The Apache Flink community is pleased to announce the availability of the 0.9.0 release. The release is the result of many months of hard work within the Flink community. It contains many new features and improvements which were previewed in the 0.9.0-milestone1 release and have been polished since then. This is the largest Flink release so far.
Download the release and check out the documentation. Feedback through the Flink mailing lists is, as always, very welcome!
This release introduces a new fault tolerance mechanism for streaming dataflows. The new checkpointing algorithm takes data sources and also user-defined state into account and recovers failures such that all records are reflected exactly once in the operator states.
The checkpointing algorithm is lightweight and driven by barriers that are periodically injected into the data streams at the sources. As such, it has an extremely low coordination overhead and is able to sustain very high throughput rates. User-defined state can be automatically backed up to configurable storage by the fault tolerance mechanism.
Please refer to the documentation on stateful computation for details in how to use fault tolerant data streams with Flink.
The fault tolerance mechanism requires data sources that can replay recent parts of the stream, such as Apache Kafka. Read more about how to use the persistent Kafka source.
Flink’s new Table API offers a higher-level abstraction for interacting with structured data sources. The Table API allows users to execute logical, SQL-like queries on distributed data sets while allowing them to freely mix declarative queries with regular Flink operators. Here is an example that groups and joins two tables:
val clickCounts = clicks .groupBy('user).select('userId, 'url.count as 'count) val activeUsers = users.join(clickCounts) .where('id === 'userId && 'count > 10).select('username, 'count, ...)
Tables consist of logical attributes that can be selected by name rather than physical Java and Scala data types. This alleviates a lot of boilerplate code for common ETL tasks and raises the abstraction for Flink programs. Tables are available for both static and streaming data sources (DataSet and DataStream APIs).
Check out the Table guide for Java and Scala.
Gelly is a Java Graph API for Flink. It contains a set of utilities for graph analysis, support for iterative graph processing and a library of graph algorithms. Gelly exposes a Graph data structure that wraps DataSets for vertices and edges, as well as methods for creating graphs from DataSets, graph transformations and utilities (e.g., in- and out- degrees of vertices), neighborhood aggregations, iterative vertex-centric graph processing, as well as a library of common graph algorithms, including PageRank, SSSP, label propagation, and community detection.
Gelly internally builds on top of Flink’s delta iterations. Iterative graph algorithms are executed leveraging mutable state, achieving similar performance with specialized graph processing systems.
Gelly will eventually subsume Spargel, Flink’s Pregel-like API.
Note: The Gelly library is still in beta status and subject to improvements and heavy performance tuning.
This release includes the first version of Flink’s Machine Learning library. The library’s pipeline approach, which has been strongly inspired by scikit-learn’s abstraction of transformers and predictors, makes it easy to quickly set up a data processing pipeline and to get your job done.
Flink distinguishes between transformers and predictors. Transformers are components which transform your input data into a new format allowing you to extract features, cleanse your data or to sample from it. Predictors on the other hand constitute the components which take your input data and train a model on it. The model you obtain from the learner can then be evaluated and used to make predictions on unseen data.
Currently, the machine learning library contains transformers and predictors to do multiple tasks. The library supports multiple linear regression using stochastic gradient descent to scale to large data sizes. Furthermore, it includes an alternating least squares (ALS) implementation to factorizes large matrices. The matrix factorization can be used to do collaborative filtering. An implementation of the communication efficient distributed dual coordinate ascent (CoCoA) algorithm is the latest addition to the library. The CoCoA algorithm can be used to train distributed soft-margin SVMs.
Note: The ML library is still in beta status and subject to improvements and heavy performance tuning.
We are introducing a new execution mode for Flink to be able to run restricted Flink programs on top of Apache Tez. This mode retains Flink’s APIs, optimizer, as well as Flink’s runtime operators, but instead of wrapping those in Flink tasks that are executed by Flink TaskManagers, it wraps them in Tez runtime tasks and builds a Tez DAG that represents the program.
By using Flink on Tez, users have an additional choice for an execution platform for Flink programs. While Flink’s distributed runtime favors low latency, streaming shuffles, and iterative algorithms, Tez focuses on scalability and elastic resource usage in shared YARN clusters.
Get started with Flink on Tez.
Flink’s RPC system has been replaced by the widely adopted Akka framework. Akka’s concurrency model offers the right abstraction to develop a fast as well as robust distributed system. By using Akka’s own failure detection mechanism the stability of Flink’s runtime is significantly improved, because the system can now react in proper form to node outages. Furthermore, Akka improves Flink’s scalability by introducing asynchronous messages to the system. These asynchronous messages allow Flink to be run on many more nodes than before.
