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The AWS Java SDK for Amazon Kinesis module holds the client classes that are used for communicating with Amazon Kinesis Service

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/*
 * Copyright 2019-2024 Amazon.com, Inc. or its affiliates. All Rights Reserved.
 * 
 * Licensed under the Apache License, Version 2.0 (the "License"). You may not use this file except in compliance with
 * the License. A copy of the License is located at
 * 
 * http://aws.amazon.com/apache2.0
 * 
 * or in the "license" file accompanying this file. This file 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 com.amazonaws.services.kinesis;

import javax.annotation.Generated;

import com.amazonaws.services.kinesis.model.*;

/**
 * Interface for accessing Kinesis asynchronously. Each asynchronous method will return a Java Future object
 * representing the asynchronous operation; overloads which accept an {@code AsyncHandler} can be used to receive
 * notification when an asynchronous operation completes.
 * 

* Note: Do not directly implement this interface, new methods are added to it regularly. Extend from * {@link com.amazonaws.services.kinesis.AbstractAmazonKinesisAsync} instead. *

*

* Amazon Kinesis Data Streams Service API Reference *

* Amazon Kinesis Data Streams is a managed service that scales elastically for real-time processing of streaming big * data. *

*/ @Generated("com.amazonaws:aws-java-sdk-code-generator") public interface AmazonKinesisAsync extends AmazonKinesis { /** *

* Adds or updates tags for the specified Kinesis data stream. You can assign up to 50 tags to a data stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If tags have already been assigned to the stream, AddTagsToStream overwrites any existing tags that * correspond to the specified tag keys. *

*

* AddTagsToStream has a limit of five transactions per second per account. *

* * @param addTagsToStreamRequest * Represents the input for AddTagsToStream. * @return A Java Future containing the result of the AddTagsToStream operation returned by the service. * @sample AmazonKinesisAsync.AddTagsToStream * @see AWS API * Documentation */ java.util.concurrent.Future addTagsToStreamAsync(AddTagsToStreamRequest addTagsToStreamRequest); /** *

* Adds or updates tags for the specified Kinesis data stream. You can assign up to 50 tags to a data stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If tags have already been assigned to the stream, AddTagsToStream overwrites any existing tags that * correspond to the specified tag keys. *

*

* AddTagsToStream has a limit of five transactions per second per account. *

* * @param addTagsToStreamRequest * Represents the input for AddTagsToStream. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the AddTagsToStream operation returned by the service. * @sample AmazonKinesisAsyncHandler.AddTagsToStream * @see AWS API * Documentation */ java.util.concurrent.Future addTagsToStreamAsync(AddTagsToStreamRequest addTagsToStreamRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Creates a Kinesis data stream. A stream captures and transports data records that are continuously emitted from * different data sources or producers. Scale-out within a stream is explicitly supported by means of shards, * which are uniquely identified groups of data records in a stream. *

*

* You can create your data stream using either on-demand or provisioned capacity mode. Data streams with an * on-demand mode require no capacity planning and automatically scale to handle gigabytes of write and read * throughput per minute. With the on-demand mode, Kinesis Data Streams automatically manages the shards in order to * provide the necessary throughput. For the data streams with a provisioned mode, you must specify the number of * shards for the data stream. Each shard can support reads up to five transactions per second, up to a maximum data * read total of 2 MiB per second. Each shard can support writes up to 1,000 records per second, up to a maximum * data write total of 1 MiB per second. If the amount of data input increases or decreases, you can add or remove * shards. *

*

* The stream name identifies the stream. The name is scoped to the Amazon Web Services account used by the * application. It is also scoped by Amazon Web Services Region. That is, two streams in two different accounts can * have the same name, and two streams in the same account, but in two different Regions, can have the same name. *

*

* CreateStream is an asynchronous operation. Upon receiving a CreateStream request, * Kinesis Data Streams immediately returns and sets the stream status to CREATING. After the stream is * created, Kinesis Data Streams sets the stream status to ACTIVE. You should perform read and write * operations only on an ACTIVE stream. *

*

* You receive a LimitExceededException when making a CreateStream request when you try to * do one of the following: *

*
    *
  • *

    * Have more than five streams in the CREATING state at any point in time. *

    *
  • *
  • *

    * Create more shards than are authorized for your account. *

    *
  • *
*

* For the default shard limit for an Amazon Web Services account, see Amazon Kinesis Data Streams * Limits in the Amazon Kinesis Data Streams Developer Guide. To increase this limit, contact Amazon Web Services * Support. *

*

* You can use DescribeStreamSummary to check the stream status, which is returned in * StreamStatus. *

*

* CreateStream has a limit of five transactions per second per account. *

* * @param createStreamRequest * Represents the input for CreateStream. * @return A Java Future containing the result of the CreateStream operation returned by the service. * @sample AmazonKinesisAsync.CreateStream * @see AWS API * Documentation */ java.util.concurrent.Future createStreamAsync(CreateStreamRequest createStreamRequest); /** *

* Creates a Kinesis data stream. A stream captures and transports data records that are continuously emitted from * different data sources or producers. Scale-out within a stream is explicitly supported by means of shards, * which are uniquely identified groups of data records in a stream. *

*

* You can create your data stream using either on-demand or provisioned capacity mode. Data streams with an * on-demand mode require no capacity planning and automatically scale to handle gigabytes of write and read * throughput per minute. With the on-demand mode, Kinesis Data Streams automatically manages the shards in order to * provide the necessary throughput. For the data streams with a provisioned mode, you must specify the number of * shards for the data stream. Each shard can support reads up to five transactions per second, up to a maximum data * read total of 2 MiB per second. Each shard can support writes up to 1,000 records per second, up to a maximum * data write total of 1 MiB per second. If the amount of data input increases or decreases, you can add or remove * shards. *

*

* The stream name identifies the stream. The name is scoped to the Amazon Web Services account used by the * application. It is also scoped by Amazon Web Services Region. That is, two streams in two different accounts can * have the same name, and two streams in the same account, but in two different Regions, can have the same name. *

*

* CreateStream is an asynchronous operation. Upon receiving a CreateStream request, * Kinesis Data Streams immediately returns and sets the stream status to CREATING. After the stream is * created, Kinesis Data Streams sets the stream status to ACTIVE. You should perform read and write * operations only on an ACTIVE stream. *

*

* You receive a LimitExceededException when making a CreateStream request when you try to * do one of the following: *

*
    *
  • *

    * Have more than five streams in the CREATING state at any point in time. *

    *
  • *
  • *

    * Create more shards than are authorized for your account. *

    *
  • *
*

* For the default shard limit for an Amazon Web Services account, see Amazon Kinesis Data Streams * Limits in the Amazon Kinesis Data Streams Developer Guide. To increase this limit, contact Amazon Web Services * Support. *

*

* You can use DescribeStreamSummary to check the stream status, which is returned in * StreamStatus. *

*

* CreateStream has a limit of five transactions per second per account. *

* * @param createStreamRequest * Represents the input for CreateStream. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the CreateStream operation returned by the service. * @sample AmazonKinesisAsyncHandler.CreateStream * @see AWS API * Documentation */ java.util.concurrent.Future createStreamAsync(CreateStreamRequest createStreamRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the CreateStream operation. * * @see #createStreamAsync(CreateStreamRequest) */ java.util.concurrent.Future createStreamAsync(String streamName, Integer shardCount); /** * Simplified method form for invoking the CreateStream operation with an AsyncHandler. * * @see #createStreamAsync(CreateStreamRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future createStreamAsync(String streamName, Integer shardCount, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Decreases the Kinesis data stream's retention period, which is the length of time data records are accessible * after they are added to the stream. The minimum value of a stream's retention period is 24 hours. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* This operation may result in lost data. For example, if the stream's retention period is 48 hours and is * decreased to 24 hours, any data already in the stream that is older than 24 hours is inaccessible. *

* * @param decreaseStreamRetentionPeriodRequest * Represents the input for DecreaseStreamRetentionPeriod. * @return A Java Future containing the result of the DecreaseStreamRetentionPeriod operation returned by the * service. * @sample AmazonKinesisAsync.DecreaseStreamRetentionPeriod * @see AWS API Documentation */ java.util.concurrent.Future decreaseStreamRetentionPeriodAsync( DecreaseStreamRetentionPeriodRequest decreaseStreamRetentionPeriodRequest); /** *

* Decreases the Kinesis data stream's retention period, which is the length of time data records are accessible * after they are added to the stream. The minimum value of a stream's retention period is 24 hours. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* This operation may result in lost data. For example, if the stream's retention period is 48 hours and is * decreased to 24 hours, any data already in the stream that is older than 24 hours is inaccessible. *

* * @param decreaseStreamRetentionPeriodRequest * Represents the input for DecreaseStreamRetentionPeriod. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DecreaseStreamRetentionPeriod operation returned by the * service. * @sample AmazonKinesisAsyncHandler.DecreaseStreamRetentionPeriod * @see AWS API Documentation */ java.util.concurrent.Future decreaseStreamRetentionPeriodAsync( DecreaseStreamRetentionPeriodRequest decreaseStreamRetentionPeriodRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Delete a policy for the specified data stream or consumer. Request patterns can be one of the following: *

*
    *
  • *

    * Data stream pattern: arn:aws.*:kinesis:.*:\d{12}:.*stream/\S+ *

    *
  • *
  • *

    * Consumer pattern: * ^(arn):aws.*:kinesis:.*:\d{12}:.*stream\/[a-zA-Z0-9_.-]+\/consumer\/[a-zA-Z0-9_.-]+:[0-9]+ *

    *
  • *
* * @param deleteResourcePolicyRequest * @return A Java Future containing the result of the DeleteResourcePolicy operation returned by the service. * @sample AmazonKinesisAsync.DeleteResourcePolicy * @see AWS * API Documentation */ java.util.concurrent.Future deleteResourcePolicyAsync(DeleteResourcePolicyRequest deleteResourcePolicyRequest); /** *

* Delete a policy for the specified data stream or consumer. Request patterns can be one of the following: *

*
    *
  • *

    * Data stream pattern: arn:aws.*:kinesis:.*:\d{12}:.*stream/\S+ *

    *
  • *
  • *

    * Consumer pattern: * ^(arn):aws.*:kinesis:.*:\d{12}:.*stream\/[a-zA-Z0-9_.-]+\/consumer\/[a-zA-Z0-9_.-]+:[0-9]+ *

