tree: 388f9494e05f7e1c57ed2950d036b4a2dec7b2aa [path history] [tgz]
  1. client/
  2. webapp/
  3. pom.xml
  4. README.MD
examples/server-async-standalone/README.MD

Server Asynchronous Standalone Example

This example demonstrates JAX-RS 2.0 asynchronous API, both on the client and server side.

The goal of the sample is to demonstrate that with limited I/O processing threads on the server the synchronous execution of a long-running task may lead to resource starvation caused by I/O processing threads being blocked by the long-running operation, unable to serve new incoming requests.

OTOH, when the same long-running operation is executed asynchronously, the I/O threads do not need to block while waiting for the long-running operation to finish and the overall throughput of the system is greatly increased.

The example consists of 2 modules:

  1. web application module “webapp” (produces server-async-standalone-webapp.war)

    • the module contains an long-running echo service deployed under application context root on path templates:

      • “long-running/sync/{echo}”, served by a synchronously executed, blockingmethod.

      • “long-running/async/{echo}”, served by an asynchronously executed, non-blocking method.

  2. client module “client” (produces client.jar)

    • the module contains the web application client developed using JAX-RS 2.0 client API & leveraging the asynchronous client execution for spawning multiple simultaneous client requests with subsequent asynchronous response processing.

To build the example, change to the example root directory and invoke maven build:

mvn clean package

This command builds the web application WAR as well as client JAR artifacts. Once built, the web application may be deployed to the application server. E.g. to deploy the application to a running GlassFish instance, you may do (while still being in the root example directory):

$AS_HOME/bin/as-admin deploy ./webapp/target/server-async-standalone-webapp.war

Once deployed, the client can be run as follows:

cd client mvn exec:java

This will start the main client GUI window. In the top panel, the GUI lets you to customize few variables such as number of requests to be sent, base web application URL or sync/async endpoint to be invoked. Once the client is set up, the “Run” button runs the requests. Each request is represented as a colored box in the lower window panel. The color indicates the request status:

  • yellow - running
  • green - successfully completed
  • red - request execution failed with an error

Also, the tooltip of each box provides additional status information. After the execution is finished, short statistics about the run are displayed in the middle window panel.

Executing command-line client:

Optionally, a command line Main.java client can be executed (by changing the mainClass of exec-maven-plugin in pom.xml to org.glassfish.jersey.examples.server.async.Main). Following properties may be customized in the command-line client runtime:

  1. req=

    : number of requests to be sent by the client, defaults to 10

  2. mode=(sync|async)

    : execution mode defines which version of the service should be used, defaults to “async”

  3. uri=<base_webapp_uri>

    : base URI of the deployed web application, defaults to “http://localhost:8080/server-async-standalone-webapp

These properties may be passed throug maven to the client runtime as command-line arguments using the -Dexec.args=“” flag, e.g.:

mvn exec:java -Dexec.args=“req=20 mode=sync uri=http://foo.com/bar

When the example client is run, successfully executed requests are output as an asterisk ‘*’, failed requests as an exclamation mark ‘!’. Any errors that occured during the client execution are reported at the end of the run including the statistics about the processing time and success ratio.

Try running the client using many requests and compare the results when running against sync and async version of the resource, e.g.:

mvn exec:java -Dexec.args=“req=100 mode=sync” mvn exec:java -Dexec.args=“req=100 mode=async”

You should see a significant speed improvement in the latter run.