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implement Nova's AugmentedFCircuit (#33)

* impl AugmentedFCircuit non-base case

* add multiple iterations to AugmentedFCircuit test

* implement base case on AugmentedFCircuit and test

* Update cmE of E=0-vec to work as zero point

Update cmE of E=0-vec to work as zero point instead of as cm(0-vec)

* patch r1cs-std dep to a cherry-picked version with the zero-scalar-mult fix

* refactor FCircuit to make it more suitable inside the AugmentedFCircuit
main
arnaucube 1 year ago
committed by GitHub
parent
commit
597ac27288
No known key found for this signature in database GPG Key ID: 4AEE18F83AFDEB23
7 changed files with 552 additions and 76 deletions
  1. +11
    -1
      Cargo.toml
  2. +5
    -5
      src/folding/circuits/cyclefold.rs
  3. +46
    -0
      src/folding/circuits/nonnative.rs
  4. +372
    -30
      src/folding/nova/circuits.rs
  5. +24
    -6
      src/folding/nova/mod.rs
  6. +69
    -22
      src/folding/nova/nifs.rs
  7. +25
    -12
      src/frontend/arkworks/mod.rs

+ 11
- 1
Cargo.toml

@ -10,7 +10,7 @@ ark-poly = "^0.4.0"
ark-std = "^0.4.0"
ark-crypto-primitives = { version = "^0.4.0", default-features = false, features = ["r1cs", "sponge", "crh"] }
ark-relations = { version = "^0.4.0", default-features = false }
ark-r1cs-std = { version = "^0.4.0", default-features = false }
ark-r1cs-std = { default-features = false } # use latest version from the patch
ark-circom = { git = "https://github.com/gakonst/ark-circom.git" }
thiserror = "1.0"
rayon = "1.7.0"
@ -26,6 +26,8 @@ espresso_transcript = {git="https://github.com/EspressoSystems/hyperplonk", pack
ark-pallas = {version="0.4.0", features=["r1cs"]}
ark-vesta = {version="0.4.0"}
ark-bn254 = "0.4.0"
tracing = { version = "0.1", default-features = false, features = [ "attributes" ] }
tracing-subscriber = { version = "0.2" }
[features]
default = ["parallel", "nova", "hypernova"]
@ -37,3 +39,11 @@ parallel = [
"ark-ff/parallel",
"ark-poly/parallel",
]
# The following patch is to use a version of ark-r1cs-std compatible with
# v0.4.0 but that includes a cherry-picked commit from after v0.4.0 which fixes
# the in-circuit scalar multiplication of the zero point. The commit is from
# https://github.com/arkworks-rs/r1cs-std/pull/124, without including other
# changes done between v0.4.0 and this fix which would break compatibility.
[patch.crates-io]
ark-r1cs-std = { git = "https://github.com/arnaucube/ark-r1cs-std-cherry-picked/" }

+ 5
- 5
src/folding/circuits/cyclefold.rs

@ -21,9 +21,8 @@ impl>> ECRLC {
p1: GC,
p2: GC,
p3: GC,
) -> Result<(), SynthesisError> {
p3.enforce_equal(&(p1 + p2.scalar_mul_le(r_bits.iter())?))?;
Ok(())
) -> Result<Boolean<CF<C>>, SynthesisError> {
p3.is_eq(&(p1 + p2.scalar_mul_le(r_bits.iter())?))
}
}
@ -32,7 +31,7 @@ mod tests {
use super::*;
use ark_ff::{BigInteger, PrimeField};
use ark_pallas::{constraints::GVar, Fq, Fr, Projective};
use ark_r1cs_std::alloc::AllocVar;
use ark_r1cs_std::{alloc::AllocVar, eq::EqGadget};
use ark_relations::r1cs::ConstraintSystem;
use ark_std::UniformRand;
use std::ops::Mul;
@ -59,7 +58,8 @@ mod tests {
let p3Var = GVar::new_witness(cs.clone(), || Ok(p3)).unwrap();
// check ECRLC circuit
ECRLC::<Projective, GVar>::check(rbitsVar, p1Var, p2Var, p3Var).unwrap();
let check_pass = ECRLC::<Projective, GVar>::check(rbitsVar, p1Var, p2Var, p3Var).unwrap();
check_pass.enforce_equal(&Boolean::<Fq>::TRUE).unwrap();
assert!(cs.is_satisfied().unwrap());
}
}

