mirror of https://github.com/zcash/halo2.git
503 lines
17 KiB
Rust
503 lines
17 KiB
Rust
use super::EccPoint;
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use ff::{BatchInvert, Field};
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use halo2_proofs::{
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circuit::Region,
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plonk::{Advice, Column, ConstraintSystem, Constraints, Error, Expression, Selector},
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poly::Rotation,
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};
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use pasta_curves::{arithmetic::FieldExt, pallas};
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use std::collections::HashSet;
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#[derive(Clone, Copy, Debug, Eq, PartialEq)]
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pub struct Config {
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q_add: Selector,
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// lambda
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lambda: Column<Advice>,
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// x-coordinate of P in P + Q = R
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pub x_p: Column<Advice>,
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// y-coordinate of P in P + Q = R
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pub y_p: Column<Advice>,
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// x-coordinate of Q or R in P + Q = R
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pub x_qr: Column<Advice>,
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// y-coordinate of Q or R in P + Q = R
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pub y_qr: Column<Advice>,
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// α = inv0(x_q - x_p)
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alpha: Column<Advice>,
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// β = inv0(x_p)
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beta: Column<Advice>,
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// γ = inv0(x_q)
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gamma: Column<Advice>,
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// δ = inv0(y_p + y_q) if x_q = x_p, 0 otherwise
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delta: Column<Advice>,
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}
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impl Config {
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#[allow(clippy::too_many_arguments)]
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pub(super) fn configure(
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meta: &mut ConstraintSystem<pallas::Base>,
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x_p: Column<Advice>,
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y_p: Column<Advice>,
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x_qr: Column<Advice>,
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y_qr: Column<Advice>,
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lambda: Column<Advice>,
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alpha: Column<Advice>,
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beta: Column<Advice>,
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gamma: Column<Advice>,
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delta: Column<Advice>,
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) -> Self {
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meta.enable_equality(x_p);
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meta.enable_equality(y_p);
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meta.enable_equality(x_qr);
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meta.enable_equality(y_qr);
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let config = Self {
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q_add: meta.selector(),
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x_p,
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y_p,
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x_qr,
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y_qr,
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lambda,
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alpha,
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beta,
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gamma,
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delta,
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};
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config.create_gate(meta);
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config
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}
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pub(crate) fn advice_columns(&self) -> HashSet<Column<Advice>> {
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[
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self.x_p,
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self.y_p,
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self.x_qr,
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self.y_qr,
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self.lambda,
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self.alpha,
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self.beta,
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self.gamma,
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self.delta,
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]
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.into_iter()
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.collect()
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}
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pub(crate) fn output_columns(&self) -> HashSet<Column<Advice>> {
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[self.x_qr, self.y_qr].into_iter().collect()
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}
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fn create_gate(&self, meta: &mut ConstraintSystem<pallas::Base>) {
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meta.create_gate("complete addition gates", |meta| {
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let q_add = meta.query_selector(self.q_add);
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let x_p = meta.query_advice(self.x_p, Rotation::cur());
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let y_p = meta.query_advice(self.y_p, Rotation::cur());
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let x_q = meta.query_advice(self.x_qr, Rotation::cur());
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let y_q = meta.query_advice(self.y_qr, Rotation::cur());
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let x_r = meta.query_advice(self.x_qr, Rotation::next());
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let y_r = meta.query_advice(self.y_qr, Rotation::next());
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let lambda = meta.query_advice(self.lambda, Rotation::cur());
