[rust-lightning] / lightning / src / onion_message / packet.rs

// This file is Copyright its original authors, visible in version control
// history.
//
// This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
// or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
// You may not use this file except in accordance with one or both of these
// licenses.

//! Structs and enums useful for constructing and reading an onion message packet.

use bitcoin::secp256k1::PublicKey;
use bitcoin::secp256k1::ecdh::SharedSecret;

use ln::msgs::DecodeError;
use ln::onion_utils;
use super::blinded_route::{ForwardTlvs, ReceiveTlvs};
use util::chacha20poly1305rfc::{ChaChaPolyReadAdapter, ChaChaPolyWriteAdapter};
use util::ser::{BigSize, FixedLengthReader, LengthRead, LengthReadable, LengthReadableArgs, Readable, ReadableArgs, Writeable, Writer};

use core::cmp;
use io::{self, Read};
use prelude::*;

// Per the spec, an onion message packet's `hop_data` field length should be
// SMALL_PACKET_HOP_DATA_LEN if it fits, else BIG_PACKET_HOP_DATA_LEN if it fits.
pub(super) const SMALL_PACKET_HOP_DATA_LEN: usize = 1300;
pub(super) const BIG_PACKET_HOP_DATA_LEN: usize = 32768;

#[derive(Clone, Debug, PartialEq)]
pub(crate) struct Packet {
        pub(super) version: u8,
        pub(super) public_key: PublicKey,
        // Unlike the onion packets used for payments, onion message packets can have payloads greater
        // than 1300 bytes.
        // TODO: if 1300 ends up being the most common size, optimize this to be:
        // enum { ThirteenHundred([u8; 1300]), VarLen(Vec<u8>) }
        pub(super) hop_data: Vec<u8>,
        pub(super) hmac: [u8; 32],
}

impl onion_utils::Packet for Packet {
        type Data = Vec<u8>;
        fn new(public_key: PublicKey, hop_data: Vec<u8>, hmac: [u8; 32]) -> Packet {
                Self {
                        version: 0,
                        public_key,
                        hop_data,
                        hmac,
                }
        }
}

impl Writeable for Packet {
        fn write<W: Writer>(&self, w: &mut W) -> Result<(), io::Error> {
                self.version.write(w)?;
                self.public_key.write(w)?;
                w.write_all(&self.hop_data)?;
                self.hmac.write(w)?;
                Ok(())
        }
}

impl LengthReadable for Packet {
        fn read<R: LengthRead>(r: &mut R) -> Result<Self, DecodeError> {
                const READ_BUFFER_SIZE: usize = 4096;

                let version = Readable::read(r)?;
                let public_key = Readable::read(r)?;

                let mut hop_data = Vec::new();
                let hop_data_len = r.total_bytes().saturating_sub(66) as usize; // 1 (version) + 33 (pubkey) + 32 (HMAC) = 66
                let mut read_idx = 0;
                while read_idx < hop_data_len {
                        let mut read_buffer = [0; READ_BUFFER_SIZE];
                        let read_amt = cmp::min(hop_data_len - read_idx, READ_BUFFER_SIZE);
                        r.read_exact(&mut read_buffer[..read_amt]);
                        hop_data.extend_from_slice(&read_buffer[..read_amt]);
                        read_idx += read_amt;
                }

                let hmac = Readable::read(r)?;
                Ok(Packet {
                        version,
                        public_key,
                        hop_data,
                        hmac,
                })
        }
}

/// Onion message payloads contain "control" TLVs and "data" TLVs. Control TLVs are used to route
/// the onion message from hop to hop and for path verification, whereas data TLVs contain the onion
/// message content itself, such as an invoice request.
pub(super) enum Payload {
        /// This payload is for an intermediate hop.
        Forward(ForwardControlTlvs),
        /// This payload is for the final hop.
        Receive {
                control_tlvs: ReceiveControlTlvs,
                // Coming soon:
                // reply_path: Option<BlindedRoute>,
                // message: Message,
        }
}

// Coming soon:
// enum Message {
//      InvoiceRequest(InvoiceRequest),
//      Invoice(Invoice),
//      InvoiceError(InvoiceError),
//      CustomMessage<T>,
// }

/// Forward control TLVs in their blinded and unblinded form.
pub(super) enum ForwardControlTlvs {
        /// If we're sending to a blinded route, the node that constructed the blinded route has provided
        /// this hop's control TLVs, already encrypted into bytes.
        Blinded(Vec<u8>),
        /// If we're constructing an onion message hop through an intermediate unblinded node, we'll need
        /// to construct the intermediate hop's control TLVs in their unblinded state to avoid encoding
        /// them into an intermediate Vec. See [`super::blinded_route::ForwardTlvs`] for more info.
        Unblinded(ForwardTlvs),
}

/// Receive control TLVs in their blinded and unblinded form.
pub(super) enum ReceiveControlTlvs {
        /// See [`ForwardControlTlvs::Blinded`].
        Blinded(Vec<u8>),
        /// See [`ForwardControlTlvs::Unblinded`] and [`super::blinded_route::ReceiveTlvs`].
        Unblinded(ReceiveTlvs),
}

