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Implement Nova's NIFS.P & NIFS.V (#7)

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arnaucube 1 year ago
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  1. +1
    -0
      src/folding/mod.rs
  2. +62
    -0
      src/folding/nova/mod.rs
  3. +336
    -0
      src/folding/nova/nifs.rs
  4. +1
    -0
      src/lib.rs

+ 1
- 0
src/folding/mod.rs
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@ -0,0 +1 @@
pub mod nova;

+ 62
- 0
src/folding/nova/mod.rs
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@ -0,0 +1,62 @@
use ark_crypto_primitives::sponge::Absorb;
use ark_ec::{CurveGroup, Group};
use ark_std::fmt::Debug;
use ark_std::{One, Zero};
use crate::pedersen::{Params as PedersenParams, Pedersen};
pub mod nifs;
#[derive(Debug, Clone, Eq, PartialEq)]
pub struct CommittedInstance<C: CurveGroup> {
pub cmE: C,
pub u: C::ScalarField,
pub cmW: C,
pub x: Vec<C::ScalarField>,
}
impl<C: CurveGroup> CommittedInstance<C> {
pub fn empty() -> Self {
CommittedInstance {
cmE: C::zero(),
u: C::ScalarField::one(),
cmW: C::zero(),
x: Vec::new(),
}
}
}
#[derive(Debug, Clone, Eq, PartialEq)]
pub struct Witness<C: CurveGroup> {
pub E: Vec<C::ScalarField>,
pub rE: C::ScalarField,
pub W: Vec<C::ScalarField>,
pub rW: C::ScalarField,
}
impl<C: CurveGroup> Witness<C>
where
<C as Group>::ScalarField: Absorb,
{
pub fn new(w: Vec<C::ScalarField>, e_len: usize) -> Self {
Self {
E: vec![C::ScalarField::zero(); e_len],
rE: C::ScalarField::one(),
W: w,
rW: C::ScalarField::one(),
}
}
pub fn commit(
&self,
params: &PedersenParams<C>,
x: Vec<C::ScalarField>,
) -> CommittedInstance<C> {
let cmE = Pedersen::commit(params, &self.E, &self.rE);
let cmW = Pedersen::commit(params, &self.W, &self.rW);
CommittedInstance {
cmE,
u: C::ScalarField::one(),
cmW,
x,
}
}
}

+ 336
- 0
src/folding/nova/nifs.rs
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@ -0,0 +1,336 @@
use ark_crypto_primitives::sponge::Absorb;
use ark_ec::{CurveGroup, Group};
use ark_std::One;
use std::marker::PhantomData;
use crate::ccs::r1cs::R1CS;
use crate::folding::nova::{CommittedInstance, Witness};
use crate::pedersen::{Params as PedersenParams, Pedersen, Proof as PedersenProof};
use crate::transcript::Transcript;
use crate::utils::vec::*;
pub struct NIFS<C: CurveGroup> {
_phantom: PhantomData<C>,
}
impl<C: CurveGroup> NIFS<C>
where
<C as Group>::ScalarField: Absorb,
{
// compute_T: compute cross-terms T
pub fn compute_T(
r1cs: &R1CS<C::ScalarField>,
u1: C::ScalarField,
u2: C::ScalarField,
z1: &[C::ScalarField],
z2: &[C::ScalarField],
) -> Vec<C::ScalarField> {
let (A, B, C) = (r1cs.A.clone(), r1cs.B.clone(), r1cs.C.clone());
// this is parallelizable (for the future)
let Az1 = mat_vec_mul_sparse(&A, z1);
let Bz1 = mat_vec_mul_sparse(&B, z1);
let Cz1 = mat_vec_mul_sparse(&C, z1);
let Az2 = mat_vec_mul_sparse(&A, z2);
