use std::collections::HashMap; use std::cell::RefCell; use std::default::Default; use std::collections::BTreeMap; use serde_json as json; use std::io; use std::fs; use std::mem; use std::thread::sleep; use crate::client; // ############## // UTILITIES ### // ############ /// Identifies the an OAuth2 authorization scope. /// A scope is needed when requesting an /// [authorization token](https://developers.google.com/youtube/v3/guides/authentication). #[derive(PartialEq, Eq, Hash)] pub enum Scope { /// Manage your Tasks and Taskqueues Full, /// Consume Tasks from your Taskqueues Consumer, } impl AsRef for Scope { fn as_ref(&self) -> &str { match *self { Scope::Full => "https://www.googleapis.com/auth/taskqueue", Scope::Consumer => "https://www.googleapis.com/auth/taskqueue.consumer", } } } impl Default for Scope { fn default() -> Scope { Scope::Full } } // ######## // HUB ### // ###### /// Central instance to access all Taskqueue related resource activities /// /// # Examples /// /// Instantiate a new hub /// /// ```test_harness,no_run /// extern crate hyper; /// extern crate hyper_rustls; /// extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// use taskqueue1_beta2::{Result, Error}; /// # async fn dox() { /// use std::default::Default; /// use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// // Get an ApplicationSecret instance by some means. It contains the `client_id` and /// // `client_secret`, among other things. /// let secret: oauth2::ApplicationSecret = Default::default(); /// // Instantiate the authenticator. It will choose a suitable authentication flow for you, /// // unless you replace `None` with the desired Flow. /// // Provide your own `AuthenticatorDelegate` to adjust the way it operates and get feedback about /// // what's going on. You probably want to bring in your own `TokenStorage` to persist tokens and /// // retrieve them from storage. /// let auth = oauth2::InstalledFlowAuthenticator::builder( /// secret, /// oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// ).build().await.unwrap(); /// let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().lease("project", "taskqueue", -75, -4) /// .tag("ea") /// .group_by_tag(true) /// .doit().await; /// /// match result { /// Err(e) => match e { /// // The Error enum provides details about what exactly happened. /// // You can also just use its `Debug`, `Display` or `Error` traits /// Error::HttpError(_) /// |Error::Io(_) /// |Error::MissingAPIKey /// |Error::MissingToken(_) /// |Error::Cancelled /// |Error::UploadSizeLimitExceeded(_, _) /// |Error::Failure(_) /// |Error::BadRequest(_) /// |Error::FieldClash(_) /// |Error::JsonDecodeError(_, _) => println!("{}", e), /// }, /// Ok(res) => println!("Success: {:?}", res), /// } /// # } /// ``` #[derive(Clone)] pub struct Taskqueue<> { pub client: hyper::Client, hyper::body::Body>, pub auth: oauth2::authenticator::Authenticator>, _user_agent: String, _base_url: String, _root_url: String, } impl<'a, > client::Hub for Taskqueue<> {} impl<'a, > Taskqueue<> { pub fn new(client: hyper::Client, hyper::body::Body>, authenticator: oauth2::authenticator::Authenticator>) -> Taskqueue<> { Taskqueue { client, auth: authenticator, _user_agent: "google-api-rust-client/3.1.0".to_string(), _base_url: "https://www.googleapis.com/taskqueue/v1beta2/projects/".to_string(), _root_url: "https://www.googleapis.com/".to_string(), } } pub fn taskqueues(&'a self) -> TaskqueueMethods<'a> { TaskqueueMethods { hub: &self } } pub fn tasks(&'a self) -> TaskMethods<'a> { TaskMethods { hub: &self } } /// Set the user-agent header field to use in all requests to the server. /// It defaults to `google-api-rust-client/3.1.0`. /// /// Returns the previously set user-agent. pub fn user_agent(&mut self, agent_name: String) -> String { mem::replace(&mut self._user_agent, agent_name) } /// Set the base url to use in all requests to the server. /// It defaults to `https://www.googleapis.com/taskqueue/v1beta2/projects/`. /// /// Returns the previously set base url. pub fn base_url(&mut self, new_base_url: String) -> String { mem::replace(&mut self._base_url, new_base_url) } /// Set the root url to use in all requests to the server. /// It defaults to `https://www.googleapis.com/`. /// /// Returns the previously set root url. pub fn root_url(&mut self, new_root_url: String) -> String { mem::replace(&mut self._root_url, new_root_url) } } // ############ // SCHEMAS ### // ########## /// There is no detailed description. /// /// # Activities /// /// This type is used in activities, which are methods you may call on this type or where this type is involved in. /// The list links the activity name, along with information about where it is used (one of *request* and *response*). /// /// * [delete tasks](TaskDeleteCall) (none) /// * [get tasks](TaskGetCall) (response) /// * [insert tasks](TaskInsertCall) (request|response) /// * [lease tasks](TaskLeaseCall) (none) /// * [list tasks](TaskListCall) (none) /// * [patch tasks](TaskPatchCall) (request|response) /// * [update tasks](TaskUpdateCall) (request|response) /// #[derive(Default, Clone, Debug, Serialize, Deserialize)] pub struct Task { /// Time (in seconds since the epoch) at which the task was enqueued. #[serde(rename="enqueueTimestamp")] pub enqueue_timestamp: Option, /// Name of the task. pub id: Option, /// The kind of object returned, in this case set to task. pub kind: Option, /// Time (in seconds since the epoch) at which the task lease will expire. This value is 0 if the task isnt currently leased out to a