arnaucube
/
testudo
mirror of https://github.com/arnaucube/testudo.git


								//! Demonstrates how to produces a proof for canonical cubic equation: `x^3 + x + 5 = y`.

								//! The example is described in detail [here].

								//!

								//! The R1CS for this problem consists of the following 4 constraints:

								//! `Z0 * Z0 - Z1 = 0`

								//! `Z1 * Z0 - Z2 = 0`

								//! `(Z2 + Z0) * 1 - Z3 = 0`

								//! `(Z3 + 5) * 1 - I0 = 0`

								//!

								//! [here]: https://medium.com/@VitalikButerin/quadratic-arithmetic-programs-from-zero-to-hero-f6d558cea649

								use ark_bls12_377::Fr as Scalar;

								use ark_ff::{BigInteger, PrimeField};

								use ark_std::{One, UniformRand, Zero};

								use libspartan::{

								  parameters::poseidon_params, poseidon_transcript::PoseidonTranscript, InputsAssignment, Instance,

								  SNARKGens, VarsAssignment, SNARK,

								};


								#[allow(non_snake_case)]

								fn produce_r1cs() -> (

								  usize,

								  usize,

								  usize,

								  usize,

								  Instance,

								  VarsAssignment,

								  InputsAssignment,

								) {

								  // parameters of the R1CS instance

								  let num_cons = 4;

								  let num_vars = 4;

								  let num_inputs = 1;

								  let num_non_zero_entries = 8;


								  // We will encode the above constraints into three matrices, where

								  // the coefficients in the matrix are in the little-endian byte order

								  let mut A: Vec<(usize, usize, Vec<u8>)> = Vec::new();

								  let mut B: Vec<(usize, usize, Vec<u8>)> = Vec::new();

								  let mut C: Vec<(usize, usize, Vec<u8>)> = Vec::new();


								  let one = Scalar::one().into_repr().to_bytes_le();


								  // R1CS is a set of three sparse matrices A B C, where is a row for every

								  // constraint and a column for every entry in z = (vars, 1, inputs)

								  // An R1CS instance is satisfiable iff:

								  // Az \circ Bz = Cz, where z = (vars, 1, inputs)


								  // constraint 0 entries in (A,B,C)

								  // constraint 0 is Z0 * Z0 - Z1 = 0.

								  A.push((0, 0, one.clone()));

								  B.push((0, 0, one.clone()));

								  C.push((0, 1, one.clone()));


								  // constraint 1 entries in (A,B,C)

								  // constraint 1 is Z1 * Z0 - Z2 = 0.

								  A.push((1, 1, one.clone()));

								  B.push((1, 0, one.clone()));

								  C.push((1, 2, one.clone()));


								  // constraint 2 entries in (A,B,C)

								  // constraint 2 is (Z2 + Z0) * 1 - Z3 = 0.

								  A.push((2, 2, one.clone()));

								  A.push((2, 0, one.clone()));

								  B.push((2, num_vars, one.clone()));

								  C.push((2, 3, one.clone()));


								  // constraint 3 entries in (A,B,C)

								  // constraint 3 is (Z3 + 5) * 1 - I0 = 0.

								  A.push((3, 3, one.clone()));

								  A.push((3, num_vars, Scalar::from(5u32).into_repr().to_bytes_le()));

								  B.push((3, num_vars, one.clone()));

								  C.push((3, num_vars + 1, one.clone()));


								  let inst = Instance::new(num_cons, num_vars, num_inputs, &A, &B, &C).unwrap();


								  // compute a satisfying assignment

								  let mut rng = ark_std::rand::thread_rng();

								  let z0 = Scalar::rand(&mut rng);

								  let z1 = z0 * z0; // constraint 0

								  let z2 = z1 * z0; // constraint 1

								  let z3 = z2 + z0; // constraint 2

								  let i0 = z3 + Scalar::from(5u32); // constraint 3


								  // create a VarsAssignment

								  let mut vars = vec![Scalar::zero().into_repr().to_bytes_le(); num_vars];

								  vars[0] = z0.into_repr().to_bytes_le();

								  vars[1] = z1.into_repr().to_bytes_le();

								  vars[2] = z2.into_repr().to_bytes_le();

								  vars[3] = z3.into_repr().to_bytes_le();

								  let assignment_vars = VarsAssignment::new(&vars).unwrap();


								  // create an InputsAssignment

								  let mut inputs = vec![Scalar::zero().into_repr().to_bytes_le(); num_inputs];

								  inputs[0] = i0.into_repr().to_bytes_le();

								  let assignment_inputs = InputsAssignment::new(&inputs).unwrap();


								  // check if the instance we created is satisfiable

								  let res = inst.is_sat(&assignment_vars, &assignment_inputs);

								  assert!(res.unwrap(), "should be satisfied");


								  (

								    num_cons,

								    num_vars,

								    num_inputs,

								    num_non_zero_entries,

								    inst,

								    assignment_vars,

								    assignment_inputs,

								  )

								}


								fn main() {

								  // produce an R1CS instance

								  let (

								    num_cons,

								    num_vars,

								    num_inputs,

								    num_non_zero_entries,

								    inst,

								    assignment_vars,

								    assignment_inputs,

								  ) = produce_r1cs();


								  let params = poseidon_params();


								  // produce public parameters

								  let gens = SNARKGens::new(num_cons, num_vars, num_inputs, num_non_zero_entries);


								  // create a commitment to the R1CS instance

								  let (comm, decomm) = SNARK::encode(&inst, &gens);


								  // produce a proof of satisfiability

								  let mut prover_transcript = PoseidonTranscript::new(&params);

								  let proof = SNARK::prove(

								    &inst,

								    &comm,

								    &decomm,

								    assignment_vars,

								    &assignment_inputs,

								    &gens,

								    &mut prover_transcript,

								  );


								  // verify the proof of satisfiability

								  let mut verifier_transcript = PoseidonTranscript::new(&params);

								  assert!(proof

								    .verify(&comm, &assignment_inputs, &mut verifier_transcript, &gens)

								    .is_ok());

								  println!("proof verification successful!");

								}