tools/apps/src/client.rs - third_party/rust-mirrors/quiche - Git at Google

 // Copyright (C) 2020, Cloudflare, Inc.
 // All rights reserved.
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright notice,
 //       this list of conditions and the following disclaimer.
 //
 //     * Redistributions in binary form must reproduce the above copyright
 //       notice, this list of conditions and the following disclaimer in the
 //       documentation and/or other materials provided with the distribution.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
 // IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
 // THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 // PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
 // CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
 // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
 // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
 // PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
 // LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
 // NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 // SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 use crate::args::*;
 use crate::common::*;

 use std::net::ToSocketAddrs;

 use std::io::prelude::*;

 use std::rc::Rc;

 use std::cell::RefCell;

 use ring::rand::*;

 const MAX_DATAGRAM_SIZE: usize = 1350;

 #[derive(Debug)]
 pub enum ClientError {
     HandshakeFail,
     HttpFail,
     Other(String),
 }

 pub fn connect(
     args: ClientArgs, conn_args: CommonArgs,
     output_sink: impl FnMut(String) + 'static,
 ) -> Result<(), ClientError> {
     let mut buf = [0; 65535];
     let mut out = [0; MAX_DATAGRAM_SIZE];

     let output_sink =
         Rc::new(RefCell::new(output_sink)) as Rc<RefCell<dyn FnMut(_)>>;

     // Setup the event loop.
     let poll = mio::Poll::new().unwrap();
     let mut events = mio::Events::with_capacity(1024);

     // We'll only connect to the first server provided in URL list.
     let connect_url = &args.urls[0];

     // Resolve server address.
     let peer_addr = if let Some(addr) = &args.connect_to {
         addr.parse().unwrap()
     } else {
         connect_url.to_socket_addrs().unwrap().next().unwrap()
     };

     // Bind to INADDR_ANY or IN6ADDR_ANY depending on the IP family of the
     // server address. This is needed on macOS and BSD variants that don't
     // support binding to IN6ADDR_ANY for both v4 and v6.
     let bind_addr = match peer_addr {
         std::net::SocketAddr::V4(_) => "0.0.0.0:0",
         std::net::SocketAddr::V6(_) => "[::]:0",
     };

     // Create the UDP socket backing the QUIC connection, and register it with
     // the event loop.
     let socket = std::net::UdpSocket::bind(bind_addr).unwrap();

     let socket = mio::net::UdpSocket::from_socket(socket).unwrap();
     poll.register(
         &socket,
         mio::Token(0),
         mio::Ready::readable(),
         mio::PollOpt::edge(),
     )
     .unwrap();

     // Create the configuration for the QUIC connection.
     let mut config = quiche::Config::new(args.version).unwrap();

     config.compress_certificates().unwrap();

     config.verify_peer(!args.no_verify);

     config.set_application_protos(&conn_args.alpns).unwrap();

     config.set_max_idle_timeout(conn_args.idle_timeout);
     config.set_max_recv_udp_payload_size(MAX_DATAGRAM_SIZE);
     config.set_max_send_udp_payload_size(MAX_DATAGRAM_SIZE);
     config.set_initial_max_data(conn_args.max_data);
     config.set_initial_max_stream_data_bidi_local(conn_args.max_stream_data);
     config.set_initial_max_stream_data_bidi_remote(conn_args.max_stream_data);
     config.set_initial_max_stream_data_uni(conn_args.max_stream_data);
     config.set_initial_max_streams_bidi(conn_args.max_streams_bidi);
     config.set_initial_max_streams_uni(conn_args.max_streams_uni);
     config.set_disable_active_migration(true);

     let mut keylog = None;

     if let Some(keylog_path) = std::env::var_os("SSLKEYLOGFILE") {
         let file = std::fs::OpenOptions::new()
             .create(true)
             .append(true)
             .open(keylog_path)
             .unwrap();

         keylog = Some(file);

         config.log_keys();
     }

     if conn_args.no_grease {
         config.grease(false);
     }

     if conn_args.early_data {
         config.enable_early_data();
     }

     config
         .set_cc_algorithm_name(&conn_args.cc_algorithm)
         .unwrap();

     if conn_args.disable_hystart {
         config.enable_hystart(false);
     }

     if conn_args.dgrams_enabled {
         config.enable_dgram(true, 1000, 1000);
     }

     let mut http_conn: Option<Box<dyn HttpConn>> = None;
     let mut siduck_conn: Option<SiDuckConn> = None;

     let mut app_proto_selected = false;