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// α = inv0(x_q - x_p)
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let alpha = meta.query_advice(self.alpha, Rotation::cur());
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// β = inv0(x_p)
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let beta = meta.query_advice(self.beta, Rotation::cur());
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// γ = inv0(x_q)
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let gamma = meta.query_advice(self.gamma, Rotation::cur());
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// δ = inv0(y_p + y_q) if x_q = x_p, 0 otherwise
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let delta = meta.query_advice(self.delta, Rotation::cur());
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// Useful composite expressions
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// α ⋅(x_q - x_p)
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let if_alpha = (x_q.clone() - x_p.clone()) * alpha;
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// β ⋅ x_p
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let if_beta = x_p.clone() * beta;
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// γ ⋅ x_q
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let if_gamma = x_q.clone() * gamma;
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// δ ⋅(y_p + y_q)
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let if_delta = (y_q.clone() + y_p.clone()) * delta;
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// Useful constants
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let one = Expression::Constant(pallas::Base::one());
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let two = Expression::Constant(pallas::Base::from(2));
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let three = Expression::Constant(pallas::Base::from(3));
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// (x_q − x_p)⋅((x_q − x_p)⋅λ − (y_q−y_p)) = 0
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let poly1 = {
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let x_q_minus_x_p = x_q.clone() - x_p.clone(); // (x_q − x_p)
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let y_q_minus_y_p = y_q.clone() - y_p.clone(); // (y_q − y_p)
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let incomplete = x_q_minus_x_p.clone() * lambda.clone() - y_q_minus_y_p; // (x_q − x_p)⋅λ − (y_q−y_p)
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// q_add ⋅(x_q − x_p)⋅((x_q − x_p)⋅λ − (y_q−y_p))
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x_q_minus_x_p * incomplete
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};
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// (1 - (x_q - x_p)⋅α)⋅(2y_p ⋅λ - 3x_p^2) = 0
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let poly2 = {
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let three_x_p_sq = three * x_p.clone().square(); // 3x_p^2
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let two_y_p = two * y_p.clone(); // 2y_p
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let tangent_line = two_y_p * lambda.clone() - three_x_p_sq; // (2y_p ⋅λ - 3x_p^2)
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// q_add ⋅(1 - (x_q - x_p)⋅α)⋅(2y_p ⋅λ - 3x_p^2)
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(one.clone() - if_alpha.clone()) * tangent_line
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};
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// x_p⋅x_q⋅(x_q - x_p)⋅(λ^2 - x_p - x_q - x_r) = 0
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let secant_line = lambda.clone().square() - x_p.clone() - x_q.clone() - x_r.clone(); // (λ^2 - x_p - x_q - x_r)
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let poly3 = {
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let x_q_minus_x_p = x_q.clone() - x_p.clone(); // (x_q - x_p)
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// x_p⋅x_q⋅(x_q - x_p)⋅(λ^2 - x_p - x_q - x_r)
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x_p.clone() * x_q.clone() * x_q_minus_x_p * secant_line.clone()
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};
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// x_p⋅x_q⋅(x_q - x_p)⋅(λ ⋅(x_p - x_r) - y_p - y_r) = 0
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let poly4 = {
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let x_q_minus_x_p = x_q.clone() - x_p.clone(); // (x_q - x_p)
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let x_p_minus_x_r = x_p.clone() - x_r.clone(); // (x_p - x_r)
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// x_p⋅x_q⋅(x_q - x_p)⋅(λ ⋅(x_p - x_r) - y_p - y_r)
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x_p.clone()
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* x_q.clone()
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* x_q_minus_x_p
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* (lambda.clone() * x_p_minus_x_r - y_p.clone() - y_r.clone())
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};
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// x_p⋅x_q⋅(y_q + y_p)⋅(λ^2 - x_p - x_q - x_r) = 0
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let poly5 = {
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let y_q_plus_y_p = y_q.clone() + y_p.clone(); // (y_q + y_p)
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// x_p⋅x_q⋅(y_q + y_p)⋅(λ^2 - x_p - x_q - x_r)
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x_p.clone() * x_q.clone() * y_q_plus_y_p * secant_line
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};
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// x_p⋅x_q⋅(y_q + y_p)⋅(λ ⋅(x_p - x_r) - y_p - y_r) = 0
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let poly6 = {
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let y_q_plus_y_p = y_q.clone() + y_p.clone(); // (y_q + y_p)
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let x_p_minus_x_r = x_p.clone() - x_r.clone(); // (x_p - x_r)
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// x_p⋅x_q⋅(y_q + y_p)⋅(λ ⋅(x_p - x_r) - y_p - y_r)
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x_p.clone()
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* x_q.clone()
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* y_q_plus_y_p
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* (lambda * x_p_minus_x_r - y_p.clone() - y_r.clone())
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};
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// (1 - x_p * β) * (x_r - x_q) = 0
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let poly7 = (one.clone() - if_beta.clone()) * (x_r.clone() - x_q);
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// (1 - x_p * β) * (y_r - y_q) = 0
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let poly8 = (one.clone() - if_beta) * (y_r.clone() - y_q);
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// (1 - x_q * γ) * (x_r - x_p) = 0
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let poly9 = (one.clone() - if_gamma.clone()) * (x_r.clone() - x_p);
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// (1 - x_q * γ) * (y_r - y_p) = 0
