item = next;
} while (item != NULL);
UNLOCK(&mctx->lock);
}
#endif
/*
* Release all items on the free list. No locking is done, the memory
* context must be locked, and the pool if needed.
*/
static void
mempool_releaseall(isc_mempool_t *mpctx)
{
isc_mem_t *mctx;
element *item;
element *next;
mctx = mpctx->mctx;
if (mpctx->freecount == 0)
return;
INSIST(mpctx->items != NULL);
item = mpctx->items;
do {
next = item->next;
mem_putunlocked(mctx, item, mpctx->size);
INSIST(mpctx->freecount > 0);
mpctx->freecount--;
item = next;
} while (item != NULL);
}
isc_result_t
isc_mempool_create(isc_mem_t *mctx, size_t size, isc_mempool_t **mpctxp)
{
isc_mempool_t *mpctx;
REQUIRE(VALID_CONTEXT(mctx));
REQUIRE(size > 0);
REQUIRE(mpctxp != NULL && *mpctxp == NULL);
/*
* Allocate space for this pool, initialize values, and if all works
* well, attach to the memory context.
*/
LOCK(&mctx->lock);
mpctx = mem_getunlocked(mctx, sizeof(isc_mempool_t));
if (mpctx == NULL) {
UNLOCK(&mctx->lock);
return (ISC_R_NOMEMORY);
}
mpctx->magic = MEMPOOL_MAGIC;
mpctx->lock = NULL;
mpctx->mctx = mctx;
mpctx->size = size;
mpctx->maxalloc = UINT_MAX;
mpctx->allocated = 0;
mpctx->freecount = 0;
mpctx->freemax = 1;
mpctx->fillcount = 1;
mpctx->gets = 0;
mpctx->items = NULL;
*mpctxp = mpctx;
ISC_LIST_APPEND(mctx->pools, mpctx, link);
UNLOCK(&mctx->lock);
return (ISC_R_SUCCESS);
}
void
isc_mempool_destroy(isc_mempool_t **mpctxp)
{
isc_mempool_t *mpctx;
isc_mem_t *mctx;
isc_mutex_t *lock;
REQUIRE(mpctxp != NULL);
mpctx = *mpctxp;
REQUIRE(VALID_MEMPOOL(mpctx));
REQUIRE(mpctx->allocated == 0);
mctx = mpctx->mctx;
lock = mpctx->lock;
if (lock != NULL)
LOCK(lock);
LOCK(&mctx->lock);
/*
* Return any items on the free list
*/
mempool_releaseall(mpctx);
/*
* Remove our linked list entry from the memory context.
*/
ISC_LIST_UNLINK(mctx->pools, mpctx, link);
mpctx->magic = 0;
mem_putunlocked(mpctx->mctx, mpctx, sizeof(isc_mempool_t));
UNLOCK(&mctx->lock);
if (lock != NULL)
UNLOCK(lock);
*mpctxp = NULL;
}
void
isc_mempool_associatelock(isc_mempool_t *mpctx, isc_mutex_t *lock)
{
REQUIRE(VALID_MEMPOOL(mpctx));
REQUIRE(mpctx->lock == NULL);
REQUIRE(lock != NULL);
mpctx->lock = lock;
}
void *
__isc_mempool_get(isc_mempool_t *mpctx)
{
element *item;
isc_mem_t *mctx;
unsigned int i;
REQUIRE(VALID_MEMPOOL(mpctx));
mctx = mpctx->mctx;
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
/*
* Don't let the caller go over quota
*/
if (mpctx->allocated >= mpctx->maxalloc) {
item = NULL;
goto out;
}
/*
* if we have a free list item, return the first here
*/
item = mpctx->items;
if (item != NULL) {
mpctx->items = item->next;
INSIST(mpctx->freecount > 0);
mpctx->freecount--;
mpctx->gets++;
mpctx->allocated++;
goto out;
}
/*
* We need to dip into the well. Lock the memory context here and
* fill up our free list.
*/
LOCK(&mctx->lock);
for (i = 0 ; i < mpctx->fillcount ; i++) {
item = mem_getunlocked(mctx, mpctx->size);
if (item == NULL)
break;
item->next = mpctx->items;
mpctx->items = item;
mpctx->freecount++;
}
UNLOCK(&mctx->lock);
/*
* If we didn't get any items, return NULL.
*/
item = mpctx->items;
if (item == NULL)
goto out;
mpctx->items = item->next;
mpctx->freecount--;
mpctx->gets++;
mpctx->allocated++;
out:
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return (item);
}
void
__isc_mempool_put(isc_mempool_t *mpctx, void *mem)
{
isc_mem_t *mctx;
element *item;
REQUIRE(VALID_MEMPOOL(mpctx));
REQUIRE(mem != NULL);
mctx = mpctx->mctx;
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
INSIST(mpctx->allocated > 0);
mpctx->allocated--;
/*
* If our free list is full, return this to the mctx directly.
*/
if (mpctx->freecount >= mpctx->freemax) {
__isc_mem_put(mctx, mem, mpctx->size);
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return;
}
/*
* Otherwise, attach it to our free list and bump the counter.
*/
mpctx->freecount++;
item = (element *)mem;
item->next = mpctx->items;
mpctx->items = item;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
}
void *
__isc_mempool_getdebug(isc_mempool_t *mpctx,
const char *file, int line)
{
void *ptr;
ptr = __isc_mempool_get(mpctx);
fprintf(stderr, "%s:%d: mempool_get(%p) -> %p\n", file, line,
mpctx, ptr);
return (ptr);
}
void
__isc_mempool_putdebug(isc_mempool_t *mpctx, void *ptr,
const char *file, int line)
{
fprintf(stderr, "%s:%d: mempool_put(%p, %p)\n", file, line,
mpctx, ptr);
__isc_mempool_put(mpctx, ptr);
}
/*
* Quotas
*/
void
isc_mempool_setfreemax(isc_mempool_t *mpctx, unsigned int limit)
{
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
mpctx->freemax = limit;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
}
unsigned int
isc_mempool_getfreemax(isc_mempool_t *mpctx)
{
unsigned int freemax;
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
freemax = mpctx->freemax;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return (freemax);
}
unsigned int
isc_mempool_getfreecount(isc_mempool_t *mpctx)
{
unsigned int freecount;
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
freecount = mpctx->freecount;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return (freecount);
}
void
isc_mempool_setmaxalloc(isc_mempool_t *mpctx, unsigned int limit)
{
REQUIRE(limit > 0);
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
mpctx->maxalloc = limit;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
}
unsigned int
isc_mempool_getmaxalloc(isc_mempool_t *mpctx)
{
unsigned int maxalloc;
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
maxalloc = mpctx->maxalloc;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return (maxalloc);
}
unsigned int
isc_mempool_getallocated(isc_mempool_t *mpctx)
{
unsigned int allocated;
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
allocated = mpctx->allocated;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return (allocated);
}
void
isc_mempool_setfillcount(isc_mempool_t *mpctx, unsigned int limit)
{
REQUIRE(limit > 0);
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
mpctx->fillcount = limit;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
}
unsigned int
isc_mempool_getfillcount(isc_mempool_t *mpctx)
{
unsigned int fillcount;
REQUIRE(VALID_MEMPOOL(mpctx));
if (mpctx->lock != NULL)
LOCK(mpctx->lock);
fillcount = mpctx->fillcount;
if (mpctx->lock != NULL)
UNLOCK(mpctx->lock);
return (fillcount);
}