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protogalaxy-poc
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arnaucube f9591ecd63 implement K(X) & G(X) computation. Folding works 1 year ago
src implement K(X) & G(X) computation. Folding works 1 year ago
.gitignore init repo 1 year ago
Cargo.toml port pedersen.rs & transcript.rs from https://github.com/arnaucube/nova-study 1 year ago
LICENSE add eval_f & check_instance methods, add initial Folding prover structure 1 year ago
README.md implement K(X) & G(X) computation. Folding works 1 year ago

README.md

protogalaxy-poc

Proof of concept implementation of ProtoGalaxy (https://eprint.iacr.org/2023/1106.pdf) using arkworks.

Do not use in production.

Thanks to Liam Eagen and Ariel Gabizon for their kind explanations.

This code has been done in the context of the research on folding schemes in 0xPARC.

protogalaxy img from Wikipedia

(img: protogalaxies colliding, from Wikipedia)

Details

Implementation of ProtoGalaxy's scheme described in section 4 of the paper.

Current version implements the folding on prover & verifier and it works, but it is not optimized. Next steps in terms of implementation include: F(X) O(n) construction following Claim 4.4, compute K(X) in O(kd log(kd)M + ndkC) as described in Claim 4.5, add tests folding in multiple iterations and also in a tree approach, add the decider and integrate with some existing R1CS tooling for the R1CS & witness generation.

Usage

Example of folding k+1 instances:

// assume we have:
// an R1CS instance 'r1cs'
// a valid witness 'w' from our running instance
// k valid 'witnesses' to be fold

// compute the committed instance for our running witness
let phi = Pedersen::<G1Projective>::commit(&pedersen_params, &witness.w, &witness.r_w);
let instance = CommittedInstance::<G1Projective> {
    phi,
    betas: betas.clone(),
    e: Fr::zero(),
};

// compute the k committed instances to be fold
let mut instances: Vec<CommittedInstance<G1Projective>> = Vec::new();
for i in 0..k {
    let phi_i =
	Pedersen::<G1Projective>::commit(&pedersen_params, &witnesses[i].w, &witnesses[i].r_w);
    let instance_i = CommittedInstance::<G1Projective> {
	phi: phi_i,
	betas: betas.clone(),
	e: Fr::zero(),
    };
    witnesses.push(witness_i);
    instances.push(instance_i);
}

// set the initial random betas
let beta = Fr::rand(&mut rng);
let betas = powers_of_beta(beta, t);

// Prover folds the instances and witnesses
let (F_coeffs, K_coeffs, folded_instance, folded_witness) = Folding::<G1Projective>::prover(
    &mut transcript_p,
    &r1cs,
    instance.clone(),
    witness,
    instances.clone(),
    witnesses,
);

// verifier folds the instances
let folded_instance_v = Folding::<G1Projective>::verifier(
    &mut transcript_v,
    &r1cs,
    instance,
    instances,
    F_coeffs,
    K_coeffs,
);

// check that the folded instance satisfies the relation
assert!(check_instance(&r2cs, folded_instance, folded_witness));

(see the actual code for more details)