Process Function
The ProcessFunction
The ProcessFunction
is a low-level stream processing operation, giving access to the basic building blocks of all (acyclic) streaming applications:
- events (stream elements)
- state (fault-tolerant, consistent, only on keyed stream)
- timers (event time and processing time, only on keyed stream)
The ProcessFunction
can be thought of as a FlatMapFunction
with access to keyed state and timers. It handles events by being invoked for each event received in the input stream(s).
For fault-tolerant state, the ProcessFunction
gives access to Flink’s keyed state, accessible via the RuntimeContext
, similar to the way other stateful functions can access keyed state.
The timers allow applications to react to changes in processing time and in event time. Every call to the function processElement(...)
gets a Context
object which gives access to the element’s event time timestamp, and to the TimerService. The TimerService
can be used to register callbacks for future event-/processing-time instants. With event-time timers, the onTimer(...)
method is called when the current watermark is advanced up to or beyond the timestamp of the timer, while with processing-time timers, onTimer(...)
is called when wall clock time reaches the specified time. During that call, all states are again scoped to the key with which the timer was created, allowing timers to manipulate keyed state.
Note If you want to access keyed state and timers you have to apply the ProcessFunction
on a keyed stream:
stream.keyBy(...).process(new MyProcessFunction())
Low-level Joins
To realize low-level operations on two inputs, applications can use CoProcessFunction
or KeyedCoProcessFunction
. This function is bound to two different inputs and gets individual calls to processElement1(...)
and processElement2(...)
for records from the two different inputs.
Implementing a low level join typically follows this pattern:
- Create a state object for one input (or both)
- Update the state upon receiving elements from its input
- Upon receiving elements from the other input, probe the state and produce the joined result
For example, you might be joining customer data to financial trades, while keeping state for the customer data. If you care about having complete and deterministic joins in the face of out-of-order events, you can use a timer to evaluate and emit the join for a trade when the watermark for the customer data stream has passed the time of that trade.
Example
In the following example a KeyedProcessFunction
maintains counts per key, and emits a key/count pair whenever a minute passes (in event time) without an update for that key:
- The count, key, and last-modification-timestamp are stored in a
ValueState
, which is implicitly scoped by key. - For each record, the
KeyedProcessFunction
increments the counter and sets the last-modification timestamp - The function also schedules a callback one minute into the future (in event time)
- Upon each callback, it checks the callback’s event time timestamp against the last-modification time of the stored count and emits the key/count if they match (i.e., no further update occurred during that minute)
Note This simple example could have been implemented with session windows. We use KeyedProcessFunction
here to illustrate the basic pattern it provides.
import org.apache.flink.api.common.state.ValueState;
import org.apache.flink.api.common.state.ValueStateDescriptor;
import org.apache.flink.api.java.tuple.Tuple;
import org.apache.flink.api.java.tuple.Tuple2;
import org.apache.flink.configuration.Configuration;
import org.apache.flink.streaming.api.functions.KeyedProcessFunction;
import org.apache.flink.streaming.api.functions.KeyedProcessFunction.Context;
import org.apache.flink.streaming.api.functions.KeyedProcessFunction.OnTimerContext;
import org.apache.flink.util.Collector;
// the source data stream
DataStream<Tuple2<String, String>> stream = ...;
// apply the process function onto a keyed stream
DataStream<Tuple2<String, Long>> result = stream
.keyBy(0)
.process(new CountWithTimeoutFunction());
/**
* The data type stored in the state
*/
public class CountWithTimestamp {
public String key;
public long count;
public long lastModified;
}
/**
* The implementation of the ProcessFunction that maintains the count and timeouts
*/
public class CountWithTimeoutFunction
extends KeyedProcessFunction<Tuple, Tuple2<String, String>, Tuple2<String, Long>> {
/** The state that is maintained by this process function */
private ValueState<CountWithTimestamp> state;
@Override
public void open(Configuration parameters) throws Exception {
state = getRuntimeContext().getState(new ValueStateDescriptor<>("myState", CountWithTimestamp.class));
}
@Override
public void processElement(
Tuple2<String, String> value,
Context ctx,
Collector<Tuple2<String, Long>> out) throws Exception {
// retrieve the current count
CountWithTimestamp current = state.value();
if (current == null) {
current = new CountWithTimestamp();
current.key = value.f0;
}
// update the state's count
current.count++;
// set the state's timestamp to the record's assigned event time timestamp
current.lastModified = ctx.timestamp();
// write the state back
state.update(current);
// schedule the next timer 60 seconds from the current event time
ctx.timerService().registerEventTimeTimer(current.lastModified + 60000);
}
@Override
public void onTimer(
long timestamp,
OnTimerContext ctx,
Collector<Tuple2<String, Long>> out) throws Exception {
// get the state for the key that scheduled the timer
CountWithTimestamp result = state.value();
// check if this is an outdated timer or the latest timer
if (timestamp == result.lastModified + 60000) {
// emit the state on timeout
out.collect(new Tuple2<String, Long>(result.key, result.count));
}
}
}
import org.apache.flink.api.common.state.ValueState
import org.apache.flink.api.common.state.ValueStateDescriptor
import org.apache.flink.api.java.tuple.Tuple
import org.apache.flink.streaming.api.functions.KeyedProcessFunction
import org.apache.flink.util.Collector
// the source data stream
val stream: DataStream[Tuple2[String, String]] = ...
