Adapt Frontend/Circom for FCircuit Trait (#71)

* initial * improved z_i * improved * Redefined the .circom and the test code for CircomWrapper * added test function for wrapper_circuit which has circom_fcircuit, but incompatibility error of Pairing and Pallas * changed the path in the gitignore * Remove circom generated path * improved variable vector * Pallas::Fr * improved to the primefield * mentioned the issues:1. extract z_i1(only public output) 2.constraintsSystem and its Ref * modified * public input in circom * generalized; removed the hardcorded value * Generalization using FpVar::<Fr>::new_input * initial * improved z_i * improved * Redefined the .circom and the test code for CircomWrapper * added test function for wrapper_circuit which has circom_fcircuit, but incompatibility error of Pairing and Pallas * Remove circom generated path * improved variable vector * Pallas::Fr * improved to the primefield * mentioned the issues:1. extract z_i1(only public output) 2.constraintsSystem and its Ref * modified * Small updates: - update cubic_circuit.circom: remove extra constraint, remove public inputs - remove allocations of inputs in arkworks - add return of z_{i+1} at the end of CircomtoFCircuit::generate_step_constraints With this tmp fix the `test_circom_step_constraints` passes, but needs to be iterated and polished. * Update circom-compat to re-allocate inputs * update after rebase to latest main: add usage of self.state_len() to circom frontend * move circom frontend related structs into frontend/circom dir * clippy lints * extract_witness * add comments * clean * fmt, lint, and spell * CI Check trigger * fmt * applied the feedback --------- Co-authored-by: Y5 <76672645+yugonsan@users.noreply.github.com> Co-authored-by: arnaucube <root@arnaucube.com>
7 months ago · 03f66919a3
9 changed files with 323 additions and 217 deletions
--- a/.gitignore
+++ b/.gitignore
@ -1,8 +1,8 @@
 /target
 Cargo.lock
 # Circom generated files
 /src/frontend/circom/test_folder/test_circuit.r1cs
 /src/frontend/circom/test_folder/test_circuit_js/
 folding-schemes/src/frontend/circom/test_folder/cubic_circuit.r1cs
 folding-schemes/src/frontend/circom/test_folder/cubic_circuit_js/

 # generated contracts at test time
 solidity-verifiers/generated
 solidity-verifiers/generated
--- a/folding-schemes/Cargo.toml
+++ b/folding-schemes/Cargo.toml
@ -14,7 +14,7 @@ ark-relations = { version = "^0.4.0", default-features = false }
 ark-r1cs-std = { version = "0.4.0", default-features = false } # this is patched at the workspace level
 ark-snark = { version = "^0.4.0"}
 ark-serialize = "^0.4.0"
 ark-circom = { git = "https://github.com/gakonst/ark-circom.git" }
 ark-circom = { git = "https://github.com/arnaucube/circom-compat.git" }
 thiserror = "1.0"
 rayon = "1.7.0"
 num-bigint = "0.4"
--- a/folding-schemes/src/frontend/circom/mod.rs
+++ b/folding-schemes/src/frontend/circom/mod.rs
@ -1,226 +1,177 @@
 use std::{error::Error, fs::File, io::BufReader, marker::PhantomData, path::PathBuf};

 use color_eyre::Result;
 use ark_circom::circom::CircomCircuit;
 use ark_ff::PrimeField;
 use ark_r1cs_std::alloc::AllocVar;
 use ark_r1cs_std::fields::fp::FpVar;
 use ark_r1cs_std::R1CSVar;
 use ark_relations::r1cs::{ConstraintSynthesizer, ConstraintSystemRef, SynthesisError};
 use ark_std::fmt::Debug;
 use num_bigint::BigInt;
 use std::path::PathBuf;

 use ark_circom::{circom::r1cs_reader, WitnessCalculator};
 use ark_ec::pairing::Pairing;
 use ark_ff::PrimeField;
 use crate::frontend::FCircuit;
 use crate::Error;

 use crate::ccs::r1cs::R1CS;
 use crate::utils::vec::SparseMatrix;

