Crates.io | anthill-service-system |
lib.rs | anthill-service-system |
version | 1.2.3 |
source | src |
created_at | 2021-10-02 15:23:39.582066 |
updated_at | 2022-05-05 12:39:28.801481 |
description | Rust runtime service system manager with di integration |
homepage | https://github.com/Vidrochka/anthill-service-system |
repository | https://github.com/Vidrochka/anthill-service-system |
max_upload_size | |
id | 459450 |
size | 52,443 |
Rust runtime service system manager with anthill-di integration
Minimal required version of anthill-di 1.2.3
Library required Rust nightly for anthill-di
First you need to create an application
async fn _() {
// create new ioc context
let mut app = Application::new().await;
// -- or -- //
// from exist ioc context
let root_context = DependencyContext::new_root();
root_context.register_type::<Application>(DependencyLifeCycle::Transient).await.unwrap();
// On create Application created new ioc context
let mut app = root_context.resolve::<Application>().await.unwrap();
}
The service must implement the trait IBaseService
+ Constructor
#[async_trait]
impl IBaseService for TestHostedService1 {
async fn on_start(&mut self) {
// you have (by default) 5s
// to do something on start
}
async fn on_stop(&mut self) {
// you have (by default) 5s
// to do something on stop
}
}
Or you can use the extension to work in a separate task
#[async_trait]
impl IBackgroundService for TestBackgroundService1 {
async fn execute(&self) {
// you can do anything before app stoned
// check state time by time and exit on stop (see next)
}
}
To manipulate application state, you can request a dependency Arc<dyn ILifeTimeManager>
async fn _(ctx: DependencyContext) {
let app_lifetime = ctx.resolve::<Arc<dyn ILifeTimeManager>>().await.unwrap();
// check app state
let is_running = app_lifetime.is_running().await;
// stop app
app_lifetime.stop().await;
// wait until app stop request
app_lifetime.wait_for_stop().await;
}
Then register dependencies and services
async fn _() {
// let mut app = Application::new().await;
// for mor info about ioc see (https://crates.io/crates/anthill-di)
app.root_ioc_context.register_type::<SomeType>(DependencyLifeCycle::Transient).await.unwrap();
app.register_service::<BackgroundService<TestBackgroundService>>().await.unwrap();
app.register_service::<TestBaseService>().await.unwrap();
}
For a more convenient setting of the service, use IStartup
#[async_trait]
impl IStartup for TestStartup {
async fn configure_dependency(&mut self, root_ioc_context: &mut DependencyContext) {
root_ioc_context.register_type::<SomeComponent>().await.unwrap();
}
async fn configure_application(&mut self, _ : Arc<RwLock<CoreConfig>>, app: &mut Application) {
app.register_service::<BackgroundService<TestBackgroundService1>>().await.unwrap();
app.register_service::<BackgroundService<TestBackgroundService2>>().await.unwrap();
}
}
async fn _() {
// let mut app = Application::new().await;
app.register_startup::<TestStartup>().await.unwrap();
}
Launch the app
async fn _() {
// let mut app = Application::new().await;
app.run().await.unwrap();
}
You can control start and stop timeout (by default 5s per service)
async fn _() {
// let mut app = Application::new().await;
let core_config = app.root_ioc_context.resolve::<Arc<RwLock<CoreConfig>>>().await.unwrap();
core_config.write().await.on_start_timeout = Duration::from_millis(6000);
core_config.write().await.on_stop_timeout = Duration::from_millis(6000);
}
Currently implemented CtrlCLifeTimeManager
and InnerStateLifeTimeManager
CtrlCLifeTimeManager
for close app in ctrl+c
press timeInnerStateLifeTimeManager
for close app only by service requestDefault lifetime manager is CtrlCLifeTimeManager
You can customize your app lifetime management
pub struct InnerStateLifeTimeManager {
is_running: AtomicBool,
}
#[async_trait]
impl ILifeTimeManager for CtrlCLifeTimeManager {
async fn stop(&self) {
self.is_running.store(false, Ordering::SeqCst)
}
async fn is_running(&self) -> bool {
self.is_running.load(Ordering::SeqCst)
}
async fn wait_for_stop(&self) {
while self.is_running.load(Ordering::SeqCst) {
yield_now().await;
}
}
}
async fn _() {
// let mut app = Application::new().await;
// Use here you LifeTimeManager
app.register_life_time_manager::<CtrlCLifeTimeManager>().await.unwrap();
}
use anthill_service_system::{configs::CoreConfig, Application, IStartup, life_time::{ILifeTimeManager, InnerStateLifeTimeManager}};
use std::sync::Arc;
use anthill_di::{
DependencyContext,
Constructor,
types::BuildDependencyResult,
};
use async_trait::async_trait;
use tokio::sync::oneshot;
use tokio::{
sync::{
RwLock,
oneshot::{
Sender,
Receiver,
}
},
};
use crate::services::IBackgroundService;
struct TestBackgroundService1 {
ctx: DependencyContext,
}
#[async_trait]
impl Constructor for TestBackgroundService1 {
async fn ctor(ctx: DependencyContext) -> BuildDependencyResult<Self> {
Ok(Self { ctx })
}
}
#[async_trait]
impl IBackgroundService for TestBackgroundService1 {
async fn execute(&self) {
let sender = self.ctx.resolve::<Arc<RwLock<Option<Sender<String>>>>>().await.unwrap()
.write().await
.take().unwrap();
sender.send("test".to_string()).unwrap();
}
}
struct TestBackgroundService2 {
application_life_time: Arc<dyn ILifeTimeManager>,
ctx: DependencyContext,
}
#[async_trait]
impl Constructor for TestBackgroundService2 {
async fn ctor(ctx: DependencyContext) -> BuildDependencyResult<Self> {
let application_life_time = ctx.resolve().await?;
Ok(Self {
application_life_time,
ctx,
})
}
}
#[async_trait]
impl IBackgroundService for TestBackgroundService2 {
async fn execute(&self) {
let receiver = self.ctx.resolve::<Arc<RwLock<Option<Receiver<String>>>>>().await.unwrap().write().await.take().unwrap();
assert_eq!("test".to_string(), receiver.await.unwrap());
self.application_life_time.stop().await;
}
}
struct TestStartup {}
#[async_trait]
impl Constructor for TestStartup {
async fn ctor(_ctx: DependencyContext) -> BuildDependencyResult<Self> {
Ok(Self {})
}
}
#[async_trait]
impl IStartup for TestStartup {
async fn configure_dependency(&mut self, root_ioc_context: &mut DependencyContext) {
let (tx, rx) = oneshot::channel::<String>();
root_ioc_context.register_instance(RwLock::new(Some(tx))).await.unwrap();
root_ioc_context.register_instance(RwLock::new(Some(rx))).await.unwrap();
}
async fn configure_application(&mut self, _ : Arc<RwLock<CoreConfig>>, app: &mut Application) {
app.register_life_time_manager::<InnerStateLifeTimeManager>().await.unwrap();
app.register_background_service::<TestBackgroundService1>().await.unwrap();
app.register_background_service::<TestBackgroundService2>().await.unwrap();
}
}
#[tokio::main]
async fn main() {
let mut app = Application::new().await;
app.register_startup::<TestStartup>().await.unwrap();
app.run().await.unwrap();
}