use ark_relations::r1cs::SynthesisError;
use super::PairingVar as PG;
use crate::{
fields::{fp::FpVar, fp3::Fp3Var, fp6_2over3::Fp6Var, FieldVar},
groups::mnt6::{
AteAdditionCoefficientsVar, AteDoubleCoefficientsVar, G1PreparedVar, G1Var, G2PreparedVar,
G2ProjectiveExtendedVar, G2Var,
},
};
use ark_ec::mnt6::{MNT6Parameters, MNT6};
use ark_ff::fields::BitIteratorBE;
use core::marker::PhantomData;
pub struct PairingVar<P: MNT6Parameters>(PhantomData<P>);
type Fp3G<P> = Fp3Var<<P as MNT6Parameters>::Fp3Params>;
type Fp6G<P> = Fp6Var<<P as MNT6Parameters>::Fp6Params>;
pub type GTVar<P> = Fp6G<P>;
impl<P: MNT6Parameters> PairingVar<P> {
#[tracing::instrument(target = "r1cs", skip(r))]
pub(crate) fn doubling_step_for_flipped_miller_loop(
r: &G2ProjectiveExtendedVar<P>,
) -> Result<(G2ProjectiveExtendedVar<P>, AteDoubleCoefficientsVar<P>), SynthesisError> {
let a = r.t.square()?;
let b = r.x.square()?;
let c = r.y.square()?;
let d = c.square()?;
let e = (&r.x + &c).square()? - &b - &d;
let f = b.double()? + &b + &(&a * P::TWIST_COEFF_A);
let g = f.square()?;
let d_eight = d.double()?.double()?.double()?;
let e2 = e.double()?;
let x = &g - e2.double()?;
let y = &f * (e2 - &x) - d_eight;
let z = (&r.y + &r.z).square()? - &c - &r.z.square()?;
let t = z.square()?;
let r2 = G2ProjectiveExtendedVar { x, y, z, t };
let coeff = AteDoubleCoefficientsVar {
c_h: (&r2.z + &r.t).square()? - &r2.t - &a,
c_4c: c.double()?.double()?,
c_j: (&f + &r.t).square()? - &g - &a,
c_l: (&f + &r.x).square()? - &g - &b,
};
Ok((r2, coeff))
}
#[tracing::instrument(target = "r1cs", skip(r))]
pub(crate) fn mixed_addition_step_for_flipped_miller_loop(
x: &Fp3G<P>,
y: &Fp3G<P>,
r: &G2ProjectiveExtendedVar<P>,
) -> Result<(G2ProjectiveExtendedVar<P>, AteAdditionCoefficientsVar<P>), SynthesisError> {
let a = y.square()?;
let b = &r.t * x;
let d = ((&r.z + y).square()? - &a - &r.t) * &r.t;
let h = &b - &r.x;
let i = h.square()?;
let e = i.double()?.double()?;
let j = &h * &e;
let v = &r.x * &e;
let ry2 = r.y.double()?;
let l1 = &d - &ry2;
let x = l1.square()? - &j - &v.double()?;
let y = &l1 * &(&v - &x) - &j * ry2;
let z = (&r.z + &h).square()? - &r.t - &i;
let t = z.square()?;
let r2 = G2ProjectiveExtendedVar {
x,
y,
z: z.clone(),
t,
};
let coeff = AteAdditionCoefficientsVar { c_l1: l1, c_rz: z };
Ok((r2, coeff))
}
#[tracing::instrument(target = "r1cs", skip(p, q))]
pub(crate) fn ate_miller_loop(
p: &G1PreparedVar<P>,
q: &G2PreparedVar<P>,
) -> Result<Fp6G<P>, SynthesisError> {
let zero = FpVar::<P::Fp>::zero();
let l1_coeff = Fp3Var::new(p.x.clone(), zero.clone(), zero) - &q.x_over_twist;
let mut f = Fp6G::<P>::one();
let mut add_idx: usize = 0;
for (dbl_idx, bit) in BitIteratorBE::without_leading_zeros(P::ATE_LOOP_COUNT)
.skip(1)
.enumerate()
{
let dc = &q.double_coefficients[dbl_idx];
