use ark_ff::{
fields::{Field, Fp2},
AdditiveGroup,
};
use ark_serialize::{CanonicalDeserialize, CanonicalSerialize};
use ark_std::vec::*;
use educe::Educe;
use num_traits::One;
use crate::{
bn::{BnConfig, TwistType},
models::short_weierstrass::SWCurveConfig,
short_weierstrass::{Affine, Projective},
AffineRepr, CurveGroup,
};
pub type G2Affine<P> = Affine<<P as BnConfig>::G2Config>;
pub type G2Projective<P> = Projective<<P as BnConfig>::G2Config>;
#[derive(Educe, CanonicalSerialize, CanonicalDeserialize)]
#[educe(Clone, Debug, PartialEq, Eq)]
pub struct G2Prepared<P: BnConfig> {
pub ell_coeffs: Vec<EllCoeff<P>>,
pub infinity: bool,
}
pub type EllCoeff<P> = (
Fp2<<P as BnConfig>::Fp2Config>,
Fp2<<P as BnConfig>::Fp2Config>,
Fp2<<P as BnConfig>::Fp2Config>,
);
#[derive(Educe)]
#[educe(Clone, Copy, Debug)]
pub struct G2HomProjective<P: BnConfig> {
x: Fp2<P::Fp2Config>,
y: Fp2<P::Fp2Config>,
z: Fp2<P::Fp2Config>,
}
impl<P: BnConfig> G2HomProjective<P> {
pub fn double_in_place(&mut self, two_inv: &P::Fp) -> EllCoeff<P> {
let mut a = self.x * &self.y;
a.mul_assign_by_fp(two_inv);
let b = self.y.square();
let c = self.z.square();
let e = P::G2Config::COEFF_B * &(c.double() + &c);
let f = e.double() + &e;
let mut g = b + &f;
g.mul_assign_by_fp(two_inv);
let h = (self.y + &self.z).square() - &(b + &c);
let i = e - &b;
let j = self.x.square();
let e_square = e.square();
self.x = a * &(b - &f);
self.y = g.square() - &(e_square.double() + &e_square);
self.z = b * &h;
match P::TWIST_TYPE {
TwistType::M => (i, j.double() + &j, -h),
TwistType::D => (-h, j.double() + &j, i),
}
}
pub fn add_in_place(&mut self, q: &G2Affine<P>) -> EllCoeff<P> {
let theta = self.y - &(q.y * &self.z);
let lambda = self.x - &(q.x * &self.z);
let c = theta.square();
let d = lambda.square();
let e = lambda * &d;
let f = self.z * &c;
let g = self.x * &d;
let h = e + &f - &g.double();
self.x = lambda * &h;
self.y = theta * &(g - &h) - &(e * &self.y);
self.z *= &e;
let j = theta * &q.x - &(lambda * &q.y);
match P::TWIST_TYPE {
TwistType::M => (j, -theta, lambda),
TwistType::D => (lambda, -theta, j),
}
}
}
impl<P: BnConfig> Default for G2Prepared<P> {
fn default() -> Self {
Self::from(G2Affine::<P>::generator())
}
}
impl<P: BnConfig> From<G2Affine<P>> for G2Prepared<P> {
fn from(q: G2Affine<P>) -> Self {
if q.infinity {
G2Prepared {
ell_coeffs: vec![],
infinity: true,
}
} else {
let two_inv = P::Fp::one().double().inverse().unwrap();
let mut ell_coeffs = vec![];
let mut r = G2HomProjective::<P> {
x: q.x,
y: q.y,
z: Fp2::one(),
};
let neg_q = -q;
for bit in P::ATE_LOOP_COUNT.iter().rev().skip(1) {
ell_coeffs.push(r.double_in_place(&two_inv));
match bit {
1 => ell_coeffs.push(r.add_in_place(&q)),
-1 => ell_coeffs.push(r.add_in_place(&neg_q)),
_ => continue,
}
}
let q1 = mul_by_char::<P>(q);
let mut q2 = mul_by_char::<P>(q1);
if P::X_IS_NEGATIVE {
r.y = -r.y;
}
q2.y = -q2.y;
ell_coeffs.push(r.add_in_place(&q1));
ell_coeffs.push(r.add_in_place(&q2));
Self {
ell_coeffs,
infinity: false,
}
}
}
}
impl<P: BnConfig> From<G2Projective<P>> for G2Prepared<P> {
fn from(q: G2Projective<P>) -> Self {
q.into_affine().into()
}
}
impl<'a, P: BnConfig> From<&'a G2Affine<P>> for G2Prepared<P> {
fn from(other: &'a G2Affine<P>) -> Self {
(*other).into()
}
}
impl<'a, P: BnConfig> From<&'a G2Projective<P>> for G2Prepared<P> {
fn from(q: &'a G2Projective<P>) -> Self {
q.into_affine().into()
}
}
impl<P: BnConfig> G2Prepared<P> {
pub fn is_zero(&self) -> bool {
self.infinity
}
}
fn mul_by_char<P: BnConfig>(r: G2Affine<P>) -> G2Affine<P> {
let mut s = r;
s.x.frobenius_map_in_place(1);
s.x *= &P::TWIST_MUL_BY_Q_X;
s.y.frobenius_map_in_place(1);
s.y *= &P::TWIST_MUL_BY_Q_Y;
s
}