Crates.io | hadusos |
lib.rs | hadusos |
version | 0.2.1 |
source | src |
created_at | 2024-07-10 02:24:24.509853 |
updated_at | 2024-07-10 02:30:43.634984 |
description | Half-duplex session over serial. |
homepage | |
repository | https://github.com/ZhiyaoMa98/hadusos-protocol |
max_upload_size | |
id | 1297726 |
size | 107,522 |
The client should provide a serial device instance and a timer instance, which respectively implements the Serial
and Timer
trait. Then, a session layer instance can be constructed.
The Session
supports half-duplex data transmission, i.e., a client operates as either the sender or the receiver at a time. When operating as the sender, the client should call send
to send data. When operating as the receiver, the client should call listen
to learn the incoming data length to allocate a buffer, and subsequently call receive
to receive the data. The receiver may also call reject
if it does not want to proceed to receiving the data after listen
.
Below shows an example.
use crossbeam::channel::{self, Receiver, RecvError, SendError, Sender};
use hadusos::{Serial, SerialError, Session, Timer};
use std::{
sync::Arc,
thread,
time::{Duration, SystemTime, UNIX_EPOCH},
};
fn main() {
// Create a pair of connected serial devices.
let (serial0, serial1) = MockSerial::new_pair();
// Create two timers.
let (timer0, timer1) = (MockTimer, MockTimer);
const TIMEOUT: u32 = 1000;
// Start a thread what will echo back whatever it receives.
let thread_echo = thread::spawn(|| {
// Create a session layer instance using the serial device and timer.
let mut sess = Session::<_, _, 50, 3>::new(serial0, timer0);
// Listen for incoming data.
let data_len = sess.listen(TIMEOUT).unwrap();
// Allocate a buffer and receive incoming data.
let mut buffer = vec![0u8; data_len as usize].into_boxed_slice();
sess.receive(&mut buffer, TIMEOUT).unwrap();
// Echo the data back.
sess.send(&buffer, TIMEOUT).unwrap();
});
// Start a thread that will send "hello world!" over the serial and verify
// the echoed data.
let thread_check = thread::spawn(|| {
// Create a session layer instance using the serial device and timer.
let mut sess = Session::<_, _, 50, 3>::new(serial1, timer1);
// Send "hello world!".
sess.send("hello world!".as_bytes(), TIMEOUT).unwrap();
// Listen for echoed data.
let data_len = sess.listen(TIMEOUT).unwrap();
// Allocate a buffer and receive echoed data.
let mut buffer = vec![0u8; data_len as usize].into_boxed_slice();
sess.receive(&mut buffer, TIMEOUT).unwrap();
// Verify echoed data.
assert!(buffer.as_ref() == "hello world!".as_bytes());
});
thread_echo.join().unwrap();
thread_check.join().unwrap();
}
/// Simulated timer.
struct MockTimer;
impl Timer for MockTimer {
/// Get the timestamp from the std library.
fn get_timestamp_ms(&mut self) -> u32 {
SystemTime::now()
.duration_since(UNIX_EPOCH)
.unwrap()
.as_millis() as u32
}
}
/// Simulated serial device. It is simulated with `crossbeam`'s MPMC queues.
struct MockSerial {
send: Arc<Sender<u8>>,
recv: Arc<Receiver<u8>>,
}
impl MockSerial {
/// Get a pair of connected serial devices.
fn new_pair() -> (Self, Self) {
// Create channels to send in both directions.
let (send0, recv0) = channel::unbounded();
let (send1, recv1) = channel::unbounded();
// Wrap the endpoints in `Arc`s.
let send0 = Arc::new(send0);
let send1 = Arc::new(send1);
let recv0 = Arc::new(recv0);
let recv1 = Arc::new(recv1);
// Deliberately keep the reference counts to be always positive, so
// that the channels will always be kept alive, otherwise we will get
// channel disconnection errors.
std::mem::forget(Arc::clone(&send0));
std::mem::forget(Arc::clone(&send1));
std::mem::forget(Arc::clone(&recv0));
std::mem::forget(Arc::clone(&recv1));
(
Self {
send: send0,
recv: recv1,
},
Self {
send: send1,
recv: recv0,
},
)
}
}
impl Serial for MockSerial {
type ReadError = RecvError;
type WriteError = SendError<u8>;
/// Read a byte from the channel with a timeout.
fn read_byte_with_timeout(
&mut self,
timeout_ms: u32,
) -> Result<u8, SerialError<Self::ReadError, Self::WriteError>> {
// Read byte from the channel. MUST map the timeout error to the
// specific `SerialError` variant because the protocol stack treats
// timeout error in a special way as it is sometimes recoverable.
self.recv
.recv_timeout(Duration::from_millis(timeout_ms as u64))
.map_err(|e| match e {
channel::RecvTimeoutError::Timeout => SerialError::Timeout,
channel::RecvTimeoutError::Disconnected => SerialError::ReadError(RecvError),
})
}
/// Write a byte to the channel.
fn write_byte(
&mut self,
byte: u8,
) -> Result<(), SerialError<Self::ReadError, Self::WriteError>> {
self.send.send(byte).map_err(|e| SerialError::WriteError(e))
}
}