All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.apache.kafka.streams.kstream.SessionWindowedKStream Maven / Gradle / Ivy

The newest version!
/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements. See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License. You may obtain a copy of the License at
 *
 *    http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.kafka.streams.kstream;

import org.apache.kafka.common.utils.Bytes;
import org.apache.kafka.streams.KafkaStreams;
import org.apache.kafka.streams.KeyValue;
import org.apache.kafka.streams.StoreQueryParameters;
import org.apache.kafka.streams.StreamsConfig;
import org.apache.kafka.streams.Topology;
import org.apache.kafka.streams.state.SessionStore;

import java.time.Duration;

/**
 * {@code SessionWindowedKStream} is an abstraction of a windowed record stream of {@link KeyValue} pairs.
 * It is an intermediate representation after a grouping and windowing of a {@link KStream} before an aggregation is
 * applied to the new (partitioned) windows resulting in a windowed {@link KTable} (a windowed
 * {@code KTable} is a {@link KTable} with key type {@link Windowed Windowed}).
 * 

* {@link SessionWindows} are dynamic data driven windows. * They have no fixed time boundaries, rather the size of the window is determined by the records. *

* The result is written into a local {@link SessionStore} (which is basically an ever-updating * materialized view) that can be queried using the name provided in the {@link Materialized} instance. * Furthermore, updates to the store are sent downstream into a windowed {@link KTable} changelog stream, where * "windowed" implies that the {@link KTable} key is a combined key of the original record key and a window ID. * New events are added to sessions until their grace period ends (see {@link SessionWindows#ofInactivityGapAndGrace(Duration, Duration)}). *

* A {@code SessionWindowedKStream} must be obtained from a {@link KGroupedStream} via * {@link KGroupedStream#windowedBy(SessionWindows)}. * * @param Type of keys * @param Type of values * @see KStream * @see KGroupedStream * @see SessionWindows */ public interface SessionWindowedKStream { /** * Count the number of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. *

* The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view). * The default key serde from the config will be used for serializing the result. * If a different serde is required then you should use {@link #count(Materialized)}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. * Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same session and key. * The rate of propagated updates depends on your input data rate, the number of distinct keys, the number of * parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} parameters for * {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * The changelog topic will be named "${applicationId}-${internalStoreName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "internalStoreName" is an internal name * and "-changelog" is a fixed suffix. * Note that the internal store name may not be queryable through Interactive Queries. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @return a windowed {@link KTable} that contains "update" records with unmodified keys and {@link Long} values * that represent the latest (rolling) count (i.e., number of records) for each key per session */ KTable, Long> count(); /** * Count the number of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. *

* The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view). * The default key serde from the config will be used for serializing the result. * If a different serde is required then you should use {@link #count(Named, Materialized)}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. * Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same session and key. * The rate of propagated updates depends on your input data rate, the number of distinct keys, the number of * parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} parameters for * {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * The changelog topic will be named "${applicationId}-${internalStoreName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "internalStoreName" is an internal name * and "-changelog" is a fixed suffix. * Note that the internal store name may not be queryable through Interactive Queries. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param named a {@link Named} config used to name the processor in the topology. Cannot be {@code null}. * @return a windowed {@link KTable} that contains "update" records with unmodified keys and {@link Long} values * that represent the latest (rolling) count (i.e., number of records) for each key per session */ KTable, Long> count(final Named named); /** * Count the number of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. *

* The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view) * that can be queried using the name provided with {@link Materialized}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* Not all updates might get sent downstream, as an internal cache will be used to deduplicate consecutive updates * to the same window and key if caching is enabled on the {@link Materialized} instance. * When caching is enabled the rate of propagated updates depends on your input data rate, the number of distinct * keys, the number of parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} * parameters for {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* To query the local {@link SessionStore} it must be obtained via * {@link KafkaStreams#store(StoreQueryParameters) KafkaStreams#store(...)}: *

