本篇主要讲的是 AOF 持久化,了解 AOF 的数据组织方式和运作机制。redis 主要在 aof.c 中实现 AOF 的操作。
数据结构 rio
redis AOF 持久化同样借助了 struct rio. 详细内容在《深入剖析 redis RDB 持久化策略》中有介绍。
AOF 数据组织方式
假设 redis 内存有「name:Jhon」的键值对,那么进行 AOF 持久化后,AOF 文件有如下内容:
*2 # 2个参数 $6 # 第一个参数长度为 6 SELECT # 第一个参数 $1 # 第二参数长度为 1 8 # 第二参数 *3 # 3个参数 $3 # 第一个参数长度为 4 SET # 第一个参数 $4 # 第二参数长度为 4 name # 第二个参数 $4 # 第三个参数长度为 4 Jhon # 第二参数长度为 4
所以对上面的内容进行恢复,能得到熟悉的一条 redis 命令:SELECT 8;SET name Jhon.
可以想象的是,redis 遍历内存数据集中的每个 key-value 对,依次写入磁盘中;redis 启动的时候,从 AOF 文件中读取数据,恢复数据。
AOF 持久化运作机制
和 redis RDB 持久化运作机制不同,redis AOF 有后台执行和边服务边备份两种方式。
1)AOF 后台执行的方式和 RDB 有类似的地方,fork 一个子进程,主进程仍进行服务,子进程执行 AOF 持久化,数据被 dump 到磁盘上。与 RDB 不同的是,后台子进程持久化过程中,主进程会记录期间的所有数据变更(主进程还在服务),并存储在 server.aof_rewrite_buf_blocks 中;后台子进程结束后,redis 更新缓存追加到 AOF 文件中,是 RDB 持久化所不具备的。
来说说更新缓存这个东西。redis 服务器产生数据变更的时候,譬如 set name Jhon,不仅仅会修改内存数据集,也会记录此更新(修改)操作,记录的方式就是上面所说的数据组织方式。
更新缓存可以存储在 server.aof_buf 中,你可以把它理解为一个小型临时中转站,所有累积的更新缓存都会先放入这里,它会在特定时机写入文件或者插入到 server.aof_rewrite_buf_blocks 下链表(下面会详述);server.aof_buf 中的数据在 propagrate() 添加,在涉及数据更新的地方都会调用 propagrate() 以累积变更。更新缓存也可以存储在 server.aof_rewrite_buf_blocks,这是一个元素类型为 struct aofrwblock 的链表,你可以把它理解为一个仓库,当后台有 AOF 子进程的时候,会将累积的更新缓存(在 server.aof_buf 中)插入到链表中,而当 AOF 子进程结束,它会被整个写入到文件。两者是有关联的。
下面是后台执行的主要代码:
// 启动后台子进程,执行 AOF 持久化操作。bgrewriteaofCommand(),startAppendOnly(),serverCron() 中会调用此函数 /* This is how rewriting of the append only file in background works: * * 1) The user calls BGREWRITEAOF * 2) Redis calls this function, that forks(): * 2a) the child rewrite the append only file in a temp file. * 2b) the parent accumulates differences in server.aof_rewrite_buf. * 3) When the child finished '2a' exists. * 4) The parent will trap the exit code, if it's OK, will append the * data accumulated into server.aof_rewrite_buf into the temp file, and * finally will rename(2) the temp file in the actual file name. * The the new file is reopened as the new append only file. Profit! */ int rewriteAppendOnlyFileBackground(void) { pid_t childpid; long long start; // 已经有正在执行备份的子进程 if (server.aof_child_pid != -1) return REDIS_ERR; start = ustime(); if ((childpid = fork()) == 0) { char tmpfile[256]; // 子进程 /* Child */ // 关闭监听 closeListeningSockets(0); // 设置进程 title redisSetProcTitle("redis-aof-rewrite"); // 临时文件名 snprintf(tmpfile,256,"temp-rewriteaof-bg-%d.aof", (int) getpid()); // 脏数据,其实就是子进程所消耗的内存大小 if (rewriteAppendOnlyFile(tmpfile) == REDIS_OK) { // 获取脏数据大小 size_t private_dirty = zmalloc_get_private_dirty(); // 记录脏数据 if (private_dirty) { redisLog(REDIS_NOTICE, "AOF rewrite: %zu MB of memory used by copy-on-write", private_dirty/(1024*1024)); } exitFromChild(0); } else { exitFromChild(1); } } else { /* Parent */ server.stat_fork_time = ustime()-start; if (childpid == -1) { redisLog(REDIS_WARNING, "Can't rewrite append only file in background: fork: %s", strerror(errno)); return REDIS_ERR; } redisLog(REDIS_NOTICE, "Background append only file rewriting started by pid %d",childpid); // AOF 已经开始执行,取消 AOF 计划 server.aof_rewrite_scheduled = 0; // AOF 最近一次执行的起始时间 server.aof_rewrite_time_start = time(NULL); // 子进程 ID server.aof_child_pid = childpid; updateDictResizePolicy(); // 因为更新缓存都将写入文件,要强制产生选择数据集的指令 SELECT ,以防出现数据合并错误。 /* We set appendseldb to -1 in order to force the next call to the * feedAppendOnlyFile() to issue a SELECT command, so the differences * accumulated by the parent into server.aof_rewrite_buf will start * with a SELECT statement and it will be safe to merge. */ server.aof_selected_db = -1; replicationScriptCacheFlush(); return REDIS_OK; } return REDIS_OK; /* unreached */ } // AOF 持久化主函数。只在 rewriteAppendOnlyFileBackground() 中会调用此函数 /* Write a sequence of commands able to fully rebuild the dataset into * "filename". Used both by REWRITEAOF and BGREWRITEAOF. * * In order to minimize the number of commands needed in the rewritten * log Redis uses variadic commands when possible, such as RPUSH, SADD * and ZADD. However at max REDIS_AOF_REWRITE_ITEMS_PER_CMD items per time * are inserted using a single command. */ int rewriteAppendOnlyFile(char *filename) { dictIterator *di = NULL; dictEntry *de; rio aof; FILE *fp; char tmpfile[256]; int j; long long now = mstime(); /* Note that we have to use a different temp name here compared to the * one used by rewriteAppendOnlyFileBackground() function. */ snprintf(tmpfile,256,"temp-rewriteaof-%d.aof", (int) getpid()); // 打开文件 fp = fopen(tmpfile,"w"); if (!fp) { redisLog(REDIS_WARNING, "Opening the temp file for AOF rewrite in rewriteAppendOnlyFile(): %s", strerror(errno)); return REDIS_ERR; } // 初始化 rio 结构体 rioInitWithFile(&aof,fp); // 如果设置了自动备份参数,将进行设置 if (server.aof_rewrite_incremental_fsync) rioSetAutoSync(&aof,REDIS_AOF_AUTOSYNC_BYTES); // 备份每一个数据集 for (j = 0; j < server.dbnum; j++) { char selectcmd[] = "*2 $6 SELECT "; redisDb *db = server.db+j; dict *d = db->dict; if (dictSize(d) == 0) continue; // 获取数据集的迭代器 di = dictGetSafeIterator(d); if (!di) { fclose(fp); return REDIS_ERR; } // 写入 AOF 操作码 /* SELECT the new DB */ if (rioWrite(&aof,selectcmd,sizeof(selectcmd)-1) == 0) goto werr; // 写入数据集序号 if (rioWriteBulkLongLong(&aof,j) == 0) goto werr; // 写入数据集中每一个数据项 /* Iterate this DB writing every entry */ while((de = dictNext(di)) != NULL) { sds keystr; robj key, *o; long long expiretime; keystr = dictGetKey(de); o = dictGetVal(de); // 将 keystr 封装在 robj 里 initStaticStringObject(key,keystr); // 获取过期时间 expiretime = getExpire(db,&key); // 如果已经过期,放弃存储 /* If this key is already expired skip it */ if (expiretime != -1 && expiretime < now) continue; // 写入键值对应的写操作 /* Save the key and associated value */ if (o->type == REDIS_STRING) { /* Emit a SET command */ char cmd[]="*3 $3 SET "; if (rioWrite(&aof,cmd,sizeof(cmd)-1) == 0) goto werr; /* Key and value */ if (rioWriteBulkObject(&aof,&key) == 0) goto werr; if (rioWriteBulkObject(&aof,o) == 0) goto werr; } else if (o->type == REDIS_LIST) { if (rewriteListObject(&aof,&key,o) == 0) goto werr; } else if (o->type == REDIS_SET) { if (rewriteSetObject(&aof,&key,o) == 0) goto werr; } else if (o->type == REDIS_ZSET) { if (rewriteSortedSetObject(&aof,&key,o) == 0) goto werr; } else if (o->type == REDIS_HASH) { if (rewriteHashObject(&aof,&key,o) == 0) goto werr; } else { redisPanic("Unknown object type"); } // 写入过期时间 /* Save the expire time */ if (expiretime != -1) { char cmd[]="*3 $9 PEXPIREAT "; if (rioWrite(&aof,cmd,sizeof(cmd)-1) == 0) goto werr; if (rioWriteBulkObject(&aof,&key) == 0) goto werr; if (rioWriteBulkLongLong(&aof,expiretime) == 0) goto werr; } } // 释放迭代器 dictReleaseIterator(di); } // 写入磁盘 /* Make sure data will not remain on the OS's output buffers */ fflush(fp); aof_fsync(fileno(fp)); fclose(fp); // 重写文件名 /* Use RENAME to make sure the DB file is changed atomically only * if the generate DB file is ok. */ if (rename(tmpfile,filename) == -1) { redisLog(REDIS_WARNING,"Error moving temp append only file on the final destination: %s", strerror(errno)); unlink(tmpfile); return REDIS_ERR; } redisLog(REDIS_NOTICE,"SYNC append only file rewrite performed"); return REDIS_OK; werr: // 清理工作 fclose(fp); unlink(tmpfile); redisLog(REDIS_WARNING,"Write error writing append only file on disk: %s", strerror(errno)); if (di) dictReleaseIterator(di); return REDIS_ERR; } // 后台子进程结束后,redis 更新缓存 server.aof_rewrite_buf_blocks 追加到 AOF 文件中 // 在 AOF 持久化结束后会执行这个函数, backgroundRewriteDoneHandler() 主要工作是将 server.aof_rewrite_buf_blocks,即 AOF 缓存写入文件 /* A background append only file rewriting (BGREWRITEAOF) terminated its work. * Handle this. */ void backgroundRewriteDoneHandler(int exitcode, int bysignal) { ...... // 将 AOF 缓存 server.aof_rewrite_buf_blocks 的 AOF 写入磁盘 if (aofRewriteBufferWrite(newfd) == -1) { redisLog(REDIS_WARNING, "Error trying to flush the parent diff to the rewritten AOF: %s", strerror(errno)); close(newfd); goto cleanup; } ...... } // 将累积的更新缓存 server.aof_rewrite_buf_blocks 同步到磁盘 /* Write the buffer (possibly composed of multiple blocks) into the specified * fd. If no short write or any other error happens -1 is returned, * otherwise the number of bytes written is returned. */ ssize_t aofRewriteBufferWrite(int fd) { listNode *ln; listIter li; ssize_t count = 0; listRewind(server.aof_rewrite_buf_blocks,&li); while((ln = listNext(&li))) { aofrwblock *block = listNodeValue(ln); ssize_t nwritten; if (block->used) { nwritten = write(fd,block->buf,block->used); if (nwritten != block->used) { if (nwritten == 0) errno = EIO; return -1; } count += nwritten; } } return count; }
2)边服务边备份的方式,即 redis 服务器会把所有的数据变更存储在 server.aof_buf 中,并在特定时机将更新缓存写入预设定的文件(server.aof_filename)。特定时机有三种:
- 进入事件循环之前
- redis 服务器定时程序 serverCron() 中
- 停止 AOF 策略的 stopAppendOnly() 中
redis 无非是不想服务器突然崩溃终止,导致过多的数据丢失。redis 默认是每两秒钟进行一次边服务边备份,即隔两秒将累积的写入文件。
redis 为什么取消直接在本进程进行 AOF 持久化的方法?原因可能是产生一个 AOF 文件要比 RDB 文件消耗更多的时间;如果在当前进程执行 AOF 持久化,会占用服务进程(主进程)较多的时间,停止服务的时间也更长(?)