     // Generate a random source connection ID for the connection.
     let mut scid = [0; quiche::MAX_CONN_ID_LEN];
     SystemRandom::new().fill(&mut scid[..]).unwrap();

     let scid = quiche::ConnectionId::from_ref(&scid);

     // Create a QUIC connection and initiate handshake.
     let mut conn =
         quiche::connect(connect_url.domain(), &scid, peer_addr, &mut config)
             .unwrap();

     if let Some(keylog) = &mut keylog {
         if let Ok(keylog) = keylog.try_clone() {
             conn.set_keylog(Box::new(keylog));
         }
     }

     // Only bother with qlog if the user specified it.
     #[cfg(feature = "qlog")]
     {
         if let Some(dir) = std::env::var_os("QLOGDIR") {
             let id = format!("{:?}", scid);
             let writer = make_qlog_writer(&dir, "client", &id);

             conn.set_qlog(
                 std::boxed::Box::new(writer),
                 "quiche-client qlog".to_string(),
                 format!("{} id={}", "quiche-client qlog", id),
             );
         }
     }

     if let Some(session_file) = &args.session_file {
         if let Ok(session) = std::fs::read(session_file) {
             conn.set_session(&session).ok();
         }
     }

     info!(
         "connecting to {:} from {:} with scid {:?}",
         peer_addr,
         socket.local_addr().unwrap(),
         scid,
     );

     let (write, send_info) = conn.send(&mut out).expect("initial send failed");

     while let Err(e) = socket.send_to(&out[..write], &send_info.to) {
         if e.kind() == std::io::ErrorKind::WouldBlock {
             trace!("send() would block");
             continue;
         }

         return Err(ClientError::Other(format!("send() failed: {:?}", e)));
     }

     trace!("written {}", write);

     let app_data_start = std::time::Instant::now();

     let mut pkt_count = 0;

     loop {
         if !conn.is_in_early_data() || app_proto_selected {
             poll.poll(&mut events, conn.timeout()).unwrap();
         }

         // Read incoming UDP packets from the socket and feed them to quiche,
         // until there are no more packets to read.
         'read: loop {
             // If the event loop reported no events, it means that the timeout
             // has expired, so handle it without attempting to read packets. We
             // will then proceed with the send loop.
             if events.is_empty() {
                 trace!("timed out");

                 conn.on_timeout();

                 break 'read;
             }

             let (len, from) = match socket.recv_from(&mut buf) {
                 Ok(v) => v,

                 Err(e) => {
                     // There are no more UDP packets to read, so end the read
                     // loop.
                     if e.kind() == std::io::ErrorKind::WouldBlock {
                         trace!("recv() would block");
                         break 'read;
                     }

                     return Err(ClientError::Other(format!(
                         "recv() failed: {:?}",
                         e
                     )));
                 },
             };

             trace!("got {} bytes", len);

             if let Some(target_path) = conn_args.dump_packet_path.as_ref() {
                 let path = format!("{}/{}.pkt", target_path, pkt_count);

                 if let Ok(f) = std::fs::File::create(&path) {
                     let mut f = std::io::BufWriter::new(f);
                     f.write_all(&buf[..len]).ok();
                 }
             }

             pkt_count += 1;

             let recv_info = quiche::RecvInfo { from };

             // Process potentially coalesced packets.
             let read = match conn.recv(&mut buf[..len], recv_info) {
                 Ok(v) => v,

