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// Copyright (C) 2018-2019, 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.
#[macro_use]
extern crate log;
use std::net;
use std::collections::HashMap;
use ring::rand::*;
const MAX_DATAGRAM_SIZE: usize = 1350;
struct PartialResponse {
body: Vec<u8>,
written: usize,
}
struct Client {
conn: std::pin::Pin<Box<quiche::Connection>>,
partial_responses: HashMap<u64, PartialResponse>,
}
type ClientMap = HashMap<Vec<u8>, (net::SocketAddr, Client)>;
fn main() {
let mut buf = [0; 65535];
let mut out = [0; MAX_DATAGRAM_SIZE];
let mut args = std::env::args();
let cmd = &args.next().unwrap();
if args.len() != 0 {
println!("Usage: {}", cmd);
println!("\nSee tools/apps/ for more complete implementations.");
return;
}
// Setup the event loop.
let poll = mio::Poll::new().unwrap();
let mut events = mio::Events::with_capacity(1024);
// Create the UDP listening socket, and register it with the event loop.
let socket = net::UdpSocket::bind("127.0.0.1:4433").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 connections.
let mut config = quiche::Config::new(quiche::PROTOCOL_VERSION).unwrap();
config
.load_cert_chain_from_pem_file("examples/cert.crt")
.unwrap();
config
.load_priv_key_from_pem_file("examples/cert.key")
.unwrap();
config
.set_application_protos(b"\x05hq-29\x05hq-28\x05hq-27\x08http/0.9")
.unwrap();
config.set_max_idle_timeout(5000);
config.set_max_udp_payload_size(MAX_DATAGRAM_SIZE as u64);
config.set_initial_max_data(10_000_000);
config.set_initial_max_stream_data_bidi_local(1_000_000);
config.set_initial_max_stream_data_bidi_remote(1_000_000);
config.set_initial_max_stream_data_uni(1_000_000);
config.set_initial_max_streams_bidi(100);
config.set_initial_max_streams_uni(100);
config.set_disable_active_migration(true);
config.enable_early_data();
let rng = SystemRandom::new();
let conn_id_seed =
ring::hmac::Key::generate(ring::hmac::HMAC_SHA256, &rng).unwrap();
let mut clients = ClientMap::new();
loop {
// Find the shorter timeout from all the active connections.
//
// TODO: use event loop that properly supports timers
let timeout =
clients.values().filter_map(|(_, c)| c.conn.timeout()).min();
poll.poll(&mut events, 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() {
debug!("timed out");
clients.values_mut().for_each(|(_, c)| c.conn.on_timeout());
break 'read;
}
let (len, src) = 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 {
debug!("recv() would block");
break 'read;
}
panic!("recv() failed: {:?}", e);
},
};
debug!("got {} bytes", len);
let pkt_buf = &mut buf[..len];
// Parse the QUIC packet's header.
let hdr = match quiche::Header::from_slice(
pkt_buf,
quiche::MAX_CONN_ID_LEN,
) {
Ok(v) => v,
Err(e) => {
error!("Parsing packet header failed: {:?}", e);
continue 'read;
},
};
trace!("got packet {:?}", hdr);
let conn_id = ring::hmac::sign(&conn_id_seed, &hdr.dcid);
let conn_id = &conn_id.as_ref()[..quiche::MAX_CONN_ID_LEN];
// Lookup a connection based on the packet's connection ID. If there
// is no connection matching, create a new one.
let (_, client) = if !clients.contains_key(&hdr.dcid) &&
!clients.contains_key(conn_id)
{
if hdr.ty != quiche::Type::Initial {
error!("Packet is not Initial");
continue 'read;
}
if !quiche::version_is_supported(hdr.version) {
warn!("Doing version negotiation");
let len =
quiche::negotiate_version(&hdr.scid, &hdr.dcid, &mut out)
.unwrap();
let out = &out[..len];
if let Err(e) = socket.send_to(out, &src) {
if e.kind() == std::io::ErrorKind::WouldBlock {
debug!("send() would block");
break;
}
panic!("send() failed: {:?}", e);
}
continue 'read;
}
let mut scid = [0; quiche::MAX_CONN_ID_LEN];
scid.copy_from_slice(&conn_id);
// Token is always present in Initial packets.
