// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license. use crate::io::TcpStreamResource; use crate::ops::IpAddr; use crate::ops::OpAddr; use crate::ops::OpConn; use crate::ops::TlsHandshakeInfo; use crate::resolve_addr::resolve_addr; use crate::resolve_addr::resolve_addr_sync; use crate::DefaultTlsOptions; use crate::NetPermissions; use crate::UnsafelyIgnoreCertificateErrors; use deno_core::error::bad_resource; use deno_core::error::custom_error; use deno_core::error::generic_error; use deno_core::error::invalid_hostname; use deno_core::error::type_error; use deno_core::error::AnyError; use deno_core::futures::future::poll_fn; use deno_core::futures::ready; use deno_core::futures::task::noop_waker_ref; use deno_core::futures::task::AtomicWaker; use deno_core::futures::task::Context; use deno_core::futures::task::Poll; use deno_core::futures::task::RawWaker; use deno_core::futures::task::RawWakerVTable; use deno_core::futures::task::Waker; use deno_core::op_async; use deno_core::op_sync; use deno_core::parking_lot::Mutex; use deno_core::AsyncRefCell; use deno_core::AsyncResult; use deno_core::ByteString; use deno_core::CancelHandle; use deno_core::CancelTryFuture; use deno_core::OpPair; use deno_core::OpState; use deno_core::RcRef; use deno_core::Resource; use deno_core::ResourceId; use deno_core::ZeroCopyBuf; use deno_tls::create_client_config; use deno_tls::load_certs; use deno_tls::load_private_keys; use deno_tls::rustls::Certificate; use deno_tls::rustls::ClientConfig; use deno_tls::rustls::ClientConnection; use deno_tls::rustls::Connection; use deno_tls::rustls::PrivateKey; use deno_tls::rustls::ServerConfig; use deno_tls::rustls::ServerConnection; use deno_tls::rustls::ServerName; use io::Error; use io::Read; use io::Write; use serde::Deserialize; use std::borrow::Cow; use std::cell::RefCell; use std::convert::From; use std::convert::TryFrom; use std::fs::File; use std::io; use std::io::BufReader; use std::io::ErrorKind; use std::path::Path; use std::pin::Pin; use std::rc::Rc; use std::sync::Arc; use std::sync::Weak; use tokio::io::AsyncRead; use tokio::io::AsyncReadExt; use tokio::io::AsyncWrite; use tokio::io::AsyncWriteExt; use tokio::io::ReadBuf; use tokio::net::TcpListener; use tokio::net::TcpStream; use tokio::task::spawn_local; #[derive(Copy, Clone, Debug, Eq, PartialEq)] enum Flow { Handshake, Read, Write, } #[derive(Copy, Clone, Debug, PartialEq, Eq, PartialOrd, Ord)] enum State { StreamOpen, StreamClosed, TlsClosing, TlsClosed, TcpClosed, } pub struct TlsStream(Option); impl TlsStream { fn new(tcp: TcpStream, mut tls: Connection) -> Self { tls.set_buffer_limit(None); let inner = TlsStreamInner { tcp, tls, rd_state: State::StreamOpen, wr_state: State::StreamOpen, }; Self(Some(inner)) } pub fn new_client_side( tcp: TcpStream, tls_config: Arc, server_name: ServerName, ) -> Self { let tls = ClientConnection::new(tls_config, server_name).unwrap(); Self::new(tcp, Connection::Client(tls)) } pub fn new_server_side( tcp: TcpStream, tls_config: Arc, ) -> Self { let tls = ServerConnection::new(tls_config).unwrap(); Self::new(tcp, Connection::Server(tls)) } fn into_split(self) -> (ReadHalf, WriteHalf) { let shared = Shared::new(self); let rd = ReadHalf { shared: shared.clone(), }; let wr = WriteHalf { shared }; (rd, wr) } /// Tokio-rustls compatibility: returns a reference to the underlying TCP /// stream, and a reference to the Rustls `Connection` object. pub fn get_ref(&self) -> (&TcpStream, &Connection) { let inner = self.0.as_ref().unwrap(); (&inner.tcp, &inner.tls) } fn inner_mut(&mut self) -> &mut TlsStreamInner { self.0.as_mut().unwrap() } pub async fn handshake(&mut self) -> io::Result<()> { poll_fn(|cx| self.inner_mut().poll_handshake(cx)).await } fn poll_handshake(&mut self, cx: &mut Context<'_>) -> Poll> { self.inner_mut().poll_handshake(cx) } fn get_alpn_protocol(&mut self) -> Option { self .inner_mut() .tls .alpn_protocol() .map(|s| ByteString(s.to_owned())) } } impl AsyncRead for TlsStream { fn poll_read( mut self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &mut ReadBuf<'_>, ) -> Poll> { self.inner_mut().poll_read(cx, buf) } } impl AsyncWrite for TlsStream { fn poll_write( mut self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &[u8], ) -> Poll> { self.inner_mut().poll_write(cx, buf) } fn poll_flush( mut self: Pin<&mut Self>, cx: &mut Context<'_>, ) -> Poll> { self.inner_mut().poll_io(cx, Flow::Write) // The underlying TCP stream does not need to be flushed. } fn poll_shutdown( mut self: Pin<&mut Self>, cx: &mut Context<'_>, ) -> Poll> { self.inner_mut().poll_shutdown(cx) } } impl Drop for TlsStream { fn drop(&mut self) { let mut inner = self.0.take().unwrap(); let mut cx = Context::from_waker(noop_waker_ref()); let use_linger_task = inner.poll_close(&mut cx).is_pending(); if use_linger_task { spawn_local(poll_fn(move |cx| inner.poll_close(cx))); } else if cfg!(debug_assertions) { spawn_local(async {}); // Spawn dummy task to detect missing LocalSet. } } } pub struct TlsStreamInner { tls: Connection, tcp: TcpStream, rd_state: State, wr_state: State, } impl TlsStreamInner { fn poll_io( &mut self, cx: &mut Context<'_>, flow: Flow, ) -> Poll> { loop { let wr_ready = loop { match self.wr_state { _ if self.tls.is_handshaking() && !self.tls.wants_write() => { break true; } _ if self.tls.is_handshaking() => {} State::StreamOpen if !self.tls.wants_write() => break true, State::StreamClosed => { // Rustls will enqueue the 'CloseNotify' alert and send it after // flushing the data that is already in the queue. self.tls.send_close_notify(); self.wr_state = State::TlsClosing; continue; } State::TlsClosing if !self.tls.wants_write() => { self.wr_state = State::TlsClosed; continue; } // If a 'CloseNotify' alert sent by the remote end has been received, // shut down the underlying TCP socket. Otherwise, consider polling // done for the moment. State::TlsClosed if self.rd_state < State::TlsClosed => break true, State::TlsClosed if Pin::new(&mut self.tcp).poll_shutdown(cx)?.is_pending() => { break false; } State::TlsClosed => { self.wr_state = State::TcpClosed; continue; } State::TcpClosed => break true, _ => {} } // Write ciphertext to the TCP socket. let mut wrapped_tcp = ImplementWriteTrait(&mut self.tcp); match self.tls.write_tls(&mut wrapped_tcp) { Ok(0) => {} // Wait until the socket has enough buffer space. Ok(_) => continue, // Try to send more more data immediately. Err(err) if err.kind() == ErrorKind::WouldBlock => unreachable!