worker. #[serde(rename="leaseTimestamp")] pub lease_timestamp: Option, /// A bag of bytes which is the task payload. The payload on the JSON side is always Base64 encoded. #[serde(rename="payloadBase64")] pub payload_base64: Option, /// Name of the queue that the task is in. #[serde(rename="queueName")] pub queue_name: Option, /// The number of leases applied to this task. pub retry_count: Option, /// Tag for the task, could be used later to lease tasks grouped by a specific tag. pub tag: Option, } impl client::RequestValue for Task {} impl client::Resource for Task {} impl client::ResponseResult for Task {} /// There is no detailed description. /// /// # Activities /// /// This type is used in activities, which are methods you may call on this type or where this type is involved in. /// The list links the activity name, along with information about where it is used (one of *request* and *response*). /// /// * [get taskqueues](TaskqueueGetCall) (response) /// #[derive(Default, Clone, Debug, Serialize, Deserialize)] pub struct TaskQueue { /// ACLs that are applicable to this TaskQueue object. pub acl: Option, /// Name of the taskqueue. pub id: Option, /// The kind of REST object returned, in this case taskqueue. pub kind: Option, /// The number of times we should lease out tasks before giving up on them. If unset we lease them out forever until a worker deletes the task. #[serde(rename="maxLeases")] pub max_leases: Option, /// Statistics for the TaskQueue object in question. pub stats: Option, } impl client::Resource for TaskQueue {} impl client::ResponseResult for TaskQueue {} /// There is no detailed description. /// /// # Activities /// /// This type is used in activities, which are methods you may call on this type or where this type is involved in. /// The list links the activity name, along with information about where it is used (one of *request* and *response*). /// /// * [lease tasks](TaskLeaseCall) (response) /// #[derive(Default, Clone, Debug, Serialize, Deserialize)] pub struct Tasks { /// The actual list of tasks returned as a result of the lease operation. pub items: Option>, /// The kind of object returned, a list of tasks. pub kind: Option, } impl client::ResponseResult for Tasks {} /// There is no detailed description. /// /// # Activities /// /// This type is used in activities, which are methods you may call on this type or where this type is involved in. /// The list links the activity name, along with information about where it is used (one of *request* and *response*). /// /// * [list tasks](TaskListCall) (response) /// #[derive(Default, Clone, Debug, Serialize, Deserialize)] pub struct Tasks2 { /// The actual list of tasks currently active in the TaskQueue. pub items: Option>, /// The kind of object returned, a list of tasks. pub kind: Option, } impl client::ResponseResult for Tasks2 {} /// ACLs that are applicable to this TaskQueue object. /// /// This type is not used in any activity, and only used as *part* of another schema. /// #[derive(Default, Clone, Debug, Serialize, Deserialize)] pub struct TaskQueueAcl { /// Email addresses of users who are "admins" of the TaskQueue. This means they can control the queue, eg set ACLs for the queue. #[serde(rename="adminEmails")] pub admin_emails: Option>, /// Email addresses of users who can "consume" tasks from the TaskQueue. This means they can Dequeue and Delete tasks from the queue. #[serde(rename="consumerEmails")] pub consumer_emails: Option>, /// Email addresses of users who can "produce" tasks into the TaskQueue. This means they can Insert tasks into the queue. #[serde(rename="producerEmails")] pub producer_emails: Option>, } impl client::NestedType for TaskQueueAcl {} impl client::Part for TaskQueueAcl {} /// Statistics for the TaskQueue object in question. /// /// This type is not used in any activity, and only used as *part* of another schema. /// #[derive(Default, Clone, Debug, Serialize, Deserialize)] pub struct TaskQueueStats { /// Number of tasks leased in the last hour. #[serde(rename="leasedLastHour")] pub leased_last_hour: Option, /// Number of tasks leased in the last minute. #[serde(rename="leasedLastMinute")] pub leased_last_minute: Option, /// The timestamp (in seconds since the epoch) of the oldest unfinished task. #[serde(rename="oldestTask")] pub oldest_task: Option, /// Number of tasks in the queue. #[serde(rename="totalTasks")] pub total_tasks: Option, } impl client::NestedType for TaskQueueStats {} impl client::Part for TaskQueueStats {} // ################### // MethodBuilders ### // ################# /// A builder providing access to all methods supported on *taskqueue* resources. /// It is not used directly, but through the `Taskqueue` hub. /// /// # Example /// /// Instantiate a resource builder /// /// ```test_harness,no_run /// extern crate hyper; /// extern crate hyper_rustls; /// extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// /// # async fn dox() { /// use std::default::Default; /// use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// let secret: oauth2::ApplicationSecret = Default::default(); /// let auth = oauth2::InstalledFlowAuthenticator::builder( /// secret, /// oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// ).build().await.unwrap(); /// let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // Usually you wouldn't bind this to a variable, but keep calling *CallBuilders* /// // like `get(...)