MongoDB副本集(一主两从)读写分离、故障转移功能环境部署记录

Mongodb是一种非关系数据库(NoSQL),非关系型数据库的产生就是为了解决大数据量、高扩展性、高性能、灵活数据模型、高可用性。MongoDB官方已经不建议使用主从模式了,替代方案是采用副本集的模式。主从模式其实就是一个单副本的应用,没有很好的扩展性和容错性,而Mongodb副本集具有多个副本保证了容错性,就算一个副本挂掉了还有很多副本存在,主节点挂掉后,整个集群内会实现自动切换。

Mongodb副本集的工作原理
客户端连接到整个Mongodb副本集,不关心具体哪一台节点机是否挂掉。主节点机负责整个副本集的读写,副本集定期同步数据备份,一但主节点挂掉,副本节点就会选举一个新的主服务器,这一切对于应用服务器不需要关心。副本集中的副本节点在主节点挂掉后通过心跳机制检测到后,就会在集群内发起主节点的选举机制,自动选举一位新的主服务器。

看起来Mongodb副本集很牛X的样子,下面就演示下副本集环境部署过程,官方推荐的Mongodb副本集机器数量为至少3个节点,这里我就选择三个节点,一个主节点,两个从节点,暂不使用仲裁节点。

一、环境准备

ip地址                    主机名                               角色
172.16.60.205 mongodb-master01 副本集主节点
172.16.60.206 mongodb-slave01 副本集副本节点
172.16.60.207 mongodb-slave02 副本集副本节点 三个节点机均设置好各自的主机名,并如下设置好hosts绑定
[root@mongodb-master01 ~]# cat /etc/hosts
............
172.16.60.205 mongodb-master01
172.16.60.206 mongodb-slave01
172.16.60.207 mongodb-slave02 三个节点机均关闭selinux,为了测试方便,将iptables也关闭
[root@mongodb-master01 ~]# setenforce 0
[root@mongodb-master01 ~]# cat /etc/sysconfig/selinux
...........
SELINUX=disabled [root@mongodb-master01 ~]# iptables -F
[root@mongodb-master01 ~]# /etc/init.d/iptables stop
[root@mongodb-master01 ~]# /etc/init.d/iptables stop
iptables: Setting chains to policy ACCEPT: filter [ OK ]
iptables: Flushing firewall rules: [ OK ]
iptables: Unloading modules: [ OK ]

