#![allow(dead_code)] #![allow(clippy::absurd_extreme_comparisons)] use super::*; use crate::routing_table::VersionRange; use crate::*; use core::convert::TryInto; // #[repr(C, packed)] // struct EnvelopeHeader { // // Size is at least 8 bytes. Depending on the version specified, the size may vary and should be case to the appropriate struct // magic: [u8; 4], // 0x00: 0x56 0x4C 0x49 0x44 ("VLID") // version: u8, // 0x04: 0 = EnvelopeV0 // min_version: u8, // 0x05: 0 = EnvelopeV0 // max_version: u8, // 0x06: 0 = EnvelopeV0 // reserved: u8, // 0x07: Reserved for future use // } // #[repr(C, packed)] // struct EnvelopeV0 { // // Size is 106 bytes. // magic: [u8; 4], // 0x00: 0x56 0x4C 0x49 0x44 ("VLID") // version: u8, // 0x04: 0 = EnvelopeV0 // min_version: u8, // 0x05: 0 = EnvelopeV0 // max_version: u8, // 0x06: 0 = EnvelopeV0 // reserved: u8, // 0x07: Reserved for future use // size: u16, // 0x08: Total size of the envelope including the encrypted operations message. Maximum size is 65,507 bytes, which is the data size limit for a single UDP message on IPv4. // timestamp: u64, // 0x0A: Duration since UNIX_EPOCH in microseconds when this message is sent. Messages older than 10 seconds are dropped. // nonce: [u8; 24], // 0x12: Random nonce for replay protection and for x25519 // sender_id: [u8; 32], // 0x2A: Node ID of the message source, which is the Ed25519 public key of the sender (must be verified with find_node if this is a new node_id/address combination) // recipient_id: [u8; 32], // 0x4A: Node ID of the intended recipient, which is the Ed25519 public key of the recipient (must be the receiving node, or a relay lease holder) // // 0x6A: message is appended (operations) // // encrypted by XChaCha20Poly1305(nonce,x25519(recipient_id, sender_secret_key)) // signature: [u8; 64], // 0x?? (end-0x40): Ed25519 signature of the entire envelope including header is appended to the packet // // entire header needs to be included in message digest, relays are not allowed to modify the envelope without invalidating the signature. // } pub const MAX_ENVELOPE_SIZE: usize = 65507; pub const MIN_ENVELOPE_SIZE: usize = 0x6A + 0x40; // Header + Signature pub const ENVELOPE_MAGIC: &[u8; 4] = b"VLID"; pub type EnvelopeNonce = [u8; 24]; #[derive(Debug, Clone, PartialEq, Eq, Default)] pub struct Envelope { version: u8, min_version: u8, max_version: u8, timestamp: u64, nonce: EnvelopeNonce, sender_id: DHTKey, recipient_id: DHTKey, } impl Envelope { pub fn new( version: u8, timestamp: u64, nonce: EnvelopeNonce, sender_id: DHTKey, recipient_id: DHTKey, ) -> Self { assert!(version >= MIN_CRYPTO_VERSION); assert!(version <= MAX_CRYPTO_VERSION); Self { version, min_version: MIN_CRYPTO_VERSION, max_version: MAX_CRYPTO_VERSION, timestamp, nonce, sender_id, recipient_id, } } pub fn from_signed_data(data: &[u8]) -> Result { // Ensure we are at least the length of the envelope // Silent drop here, as we use zero length packets as part of the protocol for hole punching if data.len() < MIN_ENVELOPE_SIZE { apibail_generic!("envelope data too small"); } // Verify magic number let magic: [u8; 4] = data[0x00..0x04] .try_into() .map_err(VeilidAPIError::internal)?; if magic != *ENVELOPE_MAGIC { apibail_generic!("bad magic number"); } // Check version let version = data[0x04]; if version > MAX_CRYPTO_VERSION || version < MIN_CRYPTO_VERSION { apibail_parse_error!("unsupported cryptography version", version); } // Get min version let min_version = data[0x05]; if min_version > version { apibail_parse_error!("version too low", version); } // Get max version let max_version = data[0x06]; if version > max_version { apibail_parse_error!("version too high", version); } if min_version > max_version { apibail_generic!