# frozen_string_literal: true # WARNING ABOUT GENERATED CODE # # This file is generated. See the contributing guide for more information: # https://github.com/aws/aws-sdk-ruby/blob/version-3/CONTRIBUTING.md # # WARNING ABOUT GENERATED CODE require 'seahorse/client/plugins/content_length.rb' require 'aws-sdk-core/plugins/credentials_configuration.rb' require 'aws-sdk-core/plugins/logging.rb' require 'aws-sdk-core/plugins/param_converter.rb' require 'aws-sdk-core/plugins/param_validator.rb' require 'aws-sdk-core/plugins/user_agent.rb' require 'aws-sdk-core/plugins/helpful_socket_errors.rb' require 'aws-sdk-core/plugins/retry_errors.rb' require 'aws-sdk-core/plugins/global_configuration.rb' require 'aws-sdk-core/plugins/regional_endpoint.rb' require 'aws-sdk-core/plugins/endpoint_discovery.rb' require 'aws-sdk-core/plugins/endpoint_pattern.rb' require 'aws-sdk-core/plugins/response_paging.rb' require 'aws-sdk-core/plugins/stub_responses.rb' require 'aws-sdk-core/plugins/idempotency_token.rb' require 'aws-sdk-core/plugins/invocation_id.rb' require 'aws-sdk-core/plugins/jsonvalue_converter.rb' require 'aws-sdk-core/plugins/client_metrics_plugin.rb' require 'aws-sdk-core/plugins/client_metrics_send_plugin.rb' require 'aws-sdk-core/plugins/transfer_encoding.rb' require 'aws-sdk-core/plugins/http_checksum.rb' require 'aws-sdk-core/plugins/checksum_algorithm.rb' require 'aws-sdk-core/plugins/request_compression.rb' require 'aws-sdk-core/plugins/defaults_mode.rb' require 'aws-sdk-core/plugins/recursion_detection.rb' require 'aws-sdk-core/plugins/sign.rb' require 'aws-sdk-core/plugins/protocols/json_rpc.rb' Aws::Plugins::GlobalConfiguration.add_identifier(:iotfleetwise) module Aws::IoTFleetWise # An API client for IoTFleetWise. To construct a client, you need to configure a `:region` and `:credentials`. # # client = Aws::IoTFleetWise::Client.new( # region: region_name, # credentials: credentials, # # ... # ) # # For details on configuring region and credentials see # the [developer guide](/sdk-for-ruby/v3/developer-guide/setup-config.html). # # See {#initialize} for a full list of supported configuration options. class Client < Seahorse::Client::Base include Aws::ClientStubs @identifier = :iotfleetwise set_api(ClientApi::API) add_plugin(Seahorse::Client::Plugins::ContentLength) add_plugin(Aws::Plugins::CredentialsConfiguration) add_plugin(Aws::Plugins::Logging) add_plugin(Aws::Plugins::ParamConverter) add_plugin(Aws::Plugins::ParamValidator) add_plugin(Aws::Plugins::UserAgent) add_plugin(Aws::Plugins::HelpfulSocketErrors) add_plugin(Aws::Plugins::RetryErrors) add_plugin(Aws::Plugins::GlobalConfiguration) add_plugin(Aws::Plugins::RegionalEndpoint) add_plugin(Aws::Plugins::EndpointDiscovery) add_plugin(Aws::Plugins::EndpointPattern) add_plugin(Aws::Plugins::ResponsePaging) add_plugin(Aws::Plugins::StubResponses) add_plugin(Aws::Plugins::IdempotencyToken) add_plugin(Aws::Plugins::InvocationId) add_plugin(Aws::Plugins::JsonvalueConverter) add_plugin(Aws::Plugins::ClientMetricsPlugin) add_plugin(Aws::Plugins::ClientMetricsSendPlugin) add_plugin(Aws::Plugins::TransferEncoding) add_plugin(Aws::Plugins::HttpChecksum) add_plugin(Aws::Plugins::ChecksumAlgorithm) add_plugin(Aws::Plugins::RequestCompression) add_plugin(Aws::Plugins::DefaultsMode) add_plugin(Aws::Plugins::RecursionDetection) add_plugin(Aws::Plugins::Sign) add_plugin(Aws::Plugins::Protocols::JsonRpc) add_plugin(Aws::IoTFleetWise::Plugins::Endpoints) # @overload initialize(options) # @param [Hash] options # # @option options [Array] :plugins ([]]) # A list of plugins to apply to the client. Each plugin is either a # class name or an instance of a plugin class. # # @option options [required, Aws::CredentialProvider] :credentials # Your AWS credentials. This can be an instance of any one of the # following classes: # # * `Aws::Credentials` - Used for configuring static, non-refreshing # credentials. # # * `Aws::SharedCredentials` - Used for loading static credentials from a # shared file, such as `~/.aws/config`. # # * `Aws::AssumeRoleCredentials` - Used when you need to assume a role. # # * `Aws::AssumeRoleWebIdentityCredentials` - Used when you need to # assume a role after providing credentials via the web. # # * `Aws::SSOCredentials` - Used for loading credentials from AWS SSO using an # access token generated from `aws login`. # # * `Aws::ProcessCredentials` - Used for loading credentials from a # process that outputs to stdout. # # * `Aws::InstanceProfileCredentials` - Used for loading credentials # from an EC2 IMDS on an EC2 instance. # # * `Aws::ECSCredentials` - Used for loading credentials from # instances running in ECS. # # * `Aws::CognitoIdentityCredentials` - Used for loading credentials # from the Cognito Identity service. # # When `:credentials` are not configured directly, the following # locations will be searched for credentials: # # * `Aws.config[:credentials]` # * The `:access_key_id`, `:secret_access_key`, and `:session_token` options. # * ENV['AWS_ACCESS_KEY_ID'], ENV['AWS_SECRET_ACCESS_KEY'] # * `~/.aws/credentials` # * `~/.aws/config` # * EC2/ECS IMDS instance profile - When used by default, the timeouts # are very aggressive. Construct and pass an instance of # `Aws::InstanceProfileCredentails` or `Aws::ECSCredentials` to # enable retries and extended timeouts. Instance profile credential # fetching can be disabled by setting ENV['AWS_EC2_METADATA_DISABLED'] # to true. # # @option options [required, String] :region # The AWS region to connect to. The configured `:region` is # used to determine the service `:endpoint`. When not passed, # a default `:region` is searched for in the following locations: # # * `Aws.config[:region]` # * `ENV['AWS_REGION']` # * `ENV['AMAZON_REGION']` # * `ENV['AWS_DEFAULT_REGION']` # * `~/.aws/credentials` # * `~/.aws/config` # # @option options [String] :access_key_id # # @option options [Boolean] :active_endpoint_cache (false) # When set to `true`, a thread polling for endpoints will be running in # the background every 60 secs (default). Defaults to `false`. # # @option options [Boolean] :adaptive_retry_wait_to_fill (true) # Used only in `adaptive` retry mode. When true, the request will sleep # until there is sufficent client side capacity to retry the request. # When false, the request will raise a `RetryCapacityNotAvailableError` and will # not retry instead of sleeping. # # @option options [Boolean] :client_side_monitoring (false) # When `true`, client-side metrics will be collected for all API requests from # this client. # # @option options [String] :client_side_monitoring_client_id ("") # Allows you to provide an identifier for this client which will be attached to # all generated client side metrics. Defaults to an empty string. # # @option options [String] :client_side_monitoring_host ("127.0.0.1") # Allows you to specify the DNS hostname or IPv4 or IPv6 address that the client # side monitoring agent is running on, where client metrics will be published via UDP. # # @option options [Integer] :client_side_monitoring_port (31000) # Required for publishing client metrics. The port that the client side monitoring # agent is running on, where client metrics will be published via UDP. # # @option options [Aws::ClientSideMonitoring::Publisher] :client_side_monitoring_publisher (Aws::ClientSideMonitoring::Publisher) # Allows you to provide a custom client-side monitoring publisher class. By default, # will use the Client Side Monitoring Agent Publisher. # # @option options [Boolean] :convert_params (true) # When `true`, an attempt is made to coerce request parameters into # the required types. # # @option options [Boolean] :correct_clock_skew (true) # Used only in `standard` and adaptive retry modes. Specifies whether to apply # a clock skew correction and retry requests with skewed client clocks. # # @option options [String] :defaults_mode ("legacy") # See {Aws::DefaultsModeConfiguration} for a list of the # accepted modes and the configuration defaults that are included. # # @option options [Boolean] :disable_host_prefix_injection (false) # Set to true to disable SDK automatically adding host prefix # to default service endpoint when available. # # @option options [Boolean] :disable_request_compression (false) # When set to 'true' the request body will not be compressed # for supported operations. # # @option options [String, URI::HTTPS, URI::HTTP] :endpoint # Normally you should not configure the `:endpoint` option # directly. This is normally constructed from the `:region` # option. Configuring `:endpoint` is normally reserved for # connecting to test or custom endpoints. The endpoint should # be a URI formatted like: # # 'http://example.com' # 'https://example.com' # 'http://example.com:123' # # @option options [Integer] :endpoint_cache_max_entries (1000) # Used for the maximum size limit of the LRU cache storing endpoints data # for endpoint discovery enabled operations. Defaults to 1000. # # @option options [Integer] :endpoint_cache_max_threads (10) # Used for the maximum threads in use for polling endpoints to be cached, defaults to 10. # # @option options [Integer] :endpoint_cache_poll_interval (60) # When :endpoint_discovery and :active_endpoint_cache is enabled, # Use this option to config the time interval in seconds for making # requests fetching endpoints information. Defaults to 60 sec. # # @option options [Boolean] :endpoint_discovery (false) # When set to `true`, endpoint discovery will be enabled for operations when available. # # @option options [Boolean] :ignore_configured_endpoint_urls # Setting to true disables use of endpoint URLs provided via environment # variables and the shared configuration file. # # @option options [Aws::Log::Formatter] :log_formatter (Aws::Log::Formatter.default) # The log formatter. # # @option options [Symbol] :log_level (:info) # The log level to send messages to the `:logger` at. # # @option options [Logger] :logger # The Logger instance to send log messages to. If this option # is not set, logging will be disabled. # # @option options [Integer] :max_attempts (3) # An integer representing the maximum number attempts that will be made for # a single request, including the initial attempt. For example, # setting this value to 5 will result in a request being retried up to # 4 times. Used in `standard` and `adaptive` retry modes. # # @option options [String] :profile ("default") # Used when loading credentials from the shared credentials file # at HOME/.aws/credentials. When not specified, 'default' is used. # # @option options [Integer] :request_min_compression_size_bytes (10240) # The minimum size in bytes that triggers compression for request # bodies. The value must be non-negative integer value between 0 # and 10485780 bytes inclusive. # # @option options [Proc] :retry_backoff # A proc or lambda used for backoff. Defaults to 2**retries * retry_base_delay. # This option is only used in the `legacy` retry mode. # # @option options [Float] :retry_base_delay (0.3) # The base delay in seconds used by the default backoff function. This option # is only used in the `legacy` retry mode. # # @option options [Symbol] :retry_jitter (:none) # A delay randomiser function used by the default backoff function. # Some predefined functions can be referenced by name - :none, :equal, :full, # otherwise a Proc that takes and returns a number. This option is only used # in the `legacy` retry mode. # # @see https://www.awsarchitectureblog.com/2015/03/backoff.html # # @option options [Integer] :retry_limit (3) # The maximum number of times to retry failed requests. Only # ~ 500 level server errors and certain ~ 400 level client errors # are retried. Generally, these are throttling errors, data # checksum errors, networking errors, timeout errors, auth errors, # endpoint discovery, and errors from expired credentials. # This option is only used in the `legacy` retry mode. # # @option options [Integer] :retry_max_delay (0) # The maximum number of seconds to delay between retries (0 for no limit) # used by the default backoff function. This option is only used in the # `legacy` retry mode. # # @option options [String] :retry_mode ("legacy") # Specifies which retry algorithm to use. Values are: # # * `legacy` - The pre-existing retry behavior. This is default value if # no retry mode is provided. # # * `standard` - A standardized set of retry rules across the AWS SDKs. # This includes support for retry quotas, which limit the number of # unsuccessful retries a client can make. # # * `adaptive` - An experimental retry mode that includes all the # functionality of `standard` mode along with automatic client side # throttling. This is a provisional mode that may change behavior # in the future. # # @option options [String] :sdk_ua_app_id # A unique and opaque application ID that is appended to the # User-Agent header as app/sdk_ua_app_id. It should have a # maximum length of 50. This variable is sourced from environment # variable AWS_SDK_UA_APP_ID or the shared config profile attribute sdk_ua_app_id. # # @option options [String] :secret_access_key # # @option options [String] :session_token # # @option options [Boolean] :simple_json (false) # Disables request parameter conversion, validation, and formatting. # Also disable response data type conversions. This option is useful # when you want to ensure the highest level of performance by # avoiding overhead of walking request parameters and response data # structures. # # When `:simple_json` is enabled, the request parameters hash must # be formatted exactly as the DynamoDB API expects. # # @option options [Boolean] :stub_responses (false) # Causes the client to return stubbed responses. By default # fake responses are generated and returned. You can specify # the response data to return or errors to raise by calling # {ClientStubs#stub_responses}. See {ClientStubs} for more information. # # ** Please note ** When response stubbing is enabled, no HTTP # requests are made, and retries are disabled. # # @option options [Aws::TokenProvider] :token_provider # A Bearer Token