hickory_proto/rustls/tls_stream.rs
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// Copyright 2015-2016 Benjamin Fry <benjaminfry@me.com>
//
// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
// https://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// https://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
//! DNS over TLS I/O stream implementation for Rustls
use std::future::Future;
use std::io;
use std::net::SocketAddr;
use std::pin::Pin;
use std::sync::Arc;
use rustls::pki_types::ServerName;
use rustls::ClientConfig;
use tokio;
use tokio::net::TcpStream as TokioTcpStream;
use tokio_rustls::TlsConnector;
use crate::runtime::iocompat::{AsyncIoStdAsTokio, AsyncIoTokioAsStd};
use crate::runtime::RuntimeProvider;
use crate::tcp::{DnsTcpStream, TcpStream};
use crate::xfer::{BufDnsStreamHandle, StreamReceiver};
/// Predefined type for abstracting the TlsClientStream with TokioTls
pub type TokioTlsClientStream<S> = tokio_rustls::client::TlsStream<AsyncIoStdAsTokio<S>>;
/// Predefined type for abstracting the TlsServerStream with TokioTls
pub type TokioTlsServerStream = tokio_rustls::server::TlsStream<TokioTcpStream>;
/// Predefined type for abstracting the base I/O TlsStream with TokioTls
pub type TlsStream<S> = TcpStream<S>;
/// Initializes a TlsStream with an existing tokio_tls::TlsStream.
///
/// This is intended for use with a TlsListener and Incoming connections
pub fn tls_from_stream<S: DnsTcpStream>(
stream: S,
peer_addr: SocketAddr,
) -> (TlsStream<S>, BufDnsStreamHandle) {
let (message_sender, outbound_messages) = BufDnsStreamHandle::new(peer_addr);
let stream = TcpStream::from_stream_with_receiver(stream, peer_addr, outbound_messages);
(stream, message_sender)
}
/// Creates a new TlsStream to the specified name_server
///
/// [RFC 7858](https://tools.ietf.org/html/rfc7858), DNS over TLS, May 2016
///
/// ```text
/// 3.2. TLS Handshake and Authentication
///
/// Once the DNS client succeeds in connecting via TCP on the well-known
/// port for DNS over TLS, it proceeds with the TLS handshake [RFC5246],
/// following the best practices specified in [BCP195].
///
/// The client will then authenticate the server, if required. This
/// document does not propose new ideas for authentication. Depending on
/// the privacy profile in use (Section 4), the DNS client may choose not
/// to require authentication of the server, or it may make use of a
/// trusted Subject Public Key Info (SPKI) Fingerprint pin set.
///
/// After TLS negotiation completes, the connection will be encrypted and
/// is now protected from eavesdropping.
/// ```
///
/// # Arguments
///
/// * `name_server` - IP and Port for the remote DNS resolver
/// * `bind_addr` - IP and port to connect from
/// * `dns_name` - The DNS name, Subject Public Key Info (SPKI) name, as associated to a certificate
#[allow(clippy::type_complexity)]
pub fn tls_connect<P: RuntimeProvider>(
name_server: SocketAddr,
dns_name: String,
client_config: Arc<ClientConfig>,
provider: P,
) -> (
Pin<
Box<
dyn Future<
Output = Result<
TlsStream<AsyncIoTokioAsStd<TokioTlsClientStream<P::Tcp>>>,
io::Error,
>,
> + Send,
>,
>,
BufDnsStreamHandle,
) {
tls_connect_with_bind_addr(name_server, None, dns_name, client_config, provider)
}
/// Creates a new TlsStream to the specified name_server connecting from a specific address.