下面是边服务边备份的主要代码:
// 同步磁盘;将所有累积的更新 server.aof_buf 写入磁盘 /* Write the append only file buffer on disk. * * Since we are required to write the AOF before replying to the client, * and the only way the client socket can get a write is entering when the * the event loop, we accumulate all the AOF writes in a memory * buffer and write it on disk using this function just before entering * the event loop again. * * About the 'force' argument: * * When the fsync policy is set to 'everysec' we may delay the flush if there * is still an fsync() going on in the background thread, since for instance * on Linux write(2) will be blocked by the background fsync anyway. * When this happens we remember that there is some aof buffer to be * flushed ASAP, and will try to do that in the serverCron() function. * * However if force is set to 1 we'll write regardless of the background * fsync. */ void flushAppendOnlyFile(int force) { ssize_t nwritten; int sync_in_progress = 0; // 无数据,无需同步到磁盘 if (sdslen(server.aof_buf) == 0) return; // 创建线程任务,主要调用 fsync() if (server.aof_fsync == AOF_FSYNC_EVERYSEC) sync_in_progress = bioPendingJobsOfType(REDIS_BIO_AOF_FSYNC) != 0; // 如果没有设置强制同步的选项,可能不会立即进行同步 if (server.aof_fsync == AOF_FSYNC_EVERYSEC && !force) { // 推迟执行 AOF /* With this append fsync policy we do background fsyncing. * If the fsync is still in progress we can try to delay * the write for a couple of seconds. */ if (sync_in_progress) { if (server.aof_flush_postponed_start == 0) { // 设置延迟冲洗时间选项 /* No previous write postponinig, remember that we are * postponing the flush and return. */ server.aof_flush_postponed_start = server.unixtime; // /* Unix time sampled every cron cycle. */ return; // 没有超过 2s,直接结束 } else if (server.unixtime - server.aof_flush_postponed_start < 2) { /* We were already waiting for fsync to finish, but for less * than two seconds this is still ok. Postpone again. */ return; } // 否则,要强制写入磁盘 /* Otherwise fall trough, and go write since we can't wait * over two seconds. */ server.aof_delayed_fsync++; redisLog(REDIS_NOTICE,"Asynchronous AOF fsync is taking too long (disk is busy?). Writing the AOF buffer without waiting for fsync to complete, this may slow down Redis."); } } // 取消延迟冲洗时间设置 /* If you are following this code path, then we are going to write so * set reset the postponed flush sentinel to zero. */ server.aof_flush_postponed_start = 0; /* We want to perform a single write. This should be guaranteed atomic * at least if the filesystem we are writing is a real physical one. * While this will save us against the server being killed I don't think * there is much to do about the whole server stopping for power problems * or alike */ // AOF 文件已经打开了。将 server.aof_buf 中的所有缓存数据写入文件 nwritten = write(server.aof_fd,server.aof_buf,sdslen(server.aof_buf)); if (nwritten != (signed)sdslen(server.aof_buf)) { /* Ooops, we are in troubles. The best thing to do for now is * aborting instead of giving the illusion that everything is * working as expected. */ if (nwritten == -1) { redisLog(REDIS_WARNING,"Exiting on error writing to the append-only file: %s",strerror(errno)); } else { redisLog(REDIS_WARNING,"Exiting on short write while writing to " "the append-only file: %s (nwritten=%ld, " "expected=%ld)", strerror(errno), (long)nwritten, (long)sdslen(server.aof_buf)); if (ftruncate(server.aof_fd, server.aof_current_size) == -1) { redisLog(REDIS_WARNING, "Could not remove short write " "from the append-only file. Redis may refuse " "to load the AOF the next time it starts. " "ftruncate: %s", strerror(errno)); } } exit(1); } // 更新 AOF 文件的大小 server.aof_current_size += nwritten; /*当 server.aof_buf 足够小,重新利用空间,防止频繁的内存分配。 