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TiDB Binlog Cluster Deployment

This document describes two methods of deploying TiDB Binlog:

It is recommended to deploy TiDB Binlog using TiDB Ansible. If you just want to do a simple testing, you can deploy TiDB Binlog using a Binary package.

Hardware requirements

Pump and Drainer are deployed and operate on 64-bit universal hardware server platforms with Intel x86-64 architecture.

In environments of development, testing and production, the requirements on server hardware are as follows:

ServiceThe Number of ServersCPUDiskMemory
Pump38 core+SSD, 200 GB+16G
Drainer18 core+SAS, 100 GB+ (If binlogs are output as local files, the disk size depends on how long these files are retained.)16G

Deploy TiDB Binlog using TiDB Ansible

Step 1: Download TiDB Ansible

  1. Use the TiDB user account to log in to the central control machine and go to the /home/tidb directory. The information about the branch of TiDB Ansible and the corresponding TiDB version is as follows. If you have questions regarding which version to use, email to info@pingcap.com for more information or file an issue.

    tidb-ansible branchTiDB versionNote
    release-2.12.1 versionThe latest 2.1 stable version. You can use it in the production environment.
  2. Use the following command to download the corresponding branch of TiDB Ansible from the TiDB Ansible project on GitHub. The default folder name is tidb-ansible.

    • Download the 2.1 version:

      git clone -b release-2.1 https://github.com/pingcap/tidb-ansible.git

Step 2: Deploy Pump

  1. Modify the tidb-ansible/inventory.ini file.

    1. Set enable_binlog = True to start binlog of the TiDB cluster.

      ## binlog trigger enable_binlog = True
    2. Add the deployment machine IPs for pump_servers.

      ## Binlog Part [pump_servers] 172.16.10.72 172.16.10.73 172.16.10.74

      Pump retains the data of the latest 7 days by default. You can modify the value of the gc variable in the tidb-ansible/conf/pump.yml file and remove the related comments:

      global: # an integer value to control the expiry date of the binlog data, which indicates for how long (in days) the binlog data would be stored # must be bigger than 0 # gc: 7

      Make sure the space of the deployment directory is sufficient for storing Binlog. For more details, see Configure the deployment directory. You can also set a separate deployment directory for Pump.

      ## Binlog Part [pump_servers] pump1 ansible_host=172.16.10.72 deploy_dir=/data1/pump pump2 ansible_host=172.16.10.73 deploy_dir=/data2/pump pump3 ansible_host=172.16.10.74 deploy_dir=/data3/pump
  2. Deploy and start the TiDB cluster containing Pump.

    After configuring the inventory.ini file, you can choose one method from below to deploy the TiDB cluster.

    Method #1: Add Pump on the existing TiDB cluster.

    1. Deploy pump_servers and node_exporters.

      ansible-playbook deploy.yml --tags=pump -l ${pump1_ip},${pump2_ip},[${alias1_name},${alias2_name}]
    2. Start pump_servers.

      ansible-playbook start.yml --tags=pump
    3. Update and restart tidb_servers.

      ansible-playbook rolling_update.yml --tags=tidb
    4. Update the monitoring data.

      ansible-playbook rolling_update_monitor.yml --tags=prometheus

    Method #2: Deploy a TiDB cluster containing Pump from scratch.

    For how to use TiDB Ansible to deploy the TiDB cluster, see Deploy TiDB Using TiDB Ansible.

