//! This module provides tooling to parse private key (pairs) produced by Nix //! and its //! `nix-store --generate-binary-cache-key name path.secret path.pub` command. //! It produces `ed25519_dalek` keys, but the `NarInfo::add_signature` function //! is generic, allowing other signers. use data_encoding::BASE64; use ed25519_dalek::{PUBLIC_KEY_LENGTH, SECRET_KEY_LENGTH}; use super::{SignatureRef, VerifyingKey}; pub struct SigningKey { name: String, signing_key: S, } impl SigningKey where S: ed25519::signature::Signer, { /// Constructs a singing key, using a name and a signing key. pub fn new(name: String, signing_key: S) -> Self { Self { name, signing_key } } /// Signs a fingerprint using the internal signing key, returns the [SignatureRef] pub(crate) fn sign<'a>(&'a self, fp: &[u8]) -> SignatureRef<'a> { SignatureRef::new(&self.name, self.signing_key.sign(fp).to_bytes()) } pub fn name(&self) -> &str { &self.name } } /// Parses a SigningKey / VerifyingKey from a byte slice in the format that Nix uses. pub fn parse_keypair( input: &str, ) -> Result<(SigningKey, VerifyingKey), Error> { let (name, bytes64) = input.split_once(':').ok_or(Error::MissingSeparator)?; if name.is_empty() || !name .chars() .all(|c| char::is_alphanumeric(c) || c == '-' || c == '.') { return Err(Error::InvalidName(name.to_string())); } const DECODED_BYTES_LEN: usize = SECRET_KEY_LENGTH + PUBLIC_KEY_LENGTH; if bytes64.len() != BASE64.encode_len(DECODED_BYTES_LEN) { return Err(Error::InvalidSigningKeyLen(bytes64.len())); } let mut buf = [0; DECODED_BYTES_LEN + 2]; // 64 bytes + 2 bytes padding let mut bytes = [0; DECODED_BYTES_LEN]; match BASE64.decode_mut(bytes64.as_bytes(), &mut buf) { Ok(len) if len == DECODED_BYTES_LEN => { bytes.copy_from_slice(&buf[..DECODED_BYTES_LEN]); } Ok(_) => unreachable!(), // keeping DecodePartial gets annoying lifetime-wise Err(_) => return Err(Error::DecodeError(input.to_string())), } let bytes_signing_key: [u8; SECRET_KEY_LENGTH] = { let mut b = [0u8; SECRET_KEY_LENGTH]; b.copy_from_slice(&bytes[0..SECRET_KEY_LENGTH]); b }; let bytes_verifying_key: [u8; PUBLIC_KEY_LENGTH] = { let mut b = [0u8; PUBLIC_KEY_LENGTH]; b.copy_from_slice(&bytes[SECRET_KEY_LENGTH..]); b }; let signing_key = SigningKey::new( name.to_string(), ed25519_dalek::SigningKey::from_bytes(&bytes_signing_key), ); let verifying_key = VerifyingKey::new( name.to_string(), ed25519_dalek::VerifyingKey::from_bytes(&bytes_verifying_key) .map_err(Error::InvalidVerifyingKey)?, ); Ok((signing_key, verifying_key)) } #[derive(Debug, thiserror::Error)] pub enum Error { #[error("Invalid name: {0}")] InvalidName(String), #[error("Missing separator")] MissingSeparator, #[error("Invalid signing key len: {0}")] InvalidSigningKeyLen(usize), #[error("Unable to base64-decode signing key: {0}")] DecodeError(String), #[error("VerifyingKey error: {0}")] InvalidVerifyingKey(ed25519_dalek::SignatureError), } #[cfg(test)] mod test { use crate::narinfo::DUMMY_KEYPAIR; #[test] fn parse() { let (_signing_key, _verifying_key) = super::parse_keypair(DUMMY_KEYPAIR).expect("must succeed"); } #[test] fn parse_fail() { assert!(super::parse_keypair("cache.example.com-1:cCta2MEsRNuYCgWYyeRXLyfoFpKhQJKn8gLMeXWAb7vIpRKKo/3JoxJ24OYa3DxT2JVV38KjK/1ywHWuMe2JE").is_err()); assert!(super::parse_keypair("cache.example.com-1cCta2MEsRNuYCgWYyeRXLyfoFpKhQJKn8gLMeXWAb7vIpRKKo/3JoxJ24OYa3DxT2JVV38KjK/1ywHWuMe2JE").is_err()); } }