Provider. This can be an instance of any one of the # following classes: # # * `Aws::StaticTokenProvider` - Used for configuring static, non-refreshing # tokens. # # * `Aws::SSOTokenProvider` - Used for loading tokens from AWS SSO using an # access token generated from `aws login`. # # When `:token_provider` is not configured directly, the `Aws::TokenProviderChain` # will be used to search for tokens configured for your profile in shared configuration files. # # @option options [Boolean] :use_dualstack_endpoint # When set to `true`, dualstack enabled endpoints (with `.aws` TLD) # will be used if available. # # @option options [Boolean] :use_fips_endpoint # When set to `true`, fips compatible endpoints will be used if available. # When a `fips` region is used, the region is normalized and this config # is set to `true`. # # @option options [Boolean] :validate_params (true) # When `true`, request parameters are validated before # sending the request. # # @option options [Aws::IoTFleetWise::EndpointProvider] :endpoint_provider # The endpoint provider used to resolve endpoints. Any object that responds to `#resolve_endpoint(parameters)` where `parameters` is a Struct similar to `Aws::IoTFleetWise::EndpointParameters` # # @option options [Float] :http_continue_timeout (1) # The number of seconds to wait for a 100-continue response before sending the # request body. This option has no effect unless the request has "Expect" # header set to "100-continue". Defaults to `nil` which disables this # behaviour. This value can safely be set per request on the session. # # @option options [Float] :http_idle_timeout (5) # The number of seconds a connection is allowed to sit idle before it # is considered stale. Stale connections are closed and removed from the # pool before making a request. # # @option options [Float] :http_open_timeout (15) # The default number of seconds to wait for response data. # This value can safely be set per-request on the session. # # @option options [URI::HTTP,String] :http_proxy # A proxy to send requests through. Formatted like 'http://proxy.com:123'. # # @option options [Float] :http_read_timeout (60) # The default number of seconds to wait for response data. # This value can safely be set per-request on the session. # # @option options [Boolean] :http_wire_trace (false) # When `true`, HTTP debug output will be sent to the `:logger`. # # @option options [Proc] :on_chunk_received # When a Proc object is provided, it will be used as callback when each chunk # of the response body is received. It provides three arguments: the chunk, # the number of bytes received, and the total number of # bytes in the response (or nil if the server did not send a `content-length`). # # @option options [Proc] :on_chunk_sent # When a Proc object is provided, it will be used as callback when each chunk # of the request body is sent. It provides three arguments: the chunk, # the number of bytes read from the body, and the total number of # bytes in the body. # # @option options [Boolean] :raise_response_errors (true) # When `true`, response errors are raised. # # @option options [String] :ssl_ca_bundle # Full path to the SSL certificate authority bundle file that should be used when # verifying peer certificates. If you do not pass `:ssl_ca_bundle` or # `:ssl_ca_directory` the the system default will be used if available. # # @option options [String] :ssl_ca_directory # Full path of the directory that contains the unbundled SSL certificate # authority files for verifying peer certificates. If you do # not pass `:ssl_ca_bundle` or `:ssl_ca_directory` the the system # default will be used if available. # # @option options [String] :ssl_ca_store # Sets the X509::Store to verify peer certificate. # # @option options [Float] :ssl_timeout # Sets the SSL timeout in seconds # # @option options [Boolean] :ssl_verify_peer (true) # When `true`, SSL peer certificates are verified when establishing a connection. # def initialize(*args) super end # @!group API Operations # Adds, or associates, a vehicle with a fleet. # # @option params [required, String] :vehicle_name # The unique ID of the vehicle to associate with the fleet. # # @option params [required, String] :fleet_id # The ID of a fleet. # # @return [Struct] Returns an empty {Seahorse::Client::Response response}. # # @example Request syntax with placeholder values # # resp = client.associate_vehicle_fleet({ # vehicle_name: "vehicleName", # required # fleet_id: "fleetId", # required # }) # # @overload associate_vehicle_fleet(params = {}) # @param [Hash] params ({}) def associate_vehicle_fleet(params = {}, options = {}) req = build_request(:associate_vehicle_fleet, params) req.send_request(options) end # Creates a group, or batch, of vehicles. # # You must specify a decoder manifest and a vehicle model (model # manifest) for each vehicle. # # # # For more information, see [Create multiple vehicles (AWS CLI)][1] in # the *Amazon Web Services IoT FleetWise Developer Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/create-vehicles-cli.html # # @option params [required, Array] :vehicles # A list of information about each vehicle to create. For more # information, see the API data type. # # @return [Types::BatchCreateVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::BatchCreateVehicleResponse#vehicles #vehicles} => Array<Types::CreateVehicleResponseItem> # * {Types::BatchCreateVehicleResponse#errors #errors} => Array<Types::CreateVehicleError> # # @example Request syntax with placeholder values # # resp = client.batch_create_vehicle({ # vehicles: [ # required # { # vehicle_name: "vehicleName", # required # model_manifest_arn: "arn", # required # decoder_manifest_arn: "arn", # required # attributes: { # "attributeName" => "attributeValue", # }, # association_behavior: "CreateIotThing", # accepts CreateIotThing, ValidateIotThingExists # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }, # ], # }) # # @example Response structure # # resp.vehicles #=> Array # resp.vehicles[0].vehicle_name #=> String # resp.vehicles[0].arn #=> String # resp.vehicles[0].thing_arn #=> String # resp.errors #=> Array # resp.errors[0].vehicle_name #=> String # resp.errors[0].code #=> String # resp.errors[0].message #=> String # # @overload batch_create_vehicle(params = {}) # @param [Hash] params ({}) def batch_create_vehicle(params = {}, options = {}) req = build_request(:batch_create_vehicle, params) req.send_request(options) end # Updates a group, or batch, of vehicles. # # You must specify a decoder manifest and a vehicle model (model # manifest) for each vehicle. # # # # For more information, see [Update multiple vehicles (AWS CLI)][1] in # the *Amazon Web Services IoT FleetWise Developer Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/update-vehicles-cli.html # # @option params [required, Array] :vehicles # A list of information about the vehicles to update. For more # information, see the API data type. # # @return [Types::BatchUpdateVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::BatchUpdateVehicleResponse#vehicles #vehicles} => Array<Types::UpdateVehicleResponseItem> # * {Types::BatchUpdateVehicleResponse#errors #errors} => Array<Types::UpdateVehicleError> # # @example Request syntax with placeholder values # # resp = client.batch_update_vehicle({ # vehicles: [ # required # { # vehicle_name: "vehicleName", # required # model_manifest_arn: "arn", # decoder_manifest_arn: "arn", # attributes: { # "attributeName" => "attributeValue", # }, # attribute_update_mode: "Overwrite", # accepts Overwrite, Merge # }, # ], # }) # # @example Response structure # # resp.vehicles #=> Array # resp.vehicles[0].vehicle_name #=> String # resp.vehicles[0].arn #=> String # resp.errors #=> Array # resp.errors[0].vehicle_name #=> String # resp.errors[0].code #=> Integer # resp.errors[0].message #=> String # # @overload batch_update_vehicle(params = {}) # @param [Hash] params ({}) def batch_update_vehicle(params = {}, options = {}) req = build_request(:batch_update_vehicle, params) req.send_request(options) end # Creates an orchestration of data collection rules. The Amazon Web # Services IoT FleetWise Edge Agent software running in vehicles uses # campaigns to decide how to collect and transfer data to the cloud. You # create campaigns in the cloud. After you or your team approve # campaigns, Amazon Web Services IoT FleetWise automatically deploys # them to vehicles. # # For more information, see [Collect and transfer data with # campaigns][1] in the *Amazon Web Services IoT FleetWise Developer # Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/campaigns.html # # @option params [required, String] :name # The name of the campaign to create. # # @option params [String] :description # An optional description of the campaign to help identify its purpose. # # @option params [required, String] :signal_catalog_arn # The Amazon Resource Name (ARN) of the signal catalog to associate with # the campaign. # # @option params [required, String] :target_arn # The ARN of the vehicle or fleet to deploy a campaign to. # # @option params [Time,DateTime,Date,Integer,String] :start_time # (Optional) The time, in milliseconds, to deliver a campaign after it # was approved. If it's not specified, `0` is used. # # Default: `0` # # @option params [Time,DateTime,Date,Integer,String] :expiry_time # (Optional) The time the campaign expires, in seconds since epoch # (January 1, 1970 at midnight UTC time). Vehicle data isn't collected # after the campaign expires. # # Default: 253402214400 (December 31, 9999, 00:00:00 UTC) # # @option params [Integer] :post_trigger_collection_duration # (Optional) How long (in milliseconds) to collect raw data after a # triggering event initiates the collection. If it's not specified, `0` # is used. # # Default: `0` # # @option params [String] :diagnostics_mode # (Optional) Option for a vehicle to send diagnostic trouble codes to # Amazon Web Services IoT FleetWise. If you want to send diagnostic # trouble codes, use `SEND_ACTIVE_DTCS`. If it's not specified, `OFF` # is used. # # Default: `OFF` # # @option params [String] :spooling_mode # (Optional) Whether to store collected data after a vehicle lost a # connection with the cloud. After a connection is re-established, the # data is automatically forwarded to Amazon Web Services IoT FleetWise. # If you want to store collected data when a vehicle loses connection # with the cloud, use `TO_DISK`. If it's not specified, `OFF` is used. # # Default: `OFF` # # @option params [String] :compression # (Optional) Whether to compress signals before transmitting data to # Amazon Web Services IoT FleetWise. If you don't want to compress the # signals, use `OFF`. If it's not specified, `SNAPPY` is used. # # Default: `SNAPPY` # # @option params [Integer] :priority # (Optional) A number indicating the priority of one campaign over # another campaign for a certain vehicle or fleet. A campaign with the # lowest value is deployed to vehicles before any other campaigns. If # it's not specified, `0` is used. # # Default: `0` # # @option params [Array] :signals_to_collect # (Optional) A list of information about signals to collect. # # @option params [required, Types::CollectionScheme] :collection_scheme # The data collection scheme associated with the campaign. You can # specify a scheme that collects data based on time or an event. # # @option params [Array] :data_extra_dimensions # (Optional) A list of vehicle attributes to associate with a campaign. # # Enrich the data with specified vehicle attributes. For example, add # `make` and `model` to the campaign, and Amazon Web Services IoT # FleetWise will associate the data with those attributes as dimensions # in Amazon Timestream. You can then query the data against `make` and # `model`. # # Default: An empty array # # @option params [Array] :tags # Metadata that can be used to manage the campaign. # # @option params [Array] :data_destination_configs # The destination where the campaign sends data. You can choose to send # data to be stored in Amazon S3 or Amazon Timestream. # # Amazon S3 optimizes the cost of data storage and provides additional # mechanisms to use vehicle data, such as data lakes, centralized data # storage, data processing pipelines, and analytics. Amazon Web Services # IoT FleetWise supports at-least-once file delivery to S3. Your vehicle # data is stored on multiple Amazon Web Services IoT FleetWise servers # for redundancy and high availability. # # You can use Amazon Timestream to access and analyze time series data, # and Timestream to query vehicle data so that you can identify trends # and patterns. # # @return [Types::CreateCampaignResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::CreateCampaignResponse#name #name} => String # * {Types::CreateCampaignResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.create_campaign({ # name: "campaignName", # required # description: "description", # signal_catalog_arn: "arn", # required # target_arn: "arn", # required # start_time: Time.now, # expiry_time: Time.now, # post_trigger_collection_duration: 1, # diagnostics_mode: "OFF", # accepts OFF, SEND_ACTIVE_DTCS # spooling_mode: "OFF", # accepts OFF, TO_DISK # compression: "OFF", # accepts OFF, SNAPPY # priority: 1, # signals_to_collect: [ # { # name: "wildcardSignalName", # required # max_sample_count: 1, # minimum_sampling_interval_ms: 1, # }, # ], # collection_scheme: { # required # time_based_collection_scheme: { # period_ms: 1, # required # }, # condition_based_collection_scheme: { # expression: "eventExpression", # required # minimum_trigger_interval_ms: 1, # trigger_mode: "ALWAYS", # accepts ALWAYS, RISING_EDGE # condition_language_version: 1, # }, # }, # data_extra_dimensions: ["NodePath"], # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # data_destination_configs: [ # { # s3_config: { # bucket_arn: "S3BucketArn", # required # data_format: "JSON", # accepts JSON, PARQUET # storage_compression_format: "NONE", # accepts NONE, GZIP # prefix: "Prefix", # }, # timestream_config: { # timestream_table_arn: "TimestreamTableArn", # required # execution_role_arn: "IAMRoleArn", # required # }, # }, # ], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload create_campaign(params = {}) # @param [Hash] params ({}) def create_campaign(params = {}, options = {}) req = build_request(:create_campaign, params) req.send_request(options) end # Creates the decoder manifest associated with a model manifest. To # create a decoder manifest, the following must be true: # # * Every signal decoder has a unique name. # # * Each signal decoder is associated with a network interface. # # * Each network interface has a unique ID. # # * The signal decoders are specified in the model manifest. # # @option params [required, String] :name # The unique name of the decoder manifest to create. # # @option params [String] :description # A brief description of the decoder manifest. # # @option params [required, String] :model_manifest_arn # The Amazon Resource Name (ARN) of the vehicle model (model manifest). # # @option params [Array] :signal_decoders # A list of information about signal decoders. # # @option params [Array] :network_interfaces # A list of information about available network interfaces. # # @option params [Array] :tags # Metadata that can be used to manage the decoder manifest. # # @return [Types::CreateDecoderManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::CreateDecoderManifestResponse#name #name} => String # * {Types::CreateDecoderManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.create_decoder_manifest({ # name: "resourceName", # required # description: "description", # model_manifest_arn: "arn", # required # signal_decoders: [ # { # fully_qualified_name: "FullyQualifiedName", # required # type: "CAN_SIGNAL", # required, accepts CAN_SIGNAL, OBD_SIGNAL, MESSAGE_SIGNAL # interface_id: "InterfaceId", # required # can_signal: { # message_id: 1, # required # is_big_endian: false, # required # is_signed: false, # required # start_bit: 1, # required # offset: 1.0, # required # factor: 1.0, # required # length: 1, # required # name: "CanSignalName", # }, # obd_signal: { # pid_response_length: 1, # required # service_mode: 1, # required # pid: 1, # required # scaling: 1.0, # required # offset: 1.0, # required # start_byte: 1, # required # byte_length: 1, # required # bit_right_shift: 1, # bit_mask_length: 1, # }, # message_signal: { # topic_name: "TopicName", # required # structured_message: { # required # primitive_message_definition: { # ros2_primitive_message_definition: { # primitive_type: "BOOL", # required, accepts BOOL, BYTE, CHAR, FLOAT32, FLOAT64, INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, STRING, WSTRING # offset: 1.0, # scaling: 1.0, # upper_bound: 1, # }, # }, # structured_message_list_definition: { # name: "StructureMessageName", # required # member_type: { # required # # recursive StructuredMessage # }, # list_type: "FIXED_CAPACITY", # required, accepts FIXED_CAPACITY, DYNAMIC_UNBOUNDED_CAPACITY, DYNAMIC_BOUNDED_CAPACITY # capacity: 1, # }, # structured_message_definition: [ # { # field_name: "StructureMessageName", # required # data_type: { # required # # recursive StructuredMessage # }, # }, # ], # }, # }, # }, # ], # network_interfaces: [ # { # interface_id: "InterfaceId", # required # type: "CAN_INTERFACE", # required, accepts CAN_INTERFACE, OBD_INTERFACE, VEHICLE_MIDDLEWARE # can_interface: { # name: "CanInterfaceName", # required # protocol_name: "ProtocolName", # protocol_version: "ProtocolVersion", # }, # obd_interface: { # name: "ObdInterfaceName", # required # request_message_id: 1, # required # obd_standard: "ObdStandard", # pid_request_interval_seconds: 1, # dtc_request_interval_seconds: 1, # use_extended_ids: false, # has_transmission_ecu: false, # }, # vehicle_middleware: { # name: "VehicleMiddlewareName", # required # protocol_name: "ROS_2", # required, accepts ROS_2 # }, # }, # ], # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload create_decoder_manifest(params = {}) # @param [Hash] params ({}) def create_decoder_manifest(params = {}, options = {}) req = build_request(:create_decoder_manifest, params) req.send_request(options) end # Creates a fleet that represents a group of vehicles. # # You must create both a signal catalog and vehicles before you can # create a fleet. # # # # For more information, see [Fleets][1] in the *Amazon Web Services IoT # FleetWise Developer Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/fleets.html # # @option params [required, String] :fleet_id # The unique ID of the fleet to create. # # @option params [String] :description # A brief description of the fleet to create. # # @option params [required, String] :signal_catalog_arn # The Amazon Resource Name (ARN) of a signal catalog. # # @option params [Array] :tags # Metadata that can be used to manage the fleet. # # @return [Types::CreateFleetResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::CreateFleetResponse#id #id} => String # * {Types::CreateFleetResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.create_fleet({ # fleet_id: "fleetId", # required # description: "description", # signal_catalog_arn: "arn", # required # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @example Response structure # # resp.id #=> String # resp.arn #=> String # # @overload create_fleet(params = {}) # @param [Hash] params ({}) def create_fleet(params = {}, options = {}) req = build_request(:create_fleet, params) req.send_request(options) end # Creates a vehicle model (model manifest) that specifies signals # (attributes, branches, sensors, and actuators). # # For more information, see [Vehicle models][1] in the *Amazon Web # Services IoT FleetWise Developer Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/vehicle-models.html # # @option params [required, String] :name # The name of the vehicle model to create. # # @option params [String] :description # A brief description of the vehicle model. # # @option params [required, Array] :nodes # A list of nodes, which are a general abstraction of signals. # # @option params [required, String] :signal_catalog_arn # The Amazon Resource Name (ARN) of a signal catalog. # # @option params [Array] :tags # Metadata that can be used to manage the vehicle model. # # @return [Types::CreateModelManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::CreateModelManifestResponse#name #name} => String # * {Types::CreateModelManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.create_model_manifest({ # name: "resourceName", # required # description: "description", # nodes: ["string"], # required # signal_catalog_arn: "arn", # required # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload create_model_manifest(params = {}) # @param [Hash] params ({}) def create_model_manifest(params = {}, options = {}) req = build_request(:create_model_manifest, params) req.send_request(options) end # Creates a collection of standardized signals that can be reused to # create vehicle models. # # @option params [required, String] :name # The name of the signal catalog to create. # # @option params [String] :description # A brief description of the signal catalog. # # @option params [Array] :nodes # A list of information about nodes, which are a general abstraction of # signals. For more information, see the API data type. # # @option params [Array] :tags # Metadata that can be used to manage the signal catalog. # # @return [Types::CreateSignalCatalogResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::CreateSignalCatalogResponse#name #name} => String # * {Types::CreateSignalCatalogResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.create_signal_catalog({ # name: "resourceName", # required # description: "description", # nodes: [ # { # branch: { # fully_qualified_name: "string", # required # description: "description", # deprecation_message: "message", # comment: "message", # }, # sensor: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # actuator: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # assigned_value: "string", # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # attribute: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # assigned_value: "string", # default_value: "string", # deprecation_message: "message", # comment: "message", # }, # struct: { # fully_qualified_name: "string", # required # description: "description", # deprecation_message: "message", # comment: "message", # }, # property: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # data_encoding: "BINARY", # accepts BINARY, TYPED # description: "description", # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # }, # ], # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload create_signal_catalog(params = {}) # @param [Hash] params ({}) def create_signal_catalog(params = {}, options = {}) req = build_request(:create_signal_catalog, params) req.send_request(options) end # Creates a vehicle, which is an instance of a vehicle model (model # manifest). Vehicles created from the same vehicle model consist of the # same signals inherited from the vehicle model. # # If you have an existing Amazon Web Services IoT thing, you can use # Amazon Web Services IoT FleetWise to create a vehicle and collect data # from your thing. # # # # For more information, see [Create a vehicle (AWS CLI)][1] in the # *Amazon Web Services IoT FleetWise Developer Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/create-vehicle-cli.html # # @option params [required, String] :vehicle_name # The unique ID of the vehicle to create. # # @option params [required, String] :model_manifest_arn # The Amazon Resource Name ARN of a vehicle model. # # @option params [required, String] :decoder_manifest_arn # The ARN of a decoder manifest. # # @option params [Hash] :attributes # Static information about a vehicle in a key-value pair. For example: # `"engineType"` : `"1.3 L R2"` # # A campaign must include the keys (attribute names) in # `dataExtraDimensions` for them to display in Amazon Timestream. # # @option params [String] :association_behavior # An option to create a new Amazon Web Services IoT thing when creating # a vehicle, or to validate an existing Amazon Web Services IoT thing as # a vehicle. # # Default: `` # # @option params [Array] :tags # Metadata that can be used to manage the vehicle. # # @return [Types::CreateVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::CreateVehicleResponse#vehicle_name #vehicle_name} => String # * {Types::CreateVehicleResponse#arn #arn} => String # * {Types::CreateVehicleResponse#thing_arn #thing_arn} => String # # @example Request syntax with placeholder values # # resp = client.create_vehicle({ # vehicle_name: "vehicleName", # required # model_manifest_arn: "arn", # required # decoder_manifest_arn: "arn", # required # attributes: { # "attributeName" => "attributeValue", # }, # association_behavior: "CreateIotThing", # accepts CreateIotThing, ValidateIotThingExists # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @example Response structure # # resp.vehicle_name #=> String # resp.arn #=> String # resp.thing_arn #=> String # # @overload create_vehicle(params = {}) # @param [Hash] params ({}) def create_vehicle(params = {}, options = {}) req = build_request(:create_vehicle, params) req.send_request(options) end # Deletes a data collection campaign. Deleting a campaign suspends all # data collection and removes it from any vehicles. # # @option params [required, String] :name # The name of the campaign to delete. # # @return [Types::DeleteCampaignResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::DeleteCampaignResponse#name #name} => String # * {Types::DeleteCampaignResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.delete_campaign({ # name: "campaignName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload delete_campaign(params = {}) # @param [Hash] params ({}) def delete_campaign(params = {}, options = {}) req = build_request(:delete_campaign, params) req.send_request(options) end # Deletes a decoder manifest. You can't delete a decoder manifest if it # has vehicles associated with it. # # If the decoder manifest is successfully deleted, Amazon Web Services # IoT FleetWise sends back an HTTP 200 response with an empty body. # # # # @option params [required, String] :name # The name of the decoder manifest to delete. # # @return [Types::DeleteDecoderManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::DeleteDecoderManifestResponse#name #name} => String # * {Types::DeleteDecoderManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.delete_decoder_manifest({ # name: "resourceName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload delete_decoder_manifest(params = {}) # @param [Hash] params ({}) def delete_decoder_manifest(params = {}, options = {}) req = build_request(:delete_decoder_manifest, params) req.send_request(options) end # Deletes a fleet. Before you delete a fleet, all vehicles must be # dissociated from the fleet. For more information, see [Delete a fleet # (AWS CLI)][1] in the *Amazon Web Services IoT FleetWise Developer # Guide*. # # If the fleet is successfully deleted, Amazon Web Services IoT # FleetWise sends back an HTTP 200 response with an empty body. # # # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/delete-fleet-cli.html # # @option params [required, String] :fleet_id # The ID of the fleet to delete. # # @return [Types::DeleteFleetResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::DeleteFleetResponse#id #id} => String # * {Types::DeleteFleetResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.delete_fleet({ # fleet_id: "fleetId", # required # }) # # @example Response structure # # resp.id #=> String # resp.arn #=> String # # @overload delete_fleet(params = {}) # @param [Hash] params ({}) def delete_fleet(params = {}, options = {}) req = build_request(:delete_fleet, params) req.send_request(options) end # Deletes a vehicle model (model manifest). # # If the vehicle model is successfully deleted, Amazon Web Services IoT # FleetWise sends back an HTTP 200 response with an empty body. # # # # @option params [required, String] :name # The name of the model manifest to delete. # # @return [Types::DeleteModelManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::DeleteModelManifestResponse#name #name} => String # * {Types::DeleteModelManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.delete_model_manifest({ # name: "resourceName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload delete_model_manifest(params = {}) # @param [Hash] params ({}) def delete_model_manifest(params = {}, options = {}) req = build_request(:delete_model_manifest, params) req.send_request(options) end # Deletes a signal catalog. # # If the signal catalog is successfully deleted, Amazon Web Services IoT # FleetWise sends back an HTTP 200 response with an empty body. # # # # @option params [required, String] :name # The name of the signal catalog to delete. # # @return [Types::DeleteSignalCatalogResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::DeleteSignalCatalogResponse#name #name} => String # * {Types::DeleteSignalCatalogResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.delete_signal_catalog({ # name: "resourceName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload delete_signal_catalog(params = {}) # @param [Hash] params ({}) def delete_signal_catalog(params = {}, options = {}) req = build_request(:delete_signal_catalog, params) req.send_request(options) end # Deletes a vehicle and removes it from any campaigns. # # If the vehicle is successfully deleted, Amazon Web Services IoT # FleetWise sends back an HTTP 200 response with an empty body. # # # # @option params [required, String] :vehicle_name # The ID of the vehicle to delete. # # @return [Types::DeleteVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::DeleteVehicleResponse#vehicle_name #vehicle_name} => String # * {Types::DeleteVehicleResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.delete_vehicle({ # vehicle_name: "vehicleName", # required # }) # # @example Response structure # # resp.vehicle_name #=> String # resp.arn #=> String # # @overload delete_vehicle(params = {}) # @param [Hash] params ({}) def delete_vehicle(params = {}, options = {}) req = build_request(:delete_vehicle, params) req.send_request(options) end # Removes, or disassociates, a vehicle from a fleet. Disassociating a # vehicle from a fleet doesn't delete the vehicle. # # If the vehicle is successfully dissociated from a fleet, Amazon Web # Services IoT FleetWise sends back an HTTP 200 response with an empty # body. # # # # @option params [required, String] :vehicle_name # The unique ID of the vehicle to disassociate from the fleet. # # @option params [required, String] :fleet_id # The unique ID of a fleet. # # @return [Struct] Returns an empty {Seahorse::Client::Response response}. # # @example Request syntax with placeholder values # # resp = client.disassociate_vehicle_fleet({ # vehicle_name: "vehicleName", # required # fleet_id: "fleetId", # required # }) # # @overload disassociate_vehicle_fleet(params = {}) # @param [Hash] params ({}) def disassociate_vehicle_fleet(params = {}, options = {}) req = build_request(:disassociate_vehicle_fleet, params) req.send_request(options) end # Retrieves information about a campaign. # # @option params [required, String] :name # The name of the campaign to retrieve information about. # # @return [Types::GetCampaignResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetCampaignResponse#name #name} => String # * {Types::GetCampaignResponse#arn #arn} => String # * {Types::GetCampaignResponse#description #description} => String # * {Types::GetCampaignResponse#signal_catalog_arn #signal_catalog_arn} => String # * {Types::GetCampaignResponse#target_arn #target_arn} => String # * {Types::GetCampaignResponse#status #status} => String # * {Types::GetCampaignResponse#start_time #start_time} => Time # * {Types::GetCampaignResponse#expiry_time #expiry_time} => Time # * {Types::GetCampaignResponse#post_trigger_collection_duration #post_trigger_collection_duration} => Integer # * {Types::GetCampaignResponse#diagnostics_mode #diagnostics_mode} => String # * {Types::GetCampaignResponse#spooling_mode #spooling_mode} => String # * {Types::GetCampaignResponse#compression #compression} => String # * {Types::GetCampaignResponse#priority #priority} => Integer # * {Types::GetCampaignResponse#signals_to_collect #signals_to_collect} => Array<Types::SignalInformation> # * {Types::GetCampaignResponse#collection_scheme #collection_scheme} => Types::CollectionScheme # * {Types::GetCampaignResponse#data_extra_dimensions #data_extra_dimensions} => Array<String> # * {Types::GetCampaignResponse#creation_time #creation_time} => Time # * {Types::GetCampaignResponse#last_modification_time #last_modification_time} => Time # * {Types::GetCampaignResponse#data_destination_configs #data_destination_configs} => Array<Types::DataDestinationConfig> # # @example Request syntax with placeholder values # # resp = client.get_campaign({ # name: "campaignName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # resp.description #=> String # resp.signal_catalog_arn #=> String # resp.target_arn #=> String # resp.status #=> String, one of "CREATING", "WAITING_FOR_APPROVAL", "RUNNING", "SUSPENDED" # resp.start_time #=> Time # resp.expiry_time #=> Time # resp.post_trigger_collection_duration #=> Integer # resp.diagnostics_mode #=> String, one of "OFF", "SEND_ACTIVE_DTCS" # resp.spooling_mode #=> String, one of "OFF", "TO_DISK" # resp.compression #=> String, one of "OFF", "SNAPPY" # resp.priority #=> Integer # resp.signals_to_collect #=> Array # resp.signals_to_collect[0].name #=> String # resp.signals_to_collect[0].max_sample_count #=> Integer # resp.signals_to_collect[0].minimum_sampling_interval_ms #=> Integer # resp.collection_scheme.time_based_collection_scheme.period_ms #=> Integer # resp.collection_scheme.condition_based_collection_scheme.expression #=> String # resp.collection_scheme.condition_based_collection_scheme.minimum_trigger_interval_ms #=> Integer # resp.collection_scheme.condition_based_collection_scheme.trigger_mode #=> String, one of "ALWAYS", "RISING_EDGE" # resp.collection_scheme.condition_based_collection_scheme.condition_language_version #=> Integer # resp.data_extra_dimensions #=> Array # resp.data_extra_dimensions[0] #=> String # resp.creation_time #=> Time # resp.last_modification_time #=> Time # resp.data_destination_configs #=> Array # resp.data_destination_configs[0].s3_config.bucket_arn #=> String # resp.data_destination_configs[0].s3_config.data_format #=> String, one of "JSON", "PARQUET" # resp.data_destination_configs[0].s3_config.storage_compression_format #=> String, one of "NONE", "GZIP" # resp.data_destination_configs[0].s3_config.prefix #=> String # resp.data_destination_configs[0].timestream_config.timestream_table_arn #=> String # resp.data_destination_configs[0].timestream_config.execution_role_arn #=> String # # @overload get_campaign(params = {}) # @param [Hash] params ({}) def get_campaign(params = {}, options = {}) req = build_request(:get_campaign, params) req.send_request(options) end # Retrieves information about a created decoder manifest. # # @option params [required, String] :name # The name of the decoder manifest to retrieve information about. # # @return [Types::GetDecoderManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetDecoderManifestResponse#name #name} => String # * {Types::GetDecoderManifestResponse#arn #arn} => String # * {Types::GetDecoderManifestResponse#description #description} => String # * {Types::GetDecoderManifestResponse#model_manifest_arn #model_manifest_arn} => String # * {Types::GetDecoderManifestResponse#status #status} => String # * {Types::GetDecoderManifestResponse#creation_time #creation_time} => Time # * {Types::GetDecoderManifestResponse#last_modification_time #last_modification_time} => Time # * {Types::GetDecoderManifestResponse#message #message} => String # # @example Request syntax with placeholder values # # resp = client.get_decoder_manifest({ # name: "resourceName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # resp.description #=> String # resp.model_manifest_arn #=> String # resp.status #=> String, one of "ACTIVE", "DRAFT", "INVALID", "VALIDATING" # resp.creation_time #=> Time # resp.last_modification_time #=> Time # resp.message #=> String # # @overload get_decoder_manifest(params = {}) # @param [Hash] params ({}) def get_decoder_manifest(params = {}, options = {}) req = build_request(:get_decoder_manifest, params) req.send_request(options) end # Retrieves the encryption configuration for resources and data in # Amazon Web Services IoT FleetWise. # # @return [Types::GetEncryptionConfigurationResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetEncryptionConfigurationResponse#kms_key_id #kms_key_id} => String # * {Types::GetEncryptionConfigurationResponse#encryption_status #encryption_status} => String # * {Types::GetEncryptionConfigurationResponse#encryption_type #encryption_type} => String # * {Types::GetEncryptionConfigurationResponse#error_message #error_message} => String # * {Types::GetEncryptionConfigurationResponse#creation_time #creation_time} => Time # * {Types::GetEncryptionConfigurationResponse#last_modification_time #last_modification_time} => Time # # @example Response structure # # resp.kms_key_id #=> String # resp.encryption_status #=> String, one of "PENDING", "SUCCESS", "FAILURE" # resp.encryption_type #=> String, one of "KMS_BASED_ENCRYPTION", "FLEETWISE_DEFAULT_ENCRYPTION" # resp.error_message #=> String # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload get_encryption_configuration(params = {}) # @param [Hash] params ({}) def get_encryption_configuration(params = {}, options = {}) req = build_request(:get_encryption_configuration, params) req.send_request(options) end # Retrieves information about a fleet. # # @option params [required, String] :fleet_id # The ID of the fleet to retrieve information about. # # @return [Types::GetFleetResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetFleetResponse#id #id} => String # * {Types::GetFleetResponse#arn #arn} => String # * {Types::GetFleetResponse#description #description} => String # * {Types::GetFleetResponse#signal_catalog_arn #signal_catalog_arn} => String # * {Types::GetFleetResponse#creation_time #creation_time} => Time # * {Types::GetFleetResponse#last_modification_time #last_modification_time} => Time # # @example Request syntax with placeholder values # # resp = client.get_fleet({ # fleet_id: "fleetId", # required # }) # # @example Response structure # # resp.id #=> String # resp.arn #=> String # resp.description #=> String # resp.signal_catalog_arn #=> String # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload get_fleet(params = {}) # @param [Hash] params ({}) def get_fleet(params = {}, options = {}) req = build_request(:get_fleet, params) req.send_request(options) end # Retrieves the logging options. # # @return [Types::GetLoggingOptionsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetLoggingOptionsResponse#cloud_watch_log_delivery #cloud_watch_log_delivery} => Types::CloudWatchLogDeliveryOptions # # @example Response structure # # resp.cloud_watch_log_delivery.log_type #=> String, one of "OFF", "ERROR" # resp.cloud_watch_log_delivery.log_group_name #=> String # # @overload get_logging_options(params = {}) # @param [Hash] params ({}) def get_logging_options(params = {}, options = {}) req = build_request(:get_logging_options, params) req.send_request(options) end # Retrieves information about a vehicle model (model manifest). # # @option params [required, String] :name # The name of the vehicle model to retrieve information about. # # @return [Types::GetModelManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetModelManifestResponse#name #name} => String # * {Types::GetModelManifestResponse#arn #arn} => String # * {Types::GetModelManifestResponse#description #description} => String # * {Types::GetModelManifestResponse#signal_catalog_arn #signal_catalog_arn} => String # * {Types::GetModelManifestResponse#status #status} => String # * {Types::GetModelManifestResponse#creation_time #creation_time} => Time # * {Types::GetModelManifestResponse#last_modification_time #last_modification_time} => Time # # @example Request syntax with placeholder values # # resp = client.get_model_manifest({ # name: "resourceName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # resp.description #=> String # resp.signal_catalog_arn #=> String # resp.status #=> String, one of "ACTIVE", "DRAFT", "INVALID", "VALIDATING" # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload get_model_manifest(params = {}) # @param [Hash] params ({}) def get_model_manifest(params = {}, options = {}) req = build_request(:get_model_manifest, params) req.send_request(options) end # Retrieves information about the status of registering your Amazon Web # Services account, IAM, and Amazon Timestream resources so that Amazon # Web Services IoT FleetWise can transfer your vehicle data to the # Amazon Web Services Cloud. # # For more information, including step-by-step procedures, see [Setting # up Amazon Web Services IoT FleetWise][1]. # # This API operation doesn't require input parameters. # # # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/setting-up.html # # @return [Types::GetRegisterAccountStatusResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetRegisterAccountStatusResponse#customer_account_id #customer_account_id} => String # * {Types::GetRegisterAccountStatusResponse#account_status #account_status} => String # * {Types::GetRegisterAccountStatusResponse#timestream_registration_response #timestream_registration_response} => Types::TimestreamRegistrationResponse # * {Types::GetRegisterAccountStatusResponse#iam_registration_response #iam_registration_response} => Types::IamRegistrationResponse # * {Types::GetRegisterAccountStatusResponse#creation_time #creation_time} => Time # * {Types::GetRegisterAccountStatusResponse#last_modification_time #last_modification_time} => Time # # @example Response structure # # resp.customer_account_id #=> String # resp.account_status #=> String, one of "REGISTRATION_PENDING", "REGISTRATION_SUCCESS", "REGISTRATION_FAILURE" # resp.timestream_registration_response.timestream_database_name #=> String # resp.timestream_registration_response.timestream_table_name #=> String # resp.timestream_registration_response.timestream_database_arn #=> String # resp.timestream_registration_response.timestream_table_arn #=> String # resp.timestream_registration_response.registration_status #=> String, one of "REGISTRATION_PENDING", "REGISTRATION_SUCCESS", "REGISTRATION_FAILURE" # resp.timestream_registration_response.error_message #=> String # resp.iam_registration_response.role_arn #=> String # resp.iam_registration_response.registration_status #=> String, one of "REGISTRATION_PENDING", "REGISTRATION_SUCCESS", "REGISTRATION_FAILURE" # resp.iam_registration_response.error_message #=> String # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload get_register_account_status(params = {}) # @param [Hash] params ({}) def get_register_account_status(params = {}, options = {}) req = build_request(:get_register_account_status, params) req.send_request(options) end # Retrieves information about a signal catalog. # # @option params [required, String] :name # The name of the signal catalog to retrieve information about. # # @return [Types::GetSignalCatalogResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetSignalCatalogResponse#name #name} => String # * {Types::GetSignalCatalogResponse#arn #arn} => String # * {Types::GetSignalCatalogResponse#description #description} => String # * {Types::GetSignalCatalogResponse#node_counts #node_counts} => Types::NodeCounts # * {Types::GetSignalCatalogResponse#creation_time #creation_time} => Time # * {Types::GetSignalCatalogResponse#last_modification_time #last_modification_time} => Time # # @example Request syntax with placeholder values # # resp = client.get_signal_catalog({ # name: "resourceName", # required # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # resp.description #=> String # resp.node_counts.total_nodes #=> Integer # resp.node_counts.total_branches #=> Integer # resp.node_counts.total_sensors #=> Integer # resp.node_counts.total_attributes #=> Integer # resp.node_counts.total_actuators #=> Integer # resp.node_counts.total_structs #=> Integer # resp.node_counts.total_properties #=> Integer # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload get_signal_catalog(params = {}) # @param [Hash] params ({}) def get_signal_catalog(params = {}, options = {}) req = build_request(:get_signal_catalog, params) req.send_request(options) end # Retrieves information about a vehicle. # # @option params [required, String] :vehicle_name # The ID of the vehicle to retrieve information about. # # @return [Types::GetVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetVehicleResponse#vehicle_name #vehicle_name} => String # * {Types::GetVehicleResponse#arn #arn} => String # * {Types::GetVehicleResponse#model_manifest_arn #model_manifest_arn} => String # * {Types::GetVehicleResponse#decoder_manifest_arn #decoder_manifest_arn} => String # * {Types::GetVehicleResponse#attributes #attributes} => Hash<String,String> # * {Types::GetVehicleResponse#creation_time #creation_time} => Time # * {Types::GetVehicleResponse#last_modification_time #last_modification_time} => Time # # @example Request syntax with placeholder values # # resp = client.get_vehicle({ # vehicle_name: "vehicleName", # required # }) # # @example Response structure # # resp.vehicle_name #=> String # resp.arn #=> String # resp.model_manifest_arn #=> String # resp.decoder_manifest_arn #=> String # resp.attributes #=> Hash # resp.attributes["attributeName"] #=> String # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload get_vehicle(params = {}) # @param [Hash] params ({}) def get_vehicle(params = {}, options = {}) req = build_request(:get_vehicle, params) req.send_request(options) end # Retrieves information about the status of a vehicle with any # associated campaigns. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @option params [required, String] :vehicle_name # The ID of the vehicle to retrieve information about. # # @return [Types::GetVehicleStatusResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::GetVehicleStatusResponse#campaigns #campaigns} => Array<Types::VehicleStatus> # * {Types::GetVehicleStatusResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.get_vehicle_status({ # next_token: "nextToken", # max_results: 1, # vehicle_name: "vehicleName", # required # }) # # @example Response structure # # resp.campaigns #=> Array # resp.campaigns[0].campaign_name #=> String # resp.campaigns[0].vehicle_name #=> String # resp.campaigns[0].status #=> String, one of "CREATED", "READY", "HEALTHY", "SUSPENDED", "DELETING" # resp.next_token #=> String # # @overload get_vehicle_status(params = {}) # @param [Hash] params ({}) def get_vehicle_status(params = {}, options = {}) req = build_request(:get_vehicle_status, params) req.send_request(options) end # Creates a decoder manifest using your existing CAN DBC file from your # local device. # # @option params [required, String] :name # The name of the decoder manifest to import. # # @option params [required, Array] :network_file_definitions # The file to load into an Amazon Web Services account. # # @return [Types::ImportDecoderManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ImportDecoderManifestResponse#name #name} => String # * {Types::ImportDecoderManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.import_decoder_manifest({ # name: "resourceName", # required # network_file_definitions: [ # required # { # can_dbc: { # network_interface: "InterfaceId", # required # can_dbc_files: ["data"], # required # signals_map: { # "string" => "string", # }, # }, # }, # ], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload import_decoder_manifest(params = {}) # @param [Hash] params ({}) def import_decoder_manifest(params = {}, options = {}) req = build_request(:import_decoder_manifest, params) req.send_request(options) end # Creates a signal catalog using your existing VSS formatted content # from your local device. # # @option params [required, String] :name # The name of the signal catalog to import. # # @option params [String] :description # A brief description of the signal catalog. # # @option params [Types::FormattedVss] :vss # The contents of the Vehicle Signal Specification (VSS) configuration. # VSS is a precise language used to describe and model signals in # vehicle networks. # # @option params [Array] :tags # Metadata that can be used to manage the signal catalog. # # @return [Types::ImportSignalCatalogResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ImportSignalCatalogResponse#name #name} => String # * {Types::ImportSignalCatalogResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.import_signal_catalog({ # name: "resourceName", # required # description: "description", # vss: { # vss_json: "String", # }, # tags: [ # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload import_signal_catalog(params = {}) # @param [Hash] params ({}) def import_signal_catalog(params = {}, options = {}) req = build_request(:import_signal_catalog, params) req.send_request(options) end # Lists information about created campaigns. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @option params [String] :status # Optional parameter to filter the results by the status of each created # campaign in your account. The status can be one of: `CREATING`, # `WAITING_FOR_APPROVAL`, `RUNNING`, or `SUSPENDED`. # # @return [Types::ListCampaignsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListCampaignsResponse#campaign_summaries #campaign_summaries} => Array<Types::CampaignSummary> # * {Types::ListCampaignsResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_campaigns({ # next_token: "nextToken", # max_results: 1, # status: "status", # }) # # @example Response structure # # resp.campaign_summaries #=> Array # resp.campaign_summaries[0].arn #=> String # resp.campaign_summaries[0].name #=> String # resp.campaign_summaries[0].description #=> String # resp.campaign_summaries[0].signal_catalog_arn #=> String # resp.campaign_summaries[0].target_arn #=> String # resp.campaign_summaries[0].status #=> String, one of "CREATING", "WAITING_FOR_APPROVAL", "RUNNING", "SUSPENDED" # resp.campaign_summaries[0].creation_time #=> Time # resp.campaign_summaries[0].last_modification_time #=> Time # resp.next_token #=> String # # @overload list_campaigns(params = {}) # @param [Hash] params ({}) def list_campaigns(params = {}, options = {}) req = build_request(:list_campaigns, params) req.send_request(options) end # Lists the network interfaces specified in a decoder manifest. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [required, String] :name # The name of the decoder manifest to list information about. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListDecoderManifestNetworkInterfacesResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListDecoderManifestNetworkInterfacesResponse#network_interfaces #network_interfaces} => Array<Types::NetworkInterface> # * {Types::ListDecoderManifestNetworkInterfacesResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_decoder_manifest_network_interfaces({ # name: "resourceName", # required # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.network_interfaces #=> Array # resp.network_interfaces[0].interface_id #=> String # resp.network_interfaces[0].type #=> String, one of "CAN_INTERFACE", "OBD_INTERFACE", "VEHICLE_MIDDLEWARE" # resp.network_interfaces[0].can_interface.name #=> String # resp.network_interfaces[0].can_interface.protocol_name #=> String # resp.network_interfaces[0].can_interface.protocol_version #=> String # resp.network_interfaces[0].obd_interface.name #=> String # resp.network_interfaces[0].obd_interface.request_message_id #=> Integer # resp.network_interfaces[0].obd_interface.obd_standard #=> String # resp.network_interfaces[0].obd_interface.pid_request_interval_seconds #=> Integer # resp.network_interfaces[0].obd_interface.dtc_request_interval_seconds #=> Integer # resp.network_interfaces[0].obd_interface.use_extended_ids #=> Boolean # resp.network_interfaces[0].obd_interface.has_transmission_ecu #=> Boolean # resp.network_interfaces[0].vehicle_middleware.name #=> String # resp.network_interfaces[0].vehicle_middleware.protocol_name #=> String, one of "ROS_2" # resp.next_token #=> String # # @overload list_decoder_manifest_network_interfaces(params = {}) # @param [Hash] params ({}) def list_decoder_manifest_network_interfaces(params = {}, options = {}) req = build_request(:list_decoder_manifest_network_interfaces, params) req.send_request(options) end # A list of information about signal decoders specified in a decoder # manifest. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [required, String] :name # The name of the decoder manifest to list information about. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListDecoderManifestSignalsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListDecoderManifestSignalsResponse#signal_decoders #signal_decoders} => Array<Types::SignalDecoder> # * {Types::ListDecoderManifestSignalsResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_decoder_manifest_signals({ # name: "resourceName", # required # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.signal_decoders #=> Array # resp.signal_decoders[0].fully_qualified_name #=> String # resp.signal_decoders[0].type #=> String, one of "CAN_SIGNAL", "OBD_SIGNAL", "MESSAGE_SIGNAL" # resp.signal_decoders[0].interface_id #=> String # resp.signal_decoders[0].can_signal.message_id #=> Integer # resp.signal_decoders[0].can_signal.is_big_endian #=> Boolean # resp.signal_decoders[0].can_signal.is_signed #=> Boolean # resp.signal_decoders[0].can_signal.start_bit #=> Integer # resp.signal_decoders[0].can_signal.offset #=> Float # resp.signal_decoders[0].can_signal.factor #=> Float # resp.signal_decoders[0].can_signal.length #=> Integer # resp.signal_decoders[0].can_signal.name #=> String # resp.signal_decoders[0].obd_signal.pid_response_length #=> Integer # resp.signal_decoders[0].obd_signal.service_mode #=> Integer # resp.signal_decoders[0].obd_signal.pid #=> Integer # resp.signal_decoders[0].obd_signal.scaling #=> Float # resp.signal_decoders[0].obd_signal.offset #=> Float # resp.signal_decoders[0].obd_signal.start_byte #=> Integer # resp.signal_decoders[0].obd_signal.byte_length #=> Integer # resp.signal_decoders[0].obd_signal.bit_right_shift #=> Integer # resp.signal_decoders[0].obd_signal.bit_mask_length #=> Integer # resp.signal_decoders[0].message_signal.topic_name #=> String # resp.signal_decoders[0].message_signal.structured_message.primitive_message_definition.ros2_primitive_message_definition.primitive_type #=> String, one of "BOOL", "BYTE", "CHAR", "FLOAT32", "FLOAT64", "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "STRING", "WSTRING" # resp.signal_decoders[0].message_signal.structured_message.primitive_message_definition.ros2_primitive_message_definition.offset #=> Float # resp.signal_decoders[0].message_signal.structured_message.primitive_message_definition.ros2_primitive_message_definition.scaling #=> Float # resp.signal_decoders[0].message_signal.structured_message.primitive_message_definition.ros2_primitive_message_definition.upper_bound #=> Integer # resp.signal_decoders[0].message_signal.structured_message.structured_message_list_definition.name #=> String # resp.signal_decoders[0].message_signal.structured_message.structured_message_list_definition.member_type #=> Types::StructuredMessage # resp.signal_decoders[0].message_signal.structured_message.structured_message_list_definition.list_type #=> String, one of "FIXED_CAPACITY", "DYNAMIC_UNBOUNDED_CAPACITY", "DYNAMIC_BOUNDED_CAPACITY" # resp.signal_decoders[0].message_signal.structured_message.structured_message_list_definition.capacity #=> Integer # resp.signal_decoders[0].message_signal.structured_message.structured_message_definition #=> Array # resp.signal_decoders[0].message_signal.structured_message.structured_message_definition[0].field_name #=> String # resp.signal_decoders[0].message_signal.structured_message.structured_message_definition[0].data_type #=> Types::StructuredMessage # resp.next_token #=> String # # @overload list_decoder_manifest_signals(params = {}) # @param [Hash] params ({}) def list_decoder_manifest_signals(params = {}, options = {}) req = build_request(:list_decoder_manifest_signals, params) req.send_request(options) end # Lists decoder manifests. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [String] :model_manifest_arn # The Amazon Resource Name (ARN) of a vehicle model (model manifest) # associated with the decoder manifest. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListDecoderManifestsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListDecoderManifestsResponse#summaries #summaries} => Array<Types::DecoderManifestSummary> # * {Types::ListDecoderManifestsResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_decoder_manifests({ # model_manifest_arn: "arn", # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.summaries #=> Array # resp.summaries[0].name #=> String # resp.summaries[0].arn #=> String # resp.summaries[0].model_manifest_arn #=> String # resp.summaries[0].description #=> String # resp.summaries[0].status #=> String, one of "ACTIVE", "DRAFT", "INVALID", "VALIDATING" # resp.summaries[0].creation_time #=> Time # resp.summaries[0].last_modification_time #=> Time # resp.summaries[0].message #=> String # resp.next_token #=> String # # @overload list_decoder_manifests(params = {}) # @param [Hash] params ({}) def list_decoder_manifests(params = {}, options = {}) req = build_request(:list_decoder_manifests, params) req.send_request(options) end # Retrieves information for each created fleet in an Amazon Web Services # account. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListFleetsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListFleetsResponse#fleet_summaries #fleet_summaries} => Array<Types::FleetSummary> # * {Types::ListFleetsResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_fleets({ # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.fleet_summaries #=> Array # resp.fleet_summaries[0].id #=> String # resp.fleet_summaries[0].arn #=> String # resp.fleet_summaries[0].description #=> String # resp.fleet_summaries[0].signal_catalog_arn #=> String # resp.fleet_summaries[0].creation_time #=> Time # resp.fleet_summaries[0].last_modification_time #=> Time # resp.next_token #=> String # # @overload list_fleets(params = {}) # @param [Hash] params ({}) def list_fleets(params = {}, options = {}) req = build_request(:list_fleets, params) req.send_request(options) end # Retrieves a list of IDs for all fleets that the vehicle is associated # with. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [required, String] :vehicle_name # The ID of the vehicle to retrieve information about. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListFleetsForVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListFleetsForVehicleResponse#fleets #fleets} => Array<String> # * {Types::ListFleetsForVehicleResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_fleets_for_vehicle({ # vehicle_name: "vehicleName", # required # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.fleets #=> Array # resp.fleets[0] #=> String # resp.next_token #=> String # # @overload list_fleets_for_vehicle(params = {}) # @param [Hash] params ({}) def list_fleets_for_vehicle(params = {}, options = {}) req = build_request(:list_fleets_for_vehicle, params) req.send_request(options) end # Lists information about nodes specified in a vehicle model (model # manifest). # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [required, String] :name # The name of the vehicle model to list information about. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListModelManifestNodesResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListModelManifestNodesResponse#nodes #nodes} => Array<Types::Node> # * {Types::ListModelManifestNodesResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_model_manifest_nodes({ # name: "resourceName", # required # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.nodes #=> Array # resp.nodes[0].branch.fully_qualified_name #=> String # resp.nodes[0].branch.description #=> String # resp.nodes[0].branch.deprecation_message #=> String # resp.nodes[0].branch.comment #=> String # resp.nodes[0].sensor.fully_qualified_name #=> String # resp.nodes[0].sensor.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].sensor.description #=> String # resp.nodes[0].sensor.unit #=> String # resp.nodes[0].sensor.allowed_values #=> Array # resp.nodes[0].sensor.allowed_values[0] #=> String # resp.nodes[0].sensor.min #=> Float # resp.nodes[0].sensor.max #=> Float # resp.nodes[0].sensor.deprecation_message #=> String # resp.nodes[0].sensor.comment #=> String # resp.nodes[0].sensor.struct_fully_qualified_name #=> String # resp.nodes[0].actuator.fully_qualified_name #=> String # resp.nodes[0].actuator.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].actuator.description #=> String # resp.nodes[0].actuator.unit #=> String # resp.nodes[0].actuator.allowed_values #=> Array # resp.nodes[0].actuator.allowed_values[0] #=> String # resp.nodes[0].actuator.min #=> Float # resp.nodes[0].actuator.max #=> Float # resp.nodes[0].actuator.assigned_value #=> String # resp.nodes[0].actuator.deprecation_message #=> String # resp.nodes[0].actuator.comment #=> String # resp.nodes[0].actuator.struct_fully_qualified_name #=> String # resp.nodes[0].attribute.fully_qualified_name #=> String # resp.nodes[0].attribute.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].attribute.description #=> String # resp.nodes[0].attribute.unit #=> String # resp.nodes[0].attribute.allowed_values #=> Array # resp.nodes[0].attribute.allowed_values[0] #=> String # resp.nodes[0].attribute.min #=> Float # resp.nodes[0].attribute.max #=> Float # resp.nodes[0].attribute.assigned_value #=> String # resp.nodes[0].attribute.default_value #=> String # resp.nodes[0].attribute.deprecation_message #=> String # resp.nodes[0].attribute.comment #=> String # resp.nodes[0].struct.fully_qualified_name #=> String # resp.nodes[0].struct.description #=> String # resp.nodes[0].struct.deprecation_message #=> String # resp.nodes[0].struct.comment #=> String # resp.nodes[0].property.fully_qualified_name #=> String # resp.nodes[0].property.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].property.data_encoding #=> String, one of "BINARY", "TYPED" # resp.nodes[0].property.description #=> String # resp.nodes[0].property.deprecation_message #=> String # resp.nodes[0].property.comment #=> String # resp.nodes[0].property.struct_fully_qualified_name #=> String # resp.next_token #=> String # # @overload list_model_manifest_nodes(params = {}) # @param [Hash] params ({}) def list_model_manifest_nodes(params = {}, options = {}) req = build_request(:list_model_manifest_nodes, params) req.send_request(options) end # Retrieves a list of vehicle models (model manifests). # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [String] :signal_catalog_arn # The ARN of a signal catalog. If you specify a signal catalog, only the # vehicle models associated with it are returned. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListModelManifestsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListModelManifestsResponse#summaries #summaries} => Array<Types::ModelManifestSummary> # * {Types::ListModelManifestsResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_model_manifests({ # signal_catalog_arn: "arn", # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.summaries #=> Array # resp.summaries[0].name #=> String # resp.summaries[0].arn #=> String # resp.summaries[0].signal_catalog_arn #=> String # resp.summaries[0].description #=> String # resp.summaries[0].status #=> String, one of "ACTIVE", "DRAFT", "INVALID", "VALIDATING" # resp.summaries[0].creation_time #=> Time # resp.summaries[0].last_modification_time #=> Time # resp.next_token #=> String # # @overload list_model_manifests(params = {}) # @param [Hash] params ({}) def list_model_manifests(params = {}, options = {}) req = build_request(:list_model_manifests, params) req.send_request(options) end # Lists of information about the signals (nodes) specified in a signal # catalog. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [required, String] :name # The name of the signal catalog to list information about. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @option params [String] :signal_node_type # The type of node in the signal catalog. # # @return [Types::ListSignalCatalogNodesResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListSignalCatalogNodesResponse#nodes #nodes} => Array<Types::Node> # * {Types::ListSignalCatalogNodesResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_signal_catalog_nodes({ # name: "resourceName", # required # next_token: "nextToken", # max_results: 1, # signal_node_type: "SENSOR", # accepts SENSOR, ACTUATOR, ATTRIBUTE, BRANCH, CUSTOM_STRUCT, CUSTOM_PROPERTY # }) # # @example Response structure # # resp.nodes #=> Array # resp.nodes[0].branch.fully_qualified_name #=> String # resp.nodes[0].branch.description #=> String # resp.nodes[0].branch.deprecation_message #=> String # resp.nodes[0].branch.comment #=> String # resp.nodes[0].sensor.fully_qualified_name #=> String # resp.nodes[0].sensor.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].sensor.description #=> String # resp.nodes[0].sensor.unit #=> String # resp.nodes[0].sensor.allowed_values #=> Array # resp.nodes[0].sensor.allowed_values[0] #=> String # resp.nodes[0].sensor.min #=> Float # resp.nodes[0].sensor.max #=> Float # resp.nodes[0].sensor.deprecation_message #=> String # resp.nodes[0].sensor.comment #=> String # resp.nodes[0].sensor.struct_fully_qualified_name #=> String # resp.nodes[0].actuator.fully_qualified_name #=> String # resp.nodes[0].actuator.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].actuator.description #=> String # resp.nodes[0].actuator.unit #=> String # resp.nodes[0].actuator.allowed_values #=> Array # resp.nodes[0].actuator.allowed_values[0] #=> String # resp.nodes[0].actuator.min #=> Float # resp.nodes[0].actuator.max #=> Float # resp.nodes[0].actuator.assigned_value #=> String # resp.nodes[0].actuator.deprecation_message #=> String # resp.nodes[0].actuator.comment #=> String # resp.nodes[0].actuator.struct_fully_qualified_name #=> String # resp.nodes[0].attribute.fully_qualified_name #=> String # resp.nodes[0].attribute.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].attribute.description #=> String # resp.nodes[0].attribute.unit #=> String # resp.nodes[0].attribute.allowed_values #=> Array # resp.nodes[0].attribute.allowed_values[0] #=> String # resp.nodes[0].attribute.min #=> Float # resp.nodes[0].attribute.max #=> Float # resp.nodes[0].attribute.assigned_value #=> String # resp.nodes[0].attribute.default_value #=> String # resp.nodes[0].attribute.deprecation_message #=> String # resp.nodes[0].attribute.comment #=> String # resp.nodes[0].struct.fully_qualified_name #=> String # resp.nodes[0].struct.description #=> String # resp.nodes[0].struct.deprecation_message #=> String # resp.nodes[0].struct.comment #=> String # resp.nodes[0].property.fully_qualified_name #=> String # resp.nodes[0].property.data_type #=> String, one of "INT8", "UINT8", "INT16", "UINT16", "INT32", "UINT32", "INT64", "UINT64", "BOOLEAN", "FLOAT", "DOUBLE", "STRING", "UNIX_TIMESTAMP", "INT8_ARRAY", "UINT8_ARRAY", "INT16_ARRAY", "UINT16_ARRAY", "INT32_ARRAY", "UINT32_ARRAY", "INT64_ARRAY", "UINT64_ARRAY", "BOOLEAN_ARRAY", "FLOAT_ARRAY", "DOUBLE_ARRAY", "STRING_ARRAY", "UNIX_TIMESTAMP_ARRAY", "UNKNOWN", "STRUCT", "STRUCT_ARRAY" # resp.nodes[0].property.data_encoding #=> String, one of "BINARY", "TYPED" # resp.nodes[0].property.description #=> String # resp.nodes[0].property.deprecation_message #=> String # resp.nodes[0].property.comment #=> String # resp.nodes[0].property.struct_fully_qualified_name #=> String # resp.next_token #=> String # # @overload list_signal_catalog_nodes(params = {}) # @param [Hash] params ({}) def list_signal_catalog_nodes(params = {}, options = {}) req = build_request(:list_signal_catalog_nodes, params) req.send_request(options) end # Lists all the created signal catalogs in an Amazon Web Services # account. # # You can use to list information about each signal (node) specified in # a signal catalog. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListSignalCatalogsResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListSignalCatalogsResponse#summaries #summaries} => Array<Types::SignalCatalogSummary> # * {Types::ListSignalCatalogsResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_signal_catalogs({ # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.summaries #=> Array # resp.summaries[0].name #=> String # resp.summaries[0].arn #=> String # resp.summaries[0].creation_time #=> Time # resp.summaries[0].last_modification_time #=> Time # resp.next_token #=> String # # @overload list_signal_catalogs(params = {}) # @param [Hash] params ({}) def list_signal_catalogs(params = {}, options = {}) req = build_request(:list_signal_catalogs, params) req.send_request(options) end # Lists the tags (metadata) you have assigned to the resource. # # @option params [required, String] :resource_arn # The ARN of the resource. # # @return [Types::ListTagsForResourceResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListTagsForResourceResponse#tags #tags} => Array<Types::Tag> # # @example Request syntax with placeholder values # # resp = client.list_tags_for_resource({ # resource_arn: "AmazonResourceName", # required # }) # # @example Response structure # # resp.tags #=> Array # resp.tags[0].key #=> String # resp.tags[0].value #=> String # # @overload list_tags_for_resource(params = {}) # @param [Hash] params ({}) def list_tags_for_resource(params = {}, options = {}) req = build_request(:list_tags_for_resource, params) req.send_request(options) end # Retrieves a list of summaries of created vehicles. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [String] :model_manifest_arn # The Amazon Resource Name (ARN) of a vehicle model (model manifest). # You can use this optional parameter to list only the vehicles created # from a certain vehicle model. # # @option params [Array] :attribute_names # The fully qualified names of the attributes. For example, the fully # qualified name of an attribute might be `Vehicle.Body.Engine.Type`. # # @option params [Array] :attribute_values # Static information about a vehicle attribute value in string format. # For example: # # `"1.3 L R2"` # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListVehiclesResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListVehiclesResponse#vehicle_summaries #vehicle_summaries} => Array<Types::VehicleSummary> # * {Types::ListVehiclesResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_vehicles({ # model_manifest_arn: "arn", # attribute_names: ["attributeName"], # attribute_values: ["attributeValue"], # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.vehicle_summaries #=> Array # resp.vehicle_summaries[0].vehicle_name #=> String # resp.vehicle_summaries[0].arn #=> String # resp.vehicle_summaries[0].model_manifest_arn #=> String # resp.vehicle_summaries[0].decoder_manifest_arn #=> String # resp.vehicle_summaries[0].creation_time #=> Time # resp.vehicle_summaries[0].last_modification_time #=> Time # resp.vehicle_summaries[0].attributes #=> Hash # resp.vehicle_summaries[0].attributes["attributeName"] #=> String # resp.next_token #=> String # # @overload list_vehicles(params = {}) # @param [Hash] params ({}) def list_vehicles(params = {}, options = {}) req = build_request(:list_vehicles, params) req.send_request(options) end # Retrieves a list of summaries of all vehicles associated with a fleet. # # This API operation uses pagination. Specify the `nextToken` parameter # in the request to return more results. # # # # @option params [required, String] :fleet_id # The ID of a fleet. # # @option params [String] :next_token # A pagination token for the next set of results. # # If the results of a search are large, only a portion of the results # are returned, and a `nextToken` pagination token is returned in the # response. To retrieve the next set of results, reissue the search # request and include the returned token. When all results have been # returned, the response does not contain a pagination token value. # # @option params [Integer] :max_results # The maximum number of items to return, between 1 and 100, inclusive. # # @return [Types::ListVehiclesInFleetResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::ListVehiclesInFleetResponse#vehicles #vehicles} => Array<String> # * {Types::ListVehiclesInFleetResponse#next_token #next_token} => String # # The returned {Seahorse::Client::Response response} is a pageable response and is Enumerable. For details on usage see {Aws::PageableResponse PageableResponse}. # # @example Request syntax with placeholder values # # resp = client.list_vehicles_in_fleet({ # fleet_id: "fleetId", # required # next_token: "nextToken", # max_results: 1, # }) # # @example Response structure # # resp.vehicles #=> Array # resp.vehicles[0] #=> String # resp.next_token #=> String # # @overload list_vehicles_in_fleet(params = {}) # @param [Hash] params ({}) def list_vehicles_in_fleet(params = {}, options = {}) req = build_request(:list_vehicles_in_fleet, params) req.send_request(options) end # Creates or updates the encryption configuration. Amazon Web Services # IoT FleetWise can encrypt your data and resources using an Amazon Web # Services managed key. Or, you can use a KMS key that you own and # manage. For more information, see [Data encryption][1] in the *Amazon # Web Services IoT FleetWise Developer Guide*. # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/data-encryption.html # # @option params [String] :kms_key_id # The ID of the KMS key that is used for encryption. # # @option params [required, String] :encryption_type # The type of encryption. Choose `KMS_BASED_ENCRYPTION` to use a KMS key # or `FLEETWISE_DEFAULT_ENCRYPTION` to use an Amazon Web Services # managed key. # # @return [Types::PutEncryptionConfigurationResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::PutEncryptionConfigurationResponse#kms_key_id #kms_key_id} => String # * {Types::PutEncryptionConfigurationResponse#encryption_status #encryption_status} => String # * {Types::PutEncryptionConfigurationResponse#encryption_type #encryption_type} => String # # @example Request syntax with placeholder values # # resp = client.put_encryption_configuration({ # kms_key_id: "PutEncryptionConfigurationRequestKmsKeyIdString", # encryption_type: "KMS_BASED_ENCRYPTION", # required, accepts KMS_BASED_ENCRYPTION, FLEETWISE_DEFAULT_ENCRYPTION # }) # # @example Response structure # # resp.kms_key_id #=> String # resp.encryption_status #=> String, one of "PENDING", "SUCCESS", "FAILURE" # resp.encryption_type #=> String, one of "KMS_BASED_ENCRYPTION", "FLEETWISE_DEFAULT_ENCRYPTION" # # @overload put_encryption_configuration(params = {}) # @param [Hash] params ({}) def put_encryption_configuration(params = {}, options = {}) req = build_request(:put_encryption_configuration, params) req.send_request(options) end # Creates or updates the logging option. # # @option params [required, Types::CloudWatchLogDeliveryOptions] :cloud_watch_log_delivery # Creates or updates the log delivery option to Amazon CloudWatch Logs. # # @return [Struct] Returns an empty {Seahorse::Client::Response response}. # # @example Request syntax with placeholder values # # resp = client.put_logging_options({ # cloud_watch_log_delivery: { # required # log_type: "OFF", # required, accepts OFF, ERROR # log_group_name: "CloudWatchLogGroupName", # }, # }) # # @overload put_logging_options(params = {}) # @param [Hash] params ({}) def put_logging_options(params = {}, options = {}) req = build_request(:put_logging_options, params) req.send_request(options) end # This API operation contains deprecated parameters. Register your # account again without the Timestream resources parameter so that # Amazon Web Services IoT FleetWise can remove the Timestream metadata # stored. You should then pass the data destination into the # [CreateCampaign][1] API operation. # # You must delete any existing campaigns that include an empty data # destination before you register your account again. For more # information, see the [DeleteCampaign][2] API operation. # # If you want to delete the Timestream inline policy from the # service-linked role, such as to mitigate an overly permissive policy, # you must first delete any existing campaigns. Then delete the # service-linked role and register your account again to enable # CloudWatch metrics. For more information, see # [DeleteServiceLinkedRole][3] in the *Identity and Access Management # API Reference*. # # Registers your Amazon Web Services account, IAM, and Amazon Timestream # resources so Amazon Web Services IoT FleetWise can transfer your # vehicle data to the Amazon Web Services Cloud. For more information, # including step-by-step procedures, see [Setting up Amazon Web Services # IoT FleetWise][4]. # # An Amazon Web Services account is **not** the same thing as a # "user." An [Amazon Web Services user][5] is an identity that you # create using Identity and Access Management (IAM) and takes the form # of either an [IAM user][6] or an [IAM role, both with credentials][7]. # A single Amazon Web Services account can, and typically does, contain # many users and roles. # # # # # # [1]: https://docs.aws.amazon.com/iot-fleetwise/latest/APIReference/API_CreateCampaign.html # [2]: https://docs.aws.amazon.com/iot-fleetwise/latest/APIReference/API_DeleteCampaign.html # [3]: https://docs.aws.amazon.com/IAM/latest/APIReference/API_DeleteServiceLinkedRole.html # [4]: https://docs.aws.amazon.com/iot-fleetwise/latest/developerguide/setting-up.html # [5]: https://docs.aws.amazon.com/IAM/latest/UserGuide/introduction_identity-management.html#intro-identity-users # [6]: https://docs.aws.amazon.com/IAM/latest/UserGuide/id_users.html # [7]: https://docs.aws.amazon.com/IAM/latest/UserGuide/id_roles.html # # @option params [Types::TimestreamResources] :timestream_resources # The registered Amazon Timestream resources that Amazon Web Services # IoT FleetWise edge agent software can transfer your vehicle data to. # # @option params [Types::IamResources] :iam_resources # The IAM resource that allows Amazon Web Services IoT FleetWise to send # data to Amazon Timestream. # # @return [Types::RegisterAccountResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::RegisterAccountResponse#register_account_status #register_account_status} => String # * {Types::RegisterAccountResponse#timestream_resources #timestream_resources} => Types::TimestreamResources # * {Types::RegisterAccountResponse#iam_resources #iam_resources} => Types::IamResources # * {Types::RegisterAccountResponse#creation_time #creation_time} => Time # * {Types::RegisterAccountResponse#last_modification_time #last_modification_time} => Time # # @example Request syntax with placeholder values # # resp = client.register_account({ # timestream_resources: { # timestream_database_name: "TimestreamDatabaseName", # required # timestream_table_name: "TimestreamTableName", # required # }, # iam_resources: { # role_arn: "IAMRoleArn", # required # }, # }) # # @example Response structure # # resp.register_account_status #=> String, one of "REGISTRATION_PENDING", "REGISTRATION_SUCCESS", "REGISTRATION_FAILURE" # resp.timestream_resources.timestream_database_name #=> String # resp.timestream_resources.timestream_table_name #=> String # resp.iam_resources.role_arn #=> String # resp.creation_time #=> Time # resp.last_modification_time #=> Time # # @overload register_account(params = {}) # @param [Hash] params ({}) def register_account(params = {}, options = {}) req = build_request(:register_account, params) req.send_request(options) end # Adds to or modifies the tags of the given resource. Tags are metadata # which can be used to manage a resource. # # @option params [required, String] :resource_arn # The ARN of the resource. # # @option params [required, Array] :tags # The new or modified tags for the resource. # # @return [Struct] Returns an empty {Seahorse::Client::Response response}. # # @example Request syntax with placeholder values # # resp = client.tag_resource({ # resource_arn: "AmazonResourceName", # required # tags: [ # required # { # key: "TagKey", # required # value: "TagValue", # required # }, # ], # }) # # @overload tag_resource(params = {}) # @param [Hash] params ({}) def tag_resource(params = {}, options = {}) req = build_request(:tag_resource, params) req.send_request(options) end # Removes the given tags (metadata) from the resource. # # @option params [required, String] :resource_arn # The ARN of the resource. # # @option params [required, Array] :tag_keys # A list of the keys of the tags to be removed from the resource. # # @return [Struct] Returns an empty {Seahorse::Client::Response response}. # # @example Request syntax with placeholder values # # resp = client.untag_resource({ # resource_arn: "AmazonResourceName", # required # tag_keys: ["TagKey"], # required # }) # # @overload untag_resource(params = {}) # @param [Hash] params ({}) def untag_resource(params = {}, options = {}) req = build_request(:untag_resource, params) req.send_request(options) end # Updates a campaign. # # @option params [required, String] :name # The name of the campaign to update. # # @option params [String] :description # The description of the campaign. # # @option params [Array] :data_extra_dimensions # A list of vehicle attributes to associate with a signal. # # Default: An empty array # # @option params [required, String] :action # Specifies how to update a campaign. The action can be one of the # following: # # * `APPROVE` - To approve delivering a data collection scheme to # vehicles. # # * `SUSPEND` - To suspend collecting signal data. The campaign is # deleted from vehicles and all vehicles in the suspended campaign # will stop sending data. # # * `RESUME` - To reactivate the `SUSPEND` campaign. The campaign is # redeployed to all vehicles and the vehicles will resume sending # data. # # * `UPDATE` - To update a campaign. # # @return [Types::UpdateCampaignResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::UpdateCampaignResponse#arn #arn} => String # * {Types::UpdateCampaignResponse#name #name} => String # * {Types::UpdateCampaignResponse#status #status} => String # # @example Request syntax with placeholder values # # resp = client.update_campaign({ # name: "campaignName", # required # description: "description", # data_extra_dimensions: ["NodePath"], # action: "APPROVE", # required, accepts APPROVE, SUSPEND, RESUME, UPDATE # }) # # @example Response structure # # resp.arn #=> String # resp.name #=> String # resp.status #=> String, one of "CREATING", "WAITING_FOR_APPROVAL", "RUNNING", "SUSPENDED" # # @overload update_campaign(params = {}) # @param [Hash] params ({}) def update_campaign(params = {}, options = {}) req = build_request(:update_campaign, params) req.send_request(options) end # Updates a decoder manifest. # # A decoder manifest can only be updated when the status is `DRAFT`. # Only `ACTIVE` decoder manifests can be associated with vehicles. # # @option params [required, String] :name # The name of the decoder manifest to update. # # @option params [String] :description # A brief description of the decoder manifest to update. # # @option params [Array] :signal_decoders_to_add # A list of information about decoding additional signals to add to the # decoder manifest. # # @option params [Array] :signal_decoders_to_update # A list of updated information about decoding signals to update in the # decoder manifest. # # @option params [Array] :signal_decoders_to_remove # A list of signal decoders to remove from the decoder manifest. # # @option params [Array] :network_interfaces_to_add # A