Memcached过期键删除策略
1. 惰性删除。memcached一般不会主动去清除已经过期或者失效的缓存,当get请求一个item的时候,才会去检查item是否失效。
2. flush命令。flush命令会将所有的item设置为失效。
3. 创建的时候检查。Memcached会在创建ITEM的时候去LRU的链表尾部开始检查,是否有失效的ITEM,如果没有的话就重新创建。
4. LRU爬虫。memcached默认是关闭LRU爬虫的。LRU爬虫是一个单独的线程,会去清理失效的ITEM。
5. LRU淘汰。当缓存没有内存可以分配给新的元素的时候,memcached会从LRU链表的尾部开始淘汰一个ITEM,不管这个ITEM是否还在有效期都将会面临淘汰。LRU链表插入缓存ITEM的时候有先后顺序,所以淘汰一个ITEM也是从尾部进行 也就是先淘汰最早的ITEM。
LRU的数据结构和基本操作
Mecached的LRU的链表操作主要在item.c这个文件上的。其中数组heads和tails分别存储不同的LRU的双向链表的头地址和尾部地址。
每个slabs class都会有自己的一个双向链表结构。链表结构主要通过item结构中的两个指针地址来记录item在链表上左右两边位置的item地址值。
1 //item的具体结构 2 typedef struct _stritem { 3 //记录LRU双向链表下一个item的地址 4 struct _stritem *next; //下一个结构 5 //记录LRU双向链表前一个Item的地址 6 struct _stritem *prev; //前一个结构 7 8 //....more code 9 } item;
item_link_q方法主要是将一个item添加到LRU链表上面:
1 //从LRU链表上新增一个Item 2 //LRU链表是一个双向链表结构 3 static void item_link_q(item *it) { /* item is the new head */ 4 item **head, **tail; 5 assert(it->slabs_clsid < LARGEST_ID); 6 assert((it->it_flags & ITEM_SLABBED) == 0); 7 8 head = &heads[it->slabs_clsid]; 9 tail = &tails[it->slabs_clsid]; 10 assert(it != *head); 11 assert((*head && *tail) || (*head == 0 && *tail == 0)); 12 it->prev = 0; 13 it->next = *head; 14 if (it->next) it->next->prev = it; 15 *head = it; 16 if (*tail == 0) *tail = it; 17 sizes[it->slabs_clsid]++; 18 return; 19 }
item_unlink_q方法主要是将一个item从LRU链表上面解除:
1 //从LRU链表上解除Item 2 static void item_unlink_q(item *it) { 3 item **head, **tail; 4 assert(it->slabs_clsid < LARGEST_ID); 5 head = &heads[it->slabs_clsid]; 6 tail = &tails[it->slabs_clsid]; 7 8 if (*head == it) { 9 assert(it->prev == 0); 10 *head = it->next; 11 } 12 if (*tail == it) { 13 assert(it->next == 0); 14 *tail = it->prev; 15 } 16 assert(it->next != it); 17 assert(it->prev != it); 18 19 if (it->next) it->next->prev = it->prev; 20 if (it->prev) it->prev->next = it->next; 21 sizes[it->slabs_clsid]--; 22 return; 23 }
策略1--惰性删除
Memcached的缓存清除策略是惰性的。这个如何来理解?当用户设置了一个缓存数据,缓存有效期为5分钟。当5分钟时间过后,缓存失效,这个时候Memcached并不会自动去检查当前的Item是否过期。当客户端再次来请求这个数据的时候,才会去检查缓存是否失效了,如果失效则会去清除这个数据。
看一下do_item_get这个方法中,判断缓存数据是否失效的代码:
1 /** wrapper around assoc_find which does the lazy expiration logic */ 2 item *do_item_get(const char *key, const size_t nkey, const uint32_t hv) { 3 //...code 4 if (it != NULL) { 5 //settings.oldest_live主要用来记录flush命令执行的时间 6 //it->time用来记录item最近set/add/replce等操作的时间(get操作不会改变) 7 //然后判断it->time是否在执行flush命令之前,如果是执行flush之前,说明该item已经失效 8 if (settings.oldest_live != 0 && settings.oldest_live <= current_time && 9 it->time <= settings.oldest_live) { 10 //LRU链表和HASHTABLE上解除绑定 11 do_item_unlink(it, hv); 12 //删除该Item 13 do_item_remove(it); 14 it = NULL; //返回NULL 15 if (was_found) { 16 fprintf(stderr, " -nuked by flush"); 17 } 18 //检查是否过期,主要是检查有效期时间 19 //如果数据已经过期,则需要清除 20 } else if (it->exptime != 0 && it->exptime <= current_time) { 21 //LRU链表和HASHTABLE上解除绑定 22 do_item_unlink(it, hv); 23 //删除该Item 24 do_item_remove(it); 25 it = NULL; 26 if (was_found) { 27 fprintf(stderr, " -nuked by expire"); 28 } 29 } else { 30 it->it_flags |= ITEM_FETCHED; 31 DEBUG_REFCNT(it, '+'); 32 } 33 } 34 //...code 35 }
