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// -*- mode: rust; -*- // // This file is part of schnorrkel. // Copyright (c) 2019 Web 3 Foundation // See LICENSE for licensing information. // // Authors: // - Jeff Burdges <[email protected]> //! ### Ristretto point tooling //! //! We provide a `RistrettoBoth` type that contains both an uncompressed //! `RistrettoPoint` along side its matching `CompressedRistretto`, //! which helps several protocols avoid duplicate ristretto compressions //! and/or decompressions. // We're discussing including some variant in curve25519-dalek directly in // https://github.com/dalek-cryptography/curve25519-dalek/pull/220 use core::fmt::{Debug}; use curve25519_dalek::ristretto::{CompressedRistretto,RistrettoPoint}; // use curve25519_dalek::scalar::Scalar; use crate::errors::{SignatureError,SignatureResult}; /// Compressed Ristretto point length pub const RISTRETTO_POINT_LENGTH: usize = 32; /// A `RistrettoBoth` contains both an uncompressed `RistrettoPoint` /// as well as the corresponding `CompressedRistretto`. It provides /// a convenient middle ground for protocols that both hash compressed /// points to derive scalars for use with uncompressed points. #[derive(Copy, Clone, Default, Eq)] // PartialEq optimnized below pub struct RistrettoBoth { compressed: CompressedRistretto, point: RistrettoPoint, } impl Debug for RistrettoBoth { fn fmt(&self, f: &mut ::core::fmt::Formatter<'_>) -> ::core::fmt::Result { write!(f, "RistrettoPoint( {:?} )", self.compressed) } } /* #[inline(always)] fn zeroize_hack<Z: Default>(z: &mut Z) { use core::{ptr, sync::atomic}; unsafe { ptr::write_volatile(z, Z::default()); } atomic::compiler_fence(atomic::Ordering::SeqCst); } impl ::zeroize::Zeroize for RistrettoBoth { fn zeroize(&mut self) { zeroize_hack(&mut self.compressed); zeroize_hack(&mut self.point); } } */ impl RistrettoBoth { const DESCRIPTION : &'static str = "A ristretto point represented as a 32-byte compressed point"; // I dislike getter methods, and prefer direct field access, but doing // getters here permits the fields being private, and gives us faster // equality comparisons. /// Access the compressed Ristretto form pub fn as_compressed(&self) -> &CompressedRistretto { &self.compressed } /// Extract the compressed Ristretto form pub fn into_compressed(self) -> CompressedRistretto { self.compressed } /// Access the point form pub fn as_point(&self) -> &RistrettoPoint { &self.point } /// Extract the point form pub fn into_point(self) -> RistrettoPoint { self.point } /// Decompress into the `RistrettoBoth` format that also retains the /// compressed form. pub fn from_compressed(compressed: CompressedRistretto) -> SignatureResult<RistrettoBoth> { Ok(RistrettoBoth { point: compressed.decompress().ok_or(SignatureError::PointDecompressionError) ?, compressed, }) } /// Compress into the `RistrettoBoth` format that also retains the /// uncompressed form. pub fn from_point(point: RistrettoPoint) -> RistrettoBoth { RistrettoBoth { compressed: point.compress(), point, } } /// Convert this public key to a byte array. #[inline] pub fn to_bytes(&self) -> [u8; RISTRETTO_POINT_LENGTH] { self.compressed.to_bytes() } /// Construct a `RistrettoBoth` from a slice of bytes. /// /// # Example /// /// ``` /// use schnorrkel::points::RistrettoBoth; /// use schnorrkel::PUBLIC_KEY_LENGTH; /// use schnorrkel::SignatureError; /// /// # fn doctest() -> Result<RistrettoBoth, SignatureError> { /// let public_key_bytes: [u8; PUBLIC_KEY_LENGTH] = [ /// 215, 90, 152, 1, 130, 177, 10, 183, 213, 75, 254, 211, 201, 100, 7, 58, /// 14, 225, 114, 243, 218, 166, 35, 37, 175, 2, 26, 104, 247, 7, 81, 26]; /// /// let public_key = RistrettoBoth::from_bytes(&public_key_bytes)?; /// # /// # Ok(public_key) /// # } /// # /// # fn main() { /// # doctest(); /// # } /// ``` /// /// # Returns /// /// A `Result` whose okay value is an EdDSA `RistrettoBoth` or whose error value /// is an `SignatureError` describing the error that occurred. #[inline] pub fn from_bytes(bytes: &[u8]) -> SignatureResult<RistrettoBoth> { RistrettoBoth::from_bytes_ser("RistrettoPoint",RistrettoBoth::DESCRIPTION,bytes) } /// Variant of `RistrettoBoth::from_bytes` that propogates more informative errors. #[inline] pub fn from_bytes_ser(name: &'static str, description: &'static str, bytes: &[u8]) -> SignatureResult<RistrettoBoth> { if bytes.len() != RISTRETTO_POINT_LENGTH { return Err(SignatureError::BytesLengthError{ name, description, length: RISTRETTO_POINT_LENGTH, }); } let mut compressed = CompressedRistretto([0u8; RISTRETTO_POINT_LENGTH]); compressed.0.copy_from_slice(&bytes[..32]); RistrettoBoth::from_compressed(compressed) } } serde_boilerplate!(RistrettoBoth); /// We hide fields largely so that only compairing the compressed forms works. impl PartialEq<Self> for RistrettoBoth { fn eq(&self, other: &Self) -> bool { let r = self.compressed.eq(&other.compressed); debug_assert_eq!(r, self.point.eq(&other.point)); r } // fn ne(&self, other: &Rhs) -> bool { // self.compressed.0.ne(&other.compressed.0) // } } // impl Eq for RistrettoBoth {} impl PartialOrd<RistrettoBoth> for RistrettoBoth { fn partial_cmp(&self, other: &RistrettoBoth) -> Option<::core::cmp::Ordering> { self.compressed.0.partial_cmp(&other.compressed.0) } // fn lt(&self, other: &Rhs) -> bool { // self.compressed.0.lt(&other.compressed.0) // } // fn le(&self, other: &Rhs) -> bool { // self.compressed.0.le(&other.compressed.0) // } // fn gt(&self, other: &Rhs) -> bool { // self.compressed.0.gt(&other.compressed.0) // } // fn ge(&self, other: &Rhs) -> bool { // self.compressed.0.ge(&other.compressed.0) // } } impl Ord for RistrettoBoth { fn cmp(&self, other: &Self) -> ::core::cmp::Ordering { self.compressed.0.cmp(&other.compressed.0) } // fn max(self, other: Self) -> Self { // self.compressed.0.max(other.compressed.0) // } // fn min(self, other: Self) -> Self { // self.compressed.0.min(other.compressed.0) // } } impl ::core::hash::Hash for RistrettoBoth { fn hash<H: ::core::hash::Hasher>(&self, state: &mut H) { self.compressed.0.hash(state); } }