+use std::io;
+use std::fmt;
+use std::rand::{ random, task_rng, distributions };
+use std::rand::distributions::IndependentSample;
+use crypto;
+
+// There are all the errors that may occur when reading an encrypted and authenticated packet.
+#[deriving(Show)]
+pub enum ReadingError {
+ IOReadError(io::IoError),
+ UnknownPacketTypeReadError, // If the first byte is unknown.
+ UnconsistentEncryptedSizeError,
+ UnconsistentDataSizeError, // The data size is not valid.
+ UnconsistentMACSizeError, // The MAC hasn't the correct size.
+ MACMismatchError, // The uncrypted received data doesn't match to the received MAC.
+ PaddingError, // Padding format error.
+ DataError, // The data are invalid.
+}
+
+// A macro to return a 'IOReadError' in case of error.
+macro_rules! try_read_io(
+ ($e:expr) => (match $e { Ok(e) => e, Err(e) => return Err(IOReadError(e)) })
+)
+
+// There are all the errors that may occur when encrypting, authenticating and writing a packet.
+#[deriving(Show)]
+pub enum WritingError {
+ WriteIOError(io::IoError)
+ // TODO...
+}
+
+// A macro to return a 'IOWritingError' in case of error.
+macro_rules! try_write_io(
+ ($e:expr) => (match $e { Ok(e) => e, Err(e) => return Err(WriteIOError(e)) })
+)
+
+pub type ReadingResult = Result<Packet, ReadingError>;
+pub type WritingResult = Result<(), WritingError>;
+
+static MIN_PAYLOAD_SIZE: uint = 7;
+static MAX_PAYLOAD_SIZE: uint = 39;
+static FIXED_PACKET_SIZE: uint = 1 + 8 + 10; // Packet type + timestamp + MAC.
+
+#[deriving(Show)]
+pub struct PacketData {
+ id: u8,
+ payload: Vec<u8> // The size can vary from 'MIN_PAYLOAD_SIZE' to 'MAX_PAYLOAD_SIZE' bytes.
+}
+
+#[deriving(Show)]
+pub enum ErrorType {
+ CryptError,
+ AuthError
+}
+
+#[deriving(Show)]
+pub enum PacketType {
+ Command(PacketData),
+ Answer(PacketData),
+ Error(ErrorType),
+}
+
+pub struct Packet {
+ pub t: PacketType,
+ pub timestamp: u64
+}
+
+impl fmt::Show for Packet {
+ fn fmt(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
+ fn data_to_str(data: &PacketData) -> String {
+ format!("id: {}, payload({}): {}", data.id, data.payload.len(), data.payload)
+ }
+ match self.t {
+ Command(ref data) => write!(formatter, "Command packet {{ timestamp: {}, {} }}", self.timestamp, data_to_str(data)),
+ Answer(ref data) => write!(formatter, "Answer packet {{ timestamp: {}, {} }}", self.timestamp, data_to_str(data)),
+ Error(error_type) => write!(formatter, "Error packet {{ timestamp: {}, errorType: {} }}", self.timestamp, error_type)
+ }
+ }
+}
+
+impl Packet {
+ pub fn random_packet_data() -> PacketData {
+ let mut rng = task_rng();
+ PacketData {
+ id: random::<u8>(),
+ payload: Vec::from_fn(distributions::Range::new(MIN_PAYLOAD_SIZE, MAX_PAYLOAD_SIZE + 1).ind_sample(&mut rng), |_| random::<u8>())
+ }
+ }
+
+ pub fn write(&self, output: &mut io::Writer) -> WritingResult {
+ fn packet_data(p: &PacketData) -> Vec<u8> {
+ let mut d = Vec::new();
+ d.push(p.id);
+ d.push_all(p.payload.as_slice());
+ d
+ }
+
+ // Data to be encrypted.
+ let mut data =
+ match self.t {
+ Command(ref p) | Answer(ref p) => packet_data(p),
+ Error(_) => Vec::from_elem(16, '0' as u8) // Padding as data: 16 * '0'.
+ };
+
+ // Compute the MAC
+ let mac = crypto::compute_mac(data.as_slice());
+
+ // Padding.