(), Err(err) => return Poll::Ready(Err(err)), } // Poll whether there is space in the socket send buffer so we can flush // the remaining outgoing ciphertext. if self.tcp.poll_write_ready(cx)?.is_pending() { break false; } }; let rd_ready = loop { // Interpret and decrypt unprocessed TLS protocol data. let tls_state = self .tls .process_new_packets() .map_err(|e| Error::new(ErrorKind::InvalidData, e))?; match self.rd_state { State::TcpClosed if self.tls.is_handshaking() => { let err = Error::new(ErrorKind::UnexpectedEof, "tls handshake eof"); return Poll::Ready(Err(err)); } _ if self.tls.is_handshaking() && !self.tls.wants_read() => { break true; } _ if self.tls.is_handshaking() => {} State::StreamOpen if tls_state.plaintext_bytes_to_read() > 0 => { break true; } State::StreamOpen if tls_state.peer_has_closed() => { self.rd_state = State::TlsClosed; continue; } State::StreamOpen => {} State::StreamClosed if tls_state.plaintext_bytes_to_read() > 0 => { // Rustls has more incoming cleartext buffered up, but the TLS // session is closing so this data will never be processed by the // application layer. Just like what would happen if this were a raw // TCP stream, don't gracefully end the TLS session, but abort it. return Poll::Ready(Err(Error::from(ErrorKind::ConnectionReset))); } State::StreamClosed => {} State::TlsClosed if self.wr_state == State::TcpClosed => { // Keep trying to read from the TCP connection until the remote end // closes it gracefully. } State::TlsClosed => break true, State::TcpClosed => break true, _ => unreachable!(), } // Try to read more TLS protocol data from the TCP socket. let mut wrapped_tcp = ImplementReadTrait(&mut self.tcp); match self.tls.read_tls(&mut wrapped_tcp) { Ok(0) => { self.rd_state = State::TcpClosed; continue; } Ok(_) => continue, Err(err) if err.kind() == ErrorKind::WouldBlock => {} Err(err) => return Poll::Ready(Err(err)), } // Get notified when more ciphertext becomes available to read from the // TCP socket. if self.tcp.poll_read_ready(cx)?.is_pending() { break false; } }; if wr_ready { if self.rd_state >= State::TlsClosed && self.wr_state >= State::TlsClosed && self.wr_state < State::TcpClosed { continue; } if self.tls.wants_write() { continue; } } let io_ready = match flow { _ if self.tls.is_handshaking() => false, Flow::Handshake => true, Flow::Read => rd_ready, Flow::Write => wr_ready, }; return match io_ready { false => Poll::Pending, true => Poll::Ready(Ok(())), }; } } fn poll_handshake(&mut self, cx: &mut Context<'_>) -> Poll> { if self.tls.is_handshaking() { ready!(self.poll_io(cx, Flow::Handshake))?; } Poll::Ready(Ok(())) } fn poll_read( &mut self, cx: &mut Context<'_>, buf: &mut ReadBuf<'_>, ) -> Poll> { ready!(self.poll_io(cx, Flow::Read))?; if self.rd_state == State::StreamOpen { let buf_slice = unsafe { &mut *(buf.unfilled_mut() as *mut [_] as *mut [u8]) }; let bytes_read = self.tls.reader().read(buf_slice)?; assert_ne!(bytes_read, 0); unsafe { buf.assume_init(bytes_read) }; buf.advance(bytes_read); } Poll::Ready(Ok(())) } fn poll_write( &mut self, cx: &mut Context<'_>, buf: &[u8], ) -> Poll> { if buf.is_empty() { // Tokio-rustls compatibility: a zero byte write always succeeds. Poll::Ready(Ok(0)) } else if self.wr_state == State::StreamOpen { // Flush Rustls' ciphertext send queue. ready!(self.poll_io(cx, Flow::Write))?; // Copy data from `buf` to the Rustls cleartext send queue. let bytes_written = self.tls.writer().write(buf)?; assert_ne!