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Note: these instructions are currently for the S4-22 branch

Install S4

There is currently no distribution package as such. So you need to download the source and build the platform.

...

are 2 ways:

  • Download the 0.5.0 release (warning) We recommend getting the "source" release and building it, because some dependencies that may not be available on your machine, but are required for the "binary" release.
  • or checkout from the Apache git repository, by following the instructions. The 0.5.0 tag corresponds to the current release.

If you get the binary release, s4 scripts are immediately available. Otherwise you must build the project:

  1. Compile and install S4 in the local maven repository: (you can also let the tests run , which is currently quite long: we're not yet using mockswithout the -DskipTests option)
    Code Block
    S4:incubator-s4$ ./gradlew install -DskipTests
.... verbose logs ...
  2. Build the startup scripts: 
    Code Block
    S4:incubator-s4$ ./gradlew s4-tools:installApp
.... verbose logs 
...:s4-tools:installApp

(warning) If you work with NFS, you may get some issues for building the apps. The ./s4 deploy command currently may not work properly (depending on the file locking settings of your cluster). It is still possible to However you can still build applications, deploy them (as s4r, see in a further section) and run them, but you may have to tell the build tool (gradle) to use the local file system for caches and repositories, by appending the following options when using gradle commands:

...

  • HelloPE.java : a very simple PE that simply prints the name contained in incoming events
    Code Block
    // ProcessingElement provides integration with the S4 platform
public class HelloPE extends ProcessingElement {

    // you should define downstream streams here and inject them in the app definition

    // PEs can maintain some state
    boolean seen = false;

    // This method is called upon a new Event on an incoming stream. 
    // You may overload it for handling instances of your own specialized subclasses of Event
    public void onEvent(Event event) {
        System.out.println("Hello " + (seen ? "again " : "") + event.get("name") + "!");
        seen = true;
    }
// skipped remaining methods
  • HelloApp.java: defines a simple application: exposes an input stream ("names"), connected to the HelloPE. See the event dispatch configuration page for more information about how events are dispatched.
    Code Block
    // App parent class provides integration with the S4 platform
public class HelloApp extends App {

    @Override
    protected void onStart() {
    }

    @Override
    protected void onInit() {
        // That's where we define PEs and streams
        // create a prototype
        HelloPE helloPE = createPE(HelloPE.class);
        // Create a stream that listens to the "lines" stream and passes events to the helloPE instance.
        createInputStream("names", new KeyFinder<Event>() {
                // the KeyFinder is used to identify keys
            @Override
            public List<String> get(Event event) {
                return Arrays.asList(new String[] { event.get("name") });
            }
        }, helloPE);
    }
// skipped remaining methods

...

  • to set-up a cluster: provision a cluster and start S4 nodes for that cluster
  • to package the app
  • to publish the app on the clusterthe cluster
  1. Set-up the cluster:
    1. In 2 steps:
      1. Start a Zookeeper server instance
    (log4j warnings come from Zookeeper and can be ignored here)
      1. :
        Code Block
         S4:incubator-s4$ ./s4 zkServer
      1. 
S4:myApp$ calling referenced s4 script : /Users/S4/tmp/
    s4-22/
      1. incubator-s4/s4
[main] INFO  org.apache.s4.tools.ZKServer - Starting zookeeper server on port [2181]
[main] INFO  org.apache.s4.tools.ZKServer - cleaning existing data in [/var/folders/8V/8VdgKWU3HCiy2yV4dzFpDk+++TI/-Tmp-/tmp/zookeeper/data] and [/var/folders/8V/8VdgKWU3HCiy2yV4dzFpDk+++TI/
    -Tmp-/tmp/zookeeper/log] log4j:WARN No appenders could be found for logger (org.I0Itec.zkclient.ZkServer). log4j:WARN Please initialize the log4j system properly.
      1. -Tmp-/tmp/zookeeper/log]
      2. Define a new cluster. Say a cluster named "cluster1" with 2 partitions, nodes listening to ports starting from 12000:
        Code Block
        S4:myApp$ ./s4 newCluster -c=cluster1 -nbTasks=2 -flp=12000
calling referenced s4 script : /Users/S4/tmp/
    s4-22/
      1. incubator-s4/s4
[main] INFO  org.apache.s4.tools.DefineCluster - preparing new cluster [cluster1] with [2] node(s)
[main] INFO  org.apache.s4.tools
    .DefineCluster - New cluster configuration uploaded into zookeeper 
      1. .DefineCluster - New cluster configuration uploaded into zookeeper
    2. Alternatively you may combine these two steps into a single one, by passing the cluster configuration inline with the zkServer command:
      Code Block
       S4:incubator-s4$ ./s4 zkServer -clusters=c=cluster1:flp=12000:nbTasks=2
  2. Start 2 S4 nodes with the default configuration, and attach them to cluster "cluster1" :
    Code Block
    S4:myApp$ ./s4 node -c=cluster1
calling referenced s4 script : /Users/S4/tmp/s4-22/incubator-s4/s4
15:50:18.996 [main] INFO  org.apache.s4.core.Main - Initializing S4 node with : 
- comm module class [org.apache.s4.comm.DefaultCommModule]
- comm configuration file [default.s4.comm.properties from classpath]
- core module class [org.apache.s4.core.DefaultCoreModule]
- core configuration file[default.s4.core.properties from classpath]
-extra modules: []
[main] INFO  org.apache.s4.core.Main - Starting S4 node. This node will automatically download applications published for the cluster it belongs to to
    and again (maybe in another shell):
    Code Block
    
