#![allow(non_snake_case)]
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use bellperson::{gadgets::num::AllocatedNum, ConstraintSystem, SynthesisError};
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use core::marker::PhantomData;
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use criterion::*;
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use ff::PrimeField;
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use nova_snark::{
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traits::{
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circuit::{StepCircuit, TrivialTestCircuit},
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Group,
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},
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CompressedSNARK, PublicParams, RecursiveSNARK,
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};
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use std::time::Duration;
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type G1 = pasta_curves::pallas::Point;
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type G2 = pasta_curves::vesta::Point;
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type EE1 = nova_snark::provider::ipa_pc::EvaluationEngine<G1>;
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type EE2 = nova_snark::provider::ipa_pc::EvaluationEngine<G2>;
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type S1 = nova_snark::spartan::RelaxedR1CSSNARK<G1, EE1>;
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type S2 = nova_snark::spartan::RelaxedR1CSSNARK<G2, EE2>;
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type C1 = NonTrivialTestCircuit<<G1 as Group>::Scalar>;
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type C2 = TrivialTestCircuit<<G2 as Group>::Scalar>;
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criterion_group! {
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name = compressed_snark;
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config = Criterion::default().warm_up_time(Duration::from_millis(3000));
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targets = bench_compressed_snark
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}
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criterion_main!(compressed_snark);
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fn bench_compressed_snark(c: &mut Criterion) {
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let num_samples = 10;
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let num_cons_verifier_circuit_primary = 9819;
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// we vary the number of constraints in the step circuit
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for &num_cons_in_augmented_circuit in
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[9819, 16384, 32768, 65536, 131072, 262144, 524288, 1048576].iter()
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{
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// number of constraints in the step circuit
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let num_cons = num_cons_in_augmented_circuit - num_cons_verifier_circuit_primary;
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let mut group = c.benchmark_group(format!("CompressedSNARK-StepCircuitSize-{num_cons}"));
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group.sample_size(num_samples);
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let c_primary = NonTrivialTestCircuit::new(num_cons);
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let c_secondary = TrivialTestCircuit::default();
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// Produce public parameters
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let pp = PublicParams::<G1, G2, C1, C2>::setup(c_primary.clone(), c_secondary.clone());
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// Produce prover and verifier keys for CompressedSNARK
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let (pk, vk) = CompressedSNARK::<_, _, _, _, S1, S2>::setup(&pp).unwrap();
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// produce a recursive SNARK
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let num_steps = 3;
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let mut recursive_snark: RecursiveSNARK<G1, G2, C1, C2> = RecursiveSNARK::new(
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&pp,
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&c_primary,
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&c_secondary,
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vec![<G1 as Group>::Scalar::from(2u64)],
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vec![<G2 as Group>::Scalar::from(2u64)],
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);
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for i in 0..num_steps {
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let res = recursive_snark.prove_step(
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&pp,
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&c_primary,
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&c_secondary,
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vec![<G1 as Group>::Scalar::from(2u64)],
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vec![<G2 as Group>::Scalar::from(2u64)],
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);
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assert!(res.is_ok());
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// verify the recursive snark at each step of recursion
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let res = recursive_snark.verify(
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&pp,
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i + 1,
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&vec![<G1 as Group>::Scalar::from(2u64)][..],
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&vec![<G2 as Group>::Scalar::from(2u64)][..],
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);
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assert!(res.is_ok());
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}
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// Bench time to produce a compressed SNARK
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group.bench_function("Prove", |b| {
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b.iter(|| {
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assert!(CompressedSNARK::<_, _, _, _, S1, S2>::prove(
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black_box(&pp),
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black_box(&pk),
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black_box(&recursive_snark)
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)
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.is_ok());
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})
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});
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let res = CompressedSNARK::<_, _, _, _, S1, S2>::prove(&pp, &pk, &recursive_snark);
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assert!(res.is_ok());
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let compressed_snark = res.unwrap();
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// Benchmark the verification time
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group.bench_function("Verify", |b| {
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b.iter(|| {
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assert!(black_box(&compressed_snark)
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.verify(
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black_box(&vk),
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black_box(num_steps),
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black_box(vec![<G1 as Group>::Scalar::from(2u64)]),
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black_box(vec![<G2 as Group>::Scalar::from(2u64)]),
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)
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.is_ok());
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})
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});
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group.finish();
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}
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}
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#[derive(Clone, Debug, Default)]
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struct NonTrivialTestCircuit<F: PrimeField> {
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num_cons: usize,
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_p: PhantomData<F>,
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}
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impl<F> NonTrivialTestCircuit<F>
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where
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F: PrimeField,
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{
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pub fn new(num_cons: usize) -> Self {
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Self {
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num_cons,
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_p: Default::default(),
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}
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}
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}
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impl<F> StepCircuit<F> for NonTrivialTestCircuit<F>
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where
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F: PrimeField,
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{
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fn arity(&self) -> usize {
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1
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}
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fn synthesize<CS: ConstraintSystem<F>>(
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&self,
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cs: &mut CS,
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z: &[AllocatedNum<F>],
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) -> Result<Vec<AllocatedNum<F>>, SynthesisError> {
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// Consider a an equation: `x^2 = y`, where `x` and `y` are respectively the input and output.
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let mut x = z[0].clone();
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let mut y = x.clone();
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for i in 0..self.num_cons {
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y = x.square(cs.namespace(|| format!("x_sq_{i}")))?;
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x = y.clone();
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}
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Ok(vec![y])
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}
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fn output(&self, z: &[F]) -> Vec<F> {
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let mut x = z[0];
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let mut y = x;
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for _i in 0..self.num_cons {
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y = x * x;
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x = y;
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}
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vec![y]
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}
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}
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