Struct aws_sdk_autoscaling::input::create_launch_configuration_input::Builder

pub struct Builder { /* private fields */ }

A builder for CreateLaunchConfigurationInput.

Implementations

impl Builder

pub fn launch_configuration_name(self, input: impl Into<String>) -> Self

The name of the launch configuration. This name must be unique per Region per account.

Examples found in repository

src/client.rs (line 2153)

        pub fn launch_configuration_name(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.launch_configuration_name(input.into());
            self
        }

pub fn set_launch_configuration_name(self, input: Option<String>) -> Self

The name of the launch configuration. This name must be unique per Region per account.

Examples found in repository

src/client.rs (line 2161)

        pub fn set_launch_configuration_name(
            mut self,
            input: std::option::Option<std::string::String>,
        ) -> Self {
            self.inner = self.inner.set_launch_configuration_name(input);
            self
        }

pub fn image_id(self, input: impl Into<String>) -> Self

The ID of the Amazon Machine Image (AMI) that was assigned during registration. For more information, see Finding a Linux AMI in the Amazon EC2 User Guide for Linux Instances.

If you specify InstanceId, an ImageId is not required.

Examples found in repository

src/client.rs (line 2167)

        pub fn image_id(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.image_id(input.into());
            self
        }

pub fn set_image_id(self, input: Option<String>) -> Self

The ID of the Amazon Machine Image (AMI) that was assigned during registration. For more information, see Finding a Linux AMI in the Amazon EC2 User Guide for Linux Instances.

If you specify InstanceId, an ImageId is not required.

Examples found in repository

src/client.rs (line 2173)

        pub fn set_image_id(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_image_id(input);
            self
        }

pub fn key_name(self, input: impl Into<String>) -> Self

The name of the key pair. For more information, see Amazon EC2 key pairs and Linux instances in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2178)

        pub fn key_name(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.key_name(input.into());
            self
        }

pub fn set_key_name(self, input: Option<String>) -> Self

The name of the key pair. For more information, see Amazon EC2 key pairs and Linux instances in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2183)

        pub fn set_key_name(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_key_name(input);
            self
        }

pub fn security_groups(self, input: impl Into<String>) -> Self

Appends an item to security_groups.

To override the contents of this collection use set_security_groups.

A list that contains the security group IDs to assign to the instances in the Auto Scaling group. For more information, see Control traffic to resources using security groups in the Amazon Virtual Private Cloud User Guide.

Examples found in repository

src/client.rs (line 2192)

        pub fn security_groups(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.security_groups(input.into());
            self
        }

pub fn set_security_groups(self, input: Option<Vec<String>>) -> Self

A list that contains the security group IDs to assign to the instances in the Auto Scaling group. For more information, see Control traffic to resources using security groups in the Amazon Virtual Private Cloud User Guide.

Examples found in repository

src/client.rs (line 2200)

        pub fn set_security_groups(
            mut self,
            input: std::option::Option<std::vec::Vec<std::string::String>>,
        ) -> Self {
            self.inner = self.inner.set_security_groups(input);
            self
        }

pub fn classic_link_vpc_id(self, input: impl Into<String>) -> Self

EC2-Classic retires on August 15, 2022. This property is not supported after that date.

The ID of a ClassicLink-enabled VPC to link your EC2-Classic instances to. For more information, see ClassicLink in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2206)

        pub fn classic_link_vpc_id(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.classic_link_vpc_id(input.into());
            self
        }

pub fn set_classic_link_vpc_id(self, input: Option<String>) -> Self

EC2-Classic retires on August 15, 2022. This property is not supported after that date.

The ID of a ClassicLink-enabled VPC to link your EC2-Classic instances to. For more information, see ClassicLink in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2215)

        pub fn set_classic_link_vpc_id(
            mut self,
            input: std::option::Option<std::string::String>,
        ) -> Self {
            self.inner = self.inner.set_classic_link_vpc_id(input);
            self
        }

pub fn classic_link_vpc_security_groups(self, input: impl Into<String>) -> Self

Appends an item to classic_link_vpc_security_groups.

To override the contents of this collection use set_classic_link_vpc_security_groups.

EC2-Classic retires on August 15, 2022. This property is not supported after that date.

The IDs of one or more security groups for the specified ClassicLink-enabled VPC.

If you specify the ClassicLinkVPCId property, you must specify ClassicLinkVPCSecurityGroups.