 // Define the sparse matrices on PrimeFiled.
 pub type Constraints<F> = (ConstraintVec<F>, ConstraintVec<F>, ConstraintVec<F>);
 pub type ConstraintVec<F> = Vec<(usize, F)>;
 type ExtractedConstraints<F> = (Vec<Constraints<F>>, usize, usize);
 pub type ExtractedConstraintsResult<F> = Result<ExtractedConstraints<F>, Box<dyn Error>>;
 pub type R1CSandZ<F> = (R1CS<F>, Vec<F>);

 // A struct that wraps Circom functionalities, allowing for extraction of R1CS and witnesses
 // based on file paths to Circom's .r1cs and .wasm.
 pub struct CircomWrapper<E: Pairing> {
    r1cs_filepath: PathBuf,
    wasm_filepath: PathBuf,
    _marker: PhantomData<E>,
 pub mod utils;
 use utils::CircomWrapper;

 /// Define CircomFCircuit
 #[derive(Clone, Debug)]
 pub struct CircomFCircuit<F: PrimeField> {
    circom_wrapper: CircomWrapper<F>,
 }

 impl<E: Pairing> CircomWrapper<E> {
    // Creates a new instance of the CircomWrapper with the file paths.
    pub fn new(r1cs_filepath: PathBuf, wasm_filepath: PathBuf) -> Self {
        CircomWrapper {
            r1cs_filepath,
            wasm_filepath,
            _marker: PhantomData,
        }
 impl<F: PrimeField> FCircuit<F> for CircomFCircuit<F> {
    type Params = (PathBuf, PathBuf);

    fn new(params: Self::Params) -> Self {
        let (r1cs_path, wasm_path) = params;
        let circom_wrapper = CircomWrapper::new(r1cs_path, wasm_path);
        Self { circom_wrapper }
    }

    // Aggregates multiple functions to obtain R1CS and Z as defined in folding-schemes from Circom.
    pub fn extract_r1cs_and_z(
        &self,
        inputs: &[(String, Vec<BigInt>)],
    ) -> Result<R1CSandZ<E::ScalarField>, Box<dyn Error>> {
        let (constraints, pub_io_len, num_variables) = self.extract_constraints_from_r1cs()?;
        let witness = self.calculate_witness(inputs)?;
        self.circom_to_folding_schemes_r1cs_and_z(constraints, &witness, pub_io_len, num_variables)
    fn state_len(&self) -> usize {
        1
    }

    // Extracts constraints from the r1cs file.
    pub fn extract_constraints_from_r1cs(&self) -> ExtractedConstraintsResult<E::ScalarField>
    where
        E: Pairing,
    {
        // Opens the .r1cs file and create a reader.
        let file = File::open(&self.r1cs_filepath)?;
        let reader = BufReader::new(file);

        // Reads the R1CS file and extract the constraints directly.
        let r1cs_file = r1cs_reader::R1CSFile::<E>::new(reader)?;
        let pub_io_len = (r1cs_file.header.n_pub_in + r1cs_file.header.n_pub_out) as usize;
        let r1cs = r1cs_reader::R1CS::<E>::from(r1cs_file);
        let num_variables = r1cs.num_variables;
        let constraints: Vec<Constraints<E::ScalarField>> = r1cs.constraints;

        Ok((constraints, pub_io_len, num_variables))
    fn step_native(&self, _i: usize, z_i: Vec<F>) -> Result<Vec<F>, Error> {
        // Converts PrimeField values to BigInt for computing witness.
        let input_num_bigint = z_i
            .iter()
            .map(|val| self.circom_wrapper.ark_primefield_to_num_bigint(*val))
            .collect::<Vec<BigInt>>();

        // Computes witness
        let witness = self
            .circom_wrapper
            .extract_witness(&[("ivc_input".to_string(), input_num_bigint)])
            .map_err(|e| {
                Error::WitnessCalculationError(format!("Failed to calculate witness: {}", e))
            })?;

