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slabs.c
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slabs.c
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/* -*- Mode: C; tab-width: 4; c-basic-offset: 4; indent-tabs-mode: nil -*- */
/*
* Slabs memory allocation, based on powers-of-N. Slabs are up to 1MB in size
* and are divided into chunks. The chunk sizes start off at the size of the
* "item" structure plus space for a small key and value. They increase by
* a multiplier factor from there, up to half the maximum slab size. The last
* slab size is always 1MB, since that's the maximum item size allowed by the
* memcached protocol.
*/
#include "memcached.h"
#include "storage.h"
#include <sys/mman.h>
#include <sys/stat.h>
#include <sys/socket.h>
#include <sys/resource.h>
#include <fcntl.h>
#include <netinet/in.h>
#include <errno.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <signal.h>
#include <assert.h>
#include <pthread.h>
//#define DEBUG_SLAB_MOVER
/* powers-of-N allocation structures */
typedef struct {
unsigned int size; /* sizes of items */
unsigned int perslab; /* how many items per slab */
void *slots; /* list of item ptrs */
unsigned int sl_curr; /* total free items in list */
unsigned int slabs; /* how many slabs were allocated for this class */
void **slab_list; /* array of slab pointers */
unsigned int list_size; /* size of prev array */
} slabclass_t;
static slabclass_t slabclass[MAX_NUMBER_OF_SLAB_CLASSES];
static size_t mem_limit = 0;
static size_t mem_malloced = 0;
/* If the memory limit has been hit once. Used as a hint to decide when to
* early-wake the LRU maintenance thread */
static bool mem_limit_reached = false;
static int power_largest;
static void *mem_base = NULL;
static void *mem_current = NULL;
static size_t mem_avail = 0;
#ifdef EXTSTORE
static void *storage = NULL;
#endif
/**
* Access to the slab allocator is protected by this lock
*/
static pthread_mutex_t slabs_lock = PTHREAD_MUTEX_INITIALIZER;
static pthread_mutex_t slabs_rebalance_lock = PTHREAD_MUTEX_INITIALIZER;
/*
* Forward Declarations
*/
static int grow_slab_list (const unsigned int id);
static int do_slabs_newslab(const unsigned int id);
static void *memory_allocate(size_t size);
static void do_slabs_free(void *ptr, const size_t size, unsigned int id);
/* Preallocate as many slab pages as possible (called from slabs_init)
on start-up, so users don't get confused out-of-memory errors when
they do have free (in-slab) space, but no space to make new slabs.
if maxslabs is 18 (POWER_LARGEST - POWER_SMALLEST + 1), then all
slab types can be made. if max memory is less than 18 MB, only the
smaller ones will be made. */
static void slabs_preallocate (const unsigned int maxslabs);
#ifdef EXTSTORE
void slabs_set_storage(void *arg) {
storage = arg;
}
#endif
/*
* Figures out which slab class (chunk size) is required to store an item of
* a given size.
*
* Given object size, return id to use when allocating/freeing memory for object
* 0 means error: can't store such a large object
*/
unsigned int slabs_clsid(const size_t size) {
int res = POWER_SMALLEST;
if (size == 0 || size > settings.item_size_max)
return 0;
while (size > slabclass[res].size)
if (res++ == power_largest) /* won't fit in the biggest slab */
return power_largest;
return res;
}
unsigned int slabs_size(const int clsid) {
return slabclass[clsid].size;
}
// TODO: could this work with the restartable memory?
// Docs say hugepages only work with private shm allocs.