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let poly10 = (one.clone() - if_gamma) * (y_r.clone() - y_p);
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// ((1 - (x_q - x_p) * α - (y_q + y_p) * δ)) * x_r
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let poly11 = (one.clone() - if_alpha.clone() - if_delta.clone()) * x_r;
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// ((1 - (x_q - x_p) * α - (y_q + y_p) * δ)) * y_r
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let poly12 = (one - if_alpha - if_delta) * y_r;
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Constraints::with_selector(
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q_add,
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[
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poly1, poly2, poly3, poly4, poly5, poly6, poly7, poly8, poly9, poly10, poly11,
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poly12,
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],
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)
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});
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}
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pub(super) fn assign_region(
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&self,
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p: &EccPoint,
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q: &EccPoint,
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offset: usize,
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region: &mut Region<'_, pallas::Base>,
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) -> Result<EccPoint, Error> {
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// Enable `q_add` selector
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self.q_add.enable(region, offset)?;
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// Copy point `p` into `x_p`, `y_p` columns
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p.x.copy_advice(|| "x_p", region, self.x_p, offset)?;
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p.y.copy_advice(|| "y_p", region, self.y_p, offset)?;
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// Copy point `q` into `x_qr`, `y_qr` columns
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q.x.copy_advice(|| "x_q", region, self.x_qr, offset)?;
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q.y.copy_advice(|| "y_q", region, self.y_qr, offset)?;
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let (x_p, y_p) = (p.x.value(), p.y.value());
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let (x_q, y_q) = (q.x.value(), q.y.value());
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// [alpha, beta, gamma, delta]
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// = [inv0(x_q - x_p), inv0(x_p), inv0(x_q), inv0(y_q + y_p)]
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// where inv0(x) = 0 if x = 0, 1/x otherwise.
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//
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let (alpha, beta, gamma, delta) = {
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let inverses = x_p
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.zip(x_q)
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.zip(y_p)
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.zip(y_q)
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.map(|(((x_p, x_q), y_p), y_q)| {
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let alpha = x_q - x_p;
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let beta = x_p;
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let gamma = x_q;
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let delta = y_q + y_p;
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let mut inverses = [alpha, *beta, *gamma, delta];
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inverses.batch_invert();
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inverses
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});
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if let Some([alpha, beta, gamma, delta]) = inverses {
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(Some(alpha), Some(beta), Some(gamma), Some(delta))
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} else {
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(None, None, None, None)
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}
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};
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// Assign α = inv0(x_q - x_p)
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region.assign_advice(|| "α", self.alpha, offset, || alpha.ok_or(Error::Synthesis))?;
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// Assign β = inv0(x_p)
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region.assign_advice(|| "β", self.beta, offset, || beta.ok_or(Error::Synthesis))?;
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// Assign γ = inv0(x_q)
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region.assign_advice(|| "γ", self.gamma, offset, || gamma.ok_or(Error::Synthesis))?;
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// Assign δ = inv0(y_q + y_p) if x_q = x_p, 0 otherwise
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region.assign_advice(
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|| "δ",
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self.delta,
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offset,
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|| {
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let x_p = x_p.ok_or(Error::Synthesis)?;
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let x_q = x_q.ok_or(Error::Synthesis)?;
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if x_q == x_p {
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delta.ok_or(Error::Synthesis)
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} else {
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Ok(pallas::Base::zero())
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}
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},
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)?;
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#[allow(clippy::collapsible_else_if)]
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// Assign lambda
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let lambda =
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x_p.zip(y_p)
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.zip(x_q)
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.zip(y_q)
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.zip(alpha)
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.map(|((((x_p, y_p), x_q), y_q), alpha)| {
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if x_q != x_p {
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// λ = (y_q - y_p)/(x_q - x_p)
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// Here, alpha = inv0(x_q - x_p), which suffices since we
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// know that x_q != x_p in this branch.
