Adds Groth16

5 years ago · 98416f6b2e
5 changed files with 589 additions and 2 deletions
--- a/Cargo.toml
+++ b/Cargo.toml
@ -1,6 +1,6 @@
 [workspace]

 members = [ "algebra", "ff-fft", "r1cs-core", "r1cs-std", "gm17", "crypto-primitives", "dpc", "bench-utils" ]
 members = [ "algebra", "ff-fft", "r1cs-core", "r1cs-std", "groth16", "gm17", "crypto-primitives", "dpc", "bench-utils" ]

 [profile.release]
 opt-level = 3
--- a/crypto-primitives/Cargo.toml
+++ b/crypto-primitives/Cargo.toml
@ -13,7 +13,7 @@ description = "A library of cryptographic primitives that are used by Zexe"
 homepage = "https://libzexe.org"
 repository = "https://github.com/scipr/zexe"
 documentation = "https://docs.rs/crypto-primitives/"
 keywords = ["r1cs", "gm17", "pedersen", "blake2s"]
 keywords = ["r1cs", "groth16", "gm17", "pedersen", "blake2s"]
 categories = ["cryptography"]
 include = ["Cargo.toml", "src", "README.md", "LICENSE-APACHE", "LICENSE-MIT"]
 license = "MIT/Apache-2.0"
@ -26,6 +26,7 @@ algebra = { path = "../algebra" }
 r1cs-core = { path = "../r1cs-core", optional = true }
 r1cs-std = { path = "../r1cs-std", optional = true }
 gm17 = { path = "../gm17", optional = true }
 groth16 = { path = "../groth16", optional = true }
 bench-utils = { path = "../bench-utils" }

 digest = "0.7"
--- a/crypto-primitives/src/nizk/groth16/constraints.rs
+++ b/crypto-primitives/src/nizk/groth16/constraints.rs
@ -0,0 +1,500 @@
 use crate::nizk::{groth16::Groth16, NIZKVerifierGadget};
 use algebra::{Field, ToConstraintField, AffineCurve, PairingEngine};
 use r1cs_core::{ConstraintSynthesizer, ConstraintSystem, SynthesisError};
 use r1cs_std::prelude::*;

 use groth16::{Proof, VerifyingKey};
 use std::{borrow::Borrow, marker::PhantomData};

 #[derive(Derivative)]
 #[derivative(Clone(bound = "P::G1Gadget: Clone, P::G2Gadget: Clone"))]
 pub struct ProofGadget<
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 > {
    pub a: P::G1Gadget,
    pub b: P::G2Gadget,
    pub c: P::G1Gadget,
 }

 #[derive(Derivative)]
 #[derivative(Clone(
    bound = "P::G1Gadget: Clone, P::GTGadget: Clone, P::G1PreparedGadget: Clone, \
             P::G2PreparedGadget: Clone, "
 ))]
 pub struct VerifyingKeyGadget<
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 > {
    pub alpha_g1:       P::G1Gadget,
    pub beta_g2:       P::G2Gadget,
    pub gamma_g2: P::G2Gadget,
    pub delta_g2:  P::G2Gadget,
    pub gamma_abc_g1:  Vec<P::G1Gadget>,
 }

 impl<
        PairingE: PairingEngine,
        ConstraintF: Field,
        P: PairingGadget<PairingE, ConstraintF>,
    > VerifyingKeyGadget<PairingE, ConstraintF, P>
 {
    pub fn prepare<CS: ConstraintSystem<ConstraintF>>(
        &self,
        mut cs: CS,
    ) -> Result<PreparedVerifyingKeyGadget<PairingE, ConstraintF, P>, SynthesisError> {
        let mut cs = cs.ns(|| "Preparing verifying key");
        let alpha_g1_pc = P::prepare_g1(&mut cs.ns(|| "Prepare alpha_g1"), &self.alpha_g1)?;
        let beta_g2_pc = P::prepare_g2(&mut cs.ns(|| "Prepare beta_g2"), &self.beta_g2)?;

        let alpha_g1_beta_g2 = P::pairing(&mut cs.ns(|| "Precompute e(alpha_g1, beta_g2)"), alpha_g1_pc, beta_g2_pc)?;

        let gamma_g2_neg = self.gamma_g2.negate(&mut cs.ns(|| "Negate gamma_g2"))?;
        let gamma_g2_neg_pc = P::prepare_g2(&mut cs.ns(|| "Prepare gamma_g2_neg"), &gamma_g2_neg)?;

        let delta_g2_neg = self.delta_g2.negate(&mut cs.ns(|| "Negate delta_g2"))?;
        let delta_g2_neg_pc = P::prepare_g2(&mut cs.ns(|| "Prepare delta_g2_neg"), &delta_g2_neg)?;

