use std::future::Future; use std::marker::PhantomData; use std::pin::Pin; use std::task::{Context, Poll}; use std::{net, rc::Rc}; use actix_codec::{AsyncRead, AsyncWrite}; use actix_rt::net::TcpStream; use actix_service::{ fn_factory, fn_service, pipeline_factory, IntoServiceFactory, Service, ServiceFactory, }; use bytes::Bytes; use futures_core::ready; use futures_util::future::ok; use h2::server::{self, Handshake}; use log::error; use crate::body::MessageBody; use crate::cloneable::CloneableService; use crate::config::ServiceConfig; use crate::error::{DispatchError, Error}; use crate::request::Request; use crate::response::Response; use crate::{ConnectCallback, Extensions}; use super::dispatcher::Dispatcher; /// `ServiceFactory` implementation for HTTP2 transport pub struct H2Service { srv: S, cfg: ServiceConfig, on_connect_ext: Option>>, _t: PhantomData<(T, B)>, } impl H2Service where S: ServiceFactory, S::Error: Into + 'static, S::Response: Into> + 'static, >::Future: 'static, B: MessageBody + 'static, { /// Create new `HttpService` instance with config. pub(crate) fn with_config>( cfg: ServiceConfig, service: F, ) -> Self { H2Service { cfg, on_connect_ext: None, srv: service.into_factory(), _t: PhantomData, } } /// Set on connect callback. pub(crate) fn on_connect_ext(mut self, f: Option>>) -> Self { self.on_connect_ext = f; self } } impl H2Service where S: ServiceFactory, S::Error: Into + 'static, S::Response: Into> + 'static, >::Future: 'static, B: MessageBody + 'static, { /// Create simple tcp based service pub fn tcp( self, ) -> impl ServiceFactory< TcpStream, Config = (), Response = (), Error = DispatchError, InitError = S::InitError, > { pipeline_factory(fn_factory(|| async { Ok::<_, S::InitError>(fn_service(|io: TcpStream| { let peer_addr = io.peer_addr().ok(); ok::<_, DispatchError>((io, peer_addr)) })) })) .and_then(self) } } #[cfg(feature = "openssl")] mod openssl { use actix_service::{fn_factory, fn_service, ServiceFactoryExt}; use actix_tls::accept::openssl::{Acceptor, SslAcceptor, SslError, SslStream}; use actix_tls::accept::TlsError; use super::*; impl H2Service, S, B> where S: ServiceFactory, S::Error: Into + 'static, S::Response: Into> + 'static, >::Future: 'static, B: MessageBody + 'static, { /// Create ssl based service pub fn openssl( self, acceptor: SslAcceptor, ) -> impl ServiceFactory< TcpStream, Config = (), Response = (), Error = TlsError, InitError = S::InitError, > { pipeline_factory( Acceptor::new(acceptor) .map_err(TlsError::Tls) .map_init_err(|_| panic!()), ) .and_then(fn_factory(|| { ok::<_, S::InitError>(fn_service(|io: SslStream| { let peer_addr = io.get_ref().peer_addr().ok(); ok((io, peer_addr)) })) })) .and_then(self.map_err(TlsError::Service)) } } } #[cfg(feature = "rustls")] mod rustls { use super::*; use actix_service::ServiceFactoryExt; use actix_tls::accept::rustls::{Acceptor, ServerConfig, TlsStream}; use actix_tls::accept::TlsError; use std::io; impl H2Service, S, B> where S: ServiceFactory, S::Error: Into + 'static, S::Response: Into> + 'static, >::Future: 'static, B: MessageBody + 'static, { /// Create openssl based service pub fn rustls( self, mut config: ServerConfig, ) -> impl ServiceFactory< TcpStream, Config = (), Response = (), Error = TlsError, InitError = S::InitError, > { let protos = vec!["h2".to_string().into()]; config.set_protocols(&protos); pipeline_factory( Acceptor::new(config) .map_err(TlsError::Tls) .map_init_err(|_| panic!