How to Set Up Hadoop Cluster with HDFS High Availability

Last updated on Nov 22,2022 94.7K Views

How to Set Up Hadoop Cluster with HDFS High Availability

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HDFS 2.x High Availability Cluster Architecture

In this blog, I am going to talk about HDFS 2.x High Availability Cluster Architecture and the procedure to set up an HDFS High Availability cluster. This is an important part of the Big Data course. The order in which the topics have been covered in this blog are as follows:

Introduction:

The concept of High Availability cluster was introduced in Hadoop 2.x to solve the single point of failure problem in Hadoop 1.x. As you know from my previous blog that the HDFS Architecture follows Master/Slave Topology where NameNode acts as a master daemon and is responsible for managing other slave nodes called DataNodes. This single Master Daemon or NameNode becomes a bottleneck. Although, the introduction of Secondary NameNode did prevent us from data loss and offloading some of the burden of the NameNode but, it did not solve the availability issue of the NameNode.

NameNode Availability:

If you consider the standard configuration of HDFS cluster, the NameNode becomes a single point of failure. It happens because the moment the NameNode becomes unavailable, the whole cluster becomes unavailable until someone restarts the NameNode or brings a new one.

The reasons for unavailability of NameNode can be:

In either of the above cases, we have a downtime where we are not able to use the HDFS cluster which becomes a challenge. 

HDFS HA Architecture:

Let us understand that how HDFS HA Architecture solved this critical problem of NameNode availability:

The HA architecture solved this problem of NameNode availability by allowing us to have two NameNodes in an active/passive configuration. So, we have two running NameNodes at the same time in a High Availability cluster:

If one NameNode goes down, the other NameNode can take over the responsibility and therefore, reduce the cluster down time. The standby NameNode serves the purpose of a backup NameNode (unlike the Secondary NameNode) which incorporate failover capabilities to the Hadoop cluster. Therefore, with the StandbyNode, we can have automatic failover whenever a NameNode crashes (unplanned event) or we can have a graceful (manually initiated) failover during the maintenance period. 

There are two issues in maintaining consistency in the HDFS High Availability cluster:

Implementation of HA Architecture:

Now, you know that in HDFS HA Architecture, we have two NameNodes running at the same time. So, we can implement the Active and Standby NameNode configuration in following two ways:

  1. Using Quorum Journal Nodes
  2. Shared Storage using NFS

Let us understand these two ways of implementation taking one at a time:

1. Using Quorum Journal Nodes:

Fencing of NameNode:

Now, as discussed earlier, it is very important to ensure that there is only one Active NameNode at a time. So, fencing is a process to ensure this very property in a cluster. 

2. Using Shared Storage:

Automatic Failover:

Failover is a procedure by which a system automatically transfers control to secondary system when it detects a fault or failure. There are two types of failover:

Graceful Failover: In this case, we manually initiate the failover for routine maintenance.

Automatic Failover: In this case, the failover is initiated automatically in case of NameNode failure (unplanned event).

Apache Zookeeper is a service that provides the automatic failover capability in HDFS High Availabilty cluster. It maintains small amounts of coordination data, informs clients of changes in that data, and monitors clients for failures. Zookeeper maintains a session with the NameNodes. In case of failure, the session will expire and the Zookeeper will inform other NameNodes to initiate the failover process. In case of NameNode failure, other passive NameNode can take a lock in Zookeeper stating that it wants to become the next Active NameNode.

The ZookeerFailoverController (ZKFC) is a Zookeeper client that also monitors and manages the NameNode status. Each of the NameNode runs a ZKFC also. ZKFC is responsible for monitoring the health of the NameNodes periodically.

Now that you have understood what is High Availability in a Hadoop cluster, it’s time to set it up. To set up High Availability in Hadoop cluster you have to use Zookeeper in all the nodes.

The daemons in Active NameNode are:

The daemons in Standby NameNode are:

The daemons in DataNode are:

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Setting Up and Configuring High Availability Cluster in Hadoop:

You have to first set up the Java and host names of each node.

Virtual machine IP address Host name
Active NameNode192.168.1.81nn1.cluster.com or nn1
Standby NameNode192.168.1.58nn2.cluster.com or nn2
DataNode192.168.1.82dn1.cluster.com or dn1

 

Download the Hadoop and Zookeeper binary tar file, extract the files to edit configuration files.

Command : wget https://archive.apache.org/dist/zookeeper/zookeeper-3.4.6/zookeeper-3.4.6.tar.gz

 

 

 

 

 

 

                               

 

Untar the zookeeper-3.4.6.tar.gz

Command:  tar –xvf zookeeper-3.4.6.tar.gz

 

 

 

Download the stable Hadoop binary tar to from Apache Hadoop site.

Command: wget https://archive.apache.org/dist/hadoop/core/hadoop-2.6.0/hadoop-2.6.0.tar.gz

 

 

 

 

Extract the Hadoop tar ball.

Command: tar –xvf hadoop-2.6.0.tar.gz

Untar hadoop binary.