策略2 -- flush命令
当用户发送一个flush命令的时候,Memcached会将命令之前的所有的缓存都设置为失效。
Memcached不会主动去清除这些item。主要通过两种方式:
1. do_item_flush_expired方法。
Memcached会在接受到flush命令的时候,将设置全局参数settings.oldest_live =current_time - 1。然后去调用item_flush_expired方法。因为设置全局参数item_flush_expired到调用缓存锁方法之间会有一定的时间差,有可能这个过程中,会有新的item在操作。
然后Memcached调用do_item_flush_expired方法,去遍历所有的LRU链表。do_item_flush_expired不会将每一个在flush命令前的Item删除,因为这样会非常耗时,而是删除在设置全局变量到加上缓存锁这之间操作的item。这样就能加快flush的速度。
2. 惰性删除方法。
Memcached会在get操作的时候去判断it->time是否小于settings.oldest_live,如果小于,说明这个item就是过期的。通过这种方法,惰性删除大批量的item数据。
1 /* 2 * Flushes expired items after a flush_all call 3 */ 4 void item_flush_expired() { 5 mutex_lock(&cache_lock); 6 do_item_flush_expired(); 7 mutex_unlock(&cache_lock); 8 } 9 /* expires items that are more recent than the oldest_live setting. */ 10 void do_item_flush_expired(void) { 11 int i; 12 item *iter, *next; 13 if (settings.oldest_live == 0) 14 return; 15 for (i = 0; i < LARGEST_ID; i++) { 16 /* The LRU is sorted in decreasing time order, and an item's timestamp 17 * is never newer than its last access time, so we only need to walk 18 * back until we hit an item older than the oldest_live time. 19 * The oldest_live checking will auto-expire the remaining items. 20 */ 21 for (iter = heads[i]; iter != NULL; iter = next) { 22 /* iter->time of 0 are magic objects. */ 23 //iter->time 最近一次的访问时间 24 //这边为何是iter->time >= settings.oldest_live? 25 //因为在执行do_item_flush_expired方法前,已经上了cache锁,其它worker是不能操作的 26 //这边过程中,如果遍历每一个Item都去删除,那么这个遍历过程会非常缓慢,会导致客户端一直等待。 27 // 28 //Memcached就想出了一个聪明的办法,从设置settings.oldest_live到上锁之间,还是会有其它客户端 29 //操作item数据,那么Memcache就将这一部分数据先清理(这部分数据非常少量),这样就能加快flush的速度 30 //而剩余iter->time < settings.oldest_live的那大批量的item,会通过惰性删除的方式,在get请求中去判断处理 31 if (iter->time != 0 && iter->time >= settings.oldest_live) { 32 next = iter->next; 33 if ((iter->it_flags & ITEM_SLABBED) == 0) { 34 do_item_unlink_nolock(iter, hash(ITEM_key(iter), iter->nkey)); 35 } 36 } else { 37 /* We've hit the first old item. Continue to the next queue. */ 38 break; 39 } 40 } 41 } 42 }
策略3 - -分配Item的时候去检查
1 //创建一个新的Item 2 item *do_item_alloc(char *key, const size_t nkey, const int flags, 3 const rel_time_t exptime, const int nbytes, 4 const uint32_t cur_hv) { 5 uint8_t nsuffix; 6 item *it = NULL; //item结构 7 char suffix[40]; 8 //item_make_header 计算存储数据的总长度 9 size_t ntotal = item_make_header(nkey + 1, flags, nbytes, suffix, &nsuffix); 10 if (settings.use_cas) { 11 ntotal += sizeof(uint64_t); 12 } 13 14 //通过ntotal 查询在哪个slabs_class上面 15 //Memcached会根据存储数据长度的不同,分为N多个slabs_class 16 //用户存储数据的时候,根据需要存储数据的长度,就可以查询到需要存储到哪个slabs_class中。 