        // Extracts the z_i1(next state) from the witness vector.
        let z_i1 = witness[1..1 + self.state_len()].to_vec();
        Ok(z_i1)
    }

    // Converts a set of constraints from ark-circom into R1CS format of folding-schemes.
    pub fn convert_to_folding_schemes_r1cs<F>(
    fn generate_step_constraints(
        &self,
        constraints: Vec<Constraints<F>>,
        pub_io_len: usize,
        num_variables: usize,
    ) -> R1CS<F>
    where
        F: PrimeField,
    {
        let mut a_matrix: Vec<Vec<(F, usize)>> = Vec::new();
        let mut b_matrix: Vec<Vec<(F, usize)>> = Vec::new();
        let mut c_matrix: Vec<Vec<(F, usize)>> = Vec::new();

        let n_rows = constraints.len();

        for (ai, bi, ci) in constraints {
            a_matrix.push(
                ai.into_iter()
                    .map(|(index, scalar)| (scalar, index))
                    .collect(),
            );
            b_matrix.push(
                bi.into_iter()
                    .map(|(index, scalar)| (scalar, index))
                    .collect(),
            );
            c_matrix.push(
                ci.into_iter()
                    .map(|(index, scalar)| (scalar, index))
                    .collect(),
            );
        cs: ConstraintSystemRef<F>,
        _i: usize,
        z_i: Vec<FpVar<F>>,
    ) -> Result<Vec<FpVar<F>>, SynthesisError> {
        let mut input_values = Vec::new();
        // Converts each FpVar to PrimeField value, then to num_bigint::BigInt.
        for fp_var in z_i.iter() {
            // Extracts the PrimeField value from FpVar.
            let primefield_value = fp_var.value()?;
            // Converts the PrimeField value to num_bigint::BigInt.
            let num_bigint_value = self
                .circom_wrapper
                .ark_primefield_to_num_bigint(primefield_value);
            input_values.push(num_bigint_value);
        }

        let l = pub_io_len;
        let n_cols = num_variables;
        let num_bigint_inputs = vec![("ivc_input".to_string(), input_values)];

        let A = SparseMatrix {
            n_rows,
            n_cols,
            coeffs: a_matrix,
        };
        let B = SparseMatrix {
            n_rows,
            n_cols,
            coeffs: b_matrix,
        };
        let C = SparseMatrix {
            n_rows,
            n_cols,
            coeffs: c_matrix,
        // Extracts R1CS and witness.
        let (r1cs, witness) = self
            .circom_wrapper
            .extract_r1cs_and_witness(&num_bigint_inputs)
            .map_err(|_| SynthesisError::AssignmentMissing)?;

        // Initializes the CircomCircuit.
        let circom_circuit = CircomCircuit {
            r1cs,
            witness: witness.clone(),
            inputs_already_computed: true,
        };

        R1CS::<F> { l, A, B, C }
    }
        // Generates the constraints for the circom_circuit.
        circom_circuit
            .generate_constraints(cs.clone())
            .map_err(|_| SynthesisError::AssignmentMissing)?;

    // Calculates the witness given the Wasm filepath and inputs.
    pub fn calculate_witness(&self, inputs: &[(String, Vec<BigInt>)]) -> Result<Vec<BigInt>> {
        let mut calculator = WitnessCalculator::new(&self.wasm_filepath)?;
        calculator.calculate_witness(inputs.iter().cloned(), true)
    }
        // Checks for constraint satisfaction.
        if !cs.is_satisfied().unwrap() {
            return Err(SynthesisError::Unsatisfiable);
        }

    // Converts a num_bigint input to `PrimeField`'s BigInt.
    pub fn num_bigint_to_ark_bigint<F: PrimeField>(
        &self,
        value: &BigInt,
    ) -> Result<F::BigInt, Box<dyn Error>> {
        let big_uint = value
            .to_biguint()
            .ok_or_else(|| "BigInt is negative".to_string())?;
        F::BigInt::try_from(big_uint).map_err(|_| "BigInt conversion failed".to_string().into())
    }
        let w = witness.ok_or(SynthesisError::Unsatisfiable)?;