let Bz2 = mat_vec_mul_sparse(&B, z2);
let Cz2 = mat_vec_mul_sparse(&C, z2);
let Az1_Bz2 = hadamard(&Az1, &Bz2);
let Az2_Bz1 = hadamard(&Az2, &Bz1);
let u1Cz2 = vec_scalar_mul(&Cz2, &u1);
let u2Cz1 = vec_scalar_mul(&Cz1, &u2);
vec_sub(&vec_sub(&vec_add(&Az1_Bz2, &Az2_Bz1), &u1Cz2), &u2Cz1)
}
pub fn fold_witness(
r: C::ScalarField,
w1: &Witness<C>,
w2: &Witness<C>,
T: &[C::ScalarField],
rT: C::ScalarField,
) -> Witness<C> {
let r2 = r * r;
let E: Vec<C::ScalarField> = vec_add(
&vec_add(&w1.E, &vec_scalar_mul(T, &r)),
&vec_scalar_mul(&w2.E, &r2),
);
let rE = w1.rE + r * rT + r2 * w2.rE;
let W = vec_add(&w1.W, &vec_scalar_mul(&w2.W, &r));
let rW = w1.rW + r * w2.rW;
Witness::<C> { E, rE, W, rW }
}
pub fn fold_committed_instance(
r: C::ScalarField,
ci1: &CommittedInstance<C>,
ci2: &CommittedInstance<C>,
cmT: &C,
) -> CommittedInstance<C> {
let r2 = r * r;
let cmE = ci1.cmE + cmT.mul(r) + ci2.cmE.mul(r2);
let u = ci1.u + r * ci2.u;
let cmW = ci1.cmW + ci2.cmW.mul(r);
let x = vec_add(&ci1.x, &vec_scalar_mul(&ci2.x, &r));
CommittedInstance::<C> { cmE, u, cmW, x }
}
// NIFS.P
#[allow(clippy::type_complexity)]
pub fn prove(
pedersen_params: &PedersenParams<C>,
r: C::ScalarField,
r1cs: &R1CS<C::ScalarField>,
w1: &Witness<C>,
ci1: &CommittedInstance<C>,
w2: &Witness<C>,
ci2: &CommittedInstance<C>,
) -> (Witness<C>, CommittedInstance<C>, Vec<C::ScalarField>, C) {
let z1: Vec<C::ScalarField> = [vec![ci1.u], ci1.x.to_vec(), w1.W.to_vec()].concat();
let z2: Vec<C::ScalarField> = [vec![ci2.u], ci2.x.to_vec(), w2.W.to_vec()].concat();
// compute cross terms
let T = Self::compute_T(r1cs, ci1.u, ci2.u, &z1, &z2);
let rT = C::ScalarField::one(); // use 1 as rT since we don't need hiding property for cm(T)
let cmT = Pedersen::commit(pedersen_params, &T, &rT);
// fold witness
let w3 = NIFS::<C>::fold_witness(r, w1, w2, &T, rT);
// fold committed instancs
let ci3 = NIFS::<C>::fold_committed_instance(r, ci1, ci2, &cmT);
(w3, ci3, T, cmT)
}
// NIFS.V
pub fn verify(
r: C::ScalarField,
ci1: &CommittedInstance<C>,
ci2: &CommittedInstance<C>,
cmT: &C,
) -> CommittedInstance<C> {
NIFS::<C>::fold_committed_instance(r, ci1, ci2, cmT)
}
// verify commited folded instance (ci) relations
pub fn verify_folded_instance(
r: C::ScalarField,
ci1: &CommittedInstance<C>,
ci2: &CommittedInstance<C>,
ci3: &CommittedInstance<C>,
cmT: &C,
) -> bool {
let r2 = r * r;
if ci3.cmE != (ci1.cmE + cmT.mul(r) + ci2.cmE.mul(r2)) {
return false;
}
if ci3.u != ci1.u + r * ci2.u {
return false;
}
if ci3.cmW != (ci1.cmW + ci2.cmW.mul(r)) {
return false;
}
if ci3.x != vec_add(&ci1.x, &vec_scalar_mul(&ci2.x, &r)) {
return false;
}
true
}
pub fn open_commitments(
tr: &mut impl Transcript<C>,
pedersen_params: &PedersenParams<C>,
w: &Witness<C>,
ci: &CommittedInstance<C>,
T: Vec<C::ScalarField>,
cmT: &C,
) -> (PedersenProof<C>, PedersenProof<C>, PedersenProof<C>) {