{@code
     * KafkaStreams streams = ... // compute sum
     * Sting queryableStoreName = ... // the queryableStoreName should be the name of the store as defined by the Materialized instance
     * StoreQueryParameters> storeQueryParams = StoreQueryParameters.fromNameAndType(queryableStoreName, QueryableStoreTypes.sessionStore());
     * ReadOnlySessionStore sessionStore = streams.store(storeQueryParams);
     * String key = "some-key";
     * KeyValueIterator, Long> sumForKeyForWindows = sessionStore.fetch(key); // key must be local (application state is shared over all running Kafka Streams instances)
     * }
* For non-local keys, a custom RPC mechanism must be implemented using {@link KafkaStreams#metadataForAllStreamsClients()} to * query the value of the key on a parallel running instance of your Kafka Streams application. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * Therefore, the store name defined by the Materialized instance must be a valid Kafka topic name and cannot * contain characters other than ASCII alphanumerics, '.', '_' and '-'. * The changelog topic will be named "${applicationId}-${storeName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "storeName" is the provide store name defined * in {@code Materialized}, and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param materialized an instance of {@link Materialized} used to materialize a state store. Cannot be {@code null}. * Note: the valueSerde will be automatically set to {@link org.apache.kafka.common.serialization.Serdes#Long() Serdes#Long()} * if there is no valueSerde provided * @return a windowed {@link KTable} that contains "update" records with unmodified keys and {@link Long} values * that represent the latest (rolling) count (i.e., number of records) for each key per session */ KTable, Long> count(final Materialized> materialized); /** * Count the number of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. *

* The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view) * that can be queried using the name provided with {@link Materialized}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* Not all updates might get sent downstream, as an internal cache will be used to deduplicate consecutive updates * to the same window and key if caching is enabled on the {@link Materialized} instance. * When caching is enabled the rate of propagated updates depends on your input data rate, the number of distinct * keys, the number of parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} * parameters for {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* To query the local {@link SessionStore} it must be obtained via * {@link KafkaStreams#store(StoreQueryParameters) KafkaStreams#store(...)}: *

{@code
     * KafkaStreams streams = ... // compute sum
     * Sting queryableStoreName = ... // the queryableStoreName should be the name of the store as defined by the Materialized instance
     * StoreQueryParameters> storeQueryParams = StoreQueryParameters.fromNameAndType(queryableStoreName, QueryableStoreTypes.sessionStore());
     * ReadOnlySessionStore sessionStore = streams.store(storeQueryParams);
     * String key = "some-key";
     * KeyValueIterator, Long> sumForKeyForWindows = sessionStore.fetch(key); // key must be local (application state is shared over all running Kafka Streams instances)
     * }
* For non-local keys, a custom RPC mechanism must be implemented using {@link KafkaStreams#metadataForAllStreamsClients()} to * query the value of the key on a parallel running instance of your Kafka Streams application. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * Therefore, the store name defined by the Materialized instance must be a valid Kafka topic name and cannot * contain characters other than ASCII alphanumerics, '.', '_' and '-'. * The changelog topic will be named "${applicationId}-${storeName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "storeName" is the provide store name defined * in {@code Materialized}, and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param named a {@link Named} config used to name the processor in the topology. Cannot be {@code null}. * @param materialized an instance of {@link Materialized} used to materialize a state store. Cannot be {@code null}. * Note: the valueSerde will be automatically set to {@link org.apache.kafka.common.serialization.Serdes#Long() Serdes#Long()} * if there is no valueSerde provided * @return a windowed {@link KTable} that contains "update" records with unmodified keys and {@link Long} values * that represent the latest (rolling) count (i.e., number of records) for each key per session */ KTable, Long> count(final Named named, final Materialized> materialized); /** * Aggregate the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Aggregating is a generalization of {@link #reduce(Reducer) combining via reduce(...)} as it, for example, * allows the result to have a different type than the input values. * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view). * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* The specified {@link Initializer} is applied directly before the first input record per session is processed to * provide an initial intermediate aggregation result that is used to process the first record per session. * The specified {@link Aggregator} is applied for each input record and computes a new aggregate using the current * aggregate (or for the very first record using the intermediate aggregation result provided via the * {@link Initializer}) and the record's value. * The specified {@link Merger} is used to merge two existing sessions into one, i.e., when the windows overlap, * they are merged into a single session and the old sessions are discarded. * Thus, {@code aggregate()} can be used to compute aggregate functions like count (c.f. {@link #count()}). *

* The default key and value serde from the config will be used for serializing the result. * If a different serde is required then you should use * {@link #aggregate(Initializer, Aggregator, Merger, Materialized)}. *

* Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same window and key. * The rate of propagated updates depends on your input data rate, the number of distinct keys, the number of * parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} parameters for * {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * The changelog topic will be named "${applicationId}-${internalStoreName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "internalStoreName" is an internal name * and "-changelog" is a fixed suffix. * Note that the internal store name may not be queryable through Interactive Queries. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param initializer an {@link Initializer} that computes an initial intermediate aggregation result. Cannot be {@code null}. * @param aggregator an {@link Aggregator} that computes a new aggregate result. Cannot be {@code null}. * @param sessionMerger a {@link Merger} that combines two aggregation results. Cannot be {@code null}. * @param the value type of the resulting {@link KTable} * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, VR> aggregate(final Initializer initializer, final Aggregator aggregator, final Merger sessionMerger); /** * Aggregate the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Aggregating is a generalization of {@link #reduce(Reducer) combining via reduce(...)} as it, for example, * allows the result to have a different type than the input values. * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view). * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* The specified {@link Initializer} is applied directly before the first input record per session is processed to * provide an initial intermediate aggregation result that is used to process the first record per session. * The specified {@link Aggregator} is applied for each input record and computes a new aggregate using the current * aggregate (or for the very first record using the intermediate aggregation result provided via the * {@link Initializer}) and the record's value. * The specified {@link Merger} is used to merge two existing sessions into one, i.e., when the windows overlap, * they are merged into a single session and the old sessions are discarded. * Thus, {@code aggregate()} can be used to compute aggregate functions like count (c.f. {@link #count()}). *

* The default key and value serde from the config will be used for serializing the result. * If a different serde is required then you should use * {@link #aggregate(Initializer, Aggregator, Merger, Named, Materialized)}. *

* Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same window and key. * The rate of propagated updates depends on your input data rate, the number of distinct * keys, the number of parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} * parameters for {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * The changelog topic will be named "${applicationId}-${internalStoreName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "internalStoreName" is an internal name * and "-changelog" is a fixed suffix. * Note that the internal store name may not be queryable through Interactive Queries. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param initializer an {@link Initializer} that computes an initial intermediate aggregation result. Cannot be {@code null}. * @param aggregator an {@link Aggregator} that computes a new aggregate result. Cannot be {@code null}. * @param sessionMerger a {@link Merger} that combines two aggregation results. Cannot be {@code null}. * @param named a {@link Named} config used to name the processor in the topology. Cannot be {@code null}. * @param the value type of the resulting {@link KTable} * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, VR> aggregate(final Initializer initializer, final Aggregator aggregator, final Merger sessionMerger, final Named named); /** * Aggregate the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Aggregating is a generalization of {@link #reduce(Reducer) combining via reduce(...)} as it, for example, * allows the result to have a different type than the input values. * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view) * that can be queried using the store name as provided with {@link Materialized}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* The specified {@link Initializer} is applied directly before the first input record per session is processed to * provide an initial intermediate aggregation result that is used to process the first record per session. * The specified {@link Aggregator} is applied for each input record and computes a new aggregate using the current * aggregate (or for the very first record using the intermediate aggregation result provided via the * {@link Initializer}) and the record's value. * The specified {@link Merger} is used to merge two existing sessions into one, i.e., when the windows overlap, * they are merged into a single session and the old sessions are discarded. * Thus, {@code aggregate()} can be used to compute aggregate functions like count (c.f. {@link #count()}). *

* Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same window and key if caching is enabled on the {@link Materialized} instance. * When caching is enabled the rate of propagated updates depends on your input data rate, the number of distinct keys, the number of * parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} parameters for * {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* To query the local {@link SessionStore} it must be obtained via * {@link KafkaStreams#store(StoreQueryParameters) KafkaStreams#store(...)}: *

