Configuration

All configuration can be set in Flink configuration file in the conf/ directory (see Flink Configuration File).

The configuration is parsed and evaluated when the Flink processes are started. Changes to the configuration file require restarting the relevant processes.

The out of the box configuration will use your default Java installation. You can manually set the environment variable JAVA_HOME or the configuration key env.java.home in Flink configuration file if you want to manually override the Java runtime to use. Note that the configuration key env.java.home must be specified in a flattened format (i.e. one-line key-value format) in the configuration file.

You can specify a different configuration directory location by defining the FLINK_CONF_DIR environment variable. For resource providers which provide non-session deployments, you can specify per-job configurations this way. Make a copy of the conf directory from the Flink distribution and modify the settings on a per-job basis. Note that this is not supported in Docker or standalone Kubernetes deployments. On Docker-based deployments, you can use the FLINK_PROPERTIES environment variable for passing configuration values.

On session clusters, the provided configuration will only be used for configuring execution parameters, e.g. configuration parameters affecting the job, not the underlying cluster.

Flink Configuration File

Starting with version 1.19, Flink has officially introduced full support for the standard YAML 1.2 syntax. Compared to the previous versions which only supported simple key-value pairs, this update provides users with more flexible and powerful configuration capabilities. To take advantage of this new feature, users need to use the newly introduced config.yaml configuration file. The existing flink-conf.yaml configuration file is deprecated and will no longer work in the upcoming version 2.0. To ensure a smooth transition, users are advised to migrate their existing Flink configuration to the new configuration file as soon as possible.

This section will help users understand how to configure the Flink cluster and jobs through the config.yaml configuration file, as well as how to migrate old configuration to the new configuration file.

Usage

Starting from Flink-1.19, the default configuration file has been changed to config.yaml and placed in the conf/ directory. Users should directly modify this file to configure Flink.

To continue using the legacy configuration file flink-conf.yaml, users just need to copy this file into the conf/ directory. Once the legacy configuration file flink-conf.yaml is detected, Flink will prioritize using it as the configuration file.

The usage for config.yaml is as follows:

Config Key

  • Users can organize Config Keys in a nested format, such as:
  1. restart-strategy:
  2. type: failure-rate
  3. failure-rate:
  4. delay: 1 s
  5. failure-rate-interval: 1 min
  6. max-failures-per-interval: 1
  • Users can also organize Config Keys in a flatten format, such as:
  1. restart-strategy.type: failure-rate
  2. restart-strategy.failure-rate.delay: 1 s
  3. restart-strategy.failure-rate.failure-rate-interval: 1 min
  4. restart-strategy.failure-rate.max-failures-per-interval: 1

Config Value

The config.yaml configuration file allows users to configure values following the YAML 1.2 core schema. Users can configure the values corresponding to the Config Type in the following format:

Config TypeFormat Reference
Integer
Regular expression: [-+]? [0-9]+

Example: 100
Long
Regular expression: [-+]? [0-9]+

Example: 100
Float
Regular expression: [-+]? ( . [0-9]+ | [0-9]+ ( . [0-9] )? ) ( [eE] [-+]? [0-9]+ )?

Example: 100.1
Double
Regular expression: [-+]? ( . [0-9]+ | [0-9]+ ( . [0-9] )? ) ( [eE] [-+]? [0-9]+ )?

Example: 100.1
Boolean
Regular expression: true | True | TRUE | false | False | FALSE

Example: true
String
Any character

Note: If the value contains special characters used in YAML, it is necessary to use single or double quotes to escape these characters.
Map<String, String>
  • Flow Style:
    • Description: Enclosed with curly braces “{}” and pairs are separated by a comma “,”. Within the mapping, key and value are separated by a colon “:” followed by a space.
    • Example: {k1: v1, k2: v2}
  • Block Style:
    • Description: Uses indentation to represent the hierarchical structure of the data, with keys and values separated by a colon “:” and a space.
    • Example:
      1. k1: v1
        k2: v2
  • Flink Legacy Map Pattern:
    • Description: Pairs are separated by a comma “,”. Within the mapping, keys and values are separated by a colon “:”.
    • Example: k1:v1,k2:v2
Note: For values containing special characters, consider escaping them; details can be found in the description of Config Type: String.
List
  • Flow Style:
    • Description: Enclosed within square brackets “[]” and list items are separated by a comma “,”.
    • Example: [a, b, c]
  • Block Style:
    • Description: Uses indentation and a dash “-“ to denote list items.
    • Example:
      1. - a
        - b
        - c
  • Flink Legacy Map Pattern:
    • Description: List items are separated by a semicolon “;”.
    • Example: a;b;c
Note: For values containing special characters, consider escaping them; details can be found in the description of Config Type: String.
MemorySize
Regular expression: [0-9]+ (b | kb | kibibytes | m | mb | mebibytes | g | gb | gibibytes | t | tb | tebibytes)?

Example: 100 mb
Duration
Regular expression: [0-9]+ (d | day | h | hour | m | min | minute | s | sec | second | ms | milli | millisecond | us | micro | microsecond | ns | nano | nanosecond)?

Example: 10 s
Enum
Enum Constants

Additionally, users can configure the value for all Config Types as strings by simply enclosing the original value in single quotes or double quotes.

Behavior Changes

config.yaml strictly follows the YAML 1.2 syntax and is compatible with flink-conf.yaml in most cases, except for the following behavior changes:

  • Null value:

    • flink-conf.yaml: Only supports leaving the value blank.
    • config.yaml: Supports leaving it blank, or explicitly set it to null, Null, NULL, or ~.
  • Comment:

    • flink-conf.yaml: Everything after the first occurrence of # in each line is considered a comment.
    • config.yaml: When there is at least one space between the # and the preceding content, or when the # is at the beginning of a line, the subsequent content is considered a comment.
  • Special character escaping in strings:

    • flink-conf.yaml: Only needs to escape elements in Lists and Maps.
      • List elements containing a semicolon “;” require escaping.
      • Map elements containing a comma “,” or colon “:” require escaping.
    • config.yaml: Requires escaping special characters as defined in the YAML 1.2 specification; see the definition of special characters.
  • Duplicated keys:

    • flink-conf.yaml: Allows duplicated keys and takes the last key-value pair for the corresponding key that appears in the file.
    • config.yaml: Does not allow duplicated keys, and an error will be reported when loading the configuration.
  • Handling of invalid configuration:

    • flink-conf.yaml: Invalid key-value pairs will be ignored.
    • config.yaml: An error will be reported when loading the configuration.

Migration Tool

To facilitate user migration, Flink provides a configuration file migration script that can automate the migration process. The usage is as follows:

  • Place the old configuration file flink-conf.yaml in the conf/ directory.
  • Execute the following command in the $FLINK_HOME/ directory:
  1. bin/migrate-config-file.sh

After running the command above, the migration script will automatically read the old configuration file flink-conf.yaml from the conf/ directory and output the migrated results to the new configuration file config.yaml in the conf/ directory. Note that due to the limitation of the legacy configuration parser, all values in flink-conf.yaml will be recognized as String type, so the values in the generated config.yaml file will also be of String type, which means some values will be enclosed in quotes. However, Flink will convert them to the actual types defined using ConfigOption during subsequent configuration parsing.

Additionally, users need to delete the flink-conf.yaml file in the conf/ directory after migration to make the config.yaml file take effect.

Basic Setup

The default configuration supports starting a single-node Flink session cluster without any changes. The options in this section are the ones most commonly needed for a basic distributed Flink setup.

Hostnames / Ports

These options are only necessary for standalone application- or session deployments (simple standalone or Kubernetes).

If you use Flink with Yarn or the active Kubernetes integration, the hostnames and ports are automatically discovered.

  • rest.address, rest.port: These are used by the client to connect to Flink. Set this to the hostname where the JobManager runs, or to the hostname of the (Kubernetes) service in front of the JobManager’s REST interface.

  • The jobmanager.rpc.address (defaults to “localhost”) and jobmanager.rpc.port (defaults to 6123) config entries are used by the TaskManager to connect to the JobManager/ResourceManager. Set this to the hostname where the JobManager runs, or to the hostname of the (Kubernetes internal) service for the JobManager. This option is ignored on setups with high-availability where the leader election mechanism is used to discover this automatically.

Memory Sizes

The default memory sizes support simple streaming/batch applications, but are too low to yield good performance for more complex applications.

  • jobmanager.memory.process.size: Total size of the JobManager (JobMaster / ResourceManager / Dispatcher) process.
  • taskmanager.memory.process.size: Total size of the TaskManager process.

The total sizes include everything. Flink will subtract some memory for the JVM’s own memory requirements (metaspace and others), and divide and configure the rest automatically between its components (JVM Heap, Off-Heap, for Task Managers also network, managed memory etc.).

These values are configured as memory sizes, for example 1536m or 2g.

Parallelism

  • taskmanager.numberOfTaskSlots: The number of slots that a TaskManager offers (default: 1). Each slot can take one task or pipeline. Having multiple slots in a TaskManager can help amortize certain constant overheads (of the JVM, application libraries, or network connections) across parallel tasks or pipelines. See the Task Slots and Resources concepts section for details.

    Running more smaller TaskManagers with one slot each is a good starting point and leads to the best isolation between tasks. Dedicating the same resources to fewer larger TaskManagers with more slots can help to increase resource utilization, at the cost of weaker isolation between the tasks (more tasks share the same JVM).

  • parallelism.default: The default parallelism used when no parallelism is specified anywhere (default: 1).

Checkpointing

You can configure checkpointing directly in code within your Flink job or application. Putting these values here in the configuration defines them as defaults in case the application does not configure anything.

  • state.backend.type: The state backend to use. This defines the data structure mechanism for taking snapshots. Common values are hashmap or rocksdb.
  • execution.checkpointing.dir: The directory to write checkpoints to. This takes a path URI like s3://mybucket/flink-app/checkpoints or hdfs://namenode:port/flink/checkpoints.
  • execution.checkpointing.savepoint-dir: The default directory for savepoints. Takes a path URI, similar to execution.checkpointing.dir.
  • execution.checkpointing.interval: The base interval setting. To enable checkpointing, you need to set this value larger than 0.

Web UI

  • web.submit.enable: Enables uploading and starting jobs through the Flink UI (true by default). Please note that even when this is disabled, session clusters still accept jobs through REST requests (HTTP calls). This flag only guards the feature to upload jobs in the UI.
  • web.cancel.enable: Enables canceling jobs through the Flink UI (true by default). Please note that even when this is disabled, session clusters still cancel jobs through REST requests (HTTP calls). This flag only guards the feature to cancel jobs in the UI.
  • web.upload.dir: The directory where to store uploaded jobs. Only used when web.submit.enable is true.
  • web.exception-history-size: Sets the size of the exception history that prints the most recent failures that were handled by Flink for a job.

Other

  • io.tmp.dirs: The directories where Flink puts local data, defaults to the system temp directory (java.io.tmpdir property). If a list of directories is configured, Flink will rotate files across the directories.

    The data put in these directories include by default the files created by RocksDB, spilled intermediate results (batch algorithms), and cached jar files.

    This data is NOT relied upon for persistence/recovery, but if this data gets deleted, it typically causes a heavyweight recovery operation. It is hence recommended to set this to a directory that is not automatically periodically purged.

    Yarn and Kubernetes setups automatically configure this value to the local working directories by default.



Common Setup Options

Common options to configure your Flink application or cluster.

Hosts and Ports

Options to configure hostnames and ports for the different Flink components.

The JobManager hostname and port are only relevant for standalone setups without high-availability. In that setup, the config values are used by the TaskManagers to find (and connect to) the JobManager. In all highly-available setups, the TaskManagers discover the JobManager via the High-Availability-Service (for example ZooKeeper).

Setups using resource orchestration frameworks (K8s, Yarn) typically use the framework’s service discovery facilities.

You do not need to configure any TaskManager hosts and ports, unless the setup requires the use of specific port ranges or specific network interfaces to bind to.

KeyDefaultTypeDescription
jobmanager.bind-host
(none)StringThe local address of the network interface that the job manager binds to. If not configured, ‘0.0.0.0’ will be used.
jobmanager.rpc.address
(none)StringThe config parameter defining the network address to connect to for communication with the job manager. This value is only interpreted in setups where a single JobManager with static name or address exists (simple standalone setups, or container setups with dynamic service name resolution). It is not used in many high-availability setups, when a leader-election service (like ZooKeeper) is used to elect and discover the JobManager leader from potentially multiple standby JobManagers.
jobmanager.rpc.bind-port
(none)IntegerThe local RPC port that the JobManager binds to. If not configured, the external port (configured by ‘jobmanager.rpc.port’) will be used.
jobmanager.rpc.port
6123IntegerThe config parameter defining the network port to connect to for communication with the job manager. Like jobmanager.rpc.address, this value is only interpreted in setups where a single JobManager with static name/address and port exists (simple standalone setups, or container setups with dynamic service name resolution). This config option is not used in many high-availability setups, when a leader-election service (like ZooKeeper) is used to elect and discover the JobManager leader from potentially multiple standby JobManagers.
metrics.internal.query-service.port
“0”StringThe port range used for Flink’s internal metric query service. Accepts a list of ports (“50100,50101”), ranges(“50100-50200”) or a combination of both. It is recommended to set a range of ports to avoid collisions when multiple Flink components are running on the same machine. Per default Flink will pick a random port.
rest.address
(none)StringThe address that should be used by clients to connect to the server. Attention: This option is respected only if the high-availability configuration is NONE.
rest.bind-address
(none)StringThe address that the server binds itself.
rest.bind-port
“8081”StringThe port that the server binds itself. Accepts a list of ports (“50100,50101”), ranges (“50100-50200”) or a combination of both. It is recommended to set a range of ports to avoid collisions when multiple Rest servers are running on the same machine.
rest.path
(none)StringThe path that should be used by clients to interact to the server which is accessible via URL.
rest.port
8081IntegerThe port that the client connects to. If rest.bind-port has not been specified, then the REST server will bind to this port. Attention: This option is respected only if the high-availability configuration is NONE.
taskmanager.bind-host
(none)StringThe local address of the network interface that the task manager binds to. If not configured, ‘0.0.0.0’ will be used.
taskmanager.collect-sink.port
0IntegerThe port used for the client to retrieve query results from the TaskManager. The default value is 0, which corresponds to a random port assignment.
taskmanager.data.bind-port
(none)StringThe task manager’s bind port used for data exchange operations. Also accepts a list of ports (“50100,50101”), ranges (“50100-50200”) or a combination of both. If not configured, ‘taskmanager.data.port’ will be used.
taskmanager.data.port
0IntegerThe task manager’s external port used for data exchange operations.
taskmanager.host
(none)StringThe external address of the network interface where the TaskManager is exposed. Because different TaskManagers need different values for this option, usually it is specified in an additional non-shared TaskManager-specific config file.
taskmanager.rpc.bind-port
(none)IntegerThe local RPC port that the TaskManager binds to. If not configured, the external port (configured by ‘taskmanager.rpc.port’) will be used.
taskmanager.rpc.port
“0”StringThe external RPC port where the TaskManager is exposed. Accepts a list of ports (“50100,50101”), ranges (“50100-50200”) or a combination of both. It is recommended to set a range of ports to avoid collisions when multiple TaskManagers are running on the same machine.

Fault Tolerance

These configuration options control Flink’s restart behaviour in case of failures during the execution. By configuring these options in your flink-conf.yaml, you define the cluster’s default restart strategy.

The default restart strategy will only take effect if no job specific restart strategy has been configured via the ExecutionConfig.

KeyDefaultTypeDescription
restart-strategy.type
(none)StringDefines the restart strategy to use in case of job failures.
Accepted values are:
  • disable, off, none: No restart strategy.
  • fixed-delay, fixeddelay: Fixed delay restart strategy. More details can be found here.
  • failure-rate, failurerate: Failure rate restart strategy. More details can be found here.
  • exponential-delay, exponentialdelay: Exponential delay restart strategy. More details can be found here.
If checkpointing is disabled, the default value is disable. If checkpointing is enabled, the default value is exponential-delay, and the default values of exponential-delay related config options will be used.

Fixed Delay Restart Strategy

KeyDefaultTypeDescription
restart-strategy.fixed-delay.attempts
1IntegerThe number of times that Flink retries the execution before the job is declared as failed if restart-strategy.type has been set to fixed-delay.
restart-strategy.fixed-delay.delay
1 sDurationDelay between two consecutive restart attempts if restart-strategy.type has been set to fixed-delay. Delaying the retries can be helpful when the program interacts with external systems where for example connections or pending transactions should reach a timeout before re-execution is attempted. It can be specified using notation: “1 min”, “20 s”

Exponential Delay Restart Strategy

KeyDefaultTypeDescription
restart-strategy.exponential-delay.attempts-before-reset-backoff
infiniteIntegerThe number of times that Flink retries the execution before failing the job if restart-strategy.type has been set to exponential-delay. The number will be reset once the backoff is reset to its initial value.
restart-strategy.exponential-delay.backoff-multiplier
1.5DoubleBackoff value is multiplied by this value after every failure,until max backoff is reached if restart-strategy.type has been set to exponential-delay.
restart-strategy.exponential-delay.initial-backoff
1 sDurationStarting duration between restarts if restart-strategy.type has been set to exponential-delay. It can be specified using notation: “1 min”, “20 s”
restart-strategy.exponential-delay.jitter-factor
0.1DoubleJitter specified as a portion of the backoff if restart-strategy.type has been set to exponential-delay. It represents how large random value will be added or subtracted to the backoff. Useful when you want to avoid restarting multiple jobs at the same time.
restart-strategy.exponential-delay.max-backoff
1 minDurationThe highest possible duration between restarts if restart-strategy.type has been set to exponential-delay. It can be specified using notation: “1 min”, “20 s”
restart-strategy.exponential-delay.reset-backoff-threshold
1 hDurationThreshold when the backoff is reset to its initial value if restart-strategy.type has been set to exponential-delay. It specifies how long the job must be running without failure to reset the exponentially increasing backoff to its initial value. It can be specified using notation: “1 min”, “20 s”

Failure Rate Restart Strategy

KeyDefaultTypeDescription
restart-strategy.failure-rate.delay
1 sDurationDelay between two consecutive restart attempts if restart-strategy.type has been set to failure-rate. It can be specified using notation: “1 min”, “20 s”
restart-strategy.failure-rate.failure-rate-interval
1 minDurationTime interval for measuring failure rate if restart-strategy.type has been set to failure-rate. It can be specified using notation: “1 min”, “20 s”
restart-strategy.failure-rate.max-failures-per-interval
1IntegerMaximum number of restarts in given time interval before failing a job if restart-strategy.type has been set to failure-rate.

Retryable Cleanup

After jobs reach a globally-terminal state, a cleanup of all related resources is performed. This cleanup can be retried in case of failure. Different retry strategies can be configured to change this behavior:

KeyDefaultTypeDescription
cleanup-strategy.type
“exponential-delay”StringDefines the cleanup strategy to use in case of cleanup failures.
Accepted values are:
  • none, disable, off: Cleanup is only performed once. No retry will be initiated in case of failure. The job artifacts (and the job’s JobResultStore entry) have to be cleaned up manually in case of a failure.
  • fixed-delay, fixeddelay: Cleanup attempts will be separated by a fixed interval up to the point where the cleanup is considered successful or a set amount of retries is reached. Reaching the configured limit means that the job artifacts (and the job’s JobResultStore entry) might need to be cleaned up manually.
  • exponential-delay, exponentialdelay: Exponential delay restart strategy triggers the cleanup with an exponentially increasing delay up to the point where the cleanup succeeded or a set amount of retries is reached. Reaching the configured limit means that the job artifacts (and the job’s JobResultStore entry) might need to be cleaned up manually.
The default configuration relies on an exponentially delayed retry strategy with the given default values.

Fixed-Delay Cleanup Retry Strategy

KeyDefaultTypeDescription
cleanup-strategy.fixed-delay.attempts
infiniteIntegerThe number of times that Flink retries the cleanup before giving up if cleanup-strategy.type has been set to fixed-delay. Reaching the configured limit means that the job artifacts (and the job’s JobResultStore entry) might need to be cleaned up manually.
cleanup-strategy.fixed-delay.delay
1 minDurationAmount of time that Flink waits before re-triggering the cleanup after a failed attempt if the cleanup-strategy.type is set to fixed-delay. It can be specified using the following notation: “1 min”, “20 s”

Exponential-Delay Cleanup Retry Strategy

KeyDefaultTypeDescription
cleanup-strategy.exponential-delay.attempts
infiniteIntegerThe number of times a failed cleanup is retried if cleanup-strategy.type has been set to exponential-delay. Reaching the configured limit means that the job artifacts (and the job’s JobResultStore entry) might need to be cleaned up manually.
cleanup-strategy.exponential-delay.initial-backoff
1 sDurationStarting duration between cleanup retries if cleanup-strategy.type has been set to exponential-delay. It can be specified using the following notation: “1 min”, “20 s”
cleanup-strategy.exponential-delay.max-backoff
1 hDurationThe highest possible duration between cleanup retries if cleanup-strategy.type has been set to exponential-delay. It can be specified using the following notation: “1 min”, “20 s”

Checkpoints and State Backends

These options control the basic setup of state backends and checkpointing behavior.

The options are only relevant for jobs/applications executing in a continuous streaming fashion. Jobs/applications executing in a batch fashion do not use state backends and checkpoints, but different internal data structures that are optimized for batch processing.

State Backends

KeyDefaultTypeDescription
state.backend.type
“hashmap”StringThe state backend to be used to store state.
The implementation can be specified either via their shortcut name, or via the class name of a StateBackendFactory. If a factory is specified it is instantiated via its zero argument constructor and its StateBackendFactory#createFromConfig(ReadableConfig, ClassLoader) method is called.
Recognized shortcut names are ‘hashmap’ and ‘rocksdb’.