  3. Check the Pump status.

    Use binlogctl to check the Pump status. Change the pd-urls parameter to the PD address of the cluster. If State is online, Pump is started successfully.

    cd /home/tidb/tidb-ansible && resources/bin/binlogctl -pd-urls=http://172.16.10.72:2379 -cmd pumps
    INFO[0000] pump: {NodeID: ip-172-16-10-72:8250, Addr: 172.16.10.72:8250, State: online, MaxCommitTS: 403051525690884099, UpdateTime: 2018-12-25 14:23:37 +0800 CST} INFO[0000] pump: {NodeID: ip-172-16-10-73:8250, Addr: 172.16.10.73:8250, State: online, MaxCommitTS: 403051525703991299, UpdateTime: 2018-12-25 14:23:36 +0800 CST} INFO[0000] pump: {NodeID: ip-172-16-10-74:8250, Addr: 172.16.10.74:8250, State: online, MaxCommitTS: 403051525717360643, UpdateTime: 2018-12-25 14:23:35 +0800 CST}

Step 3: Deploy Drainer

  1. Obtain the value of initial_commit_ts.

    When Drainer starts for the first time, the timestamp information initial_commit_ts is required.

    • For replication started from the latest time point, you can use binlogctl to get the the most recent timestamp information initial_commit_ts. Refer to the following method to obtain the latest timestamp.

      cd /home/tidb/tidb-ansible && resources/bin/binlogctl -pd-urls=http://127.0.0.1:2379 -cmd generate_meta
      INFO[0000] [pd] create pd client with endpoints [http://192.168.199.118:32379] INFO[0000] [pd] leader switches to: http://192.168.199.118:32379, previous: INFO[0000] [pd] init cluster id 6569368151110378289 2018/06/21 11:24:47 meta.go:117: [info] meta: &{CommitTS:400962745252184065}

      This command outputs meta: &{CommitTS:400962745252184065}, and the value of CommitTS is the needed value of the initial-commit-ts.

    • If the downstream database is MySQL or TiDB, to ensure data integrity, you need to perform full data backup and recovery. In this case, the value of initial_commit_ts must be the timestamp information of the full backup.

      If you use mydumper to perform full data backup, you can get the timestamp by referring to the Pos field in the metadata file from the export directory. An example of the metadata file is as follows:

      Started dump at: 2019-12-30 13:25:41 SHOW MASTER STATUS: Log: tidb-binlog Pos: 413580274257362947 GTID: Finished dump at: 2019-12-30 13:25:41
  2. Modify the tidb-ansible/inventory.ini file.

    Add the deployment machine IPs for drainer_servers. Set initial_commit_ts to the value you have obtained, which is only used for the initial start of Drainer.

    • Assume that the downstream is MySQL with the alias drainer_mysql:

      [drainer_servers] drainer_mysql ansible_host=172.16.10.71 initial_commit_ts="402899541671542785"
    • Assume that the downstream is file with the alias drainer_file:

      [drainer_servers] drainer_file ansible_host=172.16.10.71 initial_commit_ts="402899541671542785"
  3. Modify the configuration file.

    • Assume that the downstream is MySQL:

      cd /home/tidb/tidb-ansible/conf && cp drainer-cluster.toml drainer_mysql_drainer.toml && vi drainer_mysql_drainer.toml

      Set db-type to mysql and configure the downstream MySQL information:

      # downstream storage, equal to --dest-db-type # Valid values are "mysql", "tidb", "file", "kafka". db-type = "mysql" # the downstream MySQL protocol database [syncer.to] host = "172.16.10.72" user = "root" password = "123456" port = 3306 # Time and size limits for flash batch write
    • Assume that the downstream is incremental backup data:

      cd /home/tidb/tidb-ansible/conf && cp drainer-cluster.toml drainer_file_drainer.toml && vi drainer_file_drainer.toml

      Set db-type to file.

      # downstream storage, equal to --dest-db-type # Valid values are "mysql", "file", "tidb", and "kafka". db-type = "file" # Uncomment this if you want to use "file" as "db-type". [syncer.to] # default data directory: "{{ deploy_dir }}/data.drainer" dir = "data.drainer"
  4. Deploy Drainer.

    ansible-playbook deploy_drainer.yml
  5. Start Drainer.

    ansible-playbook start_drainer.yml

Deploy TiDB Binlog using a Binary package

Download the official Binary package

Run the following commands to download the packages:

version="latest" for nightly builds && wget https://download.pingcap.org/tidb-latest-linux-amd64.{tar.gz,sha256}

Check the file integrity. If the result is OK, the file is correct.