    *
  • *
* * @param deleteResourcePolicyRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DeleteResourcePolicy operation returned by the service. * @sample AmazonKinesisAsyncHandler.DeleteResourcePolicy * @see AWS * API Documentation */ java.util.concurrent.Future deleteResourcePolicyAsync(DeleteResourcePolicyRequest deleteResourcePolicyRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Deletes a Kinesis data stream and all its shards and data. You must shut down any applications that are operating * on the stream before you delete the stream. If an application attempts to operate on a deleted stream, it * receives the exception ResourceNotFoundException. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If the stream is in the ACTIVE state, you can delete it. After a DeleteStream request, * the specified stream is in the DELETING state until Kinesis Data Streams completes the deletion. *

*

* Note: Kinesis Data Streams might continue to accept data read and write operations, such as * PutRecord, PutRecords, and GetRecords, on a stream in the DELETING state until * the stream deletion is complete. *

*

* When you delete a stream, any shards in that stream are also deleted, and any tags are dissociated from the * stream. *

*

* You can use the DescribeStreamSummary operation to check the state of the stream, which is returned in * StreamStatus. *

*

* DeleteStream has a limit of five transactions per second per account. *

* * @param deleteStreamRequest * Represents the input for DeleteStream. * @return A Java Future containing the result of the DeleteStream operation returned by the service. * @sample AmazonKinesisAsync.DeleteStream * @see AWS API * Documentation */ java.util.concurrent.Future deleteStreamAsync(DeleteStreamRequest deleteStreamRequest); /** *

* Deletes a Kinesis data stream and all its shards and data. You must shut down any applications that are operating * on the stream before you delete the stream. If an application attempts to operate on a deleted stream, it * receives the exception ResourceNotFoundException. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If the stream is in the ACTIVE state, you can delete it. After a DeleteStream request, * the specified stream is in the DELETING state until Kinesis Data Streams completes the deletion. *

*

* Note: Kinesis Data Streams might continue to accept data read and write operations, such as * PutRecord, PutRecords, and GetRecords, on a stream in the DELETING state until * the stream deletion is complete. *

*

* When you delete a stream, any shards in that stream are also deleted, and any tags are dissociated from the * stream. *

*

* You can use the DescribeStreamSummary operation to check the state of the stream, which is returned in * StreamStatus. *

*

* DeleteStream has a limit of five transactions per second per account. *

* * @param deleteStreamRequest * Represents the input for DeleteStream. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DeleteStream operation returned by the service. * @sample AmazonKinesisAsyncHandler.DeleteStream * @see AWS API * Documentation */ java.util.concurrent.Future deleteStreamAsync(DeleteStreamRequest deleteStreamRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the DeleteStream operation. * * @see #deleteStreamAsync(DeleteStreamRequest) */ java.util.concurrent.Future deleteStreamAsync(String streamName); /** * Simplified method form for invoking the DeleteStream operation with an AsyncHandler. * * @see #deleteStreamAsync(DeleteStreamRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future deleteStreamAsync(String streamName, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* To deregister a consumer, provide its ARN. Alternatively, you can provide the ARN of the data stream and the name * you gave the consumer when you registered it. You may also provide all three parameters, as long as they don't * conflict with each other. If you don't know the name or ARN of the consumer that you want to deregister, you can * use the ListStreamConsumers operation to get a list of the descriptions of all the consumers that are * currently registered with a given data stream. The description of a consumer contains its name and ARN. *

*

* This operation has a limit of five transactions per second per stream. *

* * @param deregisterStreamConsumerRequest * @return A Java Future containing the result of the DeregisterStreamConsumer operation returned by the service. * @sample AmazonKinesisAsync.DeregisterStreamConsumer * @see AWS API Documentation */ java.util.concurrent.Future deregisterStreamConsumerAsync(DeregisterStreamConsumerRequest deregisterStreamConsumerRequest); /** *

* To deregister a consumer, provide its ARN. Alternatively, you can provide the ARN of the data stream and the name * you gave the consumer when you registered it. You may also provide all three parameters, as long as they don't * conflict with each other. If you don't know the name or ARN of the consumer that you want to deregister, you can * use the ListStreamConsumers operation to get a list of the descriptions of all the consumers that are * currently registered with a given data stream. The description of a consumer contains its name and ARN. *

*

* This operation has a limit of five transactions per second per stream. *

* * @param deregisterStreamConsumerRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DeregisterStreamConsumer operation returned by the service. * @sample AmazonKinesisAsyncHandler.DeregisterStreamConsumer * @see AWS API Documentation */ java.util.concurrent.Future deregisterStreamConsumerAsync(DeregisterStreamConsumerRequest deregisterStreamConsumerRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Describes the shard limits and usage for the account. *

*

* If you update your account limits, the old limits might be returned for a few minutes. *

*

* This operation has a limit of one transaction per second per account. *

* * @param describeLimitsRequest * @return A Java Future containing the result of the DescribeLimits operation returned by the service. * @sample AmazonKinesisAsync.DescribeLimits * @see AWS API * Documentation */ java.util.concurrent.Future describeLimitsAsync(DescribeLimitsRequest describeLimitsRequest); /** *

* Describes the shard limits and usage for the account. *

*

* If you update your account limits, the old limits might be returned for a few minutes. *

*

* This operation has a limit of one transaction per second per account. *

* * @param describeLimitsRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DescribeLimits operation returned by the service. * @sample AmazonKinesisAsyncHandler.DescribeLimits * @see AWS API * Documentation */ java.util.concurrent.Future describeLimitsAsync(DescribeLimitsRequest describeLimitsRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Describes the specified Kinesis data stream. *

* *

* This API has been revised. It's highly recommended that you use the DescribeStreamSummary API to get a * summarized description of the specified Kinesis data stream and the ListShards API to list the shards in a * specified data stream and obtain information about each shard. *

*
*

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* The information returned includes the stream name, Amazon Resource Name (ARN), creation time, enhanced metric * configuration, and shard map. The shard map is an array of shard objects. For each shard object, there is the * hash key and sequence number ranges that the shard spans, and the IDs of any earlier shards that played in a role * in creating the shard. Every record ingested in the stream is identified by a sequence number, which is assigned * when the record is put into the stream. *

*

* You can limit the number of shards returned by each call. For more information, see Retrieving * Shards from a Stream in the Amazon Kinesis Data Streams Developer Guide. *

*

* There are no guarantees about the chronological order shards returned. To process shards in chronological order, * use the ID of the parent shard to track the lineage to the oldest shard. *

*

* This operation has a limit of 10 transactions per second per account. *

* * @param describeStreamRequest * Represents the input for DescribeStream. * @return A Java Future containing the result of the DescribeStream operation returned by the service. * @sample AmazonKinesisAsync.DescribeStream * @see AWS API * Documentation */ java.util.concurrent.Future describeStreamAsync(DescribeStreamRequest describeStreamRequest); /** *

* Describes the specified Kinesis data stream. *

* *

* This API has been revised. It's highly recommended that you use the DescribeStreamSummary API to get a * summarized description of the specified Kinesis data stream and the ListShards API to list the shards in a * specified data stream and obtain information about each shard. *

*
*

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* The information returned includes the stream name, Amazon Resource Name (ARN), creation time, enhanced metric * configuration, and shard map. The shard map is an array of shard objects. For each shard object, there is the * hash key and sequence number ranges that the shard spans, and the IDs of any earlier shards that played in a role * in creating the shard. Every record ingested in the stream is identified by a sequence number, which is assigned * when the record is put into the stream. *

*

* You can limit the number of shards returned by each call. For more information, see Retrieving * Shards from a Stream in the Amazon Kinesis Data Streams Developer Guide. *

*

* There are no guarantees about the chronological order shards returned. To process shards in chronological order, * use the ID of the parent shard to track the lineage to the oldest shard. *

*

* This operation has a limit of 10 transactions per second per account. *

* * @param describeStreamRequest * Represents the input for DescribeStream. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DescribeStream operation returned by the service. * @sample AmazonKinesisAsyncHandler.DescribeStream * @see AWS API * Documentation */ java.util.concurrent.Future describeStreamAsync(DescribeStreamRequest describeStreamRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the DescribeStream operation. * * @see #describeStreamAsync(DescribeStreamRequest) */ java.util.concurrent.Future describeStreamAsync(String streamName); /** * Simplified method form for invoking the DescribeStream operation with an AsyncHandler. * * @see #describeStreamAsync(DescribeStreamRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future describeStreamAsync(String streamName, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the DescribeStream operation. * * @see #describeStreamAsync(DescribeStreamRequest) */ java.util.concurrent.Future describeStreamAsync(String streamName, String exclusiveStartShardId); /** * Simplified method form for invoking the DescribeStream operation with an AsyncHandler. * * @see #describeStreamAsync(DescribeStreamRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future describeStreamAsync(String streamName, String exclusiveStartShardId, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the DescribeStream operation. * * @see #describeStreamAsync(DescribeStreamRequest) */ java.util.concurrent.Future describeStreamAsync(String streamName, Integer limit, String exclusiveStartShardId); /** * Simplified method form for invoking the DescribeStream operation with an AsyncHandler. * * @see #describeStreamAsync(DescribeStreamRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future describeStreamAsync(String streamName, Integer limit, String exclusiveStartShardId, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* To get the description of a registered consumer, provide the ARN of the consumer. Alternatively, you can provide * the ARN of the data stream and the name you gave the consumer when you registered it. You may also provide all * three parameters, as long as they don't conflict with each other. If you don't know the name or ARN of the * consumer that you want to describe, you can use the ListStreamConsumers operation to get a list of the * descriptions of all the consumers that are currently registered with a given data stream. *

*

* This operation has a limit of 20 transactions per second per stream. *

* *

* When making a cross-account call with DescribeStreamConsumer, make sure to provide the ARN of the * consumer. *

*
* * @param describeStreamConsumerRequest * @return A Java Future containing the result of the DescribeStreamConsumer operation returned by the service. * @sample AmazonKinesisAsync.DescribeStreamConsumer * @see AWS * API Documentation */ java.util.concurrent.Future describeStreamConsumerAsync(DescribeStreamConsumerRequest describeStreamConsumerRequest); /** *

* To get the description of a registered consumer, provide the ARN of the consumer. Alternatively, you can provide * the ARN of the data stream and the name you gave the consumer when you registered it. You may also provide all * three parameters, as long as they don't conflict with each other. If you don't know the name or ARN of the * consumer that you want to describe, you can use the ListStreamConsumers operation to get a list of the * descriptions of all the consumers that are currently registered with a given data stream. *

*

* This operation has a limit of 20 transactions per second per stream. *

* *

* When making a cross-account call with DescribeStreamConsumer, make sure to provide the ARN of the * consumer. *