+ 46
- 0
src/folding/circuits/nonnative.rs

@ -6,6 +6,7 @@ use ark_r1cs_std::{
fields::nonnative::NonNativeFieldVar,
};
use ark_relations::r1cs::{Namespace, SynthesisError};
use ark_std::{One, Zero};
use core::borrow::Borrow;
/// NonNativeAffineVar represents an elliptic curve point in Affine represenation in the non-native
@ -31,6 +32,19 @@ where
let cs = cs.into();
let affine = val.borrow().into_affine();
if affine.is_zero() {
let x = NonNativeFieldVar::<C::BaseField, C::ScalarField>::new_variable(
cs.clone(),
|| Ok(C::BaseField::zero()),
mode,
)?;
let y = NonNativeFieldVar::<C::BaseField, C::ScalarField>::new_variable(
cs.clone(),
|| Ok(C::BaseField::one()),
mode,
)?;
return Ok(Self { x, y });
}
let xy = affine.xy().unwrap();
let x = NonNativeFieldVar::<C::BaseField, C::ScalarField>::new_variable(
cs.clone(),
@ -58,6 +72,20 @@ where
<C as ark_ec::CurveGroup>::BaseField: ark_ff::PrimeField,
{
let affine = p.into_affine();
if affine.is_zero() {
let x =
AllocatedNonNativeFieldVar::<C::BaseField, C::ScalarField>::get_limbs_representations(
&C::BaseField::zero(),
OptimizationType::Weight,
)?;
let y =
AllocatedNonNativeFieldVar::<C::BaseField, C::ScalarField>::get_limbs_representations(
&C::BaseField::one(),
OptimizationType::Weight,
)?;
return Ok((x, y));
}
let (x, y) = affine.xy().unwrap();
let x = AllocatedNonNativeFieldVar::<C::BaseField, C::ScalarField>::get_limbs_representations(
x,
@ -69,3 +97,21 @@ where
)?;
Ok((x, y))
}
#[cfg(test)]
mod tests {
use super::*;
use ark_pallas::{Fq, Fr, Projective};
use ark_r1cs_std::alloc::AllocVar;
use ark_relations::r1cs::ConstraintSystem;
use ark_std::Zero;
#[test]
fn test_alloc_nonnativeaffinevar_zero() {
let cs = ConstraintSystem::<Fr>::new_ref();
// dealing with the 'zero' point should not panic when doing the unwrap
let p = Projective::zero();
NonNativeAffineVar::<Fq, Fr>::new_witness(cs.clone(), || Ok(p)).unwrap();
}
}

