use std::collections::{BTreeMap, HashMap, VecDeque};
use std::sync::Arc;
use log::trace;
use async_trait::async_trait;
use async_std::io::prelude::WriteExt;
use async_std::io::ReadExt;
use tokio::io::{ReadHalf, WriteHalf};
use tokio::net::TcpStream;
use tokio::sync::{mpsc, watch};
use crate::error::*;
use kuska_handshake::async_std::{BoxStreamRead, BoxStreamWrite, TokioCompat};
/// Priority of a request (click to read more about priorities).
///
/// This priority value is used to priorize messages
/// in the send queue of the client, and their responses in the send queue of the
/// server. Lower values mean higher priority.
///
/// This mechanism is usefull for messages bigger than the maximum chunk size
/// (set at `0x4000` bytes), such as large file transfers.
/// In such case, all of the messages in the send queue with the highest priority
/// will take turns to send individual chunks, in a round-robin fashion.
/// Once all highest priority messages are sent successfully, the messages with
/// the next highest priority will begin being sent in the same way.
///
/// The same priority value is given to a request and to its associated response.
pub type RequestPriority = u8;
/// Priority class: high
pub const PRIO_HIGH: RequestPriority = 0x20;
/// Priority class: normal
pub const PRIO_NORMAL: RequestPriority = 0x40;
/// Priority class: background
pub const PRIO_BACKGROUND: RequestPriority = 0x80;
/// Priority: primary among given class
pub const PRIO_PRIMARY: RequestPriority = 0x00;
/// Priority: secondary among given class (ex: `PRIO_HIGH || PRIO_SECONDARY`)
pub const PRIO_SECONDARY: RequestPriority = 0x01;
const MAX_CHUNK_SIZE: usize = 0x4000;
pub(crate) type RequestID = u16;
struct SendQueueItem {
id: RequestID,
prio: RequestPriority,
data: Vec<u8>,
cursor: usize,
}
struct SendQueue {
items: BTreeMap<u8, VecDeque<SendQueueItem>>,
}
impl SendQueue {
fn new() -> Self {
Self {
items: BTreeMap::new(),
}
}
fn push(&mut self, item: SendQueueItem) {
let prio = item.prio;
let mut items_at_prio = self
.items
.remove(&prio)
.unwrap_or(VecDeque::with_capacity(4));
items_at_prio.push_back(item);
self.items.insert(prio, items_at_prio);
}
fn pop(&mut self) -> Option<SendQueueItem> {
match self.items.pop_first() {
None => None,
Some((prio, mut items_at_prio)) => {
let ret = items_at_prio.pop_front();
if !items_at_prio.is_empty() {
self.items.insert(prio, items_at_prio);
}
ret
}
}
}
}
#[async_trait]
pub(crate) trait SendLoop: Sync {
async fn send_loop(
self: Arc<Self>,
mut msg_recv: mpsc::UnboundedReceiver<(RequestID, RequestPriority, Vec<u8>)>,
mut write: BoxStreamWrite<TokioCompat<WriteHalf<TcpStream>>>,
mut must_exit: watch::Receiver<bool>,
) -> Result<(), Error> {
let mut sending = SendQueue::new();
while !*must_exit.borrow() {
if let Ok((id, prio, data)) = msg_recv.try_recv() {
trace!("send_loop: got {}, {} bytes", id, data.len());
sending.push(SendQueueItem {
id,
prio,
data,
cursor: 0,
});
} else if let Some(mut item) = sending.pop() {
trace!(
"send_loop: sending bytes for {} ({} bytes, {} already sent)",
item.id,
item.data.len(),
item.cursor
);
let header_id = u16::to_be_bytes(item.id);
if write_all_or_exit(&header_id[..], &mut write, &mut must_exit)
.await?