/* Function split out for better error path handling */
static void * alloc_large_chunk(const size_t limit)
{
void *ptr = NULL;
#if defined(__linux__) && defined(MADV_HUGEPAGE)
size_t pagesize = 0;
FILE *fp;
int ret;
/* Get the size of huge pages */
fp = fopen("/proc/meminfo", "r");
if (fp != NULL) {
char buf[64];
while ((fgets(buf, sizeof(buf), fp)))
if (!strncmp(buf, "Hugepagesize:", 13)) {
ret = sscanf(buf + 13, "%zu\n", &pagesize);
/* meminfo huge page size is in KiBs */
pagesize <<= 10;
}
fclose(fp);
}
if (!pagesize) {
fprintf(stderr, "Failed to get supported huge page size\n");
return NULL;
}
if (settings.verbose > 1)
fprintf(stderr, "huge page size: %zu\n", pagesize);
/* This works because glibc simply uses mmap when the alignment is
* above a certain limit. */
ret = posix_memalign(&ptr, pagesize, limit);
if (ret != 0) {
fprintf(stderr, "Failed to get aligned memory chunk: %d\n", ret);
return NULL;
}
ret = madvise(ptr, limit, MADV_HUGEPAGE);
if (ret < 0) {
fprintf(stderr, "Failed to set transparent hugepage hint: %d\n", ret);
free(ptr);
ptr = NULL;
}
#elif defined(__FreeBSD__)
size_t align = (sizeof(size_t) * 8 - (__builtin_clzl(4095)));
ptr = mmap(NULL, limit, PROT_READ | PROT_WRITE, MAP_SHARED | MAP_ANON | MAP_ALIGNED(align) | MAP_ALIGNED_SUPER, -1, 0);
if (ptr == MAP_FAILED) {
fprintf(stderr, "Failed to set super pages\n");
ptr = NULL;
}
#else
ptr = malloc(limit);
#endif
return ptr;
}
unsigned int slabs_fixup(char *chunk, const int border) {
slabclass_t *p;
item *it = (item *)chunk;
int id = ITEM_clsid(it);
// memory isn't used yet. shunt to global pool.
// (which must be 0)
if (id == 0) {
//assert(border == 0);
p = &slabclass[0];
grow_slab_list(0);
p->slab_list[p->slabs++] = (char*)chunk;
return -1;
}
p = &slabclass[id];
// if we're on a page border, add the slab to slab class
if (border == 0) {
grow_slab_list(id);
p->slab_list[p->slabs++] = chunk;
}
// increase free count if ITEM_SLABBED
if (it->it_flags == ITEM_SLABBED) {
// if ITEM_SLABBED re-stack on freelist.
// don't have to run pointer fixups.
it->prev = 0;
it->next = p->slots;
if (it->next) it->next->prev = it;
p->slots = it;
p->sl_curr++;
//fprintf(stderr, "replacing into freelist\n");
}
return p->size;
}
/**
* Determines the chunk sizes and initializes the slab class descriptors
* accordingly.
*/
void slabs_init(const size_t limit, const double factor, const bool prealloc, const uint32_t *slab_sizes, void *mem_base_external, bool reuse_mem) {
int i = POWER_SMALLEST - 1;
unsigned int size = sizeof(item) + settings.chunk_size;
/* Some platforms use runtime transparent hugepages. If for any reason
* the initial allocation fails, the required settings do not persist
* for remaining allocations. As such it makes little sense to do slab
* preallocation. */
bool __attribute__ ((unused)) do_slab_prealloc = false;
mem_limit = limit;
if (prealloc && mem_base_external == NULL) {
mem_base = alloc_large_chunk(mem_limit);
if (mem_base) {
do_slab_prealloc = true;
mem_current = mem_base;
mem_avail = mem_limit;
} else {
fprintf(stderr, "Warning: Failed to allocate requested memory in"
" one large chunk.\nWill allocate in smaller chunks\n");
}
} else if (prealloc && mem_base_external != NULL) {
// Can't (yet) mix hugepages with mmap allocations, so separate the
// logic from above. Reusable memory also force-preallocates memory
// pages into the global pool, which requires turning mem_* variables.
do_slab_prealloc = true;
mem_base = mem_base_external;
// _current shouldn't be used in this case, but we set it to where it
// should be anyway.