*
* * @param describeStreamConsumerRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DescribeStreamConsumer operation returned by the service. * @sample AmazonKinesisAsyncHandler.DescribeStreamConsumer * @see AWS * API Documentation */ java.util.concurrent.Future describeStreamConsumerAsync(DescribeStreamConsumerRequest describeStreamConsumerRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Provides a summarized description of the specified Kinesis data stream without the shard list. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* The information returned includes the stream name, Amazon Resource Name (ARN), status, record retention period, * approximate creation time, monitoring, encryption details, and open shard count. *

*

* DescribeStreamSummary has a limit of 20 transactions per second per account. *

* * @param describeStreamSummaryRequest * @return A Java Future containing the result of the DescribeStreamSummary operation returned by the service. * @sample AmazonKinesisAsync.DescribeStreamSummary * @see AWS * API Documentation */ java.util.concurrent.Future describeStreamSummaryAsync(DescribeStreamSummaryRequest describeStreamSummaryRequest); /** *

* Provides a summarized description of the specified Kinesis data stream without the shard list. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* The information returned includes the stream name, Amazon Resource Name (ARN), status, record retention period, * approximate creation time, monitoring, encryption details, and open shard count. *

*

* DescribeStreamSummary has a limit of 20 transactions per second per account. *

* * @param describeStreamSummaryRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DescribeStreamSummary operation returned by the service. * @sample AmazonKinesisAsyncHandler.DescribeStreamSummary * @see AWS * API Documentation */ java.util.concurrent.Future describeStreamSummaryAsync(DescribeStreamSummaryRequest describeStreamSummaryRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Disables enhanced monitoring. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
* * @param disableEnhancedMonitoringRequest * Represents the input for DisableEnhancedMonitoring. * @return A Java Future containing the result of the DisableEnhancedMonitoring operation returned by the service. * @sample AmazonKinesisAsync.DisableEnhancedMonitoring * @see AWS API Documentation */ java.util.concurrent.Future disableEnhancedMonitoringAsync( DisableEnhancedMonitoringRequest disableEnhancedMonitoringRequest); /** *

* Disables enhanced monitoring. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
* * @param disableEnhancedMonitoringRequest * Represents the input for DisableEnhancedMonitoring. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the DisableEnhancedMonitoring operation returned by the service. * @sample AmazonKinesisAsyncHandler.DisableEnhancedMonitoring * @see AWS API Documentation */ java.util.concurrent.Future disableEnhancedMonitoringAsync( DisableEnhancedMonitoringRequest disableEnhancedMonitoringRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Enables enhanced Kinesis data stream monitoring for shard-level metrics. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
* * @param enableEnhancedMonitoringRequest * Represents the input for EnableEnhancedMonitoring. * @return A Java Future containing the result of the EnableEnhancedMonitoring operation returned by the service. * @sample AmazonKinesisAsync.EnableEnhancedMonitoring * @see AWS API Documentation */ java.util.concurrent.Future enableEnhancedMonitoringAsync(EnableEnhancedMonitoringRequest enableEnhancedMonitoringRequest); /** *

* Enables enhanced Kinesis data stream monitoring for shard-level metrics. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
* * @param enableEnhancedMonitoringRequest * Represents the input for EnableEnhancedMonitoring. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the EnableEnhancedMonitoring operation returned by the service. * @sample AmazonKinesisAsyncHandler.EnableEnhancedMonitoring * @see AWS API Documentation */ java.util.concurrent.Future enableEnhancedMonitoringAsync(EnableEnhancedMonitoringRequest enableEnhancedMonitoringRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Gets data records from a Kinesis data stream's shard. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Specify a shard iterator using the ShardIterator parameter. The shard iterator specifies the * position in the shard from which you want to start reading data records sequentially. If there are no records * available in the portion of the shard that the iterator points to, GetRecords returns an empty list. It * might take multiple calls to get to a portion of the shard that contains records. *

*

* You can scale by provisioning multiple shards per stream while considering service limits (for more information, * see Amazon Kinesis Data * Streams Limits in the Amazon Kinesis Data Streams Developer Guide). Your application should have one * thread per shard, each reading continuously from its stream. To read from a stream continually, call * GetRecords in a loop. Use GetShardIterator to get the shard iterator to specify in the first * GetRecords call. GetRecords returns a new shard iterator in NextShardIterator. Specify * the shard iterator returned in NextShardIterator in subsequent calls to GetRecords. If the * shard has been closed, the shard iterator can't return more data and GetRecords returns null * in NextShardIterator. You can terminate the loop when the shard is closed, or when the shard * iterator reaches the record with the sequence number or other attribute that marks it as the last record to * process. *

*

* Each data record can be up to 1 MiB in size, and each shard can read up to 2 MiB per second. You can ensure that * your calls don't exceed the maximum supported size or throughput by using the Limit parameter to * specify the maximum number of records that GetRecords can return. Consider your average record size when * determining this limit. The maximum number of records that can be returned per call is 10,000. *

*

* The size of the data returned by GetRecords varies depending on the utilization of the shard. It is * recommended that consumer applications retrieve records via the GetRecords command using the 5 TPS * limit to remain caught up. Retrieving records less frequently can lead to consumer applications falling behind. * The maximum size of data that GetRecords can return is 10 MiB. If a call returns this amount of data, * subsequent calls made within the next 5 seconds throw ProvisionedThroughputExceededException. If * there is insufficient provisioned throughput on the stream, subsequent calls made within the next 1 second throw * ProvisionedThroughputExceededException. GetRecords doesn't return any data when it throws an * exception. For this reason, we recommend that you wait 1 second between calls to GetRecords. However, it's * possible that the application will get exceptions for longer than 1 second. *

*

* To detect whether the application is falling behind in processing, you can use the * MillisBehindLatest response attribute. You can also monitor the stream using CloudWatch metrics and * other mechanisms (see Monitoring in * the Amazon Kinesis Data Streams Developer Guide). *

*

* Each Amazon Kinesis record includes a value, ApproximateArrivalTimestamp, that is set when a stream * successfully receives and stores a record. This is commonly referred to as a server-side time stamp, whereas a * client-side time stamp is set when a data producer creates or sends the record to a stream (a data producer is * any data source putting data records into a stream, for example with PutRecords). The time stamp has * millisecond precision. There are no guarantees about the time stamp accuracy, or that the time stamp is always * increasing. For example, records in a shard or across a stream might have time stamps that are out of order. *

*

* This operation has a limit of five transactions per second per shard. *

* * @param getRecordsRequest * Represents the input for GetRecords. * @return A Java Future containing the result of the GetRecords operation returned by the service. * @sample AmazonKinesisAsync.GetRecords * @see AWS API * Documentation */ java.util.concurrent.Future getRecordsAsync(GetRecordsRequest getRecordsRequest); /** *

* Gets data records from a Kinesis data stream's shard. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Specify a shard iterator using the ShardIterator parameter. The shard iterator specifies the * position in the shard from which you want to start reading data records sequentially. If there are no records * available in the portion of the shard that the iterator points to, GetRecords returns an empty list. It * might take multiple calls to get to a portion of the shard that contains records. *

*

* You can scale by provisioning multiple shards per stream while considering service limits (for more information, * see Amazon Kinesis Data * Streams Limits in the Amazon Kinesis Data Streams Developer Guide). Your application should have one * thread per shard, each reading continuously from its stream. To read from a stream continually, call * GetRecords in a loop. Use GetShardIterator to get the shard iterator to specify in the first * GetRecords call. GetRecords returns a new shard iterator in NextShardIterator. Specify * the shard iterator returned in NextShardIterator in subsequent calls to GetRecords. If the * shard has been closed, the shard iterator can't return more data and GetRecords returns null * in NextShardIterator. You can terminate the loop when the shard is closed, or when the shard * iterator reaches the record with the sequence number or other attribute that marks it as the last record to * process. *

*

* Each data record can be up to 1 MiB in size, and each shard can read up to 2 MiB per second. You can ensure that * your calls don't exceed the maximum supported size or throughput by using the Limit parameter to * specify the maximum number of records that GetRecords can return. Consider your average record size when * determining this limit. The maximum number of records that can be returned per call is 10,000. *

*

* The size of the data returned by GetRecords varies depending on the utilization of the shard. It is * recommended that consumer applications retrieve records via the GetRecords command using the 5 TPS * limit to remain caught up. Retrieving records less frequently can lead to consumer applications falling behind. * The maximum size of data that GetRecords can return is 10 MiB. If a call returns this amount of data, * subsequent calls made within the next 5 seconds throw ProvisionedThroughputExceededException. If * there is insufficient provisioned throughput on the stream, subsequent calls made within the next 1 second throw * ProvisionedThroughputExceededException. GetRecords doesn't return any data when it throws an * exception. For this reason, we recommend that you wait 1 second between calls to GetRecords. However, it's * possible that the application will get exceptions for longer than 1 second. *

*

* To detect whether the application is falling behind in processing, you can use the * MillisBehindLatest response attribute. You can also monitor the stream using CloudWatch metrics and * other mechanisms (see Monitoring in * the Amazon Kinesis Data Streams Developer Guide). *

*

* Each Amazon Kinesis record includes a value, ApproximateArrivalTimestamp, that is set when a stream * successfully receives and stores a record. This is commonly referred to as a server-side time stamp, whereas a * client-side time stamp is set when a data producer creates or sends the record to a stream (a data producer is * any data source putting data records into a stream, for example with PutRecords). The time stamp has * millisecond precision. There are no guarantees about the time stamp accuracy, or that the time stamp is always * increasing. For example, records in a shard or across a stream might have time stamps that are out of order. *

*

* This operation has a limit of five transactions per second per shard. *

* * @param getRecordsRequest * Represents the input for GetRecords. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the GetRecords operation returned by the service. * @sample AmazonKinesisAsyncHandler.GetRecords * @see AWS API * Documentation */ java.util.concurrent.Future getRecordsAsync(GetRecordsRequest getRecordsRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Returns a policy attached to the specified data stream or consumer. Request patterns can be one of the following: *

*
    *
  • *

    * Data stream pattern: arn:aws.*:kinesis:.*:\d{12}:.*stream/\S+ *

    *
  • *
  • *

    * Consumer pattern: * ^(arn):aws.*:kinesis:.*:\d{12}:.*stream\/[a-zA-Z0-9_.-]+\/consumer\/[a-zA-Z0-9_.-]+:[0-9]+ *

    *
  • *
* * @param getResourcePolicyRequest * @return A Java Future containing the result of the GetResourcePolicy operation returned by the service. * @sample AmazonKinesisAsync.GetResourcePolicy * @see AWS API * Documentation */ java.util.concurrent.Future getResourcePolicyAsync(GetResourcePolicyRequest getResourcePolicyRequest); /** *