(bytes_written, 0); // Try to flush as much ciphertext as possible. However, since we just // handed off at least some bytes to rustls, so we can't return // `Poll::Pending()` any more: this would tell the caller that it should // try to send those bytes again. let _ = self.poll_io(cx, Flow::Write)?; Poll::Ready(Ok(bytes_written)) } else { // Return error if stream has been shut down for writing. Poll::Ready(Err(ErrorKind::BrokenPipe.into())) } } fn poll_shutdown(&mut self, cx: &mut Context<'_>) -> Poll> { if self.wr_state == State::StreamOpen { self.wr_state = State::StreamClosed; } ready!(self.poll_io(cx, Flow::Write))?; // At minimum, a TLS 'CloseNotify' alert should have been sent. assert!(self.wr_state >= State::TlsClosed); // If we received a TLS 'CloseNotify' alert from the remote end // already, the TCP socket should be shut down at this point. assert!( self.rd_state < State::TlsClosed || self.wr_state == State::TcpClosed ); Poll::Ready(Ok(())) } fn poll_close(&mut self, cx: &mut Context<'_>) -> Poll> { if self.rd_state == State::StreamOpen { self.rd_state = State::StreamClosed; } // Send TLS 'CloseNotify' alert. ready!(self.poll_shutdown(cx))?; // Wait for 'CloseNotify', shut down TCP stream, wait for TCP FIN packet. ready!(self.poll_io(cx, Flow::Read))?; assert_eq!(self.rd_state, State::TcpClosed); assert_eq!(self.wr_state, State::TcpClosed); Poll::Ready(Ok(())) } } pub struct ReadHalf { shared: Arc, } impl ReadHalf { pub fn reunite(self, wr: WriteHalf) -> TlsStream { assert!(Arc::ptr_eq(&self.shared, &wr.shared)); drop(wr); // Drop `wr`, so only one strong reference to `shared` remains. Arc::try_unwrap(self.shared) .unwrap_or_else(|_| panic!("Arc::::try_unwrap() failed")) .tls_stream .into_inner() } } impl AsyncRead for ReadHalf { fn poll_read( self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &mut ReadBuf<'_>, ) -> Poll> { self .shared .poll_with_shared_waker(cx, Flow::Read, move |tls, cx| { tls.poll_read(cx, buf) }) } } pub struct WriteHalf { shared: Arc, } impl WriteHalf { pub async fn handshake(&mut self) -> io::Result<()> { poll_fn(|cx| { self .shared .poll_with_shared_waker(cx, Flow::Write, |mut tls, cx| { tls.poll_handshake(cx) }) }) .await } fn get_alpn_protocol(&mut self) -> Option { self.shared.get_alpn_protocol() } } impl AsyncWrite for WriteHalf { fn poll_write( self: Pin<&mut Self>, cx: &mut Context<'_>, buf: &[u8], ) -> Poll> { self .shared .poll_with_shared_waker(cx, Flow::Write, move |tls, cx| { tls.poll_write(cx, buf) }) } fn poll_flush( self: Pin<&mut Self>, cx: &mut Context<'_>, ) -> Poll> { self .shared .poll_with_shared_waker(cx, Flow::Write, |tls, cx| tls.poll_flush(cx)) } fn poll_shutdown( self: Pin<&mut Self>, cx: &mut Context<'_>, ) -> Poll> { self .shared .poll_with_shared_waker(cx, Flow::Write, |tls, cx| tls.poll_shutdown(cx)) } } struct Shared { tls_stream: Mutex, rd_waker: AtomicWaker, wr_waker: AtomicWaker, } impl Shared { fn new(tls_stream: TlsStream) -> Arc { let self_ = Self { tls_stream: Mutex::new(tls_stream), rd_waker: AtomicWaker::new(), wr_waker: AtomicWaker::new(), }; Arc::new(self_) } fn poll_with_shared_waker( self: &Arc, cx: &mut Context<'_>, flow: Flow, mut f: impl FnMut(Pin<&mut TlsStream>, &mut Context<'_>) -> R, ) -> R { match flow { Flow::Handshake => unreachable!