{@code
     * KafkaStreams streams = ... // some windowed aggregation on value type double
     * Sting queryableStoreName = ... // the queryableStoreName should be the name of the store as defined by the Materialized instance
     * StoreQueryParameters> storeQueryParams = StoreQueryParameters.fromNameAndType(queryableStoreName, QueryableStoreTypes.sessionStore());
     * ReadOnlySessionStore sessionStore = streams.store(storeQueryParams);
     * String key = "some-key";
     * KeyValueIterator, Long> aggForKeyForSession = sessionStore.fetch(key); // key must be local (application state is shared over all running Kafka Streams instances)
     * }
* For non-local keys, a custom RPC mechanism must be implemented using {@link KafkaStreams#metadataForAllStreamsClients()} to * query the value of the key on a parallel running instance of your Kafka Streams application. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * Therefore, the store name defined by the {@link Materialized} instance must be a valid Kafka topic name and * cannot contain characters other than ASCII alphanumerics, '.', '_' and '-'. * The changelog topic will be named "${applicationId}-${storeName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "storeName" is the * provide store name defined in {@link Materialized}, and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param initializer an {@link Initializer} that computes an initial intermediate aggregation result. Cannot be {@code null}. * @param aggregator an {@link Aggregator} that computes a new aggregate result. Cannot be {@code null}. * @param sessionMerger a {@link Merger} that combines two aggregation results. Cannot be {@code null}. * @param materialized a {@link Materialized} config used to materialize a state store. Cannot be {@code null}. * @param the value type of the resulting {@link KTable} * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, VR> aggregate(final Initializer initializer, final Aggregator aggregator, final Merger sessionMerger, final Materialized> materialized); /** * Aggregate the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Aggregating is a generalization of {@link #reduce(Reducer) combining via reduce(...)} as it, for example, * allows the result to have a different type than the input values. * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view) * that can be queried using the store name as provided with {@link Materialized}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* The specified {@link Initializer} is applied directly before the first input record per session is processed to * provide an initial intermediate aggregation result that is used to process the first record per session. * The specified {@link Aggregator} is applied for each input record and computes a new aggregate using the current * aggregate (or for the very first record using the intermediate aggregation result provided via the * {@link Initializer}) and the record's value. * The specified {@link Merger} is used to merge two existing sessions into one, i.e., when the windows overlap, * they are merged into a single session and the old sessions are discarded. * Thus, {@code aggregate()} can be used to compute aggregate functions like count (c.f. {@link #count()}). *

* Not all updates might get sent downstream, as an internal cache will be used to deduplicate consecutive updates * to the same window and key if caching is enabled on the {@link Materialized} instance. * When caching is enabled the rate of propagated updates depends on your input data rate, the number of distinct * keys, the number of parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} * parameters for {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* To query the local {@link SessionStore} it must be obtained via * {@link KafkaStreams#store(StoreQueryParameters) KafkaStreams#store(...)}: *

{@code
     * KafkaStreams streams = ... // some windowed aggregation on value type double
     * Sting queryableStoreName = ... // the queryableStoreName should be the name of the store as defined by the Materialized instance
     * StoreQueryParameters> storeQueryParams = StoreQueryParameters.fromNameAndType(queryableStoreName, QueryableStoreTypes.sessionStore());
     * ReadOnlySessionStore sessionStore = streams.store(storeQueryParams);
     * String key = "some-key";
     * KeyValueIterator, Long> aggForKeyForSession = sessionStore.fetch(key); // key must be local (application state is shared over all running Kafka Streams instances)
     * }
* For non-local keys, a custom RPC mechanism must be implemented using {@link KafkaStreams#metadataForAllStreamsClients()} to * query the value of the key on a parallel running instance of your Kafka Streams application. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * Therefore, the store name defined by the {@link Materialized} instance must be a valid Kafka topic name and * cannot contain characters other than ASCII alphanumerics, '.', '_' and '-'. * The changelog topic will be named "${applicationId}-${storeName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "storeName" is the * provide store name defined in {@link Materialized}, and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param initializer an {@link Initializer} that computes an initial intermediate aggregation result. Cannot be {@code null}. * @param aggregator an {@link Aggregator} that computes a new aggregate result. Cannot be {@code null}. * @param sessionMerger a {@link Merger} that combines two aggregation results. Cannot be {@code null}. * @param named a {@link Named} config used to name the processor in the topology. Cannot be {@code null}. * @param materialized a {@link Materialized} config used to materialize a state store. Cannot be {@code null}. * @param the value type of the resulting {@link KTable} * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, VR> aggregate(final Initializer initializer, final Aggregator aggregator, final Merger sessionMerger, final Named named, final Materialized> materialized); /** * Combine the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Combining implies that the type of the aggregate result is the same as the type of the input value * (c.f. {@link #aggregate(Initializer, Aggregator, Merger)}). * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view). * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. * The default key and value serde from the config will be used for serializing the result. * If a different serde is required then you should use {@link #reduce(Reducer, Materialized)} . *

* The value of the first record per session initialized the session result. * The specified {@link Reducer} is applied for each additional input record per session and computes a new * aggregate using the current aggregate (first argument) and the record's value (second argument): *