Checkpoints

KeyDefaultTypeDescription
execution.checkpointing.storage
(none)StringThe checkpoint storage implementation to be used to checkpoint state.
The implementation can be specified either via their shortcut name, or via the class name of a CheckpointStorageFactory. If a factory is specified it is instantiated via its zero argument constructor and its CheckpointStorageFactory#createFromConfig(ReadableConfig, ClassLoader) method is called.
Recognized shortcut names are ‘jobmanager’ and ‘filesystem’.
‘execution.checkpointing.storage’ and ‘execution.checkpointing.dir’ are usually combined to configure the checkpoint location. By default, the checkpoint meta data and actual program state will be stored in the JobManager’s memory directly. When ‘execution.checkpointing.storage’ is set to ‘jobmanager’, if ‘execution.checkpointing.dir’ is configured, the meta data of checkpoints will be persisted to the path specified by ‘execution.checkpointing.dir’. Otherwise, the meta data will be stored in the JobManager’s memory. When ‘execution.checkpointing.storage’ is set to ‘filesystem’, a valid path must be configured to ‘execution.checkpointing.dir’, and the checkpoint meta data and actual program state will both be persisted to the path.
execution.checkpointing.dir
(none)StringThe 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). If the ‘execution.checkpointing.storage’ is set to ‘jobmanager’, only the meta data of checkpoints will be stored in this directory.
execution.checkpointing.savepoint-dir
(none)StringThe default directory for savepoints. Used by the state backends that write savepoints to file systems (HashMapStateBackend, EmbeddedRocksDBStateBackend).
execution.checkpointing.cleaner.parallel-mode
trueBooleanOption whether to discard a checkpoint’s states in parallel using the ExecutorService passed into the cleaner
execution.checkpointing.incremental
falseBooleanOption whether to create incremental checkpoints, if possible. For an incremental checkpoint, only a diff from the previous checkpoint is stored, rather than the complete checkpoint state. Once enabled, the state size shown in web UI or fetched from rest API only represents the delta checkpoint size instead of full checkpoint size. Some state backends may not support incremental checkpoints and ignore this option.
execution.checkpointing.local-backup.dirs
(none)StringThe config parameter defining the root directories for storing file-based state for local recovery. Local recovery currently only covers keyed state backends. If not configured it will default to <WORKING_DIR>/localState. The <WORKING_DIR> can be configured via process.taskmanager.working-dir
execution.checkpointing.local-backup.enabled
falseBooleanThis option configures local backup for the state backend, which indicates whether to make backup checkpoint on local disk. If not configured, fallback to execution.state-recovery.from-local. By default, local backup is deactivated. Local backup currently only covers keyed state backends (including both the EmbeddedRocksDBStateBackend and the HashMapStateBackend).
execution.checkpointing.num-retained
1IntegerThe maximum number of completed checkpoints to retain.

High Availability

High-availability here refers to the ability of the JobManager process to recover from failures.

The JobManager ensures consistency during recovery across TaskManagers. For the JobManager itself to recover consistently, an external service must store a minimal amount of recovery metadata (like “ID of last committed checkpoint”), as well as help to elect and lock which JobManager is the leader (to avoid split-brain situations).

KeyDefaultTypeDescription
high-availability.type
“NONE”StringDefines high-availability mode used for cluster execution. To enable high-availability, set this mode to “ZOOKEEPER”, “KUBERNETES”, or specify the fully qualified name of the factory class.
high-availability.cluster-id
“/default”StringThe ID of the Flink cluster, used to separate multiple Flink clusters from each other. Needs to be set for standalone clusters but is automatically inferred in YARN.
high-availability.storageDir
(none)StringFile system path (URI) where Flink persists metadata in high-availability setups.

Options for the JobResultStore in high-availability setups

KeyDefaultTypeDescription
job-result-store.delete-on-commit
trueBooleanDetermines whether job results should be automatically removed from the underlying job result store when the corresponding entity transitions into a clean state. If false, the cleaned job results are, instead, marked as clean to indicate their state. In this case, Flink no longer has ownership and the resources need to be cleaned up by the user.
job-result-store.storage-path
(none)StringDefines where job results should be stored. This should be an underlying file-system that provides read-after-write consistency. By default, this is {high-availability.storageDir}/job-result-store/{high-availability.cluster-id}.

Options for high-availability setups with ZooKeeper

KeyDefaultTypeDescription
high-availability.zookeeper.path.root
“/flink”StringThe root path under which Flink stores its entries in ZooKeeper.
high-availability.zookeeper.quorum
(none)StringThe ZooKeeper quorum to use, when running Flink in a high-availability mode with ZooKeeper.

Memory Configuration

These configuration values control the way that TaskManagers and JobManagers use memory.

Flink tries to shield users as much as possible from the complexity of configuring the JVM for data-intensive processing. In most cases, users should only need to set the values taskmanager.memory.process.size or taskmanager.memory.flink.size (depending on how the setup), and possibly adjusting the ratio of JVM heap and Managed Memory via taskmanager.memory.managed.fraction. The other options below can be used for performance tuning and fixing memory related errors.

For a detailed explanation of how these options interact, see the documentation on TaskManager and JobManager memory configurations.

KeyDefaultTypeDescription
jobmanager.memory.enable-jvm-direct-memory-limit
falseBooleanWhether to enable the JVM direct memory limit of the JobManager process (-XX:MaxDirectMemorySize). The limit will be set to the value of ‘jobmanager.memory.off-heap.size’ option.
jobmanager.memory.flink.size
(none)MemorySizeTotal Flink Memory size for the JobManager. This includes all the memory that a JobManager consumes, except for JVM Metaspace and JVM Overhead. It consists of JVM Heap Memory and Off-heap Memory. See also ‘jobmanager.memory.process.size’ for total process memory size configuration.
jobmanager.memory.heap.size
(none)MemorySizeJVM Heap Memory size for JobManager. The minimum recommended JVM Heap size is 128.000mb (134217728 bytes).
jobmanager.memory.jvm-metaspace.size
256 mbMemorySizeJVM Metaspace Size for the JobManager.
jobmanager.memory.jvm-overhead.fraction
0.1FloatFraction of Total Process Memory to be reserved for JVM Overhead. This is off-heap memory reserved for JVM overhead, such as thread stack space, compile cache, etc. This includes native memory but not direct memory, and will not be counted when Flink calculates JVM max direct memory size parameter. The size of JVM Overhead is derived to make up the configured fraction of the Total Process Memory. If the derived size is less or greater than the configured min or max size, the min or max size will be used. The exact size of JVM Overhead can be explicitly specified by setting the min and max size to the same value.
jobmanager.memory.jvm-overhead.max
1 gbMemorySizeMax JVM Overhead size for the JobManager. This is off-heap memory reserved for JVM overhead, such as thread stack space, compile cache, etc. This includes native memory but not direct memory, and will not be counted when Flink calculates JVM max direct memory size parameter. The size of JVM Overhead is derived to make up the configured fraction of the Total Process Memory. If the derived size is less or greater than the configured min or max size, the min or max size will be used. The exact size of JVM Overhead can be explicitly specified by setting the min and max size to the same value.
jobmanager.memory.jvm-overhead.min
192 mbMemorySizeMin JVM Overhead size for the JobManager. This is off-heap memory reserved for JVM overhead, such as thread stack space, compile cache, etc. This includes native memory but not direct memory, and will not be counted when Flink calculates JVM max direct memory size parameter. The size of JVM Overhead is derived to make up the configured fraction of the Total Process Memory. If the derived size is less or greater than the configured min or max size, the min or max size will be used. The exact size of JVM Overhead can be explicitly specified by setting the min and max size to the same value.
jobmanager.memory.off-heap.size
128 mbMemorySizeOff-heap Memory size for JobManager. This option covers all off-heap memory usage including direct and native memory allocation. The JVM direct memory limit of the JobManager process (-XX:MaxDirectMemorySize) will be set to this value if the limit is enabled by ‘jobmanager.memory.enable-jvm-direct-memory-limit’.
jobmanager.memory.process.size
(none)MemorySizeTotal Process Memory size for the JobManager. This includes all the memory that a JobManager JVM process consumes, consisting of Total Flink Memory, JVM Metaspace, and JVM Overhead. In containerized setups, this should be set to the container memory. See also ‘jobmanager.memory.flink.size’ for Total Flink Memory size configuration.
taskmanager.memory.flink.size
(none)MemorySizeTotal Flink Memory size for the TaskExecutors. This includes all the memory that a TaskExecutor consumes, except for JVM Metaspace and JVM Overhead. It consists of Framework Heap Memory, Task Heap Memory, Task Off-Heap Memory, Managed Memory, and Network Memory. See also ‘taskmanager.memory.process.size’ for total process memory size configuration.
taskmanager.memory.framework.heap.size
128 mbMemorySizeFramework Heap Memory size for TaskExecutors. This is the size of JVM heap memory reserved for TaskExecutor framework, which will not be allocated to task slots.
taskmanager.memory.framework.off-heap.batch-shuffle.size
64 mbMemorySizeSize of memory used by batch shuffle for shuffle data read (currently only used by sort-shuffle and hybrid shuffle). Notes: 1) The memory is cut from ‘taskmanager.memory.framework.off-heap.size’ so must be smaller than that, which means you may also need to increase ‘taskmanager.memory.framework.off-heap.size’ after you increase this config value; 2) This memory size can influence the shuffle performance and you can increase this config value for large-scale batch jobs (for example, to 128M or 256M).
taskmanager.memory.framework.off-heap.size
128 mbMemorySizeFramework Off-Heap Memory size for TaskExecutors. This is the size of off-heap memory (JVM direct memory and native memory) reserved for TaskExecutor framework, which will not be allocated to task slots. The configured value will be fully counted when Flink calculates the JVM max direct memory size parameter.
taskmanager.memory.jvm-metaspace.size
256 mbMemorySizeJVM Metaspace Size for the TaskExecutors.
taskmanager.memory.jvm-overhead.fraction
0.1FloatFraction of Total Process Memory to be reserved for JVM Overhead. This is off-heap memory reserved for JVM overhead, such as thread stack space, compile cache, etc. This includes native memory but not direct memory, and will not be counted when Flink calculates JVM max direct memory size parameter. The size of JVM Overhead is derived to make up the configured fraction of the Total Process Memory. If the derived size is less/greater than the configured min/max size, the min/max size will be used. The exact size of JVM Overhead can be explicitly specified by setting the min/max size to the same value.
taskmanager.memory.jvm-overhead.max
1 gbMemorySizeMax JVM Overhead size for the TaskExecutors. This is off-heap memory reserved for JVM overhead, such as thread stack space, compile cache, etc. This includes native memory but not direct memory, and will not be counted when Flink calculates JVM max direct memory size parameter. The size of JVM Overhead is derived to make up the configured fraction of the Total Process Memory. If the derived size is less/greater than the configured min/max size, the min/max size will be used. The exact size of JVM Overhead can be explicitly specified by setting the min/max size to the same value.
taskmanager.memory.jvm-overhead.min
192 mbMemorySizeMin JVM Overhead size for the TaskExecutors. This is off-heap memory reserved for JVM overhead, such as thread stack space, compile cache, etc. This includes native memory but not direct memory, and will not be counted when Flink calculates JVM max direct memory size parameter. The size of JVM Overhead is derived to make up the configured fraction of the Total Process Memory. If the derived size is less/greater than the configured min/max size, the min/max size will be used. The exact size of JVM Overhead can be explicitly specified by setting the min/max size to the same value.
taskmanager.memory.managed.consumer-weights
OPERATOR:70,STATE_BACKEND:70,PYTHON:30MapManaged memory weights for different kinds of consumers. A slot’s managed memory is shared by all kinds of consumers it contains, proportionally to the kinds’ weights and regardless of the number of consumers from each kind. Currently supported kinds of consumers are OPERATOR (for built-in algorithms), STATE_BACKEND (for RocksDB state backend) and PYTHON (for Python processes).
taskmanager.memory.managed.fraction
0.4FloatFraction of Total Flink Memory to be used as Managed Memory, if Managed Memory size is not explicitly specified.
taskmanager.memory.managed.size
(none)MemorySizeManaged Memory size for TaskExecutors. This is the size of off-heap memory managed by the memory manager, reserved for sorting, hash tables, caching of intermediate results and RocksDB state backend. Memory consumers can either allocate memory from the memory manager in the form of MemorySegments, or reserve bytes from the memory manager and keep their memory usage within that boundary. If unspecified, it will be derived to make up the configured fraction of the Total Flink Memory.
taskmanager.memory.network.fraction
0.1FloatFraction of Total Flink Memory to be used as Network Memory. Network Memory is off-heap memory reserved for ShuffleEnvironment (e.g., network buffers). Network Memory size is derived to make up the configured fraction of the Total Flink Memory. If the derived size is less/greater than the configured min/max size, the min/max size will be used. The exact size of Network Memory can be explicitly specified by setting the min/max size to the same value.
taskmanager.memory.network.max
infiniteMemorySizeMax Network Memory size for TaskExecutors. Network Memory is off-heap memory reserved for ShuffleEnvironment (e.g., network buffers). Network Memory size is derived to make up the configured fraction of the Total Flink Memory. If the derived size is less/greater than the configured min/max size, the min/max size will be used. By default, the max limit of Network Memory is Long.MAX_VALUE. The exact size of Network Memory can be explicitly specified by setting the min/max to the same value.
taskmanager.memory.network.min
64 mbMemorySizeMin Network Memory size for TaskExecutors. Network Memory is off-heap memory reserved for ShuffleEnvironment (e.g., network buffers). Network Memory size is derived to make up the configured fraction of the Total Flink Memory. If the derived size is less/greater than the configured min/max size, the min/max size will be used. The exact size of Network Memory can be explicitly specified by setting the min/max to the same value.
taskmanager.memory.process.size
(none)MemorySizeTotal Process Memory size for the TaskExecutors. This includes all the memory that a TaskExecutor consumes, consisting of Total Flink Memory, JVM Metaspace, and JVM Overhead. On containerized setups, this should be set to the container memory. See also ‘taskmanager.memory.flink.size’ for total Flink memory size configuration.
taskmanager.memory.task.heap.size
(none)MemorySizeTask Heap Memory size for TaskExecutors. This is the size of JVM heap memory reserved for tasks. If not specified, it will be derived as Total Flink Memory minus Framework Heap Memory, Framework Off-Heap Memory, Task Off-Heap Memory, Managed Memory and Network Memory.
taskmanager.memory.task.off-heap.size
0 bytesMemorySizeTask Off-Heap Memory size for TaskExecutors. This is the size of off heap memory (JVM direct memory and native memory) reserved for tasks. The configured value will be fully counted when Flink calculates the JVM max direct memory size parameter.

Miscellaneous Options

KeyDefaultTypeDescription
fs.allowed-fallback-filesystems
(none)StringA (semicolon-separated) list of file schemes, for which Hadoop can be used instead of an appropriate Flink plugin. (example: s3;wasb)
fs.default-scheme
(none)StringThe default filesystem scheme, used for paths that do not declare a scheme explicitly. May contain an authority, e.g. host:port in case of an HDFS NameNode.
io.tmp.dirs
‘LOCAL_DIRS’ on Yarn. System.getProperty(“java.io.tmpdir”) in standalone.StringDirectories for temporary files, separated by”,”, “|”, or the system’s java.io.File.pathSeparator.


Security

Options for configuring Flink’s security and secure interaction with external systems.

SSL

Flink’s network connections can be secured via SSL. Please refer to the SSL Setup Docs for detailed setup guide and background.

KeyDefaultTypeDescription
security.ssl.algorithms
“TLS_RSA_WITH_AES_128_CBC_SHA”StringThe comma separated list of standard SSL algorithms to be supported. Read more here
security.ssl.internal.cert.fingerprint
(none)StringThe sha1 fingerprint of the internal certificate. This further protects the internal communication to present the exact certificate used by Flink.This is necessary where one cannot use private CA(self signed) or there is internal firm wide CA is required
security.ssl.internal.enabled
falseBooleanTurns on SSL for internal network communication. Optionally, specific components may override this through their own settings (rpc, data transport, REST, etc).
security.ssl.internal.key-password
(none)StringThe secret to decrypt the key in the keystore for Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.internal.keystore
(none)StringThe Java keystore file with SSL Key and Certificate, to be used Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.internal.keystore-password
(none)StringThe secret to decrypt the keystore file for Flink’s for Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.internal.keystore-type
JVM default keystore typeStringThe type of keystore for Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.internal.truststore
(none)StringThe truststore file containing the public CA certificates to verify the peer for Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.internal.truststore-password
(none)StringThe password to decrypt the truststore for Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.internal.truststore-type
JVM default keystore typeStringThe type of truststore for Flink’s internal endpoints (rpc, data transport, blob server).
security.ssl.protocol
“TLSv1.2”StringThe SSL protocol version to be supported for the ssl transport. Note that it doesn’t support comma separated list.
security.ssl.rest.authentication-enabled
falseBooleanTurns on mutual SSL authentication for external communication via the REST endpoints.
security.ssl.rest.cert.fingerprint
(none)StringThe sha1 fingerprint of the rest certificate. This further protects the rest REST endpoints to present certificate which is only used by proxy serverThis is necessary where once uses public CA or internal firm wide CA
security.ssl.rest.enabled
falseBooleanTurns on SSL for external communication via the REST endpoints.
security.ssl.rest.key-password
(none)StringThe secret to decrypt the key in the keystore for Flink’s external REST endpoints.
security.ssl.rest.keystore
(none)StringThe Java keystore file with SSL Key and Certificate, to be used Flink’s external REST endpoints.
security.ssl.rest.keystore-password
(none)StringThe secret to decrypt the keystore file for Flink’s for Flink’s external REST endpoints.
security.ssl.rest.keystore-type
JVM default keystore typeStringThe type of the keystore for Flink’s external REST endpoints.
security.ssl.rest.truststore
(none)StringThe truststore file containing the public CA certificates to verify the peer for Flink’s external REST endpoints.
security.ssl.rest.truststore-password
(none)StringThe password to decrypt the truststore for Flink’s external REST endpoints.
security.ssl.rest.truststore-type
JVM default keystore typeStringThe type of the truststore for Flink’s external REST endpoints.
security.ssl.verify-hostname
trueBooleanFlag to enable peer’s hostname verification during ssl handshake.

Auth with External Systems

Delegation token

Flink has a pluggable authentication protocol agnostic delegation token framework. Please refer to the Flink and Delegation Token Docs for further details.

KeyDefaultTypeDescription
security.delegation.tokens.enabled
trueBooleanIndicates whether to start delegation tokens system for external services.
security.delegation.tokens.renewal.retry.backoff
1 hDurationThe time period how long to wait before retrying to obtain new delegation tokens after a failure.
security.delegation.tokens.renewal.time-ratio
0.75DoubleRatio of the tokens’s expiration time when new credentials should be re-obtained.
security.delegation.token.provider.<serviceName>.enabled
trueBooleanControls whether to obtain credentials for services when security is enabled. By default, credentials for all supported services are retrieved when those services are configured, but it’s possible to disable that behavior if it somehow conflicts with the application being run.

ZooKeeper Authentication / Authorization

These options are necessary when connecting to a secured ZooKeeper quorum.

KeyDefaultTypeDescription
zookeeper.sasl.disable
falseBoolean
zookeeper.sasl.login-context-name
“Client”String
zookeeper.sasl.service-name
“zookeeper”String

Kerberos-based Authentication / Authorization

Please refer to the Flink and Kerberos Docs for a setup guide and a list of external system to which Flink can authenticate itself via Kerberos.

KeyDefaultTypeDescription
security.kerberos.access.hadoopFileSystems
(none)List<String>A semicolon-separated list of Kerberos-secured Hadoop filesystems Flink is going to access. For example, security.kerberos.access.hadoopFileSystems=hdfs://namenode2:9002;hdfs://namenode3:9003. The JobManager needs to have access to these filesystems to retrieve the security tokens.
security.kerberos.login.contexts
(none)StringA comma-separated list of login contexts to provide the Kerberos credentials to (for example, Client,KafkaClient to use the credentials for ZooKeeper authentication and for Kafka authentication)
security.kerberos.login.keytab
(none)StringAbsolute path to a Kerberos keytab file that contains the user credentials.
security.kerberos.login.principal
(none)StringKerberos principal name associated with the keytab.
security.kerberos.login.use-ticket-cache
trueBooleanIndicates whether to read from your Kerberos ticket cache.
security.kerberos.relogin.period
1 minDurationThe time period when keytab login happens automatically in order to always have a valid TGT.


Resource Orchestration Frameworks

This section contains options related to integrating Flink with resource orchestration frameworks, like Kubernetes, Yarn, etc.

Note that is not always necessary to integrate Flink with the resource orchestration framework. For example, you can easily deploy Flink applications on Kubernetes without Flink knowing that it runs on Kubernetes (and without specifying any of the Kubernetes config options here.) See this setup guide for an example.

The options in this section are necessary for setups where Flink itself actively requests and releases resources from the orchestrators.