let g_rr_at_p = Fp6Var::new(
&dc.c_l - &dc.c_4c - &dc.c_j * &p.x_twist,
&dc.c_h * &p.y_twist,
);
f = f.square()? * &g_rr_at_p;
if bit {
let ac = &q.addition_coefficients[add_idx];
add_idx += 1;
let g_rq_at_p = Fp6Var::new(
&ac.c_rz * &p.y_twist,
(&q.y_over_twist * &ac.c_rz + &(&l1_coeff * &ac.c_l1)).negate()?,
);
f *= &g_rq_at_p;
}
}
if P::ATE_IS_LOOP_COUNT_NEG {
let ac = &q.addition_coefficients[add_idx];
let g_rnegr_at_p = Fp6Var::new(
&ac.c_rz * &p.y_twist,
(&q.y_over_twist * &ac.c_rz + &(l1_coeff * &ac.c_l1)).negate()?,
);
f = (f * &g_rnegr_at_p).inverse()?;
}
Ok(f)
}
#[tracing::instrument(target = "r1cs")]
pub(crate) fn final_exponentiation(value: &Fp6G<P>) -> Result<GTVar<P>, SynthesisError> {
let value_inv = value.inverse()?;
let value_to_first_chunk = Self::final_exponentiation_first_chunk(value, &value_inv)?;
let value_inv_to_first_chunk = Self::final_exponentiation_first_chunk(&value_inv, value)?;
Self::final_exponentiation_last_chunk(&value_to_first_chunk, &value_inv_to_first_chunk)
}
#[tracing::instrument(target = "r1cs", skip(elt, elt_inv))]
fn final_exponentiation_first_chunk(
elt: &Fp6G<P>,
elt_inv: &Fp6G<P>,
) -> Result<Fp6G<P>, SynthesisError> {
let elt_q3 = elt.unitary_inverse()?;
let elt_q3_over_elt = elt_q3 * elt_inv;
let alpha = elt_q3_over_elt.frobenius_map(1)?;
Ok(alpha * &elt_q3_over_elt)
}
#[tracing::instrument(target = "r1cs", skip(elt, elt_inv))]
fn final_exponentiation_last_chunk(
elt: &Fp6G<P>,
elt_inv: &Fp6G<P>,
) -> Result<Fp6G<P>, SynthesisError> {
let elt_q = elt.frobenius_map(1)?;
let w1_part = elt_q.cyclotomic_exp(&P::FINAL_EXPONENT_LAST_CHUNK_1)?;
let w0_part = if P::FINAL_EXPONENT_LAST_CHUNK_W0_IS_NEG {
elt_inv.cyclotomic_exp(&P::FINAL_EXPONENT_LAST_CHUNK_ABS_OF_W0)?
} else {
elt.cyclotomic_exp(&P::FINAL_EXPONENT_LAST_CHUNK_ABS_OF_W0)?
};
Ok(w1_part * &w0_part)
}
}
impl<P: MNT6Parameters> PG<MNT6<P>, P::Fp> for PairingVar<P> {
type G1Var = G1Var<P>;
type G2Var = G2Var<P>;
type G1PreparedVar = G1PreparedVar<P>;
type G2PreparedVar = G2PreparedVar<P>;
type GTVar = GTVar<P>;
#[tracing::instrument(target = "r1cs")]
fn miller_loop(
ps: &[Self::G1PreparedVar],
qs: &[Self::G2PreparedVar],
) -> Result<Self::GTVar, SynthesisError> {
let mut result = Fp6G::<P>::one();
for (p, q) in ps.iter().zip(qs) {
result *= Self::ate_miller_loop(p, q)?;
}
Ok(result)
}
#[tracing::instrument(target = "r1cs")]
fn final_exponentiation(r: &Self::GTVar) -> Result<Self::GTVar, SynthesisError> {
Self::final_exponentiation(r)
}
#[tracing::instrument(target = "r1cs")]
fn prepare_g1(p: &Self::G1Var) -> Result<Self::G1PreparedVar, SynthesisError> {
Self::G1PreparedVar::from_group_var(p)
}
#[tracing::instrument(target = "r1cs")]
fn prepare_g2(q: &Self::G2Var) -> Result<Self::G2PreparedVar, SynthesisError> {
Self::G2PreparedVar::from_group_var(q)
}
}