#![allow(non_snake_case)] extern crate curve25519_dalek; extern crate merlin; extern crate noah_bulletproofs; extern crate rand; use curve25519_dalek::ristretto::CompressedRistretto; use curve25519_dalek::scalar::Scalar; use merlin::Transcript; use noah_bulletproofs::r1cs::*; use noah_bulletproofs::{BulletproofGens, PedersenGens}; use rand::seq::SliceRandom; use rand::thread_rng; // Shuffle gadget (documented in markdown file) /// A proof-of-shuffle. struct ShuffleProof(R1CSProof); impl ShuffleProof { fn gadget( cs: &mut CS, x: Vec, y: Vec, ) -> Result<(), R1CSError> { assert_eq!(x.len(), y.len()); let k = x.len(); if k == 1 { cs.constrain(y[0] - x[0]); return Ok(()); } cs.specify_randomized_constraints(move |cs| { let z = cs.challenge_scalar(b"shuffle challenge"); // Make last x multiplier for i = k-1 and k-2 let (_, _, last_mulx_out) = cs.multiply(x[k - 1] - z, x[k - 2] - z); // Make multipliers for x from i == [0, k-3] let first_mulx_out = (0..k - 2).rev().fold(last_mulx_out, |prev_out, i| { let (_, _, o) = cs.multiply(prev_out.into(), x[i] - z); o }); // Make last y multiplier for i = k-1 and k-2 let (_, _, last_muly_out) = cs.multiply(y[k - 1] - z, y[k - 2] - z); // Make multipliers for y from i == [0, k-3] let first_muly_out = (0..k - 2).rev().fold(last_muly_out, |prev_out, i| { let (_, _, o) = cs.multiply(prev_out.into(), y[i] - z); o }); // Constrain last x mul output and last y mul output to be equal cs.constrain(first_mulx_out - first_muly_out); Ok(()) }) } } impl ShuffleProof { /// Attempt to construct a proof that `output` is a permutation of `input`. /// /// Returns a tuple `(proof, input_commitments || output_commitments)`. pub fn prove<'a, 'b>( pc_gens: &'b PedersenGens, bp_gens: &'b BulletproofGens, transcript: &'a mut Transcript, input: &[Scalar], output: &[Scalar], ) -> Result< ( ShuffleProof, Vec, Vec, ), R1CSError, > { // Apply a domain separator with the shuffle parameters to the transcript // XXX should this be part of the gadget? let k = input.len(); transcript.append_message(b"dom-sep", b"ShuffleProof"); transcript.append_u64(b"k", k as u64); let mut rng = rand::thread_rng(); let mut prover = Prover::new(&pc_gens, transcript); // Construct blinding factors using an RNG. // Note: a non-example implementation would want to operate on existing commitments. let mut blinding_rng = rand::thread_rng(); let (input_commitments, input_vars): (Vec<_>, Vec<_>) = input .into_iter() .map(|v| prover.commit(*v, Scalar::random(&mut blinding_rng))) .unzip(); let (output_commitments, output_vars): (Vec<_>, Vec<_>) = output .into_iter() .map(|v| prover.commit(*v, Scalar::random(&mut blinding_rng))) .unzip(); ShuffleProof::gadget(&mut prover, input_vars, output_vars)?; let proof = prover.prove(&mut rng, &bp_gens)?; Ok((ShuffleProof(proof), input_commitments, output_commitments)) } } impl ShuffleProof { /// Attempt to verify a `ShuffleProof`. pub fn verify<'a, 'b>( &self, pc_gens: &'b PedersenGens, bp_gens: &'b BulletproofGens, transcript: &'a mut Transcript, input_commitments: &Vec, output_commitments: &Vec, ) -> Result<(), R1CSError> { // Apply a domain separator with the shuffle parameters to the transcript // XXX should this be part of the gadget? let k = input_commitments.len(); transcript.append_message(b"dom-sep", b"ShuffleProof"); transcript.append_u64(b"k", k as u64); let mut rng = rand::thread_rng(); let mut verifier = Verifier::new(transcript); let input_vars: Vec<_> = input_commitments .iter() .map(|V| verifier.commit(*V)) .collect(); let output_vars: Vec<_> = output_commitments .iter() .map(|V| verifier.commit(*V)) .collect(); ShuffleProof::gadget(&mut verifier, input_vars, output_vars)?; verifier.verify(&mut rng, &self.0, &pc_gens, &bp_gens)?; Ok(()) } } fn kshuffle_helper(k: usize) { use rand::Rng; // Common code let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new((2 * k).next_power_of_two(), 1); let (proof, input_commitments, output_commitments) = { // Randomly generate inputs and outputs to kshuffle let mut rng = rand::thread_rng(); let (min, max) = (0u64, u64::MAX); let input: Vec = (0..k) .map(|_| Scalar::from(rng.gen_range(min..max))) .collect(); let mut output = input.clone(); output.shuffle(&mut rand::thread_rng()); let mut prover_transcript = Transcript::new(b"ShuffleProofTest"); ShuffleProof::prove(&pc_gens, &bp_gens, &mut prover_transcript, &input, &output).unwrap() }; { let mut verifier_transcript = Transcript::new(b"ShuffleProofTest"); assert!