一、GTID生成类型

这里首先使用源码的解释给出三种类型：

AUTOMATIC_GROUPGTID_GROUPANONYMOUS_GROUP

其中AUTOMATIC_GROUP通常用于主库开启GTID的情况，GTID_GROUP通常用于备库和使用了GTID_NEXT的情况下。

源码中有详细解释如下：

/**    Specifies that the GTID has not been generated yet; it will be    generated on commit.  It will depend on the GTID_MODE: if    GTID_MODE<=OFF_PERMISSIVE, then the transaction will be anonymous;    if GTID_MODE>=ON_PERMISSIVE, then the transaction will be assigned    a new GTID.    This is the default value: thd->variables.gtid_next has this state    when GTID_NEXT="AUTOMATIC".    It is important that AUTOMATIC_GROUP==0 so that the default value    for thd->variables->gtid_next.type is AUTOMATIC_GROUP.  */  AUTOMATIC_GROUP= 0,  /**    Specifies that the transaction has been assigned a GTID (UUID:NUMBER).    thd->variables.gtid_next has this state when GTID_NEXT="UUID:NUMBER".    This is the state of GTID-transactions replicated to the slave.  */  GTID_GROUP,  /**    Specifies that the transaction is anonymous, i.e., it does not    have a GTID and will never be assigned one.    thd->variables.gtid_next has this state when GTID_NEXT="ANONYMOUS".    This is the state of any transaction generated on a pre-GTID    server, or on a server with GTID_MODE==OFF.  */ANONYMOUS_GROUP

二、GTID和LAST_COMMT/SEQUNCE_NUMBER的生成时机

GTID其实是在COMMIT的时候调用MySQL_BIN_LOG::ORDERED_COMMIT执行到FLUSH阶段产生GTID EVENT的时候才生成，生成后会将这个GTID加入到GTID_STATE的OWNED_GTIDS中，实际上这个过程不仅要生成GTID还会生成SEQUENCE_NUMBER和LAST_COMMIT并且会构造GTID_EVENT写入到BINLOG CACHE,最后将BINLOG CACHE写入到BINLOG FILE（注意这里还没有调用FSYNC真正落盘），下面是BINLOG_CACHE_DATA::FLUSH函数的片段：

if (!error)      if ((error= mysql_bin_log.write_gtid(thd, this, &writer))) //生成Gtid和Last_commt/sequnce_number构造好Gtid event并且写入到到binlog cache中        thd->commit_error= THD::CE_FLUSH_ERROR;if (!error)      error= mysql_bin_log.write_cache(thd, this, &writer);  //将binlog cache写入到文件

下面是MySQL_BIN_LOG.WRITE_GTID中生成GTID和LAST_COMMT/SEQUNCE_NUMBER的代码片段：

if (thd->variables.gtid_next.type == AUTOMATIC_GROUP)//如果过是非指定的Gtid则需要自动生成调用generate_automatic_gtid生成  {    if (gtid_state->generate_automatic_gtid(thd,            thd->get_transaction()->get_rpl_transaction_ctx()->get_sidno(),            thd->get_transaction()->get_rpl_transaction_ctx()->get_gno())            != RETURN_STATUS_OK)      DBUG_RETURN(true);  }.....//下面生成sequence_number和last_committed  int64 relative_sequence_number= trn_ctx->sequence_number - clock.get_offset();  int64 relative_last_committed=    trn_ctx->last_committed <= clock.get_offset() ?    SEQ_UNINIT : trn_ctx->last_committed - clock.get_offset();

其调用栈帧如下:

#0  Gtid_state::get_automatic_gno (this=0x2ff8bb0, sidno=1) at /root/mysql5.7.14/percona-server-5.7.14-7/sql/rpl_gtid_state.cc:564#1  0x0000000001803248 in Gtid_state::generate_automatic_gtid (this=0x2ff8bb0, thd=0x7fff2c000b70, specified_sidno=0, specified_gno=0)    at /root/mysql5.7.14/percona-server-5.7.14-7/sql/rpl_gtid_state.cc:628#2  0x0000000001845703 in MYSQL_BIN_LOG::write_gtid (this=0x2dffc80, thd=0x7fff2c000b70, cache_data=0x7fff2c021178, writer=0x7ffff0358810)    at /root/mysql5.7.14/percona-server-5.7.14-7/sql/binlog.cc:1167#3  0x0000000001846307 in binlog_cache_data::flush (this=0x7fff2c021178, thd=0x7fff2c000b70, bytes_written=0x7ffff03588b8, wrote_xid=0x7ffff0358917)    at /root/mysql5.7.14/percona-server-5.7.14-7/sql/binlog.cc:1454#4  0x0000000001860e57 in binlog_cache_mngr::flush (this=0x7fff2c020ff0, thd=0x7fff2c000b70, bytes_written=0x7ffff0358918, wrote_xid=0x7ffff0358917)    at /root/mysql5.7.14/percona-server-5.7.14-7/sql/binlog.cc:768#5  0x0000000001856d46 in MYSQL_BIN_LOG::flush_thread_caches (this=0x2dffc80, thd=0x7fff2c000b70) at /root/mysql5.7.14/percona-server-5.7.14-7/sql/binlog.cc:8470#6  0x0000000001856f77 in MYSQL_BIN_LOG::process_flush_stage_queue (this=0x2dffc80, total_bytes_var=0x7ffff0358a88, rotate_var=0x7ffff0358a87,     out_queue_var=0x7ffff0358a78) at /root/mysql5.7.14/percona-server-5.7.14-7/sql/binlog.cc:8532#7  0x0000000001858593 in MYSQL_BIN_LOG::ordered_commit (this=0x2dffc80, thd=0x7fff2c000b70, all=false, skip_commit=false)

