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In many real-life situations where you apply MapReduce, the final algorithms end up being several MapReduce steps.

I.e. Map1 , Reduce1 , Map2 , Reduce2 , etc.

So you have the output from the last reduce that is needed as the input for the next map.

The intermediate data is something you (in general) do not want to keep once the pipeline has been successfully completed. Also because this intermediate data is in general some data structure (like a 'map' or a 'set') you don't want to put too much effort in writing and reading these key-value pairs.

What is the recommended way of doing that in Hadoop?

Is there a (simple) example that shows how to handle this intermediate data in the correct way, including the cleanup afterward?

Thanks.

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1  
using which mapreduce framework? –  skaffman Mar 23 '10 at 12:03
    
I edited the question to clarify I'm talking about Hadoop. –  Niels Basjes Mar 23 '10 at 13:11
    
I'd recommend the swineherd gem for this: github.com/Ganglion/swineherd best, Tobias –  Tobias Jun 15 '11 at 9:33

10 Answers 10

up vote 26 down vote accepted

I think this tutorial on Yahoo's developer network will help you with this: Chaining Jobs

You use the JobClient.runJob(). The output path of the data from the first job becomes the input path to your second job. These need to be passed in as arguments to your jobs with appropriate code to parse them and set up the parameters for the job.

I think that the above method might however be the way the now older mapred API did it, but it should still work. There will be a similar method in the new mapreduce API but i'm not sure what it is.

As far as removing intermediate data after a job has finished you can do this in your code. The way i've done it before is using something like:

FileSystem.delete(Path f, boolean recursive);

Where the path is the location on HDFS of the data. You need to make sure that you only delete this data once no other job requires it.

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Thanks for the link to the Yahoo tutorial. The Chaining Jobs is indeed what you want if the two are in the same run. What I was looking for is what the easy way is to do if you want to be able to run them separately. In the mentioned tutorial I found SequenceFileOutputFormat "Writes binary files suitable for reading into subsequent MapReduce jobs" and the matching SequenceFileInputFormat which make it all very easy to do. Thanks. –  Niels Basjes May 17 '10 at 9:14

There are many ways you can do it. (1) Cascading jobs

Create the JobConf object "job1" for the first job and set all the parameters with "input" as inputdirectory and "temp" as output directory. Execute this job: JobClient.run(job1).

Immediately below it, create the JobConf object "job2" for the second job and set all the parameters with "temp" as inputdirectory and "output" as output directory. Execute this job: JobClient.run(job2).

(2) Create two JobConf objects and set all the parameters in them just like (1) except that you don't use JobClient.run.

Then create two Job objects with jobconfs as parameters: Job job1=new Job(jobconf1); Job job2=new Job(jobconf2);

Using the jobControl object, you specify the job dependencies and then run the jobs: JobControl jbcntrl=new JobControl("jbcntrl"); jbcntrl.addJob(job1); jbcntrl.addJob(job2); job2.addDependingJob(job1); jbcntrl.run();

(3) If you need a structure somewhat like Map+ | Reduce | Map*, you can use the ChainMapper and ChainReducer classes that come with Hadoop version 0.19 and onwards.

Cheers

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There are actually a number of ways to do this. I'll focus on two.

One is via Riffle ( http://github.com/cwensel/riffle ) an annotation library for identifying dependent things and 'executing' them in dependency (topological) order.

Or you can use a Cascade (and MapReduceFlow) in Cascading ( http://www.cascading.org/ ). A future version will support Riffle annotations, but it works great now with raw MR JobConf jobs.

A variant on this is to not manage MR jobs by hand at all, but develop your application using the Cascading API. Then the JobConf and job chaining is handled internally via the Cascading planner and Flow classes.

This way you spend your time focusing on your problem, not on the mechanics of managing Hadoop jobs etc. You can even layer different languages on top (like clojure or jruby) to even further simplify your development and applications. http://www.cascading.org/modules.html

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You can use oozie for barch processing your MapReduce jobs. http://issues.apache.org/jira/browse/HADOOP-5303

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Thanks for the suggestion. This seems like a lot more than I was looking for. –  Niels Basjes Mar 24 '10 at 13:57

There are examples in Apache Mahout project that chains together multiple MapReduce jobs. One of the examples can be found at:

RecommenderJob.java

http://search-lucene.com/c/Mahout:/core/src/main/java/org/apache/mahout/cf/taste/hadoop/item/RecommenderJob.java%7C%7CRecommenderJob

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We can make use of waitForCompletion(true) method of the Job to define the dependency among the job.