(), Flow::Read => self.rd_waker.register(cx.waker()), Flow::Write => self.wr_waker.register(cx.waker()), } let shared_waker = self.new_shared_waker(); let mut cx = Context::from_waker(&shared_waker); let mut tls_stream = self.tls_stream.lock(); f(Pin::new(&mut tls_stream), &mut cx) } const SHARED_WAKER_VTABLE: RawWakerVTable = RawWakerVTable::new( Self::clone_shared_waker, Self::wake_shared_waker, Self::wake_shared_waker_by_ref, Self::drop_shared_waker, ); fn new_shared_waker(self: &Arc) -> Waker { let self_weak = Arc::downgrade(self); let self_ptr = self_weak.into_raw() as *const (); let raw_waker = RawWaker::new(self_ptr, &Self::SHARED_WAKER_VTABLE); unsafe { Waker::from_raw(raw_waker) } } fn clone_shared_waker(self_ptr: *const ()) -> RawWaker { let self_weak = unsafe { Weak::from_raw(self_ptr as *const Self) }; let ptr1 = self_weak.clone().into_raw(); let ptr2 = self_weak.into_raw(); assert!(ptr1 == ptr2); RawWaker::new(self_ptr, &Self::SHARED_WAKER_VTABLE) } fn wake_shared_waker(self_ptr: *const ()) { Self::wake_shared_waker_by_ref(self_ptr); Self::drop_shared_waker(self_ptr); } fn wake_shared_waker_by_ref(self_ptr: *const ()) { let self_weak = unsafe { Weak::from_raw(self_ptr as *const Self) }; if let Some(self_arc) = Weak::upgrade(&self_weak) { self_arc.rd_waker.wake(); self_arc.wr_waker.wake(); } let _ = self_weak.into_raw(); } fn drop_shared_waker(self_ptr: *const ()) { let _ = unsafe { Weak::from_raw(self_ptr as *const Self) }; } fn get_alpn_protocol(self: &Arc) -> Option { let mut tls_stream = self.tls_stream.lock(); tls_stream.get_alpn_protocol() } } struct ImplementReadTrait<'a, T>(&'a mut T); impl Read for ImplementReadTrait<'_, TcpStream> { fn read(&mut self, buf: &mut [u8]) -> io::Result { self.0.try_read(buf) } } struct ImplementWriteTrait<'a, T>(&'a mut T); impl Write for ImplementWriteTrait<'_, TcpStream> { fn write(&mut self, buf: &[u8]) -> io::Result { match self.0.try_write(buf) { Ok(n) => Ok(n), Err(err) if err.kind() == ErrorKind::WouldBlock => Ok(0), Err(err) => Err(err), } } fn flush(&mut self) -> io::Result<()> { Ok(()) } } pub fn init() -> Vec { vec![ ("op_tls_start", op_async(op_tls_start::

)), ("op_tls_connect", op_async(op_tls_connect::

)), ("op_tls_listen", op_sync(op_tls_listen::

)), ("op_tls_accept", op_async(op_tls_accept)), ("op_tls_handshake", op_async(op_tls_handshake)), ] } #[derive(Debug)] pub struct TlsStreamResource { rd: AsyncRefCell, wr: AsyncRefCell, // `None` when a TLS handshake hasn't been done. handshake_info: RefCell>, cancel_handle: CancelHandle, // Only read and handshake ops get canceled. } impl TlsStreamResource { pub fn new((rd, wr): (ReadHalf, WriteHalf)) -> Self { Self { rd: rd.into(), wr: wr.into(), handshake_info: RefCell::new(None), cancel_handle: Default::default(), } } pub fn into_inner(self) -> (ReadHalf, WriteHalf) { (self.rd.into_inner(), self.wr.into_inner()) } pub async fn read( self: Rc, mut buf: ZeroCopyBuf, ) -> Result { let mut rd = RcRef::map(&self, |r| &r.rd).borrow_mut().await; let cancel_handle = RcRef::map(&self, |r| &r.cancel_handle); let nread = rd.read(&mut buf).try_or_cancel(cancel_handle).await?; Ok(nread) } pub async fn write( self: Rc, buf: ZeroCopyBuf, ) -> Result { self.handshake().await?; let