{@code
     * // At the example of a Reducer
     * new Reducer() {
     *   public Long apply(Long aggValue, Long currValue) {
     *     return aggValue + currValue;
     *   }
     * }
     * }
* Thus, {@code reduce()} can be used to compute aggregate functions like sum, min, or max. *

* Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same window and key. * The rate of propagated updates depends on your input data rate, the number of distinct keys, the number of * parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} parameters for * {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * The changelog topic will be named "${applicationId}-${internalStoreName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "internalStoreName" is an internal name * and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param reducer a {@link Reducer} that computes a new aggregate result. Cannot be {@code null}. * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, V> reduce(final Reducer reducer); /** * Combine the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Combining implies that the type of the aggregate result is the same as the type of the input value * (c.f. {@link #aggregate(Initializer, Aggregator, Merger)}). * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view). * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. * The default key and value serde from the config will be used for serializing the result. * If a different serde is required then you should use {@link #reduce(Reducer, Named, Materialized)} . *

* The value of the first record per session initialized the session result. * The specified {@link Reducer} is applied for each additional input record per session and computes a new * aggregate using the current aggregate (first argument) and the record's value (second argument): *

{@code
     * // At the example of a Reducer
     * new Reducer() {
     *   public Long apply(Long aggValue, Long currValue) {
     *     return aggValue + currValue;
     *   }
     * }
     * }
* Thus, {@code reduce()} can be used to compute aggregate functions like sum, min, or max. *

* Not all updates might get sent downstream, as an internal cache is used to deduplicate consecutive updates to * the same window and key. * The rate of propagated updates depends on your input data rate, the number of distinct keys, the number of * parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} parameters for * {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * The changelog topic will be named "${applicationId}-${internalStoreName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "internalStoreName" is an internal name * and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param reducer a {@link Reducer} that computes a new aggregate result. Cannot be {@code null}. * @param named a {@link Named} config used to name the processor in the topology. Cannot be {@code null}. * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, V> reduce(final Reducer reducer, final Named named); /** * Combine the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Combining implies that the type of the aggregate result is the same as the type of the input value * (c.f. {@link #aggregate(Initializer, Aggregator, Merger)}). * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view) * that can be queried using the store name as provided with {@link Materialized}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* The value of the first record per session initialized the session result. * The specified {@link Reducer} is applied for each additional input record per session and computes a new * aggregate using the current aggregate (first argument) and the record's value (second argument): *

{@code
     * // At the example of a Reducer
     * new Reducer() {
     *   public Long apply(Long aggValue, Long currValue) {
     *     return aggValue + currValue;
     *   }
     * }
     * }
* Thus, {@code reduce()} can be used to compute aggregate functions like sum, min, or max. *

* Not all updates might get sent downstream, as an internal cache will be used to deduplicate consecutive updates * to the same window and key if caching is enabled on the {@link Materialized} instance. * When caching is enabled the rate of propagated updates depends on your input data rate, the number of distinct * keys, the number of parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} * parameters for {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* To query the local {@link SessionStore} it must be obtained via * {@link KafkaStreams#store(StoreQueryParameters) KafkaStreams#store(...)}: *

{@code
     * KafkaStreams streams = ... // compute sum
     * Sting queryableStoreName = ... // the queryableStoreName should be the name of the store as defined by the Materialized instance
     * StoreQueryParameters> storeQueryParams = StoreQueryParameters.fromNameAndType(queryableStoreName, QueryableStoreTypes.sessionStore());
     * ReadOnlySessionStore sessionStore = streams.store(storeQueryParams);
     * String key = "some-key";
     * KeyValueIterator, Long> sumForKeyForWindows = sessionStore.fetch(key); // key must be local (application state is shared over all running Kafka Streams instances)
     * }
* For non-local keys, a custom RPC mechanism must be implemented using {@link KafkaStreams#metadataForAllStreamsClients()} to * query the value of the key on a parallel running instance of your Kafka Streams application. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * Therefore, the store name defined by the Materialized instance must be a valid Kafka topic name and cannot * contain characters other than ASCII alphanumerics, '.', '_' and '-'. * The changelog topic will be named "${applicationId}-${storeName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "storeName" is the provide store name defined * in {@code Materialized}, and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param reducer a {@link Reducer} that computes a new aggregate result. Cannot be {@code null}. * @param materialized a {@link Materialized} config used to materialize a state store. Cannot be {@code null}. * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, V> reduce(final Reducer reducer, final Materialized> materialized); /** * Combine the values of records in this stream by the grouped key and defined sessions. * Note that sessions are generated on a per-key basis and records with different keys create independent sessions. * Records with {@code null} key or value are ignored. * Combining implies that the type of the aggregate result is the same as the type of the input value * (c.f. {@link #aggregate(Initializer, Aggregator, Merger)}). * The result is written into a local {@link SessionStore} (which is basically an ever-updating materialized view) * that can be queried using the store name as provided with {@link Materialized}. * Furthermore, updates to the store are sent downstream into a {@link KTable} changelog stream. *

