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// -*- mode: rust; -*- // // This file is part of ed25519-dalek. // Copyright (c) 2017-2019 isis lovecruft // See LICENSE for licensing information. // // Authors: // - isis agora lovecruft <isis@patternsinthevoid.net> //! ed25519 secret key types. use core::fmt::Debug; use curve25519_dalek::constants; use curve25519_dalek::digest::generic_array::typenum::U64; use curve25519_dalek::digest::Digest; use curve25519_dalek::edwards::CompressedEdwardsY; use curve25519_dalek::scalar::Scalar; #[cfg(feature = "rand")] use rand::{CryptoRng, RngCore}; use sha2::Sha512; #[cfg(feature = "serde")] use serde::de::Error as SerdeError; #[cfg(feature = "serde")] use serde::{Deserialize, Deserializer, Serialize, Serializer}; #[cfg(feature = "serde")] use serde_bytes::{Bytes as SerdeBytes, ByteBuf as SerdeByteBuf}; use zeroize::Zeroize; use crate::constants::*; use crate::errors::*; use crate::public::*; use crate::signature::*; /// An EdDSA secret key. /// /// Instances of this secret are automatically overwritten with zeroes when they /// fall out of scope. #[derive(Zeroize)] #[zeroize(drop)] // Overwrite secret key material with null bytes when it goes out of scope. pub struct SecretKey(pub(crate) [u8; SECRET_KEY_LENGTH]); impl Debug for SecretKey { fn fmt(&self, f: &mut ::core::fmt::Formatter<'_>) -> ::core::fmt::Result { write!(f, "SecretKey: {:?}", &self.0[..]) } } impl AsRef<[u8]> for SecretKey { fn as_ref(&self) -> &[u8] { self.as_bytes() } } impl SecretKey { /// Convert this secret key to a byte array. #[inline] pub fn to_bytes(&self) -> [u8; SECRET_KEY_LENGTH] { self.0 } /// View this secret key as a byte array. #[inline] pub fn as_bytes<'a>(&'a self) -> &'a [u8; SECRET_KEY_LENGTH] { &self.0 } /// Construct a `SecretKey` from a slice of bytes. /// /// # Example /// /// ``` /// # extern crate ed25519_dalek; /// # /// use ed25519_dalek::SecretKey; /// use ed25519_dalek::SECRET_KEY_LENGTH; /// use ed25519_dalek::SignatureError; /// /// # fn doctest() -> Result<SecretKey, SignatureError> { /// let secret_key_bytes: [u8; SECRET_KEY_LENGTH] = [ /// 157, 097, 177, 157, 239, 253, 090, 096, /// 186, 132, 074, 244, 146, 236, 044, 196, /// 068, 073, 197, 105, 123, 050, 105, 025, /// 112, 059, 172, 003, 028, 174, 127, 096, ]; /// /// let secret_key: SecretKey = SecretKey::from_bytes(&secret_key_bytes)?; /// # /// # Ok(secret_key) /// # } /// # /// # fn main() { /// # let result = doctest(); /// # assert!(result.is_ok()); /// # } /// ``` /// /// # Returns /// /// A `Result` whose okay value is an EdDSA `SecretKey` or whose error value /// is an `SignatureError` wrapping the internal error that occurred. #[inline] pub fn from_bytes(bytes: &[u8]) -> Result<SecretKey, SignatureError> { if bytes.len() != SECRET_KEY_LENGTH { return Err(InternalError::BytesLengthError { name: "SecretKey", length: SECRET_KEY_LENGTH, }.into()); } let mut bits: [u8; 32] = [0u8; 32]; bits.copy_from_slice(&bytes[..32]); Ok(SecretKey(bits)) } /// Generate a `SecretKey` from a `csprng`. /// /// # Example /// /// ``` /// extern crate rand; /// extern crate ed25519_dalek; /// /// # #[cfg(feature = "std")] /// # fn main() { /// # /// use rand::rngs::OsRng; /// use ed25519_dalek::PublicKey; /// use ed25519_dalek::SecretKey; /// use ed25519_dalek::Signature; /// /// let mut csprng = OsRng{}; /// let secret_key: SecretKey = SecretKey::generate(&mut csprng); /// # } /// # /// # #[cfg(not(feature = "std"))] /// # fn main() { } /// ``` /// /// Afterwards, you can generate the corresponding public: /// /// ``` /// # extern crate rand; /// # extern crate ed25519_dalek; /// # /// # fn main() { /// # /// # use rand::rngs::OsRng; /// # use ed25519_dalek::PublicKey; /// # use ed25519_dalek::SecretKey; /// # use ed25519_dalek::Signature; /// # /// # let mut csprng = OsRng{}; /// # let secret_key: SecretKey = SecretKey::generate(&mut csprng); /// /// let public_key: PublicKey = (&secret_key).into(); /// # } /// ``` /// /// # Input /// /// A CSPRNG with a `fill_bytes()` method, e.g. `rand::OsRng` #[cfg(feature = "rand")] pub fn generate<T>(csprng: &mut T) -> SecretKey where T: CryptoRng + RngCore, { let mut sk: SecretKey = SecretKey([0u8; 32]); csprng.fill_bytes(&mut sk.0); sk } } #[cfg(feature = "serde")] impl Serialize for SecretKey { fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error> where S: Serializer, { SerdeBytes::new(self.as_bytes()).serialize(serializer) } } #[cfg(feature = "serde")] impl<'d> Deserialize<'d> for SecretKey { fn deserialize<D>(deserializer: D) -> Result<Self, D::Error> where D: Deserializer<'d>, { let bytes = <SerdeByteBuf>::deserialize(deserializer)?; SecretKey::from_bytes(bytes.as_ref()).map_err(SerdeError::custom) } } /// An "expanded" secret key. /// /// This is produced by using an hash function with 512-bits output to digest a /// `SecretKey`. The output digest is then split in half, the lower half being /// the actual `key` used to sign messages, after twiddling with some bits.¹ The /// upper half is used a sort of half-baked, ill-designed² pseudo-domain-separation /// "nonce"-like thing, which is used during signature production by /// concatenating it with the message to be signed before the message is hashed. /// /// Instances of this secret are automatically overwritten with zeroes when they /// fall out of scope. // // ¹ This results in a slight bias towards non-uniformity at one spectrum of // the range of valid keys. Oh well: not my idea; not my problem. // // ² It is the author's view (specifically, isis agora lovecruft, in the event // you'd like to complain about me, again) that this is "ill-designed" because // this doesn't actually provide true hash domain separation, in that in many // real-world applications a user wishes to have one key which is used in // several contexts (such as within tor, which does domain separation // manually by pre-concatenating static strings to messages to achieve more // robust domain separation). In other real-world applications, such as // bitcoind, a user might wish to have one master keypair from which others are // derived (à la BIP32) and different domain separators between keys derived at // different levels (and similarly for tree-based key derivation constructions, // such as hash-based signatures). Leaving the domain separation to // application designers, who thus far have produced incompatible, // slightly-differing, ad hoc domain separation (at least those application // designers who knew enough cryptographic theory to do so!), is therefore a // bad design choice on the part of the cryptographer designing primitives // which should be simple and as foolproof as possible to use for // non-cryptographers. Further, later in the ed25519 signature scheme, as // specified in RFC8032, the public key is added into *another* hash digest // (along with the message, again); it is unclear to this author why there's // not only one but two poorly-thought-out attempts at domain separation in the // same signature scheme, and which both fail in exactly the same way. For a // better-designed, Schnorr-based signature scheme, see Trevor Perrin's work on // "generalised EdDSA" and "VXEdDSA". #[derive(Zeroize)] #[zeroize(drop)] // Overwrite secret key material with null bytes when it goes out of scope. pub struct ExpandedSecretKey { pub(crate) key: Scalar, pub(crate) nonce: [u8; 32], } impl<'a> From<&'a SecretKey> for ExpandedSecretKey { /// Construct an `ExpandedSecretKey` from a `SecretKey`. /// /// # Examples /// /// ``` /// # extern crate rand; /// # extern crate sha2; /// # extern crate ed25519_dalek; /// # /// # fn main() { /// # /// use rand::rngs::OsRng; /// use