                 Err(e) => {
                     error!("recv failed: {:?}", e);
                     continue 'read;
                 },
             };

             trace!("processed {} bytes", read);
         }

         trace!("done reading");

         if conn.is_closed() {
             info!("connection closed, {:?}", conn.stats());

             if !conn.is_established() {
                 error!(
                     "connection timed out after {:?}",
                     app_data_start.elapsed(),
                 );

                 return Err(ClientError::HandshakeFail);
             }

             if let Some(session_file) = &args.session_file {
                 if let Some(session) = conn.session() {
                     std::fs::write(session_file, &session).ok();
                 }
             }

             if let Some(h_conn) = http_conn {
                 if h_conn.report_incomplete(&app_data_start) {
                     return Err(ClientError::HttpFail);
                 }
             }

             if let Some(si_conn) = siduck_conn {
                 si_conn.report_incomplete(&app_data_start);
             }

             break;
         }

         // Create a new application protocol session once the QUIC connection is
         // established.
         if (conn.is_established() || conn.is_in_early_data()) &&
             !app_proto_selected
         {
             // At this stage the ALPN negotiation succeeded and selected a
             // single application protocol name. We'll use this to construct
             // the correct type of HttpConn but `application_proto()`
             // returns a slice, so we have to convert it to a str in order
             // to compare to our lists of protocols. We `unwrap()` because
             // we need the value and if something fails at this stage, there
             // is not much anyone can do to recover.

             let app_proto = conn.application_proto();
             let app_proto = &std::str::from_utf8(&app_proto).unwrap();

             if alpns::HTTP_09.contains(app_proto) {
                 http_conn = Some(Http09Conn::with_urls(
                     &args.urls,
                     args.reqs_cardinal,
                     Rc::clone(&output_sink),
                 ));

                 app_proto_selected = true;
             } else if alpns::HTTP_3.contains(app_proto) {
                 let dgram_sender = if conn_args.dgrams_enabled {
                     Some(Http3DgramSender::new(
                         conn_args.dgram_count,
                         conn_args.dgram_data.clone(),
                         0,
                     ))
                 } else {
                     None
                 };

                 http_conn = Some(Http3Conn::with_urls(
                     &mut conn,
                     &args.urls,
                     args.reqs_cardinal,
                     &args.req_headers,
                     &args.body,
                     &args.method,
                     args.dump_json,
                     dgram_sender,
                     Rc::clone(&output_sink),
                 ));

                 app_proto_selected = true;
             } else if alpns::SIDUCK.contains(app_proto) {
                 siduck_conn = Some(SiDuckConn::new(
                     conn_args.dgram_count,
                     conn_args.dgram_data.clone(),
                 ));

                 app_proto_selected = true;
             }
         }

         // If we have an HTTP connection, first issue the requests then
         // process received data.
         if let Some(h_conn) = http_conn.as_mut() {
             h_conn.send_requests(&mut conn, &args.dump_response_path);
             h_conn.handle_responses(&mut conn, &mut buf, &app_data_start);
         }

         // If we have a siduck connection, first issue the quacks then
         // process received data.
         if let Some(si_conn) = siduck_conn.as_mut() {
             si_conn.send_quacks(&mut conn);
             si_conn.handle_quack_acks(&mut conn, &mut buf, &app_data_start);
         }

         // Generate outgoing QUIC packets and send them on the UDP socket, until
         // quiche reports that there are no more packets to be sent.
         loop {
             let (write, send_info) = match conn.send(&mut out) {
                 Ok(v) => v,

                 Err(quiche::Error::Done) => {
                     trace!("done writing");
                     break;
                 },

                 Err(e) => {
                     error!("send failed: {:?}", e);

                     conn.close(false, 0x1, b"fail").ok();
                     break;
                 },
             };

             if let Err(e) = socket.send_to(&out[..write], &send_info.to) {
                 if e.kind() == std::io::ErrorKind::WouldBlock {
                     trace!("send() would block");
                     break;
                 }

                 return Err(ClientError::Other(format!(
                     "send() failed: {:?}",
                     e
                 )));
             }

             trace!("written {}", write);
         }

         if conn.is_closed() {
             info!("connection closed, {:?}", conn.stats());

             if !conn.is_established() {
                 error!(
                     "connection timed out after {:?}",
                     app_data_start.elapsed(),
                 );

                 return Err(ClientError::HandshakeFail);
             }

             if let Some(session_file) = &args.session_file {
                 if let Some(session) = conn.session() {
                     std::fs::write(session_file, &session).ok();
                 }
             }

             if let Some(h_conn) = http_conn {
                 if h_conn.report_incomplete(&app_data_start) {
                     return Err(ClientError::HttpFail);
                 }
             }