* Returns a policy attached to the specified data stream or consumer. Request patterns can be one of the following: *

*
    *
  • *

    * Data stream pattern: arn:aws.*:kinesis:.*:\d{12}:.*stream/\S+ *

    *
  • *
  • *

    * Consumer pattern: * ^(arn):aws.*:kinesis:.*:\d{12}:.*stream\/[a-zA-Z0-9_.-]+\/consumer\/[a-zA-Z0-9_.-]+:[0-9]+ *

    *
  • *
* * @param getResourcePolicyRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the GetResourcePolicy operation returned by the service. * @sample AmazonKinesisAsyncHandler.GetResourcePolicy * @see AWS API * Documentation */ java.util.concurrent.Future getResourcePolicyAsync(GetResourcePolicyRequest getResourcePolicyRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Gets an Amazon Kinesis shard iterator. A shard iterator expires 5 minutes after it is returned to the requester. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* A shard iterator specifies the shard position from which to start reading data records sequentially. The position * is specified using the sequence number of a data record in a shard. A sequence number is the identifier * associated with every record ingested in the stream, and is assigned when a record is put into the stream. Each * stream has one or more shards. *

*

* You must specify the shard iterator type. For example, you can set the ShardIteratorType parameter * to read exactly from the position denoted by a specific sequence number by using the * AT_SEQUENCE_NUMBER shard iterator type. Alternatively, the parameter can read right after the * sequence number by using the AFTER_SEQUENCE_NUMBER shard iterator type, using sequence numbers * returned by earlier calls to PutRecord, PutRecords, GetRecords, or DescribeStream. In * the request, you can specify the shard iterator type AT_TIMESTAMP to read records from an arbitrary * point in time, TRIM_HORIZON to cause ShardIterator to point to the last untrimmed * record in the shard in the system (the oldest data record in the shard), or LATEST so that you * always read the most recent data in the shard. *

*

* When you read repeatedly from a stream, use a GetShardIterator request to get the first shard iterator for * use in your first GetRecords request and for subsequent reads use the shard iterator returned by the * GetRecords request in NextShardIterator. A new shard iterator is returned by every * GetRecords request in NextShardIterator, which you use in the ShardIterator * parameter of the next GetRecords request. *

*

* If a GetShardIterator request is made too often, you receive a * ProvisionedThroughputExceededException. For more information about throughput limits, see * GetRecords, and Streams Limits in the * Amazon Kinesis Data Streams Developer Guide. *

*

* If the shard is closed, GetShardIterator returns a valid iterator for the last sequence number of the * shard. A shard can be closed as a result of using SplitShard or MergeShards. *

*

* GetShardIterator has a limit of five transactions per second per account per open shard. *

* * @param getShardIteratorRequest * Represents the input for GetShardIterator. * @return A Java Future containing the result of the GetShardIterator operation returned by the service. * @sample AmazonKinesisAsync.GetShardIterator * @see AWS API * Documentation */ java.util.concurrent.Future getShardIteratorAsync(GetShardIteratorRequest getShardIteratorRequest); /** *

* Gets an Amazon Kinesis shard iterator. A shard iterator expires 5 minutes after it is returned to the requester. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* A shard iterator specifies the shard position from which to start reading data records sequentially. The position * is specified using the sequence number of a data record in a shard. A sequence number is the identifier * associated with every record ingested in the stream, and is assigned when a record is put into the stream. Each * stream has one or more shards. *

*

* You must specify the shard iterator type. For example, you can set the ShardIteratorType parameter * to read exactly from the position denoted by a specific sequence number by using the * AT_SEQUENCE_NUMBER shard iterator type. Alternatively, the parameter can read right after the * sequence number by using the AFTER_SEQUENCE_NUMBER shard iterator type, using sequence numbers * returned by earlier calls to PutRecord, PutRecords, GetRecords, or DescribeStream. In * the request, you can specify the shard iterator type AT_TIMESTAMP to read records from an arbitrary * point in time, TRIM_HORIZON to cause ShardIterator to point to the last untrimmed * record in the shard in the system (the oldest data record in the shard), or LATEST so that you * always read the most recent data in the shard. *

*

* When you read repeatedly from a stream, use a GetShardIterator request to get the first shard iterator for * use in your first GetRecords request and for subsequent reads use the shard iterator returned by the * GetRecords request in NextShardIterator. A new shard iterator is returned by every * GetRecords request in NextShardIterator, which you use in the ShardIterator * parameter of the next GetRecords request. *

*

* If a GetShardIterator request is made too often, you receive a * ProvisionedThroughputExceededException. For more information about throughput limits, see * GetRecords, and Streams Limits in the * Amazon Kinesis Data Streams Developer Guide. *

*

* If the shard is closed, GetShardIterator returns a valid iterator for the last sequence number of the * shard. A shard can be closed as a result of using SplitShard or MergeShards. *

*

* GetShardIterator has a limit of five transactions per second per account per open shard. *

* * @param getShardIteratorRequest * Represents the input for GetShardIterator. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the GetShardIterator operation returned by the service. * @sample AmazonKinesisAsyncHandler.GetShardIterator * @see AWS API * Documentation */ java.util.concurrent.Future getShardIteratorAsync(GetShardIteratorRequest getShardIteratorRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the GetShardIterator operation. * * @see #getShardIteratorAsync(GetShardIteratorRequest) */ java.util.concurrent.Future getShardIteratorAsync(String streamName, String shardId, String shardIteratorType); /** * Simplified method form for invoking the GetShardIterator operation with an AsyncHandler. * * @see #getShardIteratorAsync(GetShardIteratorRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future getShardIteratorAsync(String streamName, String shardId, String shardIteratorType, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the GetShardIterator operation. * * @see #getShardIteratorAsync(GetShardIteratorRequest) */ java.util.concurrent.Future getShardIteratorAsync(String streamName, String shardId, String shardIteratorType, String startingSequenceNumber); /** * Simplified method form for invoking the GetShardIterator operation with an AsyncHandler. * * @see #getShardIteratorAsync(GetShardIteratorRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future getShardIteratorAsync(String streamName, String shardId, String shardIteratorType, String startingSequenceNumber, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Increases the Kinesis data stream's retention period, which is the length of time data records are accessible * after they are added to the stream. The maximum value of a stream's retention period is 8760 hours (365 days). *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If you choose a longer stream retention period, this operation increases the time period during which records * that have not yet expired are accessible. However, it does not make previous, expired data (older than the * stream's previous retention period) accessible after the operation has been called. For example, if a stream's * retention period is set to 24 hours and is increased to 168 hours, any data that is older than 24 hours remains * inaccessible to consumer applications. *

* * @param increaseStreamRetentionPeriodRequest * Represents the input for IncreaseStreamRetentionPeriod. * @return A Java Future containing the result of the IncreaseStreamRetentionPeriod operation returned by the * service. * @sample AmazonKinesisAsync.IncreaseStreamRetentionPeriod * @see AWS API Documentation */ java.util.concurrent.Future increaseStreamRetentionPeriodAsync( IncreaseStreamRetentionPeriodRequest increaseStreamRetentionPeriodRequest); /** *

* Increases the Kinesis data stream's retention period, which is the length of time data records are accessible * after they are added to the stream. The maximum value of a stream's retention period is 8760 hours (365 days). *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If you choose a longer stream retention period, this operation increases the time period during which records * that have not yet expired are accessible. However, it does not make previous, expired data (older than the * stream's previous retention period) accessible after the operation has been called. For example, if a stream's * retention period is set to 24 hours and is increased to 168 hours, any data that is older than 24 hours remains * inaccessible to consumer applications. *

* * @param increaseStreamRetentionPeriodRequest * Represents the input for IncreaseStreamRetentionPeriod. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the IncreaseStreamRetentionPeriod operation returned by the * service. * @sample AmazonKinesisAsyncHandler.IncreaseStreamRetentionPeriod * @see AWS API Documentation */ java.util.concurrent.Future increaseStreamRetentionPeriodAsync( IncreaseStreamRetentionPeriodRequest increaseStreamRetentionPeriodRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Lists the shards in a stream and provides information about each shard. This operation has a limit of 1000 * transactions per second per data stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* This action does not list expired shards. For information about expired shards, see Data Routing, Data Persistence, and Shard State after a Reshard. *

* *

* This API is a new operation that is used by the Amazon Kinesis Client Library (KCL). If you have a fine-grained * IAM policy that only allows specific operations, you must update your policy to allow calls to this API. For more * information, see Controlling * Access to Amazon Kinesis Data Streams Resources Using IAM. *

*
* * @param listShardsRequest * @return A Java Future containing the result of the ListShards operation returned by the service. * @sample AmazonKinesisAsync.ListShards * @see AWS API * Documentation */ java.util.concurrent.Future listShardsAsync(ListShardsRequest listShardsRequest); /** *

* Lists the shards in a stream and provides information about each shard. This operation has a limit of 1000 * transactions per second per data stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* This action does not list expired shards. For information about expired shards, see Data Routing, Data Persistence, and Shard State after a Reshard. *

* *

* This API is a new operation that is used by the Amazon Kinesis Client Library (KCL). If you have a fine-grained * IAM policy that only allows specific operations, you must update your policy to allow calls to this API. For more * information, see Controlling * Access to Amazon Kinesis Data Streams Resources Using IAM. *

*
* * @param listShardsRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the ListShards operation returned by the service. * @sample AmazonKinesisAsyncHandler.ListShards * @see AWS API * Documentation */ java.util.concurrent.Future listShardsAsync(ListShardsRequest listShardsRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Lists the consumers registered to receive data from a stream using enhanced fan-out, and provides information * about each consumer. *

*

* This operation has a limit of 5 transactions per second per stream. *

* * @param listStreamConsumersRequest * @return A Java Future containing the result of the ListStreamConsumers operation returned by the service. * @sample AmazonKinesisAsync.ListStreamConsumers * @see AWS * API Documentation */ java.util.concurrent.Future listStreamConsumersAsync(ListStreamConsumersRequest listStreamConsumersRequest); /** *

* Lists the consumers registered to receive data from a stream using enhanced fan-out, and provides information * about each consumer. *

*

* This operation has a limit of 5 transactions per second per stream. *

* * @param listStreamConsumersRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the ListStreamConsumers operation returned by the service. * @sample AmazonKinesisAsyncHandler.ListStreamConsumers * @see AWS * API Documentation */ java.util.concurrent.Future listStreamConsumersAsync(ListStreamConsumersRequest listStreamConsumersRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Lists your Kinesis data streams. *