相反,当 server.aof_buf 占据大量的空间,采取的策略是释放空间,可见 redis 对内存很敏感。*/ /* Re-use AOF buffer when it is small enough. The maximum comes from the * arena size of 4k minus some overhead (but is otherwise arbitrary). */ if ((sdslen(server.aof_buf)+sdsavail(server.aof_buf)) < 4000) { sdsclear(server.aof_buf); } else { sdsfree(server.aof_buf); server.aof_buf = sdsempty(); } /* Don't fsync if no-appendfsync-on-rewrite is set to yes and there are * children doing I/O in the background. */ if (server.aof_no_fsync_on_rewrite && (server.aof_child_pid != -1 || server.rdb_child_pid != -1)) return; // sync,写入磁盘 /* Perform the fsync if needed. */ if (server.aof_fsync == AOF_FSYNC_ALWAYS) { /* aof_fsync is defined as fdatasync() for Linux in order to avoid * flushing metadata. */ aof_fsync(server.aof_fd); /* Let's try to get this data on the disk */ server.aof_last_fsync = server.unixtime; } else if ((server.aof_fsync == AOF_FSYNC_EVERYSEC && server.unixtime > server.aof_last_fsync)) { if (!sync_in_progress) aof_background_fsync(server.aof_fd); server.aof_last_fsync = server.unixtime; } }
细说更新缓存
上面两次提到了「更新缓存」,它即是 redis 累积的数据变更。
更新缓存可以存储在 server.aof_buf 中,可以存储在 server.server.aof_rewrite_buf_blocks 连表中。他们的关系是:每一次数据变更记录都会写入 server.aof_buf 中,同时如果后台子进程在持久化,变更记录还会被写入 server.server.aof_rewrite_buf_blocks 中。server.aof_buf 会在特定时期写入指定文件,server.server.aof_rewrite_buf_blocks 会在后台持久化结束后追加到文件。
redis 源码中是这么实现的:propagrate()->feedAppendOnlyFile()->aofRewriteBufferAppend()
注释:feedAppendOnlyFile() 会把更新添加到 server.aof_buf;接下来会有一个判断,如果存在 AOF 子进程,则调用 aofRewriteBufferAppend() 将 server.aof_buf 中的所有数据插入到 server.aof_rewrite_buf_blocks 链表。
一副可以缓解视力疲劳的图片——AOF 持久化运作机制:
下面是主要的代码:
// 向 AOF 和从机发布数据更新 /* Propagate the specified command (in the context of the specified database id) * to AOF and Slaves. * * flags are an xor between: * + REDIS_PROPAGATE_NONE (no propagation of command at all) * + REDIS_PROPAGATE_AOF (propagate into the AOF file if is enabled) * + REDIS_PROPAGATE_REPL (propagate into the replication link) */ void propagate(struct redisCommand *cmd, int dbid, robj **argv, int argc, int flags) { // AOF 策略需要打开,且设置 AOF 传播标记,将更新发布给本地文件 if (server.aof_state != REDIS_AOF_OFF && flags & REDIS_PROPAGATE_AOF) feedAppendOnlyFile(cmd,dbid,argv,argc); // 设置了从机传播标记,将更新发布给从机 if (flags & REDIS_PROPAGATE_REPL) replicationFeedSlaves(server.slaves,dbid,argv,argc); } // 将数据更新记录到 AOF 缓存中 void feedAppendOnlyFile(struct redisCommand *cmd, int dictid, robj **argv, int argc) { sds buf = sdsempty(); robj *tmpargv[3]; /* The DB this command was targeting is not the same as the last command * we appendend. To issue a SELECT command is needed. */ if (dictid != server.aof_selected_db) { char seldb[64]; snprintf(seldb,sizeof(seldb),"%d",dictid); buf = sdscatprintf(buf,"*2 $6 SELECT $%lu %s ", (unsigned long)strlen(seldb),seldb); server.aof_selected_db = dictid; } if (cmd->proc == expireCommand || cmd->proc == pexpireCommand || cmd->proc == expireatCommand) { /* Translate EXPIRE/PEXPIRE/EXPIREAT into PEXPIREAT */ buf = catAppendOnlyExpireAtCommand(buf,cmd,argv[1],argv[2]); } else if (cmd->proc == setexCommand || cmd->proc == psetexCommand) { /* Translate SETEX/PSETEX to SET and PEXPIREAT */ tmpargv[0] = createStringObject("SET",3); tmpargv[1] = argv[1]; tmpargv[2] = argv[3]; buf = catAppendOnlyGenericCommand(buf,3,tmpargv); decrRefCount(tmpargv[0]); buf = catAppendOnlyExpireAtCommand(buf,cmd,argv[1],argv[2]); } else { /* All the other commands don't need translation or need the * same translation already operated in the command vector * for the replication itself. */ buf = catAppendOnlyGenericCommand(buf,argc,argv); } // 将生成的 AOF 追加到 server.aof_buf 中。