二、Mongodb安装、副本集配置

1) 在三个节点机上建立mongodb副本集测试文件夹,用于存放整个副本集文件
[root@mongodb-master01 ~]# mkdir -p /data/mongodb/data/replset/ 2)在三个节点机上安装mongodb
下载地址:https://www.mongodb.org/dl/linux/x86_64-rhel62 [root@mongodb-master01 ~]# wget http://downloads.mongodb.org/linux/mongodb-linux-x86_64-rhel62-v3.6-latest.tgz
[root@mongodb-master01 ~]# tar -zvxf mongodb-linux-x86_64-rhel62-v3.6-latest.tgz 3)分别在每个节点机上启动mongodb(启动时指明--bind_ip地址,默认是127.0.0.1,需要改成本机ip,否则远程连接时失败)
[root@mongodb-master01 ~]# mv mongodb-linux-x86_64-rhel62-3.6.11-rc0-2-g2151d1d219 /usr/local/mongodb
[root@mongodb-master01 ~]# nohup /usr/local/mongodb/bin/mongod -dbpath /data/mongodb/data/replset -replSet repset --bind_ip=172.16.60.205 --port=27017 & [root@mongodb-master01 ~]# ps -ef|grep mongodb
root 7729 6977 1 15:10 pts/1 00:00:01 /usr/local/mongodb/bin/mongod -dbpath /data/mongodb/data/replset -replSet repset
root 7780 6977 0 15:11 pts/1 00:00:00 grep mongodb [root@mongodb-master01 ~]# lsof -i:27017
COMMAND PID USER FD TYPE DEVICE SIZE/OFF NODE NAME
mongod 7729 root 10u IPv4 6554476 0t0 TCP localhost:27017 (LISTEN) 4)初始化副本集
在三个节点中的任意一个节点机上操作(比如在172.16.60.205节点机) 登陆mongodb
[root@mongodb-master01 ~]# /usr/local/mongodb/bin/mongo 172.16.60.205:27017
.........
#使用admin数据库
> use admin
switched to db admin #定义副本集配置变量,这里的 _id:”repset” 和上面命令参数“ –replSet repset” 要保持一样。
> config = { _id:"repset", members:[{_id:0,host:"172.16.60.205:27017"},{_id:1,host:"172.16.60.206:27017"},{_id:2,host:"172.16.60.207:27017"}]}
{
"_id" : "repset",
"members" : [
{
"_id" : 0,
"host" : "172.16.60.205:27017"
},
{
"_id" : 1,
"host" : "172.16.60.206:27017"
},
{
"_id" : 2,
"host" : "172.16.60.207:27017"
}
]
} #初始化副本集配置
> rs.initiate(config);
{
"ok" : 1,
"operationTime" : Timestamp(1551166191, 1),
"$clusterTime" : {
"clusterTime" : Timestamp(1551166191, 1),
"signature" : {
"hash" : BinData(0,"AAAAAAAAAAAAAAAAAAAAAAAAAAA="),
"keyId" : NumberLong(0)
}
}
} #查看集群节点的状态
repset:SECONDARY> rs.status();
{
"set" : "repset",
"date" : ISODate("2019-02-26T07:31:07.766Z"),
"myState" : 1,
"term" : NumberLong(1),
"syncingTo" : "",
"syncSourceHost" : "",
"syncSourceId" : -1,
"heartbeatIntervalMillis" : NumberLong(2000),
"optimes" : {
"lastCommittedOpTime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"readConcernMajorityOpTime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"appliedOpTime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"durableOpTime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
}
},
"members" : [
{
"_id" : 0,
"name" : "172.16.60.205:27017",
"health" : 1,
"state" : 1,
"stateStr" : "PRIMARY",
"uptime" : 270,
"optime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"optimeDate" : ISODate("2019-02-26T07:31:03Z"),
"syncingTo" : "",
"syncSourceHost" : "",
"syncSourceId" : -1,
"infoMessage" : "could not find member to sync from",
"electionTime" : Timestamp(1551166202, 1),
"electionDate" : ISODate("2019-02-26T07:30:02Z"),
"configVersion" : 1,
"self" : true,
"lastHeartbeatMessage" : ""
},
{
"_id" : 1,
"name" : "172.16.60.206:27017",
"health" : 1,
"state" : 2,
"stateStr" : "SECONDARY",
"uptime" : 76,
"optime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"optimeDurable" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"optimeDate" : ISODate("2019-02-26T07:31:03Z"),
"optimeDurableDate" : ISODate("2019-02-26T07:31:03Z"),
"lastHeartbeat" : ISODate("2019-02-26T07:31:06.590Z"),
"lastHeartbeatRecv" : ISODate("2019-02-26T07:31:06.852Z"),
"pingMs" : NumberLong(0),
"lastHeartbeatMessage" : "",
"syncingTo" : "172.16.60.205:27017",
"syncSourceHost" : "172.16.60.205:27017",
"syncSourceId" : 0,
"infoMessage" : "",
"configVersion" : 1
},
{
"_id" : 2,
"name" : "172.16.60.207:27017",
"health" : 1,
"state" : 2,
"stateStr" : "SECONDARY",
"uptime" : 76,
"optime" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"optimeDurable" : {
"ts" : Timestamp(1551166263, 1),
"t" : NumberLong(1)
},
"optimeDate" : ISODate("2019-02-26T07:31:03Z"),
"optimeDurableDate" : ISODate("2019-02-26T07:31:03Z"),
"lastHeartbeat" : ISODate("2019-02-26T07:31:06.589Z"),
"lastHeartbeatRecv" : ISODate("2019-02-26T07:31:06.958Z"),
"pingMs" : NumberLong(0),
"lastHeartbeatMessage" : "",
"syncingTo" : "172.16.60.205:27017",
"syncSourceHost" : "172.16.60.205:27017",
"syncSourceId" : 0,
"infoMessage" : "",
"configVersion" : 1
}
],
"ok" : 1,
"operationTime" : Timestamp(1551166263, 1),
"$clusterTime" : {
"clusterTime" : Timestamp(1551166263, 1),
"signature" : {
"hash" : BinData(0,"AAAAAAAAAAAAAAAAAAAAAAAAAAA="),
"keyId" : NumberLong(0)
}
}
} 如上信息表明:
副本集配置成功后,172.16.60.205为主节点PRIMARY,172.16.60.206/207为副本节点SECONDARY。
health:1 1表明状态是正常,0表明异常
state:1 值小的是primary节点、值大的是secondary节点

