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// -*- mode: rust; -*-
//
// This file is part of curve25519-dalek.
// Copyright (c) 2016-2019 Isis Lovecruft, Henry de Valence
// See LICENSE for licensing information.
//
// Authors:
// - Isis Agora Lovecruft <isis@patternsinthevoid.net>
// - Henry de Valence <hdevalence@hdevalence.ca>
//! Module for common traits.
#![allow(non_snake_case)]
use core::borrow::Borrow;
use subtle;
use scalar::Scalar;
// ------------------------------------------------------------------------
// Public Traits
// ------------------------------------------------------------------------
/// Trait for getting the identity element of a point type.
pub trait Identity {
/// Returns the identity element of the curve.
/// Can be used as a constructor.
fn identity() -> Self;
}
/// Trait for testing if a curve point is equivalent to the identity point.
pub trait IsIdentity {
/// Return true if this element is the identity element of the curve.
fn is_identity(&self) -> bool;
}
/// Implement generic identity equality testing for a point representations
/// which have constant-time equality testing and a defined identity
/// constructor.
impl<T> IsIdentity for T
where
T: subtle::ConstantTimeEq + Identity,
{
fn is_identity(&self) -> bool {
self.ct_eq(&T::identity()).unwrap_u8() == 1u8
}
}
/// A trait for constant-time multiscalar multiplication without precomputation.
pub trait MultiscalarMul {
/// The type of point being multiplied, e.g., `RistrettoPoint`.
type Point;
/// Given an iterator of (possibly secret) scalars and an iterator of
/// public points, compute
/// $$
/// Q = c\_1 P\_1 + \cdots + c\_n P\_n.
/// $$
///
/// It is an error to call this function with two iterators of different lengths.
///
/// # Examples
///
/// The trait bound aims for maximum flexibility: the inputs must be
/// convertable to iterators (`I: IntoIter`), and the iterator's items
/// must be `Borrow<Scalar>` (or `Borrow<Point>`), to allow
/// iterators returning either `Scalar`s or `&Scalar`s.
///
/// ```
/// use curve25519_dalek_ng::constants;
/// use curve25519_dalek_ng::traits::MultiscalarMul;
/// use curve25519_dalek_ng::ristretto::RistrettoPoint;
/// use curve25519_dalek_ng::scalar::Scalar;
///
/// // Some scalars
/// let a = Scalar::from(87329482u64);
/// let b = Scalar::from(37264829u64);
/// let c = Scalar::from(98098098u64);
///
/// // Some points
/// let P = constants::RISTRETTO_BASEPOINT_POINT;
/// let Q = P + P;
/// let R = P + Q;
///
/// // A1 = a*P + b*Q + c*R
/// let abc = [a,b,c];
/// let A1 = RistrettoPoint::multiscalar_mul(&abc, &[P,Q,R]);
/// // Note: (&abc).into_iter(): Iterator<Item=&Scalar>
///
/// // A2 = (-a)*P + (-b)*Q + (-c)*R
/// let minus_abc = abc.iter().map(|x| -x);
/// let A2 = RistrettoPoint::multiscalar_mul(minus_abc, &[P,Q,R]);
/// // Note: minus_abc.into_iter(): Iterator<Item=Scalar>
///
/// assert_eq!(A1.compress(), (-A2).compress());
/// ```
fn multiscalar_mul<I, J>(scalars: I, points: J) -> Self::Point
where
I: IntoIterator,
I::Item: Borrow<Scalar>,
J: IntoIterator,
J::Item: Borrow<Self::Point>;
}
/// A trait for variable-time multiscalar multiplication without precomputation.
pub trait VartimeMultiscalarMul {
/// The type of point being multiplied, e.g., `RistrettoPoint`.
type Point;
/// Given an iterator of public scalars and an iterator of
/// `Option`s of points, compute either `Some(Q)`, where
/// $$
/// Q = c\_1 P\_1 + \cdots + c\_n P\_n,
/// $$
/// if all points were `Some(P_i)`, or else return `None`.
///
/// This function is particularly useful when verifying statements
/// involving compressed points. Accepting `Option<Point>` allows
/// inlining point decompression into the multiscalar call,
/// avoiding the need for temporary buffers.