let token = hdr.token.as_ref().unwrap();
// Do stateless retry if the client didn't send a token.
if token.is_empty() {
warn!("Doing stateless retry");
let new_token = mint_token(&hdr, &src);
let len = quiche::retry(
&hdr.scid,
&hdr.dcid,
&scid,
&new_token,
hdr.version,
&mut out,
)
.unwrap();
let out = &out[..len];
if let Err(e) = socket.send_to(out, &src) {
if e.kind() == std::io::ErrorKind::WouldBlock {
debug!("send() would block");
break;
}
panic!("send() failed: {:?}", e);
}
continue 'read;
}
let odcid = validate_token(&src, token);
// The token was not valid, meaning the retry failed, so
// drop the packet.
if odcid == None {
error!("Invalid address validation token");
continue 'read;
}
if scid.len() != hdr.dcid.len() {
error!("Invalid destination connection ID");
continue 'read;
}
// Reuse the source connection ID we sent in the Retry
// packet, instead of changing it again.
scid.copy_from_slice(&hdr.dcid);
debug!(
"New connection: dcid={} scid={}",
hex_dump(&hdr.dcid),
hex_dump(&scid)
);
let conn = quiche::accept(&scid, odcid, &mut config).unwrap();
let client = Client {
conn,
partial_responses: HashMap::new(),
};
clients.insert(scid.to_vec(), (src, client));
clients.get_mut(&scid[..]).unwrap()
} else {
match clients.get_mut(&hdr.dcid) {
Some(v) => v,
None => clients.get_mut(conn_id).unwrap(),
}
};
// Process potentially coalesced packets.
let read = match client.conn.recv(pkt_buf) {
Ok(v) => v,
Err(e) => {
error!("{} recv failed: {:?}", client.conn.trace_id(), e);
continue 'read;
},
};
debug!("{} processed {} bytes", client.conn.trace_id(), read);
if client.conn.is_in_early_data() || client.conn.is_established() {
// Handle writable streams.
for stream_id in client.conn.writable() {
handle_writable(client, stream_id);
}
// Process all readable streams.
for s in client.conn.readable() {
while let Ok((read, fin)) =
client.conn.stream_recv(s, &mut buf)
{
debug!(
"{} received {} bytes",
client.conn.trace_id(),
read
);
let stream_buf = &buf[..read];
debug!(
"{} stream {} has {} bytes (fin? {})",
client.conn.trace_id(),
s,
stream_buf.len(),
fin
);
handle_stream(client, s, stream_buf, "examples/root");
}
}
}
}
// Generate outgoing QUIC packets for all active connections and send
// them on the UDP socket, until quiche reports that there are no more
// packets to be sent.
for (peer, client) in clients.values_mut() {
loop {
let write = match client.conn.send(&mut out) {
Ok(v) => v,
Err(quiche::Error::Done) => {
debug!("{} done writing", client.conn.trace_id());
break;
},
Err(e) => {
error!("{} send failed: {:?}", client.conn.trace_id(), e);
client.conn.close(false, 0x1, b"fail").ok();
break;
},
};
// TODO: coalesce packets.
if let Err(e) = socket.send_to(&out[..write], &peer) {
if e.kind() == std::io::ErrorKind::WouldBlock {
debug!("send() would block");
break;
}
panic!("send() failed: {:?}", e);
}
debug!("{} written {} bytes", client.conn.trace_id(), write);
}
}
// Garbage collect closed connections.
clients.retain(|_, (_, ref mut c)| {
debug!("Collecting garbage");
if c.conn.is_closed() {
info!(
"{} connection collected {:?}",
c.conn.trace_id(),
c.conn.stats()
);
}
!c.conn.is_closed()
});
}
}
/// Generate a stateless retry token.