let cmE_proof = Pedersen::prove(pedersen_params, tr, &ci.cmE, &w.E, &w.rE);
let cmW_proof = Pedersen::prove(pedersen_params, tr, &ci.cmW, &w.W, &w.rW);
let cmT_proof = Pedersen::prove(pedersen_params, tr, cmT, &T, &C::ScalarField::one()); // cm(T) is committed with rT=1
(cmE_proof, cmW_proof, cmT_proof)
}
pub fn verify_commitments(
tr: &mut impl Transcript<C>,
pedersen_params: &PedersenParams<C>,
ci: CommittedInstance<C>,
cmT: C,
cmE_proof: PedersenProof<C>,
cmW_proof: PedersenProof<C>,
cmT_proof: PedersenProof<C>,
) -> bool {
if !Pedersen::verify(pedersen_params, tr, ci.cmE, cmE_proof) {
return false;
}
if !Pedersen::verify(pedersen_params, tr, ci.cmW, cmW_proof) {
return false;
}
if !Pedersen::verify(pedersen_params, tr, cmT, cmT_proof) {
return false;
}
true
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::ccs::r1cs::tests::{get_test_r1cs, get_test_z};
use crate::transcript::poseidon::{tests::poseidon_test_config, PoseidonTranscript};
use ark_bls12_377::{Fr, G1Projective};
use ark_ff::PrimeField;
use ark_std::UniformRand;
pub fn check_relaxed_r1cs<F: PrimeField>(r1cs: &R1CS<F>, z: Vec<F>, u: F, E: &[F]) {
let Az = mat_vec_mul_sparse(&r1cs.A, &z);
let Bz = mat_vec_mul_sparse(&r1cs.B, &z);
let Cz = mat_vec_mul_sparse(&r1cs.C, &z);
assert_eq!(hadamard(&Az, &Bz), vec_add(&vec_scalar_mul(&Cz, &u), E));
}
// fold 2 instances into one
#[test]
fn test_nifs_one_fold() {
let r1cs = get_test_r1cs();
let z1 = get_test_z(3);
let z2 = get_test_z(4);
let (w1, x1) = r1cs.split_z(&z1);
let (w2, x2) = r1cs.split_z(&z2);
let w1 = Witness::<G1Projective>::new(w1.clone(), r1cs.A.n_cols);
let w2 = Witness::<G1Projective>::new(w2.clone(), r1cs.A.n_cols);
let mut rng = ark_std::test_rng();
let pedersen_params = Pedersen::<G1Projective>::new_params(&mut rng, r1cs.A.n_cols);
let r = Fr::rand(&mut rng); // folding challenge would come from the transcript
// compute committed instances
let ci1 = w1.commit(&pedersen_params, x1.clone());
let ci2 = w2.commit(&pedersen_params, x2.clone());
// NIFS.P
let (w3, _, T, cmT) =
NIFS::<G1Projective>::prove(&pedersen_params, r, &r1cs, &w1, &ci1, &w2, &ci2);
// NIFS.V
let ci3 = NIFS::<G1Projective>::verify(r, &ci1, &ci2, &cmT);
// naive check that the folded witness satisfies the relaxed r1cs
let z3: Vec<Fr> = [vec![ci3.u], ci3.x.to_vec(), w3.W.to_vec()].concat();
// check that z3 is as expected
let z3_aux = vec_add(&z1, &vec_scalar_mul(&z2, &r));
assert_eq!(z3, z3_aux);
// check that relations hold for the 2 inputted instances and the folded one
check_relaxed_r1cs(&r1cs, z1, ci1.u, &w1.E);
check_relaxed_r1cs(&r1cs, z2, ci2.u, &w2.E);
check_relaxed_r1cs(&r1cs, z3, ci3.u, &w3.E);
// check that folded commitments from folded instance (ci) are equal to folding the
// use folded rE, rW to commit w3
let ci3_expected = w3.commit(&pedersen_params, ci3.x.clone());
assert_eq!(ci3_expected.cmE, ci3.cmE);
assert_eq!(ci3_expected.cmW, ci3.cmW);