` /// // to build up your call. /// let rb = hub.taskqueues(); /// # } /// ``` pub struct TaskqueueMethods<'a> where { hub: &'a Taskqueue<>, } impl<'a> client::MethodsBuilder for TaskqueueMethods<'a> {} impl<'a> TaskqueueMethods<'a> { /// Create a builder to help you perform the following task: /// /// Get detailed information about a TaskQueue. /// /// # Arguments /// /// * `project` - The project under which the queue lies. /// * `taskqueue` - The id of the taskqueue to get the properties of. pub fn get(&self, project: &str, taskqueue: &str) -> TaskqueueGetCall<'a> { TaskqueueGetCall { hub: self.hub, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _get_stats: Default::default(), _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } } /// A builder providing access to all methods supported on *task* resources. /// It is not used directly, but through the `Taskqueue` hub. /// /// # Example /// /// Instantiate a resource builder /// /// ```test_harness,no_run /// extern crate hyper; /// extern crate hyper_rustls; /// extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// /// # async fn dox() { /// use std::default::Default; /// use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// let secret: oauth2::ApplicationSecret = Default::default(); /// let auth = oauth2::InstalledFlowAuthenticator::builder( /// secret, /// oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// ).build().await.unwrap(); /// let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // Usually you wouldn't bind this to a variable, but keep calling *CallBuilders* /// // like `delete(...)`, `get(...)`, `insert(...)`, `lease(...)`, `list(...)`, `patch(...)` and `update(...)` /// // to build up your call. /// let rb = hub.tasks(); /// # } /// ``` pub struct TaskMethods<'a> where { hub: &'a Taskqueue<>, } impl<'a> client::MethodsBuilder for TaskMethods<'a> {} impl<'a> TaskMethods<'a> { /// Create a builder to help you perform the following task: /// /// Delete a task from a TaskQueue. /// /// # Arguments /// /// * `project` - The project under which the queue lies. /// * `taskqueue` - The taskqueue to delete a task from. /// * `task` - The id of the task to delete. pub fn delete(&self, project: &str, taskqueue: &str, task: &str) -> TaskDeleteCall<'a> { TaskDeleteCall { hub: self.hub, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _task: task.to_string(), _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } /// Create a builder to help you perform the following task: /// /// Get a particular task from a TaskQueue. /// /// # Arguments /// /// * `project` - The project under which the queue lies. /// * `taskqueue` - The taskqueue in which the task belongs. /// * `task` - The task to get properties of. pub fn get(&self, project: &str, taskqueue: &str, task: &str) -> TaskGetCall<'a> { TaskGetCall { hub: self.hub, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _task: task.to_string(), _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } /// Create a builder to help you perform the following task: /// /// Insert a new task in a TaskQueue /// /// # Arguments /// /// * `request` - No description provided. /// * `project` - The project under which the queue lies /// * `taskqueue` - The taskqueue to insert the task into pub fn insert(&self, request: Task, project: &str, taskqueue: &str) -> TaskInsertCall<'a> { TaskInsertCall { hub: self.hub, _request: request, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } /// Create a builder to help you perform the following task: /// /// Lease 1 or more tasks from a TaskQueue. /// /// # Arguments /// /// * `project` - The project under which the queue lies. /// * `taskqueue` - The taskqueue to lease a task from. /// * `numTasks` - The number of tasks to lease. /// * `leaseSecs` - The lease in seconds. pub fn lease(&self, project: &str, taskqueue: &str, num_tasks: i32, lease_secs: i32) -> TaskLeaseCall<'a> { TaskLeaseCall { hub: self.hub, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _num_tasks: num_tasks, _lease_secs: lease_secs, _tag: Default::default(), _group_by_tag: Default::default(), _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } /// Create a builder to help you perform the following task: /// /// List Tasks in a TaskQueue /// /// # Arguments /// /// * `project` - The project under which the queue lies. /// * `taskqueue` - The id of the taskqueue to list tasks from. pub fn list(&self, project: &str, taskqueue: &str) -> TaskListCall<'a> { TaskListCall { hub: self.hub, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } /// Create a builder to help you perform the following task: /// /// Update tasks that are leased out of a TaskQueue. This method supports patch semantics. /// /// # Arguments /// /// * `request` - No description provided. /// * `project` - The project under which the queue lies. /// * `taskqueue` - No description provided. /// * `task` - No description provided. /// * `newLeaseSeconds` - The new lease in seconds. pub fn patch(&self, request: Task, project: &str, taskqueue: &str, task: &str, new_lease_seconds: i32) -> TaskPatchCall<'a> { TaskPatchCall { hub: self.hub, _request: request, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _task: task.to_string(), _new_lease_seconds: new_lease_seconds, _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } /// Create a builder to help you perform the following task: /// /// Update tasks that are leased out of a TaskQueue. /// /// # Arguments /// /// * `request` - No description provided. /// * `project` - The project under which the queue lies. /// * `taskqueue` - No description provided. /// * `task` - No description provided. /// * `newLeaseSeconds` - The new lease in seconds. pub fn update(&self, request: Task, project: &str, taskqueue: &str, task: &str, new_lease_seconds: i32) -> TaskUpdateCall<'a> { TaskUpdateCall { hub: self.hub, _request: request, _project: project.to_string(), _taskqueue: taskqueue.to_string(), _task: task.to_string(), _new_lease_seconds: new_lease_seconds, _delegate: Default::default(), _additional_params: Default::default(), _scopes: Default::default(), } } } // ################### // CallBuilders ### // ################# /// Get detailed information about a TaskQueue. /// /// A builder for the *get* method supported by a *taskqueue* resource. /// It is not used directly, but through a `TaskqueueMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.taskqueues().get("project", "taskqueue") /// .get_stats(true) /// .doit().await; /// # } /// ``` pub struct TaskqueueGetCall<'a> where { hub: &'a Taskqueue<>, _project: String, _taskqueue: String, _get_stats: Option, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskqueueGetCall<'a> {} impl<'a> TaskqueueGetCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, TaskQueue)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.taskqueues.get", http_method: hyper::Method::GET }); let mut params: Vec<(&str, String)> = Vec::with_capacity(5 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); if let Some(value) = self._get_stats { params.push(("getStats", value.to_string())); } for &field in ["alt", "project", "taskqueue", "getStats"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(2); for param_name in ["taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::GET).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .body(hyper::body::Body::empty()); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskqueueGetCall<'a> { self._project = new_value.to_string(); self } /// The id of the taskqueue to get the properties of. /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskqueueGetCall<'a> { self._taskqueue = new_value.to_string(); self } /// Whether to get stats. Optional. /// /// Sets the *get stats* query property to the given value. pub fn get_stats(mut self, new_value: bool) -> TaskqueueGetCall<'a> { self._get_stats = Some(new_value); self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskqueueGetCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskqueueGetCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskqueueGetCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// Delete a task from a TaskQueue. /// /// A builder for the *delete* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().delete("project", "taskqueue", "task") /// .doit().await; /// # } /// ``` pub struct TaskDeleteCall<'a> where { hub: &'a Taskqueue<>, _project: String, _taskqueue: String, _task: String, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskDeleteCall<'a> {} impl<'a> TaskDeleteCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.delete", http_method: hyper::Method::DELETE }); let mut params: Vec<(&str, String)> = Vec::with_capacity(4 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); params.push(("task", self._task.to_string())); for &field in ["project", "taskqueue", "task"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks/{task}"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue"), ("{task}", "task")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(3); for param_name in ["task", "taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::DELETE).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .body(hyper::body::Body::empty()); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = res; dlg.finished(true); return Ok(result_value) } } } } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskDeleteCall<'a> { self._project = new_value.to_string(); self } /// The taskqueue to delete a task from. /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskDeleteCall<'a> { self._taskqueue = new_value.to_string(); self } /// The id of the task to delete. /// /// Sets the *task* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn task(mut self, new_value: &str) -> TaskDeleteCall<'a> { self._task = new_value.to_string(); self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskDeleteCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskDeleteCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskDeleteCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// Get a particular task from a TaskQueue. /// /// A builder for the *get* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().get("project", "taskqueue", "task") /// .doit().await; /// # } /// ``` pub struct TaskGetCall<'a> where { hub: &'a Taskqueue<>, _project: String, _taskqueue: String, _task: String, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskGetCall<'a> {} impl<'a> TaskGetCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, Task)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.get", http_method: hyper::Method::GET }); let mut params: Vec<(&str, String)> = Vec::with_capacity(5 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); params.push(("task", self._task.to_string())); for &field in ["alt", "project", "taskqueue", "task"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks/{task}"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue"), ("{task}", "task")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(3); for param_name in ["task", "taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::GET).