list of information about the network interfaces to add to the # decoder manifest. # # @option params [Array] :network_interfaces_to_update # A list of information about the network interfaces to update in the # decoder manifest. # # @option params [Array] :network_interfaces_to_remove # A list of network interfaces to remove from the decoder manifest. # # @option params [String] :status # The state of the decoder manifest. If the status is `ACTIVE`, the # decoder manifest can't be edited. If the status is `DRAFT`, you can # edit the decoder manifest. # # @return [Types::UpdateDecoderManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::UpdateDecoderManifestResponse#name #name} => String # * {Types::UpdateDecoderManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.update_decoder_manifest({ # name: "resourceName", # required # description: "description", # signal_decoders_to_add: [ # { # fully_qualified_name: "FullyQualifiedName", # required # type: "CAN_SIGNAL", # required, accepts CAN_SIGNAL, OBD_SIGNAL, MESSAGE_SIGNAL # interface_id: "InterfaceId", # required # can_signal: { # message_id: 1, # required # is_big_endian: false, # required # is_signed: false, # required # start_bit: 1, # required # offset: 1.0, # required # factor: 1.0, # required # length: 1, # required # name: "CanSignalName", # }, # obd_signal: { # pid_response_length: 1, # required # service_mode: 1, # required # pid: 1, # required # scaling: 1.0, # required # offset: 1.0, # required # start_byte: 1, # required # byte_length: 1, # required # bit_right_shift: 1, # bit_mask_length: 1, # }, # message_signal: { # topic_name: "TopicName", # required # structured_message: { # required # primitive_message_definition: { # ros2_primitive_message_definition: { # primitive_type: "BOOL", # required, accepts BOOL, BYTE, CHAR, FLOAT32, FLOAT64, INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, STRING, WSTRING # offset: 1.0, # scaling: 1.0, # upper_bound: 1, # }, # }, # structured_message_list_definition: { # name: "StructureMessageName", # required # member_type: { # required # # recursive StructuredMessage # }, # list_type: "FIXED_CAPACITY", # required, accepts FIXED_CAPACITY, DYNAMIC_UNBOUNDED_CAPACITY, DYNAMIC_BOUNDED_CAPACITY # capacity: 1, # }, # structured_message_definition: [ # { # field_name: "StructureMessageName", # required # data_type: { # required # # recursive StructuredMessage # }, # }, # ], # }, # }, # }, # ], # signal_decoders_to_update: [ # { # fully_qualified_name: "FullyQualifiedName", # required # type: "CAN_SIGNAL", # required, accepts CAN_SIGNAL, OBD_SIGNAL, MESSAGE_SIGNAL # interface_id: "InterfaceId", # required # can_signal: { # message_id: 1, # required # is_big_endian: false, # required # is_signed: false, # required # start_bit: 1, # required # offset: 1.0, # required # factor: 1.0, # required # length: 1, # required # name: "CanSignalName", # }, # obd_signal: { # pid_response_length: 1, # required # service_mode: 1, # required # pid: 1, # required # scaling: 1.0, # required # offset: 1.0, # required # start_byte: 1, # required # byte_length: 1, # required # bit_right_shift: 1, # bit_mask_length: 1, # }, # message_signal: { # topic_name: "TopicName", # required # structured_message: { # required # primitive_message_definition: { # ros2_primitive_message_definition: { # primitive_type: "BOOL", # required, accepts BOOL, BYTE, CHAR, FLOAT32, FLOAT64, INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, STRING, WSTRING # offset: 1.0, # scaling: 1.0, # upper_bound: 1, # }, # }, # structured_message_list_definition: { # name: "StructureMessageName", # required # member_type: { # required # # recursive StructuredMessage # }, # list_type: "FIXED_CAPACITY", # required, accepts FIXED_CAPACITY, DYNAMIC_UNBOUNDED_CAPACITY, DYNAMIC_BOUNDED_CAPACITY # capacity: 1, # }, # structured_message_definition: [ # { # field_name: "StructureMessageName", # required # data_type: { # required # # recursive StructuredMessage # }, # }, # ], # }, # }, # }, # ], # signal_decoders_to_remove: ["FullyQualifiedName"], # network_interfaces_to_add: [ # { # interface_id: "InterfaceId", # required # type: "CAN_INTERFACE", # required, accepts CAN_INTERFACE, OBD_INTERFACE, VEHICLE_MIDDLEWARE # can_interface: { # name: "CanInterfaceName", # required # protocol_name: "ProtocolName", # protocol_version: "ProtocolVersion", # }, # obd_interface: { # name: "ObdInterfaceName", # required # request_message_id: 1, # required # obd_standard: "ObdStandard", # pid_request_interval_seconds: 1, # dtc_request_interval_seconds: 1, # use_extended_ids: false, # has_transmission_ecu: false, # }, # vehicle_middleware: { # name: "VehicleMiddlewareName", # required # protocol_name: "ROS_2", # required, accepts ROS_2 # }, # }, # ], # network_interfaces_to_update: [ # { # interface_id: "InterfaceId", # required # type: "CAN_INTERFACE", # required, accepts CAN_INTERFACE, OBD_INTERFACE, VEHICLE_MIDDLEWARE # can_interface: { # name: "CanInterfaceName", # required # protocol_name: "ProtocolName", # protocol_version: "ProtocolVersion", # }, # obd_interface: { # name: "ObdInterfaceName", # required # request_message_id: 1, # required # obd_standard: "ObdStandard", # pid_request_interval_seconds: 1, # dtc_request_interval_seconds: 1, # use_extended_ids: false, # has_transmission_ecu: false, # }, # vehicle_middleware: { # name: "VehicleMiddlewareName", # required # protocol_name: "ROS_2", # required, accepts ROS_2 # }, # }, # ], # network_interfaces_to_remove: ["InterfaceId"], # status: "ACTIVE", # accepts ACTIVE, DRAFT, INVALID, VALIDATING # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload update_decoder_manifest(params = {}) # @param [Hash] params ({}) def update_decoder_manifest(params = {}, options = {}) req = build_request(:update_decoder_manifest, params) req.send_request(options) end # Updates the description of an existing fleet. # # If the fleet is successfully updated, Amazon Web Services IoT # FleetWise sends back an HTTP 200 response with an empty HTTP body. # # # # @option params [required, String] :fleet_id # The ID of the fleet to update. # # @option params [String] :description # An updated description of the fleet. # # @return [Types::UpdateFleetResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::UpdateFleetResponse#id #id} => String # * {Types::UpdateFleetResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.update_fleet({ # fleet_id: "fleetId", # required # description: "description", # }) # # @example Response structure # # resp.id #=> String # resp.arn #=> String # # @overload update_fleet(params = {}) # @param [Hash] params ({}) def update_fleet(params = {}, options = {}) req = build_request(:update_fleet, params) req.send_request(options) end # Updates a vehicle model (model manifest). If created vehicles are # associated with a vehicle model, it can't be updated. # # @option params [required, String] :name # The name of the vehicle model to update. # # @option params [String] :description # A brief description of the vehicle model. # # @option params [Array] :nodes_to_add # A list of `fullyQualifiedName` of nodes, which are a general # abstraction of signals, to add to the vehicle model. # # @option params [Array] :nodes_to_remove # A list of `fullyQualifiedName` of nodes, which are a general # abstraction of signals, to remove from the vehicle model. # # @option params [String] :status # The state of the vehicle model. If the status is `ACTIVE`, the vehicle # model can't be edited. If the status is `DRAFT`, you can edit the # vehicle model. # # @return [Types::UpdateModelManifestResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::UpdateModelManifestResponse#name #name} => String # * {Types::UpdateModelManifestResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.update_model_manifest({ # name: "resourceName", # required # description: "description", # nodes_to_add: ["NodePath"], # nodes_to_remove: ["NodePath"], # status: "ACTIVE", # accepts ACTIVE, DRAFT, INVALID, VALIDATING # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload update_model_manifest(params = {}) # @param [Hash] params ({}) def update_model_manifest(params = {}, options = {}) req = build_request(:update_model_manifest, params) req.send_request(options) end # Updates a signal catalog. # # @option params [required, String] :name # The name of the signal catalog to update. # # @option params [String] :description # A brief description of the signal catalog to update. # # @option params [Array] :nodes_to_add # A list of information about nodes to add to the signal catalog. # # @option params [Array] :nodes_to_update # A list of information about nodes to update in the signal catalog. # # @option params [Array] :nodes_to_remove # A list of `fullyQualifiedName` of nodes to remove from the signal # catalog. # # @return [Types::UpdateSignalCatalogResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::UpdateSignalCatalogResponse#name #name} => String # * {Types::UpdateSignalCatalogResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.update_signal_catalog({ # name: "resourceName", # required # description: "description", # nodes_to_add: [ # { # branch: { # fully_qualified_name: "string", # required # description: "description", # deprecation_message: "message", # comment: "message", # }, # sensor: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # actuator: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # assigned_value: "string", # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # attribute: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # assigned_value: "string", # default_value: "string", # deprecation_message: "message", # comment: "message", # }, # struct: { # fully_qualified_name: "string", # required # description: "description", # deprecation_message: "message", # comment: "message", # }, # property: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # data_encoding: "BINARY", # accepts BINARY, TYPED # description: "description", # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # }, # ], # nodes_to_update: [ # { # branch: { # fully_qualified_name: "string", # required # description: "description", # deprecation_message: "message", # comment: "message", # }, # sensor: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # actuator: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # assigned_value: "string", # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # attribute: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # description: "description", # unit: "string", # allowed_values: ["string"], # min: 1.0, # max: 1.0, # assigned_value: "string", # default_value: "string", # deprecation_message: "message", # comment: "message", # }, # struct: { # fully_qualified_name: "string", # required # description: "description", # deprecation_message: "message", # comment: "message", # }, # property: { # fully_qualified_name: "string", # required # data_type: "INT8", # required, accepts INT8, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, BOOLEAN, FLOAT, DOUBLE, STRING, UNIX_TIMESTAMP, INT8_ARRAY, UINT8_ARRAY, INT16_ARRAY, UINT16_ARRAY, INT32_ARRAY, UINT32_ARRAY, INT64_ARRAY, UINT64_ARRAY, BOOLEAN_ARRAY, FLOAT_ARRAY, DOUBLE_ARRAY, STRING_ARRAY, UNIX_TIMESTAMP_ARRAY, UNKNOWN, STRUCT, STRUCT_ARRAY # data_encoding: "BINARY", # accepts BINARY, TYPED # description: "description", # deprecation_message: "message", # comment: "message", # struct_fully_qualified_name: "NodePath", # }, # }, # ], # nodes_to_remove: ["NodePath"], # }) # # @example Response structure # # resp.name #=> String # resp.arn #=> String # # @overload update_signal_catalog(params = {}) # @param [Hash] params ({}) def update_signal_catalog(params = {}, options = {}) req = build_request(:update_signal_catalog, params) req.send_request(options) end # Updates a vehicle. # # @option params [required, String] :vehicle_name # The unique ID of the vehicle to update. # # @option params [String] :model_manifest_arn # The ARN of a vehicle model (model manifest) associated with the # vehicle. # # @option params [String] :decoder_manifest_arn # The ARN of the decoder manifest associated with this vehicle. # # @option params [Hash] :attributes # Static information about a vehicle in a key-value pair. For example: # # `"engineType"` : `"1.3 L R2"` # # @option params [String] :attribute_update_mode # The method the specified attributes will update the existing # attributes on the vehicle. Use`Overwite` to replace the vehicle # attributes with the specified attributes. Or use `Merge` to combine # all attributes. # # This is required if attributes are present in the input. # # @return [Types::UpdateVehicleResponse] Returns a {Seahorse::Client::Response response} object which responds to the following methods: # # * {Types::UpdateVehicleResponse#vehicle_name #vehicle_name} => String # * {Types::UpdateVehicleResponse#arn #arn} => String # # @example Request syntax with placeholder values # # resp = client.update_vehicle({ # vehicle_name: "vehicleName", # required # model_manifest_arn: "arn", # decoder_manifest_arn: "arn", # attributes: { # "attributeName" => "attributeValue", # }, # attribute_update_mode: "Overwrite", # accepts Overwrite, Merge # }) # # @example Response structure # # resp.vehicle_name #=> String # resp.arn #=> String # # @overload update_vehicle(params = {}) # @param [Hash] params ({}) def update_vehicle(params = {}, options = {}) req = build_request(:update_vehicle, params) req.send_request(options) end # @!endgroup # @param params ({}) # @api private def build_request(operation_name, params = {}) handlers = @handlers.for(operation_name) context = Seahorse::Client::RequestContext.new( operation_name: operation_name, operation: config.api.operation(operation_name), client: self, params: params, config: config) context[:gem_name] = 'aws-sdk-iotfleetwise' context[:gem_version] = '1.26.0' Seahorse::Client::Request.new(handlers, context) end # @api private # @deprecated def waiter_names [] end class << self # @api private attr_reader :identifier # @api private def errors_module Errors end end end end