+ 372
- 30
src/folding/nova/circuits.rs

@ -2,19 +2,20 @@ use ark_crypto_primitives::crh::{
poseidon::constraints::{CRHGadget, CRHParametersVar},
CRHSchemeGadget,
};
use ark_crypto_primitives::sponge::Absorb;
use ark_crypto_primitives::sponge::{poseidon::PoseidonConfig, Absorb};
use ark_ec::{AffineRepr, CurveGroup, Group};
use ark_ff::Field;
use ark_ff::{Field, PrimeField};
use ark_r1cs_std::{
alloc::{AllocVar, AllocationMode},
boolean::Boolean,
eq::EqGadget,
fields::fp::FpVar,
fields::{fp::FpVar, FieldVar},
groups::GroupOpsBounds,
prelude::CurveVar,
ToConstraintFieldGadget,
};
use ark_relations::r1cs::{Namespace, SynthesisError};
use ark_relations::r1cs::{ConstraintSynthesizer, ConstraintSystemRef, Namespace, SynthesisError};
use ark_std::Zero;
use core::{borrow::Borrow, marker::PhantomData};
use super::CommittedInstance;
@ -32,10 +33,8 @@ pub type CF2 = <::BaseField as Field>::BasePrimeField;
/// constraints field (E1::Fr, where E1 is the main curve).
#[derive(Debug, Clone)]
pub struct CommittedInstanceVar<C: CurveGroup> {
_c: PhantomData<C>,
u: FpVar<C::ScalarField>,
x: Vec<FpVar<C::ScalarField>>,
#[allow(dead_code)] // tmp while we don't have the code of the AugmentedFGadget
cmE: NonNativeAffineVar<CF2<C>, C::ScalarField>,
cmW: NonNativeAffineVar<CF2<C>, C::ScalarField>,
}
@ -43,7 +42,7 @@ pub struct CommittedInstanceVar {
impl<C> AllocVar<CommittedInstance<C>, CF1<C>> for CommittedInstanceVar<C>
where
C: CurveGroup,
<C as ark_ec::CurveGroup>::BaseField: ark_ff::PrimeField,
<C as ark_ec::CurveGroup>::BaseField: PrimeField,
{
fn new_variable<T: Borrow<CommittedInstance<C>>>(
cs: impl Into<Namespace<CF1<C>>>,
@ -68,13 +67,7 @@ where
mode,
)?;
Ok(Self {
_c: PhantomData,
u,
x,
cmE,
cmW,
})
Ok(Self { u, x, cmE, cmW })
})
}
}
@ -88,7 +81,6 @@ where
/// CommittedInstance.hash.
/// Returns `H(i, z_0, z_i, U_i)`, where `i` can be `i` but also `i+1`, and `U` is the
/// `CommittedInstance`.
#[allow(dead_code)] // tmp while we don't have the code of the AugmentedFGadget
fn hash(
self,
crh_params: &CRHParametersVar<CF1<C>>,
@ -164,9 +156,9 @@ where
ci1: CommittedInstanceVar<C>,
ci2: CommittedInstanceVar<C>,
ci3: CommittedInstanceVar<C>,
) -> Result<(), SynthesisError> {
) -> Result<Boolean<CF1<C>>, SynthesisError> {
// ensure that: ci3.u == ci1.u + r * ci2.u
ci3.u.enforce_equal(&(ci1.u + r.clone() * ci2.u))?;
let first_check = ci3.u.is_eq(&(ci1.u + r.clone() * ci2.u))?;
// ensure that: ci3.x == ci1.x + r * ci2.x
let x_rlc = ci1
@ -175,9 +167,9 @@ where
.zip(ci2.x)
.map(|(a, b)| a + &r * &b)
.collect::<Vec<FpVar<CF1<C>>>>();
x_rlc.enforce_equal(&ci3.x)?;
let second_check = x_rlc.is_eq(&ci3.x)?;
Ok(())
first_check.and(&second_check)
}
}
@ -199,14 +191,145 @@ where
ci1: CommittedInstanceCycleFoldVar<C, GC>,
ci2: CommittedInstanceCycleFoldVar<C, GC>,
ci3: CommittedInstanceCycleFoldVar<C, GC>,
) -> Result<(), SynthesisError> {
) -> Result<Boolean<CF2<C>>, SynthesisError> {