 S4:myApp$ ./s4 node -c=cluster1
  3. Build, package and publish the app to cluster1:
    1. You may do that in a single step (currently, you must use the name of the current project, and you need to specify the gradle build file with a complete path}).
      Note that specifying the app class is optional but avoids issues when the scripts tries to guess automatically the app class:
      Code Block
      S4:myApp$ ./s4 deploy -appName=myApp -c=cluster1 -b=`pwd`/build.gradle -a=hello.HelloApp
.... verbose logs for compiling, building the package, and publishing it to Zookeeper...
15:46:16.486 [main] INFO  org.apache.s4.tools.Deploy - uploaded application [myApp] to cluster [cluster1], using zookeeper znode [/s4/clusters/cluster1/apps/myApp]
    2. You may also do that in 2 separate steps: :
      1. Create an s4r archive. The following creates an archive named myApp.s4r (here you may specify an arbitrary name) in build/libs.
        Again specifying the app class is optional
      2. Create an s4r archive :
        Code Block
        ./gradlews4 s4r -a=hello.HelloApp -b=`pwd`/build.gradle myApp
      3. Publish the s4r archive (you may first copy it to a more adequate place). The name of the app is arbitrary:
        Code Block
        ./s4 deploy -s4r=`pwd`/build/libs/myApp.s4r -c=c1 -appName=myApp/myApp.s4r -c=cluster1 -appName=myApp
        (grey lightbulb) You can follow this method for a distributed deployment (by copying the s4r to a shared location on a distributed file system)
  4. S4 nodes will detect the new application, download it, load it and start it. You will get something like:
    Code Block
    [ZkClient-EventThread-15-localhost:2181] INFO  o.a.s.d.DistributedDeploymentManager - Detected new application(s) to deploy {}[myApp]
[ZkClient-EventThread-15-localhost:2181] INFO  org.apache.s4.core.Server - Local app deployment: using s4r file name [myApp] as application name
[ZkClient-EventThread-15-localhost:2181] INFO  org.apache.s4.core.Server - App class name is: hello.HelloApp
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s4.comm.topology.ClusterFromZK - Changing cluster topology to { nbNodes=0,name=unknown,mode=unicast,type=,nodes=[]} from null
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s4.comm.topology.ClusterFromZK - Adding topology change listener:org.apache.s4.comm.tcp.TCPEmitter@79b2591c
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s.comm.topology.AssignmentFromZK - New session:87684175268872203; state is : SyncConnected
[ZkClient-EventThread-19-localhost:2181] INFO  o.a.s4.comm.topology.ClusterFromZK - Changing cluster topology to { nbNodes=1,name=cluster1,mode=unicast,type=,nodes=[{partition=0,port=12000,machineName=myMachine.myNetwork,taskId=Task-0}]} from { nbNodes=0,name=unknown,mode=unicast,type=,nodes=[]}
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s.comm.topology.AssignmentFromZK - Successfully acquired task:Task-1 by myMachine.myNetwork
[ZkClient-EventThread-19-localhost:2181] INFO  o.a.s4.comm.topology.ClusterFromZK - Changing cluster topology to { nbNodes=2,name=cluster1,mode=unicast,type=,nodes=[{partition=0,port=12000,machineName=myMachine.myNetwork,taskId=Task-0}, {partition=1,port=12001,machineName=myMachine.myNetwork,taskId=Task-1}]} from { nbNodes=1,name=cluster1,mode=unicast,type=,nodes=[{partition=0,port=12000,machineName=myMachine.myNetwork,taskId=Task-0}]}
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s4.comm.topology.ClustersFromZK - New session:87684175268872205
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s4.comm.topology.ClustersFromZK - Detected new stream [names]
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s4.comm.topology.ClustersFromZK - New session:87684175268872206
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s4.comm.topology.ClusterFromZK - Changing cluster topology to { nbNodes=2,name=cluster1,mode=unicast,type=,nodes=[{partition=0,port=12000,machineName=myMachine.myNetwork,taskId=Task-0}, {partition=1,port=12001,machineName=myMachine.myNetwork,taskId=Task-1}]} from null
[ZkClient-EventThread-15-localhost:2181] INFO  org.apache.s4.core.Server - Loaded application from file /tmp/deploy-test/cluster1/myApp.s4r
[ZkClient-EventThread-15-localhost:2181] INFO  o.a.s.d.DistributedDeploymentManager - Successfully installed application myApp
[ZkClient-EventThread-15-localhost:2181] DEBUG o.a.s.c.g.OverloadDispatcherGenerator - Dumping generated overload dispatcher class for PE of class [class hello.HelloPE]
[ZkClient-EventThread-15-localhost:2181] DEBUG o.a.s4.comm.topology.ClustersFromZK - Adding input stream [names] for app [-1] in cluster [cluster1]
[ZkClient-EventThread-15-localhost:2181] INFO  org.apache.s4.core.App - Init prototype [hello.HelloPE].