             if let Some(si_conn) = siduck_conn {
                 si_conn.report_incomplete(&app_data_start);
             }

             break;
         }
     }

     Ok(())
 }
	// Copyright (C) 2020, Cloudflare, Inc.
	// All rights reserved.
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright notice,
	// this list of conditions and the following disclaimer.
	//
	// * Redistributions in binary form must reproduce the above copyright
	// notice, this list of conditions and the following disclaimer in the
	// documentation and/or other materials provided with the distribution.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS
	// IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
	// THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	// PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
	// CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	// PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
	// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
	// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
	// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	use crate::args::*;
	use crate::common::*;

	use std::net::ToSocketAddrs;

	use std::io::prelude::*;

	use std::rc::Rc;

	use std::cell::RefCell;

	use ring::rand::*;

	const MAX_DATAGRAM_SIZE: usize = 1350;

	#[derive(Debug)]
	pub enum ClientError {
	HandshakeFail,
	HttpFail,
	Other(String),
	}

	pub fn connect(
	args: ClientArgs, conn_args: CommonArgs,
	output_sink: impl FnMut(String) + 'static,
	) -> Result<(), ClientError> {
	let mut buf = [0; 65535];
	let mut out = [0; MAX_DATAGRAM_SIZE];

	let output_sink =
	Rc::new(RefCell::new(output_sink)) as Rc<RefCell<dyn FnMut(_)>>;

	// Setup the event loop.
	let poll = mio::Poll::new().unwrap();
	let mut events = mio::Events::with_capacity(1024);

	// We'll only connect to the first server provided in URL list.
	let connect_url = &args.urls[0];

	// Resolve server address.
	let peer_addr = if let Some(addr) = &args.connect_to {
	addr.parse().unwrap()
	} else {
	connect_url.to_socket_addrs().unwrap().next().unwrap()
	};

	// Bind to INADDR_ANY or IN6ADDR_ANY depending on the IP family of the
	// server address. This is needed on macOS and BSD variants that don't
	// support binding to IN6ADDR_ANY for both v4 and v6.
	let bind_addr = match peer_addr {
	std::net::SocketAddr::V4(_) => "0.0.0.0:0",
	std::net::SocketAddr::V6(_) => "[::]:0",
	};

	// Create the UDP socket backing the QUIC connection, and register it with
	// the event loop.
	let socket = std::net::UdpSocket::bind(bind_addr).unwrap();

	let socket = mio::net::UdpSocket::from_socket(socket).unwrap();
	poll.register(
	&socket,
	mio::Token(0),
	mio::Ready::readable(),
	mio::PollOpt::edge(),
	)
	.unwrap();

	// Create the configuration for the QUIC connection.
	let mut config = quiche::Config::new(args.version).unwrap();

	config.compress_certificates().unwrap();

	config.verify_peer(!args.no_verify);

	config.set_application_protos(&conn_args.alpns).unwrap();

	config.set_max_idle_timeout(conn_args.idle_timeout);
	config.set_max_recv_udp_payload_size(MAX_DATAGRAM_SIZE);
	config.set_max_send_udp_payload_size(MAX_DATAGRAM_SIZE);
	config.set_initial_max_data(conn_args.max_data);
	config.set_initial_max_stream_data_bidi_local(conn_args.max_stream_data);
	config.set_initial_max_stream_data_bidi_remote(conn_args.max_stream_data);
	config.set_initial_max_stream_data_uni(conn_args.max_stream_data);
	config.set_initial_max_streams_bidi(conn_args.max_streams_bidi);
	config.set_initial_max_streams_uni(conn_args.max_streams_uni);
	config.set_disable_active_migration(true);

	let mut keylog = None;

	if let Some(keylog_path) = std::env::var_os("SSLKEYLOGFILE") {
	let file = std::fs::OpenOptions::new()
	.create(true)
	.append(true)
	.open(keylog_path)
	.unwrap();

	keylog = Some(file);

	config.log_keys();
	}

	if conn_args.no_grease {
	config.grease(false);
	}

	if conn_args.early_data {
	config.enable_early_data();
	}

	config
	.set_cc_algorithm_name(&conn_args.cc_algorithm)
	.unwrap();

	if conn_args.disable_hystart {
	config.enable_hystart(false);
	}

	if conn_args.dgrams_enabled {
	config.enable_dgram(true, 1000, 1000);
	}

	let mut http_conn: Option<Box<dyn HttpConn>> = None;
	let mut siduck_conn: Option<SiDuckConn> = None;

	let mut app_proto_selected = false;