YARN

KeyDefaultTypeDescription
external-resource.<resource_name>.yarn.config-key
(none)StringIf configured, Flink will add this key to the resource profile of container request to Yarn. The value will be set to the value of external-resource.<resource_name>.amount.
flink.hadoop.<key>
(none)StringA general option to probe Hadoop configuration through prefix ‘flink.hadoop.’. Flink will remove the prefix to get <key> (from core-default.xml and hdfs-default.xml) then set the <key> and value to Hadoop configuration. For example, flink.hadoop.dfs.replication=5 in Flink configuration and convert to dfs.replication=5 in Hadoop configuration.
flink.yarn.<key>
(none)StringA general option to probe Yarn configuration through prefix ‘flink.yarn.’. Flink will remove the prefix ‘flink.’ to get yarn.<key> (from yarn-default.xml) then set the yarn.<key> and value to Yarn configuration. For example, flink.yarn.resourcemanager.container.liveness-monitor.interval-ms=300000 in Flink configuration and convert to yarn.resourcemanager.container.liveness-monitor.interval-ms=300000 in Yarn configuration.
yarn.application-attempt-failures-validity-interval
10000LongTime window in milliseconds which defines the number of application attempt failures when restarting the AM. Failures which fall outside of this window are not being considered. Set this value to -1 in order to count globally. See here for more information.
yarn.application-attempts
(none)IntegerNumber of ApplicationMaster restarts. By default, the value will be set to 1. If high availability is enabled, then the default value will be 2. The restart number is also limited by YARN (configured via yarn.resourcemanager.am.max-attempts). Note that the entire Flink cluster will restart and the YARN Client will lose the connection.
yarn.application-master.port
“0”StringWith this configuration option, users can specify a port, a range of ports or a list of ports for the Application Master (and JobManager) RPC port. By default we recommend using the default value (0) to let the operating system choose an appropriate port. In particular when multiple AMs are running on the same physical host, fixed port assignments prevent the AM from starting. For example when running Flink on YARN on an environment with a restrictive firewall, this option allows specifying a range of allowed ports.
yarn.application.id
(none)StringThe YARN application id of the running yarn cluster. This is the YARN cluster where the pipeline is going to be executed.
yarn.application.name
(none)StringA custom name for your YARN application.
yarn.application.node-label
(none)StringSpecify YARN node label for the YARN application.
yarn.application.priority
-1IntegerA non-negative integer indicating the priority for submitting a Flink YARN application. It will only take effect if YARN priority scheduling setting is enabled. Larger integer corresponds with higher priority. If priority is negative or set to ‘-1’(default), Flink will unset yarn priority setting and use cluster default priority. Please refer to YARN’s official documentation for specific settings required to enable priority scheduling for the targeted YARN version.
yarn.application.queue
(none)StringThe YARN queue on which to put the current pipeline.
yarn.application.type
(none)StringA custom type for your YARN application..
yarn.appmaster.vcores
1IntegerThe number of virtual cores (vcores) used by YARN application master.
yarn.classpath.include-user-jar
ORDER

Enum

Defines whether user-jars are included in the system class path as well as their positioning in the path.

Possible values:
  • “DISABLED”: Exclude user jars from the system class path
  • “FIRST”: Position at the beginning
  • “LAST”: Position at the end
  • “ORDER”: Position based on the name of the jar
yarn.container-start-command-template
“%java% %jvmmem% %jvmopts% %logging% %class% %args% %redirects%”StringThis configuration parameter allows users to pass custom settings (such as JVM paths, arguments etc.) to start the YARN. The following placeholders will be replaced:
  • %java%: Path to the Java executable
  • %jvmmem%: JVM memory limits and tweaks
  • %jvmopts%: Options for the Java VM
  • %logging%: Logging-related configuration settings
  • %class%: Main class to execute
  • %args%: Arguments for the main class
  • %redirects%: Output redirects
yarn.containers.vcores
-1IntegerThe number of virtual cores (vcores) per YARN container. By default, the number of vcores is set to the number of slots per TaskManager, if set, or to 1, otherwise. In order for this parameter to be used your cluster must have CPU scheduling enabled. You can do this by setting the org.apache.hadoop.yarn.server.resourcemanager.scheduler.fair.FairScheduler.
yarn.file-replication
-1IntegerNumber of file replication of each local resource file. If it is not configured, Flink will use the default replication value in hadoop configuration.
yarn.flink-dist-jar
(none)StringThe location of the Flink dist jar.
yarn.heartbeat.container-request-interval
500 msDurationTime between heartbeats with the ResourceManager if Flink requests containers:
  • The lower this value is, the faster Flink will get notified about container allocations since requests and allocations are transmitted via heartbeats.
  • The lower this value is, the more excessive containers might get allocated which will eventually be released but put pressure on Yarn.
If you observe too many container allocations on the ResourceManager, then it is recommended to increase this value. See this link for more information.
yarn.heartbeat.interval
5IntegerTime between heartbeats with the ResourceManager in seconds.
yarn.modify.acls
(none)StringUsers and groups to give MODIFY access. The ACLs are of for comma-separated-users&lt;space&gt;comma-separated-groups. Wildcard ACL is also supported. The only valid wildcard ACL is , which grants permission to all users and groups.
yarn.properties-file.location
(none)StringWhen a Flink job is submitted to YARN, the JobManager’s host and the number of available processing slots is written into a properties file, so that the Flink client is able to pick those details up. This configuration parameter allows changing the default location of that file (for example for environments sharing a Flink installation between users).
yarn.provided.lib.dirs
(none)List<String>A semicolon-separated list of provided lib directories. They should be pre-uploaded and world-readable. Flink will use them to exclude the local Flink jars(e.g. flink-dist, lib/, plugins/)uploading to accelerate the job submission process. Also YARN will cache them on the nodes so that they doesn’t need to be downloaded every time for each application. An example could be hdfs://$namenode_address/path/of/flink/lib
yarn.provided.usrlib.dir
(none)StringThe provided usrlib directory in remote. It should be pre-uploaded and world-readable. Flink will use it to exclude the local usrlib directory(i.e. usrlib/ under the parent directory of FLINK_LIB_DIR). Unlike yarn.provided.lib.dirs, YARN will not cache it on the nodes as it is for each application. An example could be hdfs://$namenode_address/path/of/flink/usrlib
yarn.security.appmaster.delegation.token.services
“hadoopfs”List<String>The delegation token provider services are allowed to pass obtained tokens to YARN application master. For backward compatibility to make log aggregation to work, we add tokens obtained by hadoopfs provider to AM by default.
yarn.security.kerberos.localized-keytab-path
“krb5.keytab”StringLocal (on NodeManager) path where kerberos keytab file will be localized to. If yarn.security.kerberos.ship-local-keytab set to true, Flink will ship the keytab file as a YARN local resource. In this case, the path is relative to the local resource directory. If set to false, Flink will try to directly locate the keytab from the path itself.
yarn.security.kerberos.ship-local-keytab
trueBooleanWhen this is true Flink will ship the keytab file configured via security.kerberos.login.keytab as a localized YARN resource.
yarn.ship-archives
(none)List<String>A semicolon-separated list of archives to be shipped to the YARN cluster. These archives can come from the local path of flink client or HDFS. They will be un-packed when localizing and they can be any of the following types: “.tar.gz”, “.tar”, “.tgz”, “.dst”, “.jar”, “.zip”. For example, “/path/to/local/archive.jar;hdfs://$namenode_address/path/to/archive.jar”
yarn.ship-files
(none)List<String>A semicolon-separated list of files and/or directories to be shipped to the YARN cluster. These files/directories can come from the local path of flink client or HDFS. For example, “/path/to/local/file;/path/to/local/directory;hdfs://$namenode_address/path/of/file;hdfs://$namenode_address/path/of/directory”
yarn.staging-directory
(none)StringStaging directory used to store YARN files while submitting applications. Per default, it uses the home directory of the configured file system.
yarn.tags
(none)StringA comma-separated list of tags to apply to the Flink YARN application.
yarn.taskmanager.node-label
(none)StringSpecify YARN node label for the Flink TaskManagers, it will override the yarn.application.node-label for TaskManagers if both are set.
yarn.view.acls
(none)StringUsers and groups to give VIEW access. The ACLs are of for comma-separated-users&lt;space&gt;comma-separated-groups. Wildcard ACL is also supported. The only valid wildcard ACL is , which grants permission to all users and groups.

Kubernetes

KeyDefaultTypeDescription
external-resource.<resourcename>.kubernetes.config-key
(none)StringIf configured, Flink will add “resources.limits.<config-key>” and “resources.requests.<config-key>” to the main container of TaskExecutor and set the value to the value of external-resource.<resource_name>.amount.
kubernetes.artifacts.local-upload-enabled
falseBooleanEnables uploading ‘local://‘ schemed artifacts to DFS before the the application cluster deployment.
kubernetes.artifacts.local-upload-overwrite
falseBooleanIf enabled, overwrites any existing artifact on the remote target. Disabled by default.
kubernetes.artifacts.local-upload-target
(none)StringThe target remote DFS directory to upload local artifacts.
kubernetes.client.io-pool.size
4IntegerThe size of the IO executor pool used by the Kubernetes client to execute blocking IO operations (e.g. start/stop TaskManager pods, update leader related ConfigMaps, etc.). Increasing the pool size allows to run more IO operations concurrently.
kubernetes.client.user-agent
“flink”StringThe user agent to be used for contacting with Kubernetes APIServer.
kubernetes.cluster-id
(none)StringThe cluster-id, which should be no more than 45 characters, is used for identifying a unique Flink cluster. The id must only contain lowercase alphanumeric characters and “-“. The required format is a-z. If not set, the client will automatically generate it with a random ID.
kubernetes.config.file
(none)StringThe kubernetes config file will be used to create the client. The default is located at ~/.kube/config
kubernetes.container.image.pull-policy
IfNotPresent

Enum

The Kubernetes container image pull policy. The default policy is IfNotPresent to avoid putting pressure to image repository.

Possible values:
  • “IfNotPresent”
  • “Always”
  • “Never”
kubernetes.container.image.pull-secrets
(none)List<String>A semicolon-separated list of the Kubernetes secrets used to access private image registries.
kubernetes.container.image.ref
The default value depends on the actually running version. In general it looks like “flink:<FLINK_VERSION>-scala<SCALAVERSION>”StringImage to use for Flink containers. The specified image must be based upon the same Apache Flink and Scala versions as used by the application. Visit <a href=”https://hub.docker.com//flink?tab=tags”>here for the official docker images provided by the Flink project. The Flink project also publishes docker images to apache/flink DockerHub repository.
kubernetes.context
(none)StringThe desired context from your Kubernetes config file used to configure the Kubernetes client for interacting with the cluster. This could be helpful if one has multiple contexts configured and wants to administrate different Flink clusters on different Kubernetes clusters/contexts.
kubernetes.decorator.hadoop-conf-mount.enabled
trueBooleanWhether to enable Hadoop configuration mount decorator. This must be set to false when Hadoop config is mounted outside of Flink. A typical use-case is when one uses Flink Kubernetes Operator.
kubernetes.decorator.kerberos-mount.enabled
trueBooleanWhether to enable Kerberos mount decorator. This must be set to false when Kerberos config and keytab is mounted outside of Flink. A typical use-case is when one uses Flink Kubernetes Operator.
kubernetes.entry.path
“/docker-entrypoint.sh”StringThe entrypoint script of kubernetes in the image. It will be used as command for jobmanager and taskmanager container.
kubernetes.env.secretKeyRef
(none)List<Map>The user-specified secrets to set env variables in Flink container. The value should be in the form of env:FOO_ENV,secret:foo_secret,key:foo_key;env:BAR_ENV,secret:bar_secret,key:bar_key.
kubernetes.flink.conf.dir
“/opt/flink/conf”StringThe flink conf directory that will be mounted in pod. The config.yaml, log4j.properties, logback.xml in this path will be overwritten from config map.
kubernetes.flink.log.dir
(none)StringThe directory that logs of jobmanager and taskmanager be saved in the pod. The default value is $FLINK_HOME/log.
kubernetes.hadoop.conf.config-map.name
(none)StringSpecify the name of an existing ConfigMap that contains custom Hadoop configuration to be mounted on the JobManager(s) and TaskManagers.
kubernetes.hostnetwork.enabled
falseBooleanWhether to enable HostNetwork mode. The HostNetwork allows the pod could use the node network namespace instead of the individual pod network namespace. Please note that the JobManager service account should have the permission to update Kubernetes service.
kubernetes.internal-service.annotations
(none)MapThe user-specified annotations that are set to the internal Service. The value should be in the form of a1:v1,a2:v2
kubernetes.jobmanager.annotations
(none)MapThe user-specified annotations that are set to the JobManager pod. The value could be in the form of a1:v1,a2:v2
kubernetes.jobmanager.cpu.amount
1.0DoubleThe number of cpu used by job manager
kubernetes.jobmanager.cpu.limit-factor
1.0DoubleThe limit factor of cpu used by job manager. The resources limit cpu will be set to cpu limit-factor.
kubernetes.jobmanager.entrypoint.args
(none)StringExtra arguments used when starting the job manager.
kubernetes.jobmanager.labels
(none)MapThe labels to be set for JobManager pod. Specified as key:value pairs separated by commas. For example, version:alphav1,deploy:test.
kubernetes.jobmanager.memory.limit-factor
1.0DoubleThe limit factor of memory used by job manager. The resources limit memory will be set to memory limit-factor.
kubernetes.jobmanager.node-selector
(none)MapThe node selector to be set for JobManager pod. Specified as key:value pairs separated by commas. For example, environment:production,disk:ssd.
kubernetes.jobmanager.owner.reference
(none)List<Map>The user-specified Owner References to be set to the JobManager Deployment. When all the owner resources are deleted, the JobManager Deployment will be deleted automatically, which also deletes all the resources created by this Flink cluster. The value should be formatted as a semicolon-separated list of owner references, where each owner reference is a comma-separated list of key:value pairs. E.g., apiVersion:v1,blockOwnerDeletion:true,controller:true,kind:FlinkApplication,name:flink-app-name,uid:flink-app-uid;apiVersion:v1,kind:Deployment,name:deploy-name,uid:deploy-uid
kubernetes.jobmanager.replicas
1IntegerSpecify how many JobManager pods will be started simultaneously. Configure the value to greater than 1 to start standby JobManagers. It will help to achieve faster recovery. Notice that high availability should be enabled when starting standby JobManagers.
kubernetes.jobmanager.service-account
“default”StringService account that is used by jobmanager within kubernetes cluster. The job manager uses this service account when requesting taskmanager pods from the API server. If not explicitly configured, config option ‘kubernetes.service-account’ will be used.
kubernetes.jobmanager.tolerations
(none)List<Map>The user-specified tolerations to be set to the JobManager pod. The value should be in the form of key:key1,operator:Equal,value:value1,effect:NoSchedule;key:key2,operator:Exists,effect:NoExecute,tolerationSeconds:6000
kubernetes.namespace
“default”StringThe namespace that will be used for running the jobmanager and taskmanager pods.
kubernetes.pod-template-file.default
(none)StringSpecify a local file that contains the pod template definition. It will be used to initialize the jobmanager and taskmanager pod. The main container should be defined with name ‘flink-main-container’. Notice that this can be overwritten by config options ‘kubernetes.pod-template-file.jobmanager’ and ‘kubernetes.pod-template-file.taskmanager’ for jobmanager and taskmanager respectively.
kubernetes.pod-template-file.jobmanager
(none)StringSpecify a local file that contains the jobmanager pod template definition. It will be used to initialize the jobmanager pod. The main container should be defined with name ‘flink-main-container’. If not explicitly configured, config option ‘kubernetes.pod-template-file.default’ will be used.
kubernetes.pod-template-file.taskmanager
(none)StringSpecify a local file that contains the taskmanager pod template definition. It will be used to initialize the taskmanager pod. The main container should be defined with name ‘flink-main-container’. If not explicitly configured, config option ‘kubernetes.pod-template-file.default’ will be used.
kubernetes.rest-service.annotations
(none)MapThe user-specified annotations that are set to the rest Service. The value should be in the form of a1:v1,a2:v2
kubernetes.rest-service.exposed.node-port-address-type
InternalIP

Enum

The user-specified address type that is used for filtering node IPs when constructing a node port connection string. This option is only considered when ‘kubernetes.rest-service.exposed.type’ is set to ‘NodePort’.

Possible values:
  • “InternalIP”
  • “ExternalIP”
kubernetes.rest-service.exposed.type
ClusterIP

Enum

The exposed type of the rest service. The exposed rest service could be used to access the Flink’s Web UI and REST endpoint.

Possible values:
  • “ClusterIP”
  • “NodePort”
  • “LoadBalancer”
  • “Headless_ClusterIP”
kubernetes.secrets
(none)MapThe user-specified secrets that will be mounted into Flink container. The value should be in the form of foo:/opt/secrets-foo,bar:/opt/secrets-bar.
kubernetes.service-account
“default”StringService account that is used by jobmanager and taskmanager within kubernetes cluster. Notice that this can be overwritten by config options ‘kubernetes.jobmanager.service-account’ and ‘kubernetes.taskmanager.service-account’ for jobmanager and taskmanager respectively.
kubernetes.taskmanager.annotations
(none)MapThe user-specified annotations that are set to the TaskManager pod. The value could be in the form of a1:v1,a2:v2
kubernetes.taskmanager.cpu.amount
-1.0DoubleThe number of cpu used by task manager. By default, the cpu is set to the number of slots per TaskManager
kubernetes.taskmanager.cpu.limit-factor
1.0DoubleThe limit factor of cpu used by task manager. The resources limit cpu will be set to cpu limit-factor.
kubernetes.taskmanager.entrypoint.args
(none)StringExtra arguments used when starting the task manager.
kubernetes.taskmanager.labels
(none)MapThe labels to be set for TaskManager pods. Specified as key:value pairs separated by commas. For example, version:alphav1,deploy:test.
kubernetes.taskmanager.memory.limit-factor
1.0DoubleThe limit factor of memory used by task manager. The resources limit memory will be set to memory limit-factor.
kubernetes.taskmanager.node-selector
(none)MapThe node selector to be set for TaskManager pods. Specified as key:value pairs separated by commas. For example, environment:production,disk:ssd.
kubernetes.taskmanager.service-account
“default”StringService account that is used by taskmanager within kubernetes cluster. The task manager uses this service account when watching config maps on the API server to retrieve leader address of jobmanager and resourcemanager. If not explicitly configured, config option ‘kubernetes.service-account’ will be used.
kubernetes.taskmanager.tolerations
(none)List<Map>The user-specified tolerations to be set to the TaskManager pod. The value should be in the form of key:key1,operator:Equal,value:value1,effect:NoSchedule;key:key2,operator:Exists,effect:NoExecute,tolerationSeconds:6000
kubernetes.transactional-operation.initial-retry-delay
50 msDurationDefines the initial duration of Kubernetes transactional operation retries after fail
kubernetes.transactional-operation.max-retries
15IntegerDefines the number of Kubernetes transactional operation retries before the client gives up. For example, FlinkKubeClient#checkAndUpdateConfigMap.
kubernetes.transactional-operation.max-retry-delay
1 minDurationDefines the max duration of Kubernetes transactional operation retries after fail


State Backends

Please refer to the State Backend Documentation for background on State Backends.

RocksDB State Backend

These are the options commonly needed to configure the RocksDB state backend. See the Advanced RocksDB Backend Section for options necessary for advanced low level configurations and trouble-shooting.

KeyDefaultTypeDescription
state.backend.rocksdb.memory.fixed-per-slot
(none)MemorySizeThe fixed total amount of memory, shared among all RocksDB instances per slot. This option overrides the ‘state.backend.rocksdb.memory.managed’ option when configured.
state.backend.rocksdb.memory.fixed-per-tm
(none)MemorySizeThe fixed total amount of memory, shared among all RocksDB instances per Task Manager (cluster-level option). This option only takes effect if neither ‘state.backend.rocksdb.memory.managed’ nor ‘state.backend.rocksdb.memory.fixed-per-slot’ are not configured. If none is configured then each RocksDB column family state has its own memory caches (as controlled by the column family options). The relevant options for the shared resources (e.g. write-buffer-ratio) can be set on the same level (config.yaml).Note, that this feature breaks resource isolation between the slots
state.backend.rocksdb.memory.high-prio-pool-ratio
0.1DoubleThe fraction of cache memory that is reserved for high-priority data like index, filter, and compression dictionary blocks. This option only has an effect when ‘state.backend.rocksdb.memory.managed’ or ‘state.backend.rocksdb.memory.fixed-per-slot’ are configured.
state.backend.rocksdb.memory.managed
trueBooleanIf set, the RocksDB state backend will automatically configure itself to use the managed memory budget of the task slot, and divide the memory over write buffers, indexes, block caches, etc. That way, the three major uses of memory of RocksDB will be capped.
state.backend.rocksdb.memory.partitioned-index-filters
falseBooleanWith partitioning, the index/filter block of an SST file is partitioned into smaller blocks with an additional top-level index on them. When reading an index/filter, only top-level index is loaded into memory. The partitioned index/filter then uses the top-level index to load on demand into the block cache the partitions that are required to perform the index/filter query. This option only has an effect when ‘state.backend.rocksdb.memory.managed’ or ‘state.backend.rocksdb.memory.fixed-per-slot’ are configured.
state.backend.rocksdb.memory.write-buffer-ratio
0.5DoubleThe maximum amount of memory that write buffers may take, as a fraction of the total shared memory. This option only has an effect when ‘state.backend.rocksdb.memory.managed’ or ‘state.backend.rocksdb.memory.fixed-per-slot’ are configured.
state.backend.rocksdb.timer-service.cache-size
128IntegerThe cache size per keyGroup of rocksdb timer service factory. This option only has an effect when ‘state.backend.rocksdb.timer-service.factory’ is configured to ‘ROCKSDB’. Increasing this value can improve the performance of rocksdb timer service, but consumes more heap memory at the same time.
state.backend.rocksdb.timer-service.factory
ROCKSDB

Enum

This determines the factory for timer service state implementation.

Possible values:
  • “HEAP”: Heap-based
  • “ROCKSDB”: Implementation based on RocksDB


Metrics

Please refer to the metrics system documentation for background on Flink’s metrics infrastructure.

KeyDefaultTypeDescription
metrics.fetcher.update-interval
10 sDurationUpdate interval for the metric fetcher used by the web UI. Decrease this value for faster updating metrics. Increase this value if the metric fetcher causes too much load. Setting this value to 0 disables the metric fetching completely.
metrics.internal.query-service.port
“0”StringThe port range used for Flink’s internal metric query service. Accepts a list of ports (“50100,50101”), ranges(“50100-50200”) or a combination of both. It is recommended to set a range of ports to avoid collisions when multiple Flink components are running on the same machine. Per default Flink will pick a random port.
metrics.internal.query-service.thread-priority
1IntegerThe thread priority used for Flink’s internal metric query service. The thread is created by Pekko’s thread pool executor. The range of the priority is from 1 (MIN_PRIORITY) to 10 (MAX_PRIORITY). Warning, increasing this value may bring the main Flink components down.
metrics.job.status.enable
CURRENT_TIME

List<Enum>

The selection of job status metrics that should be reported.