mut wr = RcRef::map(self, |r| &r.wr).borrow_mut().await; let nwritten = wr.write(&buf).await?; wr.flush().await?; Ok(nwritten) } pub async fn shutdown(self: Rc) -> Result<(), AnyError> { self.handshake().await?; let mut wr = RcRef::map(self, |r| &r.wr).borrow_mut().await; wr.shutdown().await?; Ok(()) } pub async fn handshake( self: &Rc, ) -> Result { if let Some(tls_info) = &*self.handshake_info.borrow() { return Ok(tls_info.clone()); } let mut wr = RcRef::map(self, |r| &r.wr).borrow_mut().await; let cancel_handle = RcRef::map(self, |r| &r.cancel_handle); wr.handshake().try_or_cancel(cancel_handle).await?; let alpn_protocol = wr.get_alpn_protocol(); let tls_info = TlsHandshakeInfo { alpn_protocol }; self.handshake_info.replace(Some(tls_info.clone())); Ok(tls_info) } } impl Resource for TlsStreamResource { fn name(&self) -> Cow { "tlsStream".into() } fn read(self: Rc, buf: ZeroCopyBuf) -> AsyncResult { Box::pin(self.read(buf)) } fn write(self: Rc, buf: ZeroCopyBuf) -> AsyncResult { Box::pin(self.write(buf)) } fn shutdown(self: Rc) -> AsyncResult<()> { Box::pin(self.shutdown()) } fn close(self: Rc) { self.cancel_handle.cancel(); } } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct ConnectTlsArgs { transport: String, hostname: String, port: u16, cert_file: Option, ca_certs: Vec, cert_chain: Option, private_key: Option, alpn_protocols: Option>, } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct StartTlsArgs { rid: ResourceId, ca_certs: Vec, hostname: String, alpn_protocols: Option>, } pub async fn op_tls_start( state: Rc>, args: StartTlsArgs, _: (), ) -> Result where NP: NetPermissions + 'static, { let rid = args.rid; let hostname = match &*args.hostname { "" => "localhost", n => n, }; { let mut s = state.borrow_mut(); let permissions = s.borrow_mut::(); permissions.check_net(&(hostname, Some(0)))?; } let ca_certs = args .ca_certs .into_iter() .map(|s| s.into_bytes()) .collect::>(); let hostname_dns = ServerName::try_from(hostname).map_err(|_| invalid_hostname(hostname))?; let unsafely_ignore_certificate_errors = state .borrow() .try_borrow::() .and_then(|it| it.0.clone()); // TODO(@justinmchase): Ideally the certificate store is created once // and not cloned. The store should be wrapped in Arc to reduce // copying memory unnecessarily. let root_cert_store = state .borrow() .borrow::() .root_cert_store .clone(); let resource_rc = state .borrow_mut() .resource_table .take::(rid)?; let resource = Rc::try_unwrap(resource_rc) .expect("Only a single use of this resource should happen"); let (read_half, write_half) = resource.into_inner(); let tcp_stream = read_half.reunite(write_half)?; let local_addr = tcp_stream.local_addr()?; let remote_addr = tcp_stream.peer_addr()?; let mut tls_config = create_client_config( root_cert_store, ca_certs, unsafely_ignore_certificate_errors, None, )?; if let Some(alpn_protocols) = args.alpn_protocols { super::check_unstable2(&state, "Deno.startTls#alpnProtocols"); tls_config.alpn_protocols = alpn_protocols.into_iter().map(|s| s.into_bytes()).collect(); } let tls_config = Arc::new(tls_config); let tls_stream = TlsStream::new_client_side(tcp_stream, tls_config, hostname_dns); let rid = { let mut state_ = state.borrow_mut(); state_ .resource_table .add(TlsStreamResource::new(tls_stream.into_split())) }; Ok(OpConn { rid, local_addr: Some(OpAddr::Tcp(IpAddr { hostname: local_addr.ip().to_string(), port: local_addr.port(), })), remote_addr: Some(OpAddr::Tcp(IpAddr { hostname: remote_addr.ip().to_string(), port: remote_addr.port(), })), }) } pub async fn op_tls_connect( state: Rc>, args: ConnectTlsArgs, _: (), ) -> Result where NP: NetPermissions + 'static, { assert_eq!