        Ok(PreparedVerifyingKeyGadget {
            alpha_g1_beta_g2:  alpha_g1_beta_g2,
            gamma_g2_neg_pc:       gamma_g2_neg_pc,
            delta_g2_neg_pc:       delta_g2_neg_pc,
            gamma_abc_g1:      self.gamma_abc_g1.clone(),
        })
    }
 }

 #[derive(Derivative)]
 #[derivative(Clone(
    bound = "P::G1Gadget: Clone, P::GTGadget: Clone, P::G1PreparedGadget: Clone, \
             P::G2PreparedGadget: Clone, "
 ))]
 pub struct PreparedVerifyingKeyGadget<
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 > {
    pub alpha_g1_beta_g2:  P::GTGadget,
    pub gamma_g2_neg_pc:       P::G2PreparedGadget,
    pub delta_g2_neg_pc:       P::G2PreparedGadget,
    pub gamma_abc_g1:      Vec<P::G1Gadget>,
 }

 pub struct Groth16VerifierGadget<PairingE, ConstraintF, P>
 where
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 {
    _pairing_engine: PhantomData<PairingE>,
    _engine:         PhantomData<ConstraintF>,
    _pairing_gadget: PhantomData<P>,
 }

 impl<PairingE, ConstraintF, P, C, V> NIZKVerifierGadget<Groth16<PairingE, C, V>, ConstraintF>
    for Groth16VerifierGadget<PairingE, ConstraintF, P>
 where
    PairingE: PairingEngine,
    ConstraintF: Field,
    C: ConstraintSynthesizer<PairingE::Fr>,
    V: ToConstraintField<PairingE::Fr>,
    P: PairingGadget<PairingE, ConstraintF>,
 {
    type VerificationKeyGadget = VerifyingKeyGadget<PairingE, ConstraintF, P>;
    type ProofGadget = ProofGadget<PairingE, ConstraintF, P>;

    fn check_verify<'a, CS, I, T>(
        mut cs: CS,
        vk: &Self::VerificationKeyGadget,
        mut public_inputs: I,
        proof: &Self::ProofGadget,
    ) -> Result<(), SynthesisError>
    where
        CS: ConstraintSystem<ConstraintF>,
        I: Iterator<Item = &'a T>,
        T: 'a + ToBitsGadget<ConstraintF> + ?Sized,
    {
        let pvk = vk.prepare(&mut cs.ns(|| "Prepare vk"))?;

        let g_ic = {
            let mut cs = cs.ns(|| "Process input");
            let mut g_ic = pvk.gamma_abc_g1[0].clone();
            let mut input_len = 1;
            for (i, (input, b)) in public_inputs
                .by_ref()
                .zip(pvk.gamma_abc_g1.iter().skip(1))
                .enumerate()
            {
                let input_bits = input.to_bits(cs.ns(|| format!("Input {}", i)))?;
                g_ic = b.mul_bits(cs.ns(|| format!("Mul {}", i)), &g_ic, input_bits.iter())?;
                input_len += 1;
            }
            // Check that the input and the query in the verification are of the
            // same length.
            assert!(input_len == pvk.gamma_abc_g1.len() && public_inputs.next().is_none());
            g_ic
        };

        let test_exp = {
            let proof_a_prep = P::prepare_g1(cs.ns(|| "Prepare proof a"), &proof.a)?;
            let proof_b_prep = P::prepare_g2(cs.ns(|| "Prepare proof b"), &proof.b)?;
            let proof_c_prep = P::prepare_g1(cs.ns(|| "Prepare proof c"), &proof.c)?;

            let g_ic_prep = P::prepare_g1(cs.ns(|| "Prepare g_ic"), &g_ic)?;