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .body(hyper::body::Body::empty()); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskGetCall<'a> { self._project = new_value.to_string(); self } /// The taskqueue in which the task belongs. /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskGetCall<'a> { self._taskqueue = new_value.to_string(); self } /// The task to get properties of. /// /// Sets the *task* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn task(mut self, new_value: &str) -> TaskGetCall<'a> { self._task = new_value.to_string(); self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskGetCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskGetCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskGetCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// Insert a new task in a TaskQueue /// /// A builder for the *insert* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// use taskqueue1_beta2::api::Task; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // As the method needs a request, you would usually fill it with the desired information /// // into the respective structure. Some of the parts shown here might not be applicable ! /// // Values shown here are possibly random and not representative ! /// let mut req = Task::default(); /// /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().insert(req, "project", "taskqueue") /// .doit().await; /// # } /// ``` pub struct TaskInsertCall<'a> where { hub: &'a Taskqueue<>, _request: Task, _project: String, _taskqueue: String, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskInsertCall<'a> {} impl<'a> TaskInsertCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, Task)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.insert", http_method: hyper::Method::POST }); let mut params: Vec<(&str, String)> = Vec::with_capacity(5 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); for &field in ["alt", "project", "taskqueue"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(2); for param_name in ["taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); let mut json_mime_type: mime::Mime = "application/json".parse().unwrap(); let mut request_value_reader = { let mut value = json::value::to_value(&self._request).expect("serde to work"); client::remove_json_null_values(&mut value); let mut dst = io::Cursor::new(Vec::with_capacity(128)); json::to_writer(&mut dst, &value).unwrap(); dst }; let request_size = request_value_reader.seek(io::SeekFrom::End(0)).unwrap(); request_value_reader.seek(io::SeekFrom::Start(0)).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; request_value_reader.seek(io::SeekFrom::Start(0)).unwrap(); let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::POST).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .header(CONTENT_TYPE, format!("{}", json_mime_type.to_string())) .header(CONTENT_LENGTH, request_size as u64) .body(hyper::body::Body::from(request_value_reader.get_ref().clone())); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// /// Sets the *request* property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn request(mut self, new_value: Task) -> TaskInsertCall<'a> { self._request = new_value; self } /// The project under which the queue lies /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskInsertCall<'a> { self._project = new_value.to_string(); self } /// The taskqueue to insert the task into /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskInsertCall<'a> { self._taskqueue = new_value.to_string(); self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskInsertCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskInsertCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskInsertCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// Lease 1 or more tasks from a TaskQueue. /// /// A builder for the *lease* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().lease("project", "taskqueue", -99, -56) /// .tag("eos") /// .group_by_tag(false) /// .doit().await; /// # } /// ``` pub struct TaskLeaseCall<'a> where { hub: &'a Taskqueue<>, _project: String, _taskqueue: String, _num_tasks: i32, _lease_secs: i32, _tag: Option, _group_by_tag: Option, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskLeaseCall<'a> {} impl<'a> TaskLeaseCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, Tasks)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.lease", http_method: hyper::Method::POST }); let mut params: Vec<(&str, String)> = Vec::with_capacity(8 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); params.push(("numTasks", self._num_tasks.to_string())); params.push(("leaseSecs", self._lease_secs.to_string())); if let Some(value) = self._tag { params.push(("tag", value.to_string())); } if let Some(value) = self._group_by_tag { params.push(("groupByTag", value.to_string())); } for &field in ["alt", "project", "taskqueue", "numTasks", "leaseSecs", "tag", "groupByTag"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks/lease"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(2); for param_name in ["taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::POST).