    // Converts R1CS constraints and witness from ark-circom format
    // into folding-schemes R1CS and z format.
    pub fn circom_to_folding_schemes_r1cs_and_z<F>(
        &self,
        constraints: Vec<Constraints<F>>,
        witness: &[BigInt],
        pub_io_len: usize,
        num_variables: usize,
    ) -> Result<(R1CS<F>, Vec<F>), Box<dyn Error>>
    where
        F: PrimeField,
    {
        let folding_schemes_r1cs =
            self.convert_to_folding_schemes_r1cs(constraints, pub_io_len, num_variables);

        let z: Result<Vec<F>, _> = witness
            .iter()
            .map(|big_int| {
                let ark_big_int = self.num_bigint_to_ark_bigint::<F>(big_int)?;
                F::from_bigint(ark_big_int).ok_or_else(|| {
                    "Failed to convert bigint to field element"
                        .to_string()
                        .into()
                })
            })
            .collect();

        z.map(|z| (folding_schemes_r1cs, z))
        // Extracts the z_i1(next state) from the witness vector.
        let z_i1: Vec<FpVar<F>> =
            Vec::<FpVar<F>>::new_witness(cs.clone(), || Ok(w[1..1 + self.state_len()].to_vec()))?;

        Ok(z_i1)
    }
 }

 #[cfg(test)]
 mod tests {
    use crate::frontend::circom::CircomWrapper;
    use ark_bn254::Bn254;
    use num_bigint::BigInt;
    use std::env;

    /*
    test_circuit represents 35 = x^3 + x + 5 in test_folder/test_circuit.circom.
    In the test_circom_conversion_success function, x is assigned the value 3, which satisfies the R1CS correctly.
    In the test_circom_conversion_failure function, x is assigned the value 6, which doesn't satisfy the R1CS.
    */

    /*
    To generate .r1cs and .wasm files, run the below command in the terminal.
    bash ./src/frontend/circom/test_folder/compile.sh
    */

    fn test_circom_conversion_logic(expect_success: bool, inputs: Vec<(String, Vec<BigInt>)>) {
        let current_dir = env::current_dir().unwrap();
        let base_path = current_dir.join("src/frontend/circom/test_folder");

        let r1cs_filepath = base_path.join("test_circuit.r1cs");
        let wasm_filepath = base_path.join("test_circuit_js/test_circuit.wasm");

        assert!(r1cs_filepath.exists());
        assert!(wasm_filepath.exists());

        let circom_wrapper = CircomWrapper::<Bn254>::new(r1cs_filepath, wasm_filepath);

        let (r1cs, z) = circom_wrapper
            .extract_r1cs_and_z(&inputs)
            .expect("Error processing input");

        // Checks the relationship of R1CS.
        let check_result = std::panic::catch_unwind(|| {
            r1cs.check_relation(&z).unwrap();
        });

        match (expect_success, check_result) {
            (true, Ok(_)) => {}
            (false, Err(_)) => {}
            (true, Err(_)) => panic!("Expected success but got a failure."),
            (false, Ok(_)) => panic!("Expected a failure but got success."),
        }
 pub mod tests {
    use super::*;
    use ark_pallas::Fr;
    use ark_r1cs_std::alloc::AllocVar;
    use ark_relations::r1cs::{ConstraintSynthesizer, ConstraintSystem};

    // Tests the step_native function of CircomFCircuit.
    #[test]
    fn test_circom_step_native() {
        let r1cs_path = PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit.r1cs");
        let wasm_path =
            PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit_js/cubic_circuit.wasm");

        let circom_fcircuit = CircomFCircuit::<Fr>::new((r1cs_path, wasm_path));

        let z_i = vec![Fr::from(3u32)];
        let z_i1 = circom_fcircuit.step_native(1, z_i).unwrap();
        assert_eq!(z_i1, vec![Fr::from(35u32)]);
    }