*

* The number of streams may be too large to return from a single call to ListStreams. You can limit * the number of returned streams using the Limit parameter. If you do not specify a value for the * Limit parameter, Kinesis Data Streams uses the default limit, which is currently 100. *

*

* You can detect if there are more streams available to list by using the HasMoreStreams flag from the * returned output. If there are more streams available, you can request more streams by using the name of the last * stream returned by the ListStreams request in the ExclusiveStartStreamName parameter in * a subsequent request to ListStreams. The group of stream names returned by the subsequent request is * then added to the list. You can continue this process until all the stream names have been collected in the list. *

*

* ListStreams has a limit of five transactions per second per account. *

* * @param listStreamsRequest * Represents the input for ListStreams. * @return A Java Future containing the result of the ListStreams operation returned by the service. * @sample AmazonKinesisAsync.ListStreams * @see AWS API * Documentation */ java.util.concurrent.Future listStreamsAsync(ListStreamsRequest listStreamsRequest); /** *

* Lists your Kinesis data streams. *

*

* The number of streams may be too large to return from a single call to ListStreams. You can limit * the number of returned streams using the Limit parameter. If you do not specify a value for the * Limit parameter, Kinesis Data Streams uses the default limit, which is currently 100. *

*

* You can detect if there are more streams available to list by using the HasMoreStreams flag from the * returned output. If there are more streams available, you can request more streams by using the name of the last * stream returned by the ListStreams request in the ExclusiveStartStreamName parameter in * a subsequent request to ListStreams. The group of stream names returned by the subsequent request is * then added to the list. You can continue this process until all the stream names have been collected in the list. *

*

* ListStreams has a limit of five transactions per second per account. *

* * @param listStreamsRequest * Represents the input for ListStreams. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the ListStreams operation returned by the service. * @sample AmazonKinesisAsyncHandler.ListStreams * @see AWS API * Documentation */ java.util.concurrent.Future listStreamsAsync(ListStreamsRequest listStreamsRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the ListStreams operation. * * @see #listStreamsAsync(ListStreamsRequest) */ java.util.concurrent.Future listStreamsAsync(); /** * Simplified method form for invoking the ListStreams operation with an AsyncHandler. * * @see #listStreamsAsync(ListStreamsRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future listStreamsAsync(com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the ListStreams operation. * * @see #listStreamsAsync(ListStreamsRequest) */ java.util.concurrent.Future listStreamsAsync(String exclusiveStartStreamName); /** * Simplified method form for invoking the ListStreams operation with an AsyncHandler. * * @see #listStreamsAsync(ListStreamsRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future listStreamsAsync(String exclusiveStartStreamName, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the ListStreams operation. * * @see #listStreamsAsync(ListStreamsRequest) */ java.util.concurrent.Future listStreamsAsync(Integer limit, String exclusiveStartStreamName); /** * Simplified method form for invoking the ListStreams operation with an AsyncHandler. * * @see #listStreamsAsync(ListStreamsRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future listStreamsAsync(Integer limit, String exclusiveStartStreamName, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Lists the tags for the specified Kinesis data stream. This operation has a limit of five transactions per second * per account. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
* * @param listTagsForStreamRequest * Represents the input for ListTagsForStream. * @return A Java Future containing the result of the ListTagsForStream operation returned by the service. * @sample AmazonKinesisAsync.ListTagsForStream * @see AWS API * Documentation */ java.util.concurrent.Future listTagsForStreamAsync(ListTagsForStreamRequest listTagsForStreamRequest); /** *

* Lists the tags for the specified Kinesis data stream. This operation has a limit of five transactions per second * per account. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
* * @param listTagsForStreamRequest * Represents the input for ListTagsForStream. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the ListTagsForStream operation returned by the service. * @sample AmazonKinesisAsyncHandler.ListTagsForStream * @see AWS API * Documentation */ java.util.concurrent.Future listTagsForStreamAsync(ListTagsForStreamRequest listTagsForStreamRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Merges two adjacent shards in a Kinesis data stream and combines them into a single shard to reduce the stream's * capacity to ingest and transport data. This API is only supported for the data streams with the provisioned * capacity mode. Two shards are considered adjacent if the union of the hash key ranges for the two shards form a * contiguous set with no gaps. For example, if you have two shards, one with a hash key range of 276...381 and the * other with a hash key range of 382...454, then you could merge these two shards into a single shard that would * have a hash key range of 276...454. After the merge, the single child shard receives data for all hash key values * covered by the two parent shards. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* MergeShards is called when there is a need to reduce the overall capacity of a stream because of * excess capacity that is not being used. You must specify the shard to be merged and the adjacent shard for a * stream. For more information about merging shards, see Merge Two * Shards in the Amazon Kinesis Data Streams Developer Guide. *

*

* If the stream is in the ACTIVE state, you can call MergeShards. If a stream is in the * CREATING, UPDATING, or DELETING state, MergeShards returns a * ResourceInUseException. If the specified stream does not exist, MergeShards returns a * ResourceNotFoundException. *

*

* You can use DescribeStreamSummary to check the state of the stream, which is returned in * StreamStatus. *

*

* MergeShards is an asynchronous operation. Upon receiving a MergeShards request, Amazon * Kinesis Data Streams immediately returns a response and sets the StreamStatus to * UPDATING. After the operation is completed, Kinesis Data Streams sets the StreamStatus * to ACTIVE. Read and write operations continue to work while the stream is in the * UPDATING state. *

*

* You use DescribeStreamSummary and the ListShards APIs to determine the shard IDs that are specified * in the MergeShards request. *

*

* If you try to operate on too many streams in parallel using CreateStream, DeleteStream, * MergeShards, or SplitShard, you receive a LimitExceededException. *

*

* MergeShards has a limit of five transactions per second per account. *

* * @param mergeShardsRequest * Represents the input for MergeShards. * @return A Java Future containing the result of the MergeShards operation returned by the service. * @sample AmazonKinesisAsync.MergeShards * @see AWS API * Documentation */ java.util.concurrent.Future mergeShardsAsync(MergeShardsRequest mergeShardsRequest); /** *

* Merges two adjacent shards in a Kinesis data stream and combines them into a single shard to reduce the stream's * capacity to ingest and transport data. This API is only supported for the data streams with the provisioned * capacity mode. Two shards are considered adjacent if the union of the hash key ranges for the two shards form a * contiguous set with no gaps. For example, if you have two shards, one with a hash key range of 276...381 and the * other with a hash key range of 382...454, then you could merge these two shards into a single shard that would * have a hash key range of 276...454. After the merge, the single child shard receives data for all hash key values * covered by the two parent shards. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* MergeShards is called when there is a need to reduce the overall capacity of a stream because of * excess capacity that is not being used. You must specify the shard to be merged and the adjacent shard for a * stream. For more information about merging shards, see Merge Two * Shards in the Amazon Kinesis Data Streams Developer Guide. *

*

* If the stream is in the ACTIVE state, you can call MergeShards. If a stream is in the * CREATING, UPDATING, or DELETING state, MergeShards returns a * ResourceInUseException. If the specified stream does not exist, MergeShards returns a * ResourceNotFoundException. *

*

* You can use DescribeStreamSummary to check the state of the stream, which is returned in * StreamStatus. *

*

* MergeShards is an asynchronous operation. Upon receiving a MergeShards request, Amazon * Kinesis Data Streams immediately returns a response and sets the StreamStatus to * UPDATING. After the operation is completed, Kinesis Data Streams sets the StreamStatus * to ACTIVE. Read and write operations continue to work while the stream is in the * UPDATING state. *

*

* You use DescribeStreamSummary and the ListShards APIs to determine the shard IDs that are specified * in the MergeShards request. *

*

* If you try to operate on too many streams in parallel using CreateStream, DeleteStream, * MergeShards, or SplitShard, you receive a LimitExceededException. *

*

* MergeShards has a limit of five transactions per second per account. *

* * @param mergeShardsRequest * Represents the input for MergeShards. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the MergeShards operation returned by the service. * @sample AmazonKinesisAsyncHandler.MergeShards * @see AWS API * Documentation */ java.util.concurrent.Future mergeShardsAsync(MergeShardsRequest mergeShardsRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the MergeShards operation. * * @see #mergeShardsAsync(MergeShardsRequest) */ java.util.concurrent.Future mergeShardsAsync(String streamName, String shardToMerge, String adjacentShardToMerge); /** * Simplified method form for invoking the MergeShards operation with an AsyncHandler. * * @see #mergeShardsAsync(MergeShardsRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future mergeShardsAsync(String streamName, String shardToMerge, String adjacentShardToMerge, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Writes a single data record into an Amazon Kinesis data stream. Call PutRecord to send data into the * stream for real-time ingestion and subsequent processing, one record at a time. Each shard can support writes up * to 1,000 records per second, up to a maximum data write total of 1 MiB per second. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* You must specify the name of the stream that captures, stores, and transports the data; a partition key; and the * data blob itself. *

*

* The data blob can be any type of data; for example, a segment from a log file, geographic/location data, website * clickstream data, and so on. *

*

* The partition key is used by Kinesis Data Streams to distribute data across shards. Kinesis Data Streams * segregates the data records that belong to a stream into multiple shards, using the partition key associated with * each data record to determine the shard to which a given data record belongs. *

*

* Partition keys are Unicode strings, with a maximum length limit of 256 characters for each key. An MD5 hash * function is used to map partition keys to 128-bit integer values and to map associated data records to shards * using the hash key ranges of the shards. You can override hashing the partition key to determine the shard by * explicitly specifying a hash value using the ExplicitHashKey parameter. For more information, see Adding Data to a Stream in the Amazon Kinesis Data Streams Developer Guide. *

*

* PutRecord returns the shard ID of where the data record was placed and the sequence number that was * assigned to the data record. *

*

* Sequence numbers increase over time and are specific to a shard within a stream, not across all shards within a * stream. To guarantee strictly increasing ordering, write serially to a shard and use the * SequenceNumberForOrdering parameter. For more information, see Adding Data to a Stream in the Amazon Kinesis Data Streams Developer Guide. *

* *

* After you write a record to a stream, you cannot modify that record or its order within the stream. *

*
*

* If a PutRecord request cannot be processed because of insufficient provisioned throughput on the * shard involved in the request, PutRecord throws ProvisionedThroughputExceededException. *

*

* By default, data records are accessible for 24 hours from the time that they are added to a stream. You can use * IncreaseStreamRetentionPeriod or DecreaseStreamRetentionPeriod to modify this retention period. *