接下来我们就需要具体研究下一个GTID是依靠什么逻辑生成的。我们需要查看函数GTID_STATE::GENERATE_AUTOMATIC_GTID和GTID_STATE::GET_AUTOMATIC_GNO逻辑，他们用于生成一个GTID。

三、GTID_STATE::GENERATE_AUTOMATIC_GTID逻辑

// If GTID_MODE = ON_PERMISSIVE or ON, generate a new GTID if (get_gtid_mode(GTID_MODE_LOCK_SID) >= GTID_MODE_ON_PERMISSIVE)//如果GTID_MODE是ON_PERMISSIVE和ON则生成GTID {   Gtid automatic_gtid= { specified_sidno, specified_gno };   if (automatic_gtid.sidno == 0)//如果是备库则sidno>0，如果是主库sidno==0，因为主库的Gtid这个时候才生成，但是备库则是使用GTID_GROUP指定生成     automatic_gtid.sidno= get_server_sidno();//此处返回本server的sidno   lock_sidno(automatic_gtid.sidno);//此处对并发生成GNO的多个线程进行控制   if (automatic_gtid.gno == 0)//如果是备库则gno>0，如果是主库gno == 0，因为主库的Gtid这个时候才生成，但是备库则是使用GTID_GROUP指定生成     automatic_gtid.gno= get_automatic_gno(automatic_gtid.sidno);//此处返回最后指定sidno的end gno   if (automatic_gtid.gno != -1)     acquire_ownership(thd, automatic_gtid);//此处将这个gtid 及上面的SIDNO:gno加入到owned_gtids中 并且赋予给线程 经过本步骤 可以显示   else     ret= RETURN_STATUS_REPORTED_ERROR;   unlock_sidno(automatic_gtid.sidno);//分配完成其他线程可以分配 } else //如果是OFF_PERMISSIVE或者OFF状态如何处理 这里不做讨论了 {   // If GTID_MODE = OFF or OFF_PERMISSIVE, just mark this thread as   // using an anonymous transaction.   thd->owned_gtid.sidno= THD::OWNED_SIDNO_ANONYMOUS;   thd->owned_gtid.gno= 0;   acquire_anonymous_ownership();   thd->owned_gtid.dbug_print(NULL,                              "set owned_gtid (anonymous) in generate_automatic_gtid"); } sid_lock->unlock();//释放读写锁接下来看看GNO的生成逻辑GTID_STATE::GET_AUTOMATIC_GNO。四、GTID_STATE::GENERATE_AUTOMATIC_GTID逻辑while (true) {   const Gtid_set::Interval *iv= ivit.get(); //定义Interval指针指向 这个链表指针开头,如果在进行下次循环会获得NULL   rpl_gno next_interval_start= iv != NULL ? iv->start : MAX_GNO; //正常情况下不会为NULL因此 next_interval_start 等于第一个interval的start，当然如果初始化会为NULL，                                                                  //如果Interval->next =NULL 则标示没有区间了。   while (next_candidate.gno < next_interval_start &&          DBUG_EVALUATE_IF("simulate_gno_exhausted", false, true)) //这里next_candidate.gno正常不会小于next_interval_start ，如果Interval->next =NULL或者初始化                                                                   //next_interval_start会被制为MAX_GNO那么条件成立                                                                     //DBUG_RETURN(next_candidate.gno);返回了这个gno 则GTID生成   {     if (owned_gtids.get_owner(next_candidate) == 0) //如果本GTID已经被其他线程占用则next_candidate.gno++;返回这个gno。       DBUG_RETURN(next_candidate.gno);     next_candidate.gno++;   }   if (iv == NULL ||       DBUG_EVALUATE_IF("simulate_gno_exhausted", true, false))   {     my_error(ER_GNO_EXHAUSTED, MYF(0));     DBUG_RETURN(-1);   }   next_candidate.gno= iv->end; //iv->end 则指向了本区间最大的值+1   ivit.next(); }

五、本节小结

学习完本节至少能够学习到：1、GTID在主库什么时候时候生成。2、LAST_COMMIT/SEQUENCE_NUMBER什么时候生成。3、GTID的生成逻辑是怎么样的。

原文发布时间为：2018-01-13

本文作者：高鹏（重庆八怪）本文来自云栖社区合作伙伴“”，了解相关信息可以关注“”微信公众号