(proof .verify( &pc_gens, &bp_gens, &mut verifier_transcript, &input_commitments, &output_commitments ) .is_ok()); } } #[test] fn shuffle_gadget_test_1() { kshuffle_helper(1); } #[test] fn shuffle_gadget_test_2() { kshuffle_helper(2); } #[test] fn shuffle_gadget_test_3() { kshuffle_helper(3); } #[test] fn shuffle_gadget_test_4() { kshuffle_helper(4); } #[test] fn shuffle_gadget_test_5() { kshuffle_helper(5); } #[test] fn shuffle_gadget_test_6() { kshuffle_helper(6); } #[test] fn shuffle_gadget_test_7() { kshuffle_helper(7); } #[test] fn shuffle_gadget_test_24() { kshuffle_helper(24); } #[test] fn shuffle_gadget_test_42() { kshuffle_helper(42); } /// Constrains (a1 + a2) * (b1 + b2) = (c1 + c2) fn example_gadget( cs: &mut CS, a1: LinearCombination, a2: LinearCombination, b1: LinearCombination, b2: LinearCombination, c1: LinearCombination, c2: LinearCombination, ) { let (_, _, c_var) = cs.multiply(a1 + a2, b1 + b2); cs.constrain(c1 + c2 - c_var); } // Prover's scope fn example_gadget_proof( pc_gens: &PedersenGens, bp_gens: &BulletproofGens, a1: u64, a2: u64, b1: u64, b2: u64, c1: u64, c2: u64, ) -> Result<(R1CSProof, Vec), R1CSError> { let mut transcript = Transcript::new(b"R1CSExampleGadget"); let mut rng = thread_rng(); // 1. Create a prover let mut prover = Prover::new(pc_gens, &mut transcript); // 2. Commit high-level variables let (commitments, vars): (Vec<_>, Vec<_>) = [a1, a2, b1, b2, c1] .iter() .map(|x| prover.commit(Scalar::from(*x), Scalar::random(&mut thread_rng()))) .unzip(); // 3. Build a CS example_gadget( &mut prover, vars[0].into(), vars[1].into(), vars[2].into(), vars[3].into(), vars[4].into(), Scalar::from(c2).into(), ); // 4. Make a proof let proof = prover.prove(&mut rng, bp_gens)?; Ok((proof, commitments)) } // Verifier logic fn example_gadget_verify( pc_gens: &PedersenGens, bp_gens: &BulletproofGens, c2: u64, proof: R1CSProof, commitments: Vec, ) -> Result<(), R1CSError> { let mut rng = thread_rng(); let mut transcript = Transcript::new(b"R1CSExampleGadget"); // 1. Create a verifier let mut verifier = Verifier::new(&mut transcript); // 2. Commit high-level variables let vars: Vec<_> = commitments.iter().map(|V| verifier.commit(*V)).collect(); // 3. Build a CS example_gadget( &mut verifier, vars[0].into(), vars[1].into(), vars[2].into(), vars[3].into(), vars[4].into(), Scalar::from(c2).into(), ); // 4. Verify the proof verifier .verify(&mut rng, &proof, &pc_gens, &bp_gens) .map_err(|_| R1CSError::VerificationError) } fn example_gadget_roundtrip_helper( a1: u64, a2: u64, b1: u64, b2: u64, c1: u64, c2: u64, ) -> Result<(), R1CSError> { // Common let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new(128, 1); let (proof, commitments) = example_gadget_proof(&pc_gens, &bp_gens, a1, a2, b1, b2, c1, c2)?; example_gadget_verify(&pc_gens, &bp_gens, c2, proof, commitments) } fn example_gadget_roundtrip_serialization_helper( a1: u64, a2: u64, b1: u64, b2: u64, c1: u64, c2: u64, ) -> Result<(), R1CSError> { // Common let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new(128, 1); let (proof, commitments) = example_gadget_proof(&pc_gens, &bp_gens, a1, a2, b1, b2, c1, c2)?; let proof = proof.to_bytes(); let proof = R1CSProof::from_bytes(&proof)?; example_gadget_verify(&pc_gens, &bp_gens, c2, proof, commitments) } #[test] fn example_gadget_test() { // (3 + 4) * (6 + 1) = (40 + 9) assert!(example_gadget_roundtrip_helper(3, 4, 6, 1, 40, 9).is_ok()); // (3 + 4) * (6 + 1) != (40 + 10) assert!(example_gadget_roundtrip_helper(3, 4, 6, 1, 40, 10).is_err()); } #[test] fn example_gadget_serialization_test() { // (3 + 4) * (6 + 1) = (40 + 9) assert!(example_gadget_roundtrip_serialization_helper(3, 4, 6, 1, 40, 9).is_ok()); // (3 + 4) * (6 + 1) != (40 + 10) assert!