sha256sum -c tidb-latest-linux-amd64.sha256

For TiDB v2.1.0 GA or later versions, Pump and Drainer are already included in the TiDB download package. For other TiDB versions, you need to download Pump and Drainer separately using the following command:

wget https://download.pingcap.org/tidb-binlog-$version-linux-amd64.{tar.gz,sha256}

Check the file integrity. If the result is OK, the file is correct.

sha256sum -c tidb-binlog-$version-linux-amd64.sha256

The usage example

Assuming that you have three PD nodes, one TiDB node, two Pump nodes, and one Drainer node, the information of each node is as follows:

NodeIP
TiDB192.168.0.10
PD1192.168.0.16
PD2192.168.0.15
PD3192.168.0.14
Pump192.168.0.11
Pump192.168.0.12
Drainer192.168.0.13

The following part shows how to use Pump and Drainer based on the nodes above.

  1. Deploy Pump using the binary.

    • To view the command line parameters of Pump, execute ./bin/pump -help:

      Usage of Pump: -L string the output information level of logs: debug, info, warn, error, fatal ("info" by default) -V the print version information -addr string the RPC address through which Pump provides the service (-addr="192.168.0.11:8250") -advertise-addr string the RPC address through which Pump provides the external service (-advertise-addr="192.168.0.11:8250") -config string the path of the configuration file. If you specify the configuration file, Pump reads the configuration in the configuration file first. If the corresponding configuration also exits in the command line parameters, Pump uses the configuration of the command line parameters to cover that of the configuration file. -data-dir string the path where the Pump data is stored -gc int the number of days to retain the data in Pump ("7" by default) -heartbeat-interval int the interval of the heartbeats Pump sends to PD (in seconds) -log-file string the file path of logs -log-rotate string the switch frequency of logs (hour/day) -metrics-addr string the Prometheus Pushgateway address. If not set, it is forbidden to report the monitoring metrics. -metrics-interval int the report frequency of the monitoring metrics ("15" by default, in seconds) -node-id string the unique ID of a Pump node. If you do not specify this ID, the system automatically generates an ID based on the host name and listening port. -pd-urls string the address of the PD cluster nodes (-pd-urls="http://192.168.0.16:2379,http://192.168.0.15:2379,http://192.168.0.14:2379") -fake-binlog-interval int the frequency at which a Pump node generates fake binlog ("3" by default, in seconds)
    • Taking deploying Pump on "192.168.0.11" as an example, the Pump configuration file is as follows:

      # Pump Configuration # the bound address of Pump addr = "192.168.0.11:8250" # the address through which Pump provides the service advertise-addr = "192.168.0.11:8250" # the number of days to retain the data in Pump ("7" by default) gc = 7 # the directory where the Pump data is stored data-dir = "data.pump" # the interval of the heartbeats Pump sends to PD (in seconds) heartbeat-interval = 2 # the address of the PD cluster nodes (each separated by a comma with no whitespace) pd-urls = "http://192.168.0.16:2379,http://192.168.0.15:2379,http://192.168.0.14:2379" # [security] # This section is generally commented out if no special security settings are required. # The file path containing a list of trusted SSL CAs connected to the cluster. # ssl-ca = "/path/to/ca.pem" # The path to the X509 certificate in PEM format that is connected to the cluster. # ssl-cert = "/path/to/drainer.pem" # The path to the X509 key in PEM format that is connected to the cluster. # ssl-key = "/path/to/drainer-key.pem" # [storage] # Set to true (by default) to guarantee reliability by ensuring binlog data is flushed to the disk # sync-log = true # When the available disk capacity is less than the set value, Pump stops writing data. # 42 MB -> 42000000, 42 mib -> 44040192 # default: 10 gib # stop-write-at-available-space = "10 gib" # The LSM DB settings embedded in Pump. Unless you know this part well, it is usually commented out. # [storage.kv] # block-cache-capacity = 8388608 # block-restart-interval = 16 # block-size = 4096 # compaction-L0-trigger = 8 # compaction-table-size = 67108864 # compaction-total-size = 536870912 # compaction-total-size-multiplier = 8.0 # write-buffer = 67108864 # write-L0-pause-trigger = 24 # write-L0-slowdown-trigger = 17
    • The example of starting Pump:

      ./bin/pump -config pump.toml

      If the command line parameters is the same with the configuration file parameters, the values of command line parameters are used.