    // Tests the generate_step_constraints function of CircomFCircuit.
    #[test]
    fn test_circom_conversion() {
        // expect it to pass for correct inputs.
        test_circom_conversion_logic(true, vec![("step_in".to_string(), vec![BigInt::from(3)])]);
    fn test_circom_step_constraints() {
        let r1cs_path = PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit.r1cs");
        let wasm_path =
            PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit_js/cubic_circuit.wasm");

        let circom_fcircuit = CircomFCircuit::<Fr>::new((r1cs_path, wasm_path));

        let cs = ConstraintSystem::<Fr>::new_ref();

        let z_i = vec![Fr::from(3u32)];

        let z_i_var = Vec::<FpVar<Fr>>::new_witness(cs.clone(), || Ok(z_i)).unwrap();

        let cs = ConstraintSystem::<Fr>::new_ref();
        let z_i1_var = circom_fcircuit
            .generate_step_constraints(cs.clone(), 1, z_i_var)
            .unwrap();
        assert_eq!(z_i1_var.value().unwrap(), vec![Fr::from(35u32)]);
    }

    // Tests the WrapperCircuit with CircomFCircuit.
    #[test]
    fn test_wrapper_circomtofcircuit() {
        let r1cs_path = PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit.r1cs");
        let wasm_path =
            PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit_js/cubic_circuit.wasm");

        let circom_fcircuit = CircomFCircuit::<Fr>::new((r1cs_path, wasm_path));

        // Allocates z_i1 by using step_native function.
        let z_i = vec![Fr::from(3_u32)];
        let wrapper_circuit = crate::frontend::tests::WrapperCircuit {
            FC: circom_fcircuit.clone(),
            z_i: Some(z_i.clone()),
            z_i1: Some(circom_fcircuit.step_native(0, z_i.clone()).unwrap()),
        };

        let cs = ConstraintSystem::<Fr>::new_ref();

        // expect it to fail for incorrect inputs.
        test_circom_conversion_logic(false, vec![("step_in".to_string(), vec![BigInt::from(7)])]);
        wrapper_circuit.generate_constraints(cs.clone()).unwrap();
        assert!(
            cs.is_satisfied().unwrap(),
            "Constraint system is not satisfied"
        );
    }
 }
--- a/folding-schemes/src/frontend/circom/test_folder/compile.sh
+++ b/folding-schemes/src/frontend/circom/test_folder/compile.sh
@ -1,2 +1,2 @@
 #!/bin/bash
 circom ./folding-schemes/src/frontend/circom/test_folder/test_circuit.circom --r1cs --wasm --prime bn128 --output ./folding-schemes/src/frontend/circom/test_folder/
 circom ./folding-schemes/src/frontend/circom/test_folder/cubic_circuit.circom --r1cs --wasm --prime bn128 --output ./folding-schemes/src/frontend/circom/test_folder/
--- a/folding-schemes/src/frontend/circom/test_folder/cubic_circuit.circom
+++ b/folding-schemes/src/frontend/circom/test_folder/cubic_circuit.circom
@ -0,0 +1,13 @@
 pragma circom 2.0.3;

 template Example () {
    signal input ivc_input[1];
    signal output ivc_output[1];   
    signal temp;
    
    temp <== ivc_input[0] * ivc_input[0];
    ivc_output[0] <== temp * ivc_input[0] + ivc_input[0] + 5;
 }

 component main {public [ivc_input]} = Example();

--- a/folding-schemes/src/frontend/circom/test_folder/test_circuit.circom
+++ b/folding-schemes/src/frontend/circom/test_folder/test_circuit.circom
@ -1,13 +0,0 @@
 pragma circom 2.0.3;

 template Example () {
    signal input step_in;
    signal output step_out;   
    signal temp;
    
    temp <== step_in * step_in;
    step_out <== temp * step_in + step_in + 5;
    step_out === 35; 
 }

 component main = Example();
--- a/folding-schemes/src/frontend/circom/utils.rs
+++ b/folding-schemes/src/frontend/circom/utils.rs
@ -0,0 +1,149 @@
 use ark_circom::{
    circom::{r1cs_reader, R1CS},
    WitnessCalculator,
 };
 use ark_ff::{BigInteger, PrimeField};
 use color_eyre::Result;
 use num_bigint::{BigInt, Sign};
 use std::{fs::File, io::BufReader, marker::PhantomData, path::PathBuf};

 use crate::Error;