if (reuse_mem) {
mem_current = ((char*)mem_base) + mem_limit;
mem_avail = 0;
} else {
mem_current = mem_base;
mem_avail = mem_limit;
}
}
memset(slabclass, 0, sizeof(slabclass));
while (++i < MAX_NUMBER_OF_SLAB_CLASSES-1) {
if (slab_sizes != NULL) {
if (slab_sizes[i-1] == 0)
break;
size = slab_sizes[i-1];
} else if (size >= settings.slab_chunk_size_max / factor) {
break;
}
/* Make sure items are always n-byte aligned */
if (size % CHUNK_ALIGN_BYTES)
size += CHUNK_ALIGN_BYTES - (size % CHUNK_ALIGN_BYTES);
slabclass[i].size = size;
slabclass[i].perslab = settings.slab_page_size / slabclass[i].size;
if (slab_sizes == NULL)
size *= factor;
if (settings.verbose > 1) {
fprintf(stderr, "slab class %3d: chunk size %9u perslab %7u\n",
i, slabclass[i].size, slabclass[i].perslab);
}
}
power_largest = i;
slabclass[power_largest].size = settings.slab_chunk_size_max;
slabclass[power_largest].perslab = settings.slab_page_size / settings.slab_chunk_size_max;
if (settings.verbose > 1) {
fprintf(stderr, "slab class %3d: chunk size %9u perslab %7u\n",
i, slabclass[i].size, slabclass[i].perslab);
}
/* for the test suite: faking of how much we've already malloc'd */
{
char *t_initial_malloc = getenv("T_MEMD_INITIAL_MALLOC");
if (t_initial_malloc) {
int64_t env_malloced;
if (safe_strtoll((const char *)t_initial_malloc, &env_malloced)) {
mem_malloced = (size_t)env_malloced;
}
}
}
if (do_slab_prealloc) {
if (!reuse_mem) {
slabs_preallocate(power_largest);
}
}
}
void slabs_prefill_global(void) {
void *ptr;
slabclass_t *p = &slabclass[0];
int len = settings.slab_page_size;
while (mem_malloced < mem_limit
&& (ptr = memory_allocate(len)) != NULL) {
grow_slab_list(0);
// Ensure the front header is zero'd to avoid confusing restart code.
// It's probably good enough to cast it and just zero slabs_clsid, but
// this is extra paranoid.
memset(ptr, 0, sizeof(item));
p->slab_list[p->slabs++] = ptr;
}
mem_limit_reached = true;
}
static void slabs_preallocate (const unsigned int maxslabs) {
int i;
unsigned int prealloc = 0;
/* pre-allocate a 1MB slab in every size class so people don't get
confused by non-intuitive "SERVER_ERROR out of memory"
messages. this is the most common question on the mailing
list. if you really don't want this, you can rebuild without
these three lines. */
for (i = POWER_SMALLEST; i < MAX_NUMBER_OF_SLAB_CLASSES; i++) {
if (++prealloc > maxslabs)
break;
if (do_slabs_newslab(i) == 0) {
fprintf(stderr, "Error while preallocating slab memory!\n"
"If using -L or other prealloc options, max memory must be "
"at least %d megabytes.\n", power_largest);
exit(1);
}
}
}
static int grow_slab_list (const unsigned int id) {
slabclass_t *p = &slabclass[id];
if (p->slabs == p->list_size) {
size_t new_size = (p->list_size != 0) ? p->list_size * 2 : 16;
void *new_list = realloc(p->slab_list, new_size * sizeof(void *));
if (new_list == 0) return 0;
p->list_size = new_size;
p->slab_list = new_list;
}
return 1;
}
static void split_slab_page_into_freelist(char *ptr, const unsigned int id) {
slabclass_t *p = &slabclass[id];
int x;
for (x = 0; x < p->perslab; x++) {
do_slabs_free(ptr, 0, id);
ptr += p->size;
}
}
/* Fast FIFO queue */
static void *get_page_from_global_pool(void) {
slabclass_t *p = &slabclass[SLAB_GLOBAL_PAGE_POOL];
if (p->slabs < 1) {
return NULL;
}
char *ret = p->slab_list[p->slabs - 1];
p->slabs--;
return ret;
}
static int do_slabs_newslab(const unsigned int id) {
slabclass_t *p = &slabclass[id];
slabclass_t *g = &slabclass[SLAB_GLOBAL_PAGE_POOL];
int len = (settings.slab_reassign || settings.slab_chunk_size_max != settings.slab_page_size)
? settings.slab_page_size
: p->size * p->perslab;
char *ptr;
if ((mem_limit && mem_malloced + len > mem_limit && p->slabs > 0
&& g->slabs == 0)) {
mem_limit_reached = true;
MEMCACHED_SLABS_SLABCLASS_ALLOCATE_FAILED(id);
return 0;
}
if ((grow_slab_list(id) == 0) ||
(((ptr = get_page_from_global_pool()) == NULL) &&
((ptr = memory_allocate((size_t)len)) == 0))) {
MEMCACHED_SLABS_SLABCLASS_ALLOCATE_FAILED(id);
return 0;
}
// Always wipe the memory at this stage: in restart mode the mmap memory
// could be unused, yet still full of data. Better for usability if we're
// wiping memory as it's being pulled out of the global pool instead of
// blocking startup all at once.
