// Code generated by software.amazon.smithy.rust.codegen.smithy-rs. DO NOT EDIT.
pub use crate::operation::update_job_queue::_update_job_queue_output::UpdateJobQueueOutputBuilder;

pub use crate::operation::update_job_queue::_update_job_queue_input::UpdateJobQueueInputBuilder;

impl UpdateJobQueueInputBuilder {
    /// Sends a request with this input using the given client.
    pub async fn send_with(
        self,
        client: &crate::Client,
    ) -> ::std::result::Result<
        crate::operation::update_job_queue::UpdateJobQueueOutput,
        ::aws_smithy_runtime_api::client::result::SdkError<
            crate::operation::update_job_queue::UpdateJobQueueError,
            ::aws_smithy_runtime_api::client::orchestrator::HttpResponse,
        >,
    > {
        let mut fluent_builder = client.update_job_queue();
        fluent_builder.inner = self;
        fluent_builder.send().await
    }
}
/// Fluent builder constructing a request to `UpdateJobQueue`.
///
/// <p>Updates a job queue.</p>
#[derive(::std::clone::Clone, ::std::fmt::Debug)]
pub struct UpdateJobQueueFluentBuilder {
    handle: ::std::sync::Arc<crate::client::Handle>,
    inner: crate::operation::update_job_queue::builders::UpdateJobQueueInputBuilder,
    config_override: ::std::option::Option<crate::config::Builder>,
}
impl
    crate::client::customize::internal::CustomizableSend<
        crate::operation::update_job_queue::UpdateJobQueueOutput,
        crate::operation::update_job_queue::UpdateJobQueueError,
    > for UpdateJobQueueFluentBuilder
{
    fn send(
        self,
        config_override: crate::config::Builder,
    ) -> crate::client::customize::internal::BoxFuture<
        crate::client::customize::internal::SendResult<
            crate::operation::update_job_queue::UpdateJobQueueOutput,
            crate::operation::update_job_queue::UpdateJobQueueError,
        >,
    > {
        ::std::boxed::Box::pin(async move { self.config_override(config_override).send().await })
    }
}
impl UpdateJobQueueFluentBuilder {
    /// Creates a new `UpdateJobQueue`.
    pub(crate) fn new(handle: ::std::sync::Arc<crate::client::Handle>) -> Self {
        Self {
            handle,
            inner: ::std::default::Default::default(),
            config_override: ::std::option::Option::None,
        }
    }
    /// Access the UpdateJobQueue as a reference.
    pub fn as_input(&self) -> &crate::operation::update_job_queue::builders::UpdateJobQueueInputBuilder {
        &self.inner
    }
    /// 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::operation::update_job_queue::UpdateJobQueueOutput,
        ::aws_smithy_runtime_api::client::result::SdkError<
            crate::operation::update_job_queue::UpdateJobQueueError,
            ::aws_smithy_runtime_api::client::orchestrator::HttpResponse,
        >,
    > {
        let input = self
            .inner
            .build()
            .map_err(::aws_smithy_runtime_api::client::result::SdkError::construction_failure)?;
        let runtime_plugins = crate::operation::update_job_queue::UpdateJobQueue::operation_runtime_plugins(
            self.handle.runtime_plugins.clone(),
            &self.handle.conf,
            self.config_override,
        );
        crate::operation::update_job_queue::UpdateJobQueue::orchestrate(&runtime_plugins, input).await
    }

    /// Consumes this builder, creating a customizable operation that can be modified before being sent.