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .body(hyper::body::Body::empty()); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskLeaseCall<'a> { self._project = new_value.to_string(); self } /// The taskqueue to lease a task from. /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskLeaseCall<'a> { self._taskqueue = new_value.to_string(); self } /// The number of tasks to lease. /// /// Sets the *num tasks* query property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn num_tasks(mut self, new_value: i32) -> TaskLeaseCall<'a> { self._num_tasks = new_value; self } /// The lease in seconds. /// /// Sets the *lease secs* query property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn lease_secs(mut self, new_value: i32) -> TaskLeaseCall<'a> { self._lease_secs = new_value; self } /// The tag allowed for tasks in the response. Must only be specified if group_by_tag is true. If group_by_tag is true and tag is not specified the tag will be that of the oldest task by eta, i.e. the first available tag /// /// Sets the *tag* query property to the given value. pub fn tag(mut self, new_value: &str) -> TaskLeaseCall<'a> { self._tag = Some(new_value.to_string()); self } /// When true, all returned tasks will have the same tag /// /// Sets the *group by tag* query property to the given value. pub fn group_by_tag(mut self, new_value: bool) -> TaskLeaseCall<'a> { self._group_by_tag = Some(new_value); self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskLeaseCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskLeaseCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskLeaseCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// List Tasks in a TaskQueue /// /// A builder for the *list* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().list("project", "taskqueue") /// .doit().await; /// # } /// ``` pub struct TaskListCall<'a> where { hub: &'a Taskqueue<>, _project: String, _taskqueue: String, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskListCall<'a> {} impl<'a> TaskListCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, Tasks2)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.list", http_method: hyper::Method::GET }); let mut params: Vec<(&str, String)> = Vec::with_capacity(4 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); for &field in ["alt", "project", "taskqueue"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(2); for param_name in ["taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::GET).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .body(hyper::body::Body::empty()); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskListCall<'a> { self._project = new_value.to_string(); self } /// The id of the taskqueue to list tasks from. /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskListCall<'a> { self._taskqueue = new_value.to_string(); self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskListCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskListCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskListCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// Update tasks that are leased out of a TaskQueue. This method supports patch semantics. /// /// A builder for the *patch* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// use taskqueue1_beta2::api::Task; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // As the method needs a request, you would usually fill it with the desired information /// // into the respective structure. Some of the parts shown here might not be applicable ! /// // Values shown here are possibly random and not representative ! /// let mut req = Task::default(); /// /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().patch(req, "project", "taskqueue", "task", -13) /// .doit().await; /// # } /// ``` pub struct TaskPatchCall<'a> where { hub: &'a Taskqueue<>, _request: Task, _project: String, _taskqueue: String, _task: String, _new_lease_seconds: i32, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskPatchCall<'a> {} impl<'a> TaskPatchCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, Task)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.patch", http_method: hyper::Method::PATCH }); let mut params: Vec<(&str, String)> = Vec::with_capacity(7 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); params.push(("task", self._task.to_string())); params.push(("newLeaseSeconds", self._new_lease_seconds.to_string())); for &field in ["alt", "project", "taskqueue", "task", "newLeaseSeconds"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks/{task}"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue"), ("{task}", "task")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(3); for param_name in ["task", "taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); let mut json_mime_type: mime::Mime = "application/json".parse().unwrap(); let mut request_value_reader = { let mut value = json::value::to_value(&self._request).expect("serde to work"); client::remove_json_null_values(&mut value); let mut dst = io::Cursor::new(Vec::with_capacity(128)); json::to_writer(&mut dst, &value).unwrap(); dst }; let request_size = request_value_reader.seek(io::SeekFrom::End(0)).unwrap(); request_value_reader.seek(io::SeekFrom::Start(0)).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; request_value_reader.seek(io::SeekFrom::Start(0)).unwrap(); let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::PATCH).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .header(CONTENT_TYPE, format!