// apply the process function onto a keyed stream
val result: DataStream[Tuple2[String, Long]] = stream
.keyBy(0)
.process(new CountWithTimeoutFunction())
/**
* The data type stored in the state
*/
case class CountWithTimestamp(key: String, count: Long, lastModified: Long)
/**
* The implementation of the ProcessFunction that maintains the count and timeouts
*/
class CountWithTimeoutFunction extends KeyedProcessFunction[Tuple, (String, String), (String, Long)] {
/** The state that is maintained by this process function */
lazy val state: ValueState[CountWithTimestamp] = getRuntimeContext
.getState(new ValueStateDescriptor[CountWithTimestamp]("myState", classOf[CountWithTimestamp]))
override def processElement(
value: (String, String),
ctx: KeyedProcessFunction[Tuple, (String, String), (String, Long)]#Context,
out: Collector[(String, Long)]): Unit = {
// initialize or retrieve/update the state
val current: CountWithTimestamp = state.value match {
case null =>
CountWithTimestamp(value._1, 1, ctx.timestamp)
case CountWithTimestamp(key, count, lastModified) =>
CountWithTimestamp(key, count + 1, ctx.timestamp)
}
// write the state back
state.update(current)
// schedule the next timer 60 seconds from the current event time
ctx.timerService.registerEventTimeTimer(current.lastModified + 60000)
}
override def onTimer(
timestamp: Long,
ctx: KeyedProcessFunction[Tuple, (String, String), (String, Long)]#OnTimerContext,
out: Collector[(String, Long)]): Unit = {
state.value match {
case CountWithTimestamp(key, count, lastModified) if (timestamp == lastModified + 60000) =>
out.collect((key, count))
case _ =>
}
}
}
NOTE: Before Flink 1.4.0, when called from a processing-time timer, the ProcessFunction.onTimer()
method sets the current processing time as event-time timestamp. This behavior is very subtle and might not be noticed by users. Well, it’s harmful because processing-time timestamps are indeterministic and not aligned with watermarks. Besides, user-implemented logic depends on this wrong timestamp highly likely is unintendedly faulty. So we’ve decided to fix it. Upon upgrading to 1.4.0, Flink jobs that are using this incorrect event-time timestamp will fail, and users should adapt their jobs to the correct logic.
The KeyedProcessFunction
KeyedProcessFunction
, as an extension of ProcessFunction
, gives access to the key of timers in its onTimer(...)
method.
@Override
public void onTimer(long timestamp, OnTimerContext ctx, Collector<OUT> out) throws Exception {
K key = ctx.getCurrentKey();
// ...
}
override def onTimer(timestamp: Long, ctx: OnTimerContext, out: Collector[OUT]): Unit = {
var key = ctx.getCurrentKey
// ...
}
Timers
Both types of timers (processing-time and event-time) are internally maintained by the TimerService
and enqueued for execution.
The TimerService
deduplicates timers per key and timestamp, i.e., there is at most one timer per key and timestamp. If multiple timers are registered for the same timestamp, the onTimer()
method will be called just once.
Note Flink synchronizes invocations of onTimer()
and processElement()
. Hence, users do not have to worry about concurrent modification of state.
Fault Tolerance
Timers are fault tolerant and checkpointed along with the state of the application. In case of a failure recovery or when starting an application from a savepoint, the timers are restored.
Note Checkpointed processing-time timers that were supposed to fire before their restoration, will fire immediately. This might happen when an application recovers from a failure or when it is started from a savepoint.
Note Timers are always asynchronously checkpointed, except for the combination of RocksDB backend / with incremental snapshots / with heap-based timers (will be resolved with FLINK-10026
). Notice that large numbers of timers can increase the checkpointing time because timers are part of the checkpointed state. See the “Timer Coalescing” section for advice on how to reduce the number of timers.
Timer Coalescing
Since Flink maintains only one timer per key and timestamp, you can reduce the number of timers by reducing the timer resolution to coalesce them.
For a timer resolution of 1 second (event or processing time), you can round down the target time to full seconds. Timers will fire at most 1 second earlier but not later than requested with millisecond accuracy. As a result, there are at most one timer per key and second.
long coalescedTime = ((ctx.timestamp() + timeout) / 1000) * 1000;
ctx.timerService().registerProcessingTimeTimer(coalescedTime);
val coalescedTime = ((ctx.timestamp + timeout) / 1000) * 1000
ctx.timerService.registerProcessingTimeTimer(coalescedTime)
Since event-time timers only fire with watermarks coming in, you may also schedule and coalesce these timers with the next watermark by using the current one:
long coalescedTime = ctx.timerService().currentWatermark() + 1;
ctx.timerService().registerEventTimeTimer(coalescedTime);
val coalescedTime = ctx.timerService.currentWatermark + 1
ctx.timerService.registerEventTimeTimer(coalescedTime)
Timers can also be stopped and removed as follows:
Stopping a processing-time timer:
long timestampOfTimerToStop = ...
ctx.timerService().deleteProcessingTimeTimer(timestampOfTimerToStop);
val timestampOfTimerToStop = ...
ctx.timerService.deleteProcessingTimeTimer(timestampOfTimerToStop)
Stopping an event-time timer:
long timestampOfTimerToStop = ...
ctx.timerService().deleteEventTimeTimer(timestampOfTimerToStop);
val timestampOfTimerToStop = ...
ctx.timerService.deleteEventTimeTimer(timestampOfTimerToStop)
Note Stopping a timer has no effect if no such timer with the given timestamp is registered.