// cm(E) check: ci3.cmE == ci1.cmE + r * cmT + r^2 * ci2.cmE
ci3.cmE.enforce_equal(
let first_check = ci3.cmE.is_eq(
&((ci2.cmE.scalar_mul_le(r_bits.iter())? + cmT).scalar_mul_le(r_bits.iter())?
+ ci1.cmE),
)?;
// cm(W) check: ci3.cmW == ci1.cmW + r * ci2.cmW
ECRLC::<C, GC>::check(r_bits, ci1.cmW, ci2.cmW, ci3.cmW)?;
let second_check = ECRLC::<C, GC>::check(r_bits, ci1.cmW, ci2.cmW, ci3.cmW)?;
first_check.and(&second_check)
}
}
/// FCircuit defines the trait of the circuit of the F function, which is the one being executed
/// inside the agmented F' function.
pub trait FCircuit<F: PrimeField>: Copy {
/// method that returns z_i (input), z_{i+1} (output)
fn public(self) -> (F, F);
/// method that computes the next state values in place, assigning z_{i+1} into z_i, and
/// computing the new z_i
fn step_native(&mut self);
fn step_circuit(
self,
cs: ConstraintSystemRef<F>,
z_i: FpVar<F>,
) -> Result<FpVar<F>, SynthesisError>;
}
/// AugmentedFCircuit implements the F' circuit (augmented F) defined in
/// [Nova](https://eprint.iacr.org/2021/370.pdf).
#[derive(Debug, Clone)]
pub struct AugmentedFCircuit<C: CurveGroup, FC: FCircuit<CF1<C>>> {
pub poseidon_config: PoseidonConfig<CF1<C>>,
pub i: Option<CF1<C>>,
pub z_0: Option<C::ScalarField>,
pub z_i: Option<C::ScalarField>,
pub u_i: Option<CommittedInstance<C>>,
pub U_i: Option<CommittedInstance<C>>,
pub U_i1: Option<CommittedInstance<C>>,
pub cmT: Option<C>,
pub r: Option<C::ScalarField>, // This will not be an input and derived from a hash internally in the circuit (poseidon transcript)
pub F: FC, // F circuit
pub x: Option<CF1<C>>, // public inputs (u_{i+1}.x)
}
impl<C: CurveGroup, FC: FCircuit<CF1<C>>> ConstraintSynthesizer<CF1<C>> for AugmentedFCircuit<C, FC>
where
C: CurveGroup,
<C as CurveGroup>::BaseField: PrimeField,
<C as Group>::ScalarField: Absorb,
{
fn generate_constraints(self, cs: ConstraintSystemRef<CF1<C>>) -> Result<(), SynthesisError> {
let i =
FpVar::<CF1<C>>::new_witness(cs.clone(), || Ok(self.i.unwrap_or_else(CF1::<C>::zero)))?;
let z_0 = FpVar::<CF1<C>>::new_witness(cs.clone(), || {
Ok(self.z_0.unwrap_or_else(CF1::<C>::zero))
})?;
let z_i = FpVar::<CF1<C>>::new_witness(cs.clone(), || {
Ok(self.z_i.unwrap_or_else(CF1::<C>::zero))
})?;
// get z_{i+1} from the F circuit
let z_i1 = self.F.step_circuit(cs.clone(), z_i.clone())?;
let u_dummy_native = CommittedInstance {
cmE: C::zero(),
u: C::ScalarField::zero(),
cmW: C::zero(),
x: vec![CF1::<C>::zero()],
};
let u_dummy =
CommittedInstanceVar::<C>::new_witness(cs.clone(), || Ok(u_dummy_native.clone()))?;
let u_i = CommittedInstanceVar::<C>::new_witness(cs.clone(), || {
Ok(self.u_i.unwrap_or_else(|| u_dummy_native.clone()))
})?;
let U_i = CommittedInstanceVar::<C>::new_witness(cs.clone(), || {
Ok(self.U_i.unwrap_or_else(|| u_dummy_native.clone()))
})?;
let U_i1 = CommittedInstanceVar::<C>::new_witness(cs.clone(), || {
Ok(self.U_i1.unwrap_or_else(|| u_dummy_native.clone()))
