#![allow(clippy::all)] #![allow(deprecated)] #![allow(non_snake_case)] #[macro_use] extern crate criterion; use criterion::Criterion; // Code below copied from ../tests/r1cs.rs // // Ideally we wouldn't duplicate it, but AFAIK criterion requires a // seperate benchmark harness, while the test code uses a different // test harness, so I (hdevalence) just copied the code over. It // should not be edited here. In the future it would be good if // someone wants to figure a way to use #[path] attributes or // something to avoid the duplication. extern crate curve25519_dalek; extern crate merlin; extern crate rand; use bulletproofs::r1cs::*; use bulletproofs::{BulletproofGens, PedersenGens}; use curve25519_dalek::ristretto::CompressedRistretto; use curve25519_dalek::scalar::Scalar; use merlin::Transcript; use rand::seq::SliceRandom; use rand::Rng; use sunscreen_bulletproofs as bulletproofs; // 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 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(&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 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(&self.0, &pc_gens, &bp_gens) } } // End of copied code. /// Binary logarithm of maximum shuffle size. const LG_MAX_SHUFFLE_SIZE: usize = 10; /// Maximum shuffle size to benchmark. const MAX_SHUFFLE_SIZE: usize = 1 << LG_MAX_SHUFFLE_SIZE; fn bench_kshuffle_prove(c: &mut Criterion) { // Construct Bulletproof generators externally let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new(2 * MAX_SHUFFLE_SIZE, 1); c.bench_function_over_inputs( "k-shuffle proof creation", move |b, k| { // Generate inputs and outputs to kshuffle let mut rng = rand::thread_rng(); let (min, max) = (0u64, std::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()); // Make kshuffle proof b.iter(|| { let mut prover_transcript = Transcript::new(b"ShuffleBenchmark"); ShuffleProof::prove(&pc_gens, &bp_gens, &mut prover_transcript, &input, &output) .unwrap(); }) }, (1..=LG_MAX_SHUFFLE_SIZE) .map(|i| 1 << i) .collect::>(), ); } criterion_group! { name = kshuffle_prove; // Lower the sample size to run faster; larger shuffle sizes are // long so we're not microbenchmarking anyways. config = Criterion::default().sample_size(10); targets = bench_kshuffle_prove, } fn bench_kshuffle_verify(c: &mut Criterion) { // Construct Bulletproof generators externally let pc_gens = PedersenGens::default(); let bp_gens = BulletproofGens::new(2 * MAX_SHUFFLE_SIZE, 1); c.bench_function_over_inputs( "k-shuffle proof verification", move |b, k| { // Generate the proof in its own scope to prevent reuse of // prover variables by the verifier let (proof, input_commitments, output_commitments) = { // Generate inputs and outputs to kshuffle let mut rng = rand::thread_rng(); let (min, max) = (0u64, std::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"ShuffleBenchmark"); ShuffleProof::prove(&pc_gens, &bp_gens, &mut prover_transcript, &input, &output) .unwrap() }; // Verify kshuffle proof b.iter(|| { let mut verifier_transcript = Transcript::new(b"ShuffleBenchmark"); proof .verify( &pc_gens, &bp_gens, &mut verifier_transcript, &input_commitments, &output_commitments, ) .unwrap(); }) }, (1..=LG_MAX_SHUFFLE_SIZE) .map(|i| 1 << i) .collect::>(), ); } criterion_group! { name = kshuffle_verify; // Lower the sample size to run faster; larger shuffle sizes are // long so we're not microbenchmarking anyways. config = Criterion::default().sample_size(10); targets = bench_kshuffle_verify, } criterion_main!(kshuffle_prove, kshuffle_verify);