Possible values:
  • “STATE”: For a given state, return 1 if the job is currently in that state, otherwise return 0.
  • “CURRENT_TIME”: For a given state, if the job is currently in that state, return the time since the job transitioned into that state, otherwise return 0.
  • “TOTAL_TIME”: For a given state, return how much time the job has spent in that state in total.
metrics.latency.granularity
“operator”StringDefines the granularity of latency metrics. Accepted values are:
  • single - Track latency without differentiating between sources and subtasks.
  • operator - Track latency while differentiating between sources, but not subtasks.
  • subtask - Track latency while differentiating between sources and subtasks.
metrics.latency.history-size
128IntegerDefines the number of measured latencies to maintain at each operator.
metrics.latency.interval
0 msDurationDefines the interval at which latency tracking marks are emitted from the sources. Disables latency tracking if set to 0 or a negative value. Enabling this feature can significantly impact the performance of the cluster.
metrics.reporter.<name>.<parameter>
(none)StringConfigures the parameter <parameter> for the reporter named <name>.
metrics.reporter.<name>.factory.class
(none)StringThe reporter factory class to use for the reporter named <name>.
metrics.reporter.<name>.filter.excludes
List<String>The metrics that should be excluded for the reporter named <name>. The format is identical to filter.includes
metrics.reporter.<name>.filter.includes
::List<String>The metrics that should be included for the reporter named <name>. Filters are specified as a list, with each filter following this format:
<scope>[:<name>[,<name>][:<type>[,<type>]]]
A metric matches a filter if the scope pattern and at least one of the name patterns and at least one of the types match.
  • scope: Filters based on the logical scope.
    Specified as a pattern where matches any sequence of characters and . separates scope components.

    For example:
    jobmanager.job“ matches any job-related metrics on the JobManager,
    .job“ matches all job-related metrics and
    .job.“ matches all metrics below the job-level (i.e., task/operator metrics etc.).

  • name: Filters based on the metric name.
    Specified as a comma-separate list of patterns where
    matches any sequence of characters.

    For example, “Records,Bytes“ matches any metrics where the name contains “Records” or “Bytes”.

  • type: Filters based on the metric type. Specified as a comma-separated list of metric types: [counter, meter, gauge, histogram]
Examples:
  • :numRecords“ Matches metrics like numRecordsIn.
  • .job.task.operator:numRecords“ Matches metrics like numRecordsIn on the operator level.
  • .job.task.operator:numRecords:meter“ Matches meter metrics like numRecordsInPerSecond on the operator level.
  • :numRecords,numBytes*:counter,meter“ Matches all counter/meter metrics like or numRecordsInPerSecond.
metrics.reporter.<name>.interval
10 sDurationThe reporter interval to use for the reporter named <name>. Only applicable to push-based reporters.
metrics.reporter.<name>.scope.delimiter
“.”StringThe delimiter used to assemble the metric identifier for the reporter named <name>.
metrics.reporter.<name>.scope.variables.additional
MapThe map of additional variables that should be included for the reporter named <name>. Only applicable to tag-based reporters.
metrics.reporter.<name>.scope.variables.excludes
“.”StringThe set of variables that should be excluded for the reporter named <name>. Only applicable to tag-based reporters.
metrics.reporters
(none)StringAn optional list of reporter names. If configured, only reporters whose name matches any of the names in the list will be started. Otherwise, all reporters that could be found in the configuration will be started.
metrics.scope.delimiter
“.”StringDelimiter used to assemble the metric identifier.
metrics.scope.jm
“<host>.jobmanager”StringDefines the scope format string that is applied to all metrics scoped to a JobManager. Only effective when a identifier-based reporter is configured.
metrics.scope.jm-job
“<host>.jobmanager.<job_name>”StringDefines the scope format string that is applied to all metrics scoped to a job on a JobManager. Only effective when a identifier-based reporter is configured
metrics.scope.jm-operator
“<host>.jobmanager.<job_name>.<operator_name>”StringDefines the scope format string that is applied to all metrics scoped to the components running on a JobManager of an Operator, like OperatorCoordinator for Source Enumerator metrics.
metrics.scope.operator
“<host>.taskmanager.<tm_id>.<job_name>.<operator_name>.<subtask_index>”StringDefines the scope format string that is applied to all metrics scoped to an operator. Only effective when a identifier-based reporter is configured
metrics.scope.task
“<host>.taskmanager.<tm_id>.<job_name>.<task_name>.<subtask_index>”StringDefines the scope format string that is applied to all metrics scoped to a task. Only effective when a identifier-based reporter is configured
metrics.scope.tm
“<host>.taskmanager.<tm_id>”StringDefines the scope format string that is applied to all metrics scoped to a TaskManager. Only effective when a identifier-based reporter is configured
metrics.scope.tm-job
“<host>.taskmanager.<tm_id>.<job_name>”StringDefines the scope format string that is applied to all metrics scoped to a job on a TaskManager. Only effective when a identifier-based reporter is configured
metrics.system-resource
falseBooleanFlag indicating whether Flink should report system resource metrics such as machine’s CPU, memory or network usage.
metrics.system-resource-probing-interval
5 sDurationInterval between probing of system resource metrics specified. Has an effect only when ‘metrics.system-resource’ is enabled.

RocksDB Native Metrics

Flink can report metrics from RocksDB’s native code, for applications using the RocksDB state backend. The metrics here are scoped to the operators with unsigned longs and have two kinds of types:

  1. RocksDB property-based metrics, which is broken down by column family, e.g. number of currently running compactions of one specific column family.
  2. RocksDB statistics-based metrics, which holds at the database level, e.g. total block cache hit count within the DB.

Enabling RocksDB’s native metrics may cause degraded performance and should be set carefully.

KeyDefaultTypeDescription
state.backend.rocksdb.metrics.actual-delayed-write-rate
falseBooleanMonitor the current actual delayed write rate. 0 means no delay.
state.backend.rocksdb.metrics.background-errors
falseBooleanMonitor the number of background errors in RocksDB.
state.backend.rocksdb.metrics.block-cache-capacity
falseBooleanMonitor block cache capacity.
state.backend.rocksdb.metrics.block-cache-hit
falseBooleanMonitor the total count of block cache hit in RocksDB (BLOCK_CACHE_HIT == BLOCK_CACHE_INDEX_HIT + BLOCK_CACHE_FILTER_HIT + BLOCK_CACHE_DATA_HIT).
state.backend.rocksdb.metrics.block-cache-miss
falseBooleanMonitor the total count of block cache misses in RocksDB (BLOCK_CACHE_MISS == BLOCK_CACHE_INDEX_MISS + BLOCK_CACHE_FILTER_MISS + BLOCK_CACHE_DATA_MISS).
state.backend.rocksdb.metrics.block-cache-pinned-usage
falseBooleanMonitor the memory size for the entries being pinned in block cache.
state.backend.rocksdb.metrics.block-cache-usage
falseBooleanMonitor the memory size for the entries residing in block cache.
state.backend.rocksdb.metrics.bloom-filter-full-positive
falseBooleanMonitor the total count of reads not avoided by bloom full filter.
state.backend.rocksdb.metrics.bloom-filter-full-true-positive
falseBooleanMonitor the total count of reads not avoided by bloom full filter and the data actually exists in RocksDB.
state.backend.rocksdb.metrics.bloom-filter-useful
falseBooleanMonitor the total count of reads avoided by bloom filter.
state.backend.rocksdb.metrics.bytes-read
falseBooleanMonitor the number of uncompressed bytes read (from memtables/cache/sst) from Get() operation in RocksDB.
state.backend.rocksdb.metrics.bytes-written
falseBooleanMonitor the number of uncompressed bytes written by DB::{Put(), Delete(), Merge(), Write()} operations, which does not include the compaction written bytes, in RocksDB.
state.backend.rocksdb.metrics.column-family-as-variable
falseBooleanWhether to expose the column family as a variable for RocksDB property based metrics.
state.backend.rocksdb.metrics.compaction-pending
falseBooleanTrack pending compactions in RocksDB. Returns 1 if a compaction is pending, 0 otherwise.
state.backend.rocksdb.metrics.compaction-read-bytes
falseBooleanMonitor the bytes read during compaction in RocksDB.
state.backend.rocksdb.metrics.compaction-write-bytes
falseBooleanMonitor the bytes written during compaction in RocksDB.
state.backend.rocksdb.metrics.cur-size-active-mem-table
falseBooleanMonitor the approximate size of the active memtable in bytes.
state.backend.rocksdb.metrics.cur-size-all-mem-tables
falseBooleanMonitor the approximate size of the active and unflushed immutable memtables in bytes.
state.backend.rocksdb.metrics.estimate-live-data-size
falseBooleanEstimate of the amount of live data in bytes (usually smaller than sst files size due to space amplification).
state.backend.rocksdb.metrics.estimate-num-keys
falseBooleanEstimate the number of keys in RocksDB.
state.backend.rocksdb.metrics.estimate-pending-compaction-bytes
falseBooleanEstimated total number of bytes compaction needs to rewrite to get all levels down to under target size. Not valid for other compactions than level-based.
state.backend.rocksdb.metrics.estimate-table-readers-mem
falseBooleanEstimate the memory used for reading SST tables, excluding memory used in block cache (e.g.,filter and index blocks) in bytes.
state.backend.rocksdb.metrics.is-write-stopped
falseBooleanTrack whether write has been stopped in RocksDB. Returns 1 if write has been stopped, 0 otherwise.
state.backend.rocksdb.metrics.iter-bytes-read
falseBooleanMonitor the number of uncompressed bytes read (from memtables/cache/sst) from an iterator operation in RocksDB.
state.backend.rocksdb.metrics.live-sst-files-size
falseBooleanMonitor the total size (bytes) of all SST files belonging to the latest version.WARNING: may slow down online queries if there are too many files.
state.backend.rocksdb.metrics.mem-table-flush-pending
falseBooleanMonitor the number of pending memtable flushes in RocksDB.
state.backend.rocksdb.metrics.num-deletes-active-mem-table
falseBooleanMonitor the total number of delete entries in the active memtable.
state.backend.rocksdb.metrics.num-deletes-imm-mem-tables
falseBooleanMonitor the total number of delete entries in the unflushed immutable memtables.
state.backend.rocksdb.metrics.num-entries-active-mem-table
falseBooleanMonitor the total number of entries in the active memtable.
state.backend.rocksdb.metrics.num-entries-imm-mem-tables
falseBooleanMonitor the total number of entries in the unflushed immutable memtables.
state.backend.rocksdb.metrics.num-files-at-level
falseBooleanMonitor the number of files at each level.
state.backend.rocksdb.metrics.num-immutable-mem-table
falseBooleanMonitor the number of immutable memtables in RocksDB.
state.backend.rocksdb.metrics.num-live-versions
falseBooleanMonitor number of live versions. Version is an internal data structure. See RocksDB file version_set.h for details. More live versions often mean more SST files are held from being deleted, by iterators or unfinished compactions.
state.backend.rocksdb.metrics.num-running-compactions
falseBooleanMonitor the number of currently running compactions.
state.backend.rocksdb.metrics.num-running-flushes
falseBooleanMonitor the number of currently running flushes.
state.backend.rocksdb.metrics.num-snapshots
falseBooleanMonitor the number of unreleased snapshots of the database.
state.backend.rocksdb.metrics.size-all-mem-tables
falseBooleanMonitor the approximate size of the active, unflushed immutable, and pinned immutable memtables in bytes.
state.backend.rocksdb.metrics.stall-micros
falseBooleanMonitor the duration of writer requiring to wait for compaction or flush to finish in RocksDB.
state.backend.rocksdb.metrics.total-sst-files-size
falseBooleanMonitor the total size (bytes) of all SST files of all versions.WARNING: may slow down online queries if there are too many files.


Traces

Please refer to the tracing system documentation for background on Flink’s tracing infrastructure.

KeyDefaultTypeDescription
traces.reporter.<name>.<parameter>
(none)StringConfigures the parameter <parameter> for the reporter named <name>.
traces.reporter.<name>.factory.class
(none)StringThe reporter factory class to use for the reporter named <name>.
traces.reporter.<name>.scope.variables.additional
MapThe map of additional variables that should be included for the reporter named <name>.
traces.reporters
(none)StringAn optional list of trace reporter names. If configured, only reporters whose name matches any of the names in the list will be started. Otherwise, all reporters that could be found in the configuration will be started.


History Server

The history server keeps the information of completed jobs (graphs, runtimes, statistics). To enable it, you have to enable “job archiving” in the JobManager (jobmanager.archive.fs.dir).

See the History Server Docs for details.

KeyDefaultTypeDescription
historyserver.archive.clean-expired-jobs
falseBooleanWhether HistoryServer should cleanup jobs that are no longer present historyserver.archive.fs.dir.
historyserver.archive.fs.dir
(none)StringComma separated list of directories to fetch archived jobs from. The history server will monitor these directories for archived jobs. You can configure the JobManager to archive jobs to a directory via jobmanager.archive.fs.dir.
historyserver.archive.fs.refresh-interval
10 sDurationInterval for refreshing the archived job directories.
historyserver.archive.retained-jobs
-1IntegerThe maximum number of jobs to retain in each archive directory defined by historyserver.archive.fs.dir. If set to -1(default), there is no limit to the number of archives. If set to 0 or less than -1 HistoryServer will throw an IllegalConfigurationException.
historyserver.log.jobmanager.url-pattern
(none)StringPattern of the log URL of JobManager. The HistoryServer will generate actual URLs from it, with replacing the special placeholders, &lt;jobid&gt;, to the id of job. Only http / https schemes are supported.
historyserver.log.taskmanager.url-pattern
(none)StringPattern of the log URL of TaskManager. The HistoryServer will generate actual URLs from it, with replacing the special placeholders, &lt;jobid&gt; and &lt;tmid&gt;, to the id of job and TaskManager respectively. Only http / https schemes are supported.
historyserver.web.address
(none)StringAddress of the HistoryServer’s web interface.
historyserver.web.port
8082IntegerPort of the HistoryServers’s web interface.
historyserver.web.refresh-interval
10 sDurationThe refresh interval for the HistoryServer web-frontend.
historyserver.web.ssl.enabled
falseBooleanEnable HTTPs access to the HistoryServer web frontend. This is applicable only when the global SSL flag security.ssl.enabled is set to true.
historyserver.web.tmpdir
(none)StringLocal directory that is used by the history server REST API for temporary files.


Experimental

Options for experimental features in Flink.

Client

KeyDefaultTypeDescription
client.heartbeat.interval
30 sDurationTime interval for job client to report its heartbeat when ‘execution.attached’ and ‘execution.shutdown-on-attached-exit’ are both true. Cancel the job if timeout configured by ‘client.heartbeat.timeout’.
client.heartbeat.timeout
3 minDurationCancel the job if the dispatcher hasn’t received the client’s heartbeat after timeout when ‘execution.attached’ and ‘execution.shutdown-on-attached-exit’ are both true.
client.retry-period
2 sDurationThe interval (in ms) between consecutive retries of failed attempts to execute commands through the CLI or Flink’s clients, wherever retry is supported (default 2sec).
client.timeout
1 minDurationTimeout on the client side.


User Artifact Management

Flink is capable to upload and fetch local user artifacts in Application Mode. An artifact can be the actual job archive, a UDF that is packaged separately, etc.

  1. Uploading local artifacts to a DFS is a Kubernetes specific feature, see the Kubernetes section and look for kubernetes.artifacts.* prefixed options.
  2. Fetching remote artifacts on the deployed application cluster is supported from DFS or an HTTP(S) endpoint.

    Note: Artifact Fetching is supported in Standalone Application Mode and Native Kubernetes Application Mode.

KeyDefaultTypeDescription
user.artifacts.artifact-list
(none)List<String>A semicolon-separated list of the additional artifacts to fetch for the job before setting up the application cluster. All given elements have to be valid URIs. Example: s3://sandbox-bucket/format.jar;http://sandbox-server:1234/udf.jar
user.artifacts.base-dir
“/opt/flink/artifacts”StringThe base dir to put the application job artifacts.
user.artifacts.http-headers
(none)MapCustom HTTP header(s) for the HTTP artifact fetcher. The header(s) will be applied when getting the application job artifacts. Expected format: headerKey1:headerValue1,headerKey2:headerValue2.
user.artifacts.raw-http-enabled
falseBooleanEnables artifact fetching from raw HTTP endpoints.


Execution

KeyDefaultTypeDescription
execution.attached
falseBooleanSpecifies if the pipeline is submitted in attached or detached mode.
execution.job-listeners
(none)List<String>Custom JobListeners to be registered with the execution environment. The registered listeners cannot have constructors with arguments.
execution.program-config.enabled
trueBooleanDetermines whether configurations in the user program are allowed. By default, configuration can be set both on a cluster-level (via options) or within the user program (i.e. programmatic via environment setters). If disabled, all configuration must be defined on a cluster-level and programmatic setters in the user program are prohibited.

Depending on your deployment mode failing the job might have different implications. Either your client that is trying to submit the job to an external cluster (session cluster deployment) throws the exception or the job manager (application mode deployment).

The ‘execution.program-config.wildcards’ option lists configuration keys that are allowed to be set in user programs regardless of this setting.
execution.program-config.wildcards
List<String>List of configuration keys that are allowed to be set in a user program regardless whether program configuration is enabled or not.

Currently changes that are not backed by the Configuration class are always allowed.
execution.shutdown-on-application-finish
trueBooleanWhether a Flink Application cluster should shut down automatically after its application finishes (either successfully or as result of a failure). Has no effect for other deployment modes.
execution.shutdown-on-attached-exit
falseBooleanIf the job is submitted in attached mode, perform a best-effort cluster shutdown when the CLI is terminated abruptly, e.g., in response to a user interrupt, such as typing Ctrl + C.
execution.submit-failed-job-on-application-error
falseBooleanIf a failed job should be submitted (in the application mode) when there is an error in the application driver before an actual job submission. This is intended for providing a clean way of reporting failures back to the user and is especially useful in combination with ‘execution.shutdown-on-application-finish’. This option only works when the single job submission is enforced (‘high-availability.type’ is enabled). Please note that this is an experimental option and may be changed in the future.
execution.target
(none)StringThe deployment target for the execution. This can take one of the following values when calling bin/flink run:
  • remote
  • local
  • yarn-per-job (deprecated)
  • yarn-session
  • kubernetes-session
And one of the following values when calling bin/flink run-application:
  • yarn-application
  • kubernetes-application
KeyDefaultTypeDescription
execution.batch-shuffle-mode
ALL_EXCHANGES_BLOCKING

Enum

Defines how data is exchanged between tasks in batch ‘execution.runtime-mode’ if the shuffling behavior has not been set explicitly for an individual exchange.
With pipelined exchanges, upstream and downstream tasks run simultaneously. In order to achieve lower latency, a result record is immediately sent to and processed by the downstream task. Thus, the receiver back-pressures the sender. The streaming mode always uses this exchange.
With blocking exchanges, upstream and downstream tasks run in stages. Records are persisted to some storage between stages. Downstream tasks then fetch these records after the upstream tasks finished. Such an exchange reduces the resources required to execute the job as it does not need to run upstream and downstream tasks simultaneously.
With hybrid exchanges (experimental), downstream tasks can run anytime as long as upstream tasks start running. When given sufficient resources, it can reduce the overall job execution time by running tasks simultaneously. Otherwise, it also allows jobs to be executed with very little resources. It adapts to custom preferences between persisting less data and restarting less tasks on failures, by providing different spilling strategies.

Possible values:
  • “ALL_EXCHANGES_PIPELINED”: Upstream and downstream tasks run simultaneously. This leads to lower latency and more evenly distributed (but higher) resource usage across tasks.
  • “ALL_EXCHANGES_BLOCKING”: Upstream and downstream tasks run subsequently. This reduces the resource usage as downstream tasks are started after upstream tasks finished.
  • “ALL_EXCHANGES_HYBRID_FULL”: Downstream can start running anytime, as long as the upstream has started. This adapts the resource usage to whatever is available. This type will spill all data to disk to support re-consume.
  • “ALL_EXCHANGES_HYBRID_SELECTIVE”: Downstream can start running anytime, as long as the upstream has started. This adapts the resource usage to whatever is available. This type will selective spilling data to reduce disk writes as much as possible.
execution.buffer-timeout.enabled
trueBooleanIf disabled, the config execution.buffer-timeout.interval will not take effect and the flushing will be triggered only when the output buffer is full thus maximizing throughput
execution.buffer-timeout.interval
100 msDurationThe maximum time frequency (milliseconds) for the flushing of the output buffers. By default the output buffers flush frequently to provide low latency and to aid smooth developer experience. Setting the parameter can result in three logical modes:
  • A positive value triggers flushing periodically by that interval
  • 0 triggers flushing after every record thus minimizing latency
  • If the config execution.buffer-timeout.enabled is false, trigger flushing only when the output buffer is full thus maximizing throughput
execution.checkpointing.snapshot-compression
falseBooleanTells if we should use compression for the state snapshot data or not
execution.runtime-mode
STREAMING

Enum

Runtime execution mode of DataStream programs. Among other things, this controls task scheduling, network shuffle behavior, and time semantics.

Possible values:
  • “STREAMING”
  • “BATCH”
  • “AUTOMATIC”
execution.sort-keyed-partition.memory
128 mbMemorySizeSets the managed memory size for sort partition operator on KeyedPartitionWindowedStream.The memory size is only a weight hint. Thus, it will affect the operator’s memory weight within a task, but the actual memory used depends on the running environment.
execution.sort-partition.memory
128 mbMemorySizeSets the managed memory size for sort partition operator in NonKeyedPartitionWindowedStream.The memory size is only a weight hint. Thus, it will affect the operator’s memory weight within a task, but the actual memory used depends on the running environment.