(args.transport, "tcp"); let hostname = match &*args.hostname { "" => "localhost", n => n, }; let port = args.port; let cert_file = args.cert_file.as_deref(); let unsafely_ignore_certificate_errors = state .borrow() .try_borrow::() .and_then(|it| it.0.clone()); if args.cert_chain.is_some() { super::check_unstable2(&state, "ConnectTlsOptions.certChain"); } if args.private_key.is_some() { super::check_unstable2(&state, "ConnectTlsOptions.privateKey"); } { let mut s = state.borrow_mut(); let permissions = s.borrow_mut::(); permissions.check_net(&(hostname, Some(port)))?; if let Some(path) = cert_file { permissions.check_read(Path::new(path))?; } } let mut ca_certs = args .ca_certs .into_iter() .map(|s| s.into_bytes()) .collect::>(); if let Some(path) = cert_file { let mut buf = Vec::new(); File::open(path)?.read_to_end(&mut buf)?; ca_certs.push(buf); }; let root_cert_store = state .borrow() .borrow::() .root_cert_store .clone(); let hostname_dns = ServerName::try_from(hostname).map_err(|_| invalid_hostname(hostname))?; let connect_addr = resolve_addr(hostname, port) .await? .next() .ok_or_else(|| generic_error("No resolved address found"))?; let tcp_stream = TcpStream::connect(connect_addr).await?; let local_addr = tcp_stream.local_addr()?; let remote_addr = tcp_stream.peer_addr()?; let cert_chain_and_key = if args.cert_chain.is_some() || args.private_key.is_some() { let cert_chain = args .cert_chain .ok_or_else(|| type_error("No certificate chain provided"))?; let private_key = args .private_key .ok_or_else(|| type_error("No private key provided"))?; Some((cert_chain, private_key)) } else { None }; let mut tls_config = create_client_config( root_cert_store, ca_certs, unsafely_ignore_certificate_errors, cert_chain_and_key, )?; if let Some(alpn_protocols) = args.alpn_protocols { super::check_unstable2(&state, "Deno.connectTls#alpnProtocols"); tls_config.alpn_protocols = alpn_protocols.into_iter().map(|s| s.into_bytes()).collect(); } let tls_config = Arc::new(tls_config); let tls_stream = TlsStream::new_client_side(tcp_stream, tls_config, hostname_dns); let rid = { let mut state_ = state.borrow_mut(); state_ .resource_table .add(TlsStreamResource::new(tls_stream.into_split())) }; Ok(OpConn { rid, local_addr: Some(OpAddr::Tcp(IpAddr { hostname: local_addr.ip().to_string(), port: local_addr.port(), })), remote_addr: Some(OpAddr::Tcp(IpAddr { hostname: remote_addr.ip().to_string(), port: remote_addr.port(), })), }) } fn load_certs_from_file(path: &str) -> Result, AnyError> { let cert_file = File::open(path)?; let reader = &mut BufReader::new(cert_file); load_certs(reader) } fn load_private_keys_from_file( path: &str, ) -> Result, AnyError> { let key_bytes = std::fs::read(path)?; load_private_keys(&key_bytes) } pub struct TlsListenerResource { tcp_listener: AsyncRefCell, tls_config: Arc, cancel_handle: CancelHandle, } impl Resource for TlsListenerResource { fn name(&self) -> Cow { "tlsListener".into() } fn close(self: Rc) { self.cancel_handle.cancel(); } } #[derive(Deserialize)] #[serde(rename_all = "camelCase")] pub struct ListenTlsArgs { transport: String, hostname: String, port: u16, cert_file: String, key_file: String, alpn_protocols: Option>, } pub fn op_tls_listen( state: &mut OpState, args: ListenTlsArgs, _: (), ) -> Result where NP: NetPermissions + 'static, { assert_eq!