})?;
let _cmT =
NonNativeAffineVar::new_witness(cs.clone(), || Ok(self.cmT.unwrap_or_else(C::zero)))?;
let r =
FpVar::<CF1<C>>::new_witness(cs.clone(), || Ok(self.r.unwrap_or_else(CF1::<C>::zero)))?; // r will come from higher level transcript
let x =
FpVar::<CF1<C>>::new_input(cs.clone(), || Ok(self.x.unwrap_or_else(CF1::<C>::zero)))?;
let crh_params =
CRHParametersVar::<C::ScalarField>::new_constant(cs.clone(), self.poseidon_config)?;
let zero = FpVar::<CF1<C>>::new_constant(cs.clone(), CF1::<C>::zero())?;
let is_basecase = i.is_eq(&zero)?;
let is_not_basecase = i.is_neq(&zero)?;
// 1. h_{i+1} = u_i.X == H(i, z_0, z_i, U_i)
let u_i_x = U_i
.clone()
.hash(&crh_params, i.clone(), z_0.clone(), z_i.clone())?;
// check that h == u_i.x
(u_i.x[0]).conditional_enforce_equal(&u_i_x, &is_not_basecase)?;
// 2. u_i.cmE==cm(0), u_i.u==1
(u_i.cmE.x.is_eq(&u_dummy.cmE.x)?)
.conditional_enforce_equal(&Boolean::TRUE, &is_not_basecase)?;
(u_i.cmE.y.is_eq(&u_dummy.cmE.y)?)
.conditional_enforce_equal(&Boolean::TRUE, &is_not_basecase)?;
(u_i.u.is_one()?).conditional_enforce_equal(&Boolean::TRUE, &is_not_basecase)?;
// 3. nifs.verify, checks that folding u_i & U_i obtains U_{i+1}.
// Notice that NIFSGadget::verify is not checking the folding of cmE & cmW, since it will
// be done on the other curve.
let nifs_check = NIFSGadget::<C>::verify(r, u_i, U_i.clone(), U_i1.clone())?;
nifs_check.conditional_enforce_equal(&Boolean::TRUE, &is_not_basecase)?;
// 4. (base case) u_{i+1}.X == H(1, z_0, F(z_0)=F(z_i)=z_i1, U_i) (with U_i being dummy)
let u_i1_x_basecase = U_i.hash(
&crh_params,
FpVar::<CF1<C>>::one(),
z_0.clone(),
z_i1.clone(),
)?;
// 4. (non-base case). u_{i+1}.x = H(i+1, z_0, z_i+1, U_{i+1}), this is the output of F'
let u_i1_x = U_i1.hash(
&crh_params,
i + FpVar::<CF1<C>>::one(),
z_0.clone(),
z_i1.clone(),
)?;
// if i==0: check x==u_{i+1}.x_basecase
u_i1_x_basecase.conditional_enforce_equal(&x, &is_basecase)?;
// else: check x==u_{i+1}.x
u_i1_x.conditional_enforce_equal(&x, &is_not_basecase)?;
Ok(())
}
}
@ -214,18 +337,50 @@ where
#[cfg(test)]
mod tests {
use super::*;
use ark_ff::{BigInteger, PrimeField};
use ark_ff::BigInteger;
use ark_pallas::{constraints::GVar, Fq, Fr, Projective};
use ark_r1cs_std::{alloc::AllocVar, R1CSVar};
use ark_relations::r1cs::ConstraintSystem;
use ark_relations::r1cs::{ConstraintLayer, ConstraintSystem, TracingMode};
use ark_std::One;
use ark_std::UniformRand;
use tracing_subscriber::layer::SubscriberExt;
use crate::ccs::r1cs::tests::{get_test_r1cs, get_test_z};
use crate::folding::nova::{nifs::NIFS, Witness};
use crate::constants::N_BITS_CHALLENGE;
use crate::folding::nova::{check_instance_relation, nifs::NIFS, Witness};
use crate::frontend::arkworks::{extract_r1cs, extract_z};
use crate::pedersen::Pedersen;
use crate::transcript::poseidon::{tests::poseidon_test_config, PoseidonTranscript};
use crate::transcript::Transcript;
#[derive(Clone, Copy, Debug)]
