#![allow(non_snake_case)]
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#![allow(non_camel_case_types)]
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#![allow(clippy::upper_case_acronyms)]
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///
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/// This example performs the full flow:
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/// - define the circuit to be folded
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/// - fold the circuit with Nova+CycleFold's IVC
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/// - generate a DeciderEthCircuit final proof
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/// - generate the Solidity contract that verifies the proof
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/// - verify the proof in the EVM
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///
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use ark_bn254::{constraints::GVar, Bn254, Fr, G1Projective as G1};
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use ark_ff::PrimeField;
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use ark_groth16::Groth16;
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use ark_grumpkin::{constraints::GVar as GVar2, Projective as G2};
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use ark_r1cs_std::alloc::AllocVar;
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use ark_r1cs_std::fields::fp::FpVar;
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use ark_relations::r1cs::{ConstraintSystemRef, SynthesisError};
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use std::marker::PhantomData;
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use std::time::Instant;
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use folding_schemes::{
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commitment::{kzg::KZG, pedersen::Pedersen},
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folding::nova::{
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decider_eth::{prepare_calldata, Decider as DeciderEth},
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Nova, PreprocessorParam,
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},
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frontend::FCircuit,
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transcript::poseidon::poseidon_canonical_config,
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Decider, Error, FoldingScheme,
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};
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use solidity_verifiers::{
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evm::{compile_solidity, Evm},
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utils::get_function_selector_for_nova_cyclefold_verifier,
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verifiers::nova_cyclefold::get_decider_template_for_cyclefold_decider,
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NovaCycleFoldVerifierKey,
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};
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/// Test circuit to be folded
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#[derive(Clone, Copy, Debug)]
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pub struct CubicFCircuit<F: PrimeField> {
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_f: PhantomData<F>,
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}
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impl<F: PrimeField> FCircuit<F> for CubicFCircuit<F> {
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type Params = ();
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fn new(_params: Self::Params) -> Result<Self, Error> {
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Ok(Self { _f: PhantomData })
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}
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fn state_len(&self) -> usize {
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1
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}
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fn external_inputs_len(&self) -> usize {
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0
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}
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fn step_native(
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&self,
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_i: usize,
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z_i: Vec<F>,
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_external_inputs: Vec<F>,
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) -> Result<Vec<F>, Error> {
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Ok(vec![z_i[0] * z_i[0] * z_i[0] + z_i[0] + F::from(5_u32)])
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}
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fn generate_step_constraints(
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&self,
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cs: ConstraintSystemRef<F>,
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_i: usize,
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z_i: Vec<FpVar<F>>,
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_external_inputs: Vec<FpVar<F>>,
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) -> Result<Vec<FpVar<F>>, SynthesisError> {
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let five = FpVar::<F>::new_constant(cs.clone(), F::from(5u32))?;
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let z_i = z_i[0].clone();
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Ok(vec![&z_i * &z_i * &z_i + &z_i + &five])
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}
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}
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fn main() {
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let n_steps = 10;
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// set the initial state
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let z_0 = vec![Fr::from(3_u32)];
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let f_circuit = CubicFCircuit::<Fr>::new(()).unwrap();
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pub type N =
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Nova<G1, GVar, G2, GVar2, CubicFCircuit<Fr>, KZG<'static, Bn254>, Pedersen<G2>, false>;
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pub type D = DeciderEth<
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G1,
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GVar,
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G2,
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GVar2,
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CubicFCircuit<Fr>,
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KZG<'static, Bn254>,
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Pedersen<G2>,
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Groth16<Bn254>,
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N,
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>;
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let poseidon_config = poseidon_canonical_config::<Fr>();
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let mut rng = rand::rngs::OsRng;
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// prepare the Nova prover & verifier params
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let nova_preprocess_params = PreprocessorParam::new(poseidon_config.clone(), f_circuit);
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let nova_params = N::preprocess(&mut rng, &nova_preprocess_params).unwrap();
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let pp_hash = nova_params.1.pp_hash().unwrap();
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// initialize the folding scheme engine, in our case we use Nova
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let mut nova = N::init(&nova_params, f_circuit, z_0).unwrap();
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// prepare the Decider prover & verifier params
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let (decider_pp, decider_vp) = D::preprocess(&mut rng, nova_params, nova.clone()).unwrap();
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// run n steps of the folding iteration
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for i in 0..n_steps {
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let start = Instant::now();
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nova.prove_step(rng, vec![], None).unwrap();
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println!("Nova::prove_step {}: {:?}", i, start.elapsed());
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}
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let start = Instant::now();
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let proof = D::prove(rng, decider_pp, nova.clone()).unwrap();
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println!("generated Decider proof: {:?}", start.elapsed());
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let verified = D::verify(
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decider_vp.clone(),
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nova.i,
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nova.z_0.clone(),
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nova.z_i.clone(),
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&nova.U_i,
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&nova.u_i,
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&proof,
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)
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.unwrap();
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assert!(verified);
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println!("Decider proof verification: {}", verified);
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// Now, let's generate the Solidity code that verifies this Decider final proof
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let function_selector =
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get_function_selector_for_nova_cyclefold_verifier(nova.z_0.len() * 2 + 1);
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let calldata: Vec<u8> = prepare_calldata(
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function_selector,
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pp_hash,
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nova.i,
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nova.z_0,
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nova.z_i,
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&nova.U_i,
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&nova.u_i,
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proof,
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)
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.unwrap();
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// prepare the setup params for the solidity verifier
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let nova_cyclefold_vk = NovaCycleFoldVerifierKey::from((decider_vp, f_circuit.state_len()));
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// generate the solidity code
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let decider_solidity_code = get_decider_template_for_cyclefold_decider(nova_cyclefold_vk);
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// verify the proof against the solidity code in the EVM
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let nova_cyclefold_verifier_bytecode = compile_solidity(&decider_solidity_code, "NovaDecider");
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let mut evm = Evm::default();
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let verifier_address = evm.create(nova_cyclefold_verifier_bytecode);
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let (_, output) = evm.call(verifier_address, calldata.clone());
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assert_eq!(*output.last().unwrap(), 1);
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// save smart contract and the calldata
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println!("storing nova-verifier.sol and the calldata into files");
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use std::fs;
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fs::write(
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"./examples/nova-verifier.sol",
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decider_solidity_code.clone(),
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)
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.unwrap();
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fs::write("./examples/solidity-calldata.calldata", calldata.clone()).unwrap();
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let s = solidity_verifiers::utils::get_formatted_calldata(calldata.clone());
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fs::write("./examples/solidity-calldata.inputs", s.join(",\n")).expect("");
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}
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