memset(ptr, 0, (size_t)len);
split_slab_page_into_freelist(ptr, id);
p->slab_list[p->slabs++] = ptr;
MEMCACHED_SLABS_SLABCLASS_ALLOCATE(id);
return 1;
}
/*@null@*/
static void *do_slabs_alloc(const size_t size, unsigned int id,
unsigned int flags) {
slabclass_t *p;
void *ret = NULL;
item *it = NULL;
if (id < POWER_SMALLEST || id > power_largest) {
MEMCACHED_SLABS_ALLOCATE_FAILED(size, 0);
return NULL;
}
p = &slabclass[id];
assert(p->sl_curr == 0 || (((item *)p->slots)->it_flags & ITEM_SLABBED));
assert(size <= p->size);
/* fail unless we have space at the end of a recently allocated page,
we have something on our freelist, or we could allocate a new page */
if (p->sl_curr == 0 && flags != SLABS_ALLOC_NO_NEWPAGE) {
do_slabs_newslab(id);
}
if (p->sl_curr != 0) {
/* return off our freelist */
it = (item *)p->slots;
p->slots = it->next;
if (it->next) it->next->prev = 0;
/* Kill flag and initialize refcount here for lock safety in slab
* mover's freeness detection. */
it->it_flags &= ~ITEM_SLABBED;
it->refcount = 1;
p->sl_curr--;
ret = (void *)it;
} else {
ret = NULL;
}
if (ret) {
MEMCACHED_SLABS_ALLOCATE(size, id, p->size, ret);
} else {
MEMCACHED_SLABS_ALLOCATE_FAILED(size, id);
}
return ret;
}
static void do_slabs_free_chunked(item *it, const size_t size) {
item_chunk *chunk = (item_chunk *) ITEM_schunk(it);
slabclass_t *p;
it->it_flags = ITEM_SLABBED;
// FIXME: refresh on how this works?
//it->slabs_clsid = 0;
it->prev = 0;
// header object's original classid is stored in chunk.
p = &slabclass[chunk->orig_clsid];
// original class id needs to be set on free memory.
it->slabs_clsid = chunk->orig_clsid;
if (chunk->next) {
chunk = chunk->next;
chunk->prev = 0;
} else {
// header with no attached chunk
chunk = NULL;
}
// return the header object.
// TODO: This is in three places, here and in do_slabs_free().
it->prev = 0;
it->next = p->slots;
if (it->next) it->next->prev = it;
p->slots = it;
p->sl_curr++;
item_chunk *next_chunk;
while (chunk) {
assert(chunk->it_flags == ITEM_CHUNK);
chunk->it_flags = ITEM_SLABBED;
p = &slabclass[chunk->slabs_clsid];
next_chunk = chunk->next;
chunk->prev = 0;
chunk->next = p->slots;
if (chunk->next) chunk->next->prev = chunk;
p->slots = chunk;
p->sl_curr++;
chunk = next_chunk;
}
return;
}
static void do_slabs_free(void *ptr, const size_t size, unsigned int id) {
slabclass_t *p;
item *it;
assert(id >= POWER_SMALLEST && id <= power_largest);
if (id < POWER_SMALLEST || id > power_largest)
return;
MEMCACHED_SLABS_FREE(size, id, ptr);
p = &slabclass[id];
it = (item *)ptr;
if ((it->it_flags & ITEM_CHUNKED) == 0) {
it->it_flags = ITEM_SLABBED;
it->slabs_clsid = id;
it->prev = 0;
it->next = p->slots;
if (it->next) it->next->prev = it;
p->slots = it;
p->sl_curr++;
} else {
do_slabs_free_chunked(it, size);
}
return;
}
/* With refactoring of the various stats code the automover won't need a
* custom function here.
*/
void fill_slab_stats_automove(slab_stats_automove *am) {
int n;
pthread_mutex_lock(&slabs_lock);
for (n = 0; n < MAX_NUMBER_OF_SLAB_CLASSES; n++) {
slabclass_t *p = &slabclass[n];
slab_stats_automove *cur = &am[n];
cur->chunks_per_page = p->perslab;
cur->free_chunks = p->sl_curr;
cur->total_pages = p->slabs;
cur->chunk_size = p->size;
}
pthread_mutex_unlock(&slabs_lock);
}
/* TODO: slabs_available_chunks should grow up to encompass this.