server.在下一次进入事件循环之前,aof_buf 中的内容将会写到磁盘上 /* Append to the AOF buffer. This will be flushed on disk just before * of re-entering the event loop, so before the client will get a * positive reply about the operation performed. */ if (server.aof_state == REDIS_AOF_ON) server.aof_buf = sdscatlen(server.aof_buf,buf,sdslen(buf)); // 如果已经有 AOF 子进程运行,redis 采取的策略是累积子进程 AOF 备份的数据和内存中数据集的差异。 aofRewriteBufferAppend() 把 buf 的内容追加到 server.aof_rewrite_buf_blocks 数组中 /* If a background append only file rewriting is in progress we want to * accumulate the differences between the child DB and the current one * in a buffer, so that when the child process will do its work we * can append the differences to the new append only file. */ if (server.aof_child_pid != -1) aofRewriteBufferAppend((unsigned char*)buf,sdslen(buf)); sdsfree(buf); } // 将数据更新记录写入 server.aof_rewrite_buf_blocks,此函数只由 feedAppendOnlyFile() 调用 /* Append data to the AOF rewrite buffer, allocating new blocks if needed. */ void aofRewriteBufferAppend(unsigned char *s, unsigned long len) { // 尾插法 listNode *ln = listLast(server.aof_rewrite_buf_blocks); aofrwblock *block = ln ? ln->value : NULL; while(len) { /* If we already got at least an allocated block, try appending * at least some piece into it. */ if (block) { unsigned long thislen = (block->free < len) ? block->free : len; if (thislen) { /* The current block is not already full. */ memcpy(block->buf+block->used, s, thislen); block->used += thislen; block->free -= thislen; s += thislen; len -= thislen; } } if (len) { /* First block to allocate, or need another block. */ int numblocks; // 创建新的节点,插到尾部 block = zmalloc(sizeof(*block)); block->free = AOF_RW_BUF_BLOCK_SIZE; block->used = 0; // 尾插法 listAddNodeTail(server.aof_rewrite_buf_blocks,block); /* Log every time we cross more 10 or 100 blocks, respectively * as a notice or warning. */ numblocks = listLength(server.aof_rewrite_buf_blocks); if (((numblocks+1) % 10) == 0) { int level = ((numblocks+1) % 100) == 0 ? REDIS_WARNING : REDIS_NOTICE; redisLog(level,"Background AOF buffer size: %lu MB", aofRewriteBufferSize()/(1024*1024)); } } } }
两种数据落地的方式,就是 AOF 的两个主线。因此,redis AOF 持久化机制有两条主线:后台执行和边服务边备份,抓住这两点就能理解 redis AOF 了。
这里有一个疑问,两条主线都会涉及文件的写:后台执行会写一个 AOF 文件,边服务边备份也会写一个,以哪个为准?
后台持久化的数据首先会被写入「temp-rewriteaof-bg-%d.aof」,其中「%d」是 AOF 子进程 id;待 AOF 子进程结束后,「temp-rewriteaof-bg-%d.aof」会被以追加的方式打开,继而写入 server.aof_rewrite_buf_blocks 中的更新缓存,最后「temp-rewriteaof-bg-%d.aof」文件被命名为 server.aof_filename,所以之前的名为 server.aof_filename 的文件会被删除,也就是说边服务边备份写入的文件会被删除。边服务边备份的数据会被一直写入到 server.aof_filename 文件中。
因此,确实会产生两个文件,但是最后都会变成 server.aof_filename 文件。
这里还有一个疑问,既然有了后台持久化,为什么还要边服务边备份?边服务边备份时间长了会产生数据冗余甚至备份过旧的数据,而后台持久化可以消除这些东西。看,这里是 redis 的双保险。
AOF 恢复过程
AOF 的数据恢复过程设计实在是棒极了,它模拟一个服务过程。redis 首先虚拟一个客户端,读取 AOF 文件恢复 redis 命令和参数;然后就像服务客户端一样执行命令相应的函数,从而恢复数据。这些过程主要在loadAppendOnlyFile() 中实现。