* * @param putRecordRequest * Represents the input for PutRecord. * @return A Java Future containing the result of the PutRecord operation returned by the service. * @sample AmazonKinesisAsync.PutRecord * @see AWS API * Documentation */ java.util.concurrent.Future putRecordAsync(PutRecordRequest putRecordRequest); /** *

* Writes a single data record into an Amazon Kinesis data stream. Call PutRecord to send data into the * stream for real-time ingestion and subsequent processing, one record at a time. Each shard can support writes up * to 1,000 records per second, up to a maximum data write total of 1 MiB per second. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* You must specify the name of the stream that captures, stores, and transports the data; a partition key; and the * data blob itself. *

*

* The data blob can be any type of data; for example, a segment from a log file, geographic/location data, website * clickstream data, and so on. *

*

* The partition key is used by Kinesis Data Streams to distribute data across shards. Kinesis Data Streams * segregates the data records that belong to a stream into multiple shards, using the partition key associated with * each data record to determine the shard to which a given data record belongs. *

*

* Partition keys are Unicode strings, with a maximum length limit of 256 characters for each key. An MD5 hash * function is used to map partition keys to 128-bit integer values and to map associated data records to shards * using the hash key ranges of the shards. You can override hashing the partition key to determine the shard by * explicitly specifying a hash value using the ExplicitHashKey parameter. For more information, see Adding Data to a Stream in the Amazon Kinesis Data Streams Developer Guide. *

*

* PutRecord returns the shard ID of where the data record was placed and the sequence number that was * assigned to the data record. *

*

* Sequence numbers increase over time and are specific to a shard within a stream, not across all shards within a * stream. To guarantee strictly increasing ordering, write serially to a shard and use the * SequenceNumberForOrdering parameter. For more information, see Adding Data to a Stream in the Amazon Kinesis Data Streams Developer Guide. *

* *

* After you write a record to a stream, you cannot modify that record or its order within the stream. *

*
*

* If a PutRecord request cannot be processed because of insufficient provisioned throughput on the * shard involved in the request, PutRecord throws ProvisionedThroughputExceededException. *

*

* By default, data records are accessible for 24 hours from the time that they are added to a stream. You can use * IncreaseStreamRetentionPeriod or DecreaseStreamRetentionPeriod to modify this retention period. *

* * @param putRecordRequest * Represents the input for PutRecord. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the PutRecord operation returned by the service. * @sample AmazonKinesisAsyncHandler.PutRecord * @see AWS API * Documentation */ java.util.concurrent.Future putRecordAsync(PutRecordRequest putRecordRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the PutRecord operation. * * @see #putRecordAsync(PutRecordRequest) */ java.util.concurrent.Future putRecordAsync(String streamName, java.nio.ByteBuffer data, String partitionKey); /** * Simplified method form for invoking the PutRecord operation with an AsyncHandler. * * @see #putRecordAsync(PutRecordRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future putRecordAsync(String streamName, java.nio.ByteBuffer data, String partitionKey, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the PutRecord operation. * * @see #putRecordAsync(PutRecordRequest) */ java.util.concurrent.Future putRecordAsync(String streamName, java.nio.ByteBuffer data, String partitionKey, String sequenceNumberForOrdering); /** * Simplified method form for invoking the PutRecord operation with an AsyncHandler. * * @see #putRecordAsync(PutRecordRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future putRecordAsync(String streamName, java.nio.ByteBuffer data, String partitionKey, String sequenceNumberForOrdering, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Writes multiple data records into a Kinesis data stream in a single call (also referred to as a * PutRecords request). Use this operation to send data into the stream for data ingestion and * processing. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Each PutRecords request can support up to 500 records. Each record in the request can be as large as * 1 MiB, up to a limit of 5 MiB for the entire request, including partition keys. Each shard can support writes up * to 1,000 records per second, up to a maximum data write total of 1 MiB per second. *

*

* You must specify the name of the stream that captures, stores, and transports the data; and an array of request * Records, with each record in the array requiring a partition key and data blob. The record size * limit applies to the total size of the partition key and data blob. *

*

* The data blob can be any type of data; for example, a segment from a log file, geographic/location data, website * clickstream data, and so on. *

*

* The partition key is used by Kinesis Data Streams as input to a hash function that maps the partition key and * associated data to a specific shard. An MD5 hash function is used to map partition keys to 128-bit integer values * and to map associated data records to shards. As a result of this hashing mechanism, all data records with the * same partition key map to the same shard within the stream. For more information, see Adding Data to a Stream in the Amazon Kinesis Data Streams Developer Guide. *

*

* Each record in the Records array may include an optional parameter, ExplicitHashKey, * which overrides the partition key to shard mapping. This parameter allows a data producer to determine explicitly * the shard where the record is stored. For more information, see Adding Multiple Records with PutRecords in the Amazon Kinesis Data Streams Developer Guide. *

*

* The PutRecords response includes an array of response Records. Each record in the * response array directly correlates with a record in the request array using natural ordering, from the top to the * bottom of the request and response. The response Records array always includes the same number of * records as the request array. *

*

* The response Records array includes both successfully and unsuccessfully processed records. Kinesis * Data Streams attempts to process all records in each PutRecords request. A single record failure * does not stop the processing of subsequent records. As a result, PutRecords doesn't guarantee the ordering of * records. If you need to read records in the same order they are written to the stream, use PutRecord * instead of PutRecords, and write to the same shard. *

*

* A successfully processed record includes ShardId and SequenceNumber values. The * ShardId parameter identifies the shard in the stream where the record is stored. The * SequenceNumber parameter is an identifier assigned to the put record, unique to all records in the * stream. *

*

* An unsuccessfully processed record includes ErrorCode and ErrorMessage values. * ErrorCode reflects the type of error and can be one of the following values: * ProvisionedThroughputExceededException or InternalFailure. ErrorMessage * provides more detailed information about the ProvisionedThroughputExceededException exception * including the account ID, stream name, and shard ID of the record that was throttled. For more information about * partially successful responses, see Adding Multiple Records with PutRecords in the Amazon Kinesis Data Streams Developer Guide. *

* *

* After you write a record to a stream, you cannot modify that record or its order within the stream. *

*
*

* By default, data records are accessible for 24 hours from the time that they are added to a stream. You can use * IncreaseStreamRetentionPeriod or DecreaseStreamRetentionPeriod to modify this retention period. *

* * @param putRecordsRequest * A PutRecords request. * @return A Java Future containing the result of the PutRecords operation returned by the service. * @sample AmazonKinesisAsync.PutRecords * @see AWS API * Documentation */ java.util.concurrent.Future putRecordsAsync(PutRecordsRequest putRecordsRequest); /** *

* Writes multiple data records into a Kinesis data stream in a single call (also referred to as a * PutRecords request). Use this operation to send data into the stream for data ingestion and * processing. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Each PutRecords request can support up to 500 records. Each record in the request can be as large as * 1 MiB, up to a limit of 5 MiB for the entire request, including partition keys. Each shard can support writes up * to 1,000 records per second, up to a maximum data write total of 1 MiB per second. *

*

* You must specify the name of the stream that captures, stores, and transports the data; and an array of request * Records, with each record in the array requiring a partition key and data blob. The record size * limit applies to the total size of the partition key and data blob. *

*

* The data blob can be any type of data; for example, a segment from a log file, geographic/location data, website * clickstream data, and so on. *

*

* The partition key is used by Kinesis Data Streams as input to a hash function that maps the partition key and * associated data to a specific shard. An MD5 hash function is used to map partition keys to 128-bit integer values * and to map associated data records to shards. As a result of this hashing mechanism, all data records with the * same partition key map to the same shard within the stream. For more information, see Adding Data to a Stream in the Amazon Kinesis Data Streams Developer Guide. *

*

* Each record in the Records array may include an optional parameter, ExplicitHashKey, * which overrides the partition key to shard mapping. This parameter allows a data producer to determine explicitly * the shard where the record is stored. For more information, see Adding Multiple Records with PutRecords in the Amazon Kinesis Data Streams Developer Guide. *

*

* The PutRecords response includes an array of response Records. Each record in the * response array directly correlates with a record in the request array using natural ordering, from the top to the * bottom of the request and response. The response Records array always includes the same number of * records as the request array. *

*

* The response Records array includes both successfully and unsuccessfully processed records. Kinesis * Data Streams attempts to process all records in each PutRecords request. A single record failure * does not stop the processing of subsequent records. As a result, PutRecords doesn't guarantee the ordering of * records. If you need to read records in the same order they are written to the stream, use PutRecord * instead of PutRecords, and write to the same shard. *

*

* A successfully processed record includes ShardId and SequenceNumber values. The * ShardId parameter identifies the shard in the stream where the record is stored. The * SequenceNumber parameter is an identifier assigned to the put record, unique to all records in the * stream. *

*

* An unsuccessfully processed record includes ErrorCode and ErrorMessage values. * ErrorCode reflects the type of error and can be one of the following values: * ProvisionedThroughputExceededException or InternalFailure. ErrorMessage * provides more detailed information about the ProvisionedThroughputExceededException exception * including the account ID, stream name, and shard ID of the record that was throttled. For more information about * partially successful responses, see Adding Multiple Records with PutRecords in the Amazon Kinesis Data Streams Developer Guide. *

* *

* After you write a record to a stream, you cannot modify that record or its order within the stream. *

*
*

* By default, data records are accessible for 24 hours from the time that they are added to a stream. You can use * IncreaseStreamRetentionPeriod or DecreaseStreamRetentionPeriod to modify this retention period. *

* * @param putRecordsRequest * A PutRecords request. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the PutRecords operation returned by the service. * @sample AmazonKinesisAsyncHandler.PutRecords * @see AWS API * Documentation */ java.util.concurrent.Future putRecordsAsync(PutRecordsRequest putRecordsRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Attaches a resource-based policy to a data stream or registered consumer. If you are using an identity other than * the root user of the Amazon Web Services account that owns the resource, the calling identity must have the * PutResourcePolicy permissions on the specified Kinesis Data Streams resource and belong to the * owner's account in order to use this operation. If you don't have PutResourcePolicy permissions, * Amazon Kinesis Data Streams returns a 403 Access Denied error. If you receive a * ResourceNotFoundException, check to see if you passed a valid stream or consumer resource. *

*

* Request patterns can be one of the following: *

*
    *
  • *

    * Data stream pattern: arn:aws.*:kinesis:.*:\d{12}:.*stream/\S+ *

    *
  • *
  • *

    * Consumer pattern: * ^(arn):aws.*:kinesis:.*:\d{12}:.*stream\/[a-zA-Z0-9_.-]+\/consumer\/[a-zA-Z0-9_.-]+:[0-9]+ *