* mem_flag is redundant with the other function.
*/
unsigned int global_page_pool_size(bool *mem_flag) {
unsigned int ret = 0;
pthread_mutex_lock(&slabs_lock);
if (mem_flag != NULL)
*mem_flag = mem_malloced >= mem_limit ? true : false;
ret = slabclass[SLAB_GLOBAL_PAGE_POOL].slabs;
pthread_mutex_unlock(&slabs_lock);
return ret;
}
/*@null@*/
static void do_slabs_stats(ADD_STAT add_stats, void *c) {
int i, total;
/* Get the per-thread stats which contain some interesting aggregates */
struct thread_stats thread_stats;
threadlocal_stats_aggregate(&thread_stats);
total = 0;
for(i = POWER_SMALLEST; i <= power_largest; i++) {
slabclass_t *p = &slabclass[i];
if (p->slabs != 0) {
uint32_t perslab, slabs;
slabs = p->slabs;
perslab = p->perslab;
char key_str[STAT_KEY_LEN];
char val_str[STAT_VAL_LEN];
int klen = 0, vlen = 0;
APPEND_NUM_STAT(i, "chunk_size", "%u", p->size);
APPEND_NUM_STAT(i, "chunks_per_page", "%u", perslab);
APPEND_NUM_STAT(i, "total_pages", "%u", slabs);
APPEND_NUM_STAT(i, "total_chunks", "%u", slabs * perslab);
APPEND_NUM_STAT(i, "used_chunks", "%u",
slabs*perslab - p->sl_curr);
APPEND_NUM_STAT(i, "free_chunks", "%u", p->sl_curr);
/* Stat is dead, but displaying zero instead of removing it. */
APPEND_NUM_STAT(i, "free_chunks_end", "%u", 0);
APPEND_NUM_STAT(i, "get_hits", "%llu",
(unsigned long long)thread_stats.slab_stats[i].get_hits);
APPEND_NUM_STAT(i, "cmd_set", "%llu",
(unsigned long long)thread_stats.slab_stats[i].set_cmds);
APPEND_NUM_STAT(i, "delete_hits", "%llu",
(unsigned long long)thread_stats.slab_stats[i].delete_hits);
APPEND_NUM_STAT(i, "incr_hits", "%llu",
(unsigned long long)thread_stats.slab_stats[i].incr_hits);
APPEND_NUM_STAT(i, "decr_hits", "%llu",
(unsigned long long)thread_stats.slab_stats[i].decr_hits);
APPEND_NUM_STAT(i, "cas_hits", "%llu",
(unsigned long long)thread_stats.slab_stats[i].cas_hits);
APPEND_NUM_STAT(i, "cas_badval", "%llu",
(unsigned long long)thread_stats.slab_stats[i].cas_badval);
APPEND_NUM_STAT(i, "touch_hits", "%llu",
(unsigned long long)thread_stats.slab_stats[i].touch_hits);
total++;
}
}
/* add overall slab stats and append terminator */
APPEND_STAT("active_slabs", "%d", total);
APPEND_STAT("total_malloced", "%llu", (unsigned long long)mem_malloced);
add_stats(NULL, 0, NULL, 0, c);
}
static void *memory_allocate(size_t size) {
void *ret;
if (mem_base == NULL) {
/* We are not using a preallocated large memory chunk */
ret = malloc(size);
} else {
ret = mem_current;
if (size > mem_avail) {
return NULL;
}
/* mem_current pointer _must_ be aligned!!! */
if (size % CHUNK_ALIGN_BYTES) {
size += CHUNK_ALIGN_BYTES - (size % CHUNK_ALIGN_BYTES);
}
mem_current = ((char*)mem_current) + size;
if (size < mem_avail) {
mem_avail -= size;
} else {
mem_avail = 0;
}
}
mem_malloced += size;
return ret;
}
/* Must only be used if all pages are item_size_max */
static void memory_release() {
void *p = NULL;
if (mem_base != NULL)
return;
if (!settings.slab_reassign)
return;
while (mem_malloced > mem_limit &&
(p = get_page_from_global_pool()) != NULL) {
free(p);