// NIFS.Verify_Folded_Instance:
assert!(NIFS::<G1Projective>::verify_folded_instance(
r, &ci1, &ci2, &ci3, &cmT
));
let poseidon_config = poseidon_test_config::<Fr>();
// init Prover's transcript
let mut transcript_p = PoseidonTranscript::<G1Projective>::new(&poseidon_config);
// init Verifier's transcript
let mut transcript_v = PoseidonTranscript::<G1Projective>::new(&poseidon_config);
// check openings of ci3.cmE, ci3.cmW and cmT
let (cmE_proof, cmW_proof, cmT_proof) = NIFS::<G1Projective>::open_commitments(
&mut transcript_p,
&pedersen_params,
&w3,
&ci3,
T,
&cmT,
);
let v = NIFS::<G1Projective>::verify_commitments(
&mut transcript_v,
&pedersen_params,
ci3,
cmT,
cmE_proof,
cmW_proof,
cmT_proof,
);
assert!(v);
}
#[test]
fn test_nifs_fold_loop() {
let r1cs = get_test_r1cs();
let z = get_test_z(3);
let (w, x) = r1cs.split_z(&z);
let mut rng = ark_std::test_rng();
let pedersen_params = Pedersen::<G1Projective>::new_params(&mut rng, r1cs.A.n_cols);
// prepare the running instance
let mut running_instance_w = Witness::<G1Projective>::new(w.clone(), r1cs.A.n_cols);
let mut running_committed_instance = running_instance_w.commit(&pedersen_params, x);
check_relaxed_r1cs(
&r1cs,
z,
running_committed_instance.u,
&running_instance_w.E,
);
let num_iters = 10;
for i in 0..num_iters {
// prepare the incomming instance
let incomming_instance_z = get_test_z(i + 4);
let (w, x) = r1cs.split_z(&incomming_instance_z);
let incomming_instance_w = Witness::<G1Projective>::new(w.clone(), r1cs.A.n_cols);
let incomming_committed_instance = incomming_instance_w.commit(&pedersen_params, x);
check_relaxed_r1cs(
&r1cs,
incomming_instance_z.clone(),
incomming_committed_instance.u,
&incomming_instance_w.E,
);
let r = Fr::rand(&mut rng); // folding challenge would come from the transcript
// NIFS.P
let (folded_w, _, _, cmT) = NIFS::<G1Projective>::prove(
&pedersen_params,
r,
&r1cs,
&running_instance_w,
&running_committed_instance,
&incomming_instance_w,
&incomming_committed_instance,
);
// NIFS.V
let folded_committed_instance = NIFS::<G1Projective>::verify(
r,
&running_committed_instance,
&incomming_committed_instance,
&cmT,
);
let folded_z: Vec<Fr> = [
vec![folded_committed_instance.u],
folded_committed_instance.x.to_vec(),
folded_w.W.to_vec(),
]
.concat();
check_relaxed_r1cs(&r1cs, folded_z, folded_committed_instance.u, &folded_w.E);
// set running_instance for next loop iteration
running_instance_w = folded_w;
running_committed_instance = folded_committed_instance;
}
}
}

+ 1
- 0
src/lib.rs
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@ -9,6 +9,7 @@ use thiserror::Error;
pub mod transcript; pub mod transcript;
use transcript::Transcript; use transcript::Transcript;
pub mod ccs; pub mod ccs;
pub mod folding;
pub mod pedersen; pub mod pedersen;
pub mod utils; pub mod utils;

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