use std::{
io::{Read, Write},
net::TcpStream,
sync::Mutex,
thread,
time::Duration,
};
use anyhow::{bail, Context, Error, Result};
use serde_json::to_string;
use crate::{
command::{Command, CommandRequest, MessageType},
devices::{e1::E1, DeviceBackend},
hex,
packet_builder::PacketBuilder,
security::{MsgType, Security},
DeviceInfo,
};
enum ParseMessage {
Success,
Padding,
}
pub struct Device {
info: DeviceInfo,
socket: Mutex<TcpStream>,
security: Security,
device_backend: Box<dyn DeviceBackend>,
buffer: Vec<u8>,
sub_type: Option<String>,
updates: Vec<Box<dyn Fn(&[u8]) -> Result<()>>>,
token: [u8; 64],
key: [u8; 32],
}
impl Device {
pub fn connect(info: DeviceInfo, token: &str, key: &str) -> Result<Self> {
let mut socket = Err(Error::msg(""));
for _ in 0..10 {
socket = TcpStream::connect(info.addr).context(info.addr);
if socket.is_ok() {
break;
}
thread::sleep(Duration::from_millis(500));
}
let socket = socket?;
socket.set_write_timeout(Some(Duration::from_secs(10)))?;
socket.set_read_timeout(Some(Duration::from_secs(10)))?;
let mut me = Self {
device_backend: Box::new(match info.device_type {
0xE1 => E1::new()?,
_ => bail!("unsupported device type: {:02X}", info.device_type),
}),
info,
socket: Mutex::new(socket),
security: Security::default(),
buffer: Vec::new(),
sub_type: None,
updates: Vec::new(),
token: hex(token)?.try_into().unwrap(),
key: hex(key)?.try_into().unwrap(),
};
if me.info.protocol == 3 {
me.authenticate()?;
}
me.refresh_status()?;
Ok(me)
}
fn authenticate(&mut self) -> Result<()> {
let request = self
.security
.encode_8370(&self.token, MsgType::HANDSHAKE_REQUEST)?;
let mut socket = self.socket.lock().unwrap();
socket.write(&request)?;
let mut buffer = [0; 512];
let bytes_read = socket.read(&mut buffer)?;
if bytes_read < 20 {
bail!(
"Authentication failed! (answer too short) {:?}",
&buffer[..bytes_read]
);
}
self.security.tcp_key(&buffer[8..72], &self.key)?;
Ok(())
}
pub fn refresh_status(&mut self) -> Result<()> {
let mut cmds = vec![self.device_backend.build_query()];
if self.sub_type.is_none() {
cmds.insert(0, Command::sub_type(self.info.device_type));
}
for cmd in cmds {
self.build_send(cmd)?;
loop {
let mut buf = [0; 512];
let bytes_read = self.socket.lock().unwrap().read(&mut buf)?;
if bytes_read == 0 {
bail!("socket error");
}
match self.parse_message(&buf[..bytes_read])? {
ParseMessage::Success => break,
ParseMessage::Padding => continue,
}
}
}
Ok(())
}
pub fn register_update<F>(&mut self, f: F)
where
F: Fn(&[u8]) -> Result<()> + 'static,
{
self.updates.push(Box::new(f));
}
fn parse_message(&mut self, msg: &[u8]) -> Result<ParseMessage> {
let (messages, buffer) = self.security.decode_8370(&self.buffer, msg)?;
self.buffer = buffer;
if messages.is_empty() {
return Ok(ParseMessage::Padding);
}
for mut message in messages {
if message == b"ERROR" {
bail!("parse message error");
}
let payload_len = message[4] as u16 + ((message[5] as u16) << 8) - 56;
