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Migrating from Java SDK 1.4.x to 2.x

Couchbase recommends that you migrate to the Java 2.x SDK to take advantage of enhancements to the SDK as well as new features available in Couchbase Server.

The 2.x Java SDK is based on the reactive programming model and has a different architecture that uses a core I/O layer and a Java client layer. It’s asynchronous by design and offers performance, scalability, and durability enhancements.

This guide helps you migrate from the previous generation of the Java SDK (version 1.4.x) to this new generation SDK (version 2.x).

If you plan on using the synchronous blocking API, you can follow the simple migration path. Or, you can follow the optional migration path to fully reactive and asynchronous code by using the asynchronous API, which provides the best performance.

To get the full benefit of using the asynchronous code with this new generation SDK, you need to understand how to build asynchronous yet expressive code by leveraging the Observable paradigm. To learn more about using Observables, see Mastering Observables.

Getting Started

The 2.x generation of the Java SDK is a complete rewrite of the 1.x SDK. It is layered into core-io and java-client pieces. The java-client layer is more abstract and closer to the client. The core-io layer is purely asynchronous and message-oriented. It makes use of a reactive architecture based on Netty, the LMAX Disruptor, and most importantly RxJava.

The core-io layer is not intended for broad consumption. In general, you should focus on using the java-client layer in your application. For advanced use cases, when you are trying to squeeze out the very last drop of performance working with the raw byte stream or building a client layer in another language, you can use the core-io layer.

The client exposes the server-side concepts of a Cluster and Buckets as first-class citizens that replace the previous CouchbaseClient class. Each class exposes a synchronous API by default, but an asynchronous API (based on RxJava Observable objects) can be accessed simply by calling async() on either one.

This split also allows for much more efficient resource utilization. In the past, each CouchbaseClient (for each bucket) had its resources, but now they are as shared as much as possible, and the Cluster and Bucket references can always be reused.

The Maven artifact has been renamed from couchbase-client to java-client to differentiate this rewrite from the previous generation. It has minimal transitive dependencies (by embedding a few internal dependencies like Netty), most notably RxJava 1.x:

After you’ve fully migrated, make sure that old dependencies to couchbase-client or dependencies introduced in your POM because of the couchbase-client have been removed.

You’ll most probably want the SDK to perform some logging, which can easily be activated by adding a logging framework such as log4j to your dependencies. For more information about configuring logging, see Setting up logging.

Initializing the connection

CouchbaseClient is replaced by the Cluster and Bucket classes, bringing real-world concepts of Couchbase into the SDK as first-class citizens. For more information about using these classes, see Managing connections.

Compared to the 1.4.x SDK, when providing a list of nodes for bootstrapping, you only need hostnames or IP addresses in String form. No need for the URI anymore, and no need for the port and pools path either:

Cluster cluster = CouchbaseCluster.create("");

The SDK uses the factory method pattern to create the Cluster object. This pattern is heavily used throughout the SDK in place of constructors.

The Cluster and each Bucket reference must be reused as much as possible. Make them singletons, which can be used by multiple threads safely. Here’s an example that uses a naive helper approach:

public class CouchbaseHelper {

    //the IPs / hostnames would be obtained from configuration file
    private static final List<String> SEED_IPS = Arrays.asList("", "");

    public static final Cluster CLUSTER = CouchbaseCluster.create(SEED_IPS);

    public static final Bucket EXAMPLEBUCKET = CLUSTER.openBucket("example", "p4ssW0rd");

You can customize the connection to the Cluster via the CouchbaseEnvironment interface (see Configuring the environment for more details):

public class CouchbaseHelper {

    //the IPs / hostnames would be obtained from configuration file
    private static final List<String> SEED_IPS = Arrays.asList("", "");

    //the environment configuration
    private static final CouchbaseEnvironment ENV = DefaultCouchbaseEnvironment.builder()
        .connectTimeout(8 * 1000) // 8 Seconds in milliseconds
        .keepAliveInterval(3600 * 1000) // 3600 Seconds in milliseconds

    public static final Cluster CLUSTER = CouchbaseCluster.create(ENV, SEED_IPS);

    public static final Bucket EXAMPLEBUCKET = CLUSTER.openBucket("example", "p4ssW0rd");

Working With Data

In the new SDK, a new model of data within Couchbase was introduced: the Document class. It encapsulates both the content itself and the metadata ( id, expiry and cas information). See Working with documents for additional information.

The SDK has several implementations of Document. By default, most SDK methods assume the content is JSON and return a JsonDocument. This kind of document use standardized storing flags, which make it compatible with the other second generation SDKs in other languages. If you already deal with JSON transcoding to domain objects, use the RawJsonDocument instead, which exposes the JSON String as content instead of a superfluous JsonObject.

To interact with documents stored by an older Java SDK, use the LegacyDocument class. This class provides 1:1 compatibility with the 1.4 SDK, but consider to migrate to a new implementation after backward compatibility isn’t required anymore.

Concerning optimistic locking—because the CAS is now part of the Document, the SDK picks it up if it is non-zero during mutating operations. To learn more about mutating operations, see Updating documents.

Working Asynchronously

In the 2.x SDK, asynchronous processing is done via RxJava. The asynchronous API is not mixed with the synchronous API, but rather accessible via the async() method on Cluster and Bucket.

The SDK is thread-safe and uses a pool of threads internally for operations (so they are effectively processed in a separate thread). Additionally, some Rx operators use one of the Schedulers provided by RxJava (meaning it could execute in another thread).

The SDK doesn’t use Future objects anymore. For progressive migration purposes, you can convert an Observable into a Future and vice-versa. Here’s an example of how to do that:

//converting these to/from Future
Observable<String> myStringObservable;
Future<String> myStringFuture;

//this expects exactly one item emitted
Future<String> f = myStringObservable.toBlocking().toFuture();

//when several items expected, use a List
Future<List<String>> f = myStringObservable.toList().toBlocking().toFuture();

//convert back from a Future<String>
Observable<String> o = Observable.from(myStringFuture);