/// TestFCircuit is a variation of `x^3 + x + 5 = y` (as in
/// src/frontend/arkworks/mod.rs#tests::TestCircuit), adapted to have 2 public inputs which are
/// used as the state. `z_i` is used as `x`, and `z_{i+1}` is used as `y`, and at the next
/// step, `z_{i+1}` will be assigned to `z_i`, and a new `z+{i+1}` will be computted.
pub struct TestFCircuit<F: PrimeField> {
z_i: F, // z_i
z_i1: F, // z_{i+1}
}
impl<F: PrimeField> FCircuit<F> for TestFCircuit<F> {
fn public(self) -> (F, F) {
(self.z_i, self.z_i1)
}
fn step_native(&mut self) {
self.z_i = self.z_i1;
self.z_i1 = self.z_i * self.z_i * self.z_i + self.z_i + F::from(5_u32);
}
fn step_circuit(
self,
cs: ConstraintSystemRef<F>,
z_i: FpVar<F>,
) -> Result<FpVar<F>, SynthesisError> {
let five = FpVar::<F>::new_constant(cs.clone(), F::from(5u32))?;
Ok(&z_i * &z_i * &z_i + &z_i + &five)
}
}
#[test]
fn test_committed_instance_var() {
let mut rng = ark_std::test_rng();
@ -266,7 +421,7 @@ mod tests {
let w2 = Witness::<Projective>::new(w2.clone(), r1cs.A.n_rows);
let mut rng = ark_std::test_rng();
let pedersen_params = Pedersen::<Projective>::new_params(&mut rng, r1cs.A.n_cols);
let pedersen_params = Pedersen::<Projective>::new_params(&mut rng, r1cs.A.n_rows);
// compute committed instances
let ci1 = w1.commit(&pedersen_params, x1.clone());
@ -275,12 +430,15 @@ mod tests {
// get challenge from transcript
let poseidon_config = poseidon_test_config::<Fr>();
let mut tr = PoseidonTranscript::<Projective>::new(&poseidon_config);
let r_bits = tr.get_challenge_nbits(128);
let r_bits = tr.get_challenge_nbits(N_BITS_CHALLENGE);
let r_Fr = Fr::from_bigint(BigInteger::from_bits_le(&r_bits)).unwrap();
let (_w3, ci3, _T, cmT) =
NIFS::<Projective>::prove(&pedersen_params, r_Fr, &r1cs, &w1, &ci1, &w2, &ci2).unwrap();
let ci3_verifier = NIFS::<Projective>::verify(r_Fr, &ci1, &ci2, &cmT);
assert_eq!(ci3_verifier, ci3);
let cs = ConstraintSystem::<Fr>::new_ref();
let rVar = FpVar::<Fr>::new_witness(cs.clone(), || Ok(r_Fr)).unwrap();
@ -294,13 +452,14 @@ mod tests {
CommittedInstanceVar::<Projective>::new_witness(cs.clone(), || Ok(ci3.clone()))
.unwrap();
NIFSGadget::<Projective>::verify(
let nifs_check = NIFSGadget::<Projective>::verify(
rVar.clone(),
ci1Var.clone(),
ci2Var.clone(),
ci3Var.clone(),
)
.unwrap();
nifs_check.enforce_equal(&Boolean::<Fr>::TRUE).unwrap();
assert!(cs.is_satisfied().unwrap());
// cs_CC is the Constraint System on the Curve Cycle auxiliary curve constraints field
@ -326,8 +485,11 @@ mod tests {
})
.unwrap();
NIFSCycleFoldGadget::<Projective, GVar>::verify(r_bitsVar, cmTVar, ci1Var, ci2Var, ci3Var)
.unwrap();
let nifs_cf_check = NIFSCycleFoldGadget::<Projective, GVar>::verify(
r_bitsVar, cmTVar, ci1Var, ci2Var, ci3Var,
)
.unwrap();
nifs_cf_check.enforce_equal(&Boolean::<Fq>::TRUE).unwrap();
assert!(cs_CC.is_satisfied().unwrap());
}
@ -366,4 +528,184 @@ mod tests {
// check that the natively computed and in-circuit computed hashes match