17 //每个slabs_class都由诺干个slabs组成,slabs每个大小为1M,我们的item结构的数据就会被分配在slabs上 18 //每个slabs都会根据自己slabs_class存储的数据块的大小,会被分割为诺干个chunk 19 // 20 //举个例子: 21 //如果id=1的slabs_class为存储 最大为224个字节的缓存数据 22 //当用户的设置的缓存数据总数据长度为200个字节,则这个item结构就会存储到id=1的slabs_class上。 23 //当第一次或者slabs_class中的slabs不够用的时候,slabs_class就会去分配一个1M的slabs给存储item使用 24 //因为id=1的slabs_class存储小于224个字节的数据,所以slabs会被分割为诺干个大小为224字节的chunk块 25 //我们的item结构数据,就会存储在这个chunk块上面 26 unsigned int id = slabs_clsid(ntotal); 27 if (id == 0) 28 return 0; 29 30 mutex_lock(&cache_lock); 31 /* do a quick check if we have any expired items in the tail.. */ 32 int tries = 5; 33 /* Avoid hangs if a slab has nothing but refcounted stuff in it. */ 34 int tries_lrutail_reflocked = 1000; 35 int tried_alloc = 0; 36 item *search; 37 item *next_it; 38 void *hold_lock = NULL; 39 rel_time_t oldest_live = settings.oldest_live; 40 41 //这边就可以得到slabs_class上第一个item的地址 42 //item数据结构通过item->next和item->prev 来记录链表结构 43 //这边是寻找LRU 链表的尾部地址 44 search = tails[id]; 45 46 /* We walk up *only* for locked items. Never searching for expired. 47 * Waste of CPU for almost all deployments */ 48 //tries = 5 这边只尝试5次循环搜索 49 //search = tails[id] 搜索从LRU链表 的尾部开始 50 for (; tries > 0 && search != NULL; tries--, search=next_it) { 51 /* we might relink search mid-loop, so search->prev isn't reliable */ 52 next_it = search->prev; 53 if (search->nbytes == 0 && search->nkey == 0 && search->it_flags == 1) { 54 /* We are a crawler, ignore it. */ 55 tries++; 56 continue; 57 } 58 uint32_t hv = hash(ITEM_key(search), search->nkey); 59 /* Attempt to hash item lock the "search" item. If locked, no 60 * other callers can incr the refcount 61 */ 62 /* Don't accidentally grab ourselves, or bail if we can't quicklock */ 63 if (hv == cur_hv || (hold_lock = item_trylock(hv)) == NULL) 64 continue; 65 /* Now see if the item is refcount locked */ 66 67 //一般情况下search->refcount为1,如果增加了refcount之后,不等于2,说明item被其它的worker线程锁定 68 //refcount往上加1,是锁定当前的item,如果不等于2,说明锁定失败 69 if (refcount_incr(&search->refcount) != 2) { 70 /* Avoid pathological case with ref'ed items in tail */ 71 do_item_update_nolock(search); 72 tries_lrutail_reflocked--; 73 tries++; //try的次数+1 74 refcount_decr(&search->refcount); //减去1 75 itemstats[id].lrutail_reflocked++; 76 /* Old rare bug could cause a refcount leak. We haven't seen 77 * it in years, but we leave this code in to prevent failures 78 * just in case */ 79 if (settings.tail_repair_time && 80 search->time + settings.tail_repair_time < current_time) { 81 itemstats[id].tailrepairs++; 82 search->refcount = 1; 83 do_item_unlink_nolock(search, hv); 84 } 85 if (hold_lock) 86 item_trylock_unlock(hold_lock); 87 88 if (tries_lrutail_reflocked < 1) 89 break; 90 91 continue; 92 } 93 94 /* Expired or flushed */ 95 //这边判断尾部的Item是否失效,如果已经失效了的话,将当前的失效的item分配给最新的缓存 