三、测试Mongodb副本集数据复制功能 <mongodb默认是从主节点读写数据的,副本节点上不允许读,需要设置副本节点可以读>

1)在主节点172.16.60.205上连接到终端
[root@mongodb-master01 ~]# /usr/local/mongodb/bin/mongo 172.16.60.205:27017
................
#建立test 数据库
repset:PRIMARY> use test;
switched to db test #往testdb表插入测试数据
repset:PRIMARY> db.testdb.insert({"test1":"testval1"})
WriteResult({ "nInserted" : 1 }) 2)在副本节点172.16.60.206、172.16.60.207上连接到mongodb查看数据是否复制过来。
这里在172.16.60.206副本节点上进行查看
[root@mongodb-slave01 ~]# /usr/local/mongodb/bin/mongo 172.16.60.206:27017
................
repset:SECONDARY> use test;
switched to db test
repset:SECONDARY> show tables;
2019-02-26T15:37:46.446+0800 E QUERY [thread1] Error: listCollections failed: {
"operationTime" : Timestamp(1551166663, 1),
"ok" : 0,
"errmsg" : "not master and slaveOk=false",
"code" : 13435,
"codeName" : "NotMasterNoSlaveOk",
"$clusterTime" : {
"clusterTime" : Timestamp(1551166663, 1),
"signature" : {
"hash" : BinData(0,"AAAAAAAAAAAAAAAAAAAAAAAAAAA="),
"keyId" : NumberLong(0)
}
}
} :
_getErrorWithCode@src/mongo/shell/utils.js:25:13
DB.prototype._getCollectionInfosCommand@src/mongo/shell/db.js:941:1
DB.prototype.getCollectionInfos@src/mongo/shell/db.js:953:19
DB.prototype.getCollectionNames@src/mongo/shell/db.js:964:16
shellHelper.show@src/mongo/shell/utils.js:853:9
shellHelper@src/mongo/shell/utils.js:750:15
@(shellhelp2):1:1 上面出现了报错!
这是因为mongodb默认是从主节点读写数据的,副本节点上不允许读,需要设置副本节点可以读
repset:SECONDARY> db.getMongo().setSlaveOk();
repset:SECONDARY> db.testdb.find();
{ "_id" : ObjectId("5c74ec9267d8c3d06506449b"), "test1" : "testval1" }
repset:SECONDARY> show tables;
testdb 如上发现已经在副本节点上发现了测试数据,即已经从主节点复制过来了。
(在另一个副本节点172.16.60.207也如上操作即可)

四、测试副本集故障转移功能
先停掉主节点172.16.60.205,查看mongodb副本集状态,可以看到经过一系列的投票选择操作,172.16.60.206当选主节点,172.16.60.207从172.16.60.206同步数据过来。