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(y_q - y_p) * alpha
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} else {
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if !y_p.is_zero_vartime() {
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// 3(x_p)^2
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let three_x_p_sq = pallas::Base::from(3) * x_p.square();
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// 1 / 2(y_p)
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let inv_two_y_p = y_p.invert().unwrap() * pallas::Base::TWO_INV;
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// λ = 3(x_p)^2 / 2(y_p)
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three_x_p_sq * inv_two_y_p
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} else {
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pallas::Base::zero()
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}
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}
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});
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region.assign_advice(
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|| "λ",
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self.lambda,
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offset,
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|| lambda.ok_or(Error::Synthesis),
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)?;
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// Calculate (x_r, y_r)
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let r =
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x_p.zip(y_p)
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.zip(x_q)
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.zip(y_q)
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.zip(lambda)
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.map(|((((x_p, y_p), x_q), y_q), lambda)| {
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{
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if x_p.is_zero_vartime() {
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// 0 + Q = Q
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(*x_q, *y_q)
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} else if x_q.is_zero_vartime() {
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// P + 0 = P
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(*x_p, *y_p)
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} else if (x_q == x_p) && (*y_q == -y_p) {
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// P + (-P) maps to (0,0)
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(pallas::Base::zero(), pallas::Base::zero())
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} else {
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// x_r = λ^2 - x_p - x_q
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let x_r = lambda.square() - x_p - x_q;
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// y_r = λ(x_p - x_r) - y_p
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let y_r = lambda * (x_p - x_r) - y_p;
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(x_r, y_r)
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}
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}
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});
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// Assign x_r
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let x_r = r.map(|r| r.0);
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let x_r_cell = region.assign_advice(
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|| "x_r",
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self.x_qr,
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offset + 1,
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|| x_r.ok_or(Error::Synthesis),
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)?;
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// Assign y_r
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let y_r = r.map(|r| r.1);
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let y_r_cell = region.assign_advice(
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|| "y_r",
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self.y_qr,
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offset + 1,
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|| y_r.ok_or(Error::Synthesis),
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)?;
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let result = EccPoint {
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x: x_r_cell,
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y: y_r_cell,
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};
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#[cfg(test)]
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// Check that the correct sum is obtained.
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{
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use group::Curve;
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let p = p.point();
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let q = q.point();
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let real_sum = p.zip(q).map(|(p, q)| p + q);
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let result = result.point();
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if let (Some(real_sum), Some(result)) = (real_sum, result) {
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assert_eq!(real_sum.to_affine(), result);
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}
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}
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Ok(result)
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}
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}
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#[cfg(test)]
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pub mod tests {
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use group::{prime::PrimeCurveAffine, Curve};
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use halo2_proofs::{circuit::Layouter, plonk::Error};
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use pasta_curves::{arithmetic::CurveExt, pallas};
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use crate::ecc::{chip::EccPoint, EccInstructions, NonIdentityPoint};
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#[allow(clippy::too_many_arguments)]
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pub fn test_add<
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EccChip: EccInstructions<pallas::Affine, Point = EccPoint> + Clone + Eq + std::fmt::Debug,
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>(
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chip: EccChip,
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mut layouter: impl Layouter<pallas::Base>,
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p_val: pallas::Affine,
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p: &NonIdentityPoint<pallas::Affine, EccChip>,
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q_val: pallas::Affine,
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q: &NonIdentityPoint<pallas::Affine, EccChip>,
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p_neg: &NonIdentityPoint<pallas::Affine, EccChip>,
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) -> Result<(), Error> {
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// Make sure P and Q are not the same point.