    pub fn customize(
        self,
    ) -> crate::client::customize::CustomizableOperation<
        crate::operation::update_job_queue::UpdateJobQueueOutput,
        crate::operation::update_job_queue::UpdateJobQueueError,
        Self,
    > {
        crate::client::customize::CustomizableOperation::new(self)
    }
    pub(crate) fn config_override(mut self, config_override: impl Into<crate::config::Builder>) -> Self {
        self.set_config_override(Some(config_override.into()));
        self
    }

    pub(crate) fn set_config_override(&mut self, config_override: Option<crate::config::Builder>) -> &mut Self {
        self.config_override = config_override;
        self
    }
    /// <p>The name or the Amazon Resource Name (ARN) of the job queue.</p>
    pub fn job_queue(mut self, input: impl ::std::convert::Into<::std::string::String>) -> Self {
        self.inner = self.inner.job_queue(input.into());
        self
    }
    /// <p>The name or the Amazon Resource Name (ARN) of the job queue.</p>
    pub fn set_job_queue(mut self, input: ::std::option::Option<::std::string::String>) -> Self {
        self.inner = self.inner.set_job_queue(input);
        self
    }
    /// <p>The name or the Amazon Resource Name (ARN) of the job queue.</p>
    pub fn get_job_queue(&self) -> &::std::option::Option<::std::string::String> {
        self.inner.get_job_queue()
    }
    /// <p>Describes the queue's ability to accept new jobs. If the job queue state is <code>ENABLED</code>, it can accept jobs. If the job queue state is <code>DISABLED</code>, new jobs can't be added to the queue, but jobs already in the queue can finish.</p>
    pub fn state(mut self, input: crate::types::JqState) -> Self {
        self.inner = self.inner.state(input);
        self
    }
    /// <p>Describes the queue's ability to accept new jobs. If the job queue state is <code>ENABLED</code>, it can accept jobs. If the job queue state is <code>DISABLED</code>, new jobs can't be added to the queue, but jobs already in the queue can finish.</p>
    pub fn set_state(mut self, input: ::std::option::Option<crate::types::JqState>) -> Self {
        self.inner = self.inner.set_state(input);
        self
    }
    /// <p>Describes the queue's ability to accept new jobs. If the job queue state is <code>ENABLED</code>, it can accept jobs. If the job queue state is <code>DISABLED</code>, new jobs can't be added to the queue, but jobs already in the queue can finish.</p>
    pub fn get_state(&self) -> &::std::option::Option<crate::types::JqState> {
        self.inner.get_state()
    }
    /// <p>Amazon Resource Name (ARN) of the fair share scheduling policy. Once a job queue is created, the fair share scheduling policy can be replaced but not removed. The format is <code>aws:<i>Partition</i>:batch:<i>Region</i>:<i>Account</i>:scheduling-policy/<i>Name</i> </code>. For example, <code>aws:aws:batch:us-west-2:123456789012:scheduling-policy/MySchedulingPolicy</code>.</p>
    pub fn scheduling_policy_arn(mut self, input: impl ::std::convert::Into<::std::string::String>) -> Self {
        self.inner = self.inner.scheduling_policy_arn(input.into());
        self
    }
    /// <p>Amazon Resource Name (ARN) of the fair share scheduling policy. Once a job queue is created, the fair share scheduling policy can be replaced but not removed. The format is <code>aws:<i>Partition</i>:batch:<i>Region</i>:<i>Account</i>:scheduling-policy/<i>Name</i> </code>. For example, <code>aws:aws:batch:us-west-2:123456789012:scheduling-policy/MySchedulingPolicy</code>.</p>
    pub fn set_scheduling_policy_arn(mut self, input: ::std::option::Option<::std::string::String>) -> Self {
        self.inner = self.inner.set_scheduling_policy_arn(input);
        self
    }
    /// <p>Amazon Resource Name (ARN) of the fair share scheduling policy. Once a job queue is created, the fair share scheduling policy can be replaced but not removed. The format is <code>aws:<i>Partition</i>:batch:<i>Region</i>:<i>Account</i>:scheduling-policy/<i>Name</i> </code>. For example, <code>aws:aws:batch:us-west-2:123456789012:scheduling-policy/MySchedulingPolicy</code>.</p>
    pub fn get_scheduling_policy_arn(&self) -> &::std::option::Option<::std::string::String> {
        self.inner.get_scheduling_policy_arn()
    }
    /// <p>The priority of the job queue. Job queues with a higher priority (or a higher integer value for the <code>priority</code> parameter) are evaluated first when associated with the same compute environment. Priority is determined in descending order. For example, a job queue with a priority value of <code>10</code> is given scheduling preference over a job queue with a priority value of <code>1</code>. All of the compute environments must be either EC2 (<code>EC2</code> or <code>SPOT</code>) or Fargate (<code>FARGATE</code> or <code>FARGATE_SPOT</code>). EC2 and Fargate compute environments can't be mixed.</p>
