Table of Contents
The easiest way to add replication to your transactional application is to use the Replication Manager. The Replication Manager provides a comprehensive communications layer that enables replication. For a brief listing of the Replication Manager's feature set, see Replication Manager Overview.
To use the Replication Manager, you make use of special methods off the
Environment and
EnvironmentConfig classes, as well as
the ReplicationManagerSiteConfig class.
You also use a series of related classes to perform your
implementation. For example, in order to detect whether your
code is running as a master or a replica, you must implement
com.sleepycat.db.EventHandler.
(see Determining State).
That is:
Create an environment handle as normal.
Configure your environment handle as needed (e.g. set the error file and error prefix values, if desired).
Use the Replication Manager replication classes and methods to configure the Replication Manager. Using these classes and methods causes DB to know that you are using the Replication Manager.
Configuring the Replication Manager entails setting the replication environment's priority, setting the TCP/IP address that this replication environment will use for incoming replication messages, identifying TCP/IP addresses of other replication environments, setting the number of replication environments in the replication group, and so forth. These actions are discussed throughout the remainder of this chapter.
Open your environment handle. When you do this, be sure to
specify
EnvironmentConfig.setInitializeReplication()
when you configure your environment handle. This is in
addition to the configuration that you would normally
use for a transactional application. This causes
replication to be initialized for the application.
Start replication by calling
Environment.replicationManagerStart().
Open your databases as needed. Masters must open their databases for read and write activity. Replicas can open their databases for read-only activity, but doing so means they must re-open the databases if the replica ever becomes a master. Either way, replicas should never attempt to write to the database(s) directly.
The Replication Manager allows you to only use one environment handle per process.
When you are ready to shut down your application:
Close your databases
Close your environment. This causes replication to stop as well.
Before you can use the Replication Manager, you may have to enable it in your DB library. This is not a requirement for Microsoft Windows systems, or Unix systems that use pthread mutexes by default. Other systems, notably BSD and BSD-derived systems (such as Mac OS X), must enable the Replication Manager when you configure the DB build.
You do this by not disabling
replication and by configuring the library with POSIX
threads support. In other words, replication must be
turned on in the build (it is by default), and POSIX
thread support must be enabled if it is not already by
default. To do this, use the
--enable-pthread_api switch on the
configure script.
For example:
../dist/configure --enable-pthread-api
As described above, you introduce replication to an application by
starting with a transactional application, performing some basic
replication configuration, and then starting replication using
Environment.replicationManagerStart().
You stop replication by closing your environment cleanly in the same way you would for any DB application.
For example, the following code fragment initializes, then stops and starts replication. Note that other replication activities are omitted for brevity.
Note that the following code fragment would be part of a larger
class that must implement
com.sleepycat.db.EventHandler. This
class is used to track state changes between master and
replica. We put off that implementation for the moment, but the
point remains that the following code fragment would be
contained in a method or two that you would include in your
com.sleepycat.db.EventHandler
implementation.
import com.sleepycat.db.Environment;
import com.sleepycat.db.EnvironmentConfig;
import com.sleepycat.db.ReplicationHostAddress;
import com.sleepycat.db.ReplicationManagerStartPolicy;
import com.sleepycat.db.ReplicationManagerSiteConfig;
...
String progname = "example_replication";
String envHome = "TESTDIR";
int cachesize = 10 * 1024 * 1024;
Environment dbenv;
String listenHost = "mymachine.sleepycat.com";
String otherHost = "anothermachine.sleepycat.com";
int listenPort = 8080;
int otherPort = 8081;
try {
// Configure the environment handle
EnvironmentConfig envConfig = new EnvironmentConfig();
envConfig.setErrorStream(System.err);
envConfig.setErrorPrefix(progname);
envConfig.setCacheSize(cachesize);
envConfig.setTxnNoSync(true);
// Identify the local replication site. This is the local hostname
// and port that this replication participant will use to receive
// incoming replication messages. Note that this can be
// performed only once for the application. It is required.
ReplicationManagerSiteConfig thisHostConfig =
new ReplicationManagerSiteConfig(listenHost, listenPort);
thisHostConfig.setGroupCreator(creator);
thisHostConfig.setLocalSite(true)
envConfig.addReplicationManagerSite(thisHostConfig);
// Set this application's priority. This is used for elections.
//
// Set this number to a positive integer, or 0 if you do not want
// this site to be able to become a master.
envConfig.setReplicationPriority(100);
// Add a site to the list of replication environments known to
// this application.