            P::miller_loop(
                cs.ns(|| "Miller loop 1"),
                &[
                    proof_a_prep,
                    g_ic_prep,
                    proof_c_prep,
                ],
                &[
                    proof_b_prep,
                    pvk.gamma_g2_neg_pc.clone(),
                    pvk.delta_g2_neg_pc.clone(),
                ],
            )?
        };

        let test = P::final_exponentiation(cs.ns(|| "Final Exp"), &test_exp).unwrap();

        test.enforce_equal(cs.ns(|| "Test 1"), &pvk.alpha_g1_beta_g2)?;
        Ok(())
    }
 }

 impl<PairingE, ConstraintF, P> AllocGadget<VerifyingKey<PairingE>, ConstraintF>
    for VerifyingKeyGadget<PairingE, ConstraintF, P>
 where
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 {
    #[inline]
    fn alloc<FN, T, CS: ConstraintSystem<ConstraintF>>(
        mut cs: CS,
        value_gen: FN,
    ) -> Result<Self, SynthesisError>
    where
        FN: FnOnce() -> Result<T, SynthesisError>,
        T: Borrow<VerifyingKey<PairingE>>,
    {
        value_gen().and_then(|vk| {
            let VerifyingKey {
                alpha_g1,
                beta_g2,
                gamma_g2,
                delta_g2,
                gamma_abc_g1,
            } = vk.borrow().clone();
            let alpha_g1 = P::G1Gadget::alloc(cs.ns(|| "alpha_g1"), || Ok(alpha_g1.into_projective()))?;
            let beta_g2 =
                P::G2Gadget::alloc(cs.ns(|| "beta_g2"), || Ok(beta_g2.into_projective()))?;
            let gamma_g2 =
                P::G2Gadget::alloc(cs.ns(|| "gamma_g2"), || Ok(gamma_g2.into_projective()))?;
            let delta_g2 =
                P::G2Gadget::alloc(cs.ns(|| "delta_g2"), || Ok(delta_g2.into_projective()))?;

            let gamma_abc_g1 = gamma_abc_g1
                .into_iter()
                .enumerate()
                .map(|(i, gamma_abc_i)| {
                    P::G1Gadget::alloc(cs.ns(|| format!("gamma_abc_{}", i)), || {
                        Ok(gamma_abc_i.into_projective())
                    })
                })
                .collect::<Vec<_>>()
                .into_iter()
                .collect::<Result<_, _>>()?;
            Ok(Self {
                alpha_g1,
                beta_g2,
                gamma_g2,
                delta_g2,
                gamma_abc_g1,
            })
        })
    }

    #[inline]
    fn alloc_input<FN, T, CS: ConstraintSystem<ConstraintF>>(
        mut cs: CS,
        value_gen: FN,
    ) -> Result<Self, SynthesisError>
    where
        FN: FnOnce() -> Result<T, SynthesisError>,
        T: Borrow<VerifyingKey<PairingE>>,
    {
        value_gen().and_then(|vk| {
            let VerifyingKey {
                alpha_g1,
                beta_g2,
                gamma_g2,
                delta_g2,
                gamma_abc_g1,
            } = vk.borrow().clone();
            let alpha_g1 = P::G1Gadget::alloc_input(cs.ns(|| "alpha_g1"), || Ok(alpha_g1.into_projective()))?;
            let beta_g2 =
                P::G2Gadget::alloc_input(cs.ns(|| "beta_g2"), || Ok(beta_g2.into_projective()))?;
            let gamma_g2 =
                P::G2Gadget::alloc_input(cs.ns(|| "gamma_g2"), || Ok(gamma_g2.into_projective()))?;
            let delta_g2 =
                P::G2Gadget::alloc_input(cs.ns(|| "delta_g2"), || Ok(delta_g2.into_projective()))?;

            let gamma_abc_g1 = gamma_abc_g1
                .into_iter()
                .enumerate()
                .map(|(i, gamma_abc_i)| {
                    P::G1Gadget::alloc_input(cs.ns(|| format!("gamma_abc_{}", i)), || {
                        Ok(gamma_abc_i.into_projective())
                    })
                })
                .collect::<Vec<_>>()
                .into_iter()
                .collect::<Result<_, _>>()?;