.is_none()
{
break;
}
if item.data.len() - item.cursor > MAX_CHUNK_SIZE {
let header_size = u16::to_be_bytes(MAX_CHUNK_SIZE as u16 | 0x8000);
if write_all_or_exit(&header_size[..], &mut write, &mut must_exit)
.await?
.is_none()
{
break;
}
let new_cursor = item.cursor + MAX_CHUNK_SIZE as usize;
if write_all_or_exit(
&item.data[item.cursor..new_cursor],
&mut write,
&mut must_exit,
)
.await?
.is_none()
{
break;
}
item.cursor = new_cursor;
sending.push(item);
} else {
let send_len = (item.data.len() - item.cursor) as u16;
let header_size = u16::to_be_bytes(send_len);
if write_all_or_exit(&header_size[..], &mut write, &mut must_exit)
.await?
.is_none()
{
break;
}
if write_all_or_exit(&item.data[item.cursor..], &mut write, &mut must_exit)
.await?
.is_none()
{
break;
}
}
write.flush().await.log_err("Could not flush in send_loop");
} else {
let (id, prio, data) = msg_recv
.recv()
.await
.ok_or(Error::Message("Connection closed.".into()))?;
trace!("send_loop: got {}, {} bytes", id, data.len());
sending.push(SendQueueItem {
id,
prio,
data,
cursor: 0,
});
}
}
Ok(())
}
}
#[async_trait]
pub(crate) trait RecvLoop: Sync + 'static {
async fn recv_handler(self: Arc<Self>, id: RequestID, msg: Vec<u8>);
async fn recv_loop(
self: Arc<Self>,
mut read: BoxStreamRead<TokioCompat<ReadHalf<TcpStream>>>,
mut must_exit: watch::Receiver<bool>,
) -> Result<(), Error> {
let mut receiving = HashMap::new();
while !*must_exit.borrow() {
trace!("recv_loop: reading packet");
let mut header_id = [0u8; 2];
if read_exact_or_exit(&mut header_id[..], &mut read, &mut must_exit)
.await?
.is_none()
{
break;
}
let id = RequestID::from_be_bytes(header_id);
trace!("recv_loop: got header id: {:04x}", id);
let mut header_size = [0u8; 2];
if read_exact_or_exit(&mut header_size[..], &mut read, &mut must_exit)
.await?
.is_none()
{
break;
}
let size = RequestID::from_be_bytes(header_size);
trace!("recv_loop: got header size: {:04x}", id);
let has_cont = (size & 0x8000) != 0;
let size = size & !0x8000;
let mut next_slice = vec![0; size as usize];
if read_exact_or_exit(&mut next_slice[..], &mut read, &mut must_exit)
.await?
.is_none()
{
break;
}
trace!("recv_loop: read {} bytes", size);
let mut msg_bytes = receiving.remove(&id).unwrap_or(vec![]);
msg_bytes.extend_from_slice(&next_slice[..]);
if has_cont {
receiving.insert(id, msg_bytes);
} else {
tokio::spawn(self.clone().recv_handler(id, msg_bytes));
}
}
Ok(())
}
}
async fn read_exact_or_exit(
buf: &mut [u8],
read: &mut BoxStreamRead<TokioCompat<ReadHalf<TcpStream>>>,
must_exit: &mut watch::Receiver<bool>,
) -> Result<Option<()>, Error> {
tokio::select!(
res = read.read_exact(buf) => Ok(Some(res?)),
_ = await_exit(must_exit) => Ok(None),
)
}
async fn write_all_or_exit(
buf: &[u8],
write: &mut BoxStreamWrite<TokioCompat<WriteHalf<TcpStream>>>,
must_exit: &mut watch::Receiver<bool>,
) -> Result<Option<()>, Error> {
tokio::select!(
res = write.write_all(buf) => Ok(Some(res?)),
_ = await_exit(must_exit) => Ok(None),
)
}
async fn await_exit(must_exit: &mut watch::Receiver<bool>) {
loop {
if must_exit.recv().await == Some(true) {
return;
}
}
}