Add the Hadoop, Zookeeper and paths to .bashrc file.

Open the .bashrc file.

Command: sudo gedit ~/.bashrc

Add the below paths:

export HADOOP_HOME=< Path to your Hadoop-2.6.0 directory>
export HADOOP_MAPRED_HOME=$HADOOP_HOME
export HADOOP_COMMON_HOME=$HADOOP_HOME
export HADOOP_HDFS_HOME=$HADOOP_HOME
export YARN_HOME=$HADOOP_HOME
export HADOOP_CONF_DIR=$HADOOP_HOME/etc/hadoop
export YARN_CONF_DIR=$HADOOP_HOME/etc/hadoop
export JAVA_HOME=<Path to your Java Directory>
export ZOOKEEPER_HOME =<Path to your Zookeeper Directory>
export PATH=$PATH: $JAVA_HOME/bin: $HADOOP_HOME/bin: $HADOOP_HOME/sbin:$ZOOKEEPER_HOME/bin
Edit .bashrc file.

Enable the SSH in all the node.

Generate the SSH key in all the nodes.

Command: ssh-keygen –t rsa (This Step in all the Nodes)

Set up SSH key in all the nodes.

Don’t give any path to the Enter file to save the key and don’t give any passphrase. Press enter button.

Generate the ssh key process in all the nodes.

Once ssh key is generated, you will get the public key and private key.

The .ssh key Directory should contain the Permission 700 and all the keys inside the .ssh directory should contain the permissions 600.

Change the SSH directory permission.

Change the directory to .ssh and change the permission of files to 600

Change public and private key permission.

You have to copy the Name nodes ssh public key to all the nodes.

In Active Namenode, copy the id_rsa.pub using cat command.

Command: cat ~/.ssh/id_rsa.pub >> ~/.ssh/authorized_keys

Copy Namenode ssh key to it’s authorized keys.

Copy the NameNode public key to all the nodes using ssh-copy-id command.

Command: ssh-copy-id –i .ssh/id_rsa.pub edureka@nn2.cluster.com

Copy namenode key to Standby NameNode.

Copy NameNode public key to data node.

Command: ssh-copy-id –i .ssh/id_rsa.pub edureka@dn1.cluster.com

Copy Namenode public key to data node.

Restart the sshd service in all the nodes.

Command: sudo service sshd restart (Do in all the nodes)

Restart SSH service.

Now you can login to the any node from Namenode without any authentication.

Open the core-site.xml file from the Active Name node and add the below properties.

Edit core-site.xml from Active namenode

Open hdfs-site.xml file in Active Namenode. Add the below Properties.

<property>
 <name>dfs.namenode.name.dir</name>
 <value>/home/edureka/HA/data/namenode</value>
 </property>
 <property>
 <name>dfs.replication</name>
 <value>1</value>
 </property>
 <property>
 <name>dfs.permissions</name>
 <value>false</value>
 </property>
 <property>
 <name>dfs.nameservices</name>
 <value>ha-cluster</value>
 </property>
 <property>
 <name>dfs.ha.namenodes.ha-cluster</name>
 <value>nn1,nn2</value>
 </property>
 <property>
 <name>dfs.namenode.rpc-address.ha-cluster.nn1</name>
 <value>nn1.cluster.com:9000</value>
 </property>
 <property>
 <name>dfs.namenode.rpc-address.ha-cluster.nn2</name>
 <value>nn2.cluster.com:9000</value>
 </property>
 <property>
 <name>dfs.namenode.http-address.ha-cluster.nn1</name>
 <value>nn1.cluster.com:50070</value>
 </property>
 <property>
 <name>dfs.namenode.http-address.ha-cluster.nn2</name>
 <value>nn2.cluster.com:50070</value>
 </property>
 <property>
 <name>dfs.namenode.shared.edits.dir</name>
 <value>qjournal://nn1.cluster.com:8485;nn2.cluster.com:8485;dn1.cluster.com:8485/ha-cluster</value>
 </property>
 <property>
 <name>dfs.client.failover.proxy.provider.ha-cluster</name>
 <value>org.apache.hadoop.hdfs.server.namenode.ha.ConfiguredFailoverProxyProvider</value>
 </property>
 <property>
 <name>dfs.ha.automatic-failover.enabled</name>
 <value>true</value>
 </property>
 <property>
 <name>ha.zookeeper.quorum</name>
 <value> nn1.cluster.com:2181,nn2.cluster.com:2181,dn1.cluster.com:2181 </value>
 </property>
 <property>
 <name>dfs.ha.fencing.methods</name>
 <value>sshfence</value>
 </property>
 <property>
 <name>dfs.ha.fencing.ssh.private-key-files</name>
 <value>/home/edureka/.ssh/id_rsa</value>
 </property>

Change the directory to zookeeper’s conf directory.

Command: cd zookeeper-3.4.6/conf

Zookeeper Conf directory.

In a conf directory you have zoo_sample.cfg file, create the zoo.cfg using zoo_sample.cfg file.