 // A struct that wraps Circom functionalities, allowing for extraction of R1CS and witnesses
 // based on file paths to Circom's .r1cs and .wasm.
 #[derive(Clone, Debug)]
 pub struct CircomWrapper<F: PrimeField> {
    r1cs_filepath: PathBuf,
    wasm_filepath: PathBuf,
    _marker: PhantomData<F>,
 }

 impl<F: PrimeField> CircomWrapper<F> {
    // Creates a new instance of the CircomWrapper with the file paths.
    pub fn new(r1cs_filepath: PathBuf, wasm_filepath: PathBuf) -> Self {
        CircomWrapper {
            r1cs_filepath,
            wasm_filepath,
            _marker: PhantomData,
        }
    }

    // Aggregated function to obtain R1CS and witness from Circom.
    pub fn extract_r1cs_and_witness(
        &self,
        inputs: &[(String, Vec<BigInt>)],
    ) -> Result<(R1CS<F>, Option<Vec<F>>), Error> {
        // Extracts the R1CS
        let file = File::open(&self.r1cs_filepath)?;
        let reader = BufReader::new(file);
        let r1cs_file = r1cs_reader::R1CSFile::<F>::new(reader)?;
        let r1cs = r1cs_reader::R1CS::<F>::from(r1cs_file);

        // Extracts the witness vector
        let witness_vec = self.extract_witness(inputs)?;

        Ok((r1cs, Some(witness_vec)))
    }

    // Extracts the witness vector as a vector of PrimeField elements.
    pub fn extract_witness(&self, inputs: &[(String, Vec<BigInt>)]) -> Result<Vec<F>, Error> {
        let witness_bigint = self.calculate_witness(inputs)?;

        witness_bigint
            .iter()
            .map(|big_int| {
                self.num_bigint_to_ark_bigint(big_int)
                    .and_then(|ark_big_int| {
                        F::from_bigint(ark_big_int)
                            .ok_or_else(|| Error::Other("could not get F from bigint".to_string()))
                    })
            })
            .collect()
    }

    // Calculates the witness given the Wasm filepath and inputs.
    pub fn calculate_witness(
        &self,
        inputs: &[(String, Vec<BigInt>)],
    ) -> Result<Vec<BigInt>, Error> {
        let mut calculator = WitnessCalculator::new(&self.wasm_filepath).map_err(|e| {
            Error::WitnessCalculationError(format!("Failed to create WitnessCalculator: {}", e))
        })?;
        calculator
            .calculate_witness(inputs.iter().cloned(), true)
            .map_err(|e| {
                Error::WitnessCalculationError(format!("Failed to calculate witness: {}", e))
            })
    }

    // Converts a num_bigint::BigInt to a PrimeField::BigInt.
    pub fn num_bigint_to_ark_bigint(&self, value: &BigInt) -> Result<F::BigInt, Error> {
        let big_uint = value
            .to_biguint()
            .ok_or_else(|| Error::BigIntConversionError("BigInt is negative".to_string()))?;
        F::BigInt::try_from(big_uint).map_err(|_| {
            Error::BigIntConversionError("Failed to convert to PrimeField::BigInt".to_string())
        })
    }

    // Converts a PrimeField element to a num_bigint::BigInt representation.
    pub fn ark_primefield_to_num_bigint(&self, value: F) -> BigInt {
        let primefield_bigint: F::BigInt = value.into_bigint();
        let bytes = primefield_bigint.to_bytes_be();
        BigInt::from_bytes_be(Sign::Plus, &bytes)
    }
 }