  2. Deploy Drainer using binary.

    • To view the command line parameters of Drainer, execute ./bin/drainer -help:

      Usage of Drainer: -L string the output information level of logs: debug, info, warn, error, fatal ("info" by default) -V the print version information -addr string the address through which Drainer provides the service (-addr="192.168.0.13:8249") -c int the number of the concurrency of the downstream for replication. The bigger the value, the better throughput performance of the concurrency ("1" by default). -cache-binlog-count int the limit on the number of binlog items in the cache ("8" by default) If a large single binlog item in the upstream causes OOM in Drainer, try to lower the value of this parameter to reduce memory usage. -config string the directory of the configuration file. Drainer reads the configuration file first. If the corresponding configuration exists in the command line parameters, Drainer uses the configuration of the command line parameters to cover that of the configuration file. -data-dir string the directory where the Drainer data is stored ("data.drainer" by default) -dest-db-type string the downstream service type of Drainer The value can be "mysql", "tidb", "kafka", and "file". ("mysql" by default) -detect-interval int the interval of checking the online Pump in PD ("10" by default, in seconds) -disable-dispatch whether to disable the SQL feature of splitting a single binlog file. If it is set to "true", each binlog file is restored to a single transaction for replication based on the order of binlogs. It is set to "False", when the downstream is MySQL. -ignore-schemas string the db filter list ("INFORMATION_SCHEMA,PERFORMANCE_SCHEMA,mysql,test" by default) It does not support the Rename DDL operation on tables of `ignore schemas`. -initial-commit-ts If Drainer does not have the related breakpoint information, you can configure the related breakpoint information using this parameter. ("0" by default) -log-file string the path of the log file -log-rotate string the switch frequency of log files, hour/day -metrics-addr string the Prometheus Pushgateway address It it is not set, the monitoring metrics are not reported. -metrics-interval int the report frequency of the monitoring metrics ("15" by default, in seconds) -node-id string the unique ID of a Drainer node. If you do not specify this ID, the system automatically generates an ID based on the host name and listening port. -pd-urls string the address of the PD cluster nodes (-pd-urls="http://192.168.0.16:2379,http://192.168.0.15:2379,http://192.168.0.14:2379") -safe-mode Whether to enable safe mode so that data can be written into the downstream MySQL/TiDB repeatedly. This mode replaces the `INSERT` statement with the `REPLACE` statement and splits the `UPDATE` statement into `DELETE` plus `REPLACE`. -txn-batch int the number of SQL statements of a transaction which are output to the downstream database ("1" by default)
    • Taking deploying Drainer on "192.168.0.13" as an example, the Drainer configuration file is as follows:

