Flink streaming is compatible with Apache Storm interfaces and therefore allows reusing code that was implemented for Storm.
You can:
Topology
in Flink.Spout
/Bolt
as source/operator in Flink streaming programs.This document shows how to use existing Storm code with Flink.
Support for Storm is contained in the flink-storm
Maven module.
The code resides in the org.apache.flink.storm
package.
Add the following dependency to your pom.xml
if you want to execute Storm code in Flink.
<dependency>
<groupId>org.apache.flink</groupId>
<artifactId>flink-storm_2.10</artifactId>
<version>1.3-SNAPSHOT</version>
</dependency>
Please note: Do not add storm-core
as a dependency. It is already included via flink-storm
.
Please note: flink-storm
is not part of the provided binary Flink distribution.
Thus, you need to include flink-storm
classes (and their dependencies) in your program jar (also called ueber-jar or fat-jar) that is submitted to Flink’s JobManager.
See WordCount Storm within flink-storm-examples/pom.xml
for an example how to package a jar correctly.
If you want to avoid large ueber-jars, you can manually copy storm-core-0.9.4.jar
, json-simple-1.1.jar
and flink-storm-1.3-SNAPSHOT.jar
into Flink’s lib/
folder of each cluster node (before the cluster is started).
For this case, it is sufficient to include only your own Spout and Bolt classes (and their internal dependencies) into the program jar.
Flink provides a Storm compatible API (org.apache.flink.storm.api
) that offers replacements for the following classes:
StormSubmitter
replaced by FlinkSubmitter
NimbusClient
and Client
replaced by FlinkClient
LocalCluster
replaced by FlinkLocalCluster
In order to submit a Storm topology to Flink, it is sufficient to replace the used Storm classes with their Flink replacements in the Storm client code that assembles the topology.
The actual runtime code, ie, Spouts and Bolts, can be used unmodified.
If a topology is executed in a remote cluster, parameters nimbus.host
and nimbus.thrift.port
are used as jobmanger.rpc.address
and jobmanger.rpc.port
, respectively. If a parameter is not specified, the value is taken from flink-conf.yaml
.
TopologyBuilder builder = new TopologyBuilder(); // the Storm topology builder
// actual topology assembling code and used Spouts/Bolts can be used as-is
builder.setSpout("source", new FileSpout(inputFilePath));
builder.setBolt("tokenizer", new BoltTokenizer()).shuffleGrouping("source");
builder.setBolt("counter", new BoltCounter()).fieldsGrouping("tokenizer", new Fields("word"));
builder.setBolt("sink", new BoltFileSink(outputFilePath)).shuffleGrouping("counter");
Config conf = new Config();
if(runLocal) { // submit to test cluster
// replaces: LocalCluster cluster = new LocalCluster();
FlinkLocalCluster cluster = new FlinkLocalCluster();
cluster.submitTopology("WordCount", conf, FlinkTopology.createTopology(builder));
} else { // submit to remote cluster
// optional
// conf.put(Config.NIMBUS_HOST, "remoteHost");
// conf.put(Config.NIMBUS_THRIFT_PORT, 6123);
// replaces: StormSubmitter.submitTopology(topologyId, conf, builder.createTopology());
FlinkSubmitter.submitTopology("WordCount", conf, FlinkTopology.createTopology(builder));
}
As an alternative, Spouts and Bolts can be embedded into regular streaming programs.
The Storm compatibility layer offers a wrapper classes for each, namely SpoutWrapper
and BoltWrapper
(org.apache.flink.storm.wrappers
).
Per default, both wrappers convert Storm output tuples to Flink’s Tuple types (ie, Tuple0
to Tuple25
according to the number of fields of the Storm tuples).
For single field output tuples a conversion to the field’s data type is also possible (eg, String
instead of Tuple1<String>
).
Because Flink cannot infer the output field types of Storm operators, it is required to specify the output type manually.
In order to get the correct TypeInformation
object, Flink’s TypeExtractor
can be used.
In order to use a Spout as Flink source, use StreamExecutionEnvironment.addSource(SourceFunction, TypeInformation)
.
The Spout object is handed to the constructor of SpoutWrapper<OUT>
that serves as first argument to addSource(...)
.
The generic type declaration OUT
specifies the type of the source output stream.
StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
// stream has `raw` type (single field output streams only)
DataStream<String> rawInput = env.addSource(
new SpoutWrapper<String>(new FileSpout(localFilePath), new String[] { Utils.DEFAULT_STREAM_ID }), // emit default output stream as raw type
TypeExtractor.getForClass(String.class)); // output type
// process data stream
[...]
If a Spout emits a finite number of tuples, SpoutWrapper
can be configures to terminate automatically by setting numberOfInvocations
parameter in its constructor.
This allows the Flink program to shut down automatically after all data is processed.
Per default the program will run until it is canceled manually.
In order to use a Bolt as Flink operator, use DataStream.transform(String, TypeInformation, OneInputStreamOperator)
.
The Bolt object is handed to the constructor of BoltWrapper<IN,OUT>
that serves as last argument to transform(...)
.
The generic type declarations IN
and OUT
specify the type of the operator’s input and output stream, respectively.
StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
DataStream<String> text = env.readTextFile(localFilePath);
DataStream<Tuple2<String, Integer>> counts = text.transform(
"tokenizer", // operator name
TypeExtractor.getForObject(new Tuple2<String, Integer>("", 0)), // output type
new BoltWrapper<String, Tuple2<String, Integer>>(new BoltTokenizer())); // Bolt operator
// do further processing
[...]
Bolts can accesses input tuple fields via name (additionally to access via index). To use this feature with embedded Bolts, you need to have either a
For POJO input types, Flink accesses the fields via reflection.
For this case, Flink expects either a corresponding public member variable or public getter method.
For example, if a Bolt accesses a field via name sentence
(eg, String s = input.getStringByField("sentence");
), the input POJO class must have a member variable public String sentence;
or method public String getSentence() { ... };
(pay attention to camel-case naming).
For Tuple
input types, it is required to specify the input schema using Storm’s Fields
class.
For this case, the constructor of BoltWrapper
takes an additional argument: new BoltWrapper<Tuple1<String>, ...>(..., new Fields("sentence"))
.
The input type is Tuple1<String>
and Fields("sentence")
specify that input.getStringByField("sentence")
is equivalent to input.getString(0)
.
See BoltTokenizerWordCountPojo and BoltTokenizerWordCountWithNames for examples.
In Storm, Spouts and Bolts can be configured with a globally distributed Map
object that is given to submitTopology(...)
method of LocalCluster
or StormSubmitter
.
This Map
is provided by the user next to the topology and gets forwarded as a parameter to the calls Spout.open(...)
and Bolt.prepare(...)
.
If a whole topology is executed in Flink using FlinkTopologyBuilder
etc., there is no special attention required – it works as in regular Storm.
For embedded usage, Flink’s configuration mechanism must be used.
A global configuration can be set in a StreamExecutionEnvironment
via .getConfig().setGlobalJobParameters(...)
.
Flink’s regular Configuration
class can be used to configure Spouts and Bolts.
However, Configuration
does not support arbitrary key data types as Storm does (only String
keys are allowed).
Thus, Flink additionally provides StormConfig
class that can be used like a raw Map
to provide full compatibility to Storm.
StreamExecutionEnvironment env = StreamExecutionEnvironment.getExecutionEnvironment();
StormConfig config = new StormConfig();
// set config values
[...]
// set global Storm configuration
env.getConfig().setGlobalJobParameters(config);
// assemble program with embedded Spouts and/or Bolts
[...]
Flink can also handle the declaration of multiple output streams for Spouts and Bolts.
If a whole topology is executed in Flink using FlinkTopologyBuilder
etc., there is no special attention required – it works as in regular Storm.
For embedded usage, the output stream will be of data type SplitStreamType<T>
and must be split by using DataStream.split(...)
and SplitStream.select(...)
.
Flink provides the predefined output selector StormStreamSelector<T>
for .split(...)
already.
Furthermore, the wrapper type SplitStreamTuple<T>
can be removed using SplitStreamMapper<T>
.
[...]
// get DataStream from Spout or Bolt which declares two output streams s1 and s2 with output type SomeType
DataStream<SplitStreamType<SomeType>> multiStream = ...
SplitStream<SplitStreamType<SomeType>> splitStream = multiStream.split(new StormStreamSelector<SomeType>());
// remove SplitStreamType using SplitStreamMapper to get data stream of type SomeType
DataStream<SomeType> s1 = splitStream.select("s1").map(new SplitStreamMapper<SomeType>()).returns(SomeType.class);
DataStream<SomeType> s2 = splitStream.select("s2").map(new SplitStreamMapper<SomeType>()).returns(SomeType.class);
// do further processing on s1 and s2
[...]
See SpoutSplitExample.java for a full example.
In Flink, streaming sources can be finite, ie, emit a finite number of records and stop after emitting the last record. However, Spouts usually emit infinite streams.
The bridge between the two approaches is the FiniteSpout
interface which, in addition to IRichSpout
, contains a reachedEnd()
method, where the user can specify a stopping-condition.
The user can create a finite Spout by implementing this interface instead of (or additionally to) IRichSpout
, and implementing the reachedEnd()
method in addition.
In contrast to a SpoutWrapper
that is configured to emit a finite number of tuples, FiniteSpout
interface allows to implement more complex termination criteria.
Although finite Spouts are not necessary to embed Spouts into a Flink streaming program or to submit a whole Storm topology to Flink, there are cases where they may come in handy:
An example of a finite Spout that emits records for 10 seconds only:
public class TimedFiniteSpout extends BaseRichSpout implements FiniteSpout {
[...] // implement open(), nextTuple(), ...
private long starttime = System.currentTimeMillis();
public boolean reachedEnd() {
return System.currentTimeMillis() - starttime > 10000l;
}
}
You can find more examples in Maven module flink-storm-examples
.
For the different versions of WordCount, see README.md.
To run the examples, you need to assemble a correct jar file.
flink-storm-examples-1.3-SNAPSHOT.jar
is no valid jar file for job execution (it is only a standard maven artifact).
There are example jars for embedded Spout and Bolt, namely WordCount-SpoutSource.jar
and WordCount-BoltTokenizer.jar
, respectively.
Compare pom.xml
to see how both jars are built.
Furthermore, there is one example for whole Storm topologies (WordCount-StormTopology.jar
).
You can run each of those examples via bin/flink run <jarname>.jar
. The correct entry point class is contained in each jar’s manifest file.