ReplicationManagerSiteConfig remoteSiteConfig =
new ReplicationManagerSiteConfig(otherHost, otherPort);
remoteSiteConfig.setBootstrapHelper(true);
envConfig.addReplicationManagerSite(remoteSiteConfig);
// Configure the environment's subsystems. Note that we initialize
// replication. This is required.
envConfig.setAllowCreate(true);
envConfig.setRunRecovery(true);
envConfig.setThreaded(true);
envConfig.setInitializeReplication(true);
envConfig.setInitializeLocking(true);
envConfig.setInitializeLogging(true);
envConfig.setInitializeCache(true);
envConfig.setTransactional(true);
// Missing from this is where we set the event handle and the
// acknowledgement policy. We discuss these things later in this
// book.
// Open our environment handle.
try {
dbenv = new Environment(envHome, envConfig);
} catch(FileNotFoundException e) {
System.err.println("FileNotFound exception: " + e.toString());
System.err.println(
"Ensure that the environment directory is pre-created.");
}
// Start the replication manager such that it has three threads.
dbenv.replicationManagerStart(3,
ReplicationManagerStartPolicy.REP_ELECTION);
//////////////////////////////////////////////////
// All other application code goes here, including
// database opens.
//////////////////////////////////////////////////
} catch (DatabaseException dbe) {
// Error handling goes here
}
// Close out your application here.
try {
// Make sure all your databases are closed.
// Closing your environment stops replication.
dbenv.close();
} catch (DatabaseException dbe) {
// Error handling here.
}
// All done.
Before continuing, it is worth taking a look at the
startup election options that you can set for
replication. You set these using the
ReplicationManagerStartPolicy
class that you pass to the
Environment.replicationManagerStart()
method.
In the previous example, we specified
ReplicationManagerStartPolicy.REP_ELECTION
when we started replication. This causes the
application to try to find a master upon startup. If it
cannot, it calls for an election. In the event an
election is held, the environment receiving the most number of
votes will become the master.
There's some important points to make here:
This option only requires that other environments in the replication group participate in the vote. There is no requirement that all such environments participate. In other words, if an environment starts up, it can call for an election, and select a master, even if all other environment have not yet joined the replication group.
It only requires a simple majority of participating environments to elect a master. This is always true of elections held using the Replication Manager.
As always, the environment participating in the election with the most up-to-date log files is selected as master. If an environment with more recent log files has not yet joined the replication group, it may not become the master.
Any one of these points may be enough to cause a less-than-optimum environment to be selected as master. Therefore, to give you a better degree of control over which environment becomes a master at application startup, the Replication Manager offers the following start-up options:
| Option | Description |
|---|---|
ReplicationManagerStartPolicy. REP_MASTER
|
The application starts up and declares the environment to be a master without calling for an election. It is an error for more than one environment to start up using this flag, or for an environment to use this flag when a master already exists. Note that no replication group should ever operate with more than one master. In the event that a environment attempts to become a master when a master already exists, the replication code will resolve the problem by holding an election. Note, however, that there is always a possibility of data loss in the face of duplicate masters, because once a master is selected, the environment that loses the election will have to roll back any transactions committed until it is in sync with the "real" master. |
ReplicationManagerStartPolicy. REP_CLIENT
|
The application starts up and declares the environment to be a replica without calling for an election. Note that the environment can still become a master if a subsequent application starts up, calls for an election, and this environment is elected master. |
ReplicationManagerStartPolicy. REP_ELECTION
|
As described above, the application starts up, looks for a master, and if one is not found calls for an election. |
Under the hood, the Replication Manager is threaded and you can control the number of threads used to process messages received from other replicas. The threads that the Replication Manager uses are:
Incoming message thread. This thread receives messages from the site's socket and passes those messages to message processing threads (see below) for handling.
Outgoing message thread. Outgoing
messages are sent from whatever thread
performed a write to the database(s).
That is, the thread that called, for
example,
Database.put()
is the thread that writes replication messages
about that fact to the socket.
Note that if this write activity would cause the thread to be blocked due to some condition on the socket, the Replication Manager will hand the outgoing message to the incoming message thread, and it will then write the message to the socket. This prevents your database write threads from blocking due to abnormal network I/O conditions.
Message processing threads are responsible for parsing and then responding to incoming replication messages. Typically, a response will include write activity to your database(s), so these threads can be busy performing disk I/O.
Of these threads, the only ones that you have any configuration control over are the message processing threads. In this case, you can determine how many of these threads you want to run.
It is always a bit of an art to decide on a thread count, but the short answer is you probably do not need more than three threads here, and it is likely that one will suffice. That said, the best thing to do is set your thread count to a fairly low number and then increase it if it appears that your application will benefit from the additional threads.