keyfork-shard: shorten length and pad inside encrypted block
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f957b489b9
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GPG Key ID:
8E401478A3FBEF72
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@ -24,8 +24,10 @@ use sha2::Sha256;
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use sharks::{Share, Sharks};
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use x25519_dalek::{EphemeralSecret, PublicKey};
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// 256 bit share encrypted is 49 bytes, couple more bytes before we reach max size
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const ENC_LEN: u8 = 4 * 16;
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// 32-byte share, 1-byte index, 1-byte threshold, 1-byte version == 36 bytes
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// Encrypted, is 52 bytes
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const PLAINTEXT_LENGTH: u8 = 36;
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const ENCRYPTED_LENGTH: u8 = PLAINTEXT_LENGTH + 16;
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#[cfg(feature = "openpgp")]
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pub mod openpgp;
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@ -263,41 +265,34 @@ pub trait Format {
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payload.insert(0, HUNK_VERSION);
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payload.insert(1, threshold);
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assert!(
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payload.len() <= ENC_LEN as usize,
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"invalid share length (too long, max {ENC_LEN} bytes)"
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payload.len() < PLAINTEXT_LENGTH as usize,
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"invalid share length (too long, max {PLAINTEXT_LENGTH} bytes)"
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);
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// encrypt data
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let payload_bytes = shared_key.encrypt(nonce, payload.as_slice())?;
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// convert data to a static-size payload
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// NOTE: Padding length is less than u8::MAX because ENC_LEN < u8::MAX
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// convert plaintext to static-size payload
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#[allow(clippy::assertions_on_constants)]
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{
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assert!(ENC_LEN < u8::MAX, "padding byte can be u8");
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assert!(PLAINTEXT_LENGTH < u8::MAX, "length byte can be u8");
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}
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#[allow(clippy::cast_possible_truncation)]
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let mut out_bytes = [payload_bytes.len() as u8; ENC_LEN as usize];
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assert!(
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payload_bytes.len() < out_bytes.len(),
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"encrypted payload larger than acceptable limit"
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);
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out_bytes[..payload_bytes.len()].clone_from_slice(&payload_bytes);
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// NOTE: This previously used a single repeated value as the padding byte, but resulted in
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// difficulty when entering in prompts manually, as one's place could be lost due to
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// repeated keywords. This is resolved below by having sequentially increasing numbers up to
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// but not including the last byte.
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// NOTE: Previous versions of Keyfork Shard would modify the padding bytes to avoid
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// duplicate mnemonic words. This version does not include that, and instead uses a
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// repeated length byte.
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#[allow(clippy::cast_possible_truncation)]
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for (i, byte) in (out_bytes[payload_bytes.len()..(ENC_LEN as usize - 1)])
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.iter_mut()
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.enumerate()
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{
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*byte = (i % u8::MAX as usize) as u8;
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}
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let mut plaintext_bytes = [u8::try_from(payload.len()).expect(bug!(
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"previously asserted length must be < {PLAINTEXT_LENGTH}",
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PLAINTEXT_LENGTH = PLAINTEXT_LENGTH
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)); PLAINTEXT_LENGTH as usize];
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plaintext_bytes[..payload.len()].clone_from_slice(&payload);
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// encrypt data
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let encrypted_bytes = shared_key.encrypt(nonce, plaintext_bytes.as_slice())?;
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assert_eq!(encrypted_bytes.len(), ENCRYPTED_LENGTH as usize);
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// safety: size of out_bytes is constant and always % 4 == 0
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let payload_mnemonic = unsafe { Mnemonic::from_raw_bytes(&out_bytes) };
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let payload_mnemonic = unsafe { Mnemonic::from_raw_bytes(&encrypted_bytes) };
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dbg!(payload_mnemonic.words().len());
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#[cfg(feature = "qrcode")]
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{
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@ -399,7 +394,7 @@ pub struct InvalidData;
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/// 1 byte: Version
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/// 1 byte: Threshold
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/// Data: &[u8]
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pub(crate) const HUNK_VERSION: u8 = 1;
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pub(crate) const HUNK_VERSION: u8 = 2;
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pub(crate) const HUNK_OFFSET: usize = 2;
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const QRCODE_PROMPT: &str = "Press enter, then present QR code to camera.";
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@ -468,7 +463,7 @@ pub fn remote_decrypt(w: &mut impl Write) -> Result<(), Box<dyn std::error::Erro
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if let Ok(Some(hex)) =
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keyfork_qrcode::scan_camera(std::time::Duration::from_secs(QRCODE_TIMEOUT), 0)
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{
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let decoded_data = smex::decode(&hex)?;
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let decoded_data = smex::decode(hex)?;
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let _ = pubkey_data.insert(decoded_data[..32].try_into().map_err(|_| InvalidData)?);
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let _ = payload_data.insert(decoded_data[32..].to_vec());
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} else {
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@ -480,7 +475,7 @@ pub fn remote_decrypt(w: &mut impl Write) -> Result<(), Box<dyn std::error::Erro
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(Some(pubkey), Some(payload)) => (pubkey, payload),
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_ => {
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let validator = MnemonicSetValidator {
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word_lengths: [24, 48],
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word_lengths: [24, 39],
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};
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let [pubkey_mnemonic, payload_mnemonic] = pm
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@ -498,6 +493,12 @@ pub fn remote_decrypt(w: &mut impl Write) -> Result<(), Box<dyn std::error::Erro
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}
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};
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assert_eq!(
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payload.len(),
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ENCRYPTED_LENGTH as usize,
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bug!("invalid payload data")
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);
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let shared_secret = our_key.diffie_hellman(&PublicKey::from(pubkey)).to_bytes();
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let hkdf = Hkdf::<Sha256>::new(None, &shared_secret);
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@ -509,7 +510,7 @@ pub fn remote_decrypt(w: &mut impl Write) -> Result<(), Box<dyn std::error::Erro
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hkdf.expand(b"nonce", &mut nonce_data)?;
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let nonce = Nonce::<U12>::from_slice(&nonce_data);
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let payload = shared_key.decrypt(nonce, &payload[..payload[payload.len() - 1] as usize])?;
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let payload = shared_key.decrypt(nonce, payload.as_slice())?;
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assert_eq!(HUNK_VERSION, payload[0], "Incompatible hunk version");
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match &mut iter_count {
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@ -524,7 +525,8 @@ pub fn remote_decrypt(w: &mut impl Write) -> Result<(), Box<dyn std::error::Erro
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}
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}
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shares.push(payload[HUNK_OFFSET..].to_vec());
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let payload_len = payload.last().expect(bug!("payload should not be empty"));
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shares.push(payload[HUNK_OFFSET..usize::from(*payload_len)].to_vec());
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}
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let shares = shares
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