    *
  • *
*

* For more information, see Controlling Access to Amazon * Kinesis Data Streams Resources Using IAM. *

* * @param putResourcePolicyRequest * @return A Java Future containing the result of the PutResourcePolicy operation returned by the service. * @sample AmazonKinesisAsync.PutResourcePolicy * @see AWS API * Documentation */ java.util.concurrent.Future putResourcePolicyAsync(PutResourcePolicyRequest putResourcePolicyRequest); /** *

* Attaches a resource-based policy to a data stream or registered consumer. If you are using an identity other than * the root user of the Amazon Web Services account that owns the resource, the calling identity must have the * PutResourcePolicy permissions on the specified Kinesis Data Streams resource and belong to the * owner's account in order to use this operation. If you don't have PutResourcePolicy permissions, * Amazon Kinesis Data Streams returns a 403 Access Denied error. If you receive a * ResourceNotFoundException, check to see if you passed a valid stream or consumer resource. *

*

* Request patterns can be one of the following: *

*
    *
  • *

    * Data stream pattern: arn:aws.*:kinesis:.*:\d{12}:.*stream/\S+ *

    *
  • *
  • *

    * Consumer pattern: * ^(arn):aws.*:kinesis:.*:\d{12}:.*stream\/[a-zA-Z0-9_.-]+\/consumer\/[a-zA-Z0-9_.-]+:[0-9]+ *

    *
  • *
*

* For more information, see Controlling Access to Amazon * Kinesis Data Streams Resources Using IAM. *

* * @param putResourcePolicyRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the PutResourcePolicy operation returned by the service. * @sample AmazonKinesisAsyncHandler.PutResourcePolicy * @see AWS API * Documentation */ java.util.concurrent.Future putResourcePolicyAsync(PutResourcePolicyRequest putResourcePolicyRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Registers a consumer with a Kinesis data stream. When you use this operation, the consumer you register can then * call SubscribeToShard to receive data from the stream using enhanced fan-out, at a rate of up to 2 MiB per * second for every shard you subscribe to. This rate is unaffected by the total number of consumers that read from * the same stream. *

*

* You can register up to 20 consumers per stream. A given consumer can only be registered with one stream at a * time. *

*

* For an example of how to use this operations, see Enhanced Fan-Out Using the Kinesis Data Streams * API. *

*

* The use of this operation has a limit of five transactions per second per account. Also, only 5 consumers can be * created simultaneously. In other words, you cannot have more than 5 consumers in a CREATING status * at the same time. Registering a 6th consumer while there are 5 in a CREATING status results in a * LimitExceededException. *

* * @param registerStreamConsumerRequest * @return A Java Future containing the result of the RegisterStreamConsumer operation returned by the service. * @sample AmazonKinesisAsync.RegisterStreamConsumer * @see AWS * API Documentation */ java.util.concurrent.Future registerStreamConsumerAsync(RegisterStreamConsumerRequest registerStreamConsumerRequest); /** *

* Registers a consumer with a Kinesis data stream. When you use this operation, the consumer you register can then * call SubscribeToShard to receive data from the stream using enhanced fan-out, at a rate of up to 2 MiB per * second for every shard you subscribe to. This rate is unaffected by the total number of consumers that read from * the same stream. *

*

* You can register up to 20 consumers per stream. A given consumer can only be registered with one stream at a * time. *

*

* For an example of how to use this operations, see Enhanced Fan-Out Using the Kinesis Data Streams * API. *

*

* The use of this operation has a limit of five transactions per second per account. Also, only 5 consumers can be * created simultaneously. In other words, you cannot have more than 5 consumers in a CREATING status * at the same time. Registering a 6th consumer while there are 5 in a CREATING status results in a * LimitExceededException. *

* * @param registerStreamConsumerRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the RegisterStreamConsumer operation returned by the service. * @sample AmazonKinesisAsyncHandler.RegisterStreamConsumer * @see AWS * API Documentation */ java.util.concurrent.Future registerStreamConsumerAsync(RegisterStreamConsumerRequest registerStreamConsumerRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Removes tags from the specified Kinesis data stream. Removed tags are deleted and cannot be recovered after this * operation successfully completes. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If you specify a tag that does not exist, it is ignored. *

*

* RemoveTagsFromStream has a limit of five transactions per second per account. *

* * @param removeTagsFromStreamRequest * Represents the input for RemoveTagsFromStream. * @return A Java Future containing the result of the RemoveTagsFromStream operation returned by the service. * @sample AmazonKinesisAsync.RemoveTagsFromStream * @see AWS * API Documentation */ java.util.concurrent.Future removeTagsFromStreamAsync(RemoveTagsFromStreamRequest removeTagsFromStreamRequest); /** *

* Removes tags from the specified Kinesis data stream. Removed tags are deleted and cannot be recovered after this * operation successfully completes. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* If you specify a tag that does not exist, it is ignored. *

*

* RemoveTagsFromStream has a limit of five transactions per second per account. *

* * @param removeTagsFromStreamRequest * Represents the input for RemoveTagsFromStream. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the RemoveTagsFromStream operation returned by the service. * @sample AmazonKinesisAsyncHandler.RemoveTagsFromStream * @see AWS * API Documentation */ java.util.concurrent.Future removeTagsFromStreamAsync(RemoveTagsFromStreamRequest removeTagsFromStreamRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Splits a shard into two new shards in the Kinesis data stream, to increase the stream's capacity to ingest and * transport data. SplitShard is called when there is a need to increase the overall capacity of a * stream because of an expected increase in the volume of data records being ingested. This API is only supported * for the data streams with the provisioned capacity mode. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* You can also use SplitShard when a shard appears to be approaching its maximum utilization; for * example, the producers sending data into the specific shard are suddenly sending more than previously * anticipated. You can also call SplitShard to increase stream capacity, so that more Kinesis Data * Streams applications can simultaneously read data from the stream for real-time processing. *

*

* You must specify the shard to be split and the new hash key, which is the position in the shard where the shard * gets split in two. In many cases, the new hash key might be the average of the beginning and ending hash key, but * it can be any hash key value in the range being mapped into the shard. For more information, see Split a * Shard in the Amazon Kinesis Data Streams Developer Guide. *

*

* You can use DescribeStreamSummary and the ListShards APIs to determine the shard ID and hash key * values for the ShardToSplit and NewStartingHashKey parameters that are specified in the * SplitShard request. *

*

* SplitShard is an asynchronous operation. Upon receiving a SplitShard request, Kinesis * Data Streams immediately returns a response and sets the stream status to UPDATING. After the * operation is completed, Kinesis Data Streams sets the stream status to ACTIVE. Read and write * operations continue to work while the stream is in the UPDATING state. *

*

* You can use DescribeStreamSummary to check the status of the stream, which is returned in * StreamStatus. If the stream is in the ACTIVE state, you can call * SplitShard. *

*

* If the specified stream does not exist, DescribeStreamSummary returns a * ResourceNotFoundException. If you try to create more shards than are authorized for your account, * you receive a LimitExceededException. *

*

* For the default shard limit for an Amazon Web Services account, see Kinesis Data Streams * Limits in the Amazon Kinesis Data Streams Developer Guide. To increase this limit, contact Amazon Web Services * Support. *

*

* If you try to operate on too many streams simultaneously using CreateStream, DeleteStream, * MergeShards, and/or SplitShard, you receive a LimitExceededException. *

*

* SplitShard has a limit of five transactions per second per account. *

* * @param splitShardRequest * Represents the input for SplitShard. * @return A Java Future containing the result of the SplitShard operation returned by the service. * @sample AmazonKinesisAsync.SplitShard * @see AWS API * Documentation */ java.util.concurrent.Future splitShardAsync(SplitShardRequest splitShardRequest); /** *

* Splits a shard into two new shards in the Kinesis data stream, to increase the stream's capacity to ingest and * transport data. SplitShard is called when there is a need to increase the overall capacity of a * stream because of an expected increase in the volume of data records being ingested. This API is only supported * for the data streams with the provisioned capacity mode. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* You can also use SplitShard when a shard appears to be approaching its maximum utilization; for * example, the producers sending data into the specific shard are suddenly sending more than previously * anticipated. You can also call SplitShard to increase stream capacity, so that more Kinesis Data * Streams applications can simultaneously read data from the stream for real-time processing. *

*

* You must specify the shard to be split and the new hash key, which is the position in the shard where the shard * gets split in two. In many cases, the new hash key might be the average of the beginning and ending hash key, but * it can be any hash key value in the range being mapped into the shard. For more information, see Split a * Shard in the Amazon Kinesis Data Streams Developer Guide. *

*

* You can use DescribeStreamSummary and the ListShards APIs to determine the shard ID and hash key * values for the ShardToSplit and NewStartingHashKey parameters that are specified in the * SplitShard request. *

*

* SplitShard is an asynchronous operation. Upon receiving a SplitShard request, Kinesis * Data Streams immediately returns a response and sets the stream status to UPDATING. After the * operation is completed, Kinesis Data Streams sets the stream status to ACTIVE. Read and write * operations continue to work while the stream is in the UPDATING state. *

*

* You can use DescribeStreamSummary to check the status of the stream, which is returned in * StreamStatus. If the stream is in the ACTIVE state, you can call * SplitShard. *

*

* If the specified stream does not exist, DescribeStreamSummary returns a * ResourceNotFoundException. If you try to create more shards than are authorized for your account, * you receive a LimitExceededException. *

*

* For the default shard limit for an Amazon Web Services account, see Kinesis Data Streams * Limits in the Amazon Kinesis Data Streams Developer Guide. To increase this limit, contact Amazon Web Services * Support. *

*

* If you try to operate on too many streams simultaneously using CreateStream, DeleteStream, * MergeShards, and/or SplitShard, you receive a LimitExceededException. *

*

* SplitShard has a limit of five transactions per second per account. *

* * @param splitShardRequest * Represents the input for SplitShard. * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the SplitShard operation returned by the service. * @sample AmazonKinesisAsyncHandler.SplitShard * @see AWS API * Documentation */ java.util.concurrent.Future splitShardAsync(SplitShardRequest splitShardRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** * Simplified method form for invoking the SplitShard operation. * * @see #splitShardAsync(SplitShardRequest) */ java.util.concurrent.Future splitShardAsync(String streamName, String shardToSplit, String newStartingHashKey); /** * Simplified method form for invoking the SplitShard operation with an AsyncHandler. * * @see #splitShardAsync(SplitShardRequest, com.amazonaws.handlers.AsyncHandler) */ java.util.concurrent.Future splitShardAsync(String streamName, String shardToSplit, String newStartingHashKey, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Enables or updates server-side encryption using an Amazon Web Services KMS key for a specified stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Starting encryption is an asynchronous operation. Upon receiving the request, Kinesis Data Streams returns * immediately and sets the status of the stream to UPDATING. After the update is complete, Kinesis * Data Streams sets the status of the stream back to ACTIVE. Updating or applying encryption normally * takes a few seconds to complete, but it can take minutes. You can continue to read and write data to your stream * while its status is UPDATING. Once the status of the stream is ACTIVE, encryption * begins for records written to the stream. *