* The value of the first record per session initialized the session result. * The specified {@link Reducer} is applied for each additional input record per session and computes a new * aggregate using the current aggregate (first argument) and the record's value (second argument): *

{@code
     * // At the example of a Reducer
     * new Reducer() {
     *   public Long apply(Long aggValue, Long currValue) {
     *     return aggValue + currValue;
     *   }
     * }
     * }
* Thus, {@code reduce()} can be used to compute aggregate functions like sum, min, or max. *

* Not all updates might get sent downstream, as an internal cache will be used to deduplicate consecutive updates * to the same window and key if caching is enabled on the {@link Materialized} instance. * When caching is enabled the rate of propagated updates depends on your input data rate, the number of distinct * keys, the number of parallel running Kafka Streams instances, and the {@link StreamsConfig configuration} * parameters for {@link StreamsConfig#STATESTORE_CACHE_MAX_BYTES_CONFIG cache size}, and * {@link StreamsConfig#COMMIT_INTERVAL_MS_CONFIG commit interval}. *

* To query the local {@link SessionStore} it must be obtained via * {@link KafkaStreams#store(StoreQueryParameters)} KafkaStreams#store(...)}: *

{@code
     * KafkaStreams streams = ... // compute sum
     * Sting queryableStoreName = ... // the queryableStoreName should be the name of the store as defined by the Materialized instance
     * StoreQueryParameters> storeQueryParams = StoreQueryParameters.fromNameAndType(QueryableStoreTypes.sessionStore());
     * ReadOnlySessionStore sessionStore = streams.store(storeQueryParams);
     * String key = "some-key";
     * KeyValueIterator, Long> sumForKeyForWindows = sessionStore.fetch(key); // key must be local (application state is shared over all running Kafka Streams instances)
     * }
* For non-local keys, a custom RPC mechanism must be implemented using {@link KafkaStreams#metadataForAllStreamsClients()} to * query the value of the key on a parallel running instance of your Kafka Streams application. *

* For failure and recovery the store will be backed by an internal changelog topic that will be created in Kafka. * Therefore, the store name defined by the Materialized instance must be a valid Kafka topic name and cannot * contain characters other than ASCII alphanumerics, '.', '_' and '-'. * The changelog topic will be named "${applicationId}-${storeName}-changelog", where "applicationId" is * user-specified in {@link StreamsConfig} via parameter * {@link StreamsConfig#APPLICATION_ID_CONFIG APPLICATION_ID_CONFIG}, "storeName" is the provide store name defined * in {@link Materialized}, and "-changelog" is a fixed suffix. *

* You can retrieve all generated internal topic names via {@link Topology#describe()}. * * @param reducer a {@link Reducer} that computes a new aggregate result. Cannot be {@code null}. * @param named a {@link Named} config used to name the processor in the topology. Cannot be {@code null}. * @param materialized a {@link Materialized} config used to materialize a state store. Cannot be {@code null}. * @return a windowed {@link KTable} that contains "update" records with unmodified keys, and values that represent * the latest (rolling) aggregate for each key per session */ KTable, V> reduce(final Reducer reducer, final Named named, final Materialized> materialized); /** * Configure when the aggregated result will be emitted for {@code SessionWindowedKStream}. *

* For example, for {@link EmitStrategy#onWindowClose} strategy, the aggregated result for a * window will only be emitted when the window closes. For {@link EmitStrategy#onWindowUpdate()} * strategy, the aggregated result for a window will be emitted whenever there is an update to * the window. Note that whether the result will be available in downstream also depends on * cache policy. * * @param emitStrategy {@link EmitStrategy} to configure when the aggregated result for a window will be emitted. * @return a {@code SessionWindowedKStream} with {@link EmitStrategy} configured. */ SessionWindowedKStream emitStrategy(final EmitStrategy emitStrategy); }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy