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Overview

TransformWithState is the new arbitrary stateful operator in Structured Streaming since the Apache Spark 4.0 release. This operator is the next generation replacement for the old mapGroupsWithState/flatMapGroupsWithState API in Scala and the applyInPandasWithState API in Python for arbitrary stateful processing in Apache Spark.

This operator has support for an umbrella of features such as object-oriented stateful processor definition, composite types, automatic TTL based eviction, timers etc and can be used to build business-critical operational use-cases.

Language Support

TransformWithState is available in Scala, Java and Python.

Note that in Python, there are two operators named transformWithStateInPandas which works with Pandas interface, and transformWithState which works with Row interface.

Based on popularity of Pandas and its rich set of API with vectorization, transformWithStateInPandas may be the preferred API for most users. The transformWithState API is more suitable to handle high key cardinality use case, since the cost of conversion is considerably high for Pandas API. If users aren't familiar with Pandas, Row type API might be easier to learn.

Components of a TransformWithState Query

A transformWithState query typically consists of the following components:

Stateful Processor - A user-defined stateful processor that defines the stateful logic
Output Mode - Output mode for the query such as Append, Update etc
Time Mode - Time mode for the query such as EventTime, ProcessingTime etc
Initial State - An optional initial state batch dataframe used to pre-populate the state

In the following sections, we will go through the above components in more detail.

Defining a Stateful Processor

A stateful processor is the core of the user-defined logic used to operate on the input events. A stateful processor is defined by extending the StatefulProcessor class and implementing a few methods.

A typical stateful processor deals with the following constructs:

Input Records - Input records received by the stream
State Variables - Zero or more class specific members used to store user state
Output Records - Output records produced by the processor. Zero or more output records may be produced by the processor.

A stateful processor uses the object-oriented paradigm to define the stateful logic. The stateful logic is defined by implementing the following methods:

init - Initialize the stateful processor and define any state variables as needed
handleInputRows - Process input rows belonging to a grouping key and emit output if needed
handleExpiredTimer - Handle expired timers and emit output if needed
close - Perform any cleanup operations if needed
handleInitialState - Optionally handle the initial state batch dataframe

The methods above will be invoked by the Spark query engine when the operator is executed as part of a streaming query.

Note also that not all types of operations are supported in each of the methods. For eg, users cannot register timers in the init method. Similarly, they cannot operate on input rows in the handleExpiredTimer method. The engine will detect unsupported/incompatible operations and fail the query, if needed.

Using the StatefulProcessorHandle

Many operations within the methods above can be performed using the StatefulProcessorHandle object. The StatefulProcessorHandle object provides methods to interact with the underlying state store. This object can be retrieved within the StatefulProcessor by invoking the getHandle method.

Using State Variables

State variables are class specific members used to store user state. They need to be declared once and initialized within the init method of the stateful processor.

Initializing a state variable typically involves the following steps:

Provide a unique name for the state variable (unique within the stateful processor definition)
Provide a type for the state variable (ValueState, ListState, MapState) - depending on the type, the appropriate method on the handle needs to be invoked
Provide a state encoder for the state variable (in Scala - this can be skipped if implicit encoders are available)
Provide an optional TTL config for the state variable

Types of state variables

State variables can be of the following types:

Value State
List State
Map State

Similar to collections for popular programming languages, the state types could be used to model data structures optimized for various types of operations for the underlying storage layer. For example, appends are optimized for ListState and point lookups are optimized for MapState.

Providing state encoders

State encoders are used to serialize and deserialize the state variables. In Scala, the state encoders can be skipped if implicit encoders are available. In Java and Python, the state encoders need to be provided explicitly. Built-in encoders for primitives, case classes and Java Bean classes are provided by default via the Spark SQL encoders.

Providing implicit encoders in Scala

In Scala, implicit encoders can be provided for case classes and primitive types. The implicits object is provided as part of the StatefulProcessor class. Within the StatefulProcessor definition, the user can simply import implicits as import implicits._ and then they do not require to pass the encoder type explicitly.

Providing TTL for state variables

State variables can be configured with an optional TTL (Time-To-Live) value. The TTL value is used to automatically evict the state variable after the specified duration. The TTL value can be provided as a Duration.

Handling input rows

The handleInputRows method is used to process input rows belonging to a grouping key and emit output if needed. The method is invoked by the Spark query engine for each grouping key value received by the operator. If multiple rows belong to the same grouping key, the provided iterator will include all those rows.

Handling expired timers

Within the handleInputRows or handleExpiredTimer methods, the stateful processor can register timers to be triggered at a later time. The handleExpiredTimer method is invoked by the Spark query engine when a timer set by the stateful processor has expired. This method is invoked once for each expired timer. Here are a few timer properties that are supported:

Multiple timers associated with the same grouping key can be registered
The engine provides the ability to list/add/remove timers as needed
Timers are also checkpointed as part of the query checkpoint and can be triggered on query restart as well.

Handling initial state

The handleInitialState method is used to optionally handle the initial state batch dataframe. The initial state batch dataframe is used to pre-populate the state for the stateful processor. The method is invoked by the Spark query engine when the initial state batch dataframe is available. This method is only called once in the lifetime of the query. This is invoked before any input rows are processed by the stateful processor.

Putting it all together

Here is an example of a StatefulProcessor that implements a downtime detector. Each time a new value is seen for a given key, it updates the lastSeen state value, clears any existing timers, and resets a timer for the future.

When a timer expires, the application emits the elapsed time since the last observed event for the key. It then sets a new timer to emit an update 10 seconds later.

NOTE: python_Pandas tab guides the implementation of StatefulProcessor for transformWithStateInPandas, and python_Row tab guides the implementation of StatefulProcessor for transformWithState.

{% highlight python %}

class DownTimeDetector(StatefulProcessor): def init(self, handle: StatefulProcessorHandle) -> None: # Define schema for the state value (timestamp) state_schema = StructType([StructField(“value”, TimestampType(), True)]) self.handle = handle # Initialize state to store the last seen timestamp for each key self.last_seen = handle.getValueState(“last_seen”, state_schema)

def handleExpiredTimer(self, key, timerValues, expiredTimerInfo) -> Iterator[pd.DataFrame]:
    latest_from_existing = self.last_seen.get()
    # Calculate downtime duration
    downtime_duration = timerValues.getCurrentProcessingTimeInMs() - int(latest_from_existing.timestamp() * 1000)
    # Register a new timer for 10 seconds in the future
    self.handle.registerTimer(timerValues.getCurrentProcessingTimeInMs() + 10000)
    # Yield a DataFrame with the key and downtime duration
    yield pd.DataFrame(
        {
            "id": key,
            "timeValues": str(downtime_duration),
        }
    )

def handleInputRows(self, key, rows, timerValues) -> Iterator[pd.DataFrame]:
    # Find the row with the maximum timestamp
    max_row = max((tuple(pdf.iloc[0]) for pdf in rows), key=lambda row: row[1])

    # Get the latest timestamp from existing state or use epoch start if not exists
    if self.last_seen.exists():
        latest_from_existing = self.last_seen.get()
    else:
        latest_from_existing = datetime.fromtimestamp(0)

    # If new data is more recent than existing state
    if latest_from_existing < max_row[1]:
        # Delete all existing timers
        for timer in self.handle.listTimers():
            self.handle.deleteTimer(timer)
        # Update the last seen timestamp
        self.last_seen.update((max_row[1],))

    # Register a new timer for 5 seconds in the future
    self.handle.registerTimer(timerValues.getCurrentProcessingTimeInMs() + 5000)

    # Yield an empty DataFrame
    yield pd.DataFrame()

def close(self) -> None:
    # No cleanup needed
    pass

{% endhighlight %}

{% highlight python %}

def handleExpiredTimer(self, key, timerValues, expiredTimerInfo) -> Iterator[Row]:
    latest_from_existing = self.last_seen.get()
    # Calculate downtime duration
    downtime_duration = timerValues.getCurrentProcessingTimeInMs() - int(latest_from_existing.timestamp() * 1000)
    # Register a new timer for 10 seconds in the future
    self.handle.registerTimer(timerValues.getCurrentProcessingTimeInMs() + 10000)
    # Yield a DataFrame with the key and downtime duration
    yield Row(id=key[0], timeValues=str(downtime_duration))

def handleInputRows(self, key, rows, timerValues) -> Iterator[Row]:
    # Find the maximum timestamp
    max_timestamp = max(map(lambda x: x.timestamp, rows))

    # Get the latest timestamp from existing state or use epoch start if not exists
    if self.last_seen.exists():
        latest_from_existing = self.last_seen.get()
    else:
        latest_from_existing = datetime.fromtimestamp(0)

    # If new data is more recent than existing state
    if latest_from_existing < max_timestamp:
        # Delete all existing timers
        for timer in self.handle.listTimers():
            self.handle.deleteTimer(timer)
        # Update the last seen timestamp
        self.last_seen.update((max_timestamp,))

    # Register a new timer for 5 seconds in the future
    self.handle.registerTimer(timerValues.getCurrentProcessingTimeInMs() + 5000)

    return iter([])

def close(self) -> None:
    # No cleanup needed
    pass

{% endhighlight %}

{% highlight scala %}

// The (String, Timestamp) schema represents an (id, time). We want to do downtime // detection on every single unique sensor, where each sensor has a sensor ID. class DowntimeDetector(duration: Duration) extends StatefulProcessor[String, (String, Timestamp), (String, Duration)] {

@transient private var _lastSeen: ValueState[Timestamp] = _

override def init(outputMode: OutputMode, timeMode: TimeMode): Unit = { _lastSeen = getHandle.getValueState[Timestamp](“lastSeen”, Encoders.TIMESTAMP, TTLConfig.NONE) }

// The logic here is as follows: find the largest timestamp seen so far. Set a timer for // the duration later. override def handleInputRows( key: String, inputRows: Iterator[(String, Timestamp)], timerValues: TimerValues): Iterator[(String, Duration)] = { val latestRecordFromNewRows = inputRows.maxBy(_._2.getTime)

val latestTimestampFromExistingRows = if (_lastSeen.exists()) {
  _lastSeen.get()
} else {
  new Timestamp(0)
}

val latestTimestampFromNewRows = latestRecordFromNewRows._2

if (latestTimestampFromNewRows.after(latestTimestampFromExistingRows)) {
  // Cancel the one existing timer, since we have a new latest timestamp.
  // We call "listTimers()" just because we don't know ahead of time what
  // the timestamp of the existing timer is.
  getHandle.listTimers().foreach(timer => getHandle.deleteTimer(timer))

  _lastSeen.update(latestTimestampFromNewRows)
  // Use timerValues to schedule a timer using processing time.
  getHandle.registerTimer(timerValues.getCurrentProcessingTimeInMs() + duration.toMillis)
} else {
  // No new latest timestamp, so no need to update state or set a timer.
}

Iterator.empty

}

override def handleExpiredTimer( key: String, timerValues: TimerValues, expiredTimerInfo: ExpiredTimerInfo): Iterator[(String, Duration)] = { val latestTimestamp = _lastSeen.get() val downtimeDuration = new Duration( timerValues.getCurrentProcessingTimeInMs() - latestTimestamp.getTime)

  // Register another timer that will fire in 10 seconds.
  // Timers can be registered anywhere but init()
  getHandle.registerTimer(timerValues.getCurrentProcessingTimeInMs() + 10000)

  Iterator((key, downtimeDuration))

} }

{% endhighlight %}

Using the StatefulProcessor in a streaming query

Now that we have defined the StatefulProcessor, we can use it in a streaming query. The following code snippets show how to use the StatefulProcessor in a streaming query in Python and Scala.

{% highlight python %}

q = (df.groupBy(“key”) .transformWithStateInPandas( statefulProcessor=DownTimeDetector(), outputStructType=output_schema, outputMode=“Update”, timeMode=“None”, ) .writeStream...

{% endhighlight %}

{% highlight python %}

q = (df.groupBy(“key”) .transformWithState( statefulProcessor=DownTimeDetector(), outputStructType=output_schema, outputMode=“Update”, timeMode=“None”, ) .writeStream...

{% endhighlight %}

{% highlight scala %} val query = df.groupBy(“key”) .transformWithState( statefulProcessor = new DownTimeDetector(), outputMode = OutputMode.Update, timeMode = TimeMode.None) .writeStream... {% endhighlight %}

State Schema Evolution

TransformWithState also allows for performing schema evolution of the managed state. There are 2 parts here:

evolution across state variables
evolution within a state variable

Note that schema evolution is only supported on the value side. Key side state schema evolution is not supported.

Evolution across state variables

This operator allows for state variables to be added and removed across different runs of the same streaming query. In order to remove a variable, we also need to inform the engine so that the underlying state can be purged. Users can achieve this by invoking the deleteIfExists method for a given state variable within the init method of the StatefulProcessor.

Evolution within a state variable

This operator also allows for the state schema of a specific state variable to also be evolved. For example, if you are using a case class to store the state within a ValueState variable, then it's possible for you to evolve this case class by adding/removing/widening fields. We support such schema evolution only when the underlying encoding format is set to Avro. In order to enable this, please set the following Spark config as spark.conf.set("spark.sql.streaming.stateStore.encodingFormat", "avro").

The following evolution operations are supported within Avro rules:

Adding a new field
Removing a field
Type widening
Reordering fields

The following evolution operations are not supported:

Renaming a field
Type narrowing

Integration with State Data Source

TransformWithState is a stateful operator that allows users to maintain arbitrary state across batches. In order to read this state, the user needs to provide some additional options in the state data source reader query. This operator allows for multiple state variables to be used within the same query. However, because they could be of different composite types and encoding formats, they need to be read within a batch query one variable at a time. In order to allow this, the user needs to specify the stateVarName for the state variable they are interested in reading.

Timers can read by setting the option readRegisteredTimers to true. This will return all the registered timer across grouping keys.

We also allow for composite type variables to be read in 2 formats:

Flattened: This is the default format where the composite types are flattened out into individual columns.
Non-flattened: This is where the composite types are returned as a single column of Array or Map type in Spark SQL.

Depending on your memory requirements, you can choose the format that best suits your use case. More information about source options can be found here.