/// ```
/// use curve25519_dalek_ng::constants;
/// use curve25519_dalek_ng::traits::VartimeMultiscalarMul;
/// use curve25519_dalek_ng::ristretto::RistrettoPoint;
/// use curve25519_dalek_ng::scalar::Scalar;
///
/// // Some scalars
/// let a = Scalar::from(87329482u64);
/// let b = Scalar::from(37264829u64);
/// let c = Scalar::from(98098098u64);
/// let abc = [a,b,c];
///
/// // Some points
/// let P = constants::RISTRETTO_BASEPOINT_POINT;
/// let Q = P + P;
/// let R = P + Q;
/// let PQR = [P, Q, R];
///
/// let compressed = [P.compress(), Q.compress(), R.compress()];
///
/// // Now we can compute A1 = a*P + b*Q + c*R using P, Q, R:
/// let A1 = RistrettoPoint::vartime_multiscalar_mul(&abc, &PQR);
///
/// // Or using the compressed points:
/// let A2 = RistrettoPoint::optional_multiscalar_mul(
/// &abc,
/// compressed.iter().map(|pt| pt.decompress()),
/// );
///
/// assert_eq!(A2, Some(A1));
///
/// // It's also possible to mix compressed and uncompressed points:
/// let A3 = RistrettoPoint::optional_multiscalar_mul(
/// abc.iter()
/// .chain(abc.iter()),
/// compressed.iter().map(|pt| pt.decompress())
/// .chain(PQR.iter().map(|&pt| Some(pt))),
/// );
///
/// assert_eq!(A3, Some(A1+A1));
/// ```
fn optional_multiscalar_mul<I, J>(scalars: I, points: J) -> Option<Self::Point>
where
I: IntoIterator,
I::Item: Borrow<Scalar>,
J: IntoIterator<Item = Option<Self::Point>>;
/// Given an iterator of public scalars and an iterator of
/// public points, compute
/// $$
/// Q = c\_1 P\_1 + \cdots + c\_n P\_n,
/// $$
/// using variable-time operations.
///
/// It is an error to call this function with two iterators of different lengths.
///
/// # Examples
///
/// The trait bound aims for maximum flexibility: the inputs must be
/// convertable to iterators (`I: IntoIter`), and the iterator's items
/// must be `Borrow<Scalar>` (or `Borrow<Point>`), to allow
/// iterators returning either `Scalar`s or `&Scalar`s.
///
/// ```
/// use curve25519_dalek_ng::constants;
/// use curve25519_dalek_ng::traits::VartimeMultiscalarMul;
/// use curve25519_dalek_ng::ristretto::RistrettoPoint;
/// use curve25519_dalek_ng::scalar::Scalar;
///
/// // Some scalars
/// let a = Scalar::from(87329482u64);
/// let b = Scalar::from(37264829u64);
/// let c = Scalar::from(98098098u64);
///
/// // Some points
/// let P = constants::RISTRETTO_BASEPOINT_POINT;
/// let Q = P + P;
/// let R = P + Q;
///
/// // A1 = a*P + b*Q + c*R
/// let abc = [a,b,c];
/// let A1 = RistrettoPoint::vartime_multiscalar_mul(&abc, &[P,Q,R]);
/// // Note: (&abc).into_iter(): Iterator<Item=&Scalar>
///
/// // A2 = (-a)*P + (-b)*Q + (-c)*R
/// let minus_abc = abc.iter().map(|x| -x);
/// let A2 = RistrettoPoint::vartime_multiscalar_mul(minus_abc, &[P,Q,R]);
/// // Note: minus_abc.into_iter(): Iterator<Item=Scalar>
///
/// assert_eq!(A1.compress(), (-A2).compress());
/// ```
fn vartime_multiscalar_mul<I, J>(scalars: I, points: J) -> Self::Point
where
I: IntoIterator,
I::Item: Borrow<Scalar>,
J: IntoIterator,
J::Item: Borrow<Self::Point>,
Self::Point: Clone,
{
Self::optional_multiscalar_mul(
scalars,
points.into_iter().map(|P| Some(P.borrow().clone())),
)
.unwrap()
}
}
/// A trait for variable-time multiscalar multiplication with precomputation.
///
/// A general multiscalar multiplication with precomputation can be written as
/// $$
/// Q = a_1 A_1 + \cdots + a_n A_n + b_1 B_1 + \cdots + b_m B_m,
/// $$
/// where the \\(B_i\\) are *static* points, for which precomputation
/// is possible, and the \\(A_j\\) are *dynamic* points, for which
/// precomputation is not possible.
///
/// This trait has three methods for performing this computation:
///
/// * [`vartime_multiscalar_mul`], which handles the special case
/// where \\(n = 0\\) and there are no dynamic points;
///
/// * [`vartime_mixed_multiscalar_mul`], which takes the dynamic
/// points as already-validated `Point`s and is infallible;
///
/// * [`optional_mixed_multiscalar_mul`], which takes the dynamic
/// points as `Option<Point>`s and returns an `Option<Point>`,
/// allowing decompression to be composed into the input iterators.