("version information invalid"); } // Get size and ensure it matches the size of the envelope and is less than the maximum message size let size: u16 = u16::from_le_bytes( data[0x08..0x0A] .try_into() .map_err(VeilidAPIError::internal)?, ); if (size as usize) > MAX_ENVELOPE_SIZE { apibail_parse_error!("envelope too large", size); } if (size as usize) != data.len() { apibail_parse_error!( "size doesn't match envelope size", format!( "size doesn't match envelope size: size={} data.len()={}", size, data.len() ) ); } // Get the timestamp let timestamp: u64 = u64::from_le_bytes( data[0x0A..0x12] .try_into() .map_err(VeilidAPIError::internal)?, ); // Get nonce and sender node id let nonce: EnvelopeNonce = data[0x12..0x2A] .try_into() .map_err(VeilidAPIError::internal)?; let sender_id_slice: [u8; 32] = data[0x2A..0x4A] .try_into() .map_err(VeilidAPIError::internal)?; let recipient_id_slice: [u8; 32] = data[0x4A..0x6A] .try_into() .map_err(VeilidAPIError::internal)?; let sender_id = DHTKey::new(sender_id_slice); let recipient_id = DHTKey::new(recipient_id_slice); // Ensure sender_id and recipient_id are not the same if sender_id == recipient_id { apibail_parse_error!( "sender_id should not be same as recipient_id", recipient_id.encode() ); } // Get signature let signature = DHTSignature::new( data[(data.len() - 64)..] .try_into() .map_err(VeilidAPIError::internal)?, ); // Validate signature verify(&sender_id, &data[0..(data.len() - 64)], &signature) .map_err(VeilidAPIError::internal)?; // Return envelope Ok(Self { version, min_version, max_version, timestamp, nonce, sender_id, recipient_id, }) } pub fn decrypt_body( &self, crypto: Crypto, data: &[u8], node_id_secret: &DHTKeySecret, ) -> Result, VeilidAPIError> { // Get DH secret let dh_secret = crypto.cached_dh(&self.sender_id, node_id_secret)?; // Decrypt message without authentication let body = Crypto::crypt_no_auth(&data[0x6A..data.len() - 64], &self.nonce, &dh_secret); Ok(body) } pub fn to_encrypted_data( &self, crypto: Crypto, body: &[u8], node_id_secret: &DHTKeySecret, ) -> Result, VeilidAPIError> { // Ensure body isn't too long let envelope_size: usize = body.len() + MIN_ENVELOPE_SIZE; if envelope_size > MAX_ENVELOPE_SIZE { apibail_parse_error!("envelope size is too large", envelope_size); } let mut data = vec![0u8; envelope_size]; // Write magic data[0x00..0x04].copy_from_slice(ENVELOPE_MAGIC); // Write version data[0x04] = self.version; // Write min version data[0x05] = self.min_version; // Write max version data[0x06] = self.max_version; // Write size data[0x08..0x0A].copy_from_slice(&(envelope_size as u16).to_le_bytes()); // Write timestamp data[0x0A..0x12].copy_from_slice(&self.timestamp.to_le_bytes()); // Write nonce data[0x12..0x2A].copy_from_slice(&self.nonce); // Write sender node id data[0x2A..0x4A].copy_from_slice(&self.sender_id.bytes); // Write recipient node id data[0x4A..0x6A].copy_from_slice(&self.recipient_id.bytes); // Generate dh secret let dh_secret = crypto.cached_dh(&self.recipient_id, node_id_secret)?; // Encrypt and authenticate message let encrypted_body = Crypto::crypt_no_auth(body, &self.nonce, &dh_secret); // Write body if !encrypted_body.is_empty() { data[0x6A..envelope_size - 64].copy_from_slice(encrypted_body.as_slice()); } // Sign the envelope let signature = sign( &self.sender_id, node_id_secret, &data[0..(envelope_size - 64)], )?; // Append the signature data[(envelope_size - 64)..].copy_from_slice(&signature.bytes); Ok(data) } pub fn get_version(&self) -> u8 { self.version } pub fn get_min_max_version(&self) -> VersionRange { VersionRange { min: self.min_version, max: self.max_version, } } pub fn get_timestamp(&self) -> u64 { self.timestamp } pub fn get_nonce(&self) -> EnvelopeNonce { self.nonce } pub fn get_sender_id(&self) -> DHTKey { self.sender_id } pub fn get_recipient_id(&self) -> DHTKey { self.recipient_id } }