ed25519_dalek::{SecretKey, ExpandedSecretKey}; /// /// let mut csprng = OsRng{}; /// let secret_key: SecretKey = SecretKey::generate(&mut csprng); /// let expanded_secret_key: ExpandedSecretKey = ExpandedSecretKey::from(&secret_key); /// # } /// ``` fn from(secret_key: &'a SecretKey) -> ExpandedSecretKey { let mut h: Sha512 = Sha512::default(); let mut hash: [u8; 64] = [0u8; 64]; let mut lower: [u8; 32] = [0u8; 32]; let mut upper: [u8; 32] = [0u8; 32]; h.update(secret_key.as_bytes()); hash.copy_from_slice(h.finalize().as_slice()); lower.copy_from_slice(&hash[00..32]); upper.copy_from_slice(&hash[32..64]); lower[0] &= 248; lower[31] &= 63; lower[31] |= 64; ExpandedSecretKey{ key: Scalar::from_bits(lower), nonce: upper, } } } impl ExpandedSecretKey { /// Convert this `ExpandedSecretKey` into an array of 64 bytes. /// /// # Returns /// /// An array of 64 bytes. The first 32 bytes represent the "expanded" /// secret key, and the last 32 bytes represent the "domain-separation" /// "nonce". /// /// # Examples /// /// ``` /// # extern crate rand; /// # extern crate sha2; /// # extern crate ed25519_dalek; /// # /// # #[cfg(feature = "std")] /// # fn main() { /// # /// use rand::rngs::OsRng; /// use ed25519_dalek::{SecretKey, ExpandedSecretKey}; /// /// let mut csprng = OsRng{}; /// let secret_key: SecretKey = SecretKey::generate(&mut csprng); /// let expanded_secret_key: ExpandedSecretKey = ExpandedSecretKey::from(&secret_key); /// let expanded_secret_key_bytes: [u8; 64] = expanded_secret_key.to_bytes(); /// /// assert!(&expanded_secret_key_bytes[..] != &[0u8; 64][..]); /// # } /// # /// # #[cfg(not(feature = "std"))] /// # fn main() { } /// ``` #[inline] pub fn to_bytes(&self) -> [u8; EXPANDED_SECRET_KEY_LENGTH] { let mut bytes: [u8; 64] = [0u8; 64]; bytes[..32].copy_from_slice(self.key.as_bytes()); bytes[32..].copy_from_slice(&self.nonce[..]); bytes } /// Construct an `ExpandedSecretKey` from a slice of bytes. /// /// # Returns /// /// A `Result` whose okay value is an EdDSA `ExpandedSecretKey` or whose /// error value is an `SignatureError` describing the error that occurred. /// /// # Examples /// /// ``` /// # extern crate rand; /// # extern crate sha2; /// # extern crate ed25519_dalek; /// # /// # use ed25519_dalek::{ExpandedSecretKey, SignatureError}; /// # /// # #[cfg(feature = "std")] /// # fn do_test() -> Result<ExpandedSecretKey, SignatureError> { /// # /// use rand::rngs::OsRng; /// use ed25519_dalek::{SecretKey, ExpandedSecretKey}; /// use ed25519_dalek::SignatureError; /// /// let mut csprng = OsRng{}; /// let secret_key: SecretKey = SecretKey::generate(&mut csprng); /// let expanded_secret_key: ExpandedSecretKey = ExpandedSecretKey::from(&secret_key); /// let bytes: [u8; 64] = expanded_secret_key.to_bytes(); /// let expanded_secret_key_again = ExpandedSecretKey::from_bytes(&bytes)?; /// # /// # Ok(expanded_secret_key_again) /// # } /// # /// # #[cfg(feature = "std")] /// # fn main() { /// # let result = do_test(); /// # assert!(result.is_ok()); /// # } /// # /// # #[cfg(not(feature = "std"))] /// # fn main() { } /// ``` #[inline] pub fn from_bytes(bytes: &[u8]) -> Result<ExpandedSecretKey, SignatureError> { if bytes.len() != EXPANDED_SECRET_KEY_LENGTH { return Err(InternalError::BytesLengthError { name: "ExpandedSecretKey", length: EXPANDED_SECRET_KEY_LENGTH, }.into()); } let mut lower: [u8; 32] = [0u8; 32]; let mut upper: [u8; 32] = [0u8; 32]; lower.copy_from_slice(&bytes[00..32]); upper.copy_from_slice(&bytes[32..64]); Ok(ExpandedSecretKey { key: Scalar::from_bits(lower), nonce: upper, }) } /// Sign a message with this `ExpandedSecretKey`. #[allow(non_snake_case)] pub fn sign(&self, message: &[u8], public_key: &PublicKey) -> ed25519::Signature { let mut h: Sha512 = Sha512::new(); let R: CompressedEdwardsY; let r: Scalar; let s: Scalar; let k: Scalar; h.update(&self.nonce); h.update(&message); r = Scalar::from_hash(h); R = (&r * &constants::ED25519_BASEPOINT_TABLE).compress(); h = Sha512::new(); h.update(R.as_bytes()); h.update(public_key.as_bytes()); h.update(&message); k = Scalar::from_hash(h); s = &(&k * &self.key) + &r; InternalSignature { R, s }.into() } /// Sign a `prehashed_message` with this `ExpandedSecretKey` using the /// Ed25519ph algorithm defined in [RFC8032 §5.1][rfc8032]. /// /// # Inputs /// /// * `prehashed_message` is an instantiated hash digest with 512-bits of /// output which has had the message to be signed previously fed into its /// state. /// * `public_key` is a [`PublicKey`] which corresponds to this secret key. /// * `context` is an optional context string, up to 255 bytes inclusive, /// which may be used to provide additional domain separation. If not /// set, this will default to an empty string. /// /// # Returns /// /// A `Result` whose `Ok` value is an Ed25519ph [`Signature`] on the /// `prehashed_message` if the context was 255 bytes or less, otherwise /// a `SignatureError`. /// /// [rfc8032]: https://tools.ietf.org/html/rfc8032#section-5.1 #[allow(non_snake_case)] pub fn sign_prehashed<'a, D>( &self, prehashed_message: D, public_key: &PublicKey, context: Option<&'a [u8]>, ) -> Result<ed25519::Signature, SignatureError> where D: Digest<OutputSize = U64>, { let mut h: Sha512; let mut prehash: [u8; 64] = [0u8; 64]; let R: CompressedEdwardsY; let r: Scalar; let s: Scalar; let k: Scalar; let ctx: &[u8] = context.unwrap_or(b""); // By default, the context is an empty string. if ctx.len() > 255 { return Err(SignatureError::from(InternalError::PrehashedContextLengthError)); } let ctx_len: u8 = ctx.len() as u8; // Get the result of the pre-hashed message. prehash.copy_from_slice(prehashed_message.finalize().as_slice()); // This is the dumbest, ten-years-late, non-admission of fucking up the // domain separation I have ever seen. Why am I still required to put // the upper half "prefix" of the hashed "secret key" in here? Why // can't the user just supply their own nonce and decide for themselves // whether or not they want a deterministic signature scheme? Why does // the message go into what's ostensibly the signature domain separation // hash? Why wasn't there always a way to provide a context string? // // ... // // This is a really fucking stupid bandaid, and the damned scheme is // still bleeding from malleability, for fuck's sake. h = Sha512::new() .chain(b"SigEd25519 no Ed25519 collisions") .chain(&[1]) // Ed25519ph .chain(&[ctx_len]) .chain(ctx) .chain(&self.nonce) .chain(&prehash[..]); r = Scalar::from_hash(h); R = (&r * &constants::ED25519_BASEPOINT_TABLE).compress(); h = Sha512::new() .chain(b"SigEd25519 no Ed25519 collisions") .chain(&[1]) // Ed25519ph .chain(&[ctx_len]) .chain(ctx) .chain(R.as_bytes()) .chain(public_key.as_bytes()) .chain(&prehash[..]); k = Scalar::from_hash(h); s = &(&k * &self.key) + &r; Ok(InternalSignature { R, s }.into()) } } #[cfg(feature = "serde")] impl Serialize for ExpandedSecretKey { fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error> where S: Serializer, { let bytes = &self.to_bytes()[..]; SerdeBytes::new(bytes).serialize(serializer) } } #[cfg(feature = "serde")] impl<'d> Deserialize<'d> for ExpandedSecretKey { fn deserialize<D>(deserializer: D) -> Result<Self, D::Error> where D: Deserializer<'d>, { let bytes = <SerdeByteBuf>::deserialize(deserializer)?; ExpandedSecretKey::from_bytes(bytes.as_ref()).map_err(SerdeError::custom) } } #[cfg(test)] mod test { use super::*; #[test] fn secret_key_zeroize_on_drop() { let secret_ptr: *const u8; { // scope for the secret to ensure it's been dropped let secret = SecretKey::from_bytes(&[0x15u8; 32][..]).unwrap(); secret_ptr = secret.0.as_ptr(); } let memory: &[u8] = unsafe { ::std::slice::from_raw_parts(secret_ptr, 32) }; assert!(!memory.contains(&0x15)); } }