Every function and operator in Flink can be stateful (see working with state for details). Stateful functions store data across the processing of individual elements/events, making state a critical building block for any type of more elaborate operation.
In order to make state fault tolerant, Flink needs to checkpoint the state. Checkpoints allow Flink to recover state and positions in the streams to give the application the same semantics as a failure-free execution.
The documentation on streaming fault tolerance describes in detail the technique behind Flink’s streaming fault tolerance mechanism.
Flink’s checkpointing mechanism interacts with durable storage for streams and state. In general, it requires:
By default, checkpointing is disabled. To enable checkpointing, call
enableCheckpointing(n) on the
StreamExecutionEnvironment, where n is the checkpoint interval in milliseconds.
Other parameters for checkpointing include:
exactly-once vs. at-least-once: You can optionally pass a mode to the
enableCheckpointing(n) method to choose between the two guarantee levels.
Exactly-once is preferable for most applications. At-least-once may be relevant for certain super-low-latency (consistently few milliseconds) applications.
checkpoint timeout: The time after which a checkpoint-in-progress is aborted, if it did not complete by then.
minimum time between checkpoints: To make sure that the streaming application makes a certain amount of progress between checkpoints, one can define how much time needs to pass between checkpoints. If this value is set for example to 5000, the next checkpoint will be started no sooner than 5 seconds after the previous checkpoint completed, regardless of the checkpoint duration and the checkpoint interval. Note that this implies that the checkpoint interval will never be smaller than this parameter.
It is often easier to configure applications by defining the “time between checkpoints” than the checkpoint interval, because the “time between checkpoints” is not susceptible to the fact that checkpoints may sometimes take longer than on average (for example if the target storage system is temporarily slow).
Note that this value also implies that the number of concurrent checkpoints is one.
number of concurrent checkpoints: By default, the system will not trigger another checkpoint while one is still in progress. This ensures that the topology does not spend too much time on checkpoints and not make progress with processing the streams. It is possible to allow for multiple overlapping checkpoints, which is interesting for pipelines that have a certain processing delay (for example because the functions call external services that need some time to respond) but that still want to do very frequent checkpoints (100s of milliseconds) to re-process very little upon failures.
This option cannot be used when a minimum time between checkpoints is defined.
externalized checkpoints: You can configure periodic checkpoints to be persisted externally. Externalized checkpoints write their meta data out to persistent storage and are not automatically cleaned up when the job fails. This way, you will have a checkpoint around to resume from if your job fails. There are more details in the deployment notes on externalized checkpoints.
fail/continue task on checkpoint errors: This determines if a task will be failed if an error occurs in the execution of the task’s checkpoint procedure. This is the default behaviour. Alternatively, when this is disabled, the task will simply decline the checkpoint to the checkpoint coordinator and continue running.
Some more parameters and/or defaults may be set via
conf/flink-conf.yaml (see configuration for a full guide):
|(none)||The state backend to be used to store and checkpoint state.|
|true||Option whether the state backend should use an asynchronous snapshot method where possible and configurable. Some state backends may not support asynchronous snapshots, or only support asynchronous snapshots, and ignore this option.|
|1024||The minimum size of state data files. All state chunks smaller than that are stored inline in the root checkpoint metadata file.|
|false||Option whether the state backend should create incremental checkpoints, if possible. For an incremental checkpoint, only a diff from the previous checkpoint is stored, rather than the complete checkpoint state. Some state backends may not support incremental checkpoints and ignore this option.|
|(none)||The default directory used for storing the data files and meta data of checkpoints in a Flink supported filesystem. The storage path must be accessible from all participating processes/nodes(i.e. all TaskManagers and JobManagers).|
|1||The maximum number of completed checkpoints to retain.|
|(none)||The default directory for savepoints. Used by the state backends that write savepoints to file systems (MemoryStateBackend, FsStateBackend, RocksDBStateBackend).|
Flink’s checkpointing mechanism stores consistent snapshots of all the state in timers and stateful operators, including connectors, windows, and any user-defined state. Where the checkpoints are stored (e.g., JobManager memory, file system, database) depends on the configured State Backend.
By default, state is kept in memory in the TaskManagers and checkpoints are stored in memory in the JobManager. For proper persistence of large state,
Flink supports various approaches for storing and checkpointing state in other state backends. The choice of state backend can be configured via
See state backends for more details on the available state backends and options for job-wide and cluster-wide configuration.
Flink currently only provides processing guarantees for jobs without iterations. Enabling checkpointing on an iterative job causes an exception. In order to force checkpointing on an iterative program the user needs to set a special flag when enabling checkpointing:
env.enableCheckpointing(interval, force = true).
Please note that records in flight in the loop edges (and the state changes associated with them) will be lost during failure.
Flink supports different restart strategies which control how the jobs are restarted in case of a failure. For more information, see Restart Strategies.