	// Generate a random source connection ID for the connection.
	let mut scid = [0; quiche::MAX_CONN_ID_LEN];
	SystemRandom::new().fill(&mut scid[..]).unwrap();

	let scid = quiche::ConnectionId::from_ref(&scid);

	// Create a QUIC connection and initiate handshake.
	let mut conn =
	quiche::connect(connect_url.domain(), &scid, peer_addr, &mut config)
	.unwrap();

	if let Some(keylog) = &mut keylog {
	if let Ok(keylog) = keylog.try_clone() {
	conn.set_keylog(Box::new(keylog));
	}
	}

	// Only bother with qlog if the user specified it.
	#[cfg(feature = "qlog")]
	{
	if let Some(dir) = std::env::var_os("QLOGDIR") {
	let id = format!("{:?}", scid);
	let writer = make_qlog_writer(&dir, "client", &id);

	conn.set_qlog(
	std::boxed::Box::new(writer),
	"quiche-client qlog".to_string(),
	format!("{} id={}", "quiche-client qlog", id),
	);
	}
	}

	if let Some(session_file) = &args.session_file {
	if let Ok(session) = std::fs::read(session_file) {
	conn.set_session(&session).ok();
	}
	}

	info!(
	"connecting to {:} from {:} with scid {:?}",
	peer_addr,
	socket.local_addr().unwrap(),
	scid,
	);

	let (write, send_info) = conn.send(&mut out).expect("initial send failed");

	while let Err(e) = socket.send_to(&out[..write], &send_info.to) {
	if e.kind() == std::io::ErrorKind::WouldBlock {
	trace!("send() would block");
	continue;
	}

	return Err(ClientError::Other(format!("send() failed: {:?}", e)));
	}

	trace!("written {}", write);

	let app_data_start = std::time::Instant::now();

	let mut pkt_count = 0;

	loop {
	if !conn.is_in_early_data() \|\| app_proto_selected {
	poll.poll(&mut events, conn.timeout()).unwrap();
	}

	// Read incoming UDP packets from the socket and feed them to quiche,
	// until there are no more packets to read.
	'read: loop {
	// If the event loop reported no events, it means that the timeout
	// has expired, so handle it without attempting to read packets. We
	// will then proceed with the send loop.
	if events.is_empty() {
	trace!("timed out");

	conn.on_timeout();

	break 'read;
	}

	let (len, from) = match socket.recv_from(&mut buf) {
	Ok(v) => v,

	Err(e) => {
	// There are no more UDP packets to read, so end the read
	// loop.
	if e.kind() == std::io::ErrorKind::WouldBlock {
	trace!("recv() would block");
	break 'read;
	}

	return Err(ClientError::Other(format!(
	"recv() failed: {:?}",
	e
	)));
	},
	};

	trace!("got {} bytes", len);

	if let Some(target_path) = conn_args.dump_packet_path.as_ref() {
	let path = format!("{}/{}.pkt", target_path, pkt_count);

	if let Ok(f) = std::fs::File::create(&path) {
	let mut f = std::io::BufWriter::new(f);
	f.write_all(&buf[..len]).ok();
	}
	}

	pkt_count += 1;

	let recv_info = quiche::RecvInfo { from };

	// Process potentially coalesced packets.
	let read = match conn.recv(&mut buf[..len], recv_info) {
	Ok(v) => v,

	Err(e) => {
	error!("recv failed: {:?}", e);
	continue 'read;
	},
	};

	trace!("processed {} bytes", read);
	}

	trace!("done reading");

	if conn.is_closed() {
	info!("connection closed, {:?}", conn.stats());

	if !conn.is_established() {
	error!(
	"connection timed out after {:?}",
	app_data_start.elapsed(),
	);

	return Err(ClientError::HandshakeFail);
	}

	if let Some(session_file) = &args.session_file {
	if let Some(session) = conn.session() {
	std::fs::write(session_file, &session).ok();
	}
	}

	if let Some(h_conn) = http_conn {
	if h_conn.report_incomplete(&app_data_start) {
	return Err(ClientError::HttpFail);
	}
	}

	if let Some(si_conn) = siduck_conn {
	si_conn.report_incomplete(&app_data_start);
	}

	break;
	}

	// Create a new application protocol session once the QUIC connection is
	// established.
	if (conn.is_established() \|\| conn.is_in_early_data()) &&
	!app_proto_selected
	{
	// At this stage the ALPN negotiation succeeded and selected a
	// single application protocol name. We'll use this to construct
	// the correct type of HttpConn but `application_proto()`
	// returns a slice, so we have to convert it to a str in order
	// to compare to our lists of protocols. We `unwrap()` because
	// we need the value and if something fails at this stage, there
	// is not much anyone can do to recover.

	let app_proto = conn.application_proto();
	let app_proto = &std::str::from_utf8(&app_proto).unwrap();

	if alpns::HTTP_09.contains(app_proto) {
	http_conn = Some(Http09Conn::with_urls(
	&args.urls,
	args.reqs_cardinal,
	Rc::clone(&output_sink),
	));

	app_proto_selected = true;
	} else if alpns::HTTP_3.contains(app_proto) {
	let dgram_sender = if conn_args.dgrams_enabled {
	Some(Http3DgramSender::new(
	conn_args.dgram_count,
	conn_args.dgram_data.clone(),
	0,
	))
	} else {
	None
	};

	http_conn = Some(Http3Conn::with_urls(
	&mut conn,
	&args.urls,
	args.reqs_cardinal,
	&args.req_headers,
	&args.body,
	&args.method,
	args.dump_json,
	dgram_sender,
	Rc::clone(&output_sink),
	));

	app_proto_selected = true;
	} else if alpns::SIDUCK.contains(app_proto) {
	siduck_conn = Some(SiDuckConn::new(
	conn_args.dgram_count,
	conn_args.dgram_data.clone(),
	));

	app_proto_selected = true;
	}
	}

	// If we have an HTTP connection, first issue the requests then
	// process received data.
	if let Some(h_conn) = http_conn.as_mut() {
	h_conn.send_requests(&mut conn, &args.dump_response_path);
	h_conn.handle_responses(&mut conn, &mut buf, &app_data_start);
	}

	// If we have a siduck connection, first issue the quacks then
	// process received data.
	if let Some(si_conn) = siduck_conn.as_mut() {
	si_conn.send_quacks(&mut conn);
	si_conn.handle_quack_acks(&mut conn, &mut buf, &app_data_start);
	}

	// Generate outgoing QUIC packets and send them on the UDP socket, until
	// quiche reports that there are no more packets to be sent.
	loop {
	let (write, send_info) = match conn.send(&mut out) {
	Ok(v) => v,

	Err(quiche::Error::Done) => {
	trace!("done writing");
	break;
	},

	Err(e) => {
	error!("send failed: {:?}", e);

	conn.close(false, 0x1, b"fail").ok();
	break;
	},
	};

	if let Err(e) = socket.send_to(&out[..write], &send_info.to) {
	if e.kind() == std::io::ErrorKind::WouldBlock {
	trace!("send() would block");
	break;
	}

	return Err(ClientError::Other(format!(
	"send() failed: {:?}",
	e
	)));
	}

	trace!("written {}", write);
	}

	if conn.is_closed() {
	info!("connection closed, {:?}", conn.stats());

	if !conn.is_established() {
	error!(
	"connection timed out after {:?}",
	app_data_start.elapsed(),
	);

	return Err(ClientError::HandshakeFail);
	}

	if let Some(session_file) = &args.session_file {
	if let Some(session) = conn.session() {
	std::fs::write(session_file, &session).ok();
	}
	}

	if let Some(h_conn) = http_conn {
	if h_conn.report_incomplete(&app_data_start) {
	return Err(ClientError::HttpFail);
	}
	}

	if let Some(si_conn) = siduck_conn {
	si_conn.report_incomplete(&app_data_start);
	}

	break;
	}
	}

	Ok(())
	}