Great! The application is now deployed on 2 S4 nodes. It needs some input though...The application is now deployed on 2 S4 nodes.

(grey lightbulb) You can check the status of the application, nodes and streams with the "status" command:

Code Block

 ./s4 status

Now what we need is some input!

We can get input through an adapter, i.e. an S4 app that converts an external stream into S4 events, and injects the events into S4 clusters. In the sample application, the adapter is a very basic class, that extends App, listens to an input socket on port 15000, and converts each received line of characters into a generic S4 event, in which the line data is kept in a "name" field. We specify :

...

  1. First, we need to define a new S4 subcluster for that app:
    Code Block
    S4:myApp$ ./s4 newCluster -c=cluster2 -nbTasks=1 -flp=13000
  2. Then we can start the adapter, and we use "names" for identifying the output stream (this is the same name used as input by the myApp app)
    (warning)   The adapter command must be run from the root of your S4 project (myApp dir in our case).
Code Block
./s4 adapter -appClass=hello.HelloInputAdapter -c=cluster2 -

...

p=s4.adapter.output.stream

...

=names
  1. Now let's just provide some data to the external stream (our adapter is listening to port 15000):
    Code Block
    S4:~$ echo "Bob" | nc localhost 15000
  2. Nodes One of the nodes should output in their its console:
    Code Block
    Hello Bob!

both nodes If you keep sending messages, nodes will alternatively display the same messages because we did not specify any partitioning scheme for "hello" messages because the adapter app sends keyless events on the "names" stream in the producera round-robin fashion by default.

What happened?

The following figures illustrate the various steps we have taken. The local file system is used as the S4 application repository in our example.

...

  • the build.gradle file must be tailored to include new dependencies (twitter4j libs in twitter-adapter)
  • events are partitioned through various keys

Run it!

Note: You need a twitter4twitter4j.properties file in your home directory with the following content (debug is optional):

Code Block
debug=true
user=<a twitter username>
password=<matching password>
  1. Start a Zookeeper instance. From the S4 base directory, do:
    Code Block
    ./s4 zkServer
  2. Define 2 clusters : 1 for deploying the twitter-counter app, and 1 for the adapter app
    Code Block
    ./s4 newCluster -c=cluster1 -nbTasks=2 -flp=12000; ./s4 newCluster -c=cluster2 -nbTasks=1 -flp=13000
  3. Start 2 app nodes (you may want to start each node in a separate console) :
    Code Block
    ./s4 node -c=cluster1
    Code Block
    ./s4 node -c=cluster1
  4. Start 1 node for the adapter app:
    Code Block
    ./s4 node -c=cluster2 -namedStringParametersp=s4.adapter.output.stream:=RawStatus
  5. Deploy twitter-counter app (you may also first build the s4r then publish it, as described in the previous section)
    Code Block
    ./s4 deploy -appName=twitter-counter -c=cluster1 -b=`pwd`/test-apps/twitter-counter/build.gradle
  6. Deploy twitter-adapter app. In this example, we don't directly specify the app class of the adapter, we use the deployment approach for apps (remember, the adapter is also an app).
    Code Block
    ./s4 deploy -appName=twitter-adapter -c=cluster2 -b=`pwd`/test-apps/twitter-adapter/build.gradle
  7. Observe the current 10 most popular topics in file TopNTopics.txt. The file gets updated at regular intervals, and only outputs topics with a minimum of 10 occurrences, so you may have to wait a little before the file is updated :
    Code Block
    tail -f TopNTopics.txt
  8. You may also check the status of the S4 node with:
    Code Block
    tail -f TopNTopics.txt./s4 status

...

What next?

You have now seen some basics applications, and you know how to run them, and how to get events into the system. You may now try to code your own apps with your own data.

This page will help for specifying your own dependencies.

There are more parameters available for the scripts (typing the name of the task will list the options). In particular, if you want distributed deployments, you'll need to pass the Zookeeper connection strings when you start the nodes.

You may also customize the communication and the core layers of S4 by tweaking configuration files and modules.

Last, the javadoc will help you when writing applications.

We hope this will help you start rapidly, and remember: In conclusion, edges are still a bit rough, more aspects need to be documented, and this is not a final version, but that should let you start, and we're happy to help!