1)停掉原来的主节点172.16.60.205的mongodb,模拟故障
[root@mongodb-master01 ~]# ps -ef|grep mongodb|grep -v grep|awk '{print $2}'|xargs kill -9
[root@mongodb-master01 ~]# lsof -i:27017
[root@mongodb-master01 ~]# 2)接着登录到另外两个正常的从节点172.16.60.206、172.16.60.207中的任意一个节点的mongodb,查看副本集状态
[root@mongodb-slave01 ~]# /usr/local/mongodb/bin/mongo 172.16.60.206:27017
.................
repset:PRIMARY> rs.status();
{
"set" : "repset",
"date" : ISODate("2019-02-26T08:06:02.996Z"),
"myState" : 1,
"term" : NumberLong(2),
"syncingTo" : "",
"syncSourceHost" : "",
"syncSourceId" : -1,
"heartbeatIntervalMillis" : NumberLong(2000),
"optimes" : {
"lastCommittedOpTime" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
},
"readConcernMajorityOpTime" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
},
"appliedOpTime" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
},
"durableOpTime" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
}
},
"members" : [
{
"_id" : 0,
"name" : "172.16.60.205:27017",
"health" : 0,
"state" : 8,
"stateStr" : "(not reachable/healthy)",
"uptime" : 0,
"optime" : {
"ts" : Timestamp(0, 0),
"t" : NumberLong(-1)
},
"optimeDurable" : {
"ts" : Timestamp(0, 0),
"t" : NumberLong(-1)
},
"optimeDate" : ISODate("1970-01-01T00:00:00Z"),
"optimeDurableDate" : ISODate("1970-01-01T00:00:00Z"),
"lastHeartbeat" : ISODate("2019-02-26T08:06:02.917Z"),
"lastHeartbeatRecv" : ISODate("2019-02-26T08:03:37.492Z"),
"pingMs" : NumberLong(0),
"lastHeartbeatMessage" : "Connection refused",
"syncingTo" : "",
"syncSourceHost" : "",
"syncSourceId" : -1,
"infoMessage" : "",
"configVersion" : -1
},
{
"_id" : 1,
"name" : "172.16.60.206:27017",
"health" : 1,
"state" : 1,
"stateStr" : "PRIMARY",
"uptime" : 2246,
"optime" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
},
"optimeDate" : ISODate("2019-02-26T08:05:59Z"),
"syncingTo" : "",
"syncSourceHost" : "",
"syncSourceId" : -1,
"infoMessage" : "",
"electionTime" : Timestamp(1551168228, 1),
"electionDate" : ISODate("2019-02-26T08:03:48Z"),
"configVersion" : 1,
"self" : true,
"lastHeartbeatMessage" : ""
},
{
"_id" : 2,
"name" : "172.16.60.207:27017",
"health" : 1,
"state" : 2,
"stateStr" : "SECONDARY",
"uptime" : 2169,
"optime" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
},
"optimeDurable" : {
"ts" : Timestamp(1551168359, 1),
"t" : NumberLong(2)
},
"optimeDate" : ISODate("2019-02-26T08:05:59Z"),
"optimeDurableDate" : ISODate("2019-02-26T08:05:59Z"),
"lastHeartbeat" : ISODate("2019-02-26T08:06:02.861Z"),
"lastHeartbeatRecv" : ISODate("2019-02-26T08:06:02.991Z"),
"pingMs" : NumberLong(0),
"lastHeartbeatMessage" : "",
"syncingTo" : "172.16.60.206:27017",
"syncSourceHost" : "172.16.60.206:27017",
"syncSourceId" : 1,
"infoMessage" : "",
"configVersion" : 1
}
],
"ok" : 1,
"operationTime" : Timestamp(1551168359, 1),
"$clusterTime" : {
"clusterTime" : Timestamp(1551168359, 1),
"signature" : {
"hash" : BinData(0,"AAAAAAAAAAAAAAAAAAAAAAAAAAA="),
"keyId" : NumberLong(0)
}
}
} 发现当原来的主节点172.16.60.205宕掉后,经过选举,原来的从节点172.16.60.206被推举为新的主节点。 3)现在在172.16.60.206新主节点上创建测试数据
repset:PRIMARY> use kevin;
switched to db kevin
repset:PRIMARY> db.kevin.insert({"shibo":"hahaha"})
WriteResult({ "nInserted" : 1 }) 4)另一个从节点172.16.60.207上登录mongodb查看
[root@mongodb-slave02 ~]# /usr/local/mongodb/bin/mongo 172.16.60.207:27017
................
repset:SECONDARY> use kevin;
switched to db kevin
repset:SECONDARY> db.getMongo().setSlaveOk();
repset:SECONDARY> show tables;
kevin
repset:SECONDARY> db.kevin.find();