Examples found in repository

src/client.rs (line 2229)

        pub fn classic_link_vpc_security_groups(
            mut self,
            input: impl Into<std::string::String>,
        ) -> Self {
            self.inner = self.inner.classic_link_vpc_security_groups(input.into());
            self
        }

pub fn set_classic_link_vpc_security_groups(
    self,
    input: Option<Vec<String>>
) -> Self

EC2-Classic retires on August 15, 2022. This property is not supported after that date.

The IDs of one or more security groups for the specified ClassicLink-enabled VPC.

If you specify the ClassicLinkVPCId property, you must specify ClassicLinkVPCSecurityGroups.

Examples found in repository

src/client.rs (line 2239)

        pub fn set_classic_link_vpc_security_groups(
            mut self,
            input: std::option::Option<std::vec::Vec<std::string::String>>,
        ) -> Self {
            self.inner = self.inner.set_classic_link_vpc_security_groups(input);
            self
        }

pub fn user_data(self, input: impl Into<String>) -> Self

The user data to make available to the launched EC2 instances. For more information, see Instance metadata and user data (Linux) and Instance metadata and user data (Windows). If you are using a command line tool, base64-encoding is performed for you, and you can load the text from a file. Otherwise, you must provide base64-encoded text. User data is limited to 16 KB.

Examples found in repository

src/client.rs (line 2244)

        pub fn user_data(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.user_data(input.into());
            self
        }

pub fn set_user_data(self, input: Option<String>) -> Self

The user data to make available to the launched EC2 instances. For more information, see Instance metadata and user data (Linux) and Instance metadata and user data (Windows). If you are using a command line tool, base64-encoding is performed for you, and you can load the text from a file. Otherwise, you must provide base64-encoded text. User data is limited to 16 KB.

Examples found in repository

src/client.rs (line 2249)

        pub fn set_user_data(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_user_data(input);
            self
        }

pub fn instance_id(self, input: impl Into<String>) -> Self

The ID of the instance to use to create the launch configuration. The new launch configuration derives attributes from the instance, except for the block device mapping.

To create a launch configuration with a block device mapping or override any other instance attributes, specify them as part of the same request.

For more information, see Creating a launch configuration using an EC2 instance in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2256)

        pub fn instance_id(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.instance_id(input.into());
            self
        }

pub fn set_instance_id(self, input: Option<String>) -> Self

The ID of the instance to use to create the launch configuration. The new launch configuration derives attributes from the instance, except for the block device mapping.

To create a launch configuration with a block device mapping or override any other instance attributes, specify them as part of the same request.

For more information, see Creating a launch configuration using an EC2 instance in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2263)

        pub fn set_instance_id(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_instance_id(input);
            self
        }

pub fn instance_type(self, input: impl Into<String>) -> Self

Specifies the instance type of the EC2 instance. For information about available instance types, see Available instance types in the Amazon EC2 User Guide for Linux Instances.

If you specify InstanceId, an InstanceType is not required.

Examples found in repository

src/client.rs (line 2269)

        pub fn instance_type(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.instance_type(input.into());
            self
        }

pub fn set_instance_type(self, input: Option<String>) -> Self

Specifies the instance type of the EC2 instance. For information about available instance types, see Available instance types in the Amazon EC2 User Guide for Linux Instances.

If you specify InstanceId, an InstanceType is not required.

Examples found in repository

src/client.rs (line 2278)

        pub fn set_instance_type(
            mut self,
            input: std::option::Option<std::string::String>,
        ) -> Self {
            self.inner = self.inner.set_instance_type(input);
            self
        }

pub fn kernel_id(self, input: impl Into<String>) -> Self

The ID of the kernel associated with the AMI.

We recommend that you use PV-GRUB instead of kernels and RAM disks. For more information, see User provided kernels in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2285)

        pub fn kernel_id(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.kernel_id(input.into());
            self
        }

pub fn set_kernel_id(self, input: Option<String>) -> Self

The ID of the kernel associated with the AMI.

We recommend that you use PV-GRUB instead of kernels and RAM disks. For more information, see User provided kernels in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2292)

        pub fn set_kernel_id(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_kernel_id(input);
            self
        }

pub fn ramdisk_id(self, input: impl Into<String>) -> Self

The ID of the RAM disk to select.

