Configuring HA - an example

This supplements the High Availability documentation and provides an example of how to configure a pair of Apache Brooklyn servers to run in master-standby mode with a shared NFS datastore

Prerequisites

• Two VMs (or physical machines) have been provisioned
• NFS or another suitable file system has been configured and is available to both VMs*
• An NFS folder has been mounted on both VMs at /mnt/brooklyn-persistence and both machines can write to the folder

* Brooklyn can be configured to use either an object store such as S3, or a shared NFS mount. The recommended option is to use an object store as described in the Object Store Persistence documentation. For simplicity, a shared NFS folder is assumed in this example

Launching

To start, download and install the latest Apache Brooklyn release on both VMs following the instructions in Running Apache Brooklyn

On the first VM, which will be the master node, set the following configuration options in org.apache.brooklyn.osgilauncher.cfg:

• highAvailabilityMode: MASTER
• persistMode: AUTO
• persistenceDir: /mnt/brooklyn-persistence

Then launch Brooklyn with:

$ bin/start

If you are using RPMs/deb to install, please see the Running Apache Brooklyn documentation for the appropriate launch commands

Once Brooklyn has launched, on the second VM, set the following configuration options in org.apache.brooklyn.osgilauncher.cfg:

• highAvailabilityMode: AUTO
• persistMode: AUTO
• persistenceDir: /mnt/brooklyn-persistence

Then launch the standby Brooklyn with:

$ bin/start

Failover

When running as a HA standby node, each standby Brooklyn server (in this case there is only one standby) will check the shared persisted state every one second to determine the state of the HA master. If no heartbeat has been recorded for 30 seconds, then an election will be performed and one of the standby nodes will be promoted to master. At this point all requests should be directed to the new master node. If the master is terminated gracefully, the secondary will be immediately promoted to mater. Otherwise, the secondary will be promoted after heartbeats are missed for a given length of time. This defaults to 30 seconds, and is configured in brooklyn.cfg using brooklyn.ha.heartbeatTimeout

In the event that tasks - such as the provisioning of a new entity - are running when a failover occurs, the new master will display the current state of the entity, but will not resume its provisioning or re-run any partially completed tasks. In this case it may be necessary to remove the entity and reprovision it. In the case of a failover whilst executing a task called by an effector, it may be possible to simple call the effector again

Client Configuration

It is the responsibility of the client to connect to the master Brooklyn server. This can be accomplished in a variety of ways:

• Reverse Proxy

  To allow the client application to automatically fail over in the event of a master server becoming unavailable, or the promotion of a new master, a reverse proxy can be configured to route traffic depending on the response returned by https://<ip-address>:8443/v1/server/ha/state (see above). If a server returns "MASTER", then traffic should be routed to that server, otherwise it should not be. The client software should be configured to connect to the reverse proxy server and no action is required by the client in the event of a failover. It can take up to 30 seconds for the standby to be promoted, so the reverse proxy should retry for at least this period, or the failover time should be reconfigured to be shorter

• Re-allocating an Elastic IP on Failover

  If the cloud provider you are using supports Elastic or Floating IPs, then the IP address should be allocated to the HA master, and the client application configured to connect to the floating IP address. In the event of a failure of the master node, the standby node will automatically be promoted to master, and the floating IP will need to be manually re-allocated to the new master node. No action is required by the client in the event of a failover. It is possible to automate the re-allocation of the floating IP if the Brooklyn servers are deployed and managed by Brooklyn using the entity org.apache.brooklyn.entity.brooklynnode.BrooklynCluster

• Client-based failover

  In this scenario, the responsibilty for determining the Brooklyn master server falls on the client application. When configuring the client application, a list of all servers in the cluster is passed in at application startup. On first connection, the client application connects to any of the members of the cluster to retrieve the HA states (see above). The JSON object returned is used to determine the addresses of all members of the cluster, and also to determine which node is the HA master

  In the event of a failure of the master node, the client application should then retrieve the HA states of the cluster from any of the other cluster members. This is the same process as when the application first connects to the cluster. The client should refresh its list of cluster memebers and determine which node is the HA master

  It is also recommended that the client application periodically checks the status of the cluster and updates its list of addresses. This will ensure that failover is still possible if the standby server(s) has been replaced. It also allows additional standby servers to be added at any time

Testing

You can confirm that Brooklyn is running in high availibility mode on the master by logging into the web console at https://<ip-address>:8443. Similarly you can log into the web console on the standby VM where you will see a warning that the server is not the high availability master.

To test a failover, you can simply terminate the process on the first VM and log into the web console on the second VM. Upon launch, Brooklyn will output its PID to the file pid.txt; you can force an immediate (non-graceful) termination of the process by running the following command from the same directory from which you launched Brooklyn:

$ kill -9 $(cat pid.txt)

It is also possiblity to check the high availability state of a running Brooklyn server using the following curl command:

$ curl -k -u myusername:mypassword https://<ip-address>:8443/v1/server/ha/state

This will return one of the following states:

"INITIALIZING"
"STANDBY"
"HOT_STANDBY"
"HOT_BACKUP"
"MASTER"
"FAILED"
"TERMINATED"

Note: The quotation characters will be included in the reply

To obtain information about all of the nodes in the cluster, run the following command against any of the nodes in the cluster:

$ curl -k -u myusername:mypassword https://<ip-address>:8443/v1/server/ha/states

This will return a JSON document describing the Brooklyn nodes in the cluster. An example of two HA Brooklyn nodes is as follows (whitespace formatting has been added for clarity):

{
  ownId: "XkJeXUXE",
  masterId: "yAVz0fzo",
  nodes: {
    yAVz0fzo: {
      nodeId: "yAVz0fzo",
      nodeUri: "https://<server1-ip-address>:8443/",
      status: "MASTER",
      localTimestamp: 1466414301065,
      remoteTimestamp: 1466414301000
    },
    XkJeXUXE: {
      nodeId: "XkJeXUXE",
      nodeUri: "https://<server2-ip-address>:8443/",
      status: "STANDBY",
      localTimestamp: 1466414301066,
      remoteTimestamp: 1466414301000
    }
  },
  links: { }
}

The examples above show how to use curl to manually check the status of Brooklyn via its REST API. The same REST API calls can also be used by automated third party monitoring tools such as Nagios