// Uses the provided secret to simultaneously encode and encrypt the unblinded control TLVs.
impl Writeable for (Payload, [u8; 32]) {
        fn write<W: Writer>(&self, w: &mut W) -> Result<(), io::Error> {
                match &self.0 {
                        Payload::Forward(ForwardControlTlvs::Blinded(encrypted_bytes)) |
                        Payload::Receive { control_tlvs: ReceiveControlTlvs::Blinded(encrypted_bytes)} => {
                                encode_varint_length_prefixed_tlv!(w, {
                                        (4, encrypted_bytes, vec_type)
                                })
                        },
                        Payload::Forward(ForwardControlTlvs::Unblinded(control_tlvs)) => {
                                let write_adapter = ChaChaPolyWriteAdapter::new(self.1, &control_tlvs);
                                encode_varint_length_prefixed_tlv!(w, {
                                        (4, write_adapter, required)
                                })
                        },
                        Payload::Receive { control_tlvs: ReceiveControlTlvs::Unblinded(control_tlvs)} => {
                                let write_adapter = ChaChaPolyWriteAdapter::new(self.1, &control_tlvs);
                                encode_varint_length_prefixed_tlv!(w, {
                                        (4, write_adapter, required)
                                })
                        },
                }
                Ok(())
        }
}

// Uses the provided secret to simultaneously decode and decrypt the control TLVs.
impl ReadableArgs<SharedSecret> for Payload {
        fn read<R: Read>(mut r: &mut R, encrypted_tlvs_ss: SharedSecret) -> Result<Self, DecodeError> {
                let v: BigSize = Readable::read(r)?;
                let mut rd = FixedLengthReader::new(r, v.0);
                // TODO: support reply paths
                let mut _reply_path_bytes: Option<Vec<u8>> = Some(Vec::new());
                let mut read_adapter: Option<ChaChaPolyReadAdapter<ControlTlvs>> = None;
                let rho = onion_utils::gen_rho_from_shared_secret(&encrypted_tlvs_ss.secret_bytes());
                decode_tlv_stream!(&mut rd, {
                        (2, _reply_path_bytes, vec_type),
                        (4, read_adapter, (option: LengthReadableArgs, rho))
                });
                rd.eat_remaining().map_err(|_| DecodeError::ShortRead)?;

                match read_adapter {
                        None => return Err(DecodeError::InvalidValue),
                        Some(ChaChaPolyReadAdapter { readable: ControlTlvs::Forward(tlvs)}) => {
                                Ok(Payload::Forward(ForwardControlTlvs::Unblinded(tlvs)))
                        },
                        Some(ChaChaPolyReadAdapter { readable: ControlTlvs::Receive(tlvs)}) => {
                                Ok(Payload::Receive { control_tlvs: ReceiveControlTlvs::Unblinded(tlvs)})
                        },
                }
        }
}

/// When reading a packet off the wire, we don't know a priori whether the packet is to be forwarded
/// or received. Thus we read a ControlTlvs rather than reading a ForwardControlTlvs or
/// ReceiveControlTlvs directly.
pub(super) enum ControlTlvs {
        /// This onion message is intended to be forwarded.
        Forward(ForwardTlvs),
        /// This onion message is intended to be received.
        Receive(ReceiveTlvs),
}

impl Readable for ControlTlvs {
        fn read<R: Read>(mut r: &mut R) -> Result<Self, DecodeError> {
                let mut _padding: Option<Padding> = None;
                let mut _short_channel_id: Option<u64> = None;
                let mut next_node_id: Option<PublicKey> = None;
                let mut path_id: Option<[u8; 32]> = None;
                let mut next_blinding_override: Option<PublicKey> = None;
                decode_tlv_stream!(&mut r, {
                        (1, _padding, option),
                        (2, _short_channel_id, option),
                        (4, next_node_id, option),
                        (6, path_id, option),
                        (8, next_blinding_override, option),
                });

                let valid_fwd_fmt  = next_node_id.is_some() && path_id.is_none();
                let valid_recv_fmt = next_node_id.is_none() && next_blinding_override.is_none();

                let payload_fmt = if valid_fwd_fmt {
                        ControlTlvs::Forward(ForwardTlvs {
                                next_node_id: next_node_id.unwrap(),
                                next_blinding_override,
                        })
                } else if valid_recv_fmt {
                        ControlTlvs::Receive(ReceiveTlvs {
                                path_id,
                        })
                } else {
                        return Err(DecodeError::InvalidValue)
                };

                Ok(payload_fmt)
        }
}

/// Reads padding to the end, ignoring what's read.
pub(crate) struct Padding {}
impl Readable for Padding {
        #[inline]
        fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
                loop {
                        let mut buf = [0; 8192];
                        if reader.read(&mut buf[..])? == 0 { break; }
                }
                Ok(Self {})
        }
}