Struct actix_server::ServerBuilder

pub struct ServerBuilder { /* fields omitted */ }

Server builder

Methods

impl ServerBuilder

pub fn new() -> ServerBuilder

Create new Server builder instance

pub fn workers(self, num: usize) -> Self

Set number of workers to start.

By default server uses number of available logical cpu as workers count.

pub fn backlog(self, num: i32) -> Self

Set the maximum number of pending connections.

This refers to the number of clients that can be waiting to be served. Exceeding this number results in the client getting an error when attempting to connect. It should only affect servers under significant load.

Generally set in the 64-2048 range. Default value is 2048.

This method should be called before bind() method call.

pub fn maxconn(self, num: usize) -> Self

Sets the maximum per-worker number of concurrent connections.

All socket listeners will stop accepting connections when this limit is reached for each worker.

By default max connections is set to a 25k per worker.

pub fn maxconnrate(self, num: usize) -> Self

Sets the maximum per-worker concurrent connection establish process.

All listeners will stop accepting connections when this limit is reached. It can be used to limit the global SSL CPU usage.

By default max connections is set to a 256.

pub fn system_exit(self) -> Self

Stop actix system.

pub fn disable_signals(self) -> Self

Disable signal handling

pub fn shutdown_timeout(self, sec: u64) -> Self

Timeout for graceful workers shutdown in seconds.

After receiving a stop signal, workers have this much time to finish serving requests. Workers still alive after the timeout are force dropped.

By default shutdown timeout sets to 30 seconds.

pub fn configure<F>(self, f: F) -> Result<ServerBuilder> where
    F: Fn(&mut ServiceConfig) -> Result<()>, 

Execute external configuration as part of the server building process.

This function is useful for moving parts of configuration to a different module or even library.

pub fn bind<F, U, N: AsRef<str>>(
    self,
    name: N,
    addr: U,
    factory: F
) -> Result<Self> where
    F: ServiceFactory<TcpStream>,
    U: ToSocketAddrs, 

Add new service to the server.

pub fn bind_uds<F, U, N>(self, name: N, addr: U, factory: F) -> Result<Self> where
    F: ServiceFactory<UnixStream>,
    N: AsRef<str>,
    U: AsRef<Path>, 

Add new unix domain service to the server.

pub fn listen<F, N: AsRef<str>>(
    self,
    name: N,
    lst: TcpListener,
    factory: F
) -> Result<Self> where
    F: ServiceFactory<TcpStream>, 

Add new service to the server.

pub fn run(self) -> Result<()>

Spawn new thread and start listening for incoming connections.

This method spawns new thread and starts new actix system. Other than that it is similar to start() method. This method blocks.

This methods panics if no socket addresses get bound.

use actix_web::*;

fn main() -> std::io::Result<()> {
    Server::new().
        .service(
           HttpServer::new(|| App::new().service(web::service("/").to(|| HttpResponse::Ok())))
               .bind("127.0.0.1:0")
        .run()
}

pub fn start(self) -> Server

Starts processing incoming connections and return server controller.

Trait Implementations

impl Default for ServerBuilder

fn default() -> Self

Returns the "default value" for a type.

impl Future for ServerBuilder

type Item = ()

The type of value that this future will resolved with if it is successful.

type Error = ()

The type of error that this future will resolve with if it fails in a normal fashion.

fn poll(&mut self) -> Poll<Self::Item, Self::Error>

Query this future to see if its value has become available, registering interest if it is not.

fn wait(self) -> Result<Self::Item, Self::Error>

Block the current thread until this future is resolved.

fn map<F, U>(self, f: F) -> Map<Self, F> where
    F: FnOnce(Self::Item) -> U, 

Map this future's result to a different type, returning a new future of the resulting type.

fn map_err<F, E>(self, f: F) -> MapErr<Self, F> where
    F: FnOnce(Self::Error) -> E, 

Map this future's error to a different error, returning a new future.

fn from_err<E>(self) -> FromErr<Self, E> where
    E: From<Self::Error>, 

Map this future's error to any error implementing From for this future's Error, returning a new future.

fn then<F, B>(self, f: F) -> Then<Self, B, F> where
    B: IntoFuture,
    F: FnOnce(Result<Self::Item, Self::Error>) -> B, 

Chain on a computation for when a future finished, passing the result of the future to the provided closure f.

fn and_then<F, B>(self, f: F) -> AndThen<Self, B, F> where
    B: IntoFuture<Error = Self::Error>,
    F: FnOnce(Self::Item) -> B, 

Execute another future after this one has resolved successfully.

fn or_else<F, B>(self, f: F) -> OrElse<Self, B, F> where
    B: IntoFuture<Item = Self::Item>,
    F: FnOnce(Self::Error) -> B, 

Execute another future if this one resolves with an error.

fn select<B>(self, other: B) -> Select<Self, <B as IntoFuture>::Future> where
    B: IntoFuture<Item = Self::Item, Error = Self::Error>, 

Waits for either one of two futures to complete.

fn select2<B>(self, other: B) -> Select2<Self, <B as IntoFuture>::Future> where
    B: IntoFuture, 

Waits for either one of two differently-typed futures to complete.

fn join<B>(self, other: B) -> Join<Self, <B as IntoFuture>::Future> where
    B: IntoFuture<Error = Self::Error>, 

Joins the result of two futures, waiting for them both to complete.

fn join3<B, C>(
    self,
    b: B,
    c: C
) -> Join3<Self, <B as IntoFuture>::Future, <C as IntoFuture>::Future> where
    B: IntoFuture<Error = Self::Error>,
    C: IntoFuture<Error = Self::Error>, 

Same as join, but with more futures.

fn join4<B, C, D>(
    self,
    b: B,
    c: C,
    d: D
) -> Join4<Self, <B as IntoFuture>::Future, <C as IntoFuture>::Future, <D as IntoFuture>::Future> where
    B: IntoFuture<Error = Self::Error>,
    C: IntoFuture<Error = Self::Error>,
    D: IntoFuture<Error = Self::Error>, 

Same as join, but with more futures.

fn join5<B, C, D, E>(
    self,
    b: B,
    c: C,
    d: D,
    e: E
) -> Join5<Self, <B as IntoFuture>::Future, <C as IntoFuture>::Future, <D as IntoFuture>::Future, <E as IntoFuture>::Future> where
    B: IntoFuture<Error = Self::Error>,
    C: IntoFuture<Error = Self::Error>,
    D: IntoFuture<Error = Self::Error>,
    E: IntoFuture<Error = Self::Error>, 

Same as join, but with more futures.

fn into_stream(self) -> IntoStream<Self>

Convert this future into a single element stream.

fn flatten(self) -> Flatten<Self> where
    Self::Item: IntoFuture,
    <Self::Item as IntoFuture>::Error: From<Self::Error>, 

Flatten the execution of this future when the successful result of this future is itself another future.

fn flatten_stream(self) -> FlattenStream<Self> where
    Self::Item: Stream,
    <Self::Item as Stream>::Error == Self::Error, 

Flatten the execution of this future when the successful result of this future is a stream.

fn fuse(self) -> Fuse<Self>

Fuse a future such that poll will never again be called once it has completed.

fn inspect<F>(self, f: F) -> Inspect<Self, F> where
    F: FnOnce(&Self::Item), 

Do something with the item of a future, passing it on.

fn catch_unwind(self) -> CatchUnwind<Self> where
    Self: UnwindSafe, 

Catches unwinding panics while polling the future.

fn shared(self) -> Shared<Self>

Create a cloneable handle to this future where all handles will resolve to the same result.