mem_malloced -= settings.slab_page_size;
}
}
void *slabs_alloc(size_t size, unsigned int id,
unsigned int flags) {
void *ret;
pthread_mutex_lock(&slabs_lock);
ret = do_slabs_alloc(size, id, flags);
pthread_mutex_unlock(&slabs_lock);
return ret;
}
void slabs_free(void *ptr, size_t size, unsigned int id) {
pthread_mutex_lock(&slabs_lock);
do_slabs_free(ptr, size, id);
pthread_mutex_unlock(&slabs_lock);
}
void slabs_stats(ADD_STAT add_stats, void *c) {
pthread_mutex_lock(&slabs_lock);
do_slabs_stats(add_stats, c);
pthread_mutex_unlock(&slabs_lock);
}
static bool do_slabs_adjust_mem_limit(size_t new_mem_limit) {
/* Cannot adjust memory limit at runtime if prealloc'ed */
if (mem_base != NULL)
return false;
settings.maxbytes = new_mem_limit;
mem_limit = new_mem_limit;
mem_limit_reached = false; /* Will reset on next alloc */
memory_release(); /* free what might already be in the global pool */
return true;
}
bool slabs_adjust_mem_limit(size_t new_mem_limit) {
bool ret;
pthread_mutex_lock(&slabs_lock);
ret = do_slabs_adjust_mem_limit(new_mem_limit);
pthread_mutex_unlock(&slabs_lock);
return ret;
}
unsigned int slabs_available_chunks(const unsigned int id, bool *mem_flag,
unsigned int *chunks_perslab) {
unsigned int ret;
slabclass_t *p;
pthread_mutex_lock(&slabs_lock);
p = &slabclass[id];
ret = p->sl_curr;
if (mem_flag != NULL)
*mem_flag = mem_malloced >= mem_limit ? true : false;
if (chunks_perslab != NULL)
*chunks_perslab = p->perslab;
pthread_mutex_unlock(&slabs_lock);
return ret;
}
/* The slabber system could avoid needing to understand much, if anything,
* about items if callbacks were strategically used. Due to how the slab mover
* works, certain flag bits can only be adjusted while holding the slabs lock.
* Using these functions, isolate sections of code needing this and turn them
* into callbacks when an interface becomes more obvious.
*/
void slabs_mlock(void) {
pthread_mutex_lock(&slabs_lock);
}
void slabs_munlock(void) {
pthread_mutex_unlock(&slabs_lock);
}
static pthread_cond_t slab_rebalance_cond = PTHREAD_COND_INITIALIZER;
static volatile int do_run_slab_rebalance_thread = 1;
static int slab_rebalance_start(void) {
slabclass_t *s_cls;
int no_go = 0;
pthread_mutex_lock(&slabs_lock);
if (slab_rebal.s_clsid < SLAB_GLOBAL_PAGE_POOL ||
slab_rebal.s_clsid > power_largest ||
slab_rebal.d_clsid < SLAB_GLOBAL_PAGE_POOL ||
slab_rebal.d_clsid > power_largest ||
slab_rebal.s_clsid == slab_rebal.d_clsid)
no_go = -2;
s_cls = &slabclass[slab_rebal.s_clsid];
if (!grow_slab_list(slab_rebal.d_clsid)) {
no_go = -1;
}
if (s_cls->slabs < 2)
no_go = -3;
if (no_go != 0) {
pthread_mutex_unlock(&slabs_lock);
return no_go; /* Should use a wrapper function... */
}
/* Always kill the first available slab page as it is most likely to
* contain the oldest items
*/
slab_rebal.slab_start = s_cls->slab_list[0];
slab_rebal.slab_end = (char *)slab_rebal.slab_start +
(s_cls->size * s_cls->perslab);
slab_rebal.slab_pos = slab_rebal.slab_start;
slab_rebal.done = 0;
// Don't need to do chunk move work if page is in global pool.