(example_gadget_roundtrip_serialization_helper(3, 4, 6, 1, 40, 10).is_err()); } // Range Proof gadget /// Enforces that the quantity of v is in the range [0, 2^n). pub fn range_proof( cs: &mut CS, mut v: LinearCombination, v_assignment: Option, n: usize, ) -> Result<(), R1CSError> { let mut exp_2 = Scalar::one(); for i in 0..n { // Create low-level variables and add them to constraints let (a, b, o) = cs.allocate_multiplier(v_assignment.map(|q| { let bit: u64 = (q >> i) & 1; ((1 - bit).into(), bit.into()) }))?; // Enforce a * b = 0, so one of (a,b) is zero cs.constrain(o.into()); // Enforce that a = 1 - b, so they both are 1 or 0. cs.constrain(a + (b - 1u64)); // Add `-b_i*2^i` to the linear combination // in order to form the following constraint by the end of the loop: // v = Sum(b_i * 2^i, i = 0..n-1) v = v - b * exp_2; exp_2 = exp_2 + exp_2; } // Enforce that v = Sum(b_i * 2^i, i = 0..n-1) cs.constrain(v); Ok(()) } #[test] fn range_proof_gadget() { use rand::thread_rng; use rand::Rng; let mut rng = thread_rng(); let m = 3; // number of values to test per `n` for n in [2, 10, 32, 63].iter() { let (min, max) = (0u64, ((1u128 << n) - 1) as u64); let values: Vec = (0..m).map(|_| rng.gen_range(min..max)).collect(); for v in values { assert!(range_proof_helper(v.into(), *n).is_ok()); } assert!(range_proof_helper((max + 1).into(), *n).is_err()); } } fn range_proof_helper(v_val: u64, n: usize) -> Result<(), R1CSError> { // Common let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new(128, 1); let mut rng = rand::thread_rng(); // Prover's scope let (proof, commitment) = { // Prover makes a `ConstraintSystem` instance representing a range proof gadget let mut prover_transcript = Transcript::new(b"RangeProofTest"); let mut prover = Prover::new(&pc_gens, &mut prover_transcript); let (com, var) = prover.commit(v_val.into(), Scalar::random(&mut rng)); assert!(range_proof(&mut prover, var.into(), Some(v_val), n).is_ok()); let proof = prover.prove(&mut rng, &bp_gens)?; (proof, com) }; // Verifier makes a `ConstraintSystem` instance representing a merge gadget let mut verifier_transcript = Transcript::new(b"RangeProofTest"); let mut verifier = Verifier::new(&mut verifier_transcript); let var = verifier.commit(commitment); // Verifier adds constraints to the constraint system assert!(range_proof(&mut verifier, var.into(), None, n).is_ok()); // Verifier verifies proof verifier.verify(&mut rng, &proof, &pc_gens, &bp_gens) } #[test] fn batch_range_proof_gadget() { let values = [(0u64, 16usize)]; assert!(batch_range_proof_helper(&values).is_ok()); let values = [(0u64, 16usize), (3, 16), ((1 << 16) - 1, 16), (1 << 16, 32)]; assert!(batch_range_proof_helper(&values).is_ok()); let values = [(0u64, 16usize), (3, 16), (1 << 16, 16), (1 << 16, 32)]; assert!(batch_range_proof_helper(&values).is_err()); let values = [ (0u64, 16usize), (3, 16), ((1 << 16) - 1, 16), (1 << 16, 32), (1 << 63, 64), ]; assert!(batch_range_proof_helper(&values).is_ok()); let values = [ (0u64, 16usize), (3, 16), ((1 << 16) - 1, 16), (1u64 << 32, 32), (1 << 63, 64), ]; assert!(batch_range_proof_helper(&values).is_err()); } fn batch_range_proof_helper(v_vals: &[(u64, usize)]) -> Result<(), R1CSError> { // Common let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new(128, 1); let mut proofs = vec![]; let mut commitments = vec![]; let mut range_bound = vec![]; for (v, n) in v_vals { // Prover's scope let (proof, commitment) = { // Prover makes a `ConstraintSystem` instance representing a range proof gadget let mut prover_transcript = Transcript::new(b"RangeProofTest"); let mut rng = rand::thread_rng(); let mut prover = Prover::new(&pc_gens, &mut prover_transcript); let (com, var) = prover.commit(Scalar::from(*v), Scalar::random(&mut rng)); assert!(range_proof(&mut prover, var.into(), Some(*v), *n).is_ok()); let proof = prover.prove(&mut rng, &bp_gens)?; (proof, com) }; range_bound.push(*n); proofs.push(proof); commitments.push(commitment); } let mut verifier_transcripts = vec![Transcript::new(b"RangeProofTest"); commitments.len()]; let mut verifiers = vec![]; let mut prng = thread_rng(); for ((commitment, transcript), n) in commitments .iter() .zip(verifier_transcripts.iter_mut()) .zip(range_bound) { let mut verifier = Verifier::new(transcript); // Verifier makes a `ConstraintSystem` instance representing a merge gadget let var = verifier.commit(*commitment); // Verifier adds constraints to the constraint system assert!(range_proof(&mut verifier, var.into(), None, n).is_ok()); verifiers.push(verifier); } let a = verifiers.into_iter().zip(proofs.iter()); batch_verify(&mut prng, a, &pc_gens, &bp_gens) }