Pipeline

KeyDefaultTypeDescription
pipeline.auto-generate-uids
trueBooleanWhen auto-generated UIDs are disabled, users are forced to manually specify UIDs on DataStream applications.

It is highly recommended that users specify UIDs before deploying to production since they are used to match state in savepoints to operators in a job. Because auto-generated ID’s are likely to change when modifying a job, specifying custom IDs allow an application to evolve over time without discarding state.
pipeline.auto-watermark-interval
200 msDurationThe interval of the automatic watermark emission. Watermarks are used throughout the streaming system to keep track of the progress of time. They are used, for example, for time based windowing.
pipeline.cached-files
(none)List<String>Files to be registered at the distributed cache under the given name. The files will be accessible from any user-defined function in the (distributed) runtime under a local path. Files may be local files (which will be distributed via BlobServer), or files in a distributed file system. The runtime will copy the files temporarily to a local cache, if needed.

Example:
name:file1,path:’file:///tmp/file1’;name:file2,path:’hdfs:///tmp/file2’
pipeline.classpaths
(none)List<String>A semicolon-separated list of the classpaths to package with the job jars to be sent to the cluster. These have to be valid URLs.
pipeline.closure-cleaner-level
RECURSIVE

Enum

Configures the mode in which the closure cleaner works.

Possible values:
  • “NONE”: Disables the closure cleaner completely.
  • “TOP_LEVEL”: Cleans only the top-level class without recursing into fields.
  • “RECURSIVE”: Cleans all fields recursively.
pipeline.force-avro
falseBooleanForces Flink to use the Apache Avro serializer for POJOs.

Important: Make sure to include the flink-avro module.
pipeline.force-kryo
falseBooleanIf enabled, forces TypeExtractor to use Kryo serializer for POJOS even though we could analyze as POJO. In some cases this might be preferable. For example, when using interfaces with subclasses that cannot be analyzed as POJO.
pipeline.force-kryo-avro
(none)BooleanForces Flink to register avro classes in kryo serializer.

Important: Make sure to include the flink-avro module. Otherwise, nothing will be registered. For backward compatibility, the default value is empty to conform to the behavior of the older version. That is, always register avro with kryo, and if flink-avro is not in the class path, register a dummy serializer. In Flink-2.0, we will set the default value to true.
pipeline.generic-types
trueBooleanIf the use of generic types is disabled, Flink will throw an UnsupportedOperationException whenever it encounters a data type that would go through Kryo for serialization.

Disabling generic types can be helpful to eagerly find and eliminate the use of types that would go through Kryo serialization during runtime. Rather than checking types individually, using this option will throw exceptions eagerly in the places where generic types are used.

We recommend to use this option only during development and pre-production phases, not during actual production use. The application program and/or the input data may be such that new, previously unseen, types occur at some point. In that case, setting this option would cause the program to fail.
pipeline.global-job-parameters
(none)MapRegister a custom, serializable user configuration object. The configuration can be accessed in operators
pipeline.jars
(none)List<String>A semicolon-separated list of the jars to package with the job jars to be sent to the cluster. These have to be valid paths.
pipeline.jobvertex-parallelism-overrides
MapA parallelism override map (jobVertexId -> parallelism) which will be used to update the parallelism of the corresponding job vertices of submitted JobGraphs.
pipeline.max-parallelism
-1IntegerThe program-wide maximum parallelism used for operators which haven’t specified a maximum parallelism. The maximum parallelism specifies the upper limit for dynamic scaling and the number of key groups used for partitioned state. Changing the value explicitly when recovery from original job will lead to state incompatibility. Must be less than or equal to 32768.
pipeline.name
(none)StringThe job name used for printing and logging.
pipeline.object-reuse
falseBooleanWhen enabled objects that Flink internally uses for deserialization and passing data to user-code functions will be reused. Keep in mind that this can lead to bugs when the user-code function of an operation is not aware of this behaviour.
pipeline.operator-chaining.chain-operators-with-different-max-parallelism
trueBooleanOperators with different max parallelism can be chained together. Default behavior may prevent rescaling when the AdaptiveScheduler is used.
pipeline.operator-chaining.enabled
trueBooleanOperator chaining allows non-shuffle operations to be co-located in the same thread fully avoiding serialization and de-serialization.
pipeline.serialization-config
(none)List<String>List of pairs of class names and serializer configs to be used. There is a type field in the serializer config and each type has its own configuration. Note: only standard YAML config parser is supported, please use “config.yaml” as the config file. The fields involved are:
  • type: the serializer type which could be “pojo”, “kryo” or “typeinfo”. If the serializer type is “pojo” or “kryo” without field kryo-type, it means the data type will use POJO or Kryo serializer directly.
  • kryo-type: the Kryo serializer type which could be “default” or “registered”. The Kryo serializer will use the serializer for the data type as default serializers when the kryo-type is “default”, and register the data type and its serializer to Kryo serializer when the kryo-type is registered. When the field exists, there must be a field class to specify the serializer class name.
  • class: the serializer class name for type “kryo” or “typeinfo”. For “kryo”, it should be a subclass of com.esotericsoftware.kryo.Serializer. For “typeinfo”, it should be a subclass of org.apache.flink.api.common.typeinfo.TypeInfoFactory.
Example:
[org.example.ExampleClass1: {type: pojo}, org.example.ExampleClass2: {type: kryo}, org.example.ExampleClass3: {type: kryo, kryo-type: default, class: org.example.Class3KryoSerializer}, org.example.ExampleClass4: {type: kryo, kryo-type: registered, class: org.example.Class4KryoSerializer}, org.example.ExampleClass5: {type: typeinfo, class: org.example.Class5TypeInfoFactory}]
pipeline.vertex-description-mode
TREE

Enum

The mode how we organize description of a job vertex.

Possible values:
  • “TREE”
  • “CASCADING”
pipeline.vertex-name-include-index-prefix
falseBooleanWhether name of vertex includes topological index or not. When it is true, the name will have a prefix of index of the vertex, like ‘[vertex-0]Source: source’. It is false by default
pipeline.watermark-alignment.allow-unaligned-source-splits
falseBooleanIf watermark alignment is used, sources with multiple splits will attempt to pause/resume split readers to avoid watermark drift of source splits. However, if split readers don’t support pause/resume, an UnsupportedOperationException will be thrown when there is an attempt to pause/resume. To allow use of split readers that don’t support pause/resume and, hence, to allow unaligned splits while still using watermark alignment, set this parameter to true. The default value is false. Note: This parameter may be removed in future releases.

Checkpointing

KeyDefaultTypeDescription
execution.checkpointing.aligned-checkpoint-timeout
0 msDurationOnly relevant if execution.checkpointing.unaligned.enabled is enabled.

If timeout is 0, checkpoints will always start unaligned.

If timeout has a positive value, checkpoints will start aligned. If during checkpointing, checkpoint start delay exceeds this timeout, alignment will timeout and checkpoint barrier will start working as unaligned checkpoint.
execution.checkpointing.checkpoints-after-tasks-finish
trueBooleanFeature toggle for enabling checkpointing even if some of tasks have finished. Before you enable it, please take a look at the important considerations
execution.checkpointing.cleaner.parallel-mode
trueBooleanOption whether to discard a checkpoint’s states in parallel using the ExecutorService passed into the cleaner
execution.checkpointing.create-subdir
trueBooleanWhether to create sub-directories named by job id under the ‘execution.checkpointing.dir‘ to store the data files and meta data of checkpoints. The default value is true to enable user could run several jobs with the same checkpoint directory at the same time. If this value is set to false, pay attention not to run several jobs with the same directory simultaneously.
WARNING: This is an advanced configuration. If set to false, users must ensure that no multiple jobs are run with the same checkpoint directory, and that no files exist other than those necessary for the restoration of the current job when starting a new job.
execution.checkpointing.data-inline-threshold
20 kbMemorySizeThe minimum size of state data files. All state chunks smaller than that are stored inline in the root checkpoint metadata file. The max memory threshold for this configuration is 1MB.
execution.checkpointing.dir
(none)StringThe 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). If the ‘execution.checkpointing.storage’ is set to ‘jobmanager’, only the meta data of checkpoints will be stored in this directory.
execution.checkpointing.externalized-checkpoint-retention
NO_EXTERNALIZED_CHECKPOINTS

Enum

Externalized checkpoints write their meta data out to persistent storage and are not automatically cleaned up when the owning job fails or is suspended (terminating with job status JobStatus#FAILED or JobStatus#SUSPENDED). In this case, you have to manually clean up the checkpoint state, both the meta data and actual program state.

The mode defines how an externalized checkpoint should be cleaned up on job cancellation. If you choose to retain externalized checkpoints on cancellation you have to handle checkpoint clean up manually when you cancel the job as well (terminating with job status JobStatus#CANCELED).

The target directory for externalized checkpoints is configured via execution.checkpointing.dir.

Possible values:
  • “DELETE_ON_CANCELLATION”: Checkpoint state is only kept when the owning job fails. It is deleted if the job is cancelled.
  • “RETAIN_ON_CANCELLATION”: Checkpoint state is kept when the owning job is cancelled or fails.
  • “NO_EXTERNALIZED_CHECKPOINTS”: Externalized checkpoints are disabled.
execution.checkpointing.file-merging.across-checkpoint-boundary
falseBooleanOnly relevant if execution.checkpointing.file-merging.enabled is enabled.
Whether to allow merging data of multiple checkpoints into one physical file. If this option is set to false, only merge files within checkpoint boundaries. Otherwise, it is possible for the logical files of different checkpoints to share the same physical file.
execution.checkpointing.file-merging.enabled
falseBooleanWhether to enable merging multiple checkpoint files into one, which will greatly reduce the number of small checkpoint files. This is an experimental feature under evaluation, make sure you’re aware of the possible effects of enabling it.
execution.checkpointing.file-merging.max-file-size
32 mbMemorySizeMax size of a physical file for merged checkpoints.
execution.checkpointing.file-merging.max-space-amplification
2.0FloatSpace amplification stands for the magnification of the occupied space compared to the amount of valid data. The more space amplification is, the more waste of space will be. This configs a space amplification above which a re-uploading for physical files will be triggered to reclaim space. Any value below 1f means disabling the space control.
execution.checkpointing.file-merging.pool-blocking
falseBooleanWhether to use Blocking or Non-Blocking pool for merging physical files. A Non-Blocking pool will always provide usable physical file without blocking. It may create many physical files if poll file frequently. When poll a small file from a Blocking pool, it may be blocked until the file is returned.
execution.checkpointing.incremental
falseBooleanOption whether to create incremental checkpoints, if possible. For an incremental checkpoint, only a diff from the previous checkpoint is stored, rather than the complete checkpoint state. Once enabled, the state size shown in web UI or fetched from rest API only represents the delta checkpoint size instead of full checkpoint size. Some state backends may not support incremental checkpoints and ignore this option.
execution.checkpointing.interval
(none)DurationGets the interval in which checkpoints are periodically scheduled.

This setting defines the base interval. Checkpoint triggering may be delayed by the settings execution.checkpointing.max-concurrent-checkpoints, execution.checkpointing.min-pause and execution.checkpointing.interval-during-backlog
execution.checkpointing.interval-during-backlog
(none)DurationIf it is not null and any source reports isProcessingBacklog=true, it is the interval in which checkpoints are periodically scheduled.

Checkpoint triggering may be delayed by the settings execution.checkpointing.max-concurrent-checkpoints and execution.checkpointing.min-pause.

Note: if it is not null, the value must either be 0, which means the checkpoint is disabled during backlog, or be larger than or equal to execution.checkpointing.interval.
execution.checkpointing.local-backup.dirs
(none)StringThe config parameter defining the root directories for storing file-based state for local recovery. Local recovery currently only covers keyed state backends. If not configured it will default to <WORKING_DIR>/localState. The <WORKING_DIR> can be configured via process.taskmanager.working-dir
execution.checkpointing.local-backup.enabled
falseBooleanThis option configures local backup for the state backend, which indicates whether to make backup checkpoint on local disk. If not configured, fallback to execution.state-recovery.from-local. By default, local backup is deactivated. Local backup currently only covers keyed state backends (including both the EmbeddedRocksDBStateBackend and the HashMapStateBackend).
execution.checkpointing.max-concurrent-checkpoints
1IntegerThe maximum number of checkpoint attempts that may be in progress at the same time. If this value is n, then no checkpoints will be triggered while n checkpoint attempts are currently in flight. For the next checkpoint to be triggered, one checkpoint attempt would need to finish or expire.
execution.checkpointing.min-pause
0 msDurationThe minimal pause between checkpointing attempts. This setting defines how soon thecheckpoint coordinator may trigger another checkpoint after it becomes possible to triggeranother checkpoint with respect to the maximum number of concurrent checkpoints(see execution.checkpointing.max-concurrent-checkpoints).

If the maximum number of concurrent checkpoints is set to one, this setting makes effectively sure that a minimum amount of time passes where no checkpoint is in progress at all.
execution.checkpointing.mode
EXACTLY_ONCE

Enum

The checkpointing mode (exactly-once vs. at-least-once).

Possible values:
  • “EXACTLY_ONCE”
  • “AT_LEAST_ONCE”
execution.checkpointing.num-retained
1IntegerThe maximum number of completed checkpoints to retain.
execution.checkpointing.savepoint-dir
(none)StringThe default directory for savepoints. Used by the state backends that write savepoints to file systems (HashMapStateBackend, EmbeddedRocksDBStateBackend).
execution.checkpointing.storage
(none)StringThe checkpoint storage implementation to be used to checkpoint state.
The implementation can be specified either via their shortcut name, or via the class name of a CheckpointStorageFactory. If a factory is specified it is instantiated via its zero argument constructor and its CheckpointStorageFactory#createFromConfig(ReadableConfig, ClassLoader) method is called.
Recognized shortcut names are ‘jobmanager’ and ‘filesystem’.
‘execution.checkpointing.storage’ and ‘execution.checkpointing.dir’ are usually combined to configure the checkpoint location. By default, the checkpoint meta data and actual program state will be stored in the JobManager’s memory directly. When ‘execution.checkpointing.storage’ is set to ‘jobmanager’, if ‘execution.checkpointing.dir’ is configured, the meta data of checkpoints will be persisted to the path specified by ‘execution.checkpointing.dir’. Otherwise, the meta data will be stored in the JobManager’s memory. When ‘execution.checkpointing.storage’ is set to ‘filesystem’, a valid path must be configured to ‘execution.checkpointing.dir’, and the checkpoint meta data and actual program state will both be persisted to the path.
execution.checkpointing.timeout
10 minDurationThe maximum time that a checkpoint may take before being discarded.
execution.checkpointing.tolerable-failed-checkpoints
0IntegerThe tolerable checkpoint consecutive failure number. If set to 0, that means we do not tolerance any checkpoint failure. This only applies to the following failure reasons: IOException on the Job Manager, failures in the async phase on the Task Managers and checkpoint expiration due to a timeout. Failures originating from the sync phase on the Task Managers are always forcing failover of an affected task. Other types of checkpoint failures (such as checkpoint being subsumed) are being ignored.
execution.checkpointing.unaligned.enabled
falseBooleanEnables unaligned checkpoints, which greatly reduce checkpointing times under backpressure.

Unaligned checkpoints contain data stored in buffers as part of the checkpoint state, which allows checkpoint barriers to overtake these buffers. Thus, the checkpoint duration becomes independent of the current throughput as checkpoint barriers are effectively not embedded into the stream of data anymore.

Unaligned checkpoints can only be enabled if execution.checkpointing.mode is EXACTLY_ONCE and if execution.checkpointing.max-concurrent-checkpoints is 1
execution.checkpointing.unaligned.forced
falseBooleanForces unaligned checkpoints, particularly allowing them for iterative jobs.
execution.checkpointing.unaligned.interruptible-timers.enabled
falseBooleanAllows unaligned checkpoints to skip timers that are currently being fired. For this feature to be enabled, it must be also supported by the operator. Currently this is supported by all TableStreamOperators and CepOperator.
execution.checkpointing.unaligned.max-subtasks-per-channel-state-file
5IntegerDefines the maximum number of subtasks that share the same channel state file. It can reduce the number of small files when enable unaligned checkpoint. Each subtask will create a new channel state file when this is configured to 1.
execution.checkpointing.write-buffer-size
4096IntegerThe default size of the write buffer for the checkpoint streams that write to file systems. The actual write buffer size is determined to be the maximum of the value of this option and option ‘execution.checkpointing.data-inline-threshold’.

Recovery

KeyDefaultTypeDescription
execution.state-recovery.claim-mode
NO_CLAIM

Enum

Describes the mode how Flink should restore from the given savepoint or retained checkpoint.

Possible values:
  • “CLAIM”: Flink will take ownership of the given snapshot. It will clean the snapshot once it is subsumed by newer ones.
  • “NO_CLAIM”: Flink will not claim ownership of the snapshot files. However it will make sure it does not depend on any artefacts from the restored snapshot. In order to do that, Flink will take the first checkpoint as a full one, which means it might reupload/duplicate files that are part of the restored checkpoint.
execution.state-recovery.from-local
falseBooleanThis option configures local recovery for the state backend, which indicates whether to recovery from local snapshot.By default, local recovery is deactivated. Local recovery currently only covers keyed state backends (including both the EmbeddedRocksDBStateBackend and the HashMapStateBackend).”
execution.state-recovery.ignore-unclaimed-state
falseBooleanAllow to skip savepoint state that cannot be restored. Allow this if you removed an operator from your pipeline after the savepoint was triggered.
execution.state-recovery.path
(none)StringPath to a savepoint to restore the job from (for example hdfs:///flink/savepoint-1537).
execution.state-recovery.without-channel-state.checkpoint-id
-1LongCheckpoint id for which in-flight data should be ignored in case of the recovery from this checkpoint.

It is better to keep this value empty until there is explicit needs to restore from the specific checkpoint without in-flight data.


Debugging & Expert Tuning

The options below here are meant for expert users and for fixing/debugging problems. Most setups should not need to configure these options.

Class Loading

Flink dynamically loads the code for jobs submitted to a session cluster. In addition, Flink tries to hide many dependencies in the classpath from the application. This helps to reduce dependency conflicts between the application code and the dependencies in the classpath.

Please refer to the Debugging Classloading Docs for details.

KeyDefaultTypeDescription
classloader.check-leaked-classloader
trueBooleanFails attempts at loading classes if the user classloader of a job is used after it has terminated. This is usually caused by the classloader being leaked by lingering threads or misbehaving libraries, which may also result in the classloader being used by other jobs. This check should only be disabled if such a leak prevents further jobs from running.
classloader.fail-on-metaspace-oom-error
trueBooleanFail Flink JVM processes if ‘OutOfMemoryError: Metaspace’ is thrown while trying to load a user code class.
classloader.parent-first-patterns.additional
List<String>A (semicolon-separated) list of patterns that specifies which classes should always be resolved through the parent ClassLoader first. A pattern is a simple prefix that is checked against the fully qualified class name. These patterns are appended to “classloader.parent-first-patterns.default”.
classloader.parent-first-patterns.default
“java.”;“scala.”;“org.apache.flink.”;“com.esotericsoftware.kryo”;“org.apache.hadoop.”;“javax.annotation.”;“org.xml”;“javax.xml”;“org.apache.xerces”;“org.w3c”;“org.rocksdb.”;“org.slf4j”;“org.apache.log4j”;“org.apache.logging”;“org.apache.commons.logging”;“ch.qos.logback”List<String>A (semicolon-separated) list of patterns that specifies which classes should always be resolved through the parent ClassLoader first. A pattern is a simple prefix that is checked against the fully qualified class name. This setting should generally not be modified. To add another pattern we recommend to use “classloader.parent-first-patterns.additional” instead.
classloader.resolve-order
“child-first”StringDefines the class resolution strategy when loading classes from user code, meaning whether to first check the user code jar (“child-first”) or the application classpath (“parent-first”). The default settings indicate to load classes first from the user code jar, which means that user code jars can include and load different dependencies than Flink uses (transitively).

Advanced Options for the debugging

KeyDefaultTypeDescription
jmx.server.port
(none)StringThe port range for the JMX server to start the registry. The port config can be a single port: “9123”, a range of ports: “50100-50200”, or a list of ranges and ports: “50100-50200,50300-50400,51234”.
This option overrides metrics.reporter.*.port option.

Advanced Checkpointing Options

KeyDefaultTypeDescription
execution.checkpointing.create-subdir
trueBooleanWhether to create sub-directories named by job id under the ‘execution.checkpointing.dir‘ to store the data files and meta data of checkpoints. The default value is true to enable user could run several jobs with the same checkpoint directory at the same time. If this value is set to false, pay attention not to run several jobs with the same directory simultaneously.
WARNING: This is an advanced configuration. If set to false, users must ensure that no multiple jobs are run with the same checkpoint directory, and that no files exist other than those necessary for the restoration of the current job when starting a new job.
execution.checkpointing.data-inline-threshold
20 kbMemorySizeThe minimum size of state data files. All state chunks smaller than that are stored inline in the root checkpoint metadata file. The max memory threshold for this configuration is 1MB.
execution.checkpointing.write-buffer-size
4096IntegerThe default size of the write buffer for the checkpoint streams that write to file systems. The actual write buffer size is determined to be the maximum of the value of this option and option ‘execution.checkpointing.data-inline-threshold’.

State Latency Tracking Options

KeyDefaultTypeDescription
state.latency-track.history-size
128IntegerDefines the number of measured latencies to maintain at each state access operation.
state.latency-track.keyed-state-enabled
falseBooleanWhether to track latency of keyed state operations, e.g value state put/get/clear.
state.latency-track.sample-interval
100IntegerThe sample interval of latency track once ‘state.latency-track.keyed-state-enabled’ is enabled. The default value is 100, which means we would track the latency every 100 access requests.
state.latency-track.state-name-as-variable
trueBooleanWhether to expose state name as a variable if tracking latency.