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assert_ne!(p_val, q_val);
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// Check complete addition P + (-P)
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let zero = {
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let result = p.add(layouter.namespace(|| "P + (-P)"), p_neg)?;
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if let Some(is_identity) = result.inner().is_identity() {
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assert!(is_identity);
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}
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result
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};
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// Check complete addition 𝒪 + 𝒪
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{
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let result = zero.add(layouter.namespace(|| "𝒪 + 𝒪"), &zero)?;
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result.constrain_equal(layouter.namespace(|| "𝒪 + 𝒪 = 𝒪"), &zero)?;
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}
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// Check P + Q
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{
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let result = p.add(layouter.namespace(|| "P + Q"), q)?;
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let witnessed_result = NonIdentityPoint::new(
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chip.clone(),
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layouter.namespace(|| "witnessed P + Q"),
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Some((p_val + q_val).to_affine()),
|
||
)?;
|
||
result.constrain_equal(layouter.namespace(|| "constrain P + Q"), &witnessed_result)?;
|
||
}
|
||
|
||
// P + P
|
||
{
|
||
let result = p.add(layouter.namespace(|| "P + P"), p)?;
|
||
let witnessed_result = NonIdentityPoint::new(
|
||
chip.clone(),
|
||
layouter.namespace(|| "witnessed P + P"),
|
||
Some((p_val + p_val).to_affine()),
|
||
)?;
|
||
result.constrain_equal(layouter.namespace(|| "constrain P + P"), &witnessed_result)?;
|
||
}
|
||
|
||
// P + 𝒪
|
||
{
|
||
let result = p.add(layouter.namespace(|| "P + 𝒪"), &zero)?;
|
||
result.constrain_equal(layouter.namespace(|| "P + 𝒪 = P"), p)?;
|
||
}
|
||
|
||
// 𝒪 + P
|
||
{
|
||
let result = zero.add(layouter.namespace(|| "𝒪 + P"), p)?;
|
||
result.constrain_equal(layouter.namespace(|| "𝒪 + P = P"), p)?;
|
||
}
|
||
|
||
// (x, y) + (ζx, y) should behave like normal P + Q.
|
||
let endo_p = p_val.to_curve().endo();
|
||
let endo_p = NonIdentityPoint::new(
|
||
chip.clone(),
|
||
layouter.namespace(|| "endo(P)"),
|
||
Some(endo_p.to_affine()),
|
||
)?;
|
||
p.add(layouter.namespace(|| "P + endo(P)"), &endo_p)?;
|
||
|
||
// (x, y) + (ζx, -y) should also behave like normal P + Q.
|
||
let endo_p_neg = (-p_val).to_curve().endo();
|
||
let endo_p_neg = NonIdentityPoint::new(
|
||
chip.clone(),
|
||
layouter.namespace(|| "endo(-P)"),
|
||
Some(endo_p_neg.to_affine()),
|
||
)?;
|
||
p.add(layouter.namespace(|| "P + endo(-P)"), &endo_p_neg)?;
|
||
|
||
// (x, y) + ((ζ^2)x, y)
|
||
let endo_2_p = p_val.to_curve().endo().endo();
|
||
let endo_2_p = NonIdentityPoint::new(
|
||
chip.clone(),
|
||
layouter.namespace(|| "endo^2(P)"),
|
||
Some(endo_2_p.to_affine()),
|
||
)?;
|
||
p.add(layouter.namespace(|| "P + endo^2(P)"), &endo_2_p)?;
|
||
|
||
// (x, y) + ((ζ^2)x, -y)
|
||
let endo_2_p_neg = (-p_val).to_curve().endo().endo();
|
||
let endo_2_p_neg = NonIdentityPoint::new(
|
||
chip,
|
||
layouter.namespace(|| "endo^2(-P)"),
|
||
Some(endo_2_p_neg.to_affine()),
|
||
)?;
|
||
p.add(layouter.namespace(|| "P + endo^2(-P)"), &endo_2_p_neg)?;
|
||
|
||
Ok(())
|
||
}
|
||
}
|