iroh_quinn_proto/connection/datagrams.rs
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use std::collections::VecDeque;
use bytes::Bytes;
use thiserror::Error;
use tracing::{debug, trace};
use super::Connection;
use crate::{
frame::{Datagram, FrameStruct},
TransportError,
};
/// API to control datagram traffic
pub struct Datagrams<'a> {
pub(super) conn: &'a mut Connection,
}
impl<'a> Datagrams<'a> {
/// Queue an unreliable, unordered datagram for immediate transmission
///
/// If `drop` is true, previously queued datagrams which are still unsent may be discarded to
/// make space for this datagram, in order of oldest to newest. If `drop` is false, and there
/// isn't enough space due to previously queued datagrams, this function will return
/// `SendDatagramError::Blocked`. `Event::DatagramsUnblocked` will be emitted once datagrams
/// have been sent.
///
/// Returns `Err` iff a `len`-byte datagram cannot currently be sent.
pub fn send(&mut self, data: Bytes, drop: bool) -> Result<(), SendDatagramError> {
if self.conn.config.datagram_receive_buffer_size.is_none() {
return Err(SendDatagramError::Disabled);
}
let max = self
.max_size()
.ok_or(SendDatagramError::UnsupportedByPeer)?;
if data.len() > max {
return Err(SendDatagramError::TooLarge);
}
if drop {
while self.conn.datagrams.outgoing_total > self.conn.config.datagram_send_buffer_size {
let prev = self
.conn
.datagrams
.outgoing
.pop_front()
.expect("datagrams.outgoing_total desynchronized");
trace!(len = prev.data.len(), "dropping outgoing datagram");
self.conn.datagrams.outgoing_total -= prev.data.len();
}
} else if self.conn.datagrams.outgoing_total + data.len()
> self.conn.config.datagram_send_buffer_size
{
self.conn.datagrams.send_blocked = true;
return Err(SendDatagramError::Blocked(data));
}
self.conn.datagrams.outgoing_total += data.len();
self.conn.datagrams.outgoing.push_back(Datagram { data });
Ok(())
}
/// Compute the maximum size of datagrams that may passed to `send_datagram`
///
/// Returns `None` if datagrams are unsupported by the peer or disabled locally.
///
/// This may change over the lifetime of a connection according to variation in the path MTU
/// estimate. The peer can also enforce an arbitrarily small fixed limit, but if the peer's
/// limit is large this is guaranteed to be a little over a kilobyte at minimum.
///
/// Not necessarily the maximum size of received datagrams.
pub fn max_size(&self) -> Option<usize> {
// We use the conservative overhead bound for any packet number, reducing the budget by at
// most 3 bytes, so that PN size fluctuations don't cause users sending maximum-size
// datagrams to suffer avoidable packet loss.
let max_size = self.conn.path.current_mtu() as usize
- self.conn.predict_1rtt_overhead(None)
- Datagram::SIZE_BOUND;
let limit = self
.conn
.peer_params
.max_datagram_frame_size?
.into_inner()
.saturating_sub(Datagram::SIZE_BOUND as u64);
Some(limit.min(max_size as u64) as usize)
}
/// Receive an unreliable, unordered datagram
pub fn recv(&mut self) -> Option<Bytes> {
self.conn.datagrams.recv()
}
/// Bytes available in the outgoing datagram buffer
///
/// When greater than zero, [`send`](Self::send)ing a datagram of at most this size is
/// guaranteed not to cause older datagrams to be dropped.
pub fn send_buffer_space(&self) -> usize {
self.conn
.config
.datagram_send_buffer_size
.saturating_sub(self.conn.datagrams.outgoing_total)
}
}
#[derive(Default)]
pub(super) struct DatagramState {
/// Number of bytes of datagrams that have been received by the local transport but not
/// delivered to the application
pub(super) recv_buffered: usize,
pub(super) incoming: VecDeque<Datagram>,
pub(super) outgoing: VecDeque<Datagram>,
pub(super) outgoing_total: usize,
pub(super) send_blocked: bool,
}
impl DatagramState {
pub(super) fn received(
&mut self,
datagram: Datagram,
window: &Option<usize>,
) -> Result<bool, TransportError> {
let window = match window {
None => {
return Err(TransportError::PROTOCOL_VIOLATION(
"unexpected DATAGRAM frame",
));
}
Some(x) => *x,
};
if datagram.data.len() > window {
return Err(TransportError::PROTOCOL_VIOLATION("oversized datagram"));
}
let was_empty = self.recv_buffered == 0;
while datagram.data.len() + self.recv_buffered > window {
debug!("dropping stale datagram");
self.recv();
}
self.recv_buffered += datagram.data.len();
self.incoming.push_back(datagram);
Ok(was_empty)
}
/// Discard outgoing datagrams with a payload larger than `max_payload` bytes
///
/// Used to ensure that reductions in MTU don't get us stuck in a state where we have a datagram
/// queued but can't send it.
pub(super) fn drop_oversized(&mut self, max_payload: usize) {
self.outgoing.retain(|datagram| {
let result = datagram.data.len() < max_payload;
if !result {
trace!(
"dropping {} byte datagram violating {} byte limit",
datagram.data.len(),
max_payload
);
}
result
});
}
/// Attempt to write a datagram frame into `buf`, consuming it from `self.outgoing`
///
/// Returns whether a frame was written. At most `max_size` bytes will be written, including
/// framing.
pub(super) fn write(&mut self, buf: &mut Vec<u8>, max_size: usize) -> bool {
let datagram = match self.outgoing.pop_front() {
Some(x) => x,
None => return false,
};
if buf.len() + datagram.size(true) > max_size {
// Future work: we could be more clever about cramming small datagrams into
// mostly-full packets when a larger one is queued first
self.outgoing.push_front(datagram);
return false;
}
trace!(len = datagram.data.len(), "DATAGRAM");
self.outgoing_total -= datagram.data.len();
datagram.encode(true, buf);
true
}
pub(super) fn recv(&mut self) -> Option<Bytes> {
let x = self.incoming.pop_front()?.data;
self.recv_buffered -= x.len();
Some(x)
}
}
/// Errors that can arise when sending a datagram
#[derive(Debug, Error, Clone, Eq, PartialEq, Ord, PartialOrd, Hash)]
pub enum SendDatagramError {
/// The peer does not support receiving datagram frames
#[error("datagrams not supported by peer")]
UnsupportedByPeer,
/// Datagram support is disabled locally
#[error("datagram support disabled")]
Disabled,
/// The datagram is larger than the connection can currently accommodate
///
/// Indicates that the path MTU minus overhead or the limit advertised by the peer has been
/// exceeded.
#[error("datagram too large")]
TooLarge,
/// Send would block
#[error("datagram send blocked")]
Blocked(Bytes),
}