{ "_id" : ObjectId("5c74f42bb0b339ed6eb68e9c"), "shibo" : "hahaha" } 发现从节点172.16.60.207可以同步新的主节点172.16.60.206的数据 5)再重新启动原来的主节点172.16.60.205的mongodb
[root@mongodb-master01 ~]# nohup /usr/local/mongodb/bin/mongod -dbpath /data/mongodb/data/replset -replSet repset --bind_ip=172.16.60.205 --port=27017 & mongod 9162 root 49u IPv4 6561201 0t0 TCP mongodb-master01:55236->mongodb-slave01:27017 (ESTABLISHED)
[root@mongodb-master01 ~]# ps -ef|grep mongodb
root 9162 6977 4 16:14 pts/1 00:00:01 /usr/local/mongodb/bin/mongod -dbpath /data/mongodb/data/replset -replSet repset --bind_ip=172.16.60.205 --port=27017
root 9244 6977 0 16:14 pts/1 00:00:00 grep mongodb 再次登录到三个节点中的任意一个的mongodb,查看副本集状态
[root@mongodb-master01 ~]# /usr/local/mongodb/bin/mongo 172.16.60.205:27017
....................
repset:SECONDARY> rs.status();
{
"set" : "repset",
"date" : ISODate("2019-02-26T08:16:11.741Z"),
"myState" : 2,
"term" : NumberLong(2),
"syncingTo" : "172.16.60.206:27017",
"syncSourceHost" : "172.16.60.206:27017",
"syncSourceId" : 1,
"heartbeatIntervalMillis" : NumberLong(2000),
"optimes" : {
"lastCommittedOpTime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"readConcernMajorityOpTime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"appliedOpTime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"durableOpTime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
}
},
"members" : [
{
"_id" : 0,
"name" : "172.16.60.205:27017",
"health" : 1,
"state" : 2,
"stateStr" : "SECONDARY",
"uptime" : 129,
"optime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"optimeDate" : ISODate("2019-02-26T08:16:09Z"),
"syncingTo" : "172.16.60.206:27017",
"syncSourceHost" : "172.16.60.206:27017",
"syncSourceId" : 1,
"infoMessage" : "",
"configVersion" : 1,
"self" : true,
"lastHeartbeatMessage" : ""
},
{
"_id" : 1,
"name" : "172.16.60.206:27017",
"health" : 1,
"state" : 1,
"stateStr" : "PRIMARY",
"uptime" : 127,
"optime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"optimeDurable" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"optimeDate" : ISODate("2019-02-26T08:16:09Z"),
"optimeDurableDate" : ISODate("2019-02-26T08:16:09Z"),
"lastHeartbeat" : ISODate("2019-02-26T08:16:10.990Z"),
"lastHeartbeatRecv" : ISODate("2019-02-26T08:16:11.518Z"),
"pingMs" : NumberLong(0),
"lastHeartbeatMessage" : "",
"syncingTo" : "",
"syncSourceHost" : "",
"syncSourceId" : -1,
"infoMessage" : "",
"electionTime" : Timestamp(1551168228, 1),
"electionDate" : ISODate("2019-02-26T08:03:48Z"),
"configVersion" : 1
},
{
"_id" : 2,
"name" : "172.16.60.207:27017",
"health" : 1,
"state" : 2,
"stateStr" : "SECONDARY",
"uptime" : 127,
"optime" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"optimeDurable" : {
"ts" : Timestamp(1551168969, 1),
"t" : NumberLong(2)
},
"optimeDate" : ISODate("2019-02-26T08:16:09Z"),
"optimeDurableDate" : ISODate("2019-02-26T08:16:09Z"),
"lastHeartbeat" : ISODate("2019-02-26T08:16:10.990Z"),
"lastHeartbeatRecv" : ISODate("2019-02-26T08:16:11.655Z"),
"pingMs" : NumberLong(0),
"lastHeartbeatMessage" : "",
"syncingTo" : "172.16.60.206:27017",
"syncSourceHost" : "172.16.60.206:27017",
"syncSourceId" : 1,
"infoMessage" : "",
"configVersion" : 1
}
],
"ok" : 1,
"operationTime" : Timestamp(1551168969, 1),
"$clusterTime" : {
"clusterTime" : Timestamp(1551168969, 1),
"signature" : {
"hash" : BinData(0,"AAAAAAAAAAAAAAAAAAAAAAAAAAA="),
"keyId" : NumberLong(0)
}
}
} 发现原来的主节点172.16.60.205在故障恢复后,变成了新的主节点172.16.60.206的从节点