96 if ((search->exptime != 0 && search->exptime < current_time) 97 || (search->time <= oldest_live && oldest_live <= current_time)) { 98 itemstats[id].reclaimed++; 99 if ((search->it_flags & ITEM_FETCHED) == 0) { 100 itemstats[id].expired_unfetched++; 101 } 102 it = search; 103 slabs_adjust_mem_requested(it->slabs_clsid, ITEM_ntotal(it), ntotal); 104 do_item_unlink_nolock(it, hv); 105 /* Iniialize the item block: */ 106 it->slabs_clsid = 0; 107 108 //slabs_alloc方法是去分配一个新的内存块 109 } else if ((it = slabs_alloc(ntotal, id)) == NULL) { 110 tried_alloc = 1; 111 //如果设置了不允许LRU淘汰,则返回ERROR 112 if (settings.evict_to_free == 0) { 113 itemstats[id].outofmemory++; 114 } else { 115 //这边设置了LRU淘汰 116 //如果分配失败,则从LRU链表尾部,淘汰一个item 117 //如果这个item设置了有效期为0,也会被淘汰 118 itemstats[id].evicted++; 119 itemstats[id].evicted_time = current_time - search->time; 120 if (search->exptime != 0) 121 itemstats[id].evicted_nonzero++; 122 if ((search->it_flags & ITEM_FETCHED) == 0) { 123 itemstats[id].evicted_unfetched++; 124 } 125 //这边直接将LRU尾部的ITEM淘汰,并且给了最新的ITEM使用 126 it = search; 127 //重新计算一下这个slabclass_t分配出去的内存大小 128 //直接霸占被淘汰的item就需要重新计算 129 slabs_adjust_mem_requested(it->slabs_clsid, ITEM_ntotal(it), ntotal); 130 //从哈希表和lru链表中删除 131 //it->refcount的值为2,所以item不会被删除,只是HashTable和LRU上的链接关系 132 do_item_unlink_nolock(it, hv); 133 /* Initialize the item block: */ 134 it->slabs_clsid = 0; 135 136 /* If we've just evicted an item, and the automover is set to 137 * angry bird mode, attempt to rip memory into this slab class. 138 * TODO: Move valid object detection into a function, and on a 139 * "successful" memory pull, look behind and see if the next alloc 140 * would be an eviction. Then kick off the slab mover before the 141 * eviction happens. 142 */ 143 if (settings.slab_automove == 2) 144 slabs_reassign(-1, id); 145 } 146 } 147 148 //解除引用锁定 149 refcount_decr(&search->refcount); 150 /* If hash values were equal, we don't grab a second lock */ 151 if (hold_lock) 152 item_trylock_unlock(hold_lock); 153 break; 154 } 155 156 /* 如果分配了5次,结果LRU链表尾部的item都是被锁定的,则重新分配一个item */ 157 if (!tried_alloc && (tries == 0 || search == NULL)) 158 it = slabs_alloc(ntotal, id); 159 160 if (it == NULL) { 161 itemstats[id].outofmemory++; 162 mutex_unlock(&cache_lock); 163 return NULL; 164 } 165 166 assert(it->slabs_clsid == 0); 167 assert(it != heads[id]); 168 169 /* Item initialization can happen outside of the lock; the item's already 170 * been removed from the slab LRU. 171 */ 172 it->refcount = 1; //引用的次数 又设置为1 /* the caller will have a reference */ 173 mutex_unlock(&cache_lock); 174 it->next = it->prev = it->h_next = 0; 175 it->slabs_clsid = id; 176 177 DEBUG_REFCNT(it, '*'); 178 it->it_flags = settings.use_cas ? ITEM_CAS : 0; 179 it->nkey = nkey; 180 it->nbytes = nbytes; 181 //这边是内存拷贝,拷贝到item结构地址的内存块上 182 memcpy(ITEM_key(it), key, nkey); 183 it->exptime = exptime; 184 //这边也是内存拷贝 185 memcpy(ITEM_suffix(it), suffix, (size_t)nsuffix); 186 it->nsuffix = nsuffix; 187 return it; 188 }