    pub fn priority(mut self, input: i32) -> Self {
        self.inner = self.inner.priority(input);
        self
    }
    /// <p>The priority of the job queue. Job queues with a higher priority (or a higher integer value for the <code>priority</code> parameter) are evaluated first when associated with the same compute environment. Priority is determined in descending order. For example, a job queue with a priority value of <code>10</code> is given scheduling preference over a job queue with a priority value of <code>1</code>. All of the compute environments must be either EC2 (<code>EC2</code> or <code>SPOT</code>) or Fargate (<code>FARGATE</code> or <code>FARGATE_SPOT</code>). EC2 and Fargate compute environments can't be mixed.</p>
    pub fn set_priority(mut self, input: ::std::option::Option<i32>) -> Self {
        self.inner = self.inner.set_priority(input);
        self
    }
    /// <p>The priority of the job queue. Job queues with a higher priority (or a higher integer value for the <code>priority</code> parameter) are evaluated first when associated with the same compute environment. Priority is determined in descending order. For example, a job queue with a priority value of <code>10</code> is given scheduling preference over a job queue with a priority value of <code>1</code>. All of the compute environments must be either EC2 (<code>EC2</code> or <code>SPOT</code>) or Fargate (<code>FARGATE</code> or <code>FARGATE_SPOT</code>). EC2 and Fargate compute environments can't be mixed.</p>
    pub fn get_priority(&self) -> &::std::option::Option<i32> {
        self.inner.get_priority()
    }
    /// Appends an item to `computeEnvironmentOrder`.
    ///
    /// To override the contents of this collection use [`set_compute_environment_order`](Self::set_compute_environment_order).
    ///
    /// <p>Details the set of compute environments mapped to a job queue and their order relative to each other. This is one of the parameters used by the job scheduler to determine which compute environment runs a given job. Compute environments must be in the <code>VALID</code> state before you can associate them with a job queue. All of the compute environments must be either EC2 (<code>EC2</code> or <code>SPOT</code>) or Fargate (<code>FARGATE</code> or <code>FARGATE_SPOT</code>). EC2 and Fargate compute environments can't be mixed.</p> <note>
    /// <p>All compute environments that are associated with a job queue must share the same architecture. Batch doesn't support mixing compute environment architecture types in a single job queue.</p>
    /// </note>
    pub fn compute_environment_order(mut self, input: crate::types::ComputeEnvironmentOrder) -> Self {
        self.inner = self.inner.compute_environment_order(input);
        self
    }
    /// <p>Details the set of compute environments mapped to a job queue and their order relative to each other. This is one of the parameters used by the job scheduler to determine which compute environment runs a given job. Compute environments must be in the <code>VALID</code> state before you can associate them with a job queue. All of the compute environments must be either EC2 (<code>EC2</code> or <code>SPOT</code>) or Fargate (<code>FARGATE</code> or <code>FARGATE_SPOT</code>). EC2 and Fargate compute environments can't be mixed.</p> <note>
    /// <p>All compute environments that are associated with a job queue must share the same architecture. Batch doesn't support mixing compute environment architecture types in a single job queue.</p>
    /// </note>
    pub fn set_compute_environment_order(mut self, input: ::std::option::Option<::std::vec::Vec<crate::types::ComputeEnvironmentOrder>>) -> Self {
        self.inner = self.inner.set_compute_environment_order(input);
        self
    }
    /// <p>Details the set of compute environments mapped to a job queue and their order relative to each other. This is one of the parameters used by the job scheduler to determine which compute environment runs a given job. Compute environments must be in the <code>VALID</code> state before you can associate them with a job queue. All of the compute environments must be either EC2 (<code>EC2</code> or <code>SPOT</code>) or Fargate (<code>FARGATE</code> or <code>FARGATE_SPOT</code>). EC2 and Fargate compute environments can't be mixed.</p> <note>
    /// <p>All compute environments that are associated with a job queue must share the same architecture. Batch doesn't support mixing compute environment architecture types in a single job queue.</p>
    /// </note>
    pub fn get_compute_environment_order(&self) -> &::std::option::Option<::std::vec::Vec<crate::types::ComputeEnvironmentOrder>> {
        self.inner.get_compute_environment_order()
    }
}