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Java Programming Guide |
The Spark Java API exposes all the Spark features available in the Scala version to Java. To learn the basics of Spark, we recommend reading through the Scala programming guide first; it should be easy to follow even if you don't know Scala. This guide will show how to use the Spark features described there in Java.
The Spark Java API is defined in the
org.apache.spark.api.java package, and includes
a JavaSparkContext for
initializing Spark and JavaRDD classes,
which support the same methods as their Scala counterparts but take Java functions and return
Java data and collection types. The main differences have to do with passing functions to RDD
operations (e.g. map) and handling RDDs of different types, as discussed next.
There are a few key differences between the Java and Scala APIs:
- Java does not support anonymous or first-class functions, so functions must
be implemented by extending the
org.apache.spark.api.java.function.Function,Function2, etc. classes. - To maintain type safety, the Java API defines specialized Function and RDD
classes for key-value pairs and doubles. For example,
JavaPairRDDstores key-value pairs. - RDD methods like
collect()andcountByKey()return Java collections types, such asjava.util.Listandjava.util.Map. - Key-value pairs, which are simply written as
(key, value)in Scala, are represented by thescala.Tuple2class, and need to be created usingnew Tuple2<K, V>(key, value).
Spark defines additional operations on RDDs of key-value pairs and doubles, such
as reduceByKey, join, and stdev.
In the Scala API, these methods are automatically added using Scala's implicit conversions mechanism.
In the Java API, the extra methods are defined in the
JavaPairRDD
and JavaDoubleRDD
classes. RDD methods like map are overloaded by specialized PairFunction
and DoubleFunction classes, allowing them to return RDDs of the appropriate
types. Common methods like filter and sample are implemented by
each specialized RDD class, so filtering a PairRDD returns a new PairRDD,
etc (this acheives the "same-result-type" principle used by the Scala collections
framework).
The following table lists the function classes used by the Java API. Each
class has a single abstract method, call(), that must be implemented.
| Class | Function Type |
|---|---|
| Function<T, R> | T => R |
| DoubleFunction<T> | T => Double |
| PairFunction<T, K, V> | T => Tuple2<K, V> |
| FlatMapFunction<T, R> | T => Iterable<R> |
| DoubleFlatMapFunction<T> | T => Iterable<Double> |
| PairFlatMapFunction<T, K, V> | T => Iterable<Tuple2<K, V>> |
| Function2<T1, T2, R> | T1, T2 => R (function of two arguments) |
RDD storage level constants, such as MEMORY_AND_DISK, are
declared in the org.apache.spark.api.java.StorageLevels class. To
define your own storage level, you can use StorageLevels.create(...).
The Java API supports other Spark features, including accumulators, broadcast variables, and caching.
As an example, we will implement word count using the Java API.
{% highlight java %} import org.apache.spark.api.java.; import org.apache.spark.api.java.function.;
JavaSparkContext sc = new JavaSparkContext(...); JavaRDD lines = ctx.textFile("hdfs://..."); JavaRDD words = lines.flatMap( new FlatMapFunction<String, String>() { public Iterable call(String s) { return Arrays.asList(s.split(" ")); } } ); {% endhighlight %}
The word count program starts by creating a JavaSparkContext, which accepts
the same parameters as its Scala counterpart. JavaSparkContext supports the
same data loading methods as the regular SparkContext; here, textFile
loads lines from text files stored in HDFS.
To split the lines into words, we use flatMap to split each line on
whitespace. flatMap is passed a FlatMapFunction that accepts a string and
returns an java.lang.Iterable of strings.
Here, the FlatMapFunction was created inline; another option is to subclass
FlatMapFunction and pass an instance to flatMap:
{% highlight java %} class Split extends FlatMapFunction<String, String> { public Iterable call(String s) { return Arrays.asList(s.split(" ")); } ); JavaRDD words = lines.flatMap(new Split()); {% endhighlight %}
Continuing with the word count example, we map each word to a (word, 1) pair:
{% highlight java %} import scala.Tuple2; JavaPairRDD<String, Integer> ones = words.map( new PairFunction<String, String, Integer>() { public Tuple2<String, Integer> call(String s) { return new Tuple2(s, 1); } } ); {% endhighlight %}
Note that map was passed a PairFunction<String, String, Integer> and
returned a JavaPairRDD<String, Integer>.
To finish the word count program, we will use reduceByKey to count the
occurrences of each word:
{% highlight java %} JavaPairRDD<String, Integer> counts = ones.reduceByKey( new Function2<Integer, Integer, Integer>() { public Integer call(Integer i1, Integer i2) { return i1 + i2; } } ); {% endhighlight %}
Here, reduceByKey is passed a Function2, which implements a function with
two arguments. The resulting JavaPairRDD contains (word, count) pairs.
In this example, we explicitly showed each intermediate RDD. It is also possible to chain the RDD transformations, so the word count example could also be written as:
{% highlight java %} JavaPairRDD<String, Integer> counts = lines.flatMap( ... ).map( ... ).reduceByKey( ... ); {% endhighlight %}
There is no performance difference between these approaches; the choice is just a matter of style.
We currently provide documentation for the Java API as Scaladoc, in the
org.apache.spark.api.java package, because
some of the classes are implemented in Scala. The main downside is that the types and function
definitions show Scala syntax (for example, def reduce(func: Function2[T, T]): T instead of
T reduce(Function2<T, T> func)).
We hope to generate documentation with Java-style syntax in the future.
Spark includes several sample programs using the Java API in
examples/src/main/java. You can run them by passing the class name to the
run-example script included in Spark; for example:
./run-example org.apache.spark.examples.JavaWordCount
Each example program prints usage help when run without any arguments.