Advanced RocksDB State Backends Options

Advanced options to tune RocksDB and RocksDB checkpoints.

KeyDefaultTypeDescription
state.backend.rocksdb.checkpoint.transfer.thread.num
4IntegerThe number of threads (per stateful operator) used to transfer (download and upload) files in RocksDBStateBackend.If negative, the common (TM) IO thread pool is used (see cluster.io-pool.size)
state.backend.rocksdb.localdir
(none)StringThe local directory (on the TaskManager) where RocksDB puts its files. Per default, it will be <WORKING_DIR>/tmp. See process.taskmanager.working-dir for more details.
state.backend.rocksdb.options-factory
(none)StringThe options factory class for users to add customized options in DBOptions and ColumnFamilyOptions for RocksDB. If set, the RocksDB state backend will load the class and apply configs to DBOptions and ColumnFamilyOptions after loading ones from ‘RocksDBConfigurableOptions’ and pre-defined options.
state.backend.rocksdb.predefined-options
“DEFAULT”StringThe predefined settings for RocksDB DBOptions and ColumnFamilyOptions by Flink community. Current supported candidate predefined-options are DEFAULT, SPINNING_DISK_OPTIMIZED, SPINNING_DISK_OPTIMIZED_HIGH_MEM or FLASH_SSD_OPTIMIZED. Note that user customized options and options from the RocksDBOptionsFactory are applied on top of these predefined ones.

State Changelog Options

Please refer to State Backends for information on using State Changelog.

KeyDefaultTypeDescription
state.changelog.enabled
falseBooleanWhether to enable state backend to write state changes to StateChangelog. If this config is not set explicitly, it means no preference for enabling the change log, and the value in lower config level will take effect. The default value ‘false’ here means if no value set (job or cluster), the change log will not be enabled.
state.changelog.max-failures-allowed
3IntegerMax number of consecutive materialization failures allowed.
state.changelog.periodic-materialize.enabled
trueBooleanDefines whether to enable periodic materialization, all changelogs will not be truncated which may increase the space of checkpoint if disabled
state.changelog.periodic-materialize.interval
10 minDurationDefines the interval in milliseconds to perform periodic materialization for state backend. It only takes effect when state.changelog.periodic-materialize.enabled is true
state.changelog.storage
“memory”StringThe storage to be used to store state changelog.
The implementation can be specified via their shortcut name.
The list of recognized shortcut names currently includes ‘memory’ and ‘filesystem’.

FileSystem-based Changelog options

These settings take effect when the state.changelog.storage is set to filesystem (see above).

KeyDefaultTypeDescription
state.changelog.dstl.dfs.base-path
(none)StringBase path to store changelog files.
state.changelog.dstl.dfs.batch.persist-delay
10 msDurationDelay before persisting changelog after receiving persist request (on checkpoint). Minimizes the number of files and requests if multiple operators (backends) or sub-tasks are using the same store. Correspondingly increases checkpoint time (async phase).
state.changelog.dstl.dfs.batch.persist-size-threshold
10 mbMemorySizeSize threshold for state changes that were requested to be persisted but are waiting for state.changelog.dstl.dfs.batch.persist-delay (from all operators). . Once reached, accumulated changes are persisted immediately. This is different from state.changelog.dstl.dfs.preemptive-persist-threshold as it happens AFTER the checkpoint and potentially for state changes of multiple operators. Must not exceed in-flight data limit (see below)
state.changelog.dstl.dfs.compression.enabled
falseBooleanWhether to enable compression when serializing changelog.
state.changelog.dstl.dfs.discard.num-threads
1IntegerNumber of threads to use to discard changelog (e.g. pre-emptively uploaded unused state).
state.changelog.dstl.dfs.download.local-cache.idle-timeout-ms
10 minDurationMaximum idle time for cache files of distributed changelog file, after which the cache files will be deleted.
state.changelog.dstl.dfs.preemptive-persist-threshold
5 mbMemorySizeSize threshold for state changes of a single operator beyond which they are persisted pre-emptively without waiting for a checkpoint. Improves checkpointing time by allowing quasi-continuous uploading of state changes (as opposed to uploading all accumulated changes on checkpoint).
state.changelog.dstl.dfs.upload.buffer-size
1 mbMemorySizeBuffer size used when uploading change sets
state.changelog.dstl.dfs.upload.max-attempts
3IntegerMaximum number of attempts (including the initial one) to perform a particular upload. Only takes effect if state.changelog.dstl.dfs.upload.retry-policy is fixed.
state.changelog.dstl.dfs.upload.max-in-flight
100 mbMemorySizeMax amount of data allowed to be in-flight. Upon reaching this limit the task will be back-pressured. I.e., snapshotting will block; normal processing will block if state.changelog.dstl.dfs.preemptive-persist-threshold is set and reached. The limit is applied to the total size of in-flight changes if multiple operators/backends are using the same changelog storage. Must be greater than or equal to state.changelog.dstl.dfs.batch.persist-size-threshold
state.changelog.dstl.dfs.upload.next-attempt-delay
500 msDurationDelay before the next attempt (if the failure was not caused by a timeout).
state.changelog.dstl.dfs.upload.num-threads
5IntegerNumber of threads to use for upload.
state.changelog.dstl.dfs.upload.retry-policy
“fixed”StringRetry policy for the failed uploads (in particular, timed out). Valid values: none, fixed.
state.changelog.dstl.dfs.upload.timeout
1 sDurationTime threshold beyond which an upload is considered timed out. If a new attempt is made but this upload succeeds earlier then this upload result will be used. May improve upload times if tail latencies of upload requests are significantly high. Only takes effect if state.changelog.dstl.dfs.upload.retry-policy is fixed. Please note that timeout * max_attempts should be less than execution.checkpointing.timeout

RocksDB Configurable Options

These options give fine-grained control over the behavior and resources of ColumnFamilies. With the introduction of state.backend.rocksdb.memory.managed and state.backend.rocksdb.memory.fixed-per-slot (Apache Flink 1.10), it should be only necessary to use the options here for advanced performance tuning. These options here can also be specified in the application program via RocksDBStateBackend.setRocksDBOptions(RocksDBOptionsFactory).

KeyDefaultTypeDescription
state.backend.rocksdb.block.blocksize
4 kbMemorySizeThe approximate size (in bytes) of user data packed per block. The default blocksize is ‘4KB’.
state.backend.rocksdb.block.cache-size
8 mbMemorySizeThe amount of the cache for data blocks in RocksDB. The default block-cache size is ‘8MB’.
state.backend.rocksdb.block.metadata-blocksize
4 kbMemorySizeApproximate size of partitioned metadata packed per block. Currently applied to indexes block when partitioned index/filters option is enabled. The default blocksize is ‘4KB’.
state.backend.rocksdb.bloom-filter.bits-per-key
10.0DoubleBits per key that bloom filter will use, this only take effect when bloom filter is used. The default value is 10.0.
state.backend.rocksdb.bloom-filter.block-based-mode
falseBooleanIf true, RocksDB will use block-based filter instead of full filter, this only take effect when bloom filter is used. The default value is ‘false’.
state.backend.rocksdb.compaction.level.max-size-level-base
256 mbMemorySizeThe upper-bound of the total size of level base files in bytes. The default value is ‘256MB’.
state.backend.rocksdb.compaction.level.target-file-size-base
64 mbMemorySizeThe target file size for compaction, which determines a level-1 file size. The default value is ‘64MB’.
state.backend.rocksdb.compaction.level.use-dynamic-size
falseBooleanIf true, RocksDB will pick target size of each level dynamically. From an empty DB, RocksDB would make last level the base level, which means merging L0 data into the last level, until it exceeds max_bytes_for_level_base. And then repeat this process for second last level and so on. The default value is ‘false’. For more information, please refer to RocksDB’s doc.
state.backend.rocksdb.compaction.style
LEVEL

Enum

The specified compaction style for DB. Candidate compaction style is LEVEL, FIFO, UNIVERSAL or NONE, and Flink chooses ‘LEVEL’ as default style.

Possible values:
  • “LEVEL”
  • “UNIVERSAL”
  • “FIFO”
  • “NONE”
state.backend.rocksdb.compression.per.level
SNAPPY_COMPRESSION

List<Enum>

A semicolon-separated list of Compression Type. Different levels can have different compression policies. In many cases, lower levels use fast compression algorithms, while higher levels with more data use slower but more effective compression algorithms. The N th element in the List corresponds to the compression type of the level N-1When state.backend.rocksdb.compaction.level.use-dynamic-size is true, compression_per_level[0] still determines L0, but other elements are based on the base level and may not match the level seen in the info log
Note: If the List size is smaller than the level number, the undefined lower level uses the last Compression Type in the List
Some commonly used compression algorithms for candidates include NO_COMPRESSION ,SNAPPY_COMPRESSION and LZ4_COMPRESSION
The default value is SNAPPY_COMPRESSION, which means that all data uses the Snappy compression algorithm.Likewise, if set to NO_COMPRESSION , means that all data is not compressed, which will achieve faster speed but will bring some space amplification.In addition, if we need to consider both spatial amplification and performance, we can also set it to ‘NO_COMPRESSION;NO_COMPRESSION;LZ4_COMPRESSION‘, which means that L0 and L1 data will not be compressed, and other data will be compressed using LZ4.

Possible values:
  • “NO_COMPRESSION”
  • “SNAPPY_COMPRESSION”
  • “ZLIB_COMPRESSION”
  • “BZLIB2_COMPRESSION”
  • “LZ4_COMPRESSION”
  • “LZ4HC_COMPRESSION”
  • “XPRESS_COMPRESSION”
  • “ZSTD_COMPRESSION”
  • “DISABLE_COMPRESSION_OPTION”
state.backend.rocksdb.files.open
-1IntegerThe maximum number of open files (per stateful operator) that can be used by the DB, ‘-1’ means no limit. The default value is ‘-1’.
state.backend.rocksdb.incremental-restore-async-compact-after-rescale
falseBooleanIf true, an async compaction of RocksDB is started after every restore after which we detect keys (including tombstones) in the database that are outside the key-groups range of the backend.
state.backend.rocksdb.log.dir
(none)StringThe directory for RocksDB’s information logging files. If empty (Flink default setting), log files will be in the same directory as the Flink log. If non-empty, this directory will be used and the data directory’s absolute path will be used as the prefix of the log file name. If setting this option as a non-existing location, e.g ‘/dev/null’, RocksDB will then create the log under its own database folder as before.
state.backend.rocksdb.log.file-num
4IntegerThe maximum number of files RocksDB should keep for information logging (Default setting: 4).
state.backend.rocksdb.log.level
INFO_LEVEL

Enum

The specified information logging level for RocksDB. If unset, Flink will use INFO_LEVEL.
Note: RocksDB info logs will not be written to the TaskManager logs and there is no rolling strategy, unless you configure state.backend.rocksdb.log.dir, state.backend.rocksdb.log.max-file-size, and state.backend.rocksdb.log.file-num accordingly. Without a rolling strategy, long-running tasks may lead to uncontrolled disk space usage if configured with increased log levels!
There is no need to modify the RocksDB log level, unless for troubleshooting RocksDB.

Possible values:
  • “DEBUG_LEVEL”
  • “INFO_LEVEL”
  • “WARN_LEVEL”
  • “ERROR_LEVEL”
  • “FATAL_LEVEL”
  • “HEADER_LEVEL”
  • “NUM_INFO_LOG_LEVELS”
state.backend.rocksdb.log.max-file-size
25 mbMemorySizeThe maximum size of RocksDB’s file used for information logging. If the log files becomes larger than this, a new file will be created. If 0, all logs will be written to one log file. The default maximum file size is ‘25MB’.
state.backend.rocksdb.rescaling.use-delete-files-in-range
falseBooleanIf true, during rescaling, the deleteFilesInRange API will be invoked to clean up the useless files so that local disk space can be reclaimed more promptly.
state.backend.rocksdb.restore-overlap-fraction-threshold
0.0DoubleThe threshold of overlap fraction between the handle’s key-group range and target key-group range. When restore base DB, only the handle which overlap fraction greater than or equal to threshold has a chance to be an initial handle. The default value is 0.0, there is always a handle will be selected for initialization.
state.backend.rocksdb.thread.num
2IntegerThe maximum number of concurrent background flush and compaction jobs (per stateful operator). The default value is ‘2’.
state.backend.rocksdb.use-bloom-filter
falseBooleanIf true, every newly created SST file will contain a Bloom filter. It is disabled by default.
state.backend.rocksdb.use-ingest-db-restore-mode
falseBooleanA recovery mode that directly clips and ingests multiple DBs during state recovery if the keys in the SST files does not exceed the declared key-group range.
state.backend.rocksdb.write-batch-size
2 mbMemorySizeThe max size of the consumed memory for RocksDB batch write, will flush just based on item count if this config set to 0.
state.backend.rocksdb.writebuffer.count
2IntegerThe maximum number of write buffers that are built up in memory. The default value is ‘2’.
state.backend.rocksdb.writebuffer.number-to-merge
1IntegerThe minimum number of write buffers that will be merged together before writing to storage. The default value is ‘1’.
state.backend.rocksdb.writebuffer.size
64 mbMemorySizeThe amount of data built up in memory (backed by an unsorted log on disk) before converting to a sorted on-disk files. The default writebuffer size is ‘64MB’.

Advanced Fault Tolerance Options

These parameters can help with problems related to failover and to components erroneously considering each other as failed.

KeyDefaultTypeDescription
cluster.io-pool.size
(none)IntegerThe size of the IO executor pool used by the cluster to execute blocking IO operations (Master as well as TaskManager processes). By default it will use 4 the number of CPU cores (hardware contexts) that the cluster process has access to. Increasing the pool size allows to run more IO operations concurrently.
cluster.registration.error-delay
10 sDurationThe pause made after an registration attempt caused an exception (other than timeout).
cluster.registration.initial-timeout
100 msDurationInitial registration timeout between cluster components.
cluster.registration.max-timeout
30 sDurationMaximum registration timeout between cluster components.
cluster.registration.refused-registration-delay
30 sDurationThe pause made after the registration attempt was refused.
cluster.services.shutdown-timeout
30 sDurationThe shutdown timeout for cluster services like executors.
heartbeat.interval
10 sDurationTime interval between heartbeat RPC requests from the sender to the receiver side.
heartbeat.rpc-failure-threshold
2IntegerThe number of consecutive failed heartbeat RPCs until a heartbeat target is marked as unreachable. Failed heartbeat RPCs can be used to detect dead targets faster because they no longer receive the RPCs. The detection time is heartbeat.interval heartbeat.rpc-failure-threshold. In environments with a flaky network, setting this value too low can produce false positives. In this case, we recommend to increase this value, but not higher than heartbeat.timeout / heartbeat.interval. The mechanism can be disabled by setting this option to -1
heartbeat.timeout
50 sDurationTimeout for requesting and receiving heartbeats for both sender and receiver sides.
jobmanager.execution.failover-strategy
“region”StringThis option specifies how the job computation recovers from task failures. Accepted values are:
  • ‘full’: Restarts all tasks to recover the job.
  • ‘region’: Restarts all tasks that could be affected by the task failure. More details can be found here.

Advanced Cluster Options

KeyDefaultTypeDescription
cluster.intercept-user-system-exit
DISABLED

Enum

Flag to check user code exiting system by terminating JVM (e.g., System.exit()). Note that this configuration option can interfere with cluster.processes.halt-on-fatal-error: In intercepted user-code, a call to System.exit() will not cause the JVM to halt, when THROW is configured.

Possible values:
  • “DISABLED”: Flink is not monitoring or intercepting calls to System.exit()
  • “LOG”: Log exit attempt with stack trace but still allowing exit to be performed
  • “THROW”: Throw exception when exit is attempted disallowing JVM termination
cluster.processes.halt-on-fatal-error
falseBooleanWhether processes should halt on fatal errors instead of performing a graceful shutdown. In some environments (e.g. Java 8 with the G1 garbage collector), a regular graceful shutdown can lead to a JVM deadlock. See FLINK-16510 for details.
cluster.thread-dump.stacktrace-max-depth
50IntegerThe maximum stacktrace depth of TaskManager and JobManager’s thread dump web-frontend displayed.
cluster.uncaught-exception-handling
LOG

Enum

Defines whether cluster will handle any uncaught exceptions by just logging them (LOG mode), or by failing job (FAIL mode)

Possible values:
  • “LOG”
  • “FAIL”
process.jobmanager.working-dir
(none)StringWorking directory for Flink JobManager processes. The working directory can be used to store information that can be used upon process recovery. If not configured, then it will default to process.working-dir.
process.taskmanager.working-dir
(none)StringWorking directory for Flink TaskManager processes. The working directory can be used to store information that can be used upon process recovery. If not configured, then it will default to process.working-dir.
process.working-dir
io.tmp.dirsStringLocal working directory for Flink processes. The working directory can be used to store information that can be used upon process recovery. If not configured, then it will default to a randomly picked temporary directory defined via io.tmp.dirs.

Advanced JobManager Options

KeyDefaultTypeDescription
jobmanager.future-pool.size
(none)IntegerThe size of the future thread pool to execute future callbacks for all spawned JobMasters. If no value is specified, then Flink defaults to the number of available CPU cores.
jobmanager.io-pool.size
(none)IntegerThe size of the IO thread pool to run blocking operations for all spawned JobMasters. This includes recovery and completion of checkpoints. Increase this value if you experience slow checkpoint operations when running many jobs. If no value is specified, then Flink defaults to the number of available CPU cores.

Advanced Scheduling Options

These parameters can help with fine-tuning scheduling for specific situations.

KeyDefaultTypeDescription
execution.batch.adaptive.auto-parallelism.avg-data-volume-per-task
16 mbMemorySizeThe average size of data volume to expect each task instance to process if jobmanager.scheduler has been set to AdaptiveBatch. Note that when data skew occurs or the decided parallelism reaches the execution.batch.adaptive.auto-parallelism.max-parallelism (due to too much data), the data actually processed by some tasks may far exceed this value.
execution.batch.adaptive.auto-parallelism.default-source-parallelism
(none)IntegerThe default parallelism of source vertices or the upper bound of source parallelism to set adaptively if jobmanager.scheduler has been set to AdaptiveBatch. Note that execution.batch.adaptive.auto-parallelism.max-parallelism will be used if this configuration is not configured. If execution.batch.adaptive.auto-parallelism.max-parallelism is not set either, then the default parallelism set via parallelism.default will be used instead.
execution.batch.adaptive.auto-parallelism.enabled
trueBooleanIf true, Flink will automatically decide the parallelism of operators in batch jobs.
execution.batch.adaptive.auto-parallelism.max-parallelism
128IntegerThe upper bound of allowed parallelism to set adaptively if jobmanager.scheduler has been set to AdaptiveBatch
execution.batch.adaptive.auto-parallelism.min-parallelism
1IntegerThe lower bound of allowed parallelism to set adaptively if jobmanager.scheduler has been set to AdaptiveBatch
execution.batch.job-recovery.enabled
falseBooleanA flag to enable or disable the job recovery. If enabled, batch jobs can resume with previously generated intermediate results after job master restarts due to failures, thereby preserving the progress.
execution.batch.job-recovery.previous-worker.recovery.timeout
30 sDurationThe timeout for a new job master to wait for the previous worker to reconnect.A reconnected worker will transmit the details of its produced intermediate results to the new job master, enabling the job master to reuse these results.
execution.batch.job-recovery.snapshot.min-pause
3 minDurationThe minimal pause between snapshots taken by operator coordinator or other components. It is used to avoid performance degradation due to excessive snapshot frequency.
execution.batch.speculative.block-slow-node-duration
1 minDurationControls how long an detected slow node should be blocked for.
execution.batch.speculative.enabled
falseBooleanControls whether to enable speculative execution.
execution.batch.speculative.max-concurrent-executions
2IntegerControls the maximum number of execution attempts of each operator that can execute concurrently, including the original one and speculative ones.
job-event.store.write-buffer.flush-interval
1 sDurationThe flush interval of JobEventStore write buffers. Buffer contents will be flushed to external file system regularly with regard to this value.
job-event.store.write-buffer.size
1 mbMemorySizeThe size of the write buffer of JobEventStore. The content will be flushed to external file system once the buffer is full
jobmanager.adaptive-scheduler.min-parallelism-increase
1IntegerConfigure the minimum increase in parallelism for a job to scale up.
jobmanager.adaptive-scheduler.resource-stabilization-timeout
10 sDurationThe resource stabilization timeout defines the time the JobManager will wait if fewer than the desired but sufficient resources are available. The timeout starts once sufficient resources for running the job are available. Once this timeout has passed, the job will start executing with the available resources.
If scheduler-mode is configured to REACTIVE, this configuration value will default to 0, so that jobs are starting immediately with the available resources.
jobmanager.adaptive-scheduler.resource-wait-timeout
5 minDurationThe maximum time the JobManager will wait to acquire all required resources after a job submission or restart. Once elapsed it will try to run the job with a lower parallelism, or fail if the minimum amount of resources could not be acquired.
Increasing this value will make the cluster more resilient against temporary resources shortages (e.g., there is more time for a failed TaskManager to be restarted).
Setting a negative duration will disable the resource timeout: The JobManager will wait indefinitely for resources to appear.
If scheduler-mode is configured to REACTIVE, this configuration value will default to a negative value to disable the resource timeout.
jobmanager.adaptive-scheduler.scaling-interval.max
(none)DurationDetermines the maximum interval time after which a scaling operation is forced even if the jobmanager.adaptive-scheduler.min-parallelism-increase aren’t met. The scaling operation will be ignored when the resource hasn’t changed. This option is disabled by default.
jobmanager.adaptive-scheduler.scaling-interval.min
30 sDurationDetermines the minimum time between scaling operations.
jobmanager.partition.hybrid.partition-data-consume-constraint
(none)

Enum

Controls the constraint that hybrid partition data can be consumed. Note that this option is allowed only when jobmanager.scheduler has been set to AdaptiveBatch. Accepted values are:
  • ALL_PRODUCERS_FINISHED‘: hybrid partition data can be consumed only when all producers are finished.
  • ONLY_FINISHED_PRODUCERS‘: hybrid partition data can be consumed when its producer is finished.
  • UNFINISHED_PRODUCERS‘: hybrid partition data can be consumed even if its producer is un-finished.