///
/// The token includes the static string `"quiche"` followed by the IP address
/// of the client and by the original destination connection ID generated by the
/// client.
///
/// Note that this function is only an example and doesn't do any cryptographic
/// authenticate of the token. *It should not be used in production system*.
fn mint_token(hdr: &quiche::Header, src: &net::SocketAddr) -> Vec<u8> {
let mut token = Vec::new();
token.extend_from_slice(b"quiche");
let addr = match src.ip() {
std::net::IpAddr::V4(a) => a.octets().to_vec(),
std::net::IpAddr::V6(a) => a.octets().to_vec(),
};
token.extend_from_slice(&addr);
token.extend_from_slice(&hdr.dcid);
token
}
/// Validates a stateless retry token.
///
/// This checks that the ticket includes the `"quiche"` static string, and that
/// the client IP address matches the address stored in the ticket.
///
/// Note that this function is only an example and doesn't do any cryptographic
/// authenticate of the token. *It should not be used in production system*.
fn validate_token<'a>(
src: &net::SocketAddr, token: &'a [u8],
) -> Option<&'a [u8]> {
if token.len() < 6 {
return None;
}
if &token[..6] != b"quiche" {
return None;
}
let token = &token[6..];
let addr = match src.ip() {
std::net::IpAddr::V4(a) => a.octets().to_vec(),
std::net::IpAddr::V6(a) => a.octets().to_vec(),
};
if token.len() < addr.len() || &token[..addr.len()] != addr.as_slice() {
return None;
}
let token = &token[addr.len()..];
Some(&token[..])
}
/// Handles incoming HTTP/0.9 requests.
fn handle_stream(client: &mut Client, stream_id: u64, buf: &[u8], root: &str) {
let conn = &mut client.conn;
if buf.len() > 4 && &buf[..4] == b"GET " {
let uri = &buf[4..buf.len()];
let uri = String::from_utf8(uri.to_vec()).unwrap();
let uri = String::from(uri.lines().next().unwrap());
let uri = std::path::Path::new(&uri);
let mut path = std::path::PathBuf::from(root);
for c in uri.components() {
if let std::path::Component::Normal(v) = c {
path.push(v)
}
}
info!(
"{} got GET request for {:?} on stream {}",
conn.trace_id(),
path,
stream_id
);
let body = std::fs::read(path.as_path())
.unwrap_or_else(|_| b"Not Found!\r\n".to_vec());
info!(
"{} sending response of size {} on stream {}",
conn.trace_id(),
body.len(),
stream_id
);
let written = match conn.stream_send(stream_id, &body, true) {
Ok(v) => v,
Err(quiche::Error::Done) => 0,
Err(e) => {
error!("{} stream send failed {:?}", conn.trace_id(), e);
return;
},
};
if written < body.len() {
let response = PartialResponse { body, written };
client.partial_responses.insert(stream_id, response);
}
}
}
/// Handles newly writable streams.
fn handle_writable(client: &mut Client, stream_id: u64) {
let conn = &mut client.conn;
debug!("{} stream {} is writable", conn.trace_id(), stream_id);
if !client.partial_responses.contains_key(&stream_id) {
return;
}
let resp = client.partial_responses.get_mut(&stream_id).unwrap();
let body = &resp.body[resp.written..];
let written = match conn.stream_send(stream_id, &body, true) {
Ok(v) => v,
Err(quiche::Error::Done) => 0,
Err(e) => {
error!("{} stream send failed {:?}", conn.trace_id(), e);
return;
},
};
resp.written += written;
if resp.written == resp.body.len() {
client.partial_responses.remove(&stream_id);
}
}
fn hex_dump(buf: &[u8]) -> String {
let vec: Vec<String> = buf.iter().map(|b| format!("{:02x}", b)).collect();
vec.join("")
}