In my scenario I had 3 jobs which were dependent on each other. In the driver class I used the below code and it works as expected.

public static void main(String[] args) throws Exception {
        // TODO Auto-generated method stub

        CCJobExecution ccJobExecution = new CCJobExecution();

        Job distanceTimeFraudJob = ccJobExecution.configureDistanceTimeFraud(new Configuration(),args[0], args[1]);
        Job spendingFraudJob = ccJobExecution.configureSpendingFraud(new Configuration(),args[0], args[1]);
        Job locationFraudJob = ccJobExecution.configureLocationFraud(new Configuration(),args[0], args[1]);

        System.out.println("****************Started Executing distanceTimeFraudJob ================");
        distanceTimeFraudJob.submit();
        if(distanceTimeFraudJob.waitForCompletion(true))
        {
            System.out.println("=================Completed DistanceTimeFraudJob================= ");
            System.out.println("=================Started Executing spendingFraudJob ================");
            spendingFraudJob.submit();
            if(spendingFraudJob.waitForCompletion(true))
            {
                System.out.println("=================Completed spendingFraudJob================= ");
                System.out.println("=================Started locationFraudJob================= ");
                locationFraudJob.submit();
                if(locationFraudJob.waitForCompletion(true))
                {
                    System.out.println("=================Completed locationFraudJob=================");
                }
            }
        }
    }
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Your answer is about how to join these jobs in terms of execution. The original question was about the best datastructures. So your answer is not relevant for this specific question. –  Niels Basjes Jan 28 '13 at 21:03

I have done job chaining using with JobConf objects one after the other. I took WordCount example for chaining the jobs. One job figures out how many times a word a repeated in the given output. Second job takes first job output as input and figures out total words in the given input. Below is the code that need to be placed in Driver class.

    //First Job - Counts, how many times a word encountered in a given file 
    JobConf job1 = new JobConf(WordCount.class);
    job1.setJobName("WordCount");

    job1.setOutputKeyClass(Text.class);
    job1.setOutputValueClass(IntWritable.class);

    job1.setMapperClass(WordCountMapper.class);
    job1.setCombinerClass(WordCountReducer.class);
    job1.setReducerClass(WordCountReducer.class);

    job1.setInputFormat(TextInputFormat.class);
    job1.setOutputFormat(TextOutputFormat.class);

    //Ensure that a folder with the "input_data" exists on HDFS and contains the input files
    FileInputFormat.setInputPaths(job1, new Path("input_data"));

    //"first_job_output" contains data that how many times a word occurred in the given file
    //This will be the input to the second job. For second job, input data name should be
    //"first_job_output". 
    FileOutputFormat.setOutputPath(job1, new Path("first_job_output"));

    JobClient.runJob(job1);


    //Second Job - Counts total number of words in a given file

    JobConf job2 = new JobConf(TotalWords.class);
    job2.setJobName("TotalWords");

    job2.setOutputKeyClass(Text.class);
    job2.setOutputValueClass(IntWritable.class);

    job2.setMapperClass(TotalWordsMapper.class);
    job2.setCombinerClass(TotalWordsReducer.class);
    job2.setReducerClass(TotalWordsReducer.class);

    job2.setInputFormat(TextInputFormat.class);
    job2.setOutputFormat(TextOutputFormat.class);

    //Path name for this job should match first job's output path name
    FileInputFormat.setInputPaths(job2, new Path("first_job_output"));

    //This will contain the final output. If you want to send this jobs output
    //as input to third job, then third jobs input path name should be "second_job_output"
    //In this way, jobs can be chained, sending output one to other as input and get the
    //final output
    FileOutputFormat.setOutputPath(job2, new Path("second_job_output"));

    JobClient.runJob(job2);

Command to run these jobs is:

bin/hadoop jar TotalWords.

We need to give final jobs name for the command. In the above case, it is TotalWords.

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Although there are complex server based Hadoop workflow engines e.g., oozie, I have a simple java library that enables execution of multiple Hadoop jobs as a workflow. The job configuration and workflow defining inter job dependency is configured in a JSON file. Everything is externally configurable and does not require any change in existing map reduce implementation to be part of a workflow.

Details can be found here. Source code and jar is available in github.

http://pkghosh.wordpress.com/2011/05/22/hadoop-orchestration/

Pranab

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I think oozie helps the consequent jobs to receive the inputs directly from the previous job. This avoids the I/o operation performed with jobcontrol.

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If you want to programmatically chain your jobs, you will wnat to use JobControl. The usage is quite simple:

    JobControl jobControl = new JobControl(name);

After that you add ControlledJob instances. ControlledJob defines a job with it's dependencies, thus automatically pluging inputs and outputs to fit a "chain" of jobs.

    jobControl.add(new ControlledJob(job, Arrays.asList(controlledjob1, controlledjob2));

    jobControl.run();

starts the chain. You will want to put that in a speerate thread. This allows to check the status of your chain whil it runs:

    while (!jobControl.allFinished()) {
        System.out.println("Jobs in waiting state: " + jobControl.getWaitingJobList().size());
        System.out.println("Jobs in ready state: " + jobControl.getReadyJobsList().size());
        System.out.println("Jobs in running state: " + jobControl.getRunningJobList().size());
        List<ControlledJob> successfulJobList = jobControl.getSuccessfulJobList();
        System.out.println("Jobs in success state: " + successfulJobList.size());
        List<ControlledJob> failedJobList = jobControl.getFailedJobList();
        System.out.println("Jobs in failed state: " + failedJobList.size());
    }
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