            Ok(Self {
                alpha_g1,
                beta_g2,
                gamma_g2,
                delta_g2,
                gamma_abc_g1,
            })
        })
    }
 }

 impl<PairingE, ConstraintF, P> AllocGadget<Proof<PairingE>, ConstraintF>
    for ProofGadget<PairingE, ConstraintF, P>
 where
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 {
    #[inline]
    fn alloc<FN, T, CS: ConstraintSystem<ConstraintF>>(
        mut cs: CS,
        value_gen: FN,
    ) -> Result<Self, SynthesisError>
    where
        FN: FnOnce() -> Result<T, SynthesisError>,
        T: Borrow<Proof<PairingE>>,
    {
        value_gen().and_then(|proof| {
            let Proof { a, b, c } = proof.borrow().clone();
            let a = P::G1Gadget::alloc_checked(cs.ns(|| "a"), || Ok(a.into_projective()))?;
            let b = P::G2Gadget::alloc_checked(cs.ns(|| "b"), || Ok(b.into_projective()))?;
            let c = P::G1Gadget::alloc_checked(cs.ns(|| "c"), || Ok(c.into_projective()))?;
            Ok(Self { a, b, c })
        })
    }

    #[inline]
    fn alloc_input<FN, T, CS: ConstraintSystem<ConstraintF>>(
        mut cs: CS,
        value_gen: FN,
    ) -> Result<Self, SynthesisError>
    where
        FN: FnOnce() -> Result<T, SynthesisError>,
        T: Borrow<Proof<PairingE>>,
    {
        value_gen().and_then(|proof| {
            let Proof { a, b, c } = proof.borrow().clone();
            // We don't need to check here because the prime order check can be performed
            // in plain.
            let a = P::G1Gadget::alloc_input(cs.ns(|| "a"), || Ok(a.into_projective()))?;
            let b = P::G2Gadget::alloc_input(cs.ns(|| "b"), || Ok(b.into_projective()))?;
            let c = P::G1Gadget::alloc_input(cs.ns(|| "c"), || Ok(c.into_projective()))?;
            Ok(Self { a, b, c })
        })
    }
 }

 impl<PairingE, ConstraintF, P> ToBytesGadget<ConstraintF>
    for VerifyingKeyGadget<PairingE, ConstraintF, P>
 where
    PairingE: PairingEngine,
    ConstraintF: Field,
    P: PairingGadget<PairingE, ConstraintF>,
 {
    #[inline]
    fn to_bytes<CS: ConstraintSystem<ConstraintF>>(
        &self,
        mut cs: CS,
    ) -> Result<Vec<UInt8>, SynthesisError> {
        let mut bytes = Vec::new();
        bytes.extend_from_slice(&self.alpha_g1.to_bytes(&mut cs.ns(|| "alpha_g1 to bytes"))?);
        bytes.extend_from_slice(
            &self
                .beta_g2
                .to_bytes(&mut cs.ns(|| "beta_g2 to bytes"))?,
        );
        bytes.extend_from_slice(
            &self
                .gamma_g2
                .to_bytes(&mut cs.ns(|| "gamma_g2 to bytes"))?,
        );
        bytes.extend_from_slice(
            &self
                .delta_g2
                .to_bytes(&mut cs.ns(|| "delta_g2 to bytes"))?,
        );
        for (i, g) in self.gamma_abc_g1.iter().enumerate() {
            let mut cs = cs.ns(|| format!("Iteration {}", i));
            bytes.extend_from_slice(&g.to_bytes(&mut cs.ns(|| "g"))?);
        }
        Ok(bytes)
    }

    fn to_bytes_strict<CS: ConstraintSystem<ConstraintF>>(
        &self,
        cs: CS,
    ) -> Result<Vec<UInt8>, SynthesisError> {
        self.to_bytes(cs)
    }
 }