We recommend that you use PV-GRUB instead of kernels and RAM disks. For more information, see User provided kernels in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2299)

        pub fn ramdisk_id(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.ramdisk_id(input.into());
            self
        }

pub fn set_ramdisk_id(self, input: Option<String>) -> Self

The ID of the RAM disk to select.

We recommend that you use PV-GRUB instead of kernels and RAM disks. For more information, see User provided kernels in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2306)

        pub fn set_ramdisk_id(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_ramdisk_id(input);
            self
        }

pub fn block_device_mappings(self, input: BlockDeviceMapping) -> Self

Appends an item to block_device_mappings.

To override the contents of this collection use set_block_device_mappings.

The block device mapping entries that define the block devices to attach to the instances at launch. By default, the block devices specified in the block device mapping for the AMI are used. For more information, see Block device mappings in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2315)

        pub fn block_device_mappings(mut self, input: crate::model::BlockDeviceMapping) -> Self {
            self.inner = self.inner.block_device_mappings(input);
            self
        }

pub fn set_block_device_mappings(
    self,
    input: Option<Vec<BlockDeviceMapping>>
) -> Self

The block device mapping entries that define the block devices to attach to the instances at launch. By default, the block devices specified in the block device mapping for the AMI are used. For more information, see Block device mappings in the Amazon EC2 User Guide for Linux Instances.

Examples found in repository

src/client.rs (line 2323)

        pub fn set_block_device_mappings(
            mut self,
            input: std::option::Option<std::vec::Vec<crate::model::BlockDeviceMapping>>,
        ) -> Self {
            self.inner = self.inner.set_block_device_mappings(input);
            self
        }

pub fn instance_monitoring(self, input: InstanceMonitoring) -> Self

Controls whether instances in this group are launched with detailed (true) or basic (false) monitoring.

The default value is true (enabled).

When detailed monitoring is enabled, Amazon CloudWatch generates metrics every minute and your account is charged a fee. When you disable detailed monitoring, CloudWatch generates metrics every 5 minutes. For more information, see Configure Monitoring for Auto Scaling Instances in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2331)

        pub fn instance_monitoring(mut self, input: crate::model::InstanceMonitoring) -> Self {
            self.inner = self.inner.instance_monitoring(input);
            self
        }

pub fn set_instance_monitoring(self, input: Option<InstanceMonitoring>) -> Self

Controls whether instances in this group are launched with detailed (true) or basic (false) monitoring.

The default value is true (enabled).

When detailed monitoring is enabled, Amazon CloudWatch generates metrics every minute and your account is charged a fee. When you disable detailed monitoring, CloudWatch generates metrics every 5 minutes. For more information, see Configure Monitoring for Auto Scaling Instances in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2342)

        pub fn set_instance_monitoring(
            mut self,
            input: std::option::Option<crate::model::InstanceMonitoring>,
        ) -> Self {
            self.inner = self.inner.set_instance_monitoring(input);
            self
        }

pub fn spot_price(self, input: impl Into<String>) -> Self

The maximum hourly price to be paid for any Spot Instance launched to fulfill the request. Spot Instances are launched when the price you specify exceeds the current Spot price. For more information, see Request Spot Instances for fault-tolerant and flexible applications in the Amazon EC2 Auto Scaling User Guide.

Valid Range: Minimum value of 0.001

When you change your maximum price by creating a new launch configuration, running instances will continue to run as long as the maximum price for those running instances is higher than the current Spot price.

Examples found in repository

src/client.rs (line 2350)

        pub fn spot_price(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.spot_price(input.into());
            self
        }

pub fn set_spot_price(self, input: Option<String>) -> Self

The maximum hourly price to be paid for any Spot Instance launched to fulfill the request. Spot Instances are launched when the price you specify exceeds the current Spot price. For more information, see Request Spot Instances for fault-tolerant and flexible applications in the Amazon EC2 Auto Scaling User Guide.

Valid Range: Minimum value of 0.001

When you change your maximum price by creating a new launch configuration, running instances will continue to run as long as the maximum price for those running instances is higher than the current Spot price.