+ match self.t {
+ Command(_) | Answer(_) => {
+ let padding_size = if data.len() % 16 == 0 { 16 } else { data.len() % 16 } ;
+ data.push_all(Vec::from_elem(padding_size, padding_size as u8).as_slice());
+ },
+ _ => ()
+ }
+
+ // Encrypt.
+ let encrypted_data = crypto::encrypt(data.as_slice(), iv_from_timestamp(self.timestamp).as_slice());
+
+ // Write packet length.
+ try_write_io!(output.write_be_u16((encrypted_data.len() + FIXED_PACKET_SIZE) as u16));
+
+ // Write packet type.
+ try_write_io!(output.write_u8(
+ match self.t {
+ Command(_) => 0x00,
+ Answer(_) => 0xFF,
+ Error(CryptError) => 0x0A,
+ Error(AuthError) => 0x0B
+ }
+ ));
+
+ // Write timestamp.
+ try_write_io!(output.write_be_u64(self.timestamp));
+
+ // Write encrypted data.
+ try_write_io!(output.write(encrypted_data.as_slice()));
+
+ // Write the MAC.
+ try_write_io!(output.write(mac));
+
+ Ok(())
+ }
+
+ pub fn read(input: &mut io::Reader) -> ReadingResult {
+ let data_size = try_read_io!(input.read_be_u16());
+ let packet_type = try_read_io!(input.read_u8());
+ let timestamp = try_read_io!(input.read_be_u64());
+
+ let mut encrypted_data = Vec::from_elem(data_size as uint - FIXED_PACKET_SIZE, 0u8);
+ if try_read_io!(input.read(encrypted_data.as_mut_slice_())) != encrypted_data.len() {
+ return Err(UnconsistentEncryptedSizeError)
+ }
+ let mut data = crypto::decrypt(encrypted_data.as_slice(), iv_from_timestamp(timestamp).as_slice());
+
+ // Control the size and the content of the padding then remove it.
+ if packet_type == 0x00 || packet_type == 0xFF {
+ match data.last() {
+ Some(&padding_size) => {
+ if padding_size as uint > data.len() || !data.slice_from(data.len() - padding_size as uint).iter().any(|b| *b == padding_size) {
+ return Err(PaddingError)
+ }
+ let data_length = data.len() - padding_size as uint;
+ data.truncate(data_length);
+ },
+ None =>
+ return Err(PaddingError)
+ }
+ }
+
+ // Read an verify the MAC.
+ let mut mac_read = [0u8, ..10];
+ if try_read_io!(input.read(mac_read)) != mac_read.len() {
+ return Err(UnconsistentMACSizeError)
+ }
+ let mac_data = crypto::compute_mac(data.as_slice());
+ if mac_read != mac_data {
+ return Err(MACMismatchError)
+ }
+
+ Ok(Packet {
+ t: match packet_type {
+ 0x00 | 0xFF => {
+ if data.len() < MIN_PAYLOAD_SIZE + 1 || data.len() > MAX_PAYLOAD_SIZE + 1 {
+ return Err(UnconsistentDataSizeError)
+ }
+ let pd = PacketData { id: data[0], payload: data.tail().to_vec() }; // match data.as_slice() { [id, payload..] => PacketData { id: id, payload: payload.to_vec() } };
+ match packet_type { 0x00 => Command(pd), _ => Answer(pd) }
+ },
+ 0x0A | 0x0B => {
+ if data.len() != 16 {
+ return Err(UnconsistentDataSizeError)
+ } else if data != Vec::from_elem(16, '0' as u8) {
+ return Err(DataError)
+ }
+ match packet_type { 0x0A => Error(CryptError), _ => Error(AuthError) }
+ },
+ _ =>
+ return Err(UnknownPacketTypeReadError)
+ },
+ timestamp: timestamp
+ })
+ }
+}
+
+// Build an initialization vector: 64 * 0u8 + timestamp (128 bits).
+fn iv_from_timestamp(timestamp: u64) -> Vec<u8> {
+ let mut iv = io::MemWriter::with_capacity(16);
+ let _ = iv.write_be_u64(0u64);
+ let _ = iv.write_be_u64(timestamp);
+ iv.unwrap()
+}