///
/// All methods require that the lengths of the input iterators be
/// known and matching, as if they were `ExactSizeIterator`s. (It
/// does not require `ExactSizeIterator` only because that trait is
/// broken).
pub trait VartimePrecomputedMultiscalarMul: Sized {
/// The type of point to be multiplied, e.g., `RistrettoPoint`.
type Point: Clone;
/// Given the static points \\( B_i \\), perform precomputation
/// and return the precomputation data.
fn new<I>(static_points: I) -> Self
where
I: IntoIterator,
I::Item: Borrow<Self::Point>;
/// Given `static_scalars`, an iterator of public scalars
/// \\(b_i\\), compute
/// $$
/// Q = b_1 B_1 + \cdots + b_m B_m,
/// $$
/// where the \\(B_j\\) are the points that were supplied to `new`.
///
/// It is an error to call this function with iterators of
/// inconsistent lengths.
///
/// The trait bound aims for maximum flexibility: the input must
/// be convertable to iterators (`I: IntoIter`), and the
/// iterator's items must be `Borrow<Scalar>`, to allow iterators
/// returning either `Scalar`s or `&Scalar`s.
fn vartime_multiscalar_mul<I>(&self, static_scalars: I) -> Self::Point
where
I: IntoIterator,
I::Item: Borrow<Scalar>,
{
use core::iter;
Self::vartime_mixed_multiscalar_mul(
self,
static_scalars,
iter::empty::<Scalar>(),
iter::empty::<Self::Point>(),
)
}
/// Given `static_scalars`, an iterator of public scalars
/// \\(b_i\\), `dynamic_scalars`, an iterator of public scalars
/// \\(a_i\\), and `dynamic_points`, an iterator of points
/// \\(A_i\\), compute
/// $$
/// Q = a_1 A_1 + \cdots + a_n A_n + b_1 B_1 + \cdots + b_m B_m,
/// $$
/// where the \\(B_j\\) are the points that were supplied to `new`.
///
/// It is an error to call this function with iterators of
/// inconsistent lengths.
///
/// The trait bound aims for maximum flexibility: the inputs must be
/// convertable to iterators (`I: IntoIter`), and the iterator's items
/// must be `Borrow<Scalar>` (or `Borrow<Point>`), to allow
/// iterators returning either `Scalar`s or `&Scalar`s.
fn vartime_mixed_multiscalar_mul<I, J, K>(
&self,
static_scalars: I,
dynamic_scalars: J,
dynamic_points: K,
) -> Self::Point
where
I: IntoIterator,
I::Item: Borrow<Scalar>,
J: IntoIterator,
J::Item: Borrow<Scalar>,
K: IntoIterator,
K::Item: Borrow<Self::Point>,
{
Self::optional_mixed_multiscalar_mul(
self,
static_scalars,
dynamic_scalars,
dynamic_points.into_iter().map(|P| Some(P.borrow().clone())),
)
.unwrap()
}
/// Given `static_scalars`, an iterator of public scalars
/// \\(b_i\\), `dynamic_scalars`, an iterator of public scalars
/// \\(a_i\\), and `dynamic_points`, an iterator of points
/// \\(A_i\\), compute
/// $$
/// Q = a_1 A_1 + \cdots + a_n A_n + b_1 B_1 + \cdots + b_m B_m,
/// $$
/// where the \\(B_j\\) are the points that were supplied to `new`.
///
/// If any of the dynamic points were `None`, return `None`.
///
/// It is an error to call this function with iterators of
/// inconsistent lengths.
///
/// This function is particularly useful when verifying statements
/// involving compressed points. Accepting `Option<Point>` allows
/// inlining point decompression into the multiscalar call,
/// avoiding the need for temporary buffers.
fn optional_mixed_multiscalar_mul<I, J, K>(
&self,
static_scalars: I,
dynamic_scalars: J,
dynamic_points: K,
) -> Option<Self::Point>
where
I: IntoIterator,
I::Item: Borrow<Scalar>,
J: IntoIterator,
J::Item: Borrow<Scalar>,
K: IntoIterator<Item = Option<Self::Point>>;
}
// ------------------------------------------------------------------------
// Private Traits
// ------------------------------------------------------------------------
/// Trait for checking whether a point is on the curve.
///
/// This trait is only for debugging/testing, since it should be
/// impossible for a `curve25519-dalek` user to construct an invalid
/// point.
pub(crate) trait ValidityCheck {
/// Checks whether the point is on the curve. Not CT.
fn is_valid(&self) -> bool;
}