Examples found in repository

src/client.rs (line 2358)

        pub fn set_spot_price(mut self, input: std::option::Option<std::string::String>) -> Self {
            self.inner = self.inner.set_spot_price(input);
            self
        }

pub fn iam_instance_profile(self, input: impl Into<String>) -> Self

The name or the Amazon Resource Name (ARN) of the instance profile associated with the IAM role for the instance. The instance profile contains the IAM role. For more information, see IAM role for applications that run on Amazon EC2 instances in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2363)

        pub fn iam_instance_profile(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.iam_instance_profile(input.into());
            self
        }

pub fn set_iam_instance_profile(self, input: Option<String>) -> Self

The name or the Amazon Resource Name (ARN) of the instance profile associated with the IAM role for the instance. The instance profile contains the IAM role. For more information, see IAM role for applications that run on Amazon EC2 instances in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2371)

        pub fn set_iam_instance_profile(
            mut self,
            input: std::option::Option<std::string::String>,
        ) -> Self {
            self.inner = self.inner.set_iam_instance_profile(input);
            self
        }

pub fn ebs_optimized(self, input: bool) -> Self

Specifies whether the launch configuration is optimized for EBS I/O (true) or not (false). The optimization provides dedicated throughput to Amazon EBS and an optimized configuration stack to provide optimal I/O performance. This optimization is not available with all instance types. Additional fees are incurred when you enable EBS optimization for an instance type that is not EBS-optimized by default. For more information, see Amazon EBS-optimized instances in the Amazon EC2 User Guide for Linux Instances.

The default value is false.

Examples found in repository

src/client.rs (line 2377)

        pub fn ebs_optimized(mut self, input: bool) -> Self {
            self.inner = self.inner.ebs_optimized(input);
            self
        }

pub fn set_ebs_optimized(self, input: Option<bool>) -> Self

Specifies whether the launch configuration is optimized for EBS I/O (true) or not (false). The optimization provides dedicated throughput to Amazon EBS and an optimized configuration stack to provide optimal I/O performance. This optimization is not available with all instance types. Additional fees are incurred when you enable EBS optimization for an instance type that is not EBS-optimized by default. For more information, see Amazon EBS-optimized instances in the Amazon EC2 User Guide for Linux Instances.

The default value is false.

Examples found in repository

src/client.rs (line 2383)

        pub fn set_ebs_optimized(mut self, input: std::option::Option<bool>) -> Self {
            self.inner = self.inner.set_ebs_optimized(input);
            self
        }

pub fn associate_public_ip_address(self, input: bool) -> Self

Specifies whether to assign a public IPv4 address to the group's instances. If the instance is launched into a default subnet, the default is to assign a public IPv4 address, unless you disabled the option to assign a public IPv4 address on the subnet. If the instance is launched into a nondefault subnet, the default is not to assign a public IPv4 address, unless you enabled the option to assign a public IPv4 address on the subnet.

If you specify true, each instance in the Auto Scaling group receives a unique public IPv4 address. For more information, see Launching Auto Scaling instances in a VPC in the Amazon EC2 Auto Scaling User Guide.

If you specify this property, you must specify at least one subnet for VPCZoneIdentifier when you create your group.

Examples found in repository

src/client.rs (line 2390)

        pub fn associate_public_ip_address(mut self, input: bool) -> Self {
            self.inner = self.inner.associate_public_ip_address(input);
            self
        }

pub fn set_associate_public_ip_address(self, input: Option<bool>) -> Self

Specifies whether to assign a public IPv4 address to the group's instances. If the instance is launched into a default subnet, the default is to assign a public IPv4 address, unless you disabled the option to assign a public IPv4 address on the subnet. If the instance is launched into a nondefault subnet, the default is not to assign a public IPv4 address, unless you enabled the option to assign a public IPv4 address on the subnet.

If you specify true, each instance in the Auto Scaling group receives a unique public IPv4 address. For more information, see Launching Auto Scaling instances in a VPC in the Amazon EC2 Auto Scaling User Guide.

If you specify this property, you must specify at least one subnet for VPCZoneIdentifier when you create your group.

Examples found in repository

src/client.rs (line 2397)

        pub fn set_associate_public_ip_address(mut self, input: std::option::Option<bool>) -> Self {
            self.inner = self.inner.set_associate_public_ip_address(input);
            self
        }

pub fn placement_tenancy(self, input: impl Into<String>) -> Self

The tenancy of the instance, either default or dedicated. An instance with dedicated tenancy runs on isolated, single-tenant hardware and can only be launched into a VPC. To launch dedicated instances into a shared tenancy VPC (a VPC with the instance placement tenancy attribute set to default), you must set the value of this property to dedicated. For more information, see Configuring instance tenancy with Amazon EC2 Auto Scaling in the Amazon EC2 Auto Scaling User Guide.