if (slab_rebal.s_clsid == SLAB_GLOBAL_PAGE_POOL) {
slab_rebal.done = 1;
}
// Bit-vector to keep track of completed chunks
slab_rebal.completed = (uint8_t*)calloc(s_cls->perslab,sizeof(uint8_t));
slab_rebalance_signal = 2;
if (settings.verbose > 1) {
fprintf(stderr, "Started a slab rebalance\n");
}
pthread_mutex_unlock(&slabs_lock);
STATS_LOCK();
stats_state.slab_reassign_running = true;
STATS_UNLOCK();
return 0;
}
/* CALLED WITH slabs_lock HELD */
static void *slab_rebalance_alloc(const size_t size, unsigned int id) {
slabclass_t *s_cls;
s_cls = &slabclass[slab_rebal.s_clsid];
int x;
item *new_it = NULL;
for (x = 0; x < s_cls->perslab; x++) {
new_it = do_slabs_alloc(size, id, SLABS_ALLOC_NO_NEWPAGE);
/* check that memory isn't within the range to clear */
if (new_it == NULL) {
break;
}
if ((void *)new_it >= slab_rebal.slab_start
&& (void *)new_it < slab_rebal.slab_end) {
/* Pulled something we intend to free. Mark it as freed since
* we've already done the work of unlinking it from the freelist.
*/
new_it->refcount = 0;
new_it->it_flags = ITEM_SLABBED|ITEM_FETCHED;
#ifdef DEBUG_SLAB_MOVER
memcpy(ITEM_key(new_it), "deadbeef", 8);
#endif
new_it = NULL;
slab_rebal.inline_reclaim++;
} else {
break;
}
}
return new_it;
}
/* CALLED WITH slabs_lock HELD */
/* detaches item/chunk from freelist. */
static void slab_rebalance_cut_free(slabclass_t *s_cls, item *it) {
/* Ensure this was on the freelist and nothing else. */
assert(it->it_flags == ITEM_SLABBED);
if (s_cls->slots == it) {
s_cls->slots = it->next;
}
if (it->next) it->next->prev = it->prev;
if (it->prev) it->prev->next = it->next;
s_cls->sl_curr--;
}
enum move_status {
MOVE_PASS=0, MOVE_FROM_SLAB, MOVE_FROM_LRU, MOVE_BUSY, MOVE_LOCKED
};
#define SLAB_MOVE_MAX_LOOPS 1000
/* refcount == 0 is safe since nobody can incr while item_lock is held.
* refcount != 0 is impossible since flags/etc can be modified in other
* threads. instead, note we found a busy one and bail. logic in do_item_get
* will prevent busy items from continuing to be busy
* NOTE: This is checking it_flags outside of an item lock. I believe this
* works since it_flags is 8 bits, and we're only ever comparing a single bit
* regardless. ITEM_SLABBED bit will always be correct since we're holding the
* lock which modifies that bit. ITEM_LINKED won't exist if we're between an
* item having ITEM_SLABBED removed, and the key hasn't been added to the item
* yet. The memory barrier from the slabs lock should order the key write and the
* flags to the item?
* If ITEM_LINKED did exist and was just removed, but we still see it, that's
* still safe since it will have a valid key, which we then lock, and then
* recheck everything.
* This may not be safe on all platforms; If not, slabs_alloc() will need to
* seed the item key while holding slabs_lock.
*/
static int slab_rebalance_move(void) {
slabclass_t *s_cls;
int was_busy = 0;
int refcount = 0;
uint32_t hv;
void *hold_lock;
enum move_status status = MOVE_PASS;
s_cls = &slabclass[slab_rebal.s_clsid];
// the offset to check if completed or not
int offset = ((char*)slab_rebal.slab_pos-(char*)slab_rebal.slab_start)/(s_cls->size);
// skip acquiring the slabs lock for items we've already fully processed.
if (slab_rebal.completed[offset] == 0) {
pthread_mutex_lock(&slabs_lock);
hv = 0;
hold_lock = NULL;
item *it = slab_rebal.slab_pos;
item_chunk *ch = NULL;
status = MOVE_PASS;
if (it->it_flags & ITEM_CHUNK) {
/* This chunk is a chained part of a larger item. */
ch = (item_chunk *) it;
/* Instead, we use the head chunk to find the item and effectively
* lock the entire structure. If a chunk has ITEM_CHUNK flag, its
* head cannot be slabbed, so the normal routine is safe. */
it = ch->head;
assert(it->it_flags & ITEM_CHUNKED);
}
/* ITEM_FETCHED when ITEM_SLABBED is overloaded to mean we've cleared
* the chunk for move. Only these two flags should exist.