(args.transport, "tcp"); let hostname = &*args.hostname; let port = args.port; let cert_file = &*args.cert_file; let key_file = &*args.key_file; { let permissions = state.borrow_mut::(); permissions.check_net(&(hostname, Some(port)))?; permissions.check_read(Path::new(cert_file))?; permissions.check_read(Path::new(key_file))?; } let mut tls_config = ServerConfig::builder() .with_safe_defaults() .with_no_client_auth() .with_single_cert( load_certs_from_file(cert_file)?, load_private_keys_from_file(key_file)?.remove(0), ) .expect("invalid key or certificate"); if let Some(alpn_protocols) = args.alpn_protocols { super::check_unstable(state, "Deno.listenTls#alpn_protocols"); tls_config.alpn_protocols = alpn_protocols.into_iter().map(|s| s.into_bytes()).collect(); } let bind_addr = resolve_addr_sync(hostname, port)? .next() .ok_or_else(|| generic_error("No resolved address found"))?; let std_listener = std::net::TcpListener::bind(bind_addr)?; std_listener.set_nonblocking(true)?; let tcp_listener = TcpListener::from_std(std_listener)?; let local_addr = tcp_listener.local_addr()?; let tls_listener_resource = TlsListenerResource { tcp_listener: AsyncRefCell::new(tcp_listener), tls_config: Arc::new(tls_config), cancel_handle: Default::default(), }; let rid = state.resource_table.add(tls_listener_resource); Ok(OpConn { rid, local_addr: Some(OpAddr::Tcp(IpAddr { hostname: local_addr.ip().to_string(), port: local_addr.port(), })), remote_addr: None, }) } pub async fn op_tls_accept( state: Rc>, rid: ResourceId, _: (), ) -> Result { let resource = state .borrow() .resource_table .get::(rid) .map_err(|_| bad_resource("Listener has been closed"))?; let cancel_handle = RcRef::map(&resource, |r| &r.cancel_handle); let tcp_listener = RcRef::map(&resource, |r| &r.tcp_listener) .try_borrow_mut() .ok_or_else(|| custom_error("Busy", "Another accept task is ongoing"))?; let (tcp_stream, remote_addr) = match tcp_listener.accept().try_or_cancel(&cancel_handle).await { Ok(tuple) => tuple, Err(err) if err.kind() == ErrorKind::Interrupted => { // FIXME(bartlomieju): compatibility with current JS implementation. return Err(bad_resource("Listener has been closed")); } Err(err) => return Err(err.into()), }; let local_addr = tcp_stream.local_addr()?; let tls_stream = TlsStream::new_server_side(tcp_stream, resource.tls_config.clone()); let rid = { let mut state_ = state.borrow_mut(); state_ .resource_table .add(TlsStreamResource::new(tls_stream.into_split())) }; Ok(OpConn { rid, local_addr: Some(OpAddr::Tcp(IpAddr { hostname: local_addr.ip().to_string(), port: local_addr.port(), })), remote_addr: Some(OpAddr::Tcp(IpAddr { hostname: remote_addr.ip().to_string(), port: remote_addr.port(), })), }) } pub async fn op_tls_handshake( state: Rc>, rid: ResourceId, _: (), ) -> Result { let resource = state .borrow() .resource_table .get::(rid)?; resource.handshake().await }