Possible values:
  • “ALL_PRODUCERS_FINISHED”
  • “ONLY_FINISHED_PRODUCERS”
  • “UNFINISHED_PRODUCERS”
jobmanager.scheduler
Default

Enum

Determines which scheduler implementation is used to schedule tasks. If this option is not explicitly set, batch jobs will use the ‘AdaptiveBatch’ scheduler as the default, while streaming jobs will default to the ‘Default’ scheduler.

Possible values:
  • “Default”: Default scheduler
  • “Adaptive”: Adaptive scheduler. More details can be found here.
  • “AdaptiveBatch”: Adaptive batch scheduler. More details can be found here.
scheduler-mode
(none)

Enum

Determines the mode of the scheduler. Note that scheduler-mode=REACTIVE is only supported by standalone application deployments, not by active resource managers (YARN, Kubernetes) or session clusters.

Possible values:
  • “REACTIVE”
slot.idle.timeout
50 sDurationThe timeout for a idle slot in Slot Pool.
slot.request.timeout
5 minDurationThe timeout for requesting a slot from Slot Pool.
slotmanager.max-total-resource.cpu
(none)DoubleMaximum cpu cores the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.max’.
slotmanager.max-total-resource.memory
(none)MemorySizeMaximum memory size the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.max’.
slotmanager.min-total-resource.cpu
(none)DoubleMinimum cpu cores the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.min’.
slotmanager.min-total-resource.memory
(none)MemorySizeMinimum memory size the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.min’.
slotmanager.number-of-slots.max
infiniteIntegerDefines the maximum number of slots that the Flink cluster allocates. This configuration option is meant for limiting the resource consumption for batch workloads. It is not recommended to configure this option for streaming workloads, which may fail if there are not enough slots. Note that this configuration option does not take effect for standalone clusters, where how many slots are allocated is not controlled by Flink.
slotmanager.number-of-slots.min
0IntegerDefines the minimum number of slots that the Flink cluster allocates. This configuration option is meant for cluster to initialize certain workers in best efforts when starting. This can be used to speed up a job startup process. Note that this configuration option does not take effect for standalone clusters, where how many slots are allocated is not controlled by Flink.
slow-task-detector.check-interval
1 sDurationThe interval to check slow tasks.
slow-task-detector.execution-time.baseline-lower-bound
1 minDurationThe lower bound of slow task detection baseline.
slow-task-detector.execution-time.baseline-multiplier
1.5DoubleThe multiplier to calculate the slow tasks detection baseline. Given that the parallelism is N and the ratio is R, define T as the median of the first NR finished tasks’ execution time. The baseline will be TM, where M is the multiplier of the baseline. Note that the execution time will be weighted with the task’s input bytes to ensure the accuracy of the detection if data skew occurs.
slow-task-detector.execution-time.baseline-ratio
0.75DoubleThe finished execution ratio threshold to calculate the slow tasks detection baseline. Given that the parallelism is N and the ratio is R, define T as the median of the first NR finished tasks’ execution time. The baseline will be TM, where M is the multiplier of the baseline. Note that the execution time will be weighted with the task’s input bytes to ensure the accuracy of the detection if data skew occurs.
taskmanager.load-balance.mode
NONE

Enum

Mode for the load-balance allocation strategy across all available TaskManagers.
  • The SLOTS mode tries to spread out the slots evenly across all available TaskManagers.
  • The NONE mode is the default mode without any specified strategy.


Possible values:
  • “NONE”
  • “SLOTS”

Advanced High-availability Options

KeyDefaultTypeDescription
high-availability.jobmanager.port
“0”StringThe port (range) used by the Flink Master for its RPC connections in highly-available setups. In highly-available setups, this value is used instead of ‘jobmanager.rpc.port’.A value of ‘0’ means that a random free port is chosen. TaskManagers discover this port through the high-availability services (leader election), so a random port or a port range works without requiring any additional means of service discovery.

Advanced High-availability ZooKeeper Options

KeyDefaultTypeDescription
high-availability.zookeeper.client.acl
“open”StringDefines the ACL (open|creator) to be configured on ZK node. The configuration value can be set to “creator” if the ZooKeeper server configuration has the “authProvider” property mapped to use SASLAuthenticationProvider and the cluster is configured to run in secure mode (Kerberos).
high-availability.zookeeper.client.connection-timeout
15 sDurationDefines the connection timeout for ZooKeeper.
high-availability.zookeeper.client.ensemble-tracker
trueBooleanDefines whether Curator should enable ensemble tracker. This can be useful in certain scenarios in which CuratorFramework is accessing to ZK clusters via load balancer or Virtual IPs. Default Curator EnsembleTracking logic watches CuratorEventType.GET_CONFIG events and changes ZooKeeper connection string. It is not desired behaviour when ZooKeeper is running under the Virtual IPs. Under certain configurations EnsembleTracking can lead to setting of ZooKeeper connection string with unresolvable hostnames.
high-availability.zookeeper.client.max-retry-attempts
3IntegerDefines the number of connection retries before the client gives up.
high-availability.zookeeper.client.retry-wait
5 sDurationDefines the pause between consecutive retries.
high-availability.zookeeper.client.session-timeout
1 minDurationDefines the session timeout for the ZooKeeper session.
high-availability.zookeeper.client.tolerate-suspended-connections
falseBooleanDefines whether a suspended ZooKeeper connection will be treated as an error that causes the leader information to be invalidated or not. In case you set this option to true, Flink will wait until a ZooKeeper connection is marked as lost before it revokes the leadership of components. This has the effect that Flink is more resilient against temporary connection instabilities at the cost of running more likely into timing issues with ZooKeeper.
high-availability.zookeeper.path.jobgraphs
“/jobgraphs”StringZooKeeper root path (ZNode) for job graphs

Advanced High-availability Kubernetes Options

KeyDefaultTypeDescription
high-availability.kubernetes.leader-election.lease-duration
15 sDurationDefine the lease duration for the Kubernetes leader election. The leader will continuously renew its lease time to indicate its existence. And the followers will do a lease checking against the current time. “renewTime + leaseDuration > now” means the leader is alive.
high-availability.kubernetes.leader-election.renew-deadline
15 sDurationDefines the deadline duration when the leader tries to renew the lease. The leader will give up its leadership if it cannot successfully renew the lease in the given time.
high-availability.kubernetes.leader-election.retry-period
5 sDurationDefines the pause duration between consecutive retries. All the contenders, including the current leader and all other followers, periodically try to acquire/renew the leadership if possible at this interval.

Advanced SSL Security Options

KeyDefaultTypeDescription
security.ssl.internal.close-notify-flush-timeout
-1IntegerThe timeout (in ms) for flushing the close_notify that was triggered by closing a channel. If the close_notify was not flushed in the given timeout the channel will be closed forcibly. (-1 = use system default)
security.ssl.internal.handshake-timeout
-1IntegerThe timeout (in ms) during SSL handshake. (-1 = use system default)
security.ssl.internal.session-cache-size
-1IntegerThe size of the cache used for storing SSL session objects. According to here, you should always set this to an appropriate number to not run into a bug with stalling IO threads during garbage collection. (-1 = use system default).
security.ssl.internal.session-timeout
-1IntegerThe timeout (in ms) for the cached SSL session objects. (-1 = use system default)
security.ssl.provider
“JDK”StringThe SSL engine provider to use for the ssl transport:
  • JDK: default Java-based SSL engine
  • OPENSSL: openSSL-based SSL engine using system libraries
OPENSSL is based on netty-tcnative and comes in two flavours:
  • dynamically linked: This will use your system’s openSSL libraries (if compatible) and requires opt/flink-shaded-netty-tcnative-dynamic-*.jar to be copied to lib/
  • statically linked: Due to potential licensing issues with openSSL (see LEGAL-393), we cannot ship pre-built libraries. However, you can build the required library yourself and put it into lib/:
    git clone https://github.com/apache/flink-shaded.git && cd flink-shaded && mvn clean package -Pinclude-netty-tcnative-static -pl flink-shaded-netty-tcnative-static

Advanced Options for the REST endpoint and Client

KeyDefaultTypeDescription
rest.async.store-duration
5 minDurationMaximum duration that the result of an async operation is stored. Once elapsed the result of the operation can no longer be retrieved.
rest.await-leader-timeout
30 sDurationThe time that the client waits for the leader address, e.g., Dispatcher or WebMonitorEndpoint
rest.cache.checkpoint-statistics.size
1000IntegerMaximum number of entries in the checkpoint statistics cache.
rest.cache.checkpoint-statistics.timeout
3 sDurationDuration from write after which cached checkpoints statistics are cleaned up. For backwards compatibility, if no value is configured, web.refresh-interval will be used instead.
rest.client.max-content-length
104857600IntegerThe maximum content length in bytes that the client will handle.
rest.connection-timeout
15 sDurationThe maximum time for the client to establish a TCP connection.
rest.flamegraph.cleanup-interval
10 minDurationTime after which cached stats are cleaned up if not accessed. It can be specified using notation: “100 s”, “10 m”.
rest.flamegraph.delay-between-samples
50 msDurationDelay between individual stack trace samples taken for building a FlameGraph. It can be specified using notation: “100 ms”, “1 s”.
rest.flamegraph.enabled
falseBooleanEnables the experimental flame graph feature.
rest.flamegraph.num-samples
100IntegerNumber of samples to take to build a FlameGraph.
rest.flamegraph.refresh-interval
1 minDurationTime after which available stats are deprecated and need to be refreshed (by resampling). It can be specified using notation: “30 s”, “1 m”.
rest.flamegraph.stack-depth
100IntegerMaximum depth of stack traces used to create FlameGraphs.
rest.idleness-timeout
5 minDurationThe maximum time for a connection to stay idle before failing.
rest.profiling.dir
System.getProperty(“java.io.tmpdir”)StringProfiling result storing directory.
rest.profiling.duration-max
5 minDurationMaximum profiling duration for each profiling request. Any profiling request’s duration exceeding this value will not be accepted.
rest.profiling.enabled
falseBooleanEnables the experimental profiler feature.
rest.profiling.history-size
10IntegerMaximum profiling history instance to be maintained for JobManager or each TaskManager. The oldest instance will be removed on a rolling basis when the history size exceeds this value.
rest.retry.delay
3 sDurationThe time that the client waits between retries (See also rest.retry.max-attempts).
rest.retry.max-attempts
20IntegerThe number of retries the client will attempt if a retryable operations fails.
rest.server.max-content-length
104857600IntegerThe maximum content length in bytes that the server will handle.
rest.server.numThreads
4IntegerThe number of threads for the asynchronous processing of requests.
rest.server.thread-priority
5IntegerThread priority of the REST server’s executor for processing asynchronous requests. Lowering the thread priority will give Flink’s main components more CPU time whereas increasing will allocate more time for the REST server’s processing.
KeyDefaultTypeDescription
web.access-control-allow-origin
“*”StringAccess-Control-Allow-Origin header for all responses from the web-frontend.
web.cancel.enable
trueBooleanFlag indicating whether jobs can be canceled from the web-frontend.
web.checkpoints.history
10IntegerNumber of checkpoints to remember for recent history.
web.exception-history-size
16IntegerThe maximum number of failures collected by the exception history per job.
web.history
5IntegerNumber of archived jobs for the JobManager.
web.log.path
(none)StringPath to the log file (may be in /log for standalone but under log directory when using YARN).
web.refresh-interval
3 sDurationRefresh interval for the web-frontend.
web.rescale.enable
trueBooleanFlag indicating whether jobs can be rescaled from the web-frontend.
web.submit.enable
trueBooleanFlag indicating whether jobs can be uploaded and run from the web-frontend.
web.timeout
10 minDurationTimeout for asynchronous operations by the web monitor.
web.tmpdir
System.getProperty(“java.io.tmpdir”)StringLocal directory that is used by the REST API for temporary files.
web.upload.dir
(none)StringLocal directory that is used by the REST API for storing uploaded jars. If not specified a dynamic directory will be created under web.tmpdir.

Full JobManager Options

JobManager

KeyDefaultTypeDescription
jobmanager.adaptive-scheduler.min-parallelism-increase
1IntegerConfigure the minimum increase in parallelism for a job to scale up.
jobmanager.adaptive-scheduler.resource-stabilization-timeout
10 sDurationThe resource stabilization timeout defines the time the JobManager will wait if fewer than the desired but sufficient resources are available. The timeout starts once sufficient resources for running the job are available. Once this timeout has passed, the job will start executing with the available resources.
If scheduler-mode is configured to REACTIVE, this configuration value will default to 0, so that jobs are starting immediately with the available resources.
jobmanager.adaptive-scheduler.resource-wait-timeout
5 minDurationThe maximum time the JobManager will wait to acquire all required resources after a job submission or restart. Once elapsed it will try to run the job with a lower parallelism, or fail if the minimum amount of resources could not be acquired.
Increasing this value will make the cluster more resilient against temporary resources shortages (e.g., there is more time for a failed TaskManager to be restarted).
Setting a negative duration will disable the resource timeout: The JobManager will wait indefinitely for resources to appear.
If scheduler-mode is configured to REACTIVE, this configuration value will default to a negative value to disable the resource timeout.
jobmanager.adaptive-scheduler.scaling-interval.max
(none)DurationDetermines the maximum interval time after which a scaling operation is forced even if the jobmanager.adaptive-scheduler.min-parallelism-increase aren’t met. The scaling operation will be ignored when the resource hasn’t changed. This option is disabled by default.
jobmanager.adaptive-scheduler.scaling-interval.min
30 sDurationDetermines the minimum time between scaling operations.
jobmanager.archive.fs.dir
(none)StringDirectory for JobManager to store the archives of completed jobs.
jobmanager.bind-host
(none)StringThe local address of the network interface that the job manager binds to. If not configured, ‘0.0.0.0’ will be used.
jobmanager.execution.attempts-history-size
16IntegerThe maximum number of historical execution attempts kept in history.
jobmanager.execution.failover-strategy
“region”StringThis option specifies how the job computation recovers from task failures. Accepted values are:
  • ‘full’: Restarts all tasks to recover the job.
  • ‘region’: Restarts all tasks that could be affected by the task failure. More details can be found here.
jobmanager.failure-enrichers
(none)StringAn optional list of failure enricher names. If empty, NO failure enrichers will be started. If configured, only enrichers whose name matches any of the names in the list will be started.
jobmanager.future-pool.size
(none)IntegerThe size of the future thread pool to execute future callbacks for all spawned JobMasters. If no value is specified, then Flink defaults to the number of available CPU cores.
jobmanager.io-pool.size
(none)IntegerThe size of the IO thread pool to run blocking operations for all spawned JobMasters. This includes recovery and completion of checkpoints. Increase this value if you experience slow checkpoint operations when running many jobs. If no value is specified, then Flink defaults to the number of available CPU cores.
jobmanager.partition.hybrid.partition-data-consume-constraint
(none)

Enum

Controls the constraint that hybrid partition data can be consumed. Note that this option is allowed only when jobmanager.scheduler has been set to AdaptiveBatch. Accepted values are:
  • ALL_PRODUCERS_FINISHED‘: hybrid partition data can be consumed only when all producers are finished.
  • ONLY_FINISHED_PRODUCERS‘: hybrid partition data can be consumed when its producer is finished.
  • UNFINISHED_PRODUCERS‘: hybrid partition data can be consumed even if its producer is un-finished.


Possible values:
  • “ALL_PRODUCERS_FINISHED”
  • “ONLY_FINISHED_PRODUCERS”
  • “UNFINISHED_PRODUCERS”
jobmanager.resource-id
(none)StringThe JobManager’s ResourceID. If not configured, the ResourceID will be generated randomly.
jobmanager.retrieve-taskmanager-hostname
trueBooleanFlag indicating whether JobManager would retrieve canonical host name of TaskManager during registration. If the option is set to “false”, TaskManager registration with JobManager could be faster, since no reverse DNS lookup is performed. However, local input split assignment (such as for HDFS files) may be impacted.
jobmanager.rpc.address
(none)StringThe config parameter defining the network address to connect to for communication with the job manager. This value is only interpreted in setups where a single JobManager with static name or address exists (simple standalone setups, or container setups with dynamic service name resolution). It is not used in many high-availability setups, when a leader-election service (like ZooKeeper) is used to elect and discover the JobManager leader from potentially multiple standby JobManagers.
jobmanager.rpc.bind-port
(none)IntegerThe local RPC port that the JobManager binds to. If not configured, the external port (configured by ‘jobmanager.rpc.port’) will be used.
jobmanager.rpc.port
6123IntegerThe config parameter defining the network port to connect to for communication with the job manager. Like jobmanager.rpc.address, this value is only interpreted in setups where a single JobManager with static name/address and port exists (simple standalone setups, or container setups with dynamic service name resolution). This config option is not used in many high-availability setups, when a leader-election service (like ZooKeeper) is used to elect and discover the JobManager leader from potentially multiple standby JobManagers.
jobmanager.scheduler
Default

Enum

Determines which scheduler implementation is used to schedule tasks. If this option is not explicitly set, batch jobs will use the ‘AdaptiveBatch’ scheduler as the default, while streaming jobs will default to the ‘Default’ scheduler.

Possible values:
  • “Default”: Default scheduler
  • “Adaptive”: Adaptive scheduler. More details can be found here.
  • “AdaptiveBatch”: Adaptive batch scheduler. More details can be found here.
jobstore.cache-size
52428800LongThe job store cache size in bytes which is used to keep completed jobs in memory.
jobstore.expiration-time
3600LongThe time in seconds after which a completed job expires and is purged from the job store.
jobstore.max-capacity
infiniteIntegerThe max number of completed jobs that can be kept in the job store. NOTICE: if memory store keeps too many jobs in session cluster, it may cause FullGC or OOM in jm.
jobstore.type
File

Enum

Determines which job store implementation is used in session cluster. Accepted values are:
  • ‘File’: the file job store keeps the archived execution graphs in files
  • ‘Memory’: the memory job store keeps the archived execution graphs in memory. You may need to limit the jobstore.max-capacity to mitigate FullGC or OOM when there are too many graphs


Possible values:
  • “File”
  • “Memory”
web.exception-history-size
16IntegerThe maximum number of failures collected by the exception history per job.

Blob Server

The Blob Server is a component in the JobManager. It is used for distribution of objects that are too large to be attached to a RPC message and that benefit from caching (like Jar files or large serialized code objects).

KeyDefaultTypeDescription
blob.client.connect.timeout
0IntegerThe connection timeout in milliseconds for the blob client.
blob.client.socket.timeout
300000IntegerThe socket timeout in milliseconds for the blob client.
blob.fetch.backlog
1000IntegerThe config parameter defining the desired backlog of BLOB fetches on the JobManager.Note that the operating system usually enforces an upper limit on the backlog size based on the SOMAXCONN setting.
blob.fetch.num-concurrent
50IntegerThe config parameter defining the maximum number of concurrent BLOB fetches that the JobManager serves.
blob.fetch.retries
5IntegerThe config parameter defining number of retires for failed BLOB fetches.
blob.offload.minsize
1048576IntegerThe minimum size for messages to be offloaded to the BlobServer.
blob.server.port
“0”StringThe config parameter defining the server port of the blob service.
blob.service.cleanup.interval
3600LongCleanup interval of the blob caches at the task managers (in seconds).
blob.service.ssl.enabled
trueBooleanFlag to override ssl support for the blob service transport.
blob.storage.directory
(none)StringThe config parameter defining the local storage directory to be used by the blob server. If not configured, then it will default to <WORKING_DIR>/blobStorage.

ResourceManager

These configuration keys control basic Resource Manager behavior, independent of the used resource orchestration management framework (YARN, etc.)

KeyDefaultTypeDescription
resourcemanager.job.timeout
5 minDurationTimeout for jobs which don’t have a job manager as leader assigned.
resourcemanager.previous-worker.recovery.timeout
0 msDurationTimeout for resource manager to recover all the previous attempts workers. If exceeded, resource manager will handle new resource requests by requesting new workers. If you would like to reuse the previous workers as much as possible, you should configure a longer timeout time to wait for previous workers to register.
resourcemanager.rpc.port
0IntegerDefines the network port to connect to for communication with the resource manager. By default, the port of the JobManager, because the same ActorSystem is used. Its not possible to use this configuration key to define port ranges.
resourcemanager.standalone.start-up-time
(none)DurationTime of the start-up period of a standalone cluster. During this time, resource manager of the standalone cluster expects new task executors to be registered, and will not fail slot requests that can not be satisfied by any current registered slots. After this time, it will fail pending and new coming requests immediately that can not be satisfied by registered slots. If not set, slot.request.timeout will be used by default.
resourcemanager.start-worker.max-failure-rate
10.0DoubleThe maximum number of start worker failures (Native Kubernetes / Yarn) per minute before pausing requesting new workers. Once the threshold is reached, subsequent worker requests will be postponed to after a configured retry interval (‘resourcemanager.start-worker.retry-interval’).
resourcemanager.start-worker.retry-interval
3 sDurationThe time to wait before requesting new workers (Native Kubernetes / Yarn) once the max failure rate of starting workers (‘resourcemanager.start-worker.max-failure-rate’) is reached.
resourcemanager.taskmanager-registration.timeout
5 minDurationTimeout for TaskManagers to register at the active resource managers. If exceeded, active resource manager will release and try to re-request the resource for the worker. If not configured, fallback to ‘taskmanager.registration.timeout’.
resourcemanager.taskmanager-timeout
30 sDurationThe timeout for an idle task manager to be released.
slotmanager.max-total-resource.cpu
(none)DoubleMaximum cpu cores the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.max’.
slotmanager.max-total-resource.memory
(none)MemorySizeMaximum memory size the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.max’.
slotmanager.min-total-resource.cpu
(none)DoubleMinimum cpu cores the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.min’.
slotmanager.min-total-resource.memory
(none)MemorySizeMinimum memory size the Flink cluster allocates for slots. Resources for JobManager and TaskManager framework are excluded. If not configured, it will be derived from ‘slotmanager.number-of-slots.min’.
slotmanager.number-of-slots.max
infiniteIntegerDefines the maximum number of slots that the Flink cluster allocates. This configuration option is meant for limiting the resource consumption for batch workloads. It is not recommended to configure this option for streaming workloads, which may fail if there are not enough slots. Note that this configuration option does not take effect for standalone clusters, where how many slots are allocated is not controlled by Flink.
slotmanager.number-of-slots.min
0IntegerDefines the minimum number of slots that the Flink cluster allocates. This configuration option is meant for cluster to initialize certain workers in best efforts when starting. This can be used to speed up a job startup process. Note that this configuration option does not take effect for standalone clusters, where how many slots are allocated is not controlled by Flink.
slotmanager.redundant-taskmanager-num
0IntegerThe number of redundant task managers. Redundant task managers are extra task managers started by Flink, in order to speed up job recovery in case of failures due to task manager lost. Note that this feature is available only to the active deployments (native K8s, Yarn).For fine-grained resource requirement, Redundant resources will be reserved, but it is possible that we have many small pieces of free resources form multiple TMs, which added up larger than the desired redundant resources, but each piece is too small to match the resource requirement of tasks from the failed worker.