*

* API Limits: You can successfully apply a new Amazon Web Services KMS key for server-side encryption 25 times in a * rolling 24-hour period. *

*

* Note: It can take up to 5 seconds after the stream is in an ACTIVE status before all records written * to the stream are encrypted. After you enable encryption, you can verify that encryption is applied by inspecting * the API response from PutRecord or PutRecords. *

* * @param startStreamEncryptionRequest * @return A Java Future containing the result of the StartStreamEncryption operation returned by the service. * @sample AmazonKinesisAsync.StartStreamEncryption * @see AWS * API Documentation */ java.util.concurrent.Future startStreamEncryptionAsync(StartStreamEncryptionRequest startStreamEncryptionRequest); /** *

* Enables or updates server-side encryption using an Amazon Web Services KMS key for a specified stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Starting encryption is an asynchronous operation. Upon receiving the request, Kinesis Data Streams returns * immediately and sets the status of the stream to UPDATING. After the update is complete, Kinesis * Data Streams sets the status of the stream back to ACTIVE. Updating or applying encryption normally * takes a few seconds to complete, but it can take minutes. You can continue to read and write data to your stream * while its status is UPDATING. Once the status of the stream is ACTIVE, encryption * begins for records written to the stream. *

*

* API Limits: You can successfully apply a new Amazon Web Services KMS key for server-side encryption 25 times in a * rolling 24-hour period. *

*

* Note: It can take up to 5 seconds after the stream is in an ACTIVE status before all records written * to the stream are encrypted. After you enable encryption, you can verify that encryption is applied by inspecting * the API response from PutRecord or PutRecords. *

* * @param startStreamEncryptionRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the StartStreamEncryption operation returned by the service. * @sample AmazonKinesisAsyncHandler.StartStreamEncryption * @see AWS * API Documentation */ java.util.concurrent.Future startStreamEncryptionAsync(StartStreamEncryptionRequest startStreamEncryptionRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Disables server-side encryption for a specified stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Stopping encryption is an asynchronous operation. Upon receiving the request, Kinesis Data Streams returns * immediately and sets the status of the stream to UPDATING. After the update is complete, Kinesis * Data Streams sets the status of the stream back to ACTIVE. Stopping encryption normally takes a few * seconds to complete, but it can take minutes. You can continue to read and write data to your stream while its * status is UPDATING. Once the status of the stream is ACTIVE, records written to the * stream are no longer encrypted by Kinesis Data Streams. *

*

* API Limits: You can successfully disable server-side encryption 25 times in a rolling 24-hour period. *

*

* Note: It can take up to 5 seconds after the stream is in an ACTIVE status before all records written * to the stream are no longer subject to encryption. After you disabled encryption, you can verify that encryption * is not applied by inspecting the API response from PutRecord or PutRecords. *

* * @param stopStreamEncryptionRequest * @return A Java Future containing the result of the StopStreamEncryption operation returned by the service. * @sample AmazonKinesisAsync.StopStreamEncryption * @see AWS * API Documentation */ java.util.concurrent.Future stopStreamEncryptionAsync(StopStreamEncryptionRequest stopStreamEncryptionRequest); /** *

* Disables server-side encryption for a specified stream. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Stopping encryption is an asynchronous operation. Upon receiving the request, Kinesis Data Streams returns * immediately and sets the status of the stream to UPDATING. After the update is complete, Kinesis * Data Streams sets the status of the stream back to ACTIVE. Stopping encryption normally takes a few * seconds to complete, but it can take minutes. You can continue to read and write data to your stream while its * status is UPDATING. Once the status of the stream is ACTIVE, records written to the * stream are no longer encrypted by Kinesis Data Streams. *

*

* API Limits: You can successfully disable server-side encryption 25 times in a rolling 24-hour period. *

*

* Note: It can take up to 5 seconds after the stream is in an ACTIVE status before all records written * to the stream are no longer subject to encryption. After you disabled encryption, you can verify that encryption * is not applied by inspecting the API response from PutRecord or PutRecords. *

* * @param stopStreamEncryptionRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the StopStreamEncryption operation returned by the service. * @sample AmazonKinesisAsyncHandler.StopStreamEncryption * @see AWS * API Documentation */ java.util.concurrent.Future stopStreamEncryptionAsync(StopStreamEncryptionRequest stopStreamEncryptionRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Updates the shard count of the specified stream to the specified number of shards. This API is only supported for * the data streams with the provisioned capacity mode. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Updating the shard count is an asynchronous operation. Upon receiving the request, Kinesis Data Streams returns * immediately and sets the status of the stream to UPDATING. After the update is complete, Kinesis * Data Streams sets the status of the stream back to ACTIVE. Depending on the size of the stream, the * scaling action could take a few minutes to complete. You can continue to read and write data to your stream while * its status is UPDATING. *

*

* To update the shard count, Kinesis Data Streams performs splits or merges on individual shards. This can cause * short-lived shards to be created, in addition to the final shards. These short-lived shards count towards your * total shard limit for your account in the Region. *

*

* When using this operation, we recommend that you specify a target shard count that is a multiple of 25% (25%, * 50%, 75%, 100%). You can specify any target value within your shard limit. However, if you specify a target that * isn't a multiple of 25%, the scaling action might take longer to complete. *

*

* This operation has the following default limits. By default, you cannot do the following: *

*
    *
  • *

    * Scale more than ten times per rolling 24-hour period per stream *

    *
  • *
  • *

    * Scale up to more than double your current shard count for a stream *

    *
  • *
  • *

    * Scale down below half your current shard count for a stream *

    *
  • *
  • *

    * Scale up to more than 10000 shards in a stream *

    *
  • *
  • *

    * Scale a stream with more than 10000 shards down unless the result is less than 10000 shards *

    *
  • *
  • *

    * Scale up to more than the shard limit for your account *

    *
  • *
  • *

    * Make over 10 TPS. TPS over 10 will trigger the LimitExceededException *

    *
  • *
*

* For the default limits for an Amazon Web Services account, see Streams Limits in the * Amazon Kinesis Data Streams Developer Guide. To request an increase in the call rate limit, the shard * limit for this API, or your overall shard limit, use the limits form. *

* * @param updateShardCountRequest * @return A Java Future containing the result of the UpdateShardCount operation returned by the service. * @sample AmazonKinesisAsync.UpdateShardCount * @see AWS API * Documentation */ java.util.concurrent.Future updateShardCountAsync(UpdateShardCountRequest updateShardCountRequest); /** *

* Updates the shard count of the specified stream to the specified number of shards. This API is only supported for * the data streams with the provisioned capacity mode. *

* *

* When invoking this API, you must use either the StreamARN or the StreamName parameter, * or both. It is recommended that you use the StreamARN input parameter when you invoke this API. *

*
*

* Updating the shard count is an asynchronous operation. Upon receiving the request, Kinesis Data Streams returns * immediately and sets the status of the stream to UPDATING. After the update is complete, Kinesis * Data Streams sets the status of the stream back to ACTIVE. Depending on the size of the stream, the * scaling action could take a few minutes to complete. You can continue to read and write data to your stream while * its status is UPDATING. *

*

* To update the shard count, Kinesis Data Streams performs splits or merges on individual shards. This can cause * short-lived shards to be created, in addition to the final shards. These short-lived shards count towards your * total shard limit for your account in the Region. *

*

* When using this operation, we recommend that you specify a target shard count that is a multiple of 25% (25%, * 50%, 75%, 100%). You can specify any target value within your shard limit. However, if you specify a target that * isn't a multiple of 25%, the scaling action might take longer to complete. *

*

* This operation has the following default limits. By default, you cannot do the following: *

*
    *
  • *

    * Scale more than ten times per rolling 24-hour period per stream *

    *
  • *
  • *

    * Scale up to more than double your current shard count for a stream *

    *
  • *
  • *

    * Scale down below half your current shard count for a stream *

    *
  • *
  • *

    * Scale up to more than 10000 shards in a stream *

    *
  • *
  • *

    * Scale a stream with more than 10000 shards down unless the result is less than 10000 shards *

    *
  • *
  • *

    * Scale up to more than the shard limit for your account *

    *
  • *
  • *

    * Make over 10 TPS. TPS over 10 will trigger the LimitExceededException *

    *
  • *
*

* For the default limits for an Amazon Web Services account, see Streams Limits in the * Amazon Kinesis Data Streams Developer Guide. To request an increase in the call rate limit, the shard * limit for this API, or your overall shard limit, use the limits form. *

* * @param updateShardCountRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the UpdateShardCount operation returned by the service. * @sample AmazonKinesisAsyncHandler.UpdateShardCount * @see AWS API * Documentation */ java.util.concurrent.Future updateShardCountAsync(UpdateShardCountRequest updateShardCountRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); /** *

* Updates the capacity mode of the data stream. Currently, in Kinesis Data Streams, you can choose between an * on-demand capacity mode and a provisioned capacity mode for your data stream. *

* * @param updateStreamModeRequest * @return A Java Future containing the result of the UpdateStreamMode operation returned by the service. * @sample AmazonKinesisAsync.UpdateStreamMode * @see AWS API * Documentation */ java.util.concurrent.Future updateStreamModeAsync(UpdateStreamModeRequest updateStreamModeRequest); /** *

* Updates the capacity mode of the data stream. Currently, in Kinesis Data Streams, you can choose between an * on-demand capacity mode and a provisioned capacity mode for your data stream. *

* * @param updateStreamModeRequest * @param asyncHandler * Asynchronous callback handler for events in the lifecycle of the request. Users can provide an * implementation of the callback methods in this interface to receive notification of successful or * unsuccessful completion of the operation. * @return A Java Future containing the result of the UpdateStreamMode operation returned by the service. * @sample AmazonKinesisAsyncHandler.UpdateStreamMode * @see AWS API * Documentation */ java.util.concurrent.Future updateStreamModeAsync(UpdateStreamModeRequest updateStreamModeRequest, com.amazonaws.handlers.AsyncHandler asyncHandler); }




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