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use crate::interfaces::MacAddr;
use crate::{arp::ArpMessage, interfaces::Interface};
use std::time::Duration;
use std::{
io::{Error, ErrorKind},
net::Ipv4Addr,
time::Instant,
};
use pnet::{
datalink::{channel, Channel, DataLinkReceiver},
packet::{
arp::ArpPacket,
ethernet::{EtherTypes, EthernetPacket, MutableEthernetPacket},
},
};
pub struct ArpClient {
rx_channel: Box<dyn DataLinkReceiver>,
interface: Interface,
}
impl ArpClient {
pub fn new() -> Self {
ArpClient::new_with_iface(&Interface::new())
}
pub fn new_with_iface(interface: &Interface) -> Self {
let rx = match channel(&interface.get_raw_interface(), Default::default()) {
Ok(Channel::Ethernet(_, rx)) => rx,
Ok(_) => panic!("Unknown channel type"),
Err(err) => panic!("Error when opening channel: {}", err),
};
ArpClient {
rx_channel: rx,
interface: interface.clone(),
}
}
fn send_request<T>(
&mut self,
timeout: Option<Duration>,
message: ArpMessage,
check_answer: &dyn Fn(ArpMessage) -> Option<T>,
) -> Result<T, Error> {
let unpacked_timeout = match timeout {
Some(t) => t,
None => Duration::from_secs(u64::MAX),
};
match message.send(&self.interface) {
Err(e) => return Err(e),
_ => {}
}
let start_time = Instant::now();
while Instant::now() - start_time < unpacked_timeout {
match self.next() {
Some(arp_message) => match check_answer(arp_message) {
Some(result) => return Ok(result),
None => {}
},
_ => {}
}
}
return Err(Error::new(ErrorKind::TimedOut, "Timeout"));
}
pub fn ip_to_mac(
&mut self,
ip_addr: Ipv4Addr,
timeout: Option<Duration>,
) -> Result<MacAddr, Error> {
let message =
ArpMessage::new_arp_request(self.interface.get_mac().into(), self.interface.get_ip(), ip_addr);
self.send_request(timeout, message, &|arp_message| {
return if arp_message.source_protocol_address == ip_addr {
Some(arp_message.source_hardware_address.into())
} else {
None
};
})
}
pub fn mac_to_ip(
&mut self,
mac_addr: MacAddr,
timeout: Option<Duration>,
) -> Result<Ipv4Addr, Error> {
let message = ArpMessage::new_rarp_request(self.interface.get_mac().into(), mac_addr.into());
self.send_request(timeout, message, &|arp_message| {
let source_mac: MacAddr = arp_message.source_hardware_address.into();
if source_mac == mac_addr {
Some(arp_message.target_protocol_address)
} else {
None
}
})
}
pub fn next(&mut self) -> Option<ArpMessage> {
loop {
let rx_ethernet_packet = self.next_ethernet_frame();
match rx_ethernet_packet {
Some((packet, bytes))
if packet.get_ethertype() == EtherTypes::Arp
|| packet.get_ethertype() == EtherTypes::Rarp =>
{
let arp_packet =
ArpPacket::new(&bytes[MutableEthernetPacket::minimum_packet_size()..])
.unwrap();
return Some(arp_packet.into());
}
_ => return None,
}
}
}
fn next_ethernet_frame(&mut self) -> Option<(EthernetPacket, &[u8])> {
let rx_bytes = match self.rx_channel.next() {
Ok(rx_bytes) => rx_bytes,
Err(_) => return None,
};
match EthernetPacket::new(&rx_bytes) {
Some(frame) => Some((frame, rx_bytes)),
None => None,
}
}
}