      # Drainer Configuration. # the address through which Drainer provides the service ("192.168.0.13:8249") addr = "192.168.0.13:8249" # the address through which Drainer provides the external service advertise-addr = "192.168.0.13:8249" # the interval of checking the online Pump in PD ("10" by default, in seconds) detect-interval = 10 # the directory where the Drainer data is stored "data.drainer" by default) data-dir = "data.drainer" # the address of the PD cluster nodes (each separated by a comma with no whitespace) pd-urls = "http://192.168.0.16:2379,http://192.168.0.15:2379,http://192.168.0.14:2379" # the directory of the log file log-file = "drainer.log" # Drainer compresses the data when it gets the binlog from Pump. The value can be "gzip". If it is not configured, it will not be compressed # compressor = "gzip" # [security] # This section is generally commented out if no special security settings are required. # The file path containing a list of trusted SSL CAs connected to the cluster. # ssl-ca = "/path/to/ca.pem" # The path to the X509 certificate in PEM format that is connected to the cluster. # ssl-cert = "/path/to/pump.pem" # The path to the X509 key in PEM format that is connected to the cluster. # ssl-key = "/path/to/pump-key.pem" # Syncer Configuration [syncer] # If the item is set, the sql-mode will be used to parse the DDL statement. # If the downstream database is MySQL or TiDB, then the downstream sql-mode # is also set to this value. # sql-mode = "STRICT_TRANS_TABLES,NO_ENGINE_SUBSTITUTION" # the number of SQL statements of a transaction that are output to the downstream database ("20" by default) txn-batch = 20 # the number of the concurrency of the downstream for replication. The bigger the value, # the better throughput performance of the concurrency ("16" by default) worker-count = 16 # whether to disable the SQL feature of splitting a single binlog file. If it is set to "true", # each binlog file is restored to a single transaction for replication based on the order of binlogs. # If the downstream service is MySQL, set it to "False". disable-dispatch = false # In safe mode, data can be written into the downstream MySQL/TiDB repeatedly. # This mode replaces the `INSERT` statement with the `REPLACE` statement and replaces the `UPDATE` statement with `DELETE` plus `REPLACE` statements. safe-mode = false # the downstream service type of Drainer ("mysql" by default) # Valid value: "mysql", "file", "tidb", and "kafka". db-type = "mysql" # If `commit ts` of the transaction is in the list, the transaction is filtered and not replicated to the downstream. ignore-txn-commit-ts = [] # the db filter list ("INFORMATION_SCHEMA,PERFORMANCE_SCHEMA,mysql,test" by default) # Does not support the Rename DDL operation on tables of `ignore schemas`. ignore-schemas = "INFORMATION_SCHEMA,PERFORMANCE_SCHEMA,mysql" # `replicate-do-db` has priority over `replicate-do-table`. When they have the same `db` name, # regular expressions are supported for configuration. # The regular expression should start with "~". # replicate-do-db = ["~^b.*","s1"] # [[syncer.replicate-do-table]] # db-name ="test" # tbl-name = "log" # [[syncer.replicate-do-table]] # db-name ="test" # tbl-name = "~^a.*" # Ignore the replication of some tables # [[syncer.ignore-table]] # db-name = "test" # tbl-name = "log" # the server parameters of the downstream database when `db-type` is set to "mysql" [syncer.to] host = "192.168.0.13" user = "root" password = "" port = 3306 [syncer.to.checkpoint] # When the downstream is MySQL or TiDB, this option can be enabled to change the database that holds the checkpoint. # schema = "tidb_binlog" # the directory where the binlog file is stored when `db-type` is set to `file` # [syncer.to] # dir = "data.drainer" # the Kafka configuration when `db-type` is set to "kafka" # [syncer.to] # only one of kafka-addrs and zookeeper-addrs is needed. If both are present, the program gives priority to the kafka address in zookeeper. # zookeeper-addrs = "127.0.0.1:2181" # kafka-addrs = "127.0.0.1:9092" # kafka-version = "0.8.2.0" # kafka-max-messages = 1024 # the topic name of the Kafka cluster that saves the binlog data. The default value is <cluster-id>_obinlog # To run multiple Drainers to replicate data to the same Kafka cluster, you need to set different `topic-name`s for each Drainer. # topic-name = ""
    • Starting Drainer:

      When Drainer is started for the first time, use the initial-commit-ts parameter.

      ./bin/drainer -config drainer.toml -initial-commit-ts {initial-commit-ts}

      If the command line parameter and the configuration file parameter are the same, the parameter value in the command line is used.

  3. Starting TiDB server:

    • After starting Pump and Drainer, start TiDB server with binlog enabled by adding this section to your config file for TiDB server:

      [binlog] enable=true
    • TiDB server will obtain the addresses of registered Pumps from PD and will stream data to all of them. If there are no registered Pump instances, TiDB server will refuse to start or will block starting until a Pump instance comes online.

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