Full TaskManagerOptions

Please refer to the network memory tuning guide for details on how to use the taskmanager.network.memory.buffer-debloat.* configuration.

KeyDefaultTypeDescription
minicluster.number-of-taskmanagers
1IntegerThe number of task managers of MiniCluster.
task.cancellation.interval
30 sDurationTime interval between two successive task cancellation attempts.
task.cancellation.timeout
3 minDurationTimeout after which a task cancellation times out and leads to a fatal TaskManager error. A value of 0 deactivates the watch dog. Notice that a task cancellation is different from both a task failure and a clean shutdown. Task cancellation timeout only applies to task cancellation and does not apply to task closing/clean-up caused by a task failure or a clean shutdown.
task.cancellation.timers.timeout
7500 msDurationTime we wait for the timers to finish all pending timer threads when the stream task is cancelled.
taskmanager.bind-host
(none)StringThe local address of the network interface that the task manager binds to. If not configured, ‘0.0.0.0’ will be used.
taskmanager.collect-sink.port
0IntegerThe port used for the client to retrieve query results from the TaskManager. The default value is 0, which corresponds to a random port assignment.
taskmanager.data.bind-port
(none)StringThe task manager’s bind port used for data exchange operations. Also accepts a list of ports (“50100,50101”), ranges (“50100-50200”) or a combination of both. If not configured, ‘taskmanager.data.port’ will be used.
taskmanager.data.port
0IntegerThe task manager’s external port used for data exchange operations.
taskmanager.data.ssl.enabled
trueBooleanEnable SSL support for the taskmanager data transport. This is applicable only when the global flag for internal SSL (security.ssl.internal.enabled) is set to true
taskmanager.debug.memory.log
falseBooleanFlag indicating whether to start a thread, which repeatedly logs the memory usage of the JVM.
taskmanager.debug.memory.log-interval
5 sDurationThe interval for the log thread to log the current memory usage.
taskmanager.host
(none)StringThe external address of the network interface where the TaskManager is exposed. Because different TaskManagers need different values for this option, usually it is specified in an additional non-shared TaskManager-specific config file.
taskmanager.jvm-exit-on-oom
falseBooleanWhether to kill the TaskManager when the task thread throws an OutOfMemoryError.
taskmanager.load-balance.mode
NONE

Enum

Mode for the load-balance allocation strategy across all available TaskManagers.
  • The SLOTS mode tries to spread out the slots evenly across all available TaskManagers.
  • The NONE mode is the default mode without any specified strategy.


Possible values:
  • “NONE”
  • “SLOTS”
taskmanager.log.path
System.getProperty(“log.file”)StringThe path to the log file of the task manager.
taskmanager.memory.min-segment-size
256 bytesMemorySizeMinimum possible size of memory buffers used by the network stack and the memory manager. ex. can be used for automatic buffer size adjustment.
taskmanager.memory.segment-size
32 kbMemorySizeSize of memory buffers used by the network stack and the memory manager.
taskmanager.network.bind-policy
“ip”StringThe automatic address binding policy used by the TaskManager if “taskmanager.host” is not set. The value should be one of the following:
  • “name” - uses hostname as binding address
  • “ip” - uses host’s ip address as binding address
taskmanager.numberOfTaskSlots
1IntegerThe number of parallel operator or user function instances that a single TaskManager can run. If this value is larger than 1, a single TaskManager takes multiple instances of a function or operator. That way, the TaskManager can utilize multiple CPU cores, but at the same time, the available memory is divided between the different operator or function instances. This value is typically proportional to the number of physical CPU cores that the TaskManager’s machine has (e.g., equal to the number of cores, or half the number of cores).
taskmanager.registration.timeout
5 minDurationDefines the timeout for the TaskManager registration. If the duration is exceeded without a successful registration, then the TaskManager terminates.
taskmanager.resource-id
(none)StringThe TaskManager’s ResourceID. If not configured, the ResourceID will be generated with the “RpcAddress:RpcPort” and a 6-character random string. Notice that this option is not valid in Yarn and Native Kubernetes mode.
taskmanager.rpc.bind-port
(none)IntegerThe local RPC port that the TaskManager binds to. If not configured, the external port (configured by ‘taskmanager.rpc.port’) will be used.
taskmanager.rpc.port
“0”StringThe external RPC port where the TaskManager is exposed. Accepts a list of ports (“50100,50101”), ranges (“50100-50200”) or a combination of both. It is recommended to set a range of ports to avoid collisions when multiple TaskManagers are running on the same machine.
taskmanager.runtime.fs-timeout
0 msDurationThe timeout for filesystem stream opening. A value of 0 indicates infinite waiting.
taskmanager.slot.timeout
10 sDurationTimeout used for identifying inactive slots. The TaskManager will free the slot if it does not become active within the given amount of time. Inactive slots can be caused by an out-dated slot request. If no value is configured, then it will fall back to pekko.ask.timeout.
taskmanager.system-out.log.cache-upper-size
100 kbMemorySizeThe cache upper size when Flink caches current line context of System.out or System.err when taskmanager.system-out.mode is LOG.
taskmanager.system-out.log.thread-name.enabled
falseBooleanWhether to log the thread name when taskmanager.system-out.mode is LOG.
taskmanager.system-out.mode
DEFAULT

Enum

Redirection mode of System.out and System.err for all TaskManagers.
  • DEFAULT: TaskManagers don’t redirect the System.out and System.err, it’s the default value.
  • LOG: TaskManagers redirect System.out and System.err to LOG.info and LOG.error.
  • IGNORE: TaskManagers ignore System.out and System.err directly.


Possible values:
  • “DEFAULT”
  • “LOG”
  • “IGNORE”

Data Transport Network Stack

These options are for the network stack that handles the streaming and batch data exchanges between TaskManagers.

KeyDefaultTypeDescription
taskmanager.network.compression.codec
LZ4

Enum

The codec to be used when compressing shuffle data. If it is “NONE”, compression is disable. If it is not “NONE”, only “LZ4”, “LZO” and “ZSTD” are supported now. Through tpc-ds test of these three algorithms, the results show that “LZ4” algorithm has the highest compression and decompression speed, but the compression ratio is the lowest. “ZSTD” has the highest compression ratio, but the compression and decompression speed is the slowest, and LZO is between the two. Also note that this option is experimental and might be changed in the future.

Possible values:
  • “NONE”
  • “LZ4”
  • “LZO”
  • “ZSTD”
taskmanager.network.detailed-metrics
falseBooleanBoolean flag to enable/disable more detailed metrics about inbound/outbound network queue lengths.
taskmanager.network.hybrid-shuffle.external-remote-tier-factory.class
(none)StringThe option configures the class that is responsible for creating an external remote tier factory for hybrid shuffle. If configured, the hybrid shuffle will only initialize the specified remote tier according to the given class name. Currently, since the tier interfaces are not yet public and are still actively evolving, it is recommended that users do not independently implement the external remote tier until the tier interfaces are stabilized.
taskmanager.network.hybrid-shuffle.remote.path
(none)StringThe option is used to configure the base path of remote storage for hybrid shuffle. The shuffle data will be stored in remote storage when the disk space is not enough. Note: If the option is configured and taskmanager.network.hybrid-shuffle.enable-new-mode is false, this option will be ignored. If the option is not configured and taskmanager.network.hybrid-shuffle.enable-new-mode is true, the remote storage will be disabled.
taskmanager.network.memory.buffer-debloat.enabled
falseBooleanThe switch of the automatic buffered debloating feature. If enabled the amount of in-flight data will be adjusted automatically accordingly to the measured throughput.
taskmanager.network.memory.buffer-debloat.period
200 msDurationThe minimum period of time after which the buffer size will be debloated if required. The low value provides a fast reaction to the load fluctuation but can influence the performance.
taskmanager.network.memory.buffer-debloat.samples
20IntegerThe number of the last buffer size values that will be taken for the correct calculation of the new one.
taskmanager.network.memory.buffer-debloat.target
1 sDurationThe target total time after which buffered in-flight data should be fully consumed. This configuration option will be used, in combination with the measured throughput, to adjust the amount of in-flight data.
taskmanager.network.memory.buffer-debloat.threshold-percentages
25IntegerThe minimum difference in percentage between the newly calculated buffer size and the old one to announce the new value. Can be used to avoid constant back and forth small adjustments.
taskmanager.network.memory.read-buffer.required-per-gate.max
(none)IntegerThe maximum number of network read buffers that are required by an input gate. (An input gate is responsible for reading data from all subtasks of an upstream task.) The number of buffers needed by an input gate is dynamically calculated in runtime, depending on various factors (e.g., the parallelism of the upstream task). Among the calculated number of needed buffers, the part below this configured value is required, while the excess part, if any, is optional. A task will fail if the required buffers cannot be obtained in runtime. A task will not fail due to not obtaining optional buffers, but may suffer a performance reduction. If not explicitly configured, the default value is Integer.MAX_VALUE for streaming workloads, and 1000 for batch workloads. If explicitly configured, the configured value should be at least 1.
taskmanager.network.netty.client.connectTimeoutSec
120IntegerThe Netty client connection timeout.
taskmanager.network.netty.client.tcp.keepCount
(none)IntegerThe maximum number of keepalive probes TCP should send before Netty client dropping the connection. Note: This will not take effect when using netty transport type of nio with an older version of JDK 8, refer to https://bugs.openjdk.org/browse/JDK-8194298.
taskmanager.network.netty.client.tcp.keepIdleSec
(none)IntegerThe time (in seconds) the connection needs to remain idle before TCP starts sending keepalive probes. Note: This will not take effect when using netty transport type of nio with an older version of JDK 8, refer to https://bugs.openjdk.org/browse/JDK-8194298.
taskmanager.network.netty.client.tcp.keepIntervalSec
(none)IntegerThe time (in seconds) between individual keepalive probes. Note: This will not take effect when using netty transport type of nio with an older version of JDK 8, refer to https://bugs.openjdk.org/browse/JDK-8194298.
taskmanager.network.partition-request-timeout
10 sDurationTimeout for an individual partition request of remote input channels. The partition request will finally fail if the total wait time exceeds twice the value of taskmanager.network.request-backoff.max.
taskmanager.network.request-backoff.initial
100IntegerMinimum backoff in milliseconds for partition requests of local input channels.
taskmanager.network.request-backoff.max
10000IntegerMaximum backoff in milliseconds for partition requests of local input channels.
taskmanager.network.retries
0IntegerThe number of retry attempts for network communication. Currently it’s only used for establishing input/output channel connections
taskmanager.network.sort-shuffle.min-buffers
512IntegerMinimum number of network buffers required per blocking result partition for sort-shuffle. For production usage, it is suggested to increase this config value to at least 2048 (64M memory if the default 32K memory segment size is used) to improve the data compression ratio and reduce the small network packets. Usually, several hundreds of megabytes memory is enough for large scale batch jobs. Note: you may also need to increase the size of total network memory to avoid the ‘insufficient number of network buffers’ error if you are increasing this config value.
taskmanager.network.tcp-connection.enable-reuse-across-jobs
trueBooleanWhether to reuse tcp connections across multi jobs. If set to true, tcp connections will not be released after job finishes. The subsequent jobs will be free from the overhead of the connection re-establish. However, this may lead to an increase in the total number of connections on your machine. When it reaches the upper limit, you can set it to false to release idle connections. Note that to avoid connection leak, you must set taskmanager.network.max-num-tcp-connections to a smaller value before you enable tcp connection reuse.

RPC / Pekko

Flink uses Pekko for RPC between components (JobManager/TaskManager/ResourceManager). Flink does not use Pekko for data transport.

KeyDefaultTypeDescription
pekko.ask.callstack
trueBooleanIf true, call stack for asynchronous asks are captured. That way, when an ask fails (for example times out), you get a proper exception, describing to the original method call and call site. Note that in case of having millions of concurrent RPC calls, this may add to the memory footprint.
pekko.ask.timeout
10 sDurationTimeout used for all futures and blocking Pekko calls. If Flink fails due to timeouts then you should try to increase this value. Timeouts can be caused by slow machines or a congested network. The timeout value requires a time-unit specifier (ms/s/min/h/d).
pekko.client-socket-worker-pool.pool-size-factor
1.0DoubleThe pool size factor is used to determine thread pool size using the following formula: ceil(available processors factor). Resulting size is then bounded by the pool-size-min and pool-size-max values.
pekko.client-socket-worker-pool.pool-size-max
2IntegerMax number of threads to cap factor-based number to.
pekko.client-socket-worker-pool.pool-size-min
1IntegerMin number of threads to cap factor-based number to.
pekko.fork-join-executor.parallelism-factor
2.0DoubleThe parallelism factor is used to determine thread pool size using the following formula: ceil(available processors factor). Resulting size is then bounded by the parallelism-min and parallelism-max values.
pekko.fork-join-executor.parallelism-max
64IntegerMax number of threads to cap factor-based parallelism number to.
pekko.fork-join-executor.parallelism-min
8IntegerMin number of threads to cap factor-based parallelism number to.
pekko.framesize
“10485760b”StringMaximum size of messages which are sent between the JobManager and the TaskManagers. If Flink fails because messages exceed this limit, then you should increase it. The message size requires a size-unit specifier.
pekko.jvm-exit-on-fatal-error
trueBooleanExit JVM on fatal Pekko errors.
pekko.log.lifecycle.events
falseBooleanTurns on the Pekko’s remote logging of events. Set this value to ‘true’ in case of debugging.
pekko.lookup.timeout
10 sDurationTimeout used for the lookup of the JobManager. The timeout value has to contain a time-unit specifier (ms/s/min/h/d).
pekko.remote-fork-join-executor.parallelism-factor
2.0DoubleThe parallelism factor is used to determine thread pool size using the following formula: ceil(available processors factor). Resulting size is then bounded by the parallelism-min and parallelism-max values.
pekko.remote-fork-join-executor.parallelism-max
16IntegerMax number of threads to cap factor-based parallelism number to.
pekko.remote-fork-join-executor.parallelism-min
8IntegerMin number of threads to cap factor-based parallelism number to.
pekko.retry-gate-closed-for
50LongMilliseconds a gate should be closed for after a remote connection was disconnected.
pekko.server-socket-worker-pool.pool-size-factor
1.0DoubleThe pool size factor is used to determine thread pool size using the following formula: ceil(available processors factor). Resulting size is then bounded by the pool-size-min and pool-size-max values.
pekko.server-socket-worker-pool.pool-size-max
2IntegerMax number of threads to cap factor-based number to.
pekko.server-socket-worker-pool.pool-size-min
1IntegerMin number of threads to cap factor-based number to.
pekko.ssl.enabled
trueBooleanTurns on SSL for Pekko’s remote communication. This is applicable only when the global ssl flag security.ssl.enabled is set to true.
pekko.startup-timeout
(none)DurationTimeout after which the startup of a remote component is considered being failed.
pekko.tcp.timeout
20 sDurationTimeout for all outbound connections. If you should experience problems with connecting to a TaskManager due to a slow network, you should increase this value.
pekko.throughput
15IntegerNumber of messages that are processed in a batch before returning the thread to the pool. Low values denote a fair scheduling whereas high values can increase the performance at the cost of unfairness.


JVM and Logging Options

KeyDefaultTypeDescription
env.hadoop.conf.dir
(none)StringPath to hadoop configuration directory. It is required to read HDFS and/or YARN configuration. You can also set it via environment variable.
env.hbase.conf.dir
(none)StringPath to hbase configuration directory. It is required to read HBASE configuration. You can also set it via environment variable.
env.java.default-opts.all
(none)StringA string of default JVM options to prepend to env.java.opts.all. This is intended to be set by administrators.
env.java.default-opts.jobmanager
(none)StringA string of default JVM options to prepend to env.java.opts.jobmanager. This is intended to be set by administrators.
env.java.default-opts.taskmanager
(none)StringA string of default JVM options to prepend to env.java.opts.taskmanager. This is intended to be set by administrators.
env.java.opts.all
(none)StringJava options to start the JVM of all Flink processes with.
env.java.opts.client
(none)StringJava options to start the JVM of the Flink Client with.
env.java.opts.historyserver
(none)StringJava options to start the JVM of the HistoryServer with.
env.java.opts.jobmanager
(none)StringJava options to start the JVM of the JobManager with.
env.java.opts.sql-gateway
(none)StringJava options to start the JVM of the Flink SQL Gateway with.
env.java.opts.taskmanager
(none)StringJava options to start the JVM of the TaskManager with.
env.log.dir
(none)StringDefines the directory where the Flink logs are saved. It has to be an absolute path. (Defaults to the log directory under Flink’s home)
env.log.level
“INFO”StringDefines the level of the root logger.
env.log.max
10IntegerThe maximum number of old log files to keep.
env.pid.dir
“/tmp”StringDefines the directory where the flink-<host>-<process>.pid files are saved.
env.ssh.opts
(none)StringAdditional command line options passed to SSH clients when starting or stopping JobManager, TaskManager, and Zookeeper services (start-cluster.sh, stop-cluster.sh, start-zookeeper-quorum.sh, stop-zookeeper-quorum.sh).
env.stdout-err.redirect-to-file
falseBooleanWhether redirect stdout and stderr to files when running foreground. If enabled, logs won’t append the console too. Note that redirected files do not support rolling rotate.
env.yarn.conf.dir
(none)StringPath to yarn configuration directory. It is required to run flink on YARN. You can also set it via environment variable.

Forwarding Environment Variables

You can configure environment variables to be set on the JobManager and TaskManager processes started on Yarn.

  • containerized.master.env.: Prefix for passing custom environment variables to Flink’s JobManager process. For example for passing LD_LIBRARY_PATH as an env variable to the JobManager, set containerized.master.env.LD_LIBRARY_PATH: “/usr/lib/native” in the flink-conf.yaml.

  • containerized.taskmanager.env.: Similar to the above, this configuration prefix allows setting custom environment variables for the workers (TaskManagers).



Deprecated Options

These options relate to parts of Flink that are not actively developed any more. These options may be removed in a future release.

DataSet API Optimizer

KeyDefaultTypeDescription
compiler.delimited-informat.max-line-samples
10IntegerThe maximum number of line samples taken by the compiler for delimited inputs. The samples are used to estimate the number of records. This value can be overridden for a specific input with the input format’s parameters.
compiler.delimited-informat.max-sample-len
2097152IntegerThe maximal length of a line sample that the compiler takes for delimited inputs. If the length of a single sample exceeds this value (possible because of misconfiguration of the parser), the sampling aborts. This value can be overridden for a specific input with the input format’s parameters.
compiler.delimited-informat.min-line-samples
2IntegerThe minimum number of line samples taken by the compiler for delimited inputs. The samples are used to estimate the number of records. This value can be overridden for a specific input with the input format’s parameters

DataSet API Runtime Algorithms

KeyDefaultTypeDescription
taskmanager.runtime.hashjoin-bloom-filters
falseBooleanFlag to activate/deactivate bloom filters in the hybrid hash join implementation. In cases where the hash join needs to spill to disk (datasets larger than the reserved fraction of memory), these bloom filters can greatly reduce the number of spilled records, at the cost some CPU cycles.
taskmanager.runtime.large-record-handler
falseBooleanWhether to use the LargeRecordHandler when spilling. If a record will not fit into the sorting buffer. The record will be spilled on disk and the sorting will continue with only the key. The record itself will be read afterwards when merging.
taskmanager.runtime.max-fan
128IntegerThe maximal fan-in for external merge joins and fan-out for spilling hash tables. Limits the number of file handles per operator, but may cause intermediate merging/partitioning, if set too small.
taskmanager.runtime.sort-spilling-threshold
0.8FloatA sort operation starts spilling when this fraction of its memory budget is full.

DataSet File Sinks

KeyDefaultTypeDescription
fs.output.always-create-directory
falseBooleanFile writers running with a parallelism larger than one create a directory for the output file path and put the different result files (one per parallel writer task) into that directory. If this option is set to “true”, writers with a parallelism of 1 will also create a directory and place a single result file into it. If the option is set to “false”, the writer will directly create the file directly at the output path, without creating a containing directory.
fs.overwrite-files
falseBooleanSpecifies whether file output writers should overwrite existing files by default. Set to “true” to overwrite by default,”false” otherwise.