*/
if (it->it_flags != (ITEM_SLABBED|ITEM_FETCHED)) {
/* ITEM_SLABBED can only be added/removed under the slabs_lock */
if (it->it_flags & ITEM_SLABBED) {
assert(ch == NULL);
slab_rebalance_cut_free(s_cls, it);
status = MOVE_FROM_SLAB;
} else if ((it->it_flags & ITEM_LINKED) != 0) {
/* If it doesn't have ITEM_SLABBED, the item could be in any
* state on its way to being freed or written to. If no
* ITEM_SLABBED, but it's had ITEM_LINKED, it must be active
* and have the key written to it already.
*/
hv = hash(ITEM_key(it), it->nkey);
if ((hold_lock = item_trylock(hv)) == NULL) {
status = MOVE_LOCKED;
} else {
bool is_linked = (it->it_flags & ITEM_LINKED);
refcount = refcount_incr(it);
if (refcount == 2) { /* item is linked but not busy */
/* Double check ITEM_LINKED flag here, since we're
* past a memory barrier from the mutex. */
if (is_linked) {
status = MOVE_FROM_LRU;
} else {
/* refcount == 1 + !ITEM_LINKED means the item is being
* uploaded to, or was just unlinked but hasn't been freed
* yet. Let it bleed off on its own and try again later */
status = MOVE_BUSY;
}
} else if (refcount > 2 && is_linked) {
// TODO: Mark items for delete/rescue and process
// outside of the main loop.
if (slab_rebal.busy_loops > SLAB_MOVE_MAX_LOOPS) {
slab_rebal.busy_deletes++;
// Only safe to hold slabs lock because refcount
// can't drop to 0 until we release item lock.
STORAGE_delete(storage, it);
pthread_mutex_unlock(&slabs_lock);
do_item_unlink(it, hv);
pthread_mutex_lock(&slabs_lock);
}
status = MOVE_BUSY;
} else {
if (settings.verbose > 2) {
fprintf(stderr, "Slab reassign hit a busy item: refcount: %d (%d -> %d)\n",
it->refcount, slab_rebal.s_clsid, slab_rebal.d_clsid);
}
status = MOVE_BUSY;
}
/* Item lock must be held while modifying refcount */
if (status == MOVE_BUSY) {
refcount_decr(it);
item_trylock_unlock(hold_lock);
}
}
} else {
/* See above comment. No ITEM_SLABBED or ITEM_LINKED. Mark
* busy and wait for item to complete its upload. */
status = MOVE_BUSY;
}
}
int save_item = 0;
item *new_it = NULL;
size_t ntotal = 0;
switch (status) {
case MOVE_FROM_LRU:
/* Lock order is LRU locks -> slabs_lock. unlink uses LRU lock.
* We only need to hold the slabs_lock while initially looking
* at an item, and at this point we have an exclusive refcount
* (2) + the item is locked. Drop slabs lock, drop item to
* refcount 1 (just our own, then fall through and wipe it
*/
/* Check if expired or flushed */
ntotal = ITEM_ntotal(it);
#ifdef EXTSTORE
if (it->it_flags & ITEM_HDR) {
ntotal = (ntotal - it->nbytes) + sizeof(item_hdr);
}
#endif
/* REQUIRES slabs_lock: CHECK FOR cls->sl_curr > 0 */
if (ch == NULL && (it->it_flags & ITEM_CHUNKED)) {
/* Chunked should be identical to non-chunked, except we need
* to swap out ntotal for the head-chunk-total. */
ntotal = s_cls->size;
}
if ((it->exptime != 0 && it->exptime < current_time)
|| item_is_flushed(it)) {
/* Expired, don't save. */
save_item = 0;
} else if (ch == NULL &&
(new_it = slab_rebalance_alloc(ntotal, slab_rebal.s_clsid)) == NULL) {
/* Not a chunk of an item, and nomem. */
save_item = 0;
slab_rebal.evictions_nomem++;
} else if (ch != NULL &&
(new_it = slab_rebalance_alloc(s_cls->size, slab_rebal.s_clsid)) == NULL) {
/* Is a chunk of an item, and nomem. */
save_item = 0;
slab_rebal.evictions_nomem++;
} else {
/* Was whatever it was, and we have memory for it. */
save_item = 1;
}
pthread_mutex_unlock(&slabs_lock);
if (save_item) {
if (ch == NULL) {
assert((new_it->it_flags & ITEM_CHUNKED) == 0);
/* if free memory, memcpy. clear prev/next/h_bucket */
memcpy(new_it, it, ntotal);