("{}", json_mime_type.to_string())) .header(CONTENT_LENGTH, request_size as u64) .body(hyper::body::Body::from(request_value_reader.get_ref().clone())); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// /// Sets the *request* property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn request(mut self, new_value: Task) -> TaskPatchCall<'a> { self._request = new_value; self } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskPatchCall<'a> { self._project = new_value.to_string(); self } /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskPatchCall<'a> { self._taskqueue = new_value.to_string(); self } /// /// Sets the *task* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn task(mut self, new_value: &str) -> TaskPatchCall<'a> { self._task = new_value.to_string(); self } /// The new lease in seconds. /// /// Sets the *new lease seconds* query property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn new_lease_seconds(mut self, new_value: i32) -> TaskPatchCall<'a> { self._new_lease_seconds = new_value; self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskPatchCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskPatchCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskPatchCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } } /// Update tasks that are leased out of a TaskQueue. /// /// A builder for the *update* method supported by a *task* resource. /// It is not used directly, but through a `TaskMethods` instance. /// /// # Example /// /// Instantiate a resource method builder /// /// ```test_harness,no_run /// # extern crate hyper; /// # extern crate hyper_rustls; /// # extern crate google_taskqueue1_beta2 as taskqueue1_beta2; /// use taskqueue1_beta2::api::Task; /// # async fn dox() { /// # use std::default::Default; /// # use taskqueue1_beta2::{Taskqueue, oauth2, hyper, hyper_rustls}; /// /// # let secret: oauth2::ApplicationSecret = Default::default(); /// # let auth = oauth2::InstalledFlowAuthenticator::builder( /// # secret, /// # oauth2::InstalledFlowReturnMethod::HTTPRedirect, /// # ).build().await.unwrap(); /// # let mut hub = Taskqueue::new(hyper::Client::builder().build(hyper_rustls::HttpsConnector::with_native_roots().https_or_http().enable_http1().enable_http2().build()), auth); /// // As the method needs a request, you would usually fill it with the desired information /// // into the respective structure. Some of the parts shown here might not be applicable ! /// // Values shown here are possibly random and not representative ! /// let mut req = Task::default(); /// /// // You can configure optional parameters by calling the respective setters at will, and /// // execute the final call using `doit()`. /// // Values shown here are possibly random and not representative ! /// let result = hub.tasks().update(req, "project", "taskqueue", "task", -68) /// .doit().await; /// # } /// ``` pub struct TaskUpdateCall<'a> where { hub: &'a Taskqueue<>, _request: Task, _project: String, _taskqueue: String, _task: String, _new_lease_seconds: i32, _delegate: Option<&'a mut dyn client::Delegate>, _additional_params: HashMap, _scopes: BTreeMap } impl<'a> client::CallBuilder for TaskUpdateCall<'a> {} impl<'a> TaskUpdateCall<'a> { /// Perform the operation you have build so far. pub async fn doit(mut self) -> client::Result<(hyper::Response, Task)> { use std::io::{Read, Seek}; use hyper::header::{CONTENT_TYPE, CONTENT_LENGTH, AUTHORIZATION, USER_AGENT, LOCATION}; use client::ToParts; let mut dd = client::DefaultDelegate; let mut dlg: &mut dyn client::Delegate = match self._delegate { Some(d) => d, None => &mut dd }; dlg.begin(client::MethodInfo { id: "taskqueue.tasks.update", http_method: hyper::Method::POST }); let mut params: Vec<(&str, String)> = Vec::with_capacity(7 + self._additional_params.len()); params.push(("project", self._project.to_string())); params.push(("taskqueue", self._taskqueue.to_string())); params.push(("task", self._task.to_string())); params.push(("newLeaseSeconds", self._new_lease_seconds.to_string())); for &field in ["alt", "project", "taskqueue", "task", "newLeaseSeconds"].iter() { if self._additional_params.contains_key(field) { dlg.finished(false); return Err(client::Error::FieldClash(field)); } } for (name, value) in self._additional_params.iter() { params.push((&name, value.clone())); } params.push(("alt", "json".to_string())); let mut url = self.hub._base_url.clone() + "{project}/taskqueues/{taskqueue}/tasks/{task}"; if self._scopes.len() == 0 { self._scopes.insert(Scope::Full.as_ref().to_string(), ()); } for &(find_this, param_name) in [("{project}", "project"), ("{taskqueue}", "taskqueue"), ("{task}", "task")].iter() { let mut replace_with: Option<&str> = None; for &(name, ref value) in params.iter() { if name == param_name { replace_with = Some(value); break; } } url = url.replace(find_this, replace_with.expect("to find substitution value in params")); } { let mut indices_for_removal: Vec = Vec::with_capacity(3); for param_name in ["task", "taskqueue", "project"].iter() { if let Some(index) = params.iter().position(|t| &t.0 == param_name) { indices_for_removal.push(index); } } for &index in indices_for_removal.iter() { params.remove(index); } } let url = url::Url::parse_with_params(&url, params).unwrap(); let mut json_mime_type: mime::Mime = "application/json".parse().unwrap(); let mut request_value_reader = { let mut value = json::value::to_value(&self._request).expect("serde to work"); client::remove_json_null_values(&mut value); let mut dst = io::Cursor::new(Vec::with_capacity(128)); json::to_writer(&mut dst, &value).unwrap(); dst }; let request_size = request_value_reader.seek(io::SeekFrom::End(0)).unwrap(); request_value_reader.seek(io::SeekFrom::Start(0)).unwrap(); loop { let token = match self.hub.auth.token(&self._scopes.keys().collect::>()[..]).await { Ok(token) => token.clone(), Err(err) => { match dlg.token(&err) { Some(token) => token, None => { dlg.finished(false); return Err(client::Error::MissingToken(err)) } } } }; request_value_reader.seek(io::SeekFrom::Start(0)).unwrap(); let mut req_result = { let client = &self.hub.client; dlg.pre_request(); let mut req_builder = hyper::Request::builder().method(hyper::Method::POST).uri(url.clone().into_string()) .header(USER_AGENT, self.hub._user_agent.clone()) .header(AUTHORIZATION, format!