 #[cfg(test)]
 mod test {
    use groth16::*;
    use r1cs_core::{ConstraintSynthesizer, ConstraintSystem, SynthesisError};

    use super::*;
    use algebra::{
        curves::bls12_377::Bls12_377,
        fields::bls12_377::Fr,
        fields::bls12_377::Fq,
        BitIterator, PrimeField,
    };
    use rand::{thread_rng, Rng};
    use r1cs_std::{
        boolean::Boolean, pairing::bls12_377::PairingGadget as Bls12_377PairingGadget,
        test_constraint_system::TestConstraintSystem,
    };

    type TestProofSystem = Groth16<Bls12_377, Bench<Fr>, Fr>;
    type TestVerifierGadget = Groth16VerifierGadget<Bls12_377, Fq, Bls12_377PairingGadget>;
    type TestProofGadget = ProofGadget<Bls12_377, Fq, Bls12_377PairingGadget>;
    type TestVkGadget = VerifyingKeyGadget<Bls12_377, Fq, Bls12_377PairingGadget>;

    struct Bench<F: Field> {
        inputs:          Vec<Option<F>>,
        num_constraints: usize,
    }

    impl<F: Field> ConstraintSynthesizer<F> for Bench<F> {
        fn generate_constraints<CS: ConstraintSystem<F>>(self, cs: &mut CS) -> Result<(), SynthesisError> {
            assert!(self.inputs.len() >= 2);
            assert!(self.num_constraints >= self.inputs.len());

            let mut variables: Vec<_> = Vec::with_capacity(self.inputs.len());
            for (i, input) in self.inputs.into_iter().enumerate() {
                let input_var = cs.alloc_input(
                    || format!("Input {}", i),
                    || input.ok_or(SynthesisError::AssignmentMissing),
                )?;
                variables.push((input, input_var));
            }

            for i in 0..self.num_constraints {
                let new_entry = {
                    let (input_1_val, input_1_var) = variables[i];
                    let (input_2_val, input_2_var) = variables[i + 1];
                    let result_val = input_1_val
                        .and_then(|input_1| input_2_val.map(|input_2| input_1 * &input_2));
                    let result_var = cs.alloc(
                        || format!("Result {}", i),
                        || result_val.ok_or(SynthesisError::AssignmentMissing),
                    )?;
                    cs.enforce(
                        || format!("Enforce constraint {}", i),
                        |lc| lc + input_1_var,
                        |lc| lc + input_2_var,
                        |lc| lc + result_var,
                    );
                    (result_val, result_var)
                };
                variables.push(new_entry);
            }
            Ok(())
        }
    }

    #[test]
    fn groth16_verifier_test() {
        let num_inputs = 100;
        let num_constraints = num_inputs;
        let rng = &mut thread_rng();
        let mut inputs: Vec<Option<Fr>> = Vec::with_capacity(num_inputs);
        for _ in 0..num_inputs {
            inputs.push(Some(rng.gen()));
        }
        let params = {
            let c = Bench::<Fr> {
                inputs: vec![None; num_inputs],
                num_constraints,
            };

            generate_random_parameters(c, rng).unwrap()
        };

        {
            let proof = {
                // Create an instance of our circuit (with the
                // witness)
                let c = Bench {
                    inputs: inputs.clone(),
                    num_constraints,
                };
                // Create a groth16 proof with our parameters.
                create_random_proof(c, &params, rng).unwrap()
            };

            // assert!(!verify_proof(&pvk, &proof, &[a]).unwrap());
            let mut cs = TestConstraintSystem::<Fq>::new();

            let inputs: Vec<_> = inputs.into_iter().map(|input| input.unwrap()).collect();
            let mut input_gadgets = Vec::new();

            {
                let mut cs = cs.ns(|| "Allocate Input");
                for (i, input) in inputs.into_iter().enumerate() {
                    let mut input_bits = BitIterator::new(input.into_repr()).collect::<Vec<_>>();
                    // Input must be in little-endian, but BitIterator outputs in big-endian.
                    input_bits.reverse();

                    let input_bits =
                        Vec::<Boolean>::alloc_input(cs.ns(|| format!("Input {}", i)), || {
                            Ok(input_bits)
                        })
                        .unwrap();
                    input_gadgets.push(input_bits);
                }
            }

            let vk_gadget = TestVkGadget::alloc_input(cs.ns(|| "Vk"), || Ok(&params.vk)).unwrap();
            let proof_gadget =
                TestProofGadget::alloc(cs.ns(|| "Proof"), || Ok(proof.clone())).unwrap();
            println!("Time to verify!\n\n\n\n");
            <TestVerifierGadget as NIZKVerifierGadget<TestProofSystem, Fq>>::check_verify(
                cs.ns(|| "Verify"),
                &vk_gadget,
                input_gadgets.iter(),
                &proof_gadget,
            )
            .unwrap();
            if !cs.is_satisfied() {
                println!("=========================================================");
                println!("Unsatisfied constraints:");
                println!("{:?}", cs.which_is_unsatisfied().unwrap());
                println!("=========================================================");
            }