Flink’s YARN client contains several improvements, such as a detached mode for starting a YARN session in the background, the ability to submit a single Flink job to a YARN cluster without starting a session, including a “fire and forget” mode. Flink is now also able to reallocate failed YARN containers to maintain the size of the requested cluster. This feature allows to implement fault-tolerant setups on top of YARN. There is also an internal Java API to deploy and control a running YARN cluster. This is being used by system integrators to easily control Flink on YARN within their Hadoop 2 cluster.
This release introduces a first version of a static code analyzer that pre-interprets functions written by the user to get information about the function’s internal dataflow. The code analyzer can provide useful information about forwarded fields to Flink's optimizer and thus speedup job executions. It also informs if the code contains obvious mistakes. For stability reasons, the code analyzer is initially disabled by default. It can be activated through
ExecutionEnvironment.getExecutionConfig().setCodeAnalysisMode(...)
either as an assistant that gives hints during the implementation or by directly applying the optimizations that have been found.
FLINK-1605: Flink is not exposing its Guava and ASM dependencies to Maven projects depending on Flink. We use the maven-shade-plugin to relocate these dependencies into our own namespace. This allows users to use any Guava or ASM version.
FLINK-1417: Automatic recognition and registration of Java Types at Kryo and the internal serializers: Flink has its own type handling and serialization framework falling back to Kryo for types that it cannot handle. To get the best performance Flink is automatically registering all types a user is using in their program with Kryo.Flink also registers serializers for Protocol Buffers, Thrift, Avro and YodaTime automatically. Users can also manually register serializers to Kryo (https://issues.apache.org/jira/browse/FLINK-1399)
FLINK-1296: Add support for sorting very large records
FLINK-1679: “degreeOfParallelism” methods renamed to “parallelism”
FLINK-1501: Add metrics library for monitoring TaskManagers
FLINK-1760: Add support for building Flink with Scala 2.11
FLINK-1648: Add a mode where the system automatically sets the parallelism to the available task slots
FLINK-1622: Add groupCombine operator
FLINK-1589: Add option to pass Configuration to LocalExecutor
FLINK-1504: Add support for accessing secured HDFS clusters in standalone mode
FLINK-1478: Add strictly local input split assignment
FLINK-1512: Add CsvReader for reading into POJOs.
FLINK-1461: Add sortPartition operator
FLINK-1450: Add Fold operator to the Streaming api
FLINK-1389: Allow setting custom file extensions for files created by the FileOutputFormat
FLINK-1236: Add support for localization of Hadoop Input Splits
FLINK-1179: Add button to JobManager web interface to request stack trace of a TaskManager
FLINK-1105: Add support for locally sorted output
FLINK-1688: Add socket sink
FLINK-1436: Improve usability of command line interface
FLINK-2174: Allow comments in ‘slaves’ file
FLINK-1698: Add polynomial base feature mapper to ML library
FLINK-1697: Add alternating least squares algorithm for matrix factorization to ML library
FLINK-1792: FLINK-456 Improve TM Monitoring: CPU utilization, hide graphs by default and show summary only
FLINK-1672: Refactor task registration/unregistration
FLINK-2001: DistanceMetric cannot be serialized
FLINK-1676: enableForceKryo() is not working as expected
FLINK-1959: Accumulators BROKEN after Partitioning
FLINK-1696: Add multiple linear regression to ML library
FLINK-1820: Bug in DoubleParser and FloatParser - empty String is not casted to 0
FLINK-1985: Streaming does not correctly forward ExecutionConfig to runtime
FLINK-1828: Impossible to output data to an HBase table
FLINK-1952: Cannot run ConnectedComponents example: Could not allocate a slot on instance
FLINK-1848: Paths containing a Windows drive letter cannot be used in FileOutputFormats
FLINK-1954: Task Failures and Error Handling
FLINK-2004: Memory leak in presence of failed checkpoints in KafkaSource
FLINK-2132: Java version parsing is not working for OpenJDK
FLINK-2098: Checkpoint barrier initiation at source is not aligned with snapshotting
FLINK-2069: writeAsCSV function in DataStream Scala API creates no file
FLINK-2092: Document (new) behavior of print() and execute()
FLINK-2177: NullPointer in task resource release
FLINK-2054: StreamOperator rework removed copy calls when passing output to a chained operator
FLINK-2196: Missplaced Class in flink-java SortPartitionOperator
FLINK-2191: Inconsistent use of Closure Cleaner in Streaming API
FLINK-2206: JobManager webinterface shows 5 finished jobs at most
FLINK-2188: Reading from big HBase Tables
FLINK-1781: Quickstarts broken due to Scala Version Variables
The 0.9 series of Flink is the last version to support Java 6. If you are still using Java 6, please consider upgrading to Java 8 (Java 7 ended its free support in April 2015).
Flink will require at least Java 7 in major releases after 0.9.0.