Command: cp zoo_sample.cfg zoo.cfg

Create zoo.cfg file.

Create the directory in any location and use this directory to store the zookeeper data.

Command: mkdir <path, where you want to store the zookeeper files>

Create a directory to store zookeeper data.

Open the zoo.cfg file.

Command: gedit zoo.cfg

Add the directory path that is created in above step to the dataDir property and add the below details regarding remaining node, in the zoo.cfg file.

Server.1=nn1.cluster.com:2888:3888

Server.2=nn2.cluster.com:2888:3888

Server.3=dn1.cluster.com:2888:3888

Edit zoo.cfg file.

Now copy the Java and Hadoop-2.6.0, zookeeper-3.4.6 directories, and .bashrc file to all the nodes (Standby name node, Data node) using scp command.

Command: scp –r <path of directory> edureka@<ip address>:<path where you need to copy>

Copy Hadoop, Zookeeper and .bashrc file to all nodes.

Similarly, copy the .bashrc file and zookeeper directory to all the nodes and change the environment variables in each according to the respective node.

In a data node, create any directory where you need to store the HDFS blocks.

In a data node, you have to add the dfs.datanode.data.dir properties.

In my case, I created datanode directory to store the blocks.

Create Datanode directory.

Change the permission to data node directory.

Change Datanode directory permission.

Open the HDFS-site.xml file, add this Datanode directory path in dfs.datanode.data.dir property.

Note: Keep all the properties that are copied from the Active namenode; add dfs.datanode.data.dir  one extract property in namenode.

<property>
<name> dfs.datanode.data.dir</name>
<value>/home/edureka/HA/data/datanode</value>
</property>

In Active namenode, change the directory where you want to store the zookeeper configuration file (dataDir property path).

Create the myid file inside the directory and add numeric 1 to the file and save the file.

Command: vi myid

Create myid file.

In a standby namenode change the directory where you want to store the zookeeper configuration file (dataDir property path).

Create the myid file inside the directory and add numeric 2 to the file and save the file.

In a data node, change the directory where you want to store the zookeeper configuration file (dataDir property path).

Create the myid file inside the directory and add numeric 3 to the file and save the file.

Start the Journalnode in all the three nodes.

Command: hadoop-daemon.sh start journalnode

Start the Journalnode.

When you enter jps command, you will see the JournalNode daemon in all the nodes.

Format the Active namenode.

Command: HDFS namenode -format

Format Active NameNode.

Start the Namenode daemon in Active namenode.

Command: hadoop-daemon.sh start namenode

Start Namenode.

Copy the HDFS Meta data from active name node to standby namenode.

Command: HDFS namenode -bootstrapStandby

Copy the HDFS Meta data from Active name node to Standby Namenode.

Once you run this command, you will get the information from which node and location the meta data is copying and whether it is copying successfully or not.

Information of Active namenode details.

Once Meta data is copied from Active namenode to standby namenode, you will get the message shown  below in the screenshot.

Information regarding HDFS in Standby Namenode.

Start the namenode daemon in Standby namenode machine.

Command: hadoop-daemon.sh start namenode

Now start the Zookeeper service in all the three nodes.

Command: zkServer.sh start (Run this command in all the nodes)

In Active Namenode:

Start zookeeper in Active NameNode.

In Standby Namenode:

Start zookeeper in standby NameNode.

In Data node:

Start zookeeper in DataNode.

After running the Zookeeper server, enter JPS command. In all the nodes you will see the QuorumPeerMain service.

Start the Data node daemon in Data node machine.

Command: hadoop-daemon.sh start datanode

Start the Zookeeper fail over controller in Active name node and standby name node.

Format the zookeeper fail over controller in Active namenode.

Command: HDFS zkfc –formatZK

Format ZKFC.

Start the ZKFC in Active namenode.

Command: hadoop-daemon.sh start zkfc

Enter jps command to check the DFSZkFailoverController daemons.

Start ZKFC.

Format the zookeeper fail over controller in Standby namenode.

Command: hdfs zkfc –formatZK

Start the ZKFC in Standby namenode.

Command: hadoop-daemon.sh start zkfc

Enter jps command to check the DFSZkFailoverController daemons.

Now check the status of each Namenode, which node is Active or which node is on Standby by using the below command.

Command: hdfs haadmin –getServiceState nn1

Check status of each NameNode.

Now Check the status of each Namenode using the web browser.

Open the Web browser and enter the below URL.

<IP Address of Active Namenode>:50070

It will show whether the name node is Active or on standby.

Active NameNode.

Open another name node details using the web browser.

Standby NameNode.

In the Active namenode, kill the namenode daemon to change the Standby name node to active namenode.

Enter jps in Active namenode and kill the daemon.

Command: sudo kill -9 <namenode process ID>

Daemons Process ID.

The Namenode process ID is 7606, kill the namenode.

Command : Sudo kill -9 7606

Kill the Name Node process

Open the two nodes through web browser and check the status.

Namenode details.

NameNode status.

Congratulations, you have successfully setup a HDFS High Availability Cluster in Hadoop.

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