            // cs.print_named_objects();
            assert!(cs.is_satisfied());
        }
    }
 }
--- a/crypto-primitives/src/nizk/groth16/mod.rs
+++ b/crypto-primitives/src/nizk/groth16/mod.rs
@ -0,0 +1,81 @@
 use algebra::PairingEngine;
 use crate::Error;
 use rand::Rng;
 use groth16::{
    create_random_proof, generate_random_parameters, prepare_verifying_key, verify_proof,
    Parameters, PreparedVerifyingKey, Proof, VerifyingKey,
 };
 use r1cs_core::ConstraintSynthesizer;

 use algebra::ToConstraintField;
 use std::marker::PhantomData;

 use super::NIZK;

 #[cfg(feature = "r1cs")]
 pub mod constraints;

 /// Note: V should serialize its contents to `Vec<E::Fr>` in the same order as
 /// during the constraint generation.
 pub struct Groth16<E: PairingEngine, C: ConstraintSynthesizer<E::Fr>, V: ToConstraintField<E::Fr> + ?Sized> {
    #[doc(hidden)]
    _engine:         PhantomData<E>,
    #[doc(hidden)]
    _circuit:        PhantomData<C>,
    #[doc(hidden)]
    _verifier_input: PhantomData<V>,
 }

 impl<E: PairingEngine, C: ConstraintSynthesizer<E::Fr>, V: ToConstraintField<E::Fr> + ?Sized> NIZK for Groth16<E, C, V> {
    type Circuit = C;
    type AssignedCircuit = C;
    type ProvingParameters = Parameters<E>;
    type VerificationParameters = VerifyingKey<E>;
    type PreparedVerificationParameters = PreparedVerifyingKey<E>;
    type VerifierInput = V;
    type Proof = Proof<E>;

    fn setup<R: Rng>(
        circuit: Self::Circuit,
        rng: &mut R,
    ) -> Result<
        (
            Self::ProvingParameters,
            Self::PreparedVerificationParameters,
        ),
        Error,
    > {
        let nizk_time = start_timer!(|| "{Groth-Maller 2017}::Setup");
        let pp = generate_random_parameters::<E, Self::Circuit, R>(circuit, rng)?;
        let vk = prepare_verifying_key(&pp.vk);
        end_timer!(nizk_time);
        Ok((pp, vk))
    }

    fn prove<R: Rng>(
        pp: &Self::ProvingParameters,
        input_and_witness: Self::AssignedCircuit,
        rng: &mut R,
    ) -> Result<Self::Proof, Error> {
        let proof_time = start_timer!(|| "{Groth-Maller 2017}::Prove");
        let result = create_random_proof::<E, _, _>(input_and_witness, pp, rng)?;
        end_timer!(proof_time);
        Ok(result)
    }

    fn verify(
        vk: &Self::PreparedVerificationParameters,
        input: &Self::VerifierInput,
        proof: &Self::Proof,
    ) -> Result<bool, Error> {
        let verify_time = start_timer!(|| "{Groth-Maller 2017}::Verify");
        let conversion_time = start_timer!(|| "Convert input to E::Fr");
        let input = input.to_field_elements()?;
        end_timer!(conversion_time);
        let verification = start_timer!(|| format!("Verify proof w/ input len: {}", input.len()));
        let result = verify_proof(&vk, proof, &input)?;
        end_timer!(verification);
        end_timer!(verify_time);
        Ok(result)
    }
 }
--- a/crypto-primitives/src/nizk/mod.rs
+++ b/crypto-primitives/src/nizk/mod.rs
@ -6,6 +6,11 @@ pub mod gm17;
 #[cfg(feature = "gm17")]
 pub use self::gm17::Gm17;

 #[cfg(feature = "groth16")]
 pub mod groth16;
 #[cfg(feature = "groth16")]
 pub use self::groth16::Groth16;

 #[cfg(feature = "r1cs")]
 pub mod constraints;
 #[cfg(feature = "r1cs")]