// 加载 AOF 文件,恢复数据 /* Replay the append log file. On error REDIS_OK is returned. On non fatal * error (the append only file is zero-length) REDIS_ERR is returned. On * fatal error an error message is logged and the program exists. */ int loadAppendOnlyFile(char *filename) { struct redisClient *fakeClient; FILE *fp = fopen(filename,"r"); struct redis_stat sb; int old_aof_state = server.aof_state; long loops = 0; // 文件大小不能为 0 if (fp && redis_fstat(fileno(fp),&sb) != -1 && sb.st_size == 0) { server.aof_current_size = 0; fclose(fp); return REDIS_ERR; } if (fp == NULL) { redisLog(REDIS_WARNING,"Fatal error: can't open the append log file for reading: %s",strerror(errno)); exit(1); } // 正在执行 AOF 加载操作,于是暂时禁止 AOF 的所有操作,以免混淆 /* Temporarily disable AOF, to prevent EXEC from feeding a MULTI * to the same file we're about to read. */ server.aof_state = REDIS_AOF_OFF; // 虚拟出一个客户端,即 redisClient fakeClient = createFakeClient(); startLoading(fp); while(1) { int argc, j; unsigned long len; robj **argv; char buf[128]; sds argsds; struct redisCommand *cmd; // 每循环 1000 次,在恢复数据的同时,服务器也为客户端服务。aeProcessEvents() 会进入事件循环 /* Serve the clients from time to time */ if (!(loops++ % 1000)) { loadingProgress(ftello(fp)); aeProcessEvents(server.el, AE_FILE_EVENTS|AE_DONT_WAIT); } // 可能 aof 文件到了结尾 if (fgets(buf,sizeof(buf),fp) == NULL) { if (feof(fp)) break; else goto readerr; } // 必须以“*”开头,格式不对,退出 if (buf[0] != '*') goto fmterr; // 参数的个数 argc = atoi(buf+1); // 参数个数错误 if (argc < 1) goto fmterr; // 为参数分配空间 argv = zmalloc(sizeof(robj*)*argc); // 依次读取参数 for (j = 0; j < argc; j++) { if (fgets(buf,sizeof(buf),fp) == NULL) goto readerr; if (buf[0] != '$') goto fmterr; len = strtol(buf+1,NULL,10); argsds = sdsnewlen(NULL,len); if (len && fread(argsds,len,1,fp) == 0) goto fmterr; argv[j] = createObject(REDIS_STRING,argsds); if (fread(buf,2,1,fp) == 0) goto fmterr; /* discard CRLF */ } // 找到相应的命令 /* Command lookup */ cmd = lookupCommand(argv[0]->ptr); if (!cmd) { redisLog(REDIS_WARNING,"Unknown command '%s' reading the append only file", (char*)argv[0]->ptr); exit(1); } // 执行命令,模拟服务客户端请求的过程,从而写入数据 /* Run the command in the context of a fake client */ fakeClient->argc = argc; fakeClient->argv = argv; cmd->proc(fakeClient); /* The fake client should not have a reply */ redisAssert(fakeClient->bufpos == 0 && listLength(fakeClient->reply) == 0); /* The fake client should never get blocked */ redisAssert((fakeClient->flags & REDIS_BLOCKED) == 0); // 释放虚拟客户端空间 /* Clean up. Command code may have changed argv/argc so we use the * argv/argc of the client instead of the local variables. */ for (j = 0; j < fakeClient->argc; j++) decrRefCount(fakeClient->argv[j]); zfree(fakeClient->argv); } /* This point can only be reached when EOF is reached without errors. * If the client is in the middle of a MULTI/EXEC, log error and quit. */ if (fakeClient->flags & REDIS_MULTI) goto readerr; // 清理工作 fclose(fp); freeFakeClient(fakeClient); // 恢复旧的 AOF 状态 server.aof_state = old_aof_state; stopLoading(); // 记录最近 AOF 操作的文件大小 aofUpdateCurrentSize(); server.aof_rewrite_base_size = server.aof_current_size; return REDIS_OK; readerr: // 错误,清理工作 if (feof(fp)) { redisLog(REDIS_WARNING,"Unexpected end of file reading the append only file"); } else { redisLog(REDIS_WARNING,"Unrecoverable error reading the append only file: %s", strerror(errno)); } exit(1); fmterr: redisLog(REDIS_WARNING,"Bad file format reading the append only file: make a backup of your AOF file, then use ./redis-check-aof --fix <filename>"); exit(1); }
AOF 的适用场景
如果对数据比较关心,分秒必争,可以用 AOF 持久化,而且 AOF 文件很容易进行分析。
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捣乱 2014-3-26