()), ) .and_then(fn_factory(|| { ok::<_, S::InitError>(fn_service(|io: TlsStream| { let peer_addr = io.get_ref().0.peer_addr().ok(); ok((io, peer_addr)) })) })) .and_then(self.map_err(TlsError::Service)) } } } impl ServiceFactory<(T, Option)> for H2Service where T: AsyncRead + AsyncWrite + Unpin, S: ServiceFactory, S::Error: Into + 'static, S::Response: Into> + 'static, >::Future: 'static, B: MessageBody + 'static, { type Response = (); type Error = DispatchError; type Config = (); type Service = H2ServiceHandler; type InitError = S::InitError; type Future = H2ServiceResponse; fn new_service(&self, _: ()) -> Self::Future { H2ServiceResponse { fut: self.srv.new_service(()), cfg: Some(self.cfg.clone()), on_connect_ext: self.on_connect_ext.clone(), _t: PhantomData, } } } #[doc(hidden)] #[pin_project::pin_project] pub struct H2ServiceResponse where S: ServiceFactory, { #[pin] fut: S::Future, cfg: Option, on_connect_ext: Option>>, _t: PhantomData, } impl Future for H2ServiceResponse where T: AsyncRead + AsyncWrite + Unpin, S: ServiceFactory, S::Error: Into + 'static, S::Response: Into> + 'static, >::Future: 'static, B: MessageBody + 'static, { type Output = Result, S::InitError>; fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { let this = self.as_mut().project(); Poll::Ready(ready!(this.fut.poll(cx)).map(|service| { let this = self.as_mut().project(); H2ServiceHandler::new( this.cfg.take().unwrap(), this.on_connect_ext.clone(), service, ) })) } } /// `Service` implementation for http/2 transport pub struct H2ServiceHandler where S: Service, { srv: CloneableService, cfg: ServiceConfig, on_connect_ext: Option>>, _t: PhantomData, } impl H2ServiceHandler where S: Service, S::Error: Into + 'static, S::Future: 'static, S::Response: Into> + 'static, B: MessageBody + 'static, { fn new( cfg: ServiceConfig, on_connect_ext: Option>>, srv: S, ) -> H2ServiceHandler { H2ServiceHandler { cfg, on_connect_ext, srv: CloneableService::new(srv), _t: PhantomData, } } } impl Service<(T, Option)> for H2ServiceHandler where T: AsyncRead + AsyncWrite + Unpin, S: Service, S::Error: Into + 'static, S::Future: 'static, S::Response: Into> + 'static, B: MessageBody + 'static, { type Response = (); type Error = DispatchError; type Future = H2ServiceHandlerResponse; fn poll_ready(&mut self, cx: &mut Context<'_>) -> Poll> { self.srv.poll_ready(cx).map_err(|e| { let e = e.into(); error!("Service readiness error: {:?}", e); DispatchError::Service(e) }) } fn call(&mut self, (io, addr): (T, Option)) -> Self::Future { let mut connect_extensions = Extensions::new(); if let Some(ref handler) = self.on_connect_ext { // run on_connect_ext callback, populating connect extensions handler(&io, &mut connect_extensions); } H2ServiceHandlerResponse { state: State::Handshake( Some(self.srv.clone()), Some(self.cfg.clone()), addr, Some(connect_extensions), server::handshake(io), ), } } } enum State, B: MessageBody> where T: AsyncRead + AsyncWrite + Unpin, S::Future: 'static, { Incoming(Dispatcher), Handshake( Option>, Option, Option, Option, Handshake, ), } pub struct H2ServiceHandlerResponse where T: AsyncRead + AsyncWrite + Unpin, S: Service, S::Error: Into + 'static, S::Future: 'static, S::Response: Into> + 'static, B: MessageBody + 'static, { state: State, } impl Future for H2ServiceHandlerResponse where T: AsyncRead + AsyncWrite + Unpin, S: Service, S::Error: Into + 'static, S::Future: 'static, S::Response: Into> + 'static, B: MessageBody, { type Output = Result<(), DispatchError>; fn poll(mut self: Pin<&mut Self>, cx: &mut Context<'_>) -> Poll { match self.state { State::Incoming(ref mut disp) => Pin::new(disp).poll(cx), State::Handshake( ref mut srv, ref mut config, ref peer_addr, ref mut on_connect_data, ref mut handshake, ) => match Pin::new(handshake).poll(cx) { Poll::Ready(Ok(conn)) => { self.state = State::Incoming(Dispatcher::new( srv.take().unwrap(), conn, on_connect_data.take().unwrap(), config.take().unwrap(), None, *peer_addr, )); self.poll(cx) } Poll::Ready(Err(err)) => { trace!("H2 handshake error: {}", err); Poll::Ready(Err(err.into())) } Poll::Pending => Poll::Pending, }, } } }