 #[cfg(test)]
 mod tests {
    use super::*;
    use ark_bn254::Fr;
    use ark_circom::circom::{CircomBuilder, CircomConfig};
    use ark_circom::CircomCircuit;
    use ark_relations::r1cs::{ConstraintSynthesizer, ConstraintSystem};
    use std::path::PathBuf;

    //To generate .r1cs and .wasm files, run the below command in the terminal.
    //bash ./folding-schemes/src/frontend/circom/test_folder/compile.sh

    // Test the satisfication by using the CircomBuilder of circom-compat
    #[test]
    fn test_circombuilder_satisfied() {
        let cfg = CircomConfig::<Fr>::new(
            "./src/frontend/circom/test_folder/cubic_circuit_js/cubic_circuit.wasm",
            "./src/frontend/circom/test_folder/cubic_circuit.r1cs",
        )
        .unwrap();
        let mut builder = CircomBuilder::new(cfg);
        builder.push_input("ivc_input", 3);

        let circom = builder.build().unwrap();
        let cs = ConstraintSystem::<Fr>::new_ref();
        circom.generate_constraints(cs.clone()).unwrap();
        assert!(cs.is_satisfied().unwrap());
    }

    // Test the satisfication by using the CircomWrapper
    #[test]
    fn test_extract_r1cs_and_witness() {
        let r1cs_path = PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit.r1cs");
        let wasm_path =
            PathBuf::from("./src/frontend/circom/test_folder/cubic_circuit_js/cubic_circuit.wasm");

        let inputs = vec![("ivc_input".to_string(), vec![BigInt::from(3)])];
        let wrapper = CircomWrapper::<Fr>::new(r1cs_path, wasm_path);

        let (r1cs, witness) = wrapper.extract_r1cs_and_witness(&inputs).unwrap();

        let cs = ConstraintSystem::<Fr>::new_ref();

        let circom_circuit = CircomCircuit {
            r1cs,
            witness,
            inputs_already_computed: false,
        };

        circom_circuit.generate_constraints(cs.clone()).unwrap();
        assert!(cs.is_satisfied().unwrap());
    }
 }
--- a/folding-schemes/src/frontend/mod.rs
+++ b/folding-schemes/src/frontend/mod.rs
@ -1,11 +1,11 @@
 pub mod circom;

 use crate::Error;
 use ark_ff::PrimeField;
 use ark_r1cs_std::fields::fp::FpVar;
 use ark_relations::r1cs::{ConstraintSystemRef, SynthesisError};
 use ark_std::fmt::Debug;

 pub mod circom;

 /// FCircuit defines the trait of the circuit of the F function, which is the one being folded (ie.
 /// inside the agmented F' function).
 /// The parameter z_i denotes the current state, and z_{i+1} denotes the next state after applying
@ -44,7 +44,7 @@ pub trait FCircuit: Clone + Debug {
 #[cfg(test)]
 pub mod tests {
    use super::*;
    use ark_pallas::Fr;
    use ark_bn254::Fr;
    use ark_r1cs_std::{alloc::AllocVar, eq::EqGadget};
    use ark_relations::r1cs::{
        ConstraintSynthesizer, ConstraintSystem, ConstraintSystemRef, SynthesisError,
--- a/folding-schemes/src/lib.rs
+++ b/folding-schemes/src/lib.rs
@ -32,6 +32,8 @@ pub enum Error {
    ArithError(#[from] utils::espresso::virtual_polynomial::ArithErrors),
    #[error(transparent)]
    ProtoGalaxy(folding::protogalaxy::ProtoGalaxyError),
    #[error("std::io::Error")]
    IOError(#[from] std::io::Error),
    #[error("{0}")]
    Other(String),

@ -86,6 +88,10 @@ pub enum Error {
    NotSupported(String),
    #[error("max i-th step reached (usize limit reached)")]
    MaxStep,
    #[error("Circom Witness calculation error: {0}")]
    WitnessCalculationError(String),
    #[error("BigInt to PrimeField conversion error: {0}")]
    BigIntConversionError(String),
 }

 /// FoldingScheme defines trait that is implemented by the diverse folding schemes. It is defined