策略4 - -LRU爬虫
Memcached会开一个单独的线程对失效的缓存数据进行处理。
1 //LRU爬虫 2 static void *item_crawler_thread(void *arg) { 3 int i; 4 5 pthread_mutex_lock(&lru_crawler_lock); 6 if (settings.verbose > 2) 7 fprintf(stderr, "Starting LRU crawler background thread\n"); 8 while (do_run_lru_crawler_thread) { 9 pthread_cond_wait(&lru_crawler_cond, &lru_crawler_lock); 10 11 while (crawler_count) { 12 item *search = NULL; 13 void *hold_lock = NULL; 14 15 for (i = 0; i < LARGEST_ID; i++) { 16 if (crawlers[i].it_flags != 1) { 17 continue; 18 } 19 pthread_mutex_lock(&cache_lock); 20 search = crawler_crawl_q((item *)&crawlers[i]); 21 if (search == NULL || 22 (crawlers[i].remaining && --crawlers[i].remaining < 1)) { 23 if (settings.verbose > 2) 24 fprintf(stderr, "Nothing left to crawl for %d\n", i); 25 crawlers[i].it_flags = 0; 26 crawler_count--; 27 crawler_unlink_q((item *)&crawlers[i]); 28 pthread_mutex_unlock(&cache_lock); 29 continue; 30 } 31 uint32_t hv = hash(ITEM_key(search), search->nkey); 32 /* Attempt to hash item lock the "search" item. If locked, no 33 * other callers can incr the refcount 34 */ 35 if ((hold_lock = item_trylock(hv)) == NULL) { 36 pthread_mutex_unlock(&cache_lock); 37 continue; 38 } 39 /* Now see if the item is refcount locked */ 40 if (refcount_incr(&search->refcount) != 2) { 41 refcount_decr(&search->refcount); 42 if (hold_lock) 43 item_trylock_unlock(hold_lock); 44 pthread_mutex_unlock(&cache_lock); 45 continue; 46 } 47 48 /* Frees the item or decrements the refcount. */ 49 /* Interface for this could improve: do the free/decr here 50 * instead? */ 51 item_crawler_evaluate(search, hv, i); 52 53 if (hold_lock) 54 item_trylock_unlock(hold_lock); 55 pthread_mutex_unlock(&cache_lock); 56 57 if (settings.lru_crawler_sleep) 58 usleep(settings.lru_crawler_sleep); 59 } 60 } 61 if (settings.verbose > 2) 62 fprintf(stderr, "LRU crawler thread sleeping\n"); 63 STATS_LOCK(); 64 stats.lru_crawler_running = false; 65 STATS_UNLOCK(); 66 } 67 pthread_mutex_unlock(&lru_crawler_lock); 68 if (settings.verbose > 2) 69 fprintf(stderr, "LRU crawler thread stopping\n"); 70 71 return NULL; 72 } 73 74 75 int start_item_crawler_thread(void) { 76 int ret; 77 78 if (settings.lru_crawler) 79 return -1; 80 pthread_mutex_lock(&lru_crawler_lock); 81 do_run_lru_crawler_thread = 1; 82 settings.lru_crawler = true; 83 if ((ret = pthread_create(&item_crawler_tid, NULL, 84 item_crawler_thread, NULL)) != 0) { 85 fprintf(stderr, "Can't create LRU crawler thread: %s\n", 86 strerror(ret)); 87 pthread_mutex_unlock(&lru_crawler_lock); 88 return -1; 89 } 90 pthread_mutex_unlock(&lru_crawler_lock); 91 92 return 0; 93 }