If you specify PlacementTenancy, you must specify at least one subnet for VPCZoneIdentifier when you create your group.

Valid values: default | dedicated

Examples found in repository

src/client.rs (line 2404)

        pub fn placement_tenancy(mut self, input: impl Into<std::string::String>) -> Self {
            self.inner = self.inner.placement_tenancy(input.into());
            self
        }

pub fn set_placement_tenancy(self, input: Option<String>) -> Self

The tenancy of the instance, either default or dedicated. An instance with dedicated tenancy runs on isolated, single-tenant hardware and can only be launched into a VPC. To launch dedicated instances into a shared tenancy VPC (a VPC with the instance placement tenancy attribute set to default), you must set the value of this property to dedicated. For more information, see Configuring instance tenancy with Amazon EC2 Auto Scaling in the Amazon EC2 Auto Scaling User Guide.

If you specify PlacementTenancy, you must specify at least one subnet for VPCZoneIdentifier when you create your group.

Valid values: default | dedicated

Examples found in repository

src/client.rs (line 2414)

        pub fn set_placement_tenancy(
            mut self,
            input: std::option::Option<std::string::String>,
        ) -> Self {
            self.inner = self.inner.set_placement_tenancy(input);
            self
        }

pub fn metadata_options(self, input: InstanceMetadataOptions) -> Self

The metadata options for the instances. For more information, see Configuring the Instance Metadata Options in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2419)

        pub fn metadata_options(mut self, input: crate::model::InstanceMetadataOptions) -> Self {
            self.inner = self.inner.metadata_options(input);
            self
        }

pub fn set_metadata_options(self, input: Option<InstanceMetadataOptions>) -> Self

The metadata options for the instances. For more information, see Configuring the Instance Metadata Options in the Amazon EC2 Auto Scaling User Guide.

Examples found in repository

src/client.rs (line 2427)

        pub fn set_metadata_options(
            mut self,
            input: std::option::Option<crate::model::InstanceMetadataOptions>,
        ) -> Self {
            self.inner = self.inner.set_metadata_options(input);
            self
        }

pub fn build(self) -> Result<CreateLaunchConfigurationInput, BuildError>

Consumes the builder and constructs a CreateLaunchConfigurationInput.

Examples found in repository

src/client.rs (line 2120)

        pub async fn customize(
            self,
        ) -> std::result::Result<
            crate::operation::customize::CustomizableOperation<
                crate::operation::CreateLaunchConfiguration,
                aws_http::retry::AwsResponseRetryClassifier,
            >,
            aws_smithy_http::result::SdkError<crate::error::CreateLaunchConfigurationError>,
        > {
            let handle = self.handle.clone();
            let operation = self
                .inner
                .build()
                .map_err(aws_smithy_http::result::SdkError::construction_failure)?
                .make_operation(&handle.conf)
                .await
                .map_err(aws_smithy_http::result::SdkError::construction_failure)?;
            Ok(crate::operation::customize::CustomizableOperation { handle, operation })
        }

        /// Sends the request and returns the response.
        ///
        /// If an error occurs, an `SdkError` will be returned with additional details that
        /// can be matched against.
        ///
        /// By default, any retryable failures will be retried twice. Retry behavior
        /// is configurable with the [RetryConfig](aws_smithy_types::retry::RetryConfig), which can be
        /// set when configuring the client.
        pub async fn send(
            self,
        ) -> std::result::Result<
            crate::output::CreateLaunchConfigurationOutput,
            aws_smithy_http::result::SdkError<crate::error::CreateLaunchConfigurationError>,
        > {
            let op = self
                .inner
                .build()
                .map_err(aws_smithy_http::result::SdkError::construction_failure)?
                .make_operation(&self.handle.conf)
                .await
                .map_err(aws_smithy_http::result::SdkError::construction_failure)?;
            self.handle.client.call(op).await
        }

Trait Implementations

impl Clone for Builder

fn clone(&self) -> Builder

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl Debug for Builder

fn fmt(&self, f: &mut Formatter<'_>) -> Result

Formats the value using the given formatter.

impl Default for Builder

fn default() -> Builder

Returns the “default value” for a type.

impl PartialEq<Builder> for Builder

fn eq(&self, other: &Builder) -> bool

This method tests for self and other values to be equal, and is used by ==.

fn ne(&self, other: &Rhs) -> bool

This method tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.

impl StructuralPartialEq for Builder