("Bearer {}", token.as_str())); let request = req_builder .header(CONTENT_TYPE, format!("{}", json_mime_type.to_string())) .header(CONTENT_LENGTH, request_size as u64) .body(hyper::body::Body::from(request_value_reader.get_ref().clone())); client.request(request.unwrap()).await }; match req_result { Err(err) => { if let client::Retry::After(d) = dlg.http_error(&err) { sleep(d); continue; } dlg.finished(false); return Err(client::Error::HttpError(err)) } Ok(mut res) => { if !res.status().is_success() { let res_body_string = client::get_body_as_string(res.body_mut()).await; let (parts, _) = res.into_parts(); let body = hyper::Body::from(res_body_string.clone()); let restored_response = hyper::Response::from_parts(parts, body); let server_response = json::from_str::(&res_body_string).ok(); if let client::Retry::After(d) = dlg.http_failure(&restored_response, server_response.clone()) { sleep(d); continue; } dlg.finished(false); return match server_response { Some(error_value) => Err(client::Error::BadRequest(error_value)), None => Err(client::Error::Failure(restored_response)), } } let result_value = { let res_body_string = client::get_body_as_string(res.body_mut()).await; match json::from_str(&res_body_string) { Ok(decoded) => (res, decoded), Err(err) => { dlg.response_json_decode_error(&res_body_string, &err); return Err(client::Error::JsonDecodeError(res_body_string, err)); } } }; dlg.finished(true); return Ok(result_value) } } } } /// /// Sets the *request* property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn request(mut self, new_value: Task) -> TaskUpdateCall<'a> { self._request = new_value; self } /// The project under which the queue lies. /// /// Sets the *project* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn project(mut self, new_value: &str) -> TaskUpdateCall<'a> { self._project = new_value.to_string(); self } /// /// Sets the *taskqueue* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn taskqueue(mut self, new_value: &str) -> TaskUpdateCall<'a> { self._taskqueue = new_value.to_string(); self } /// /// Sets the *task* path property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn task(mut self, new_value: &str) -> TaskUpdateCall<'a> { self._task = new_value.to_string(); self } /// The new lease in seconds. /// /// Sets the *new lease seconds* query property to the given value. /// /// Even though the property as already been set when instantiating this call, /// we provide this method for API completeness. pub fn new_lease_seconds(mut self, new_value: i32) -> TaskUpdateCall<'a> { self._new_lease_seconds = new_value; self } /// The delegate implementation is consulted whenever there is an intermediate result, or if something goes wrong /// while executing the actual API request. /// /// It should be used to handle progress information, and to implement a certain level of resilience. /// /// Sets the *delegate* property to the given value. pub fn delegate(mut self, new_value: &'a mut dyn client::Delegate) -> TaskUpdateCall<'a> { self._delegate = Some(new_value); self } /// Set any additional parameter of the query string used in the request. /// It should be used to set parameters which are not yet available through their own /// setters. /// /// Please note that this method must not be used to set any of the known parameters /// which have their own setter method. If done anyway, the request will fail. /// /// # Additional Parameters /// /// * *alt* (query-string) - Data format for the response. /// * *fields* (query-string) - Selector specifying which fields to include in a partial response. /// * *key* (query-string) - API key. Your API key identifies your project and provides you with API access, quota, and reports. Required unless you provide an OAuth 2.0 token. /// * *oauth_token* (query-string) - OAuth 2.0 token for the current user. /// * *prettyPrint* (query-boolean) - Returns response with indentations and line breaks. /// * *quotaUser* (query-string) - Available to use for quota purposes for server-side applications. Can be any arbitrary string assigned to a user, but should not exceed 40 characters. Overrides userIp if both are provided. /// * *userIp* (query-string) - IP address of the site where the request originates. Use this if you want to enforce per-user limits. pub fn param(mut self, name: T, value: T) -> TaskUpdateCall<'a> where T: AsRef { self._additional_params.insert(name.as_ref().to_string(), value.as_ref().to_string()); self } /// Identifies the authorization scope for the method you are building. /// /// Use this method to actively specify which scope should be used, instead the default `Scope` variant /// `Scope::Full`. /// /// The `scope` will be added to a set of scopes. This is important as one can maintain access /// tokens for more than one scope. /// If `None` is specified, then all scopes will be removed and no default scope will be used either. /// In that case, you have to specify your API-key using the `key` parameter (see the `param()` /// function for details). /// /// Usually there is more than one suitable scope to authorize an operation, some of which may /// encompass more rights than others. For example, for listing resources, a *read-only* scope will be /// sufficient, a read-write scope will do as well. pub fn add_scope(mut self, scope: T) -> TaskUpdateCall<'a> where T: Into>, S: AsRef { match scope.into() { Some(scope) => self._scopes.insert(scope.as_ref().to_string(), ()), None => None, }; self } }