let payload_type = message[2] as u16 + ((message[3] as u16) << 8);
// heartbeat
if payload_type == 0x1001 || payload_type == 0x0001 {
continue;
}
if message.len() > 56 && payload_len % 16 == 0 {
let len = message.len();
let crypt = &mut message[40..len - 16];
Security::aes_decrypt(crypt);
if self.pre_process_message(crypt)? {
let status = self.device_backend.process_message(crypt)?;
if status.len() > 0 {
for update in self.updates.iter() {
update(&status)?;
}
}
}
}
}
Ok(ParseMessage::Success)
}
fn pre_process_message(&self, msg: &[u8]) -> Result<bool> {
if msg[9] == MessageType::QuerySubtype as u8 {
let message = todo!();
Ok(false)
} else {
Ok(true)
}
}
fn send_message(&self, msg: &[u8]) -> Result<()> {
let data = self.security.encode_8370(msg, MsgType::ENCRYPTED_REQUEST)?;
self.socket.lock().unwrap().write(&data)?;
Ok(())
}
fn send_heartbeat(&self) -> Result<()> {
let msg = PacketBuilder::builder(self.info.id, &[0x00]).finalize(0);
self.send_message(&msg)
}
fn build_send(&self, cmd: CommandRequest) -> Result<()> {
let data = PacketBuilder::builder(self.info.id, to_string(&cmd.serialize())?.as_bytes())
.finalize(1);
self.send_message(&data)
}
}
#[cfg(test)]
mod test {
use anyhow::{Context, Result};
use futures::future::try_join;
use serial_test::serial;
use crate::{device::Device, Cloud, Startup};
#[tokio::test]
async fn verify_hex() -> Result<()> {
let devices = Startup::discover().await?;
const PY_TOKEN: &str = "06df24fc4e8e950c6d9783051b8e38d971e5fbc617da259459d30d5e7d7fc05b4ccb708fe3a085f6f0af0f8cc961fa39dabfd0746f7bbcfbf7404d9cc5c2b077";
const PY_KEY: &str = "2a5b5200c2c04d4c811d0550e1dc5b31435436b95b774d2a88d7e46d61fd9669";
let token_hex = b"\x06\xdf$\xfcN\x8e\x95\x0cm\x97\x83\x05\x1b\x8e8\xd9q\xe5\xfb\xc6\x17\xda%\x94Y\xd3\r^}\x7f\xc0[L\xcbp\x8f\xe3\xa0\x85\xf6\xf0\xaf\x0f\x8c\xc9a\xfa9\xda\xbf\xd0to{\xbc\xfb\xf7@M\x9c\xc5\xc2\xb0w";
let key_hex = b"*[R\x00\xc2\xc0ML\x81\x1d\x05P\xe1\xdc[1CT6\xb9[wM*\x88\xd7\xe4ma\xfd\x96i";
for device_info in devices {
let device = Device::connect(device_info, PY_TOKEN, PY_KEY)?;
assert_eq!(&device.token, token_hex);
assert_eq!(&device.key, key_hex);
}
Ok(())
}
#[tokio::test]
async fn connect_py_token() -> Result<()> {
let devices = Startup::discover().await?;
const PY_TOKEN: &str = "18a821cb88293c6552dc576f0672d8b9445205f74b636764929de5e8badfa48a24caa9d741f632a18e1a9fee67c40b0b40edc21ac7c4c40b6352181cd4000203";
const PY_KEY: &str = "0fc0c56ea8124414a362e6449ee45ba92558a54f159d4937af697e405f2326b9";
for device_info in devices {
Device::connect(device_info, PY_TOKEN, PY_KEY)?;
}
Ok(())
}
#[tokio::test]
#[serial]
async fn full_flow() -> Result<()> {
let mut cloud = Cloud::new("michaelh.95@t-online.de", "Hoda.semi1")?;
let (_, devices) = try_join(cloud.login(), Startup::discover()).await?;
for device_info in devices {
let (token, key) = cloud.keys(device_info.id).await?;
Device::connect(device_info, &token, &key)
.context(format!("\ntoken: {token}\nkey: {key}"))?;
}
Ok(())
}
}