///
/// # Arguments
///
/// * `name_server` - IP and Port for the remote DNS resolver
/// * `bind_addr` - IP and port to connect from
/// * `dns_name` - The DNS name, Subject Public Key Info (SPKI) name, as associated to a certificate
#[allow(clippy::type_complexity)]
pub fn tls_connect_with_bind_addr<P: RuntimeProvider>(
name_server: SocketAddr,
bind_addr: Option<SocketAddr>,
dns_name: String,
client_config: Arc<ClientConfig>,
provider: P,
) -> (
Pin<
Box<
dyn Future<
Output = Result<
TlsStream<AsyncIoTokioAsStd<TokioTlsClientStream<P::Tcp>>>,
io::Error,
>,
> + Send,
>,
>,
BufDnsStreamHandle,
) {
let (message_sender, outbound_messages) = BufDnsStreamHandle::new(name_server);
let early_data_enabled = client_config.enable_early_data;
let tls_connector = TlsConnector::from(client_config).early_data(early_data_enabled);
// This set of futures collapses the next tcp socket into a stream which can be used for
// sending and receiving tcp packets.
let stream = Box::pin(connect_tls(
tls_connector,
name_server,
bind_addr,
dns_name,
outbound_messages,
provider,
));
(stream, message_sender)
}
/// Creates a new TlsStream to the specified name_server connecting from a specific address.
///
/// # Arguments
///
/// * `name_server` - IP and Port for the remote DNS resolver
/// * `bind_addr` - IP and port to connect from
/// * `dns_name` - The DNS name, Subject Public Key Info (SPKI) name, as associated to a certificate
#[allow(clippy::type_complexity)]
pub fn tls_connect_with_future<S, F>(
future: F,
name_server: SocketAddr,
dns_name: String,
client_config: Arc<ClientConfig>,
) -> (
Pin<
Box<
dyn Future<
Output = Result<
TlsStream<AsyncIoTokioAsStd<TokioTlsClientStream<S>>>,
io::Error,
>,
> + Send,
>,
>,
BufDnsStreamHandle,
)
where
S: DnsTcpStream,
F: Future<Output = io::Result<S>> + Send + Unpin + 'static,
{
let (message_sender, outbound_messages) = BufDnsStreamHandle::new(name_server);
let early_data_enabled = client_config.enable_early_data;
let tls_connector = TlsConnector::from(client_config).early_data(early_data_enabled);
// This set of futures collapses the next tcp socket into a stream which can be used for
// sending and receiving tcp packets.
let stream = Box::pin(connect_tls_with_future(
tls_connector,
future,
name_server,
dns_name,
outbound_messages,
));
(stream, message_sender)
}
async fn connect_tls<P: RuntimeProvider>(
tls_connector: TlsConnector,
name_server: SocketAddr,
bind_addr: Option<SocketAddr>,
dns_name: String,
outbound_messages: StreamReceiver,
provider: P,
) -> io::Result<TcpStream<AsyncIoTokioAsStd<TokioTlsClientStream<P::Tcp>>>> {
let tcp = provider.connect_tcp(name_server, bind_addr, None);
connect_tls_with_future(tls_connector, tcp, name_server, dns_name, outbound_messages).await
}
async fn connect_tls_with_future<S, F>(
tls_connector: TlsConnector,
future: F,
name_server: SocketAddr,
server_name: String,
outbound_messages: StreamReceiver,
) -> io::Result<TcpStream<AsyncIoTokioAsStd<TokioTlsClientStream<S>>>>
where
S: DnsTcpStream,
F: Future<Output = io::Result<S>> + Send + Unpin,
{
let dns_name = match ServerName::try_from(server_name) {
Ok(name) => name,
Err(_) => return Err(io::Error::new(io::ErrorKind::InvalidInput, "bad dns_name")),
};
let stream = future.await?;
let s = tls_connector
.connect(dns_name, AsyncIoStdAsTokio(stream))
.await
.map_err(|e| io::Error::new(io::ErrorKind::ConnectionRefused, format!("tls error: {e}")))?;
Ok(TcpStream::from_stream_with_receiver(
AsyncIoTokioAsStd(s),
name_server,
outbound_messages,
))
}