五、Mongodb读写分离
目前来看。Mongodb副本集可以完美支持故障转移。至于主节点的读写压力过大如何解决?常见的解决方案是读写分离。

一般情况下,常规写操作来说并没有读操作多,所以在Mongodb副本集中,一台主节点负责写操作,两台副本节点负责读操作。
1)设置读写分离需要先在副本节点SECONDARY 设置 setSlaveOk。
2)在程序中设置副本节点负责读操作,如下代码:
public class TestMongoDBReplSetReadSplit {
public static void main(String[] args) {
try {
List<ServerAddress> addresses = new ArrayList<ServerAddress>();
ServerAddress address1 = new ServerAddress("172.16.60.205" , 27017);
ServerAddress address2 = new ServerAddress("172.16.60.206" , 27017);
ServerAddress address3 = new ServerAddress("172.16.60.207" , 27017);
addresses.add(address1);
addresses.add(address2);
addresses.add(address3);
MongoClient client = new MongoClient(addresses);
DB db = client.getDB( "test" );
DBCollection coll = db.getCollection( "testdb" );
BasicDBObject object = new BasicDBObject();
object.append( "test2" , "testval2" ); //读操作从副本节点读取
ReadPreference preference = ReadPreference. secondary();
DBObject dbObject = coll.findOne(object, null , preference);
System. out .println(dbObject);
} catch (Exception e) {
e.printStackTrace();
}
}
}

读参数除了secondary一共还有五个参数:primary、primaryPreferred、secondary、secondaryPreferred、nearest。
primary:默认参数,只从主节点上进行读取操作;
primaryPreferred:大部分从主节点上读取数据,只有主节点不可用时从secondary节点读取数据。
secondary:只从secondary节点上进行读取操作,存在的问题是secondary节点的数据会比primary节点数据“旧”。
secondaryPreferred:优先从secondary节点进行读取操作,secondary节点不可用时从主节点读取数据;
nearest:不管是主节点、secondary节点,从网络延迟最低的节点上读取数据。

读写分离做好后,就可以进行数据分流,减轻压力,解决了"主节点的读写压力过大如何解决?"这个问题。不过当副本节点增多时,主节点的复制压力会加大有什么办法解决吗?基于这个问题,Mongodb已有了相应的解决方案 - 引用仲裁节点:
在Mongodb副本集中,仲裁节点不存储数据,只是负责故障转移的群体投票,这样就少了数据复制的压力。看起来想的很周到啊,其实不只是主节点、副本节点、仲裁节点,还有Secondary-Only、Hidden、Delayed、Non-Voting,其中:
Secondary-Only:不能成为primary节点,只能作为secondary副本节点,防止一些性能不高的节点成为主节点。
Hidden:这类节点是不能够被客户端制定IP引用,也不能被设置为主节点,但是可以投票,一般用于备份数据。
Delayed:可以指定一个时间延迟从primary节点同步数据。主要用于备份数据,如果实时同步,误删除数据马上同步到从节点,恢复又恢复不了。
Non-Voting:没有选举权的secondary节点,纯粹的备份数据节点。

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