assert_eq!(hVar.value().unwrap(), h);
}
#[test]
/// test_augmented_f_circuit folds the TestFCircuit circuit in multiple iterations, feeding the
/// values into the AugmentedFCircuit.
fn test_augmented_f_circuit() {
let mut layer = ConstraintLayer::default();
layer.mode = TracingMode::OnlyConstraints;
let subscriber = tracing_subscriber::Registry::default().with(layer);
let _guard = tracing::subscriber::set_default(subscriber);
let mut rng = ark_std::test_rng();
let poseidon_config = poseidon_test_config::<Fr>();
// compute z vector for the initial instance
let cs = ConstraintSystem::<Fr>::new_ref();
// prepare the circuit to obtain its R1CS
let test_F_circuit_dummy = TestFCircuit::<Fr> {
z_i: Fr::zero(),
z_i1: Fr::zero(),
};
let mut augmented_F_circuit = AugmentedFCircuit::<Projective, TestFCircuit<Fr>> {
poseidon_config: poseidon_config.clone(),
i: None,
z_0: None,
z_i: None,
u_i: None,
U_i: None,
U_i1: None,
cmT: None,
r: None,
F: test_F_circuit_dummy,
x: None,
};
augmented_F_circuit
.generate_constraints(cs.clone())
.unwrap();
cs.finalize();
let cs = cs.into_inner().unwrap();
let r1cs = extract_r1cs::<Fr>(&cs);
let z = extract_z::<Fr>(&cs); // includes 1 and public inputs
let (w, x) = r1cs.split_z(&z);
let F_witness_len = w.len();
let mut tr = PoseidonTranscript::<Projective>::new(&poseidon_config);
let pedersen_params = Pedersen::<Projective>::new_params(&mut rng, r1cs.A.n_rows);
// first step
let z_0 = Fr::from(3_u32);
let mut z_i = z_0;
let mut z_i1 = Fr::from(35_u32);
// set the circuit to be folded with z_i=z_0=3 and z_{i+1}=35 (initial values)
let mut test_F_circuit = TestFCircuit::<Fr> { z_i, z_i1 };
let w_dummy = Witness::<Projective>::new(vec![Fr::zero(); F_witness_len], r1cs.A.n_rows);
let u_dummy = CommittedInstance::<Projective>::dummy(x.len());
// Wi is a 'dummy witness', all zeroes, but with the size corresponding to the R1CS that
// we're working with.
// set U_i <-- dummay instance
let mut W_i = w_dummy.clone();
let mut U_i = u_dummy.clone();
check_instance_relation(&r1cs, &W_i, &U_i).unwrap();
let mut w_i = w_dummy.clone();
let mut u_i = u_dummy.clone();
let (mut W_i1, mut U_i1, mut _T, mut cmT) = (
w_dummy.clone(),
u_dummy.clone(),
vec![],
Projective::generator(),
);
// as expected, dummy instances pass the relaxed_r1cs check
check_instance_relation(&r1cs, &W_i1, &U_i1).unwrap();
let mut i = Fr::zero();
let mut u_i1_x: Fr;
let n_steps: usize = 4;
for _ in 0..n_steps {
if i == Fr::zero() {
// base case: i=0, z_i=z_0, U_i = U_d := dummy instance
// u_1.x = H(1, z_0, z_i, U_i)
u_i1_x = U_i.hash(&poseidon_config, Fr::one(), z_0, z_i1).unwrap();
// base case
augmented_F_circuit = AugmentedFCircuit::<Projective, TestFCircuit<Fr>> {
poseidon_config: poseidon_config.clone(),
i: Some(i), // = 0
z_0: Some(z_0), // = z_i=3
z_i: Some(z_i),
u_i: Some(u_i.clone()), // = dummy
U_i: Some(U_i.clone()), // = dummy
U_i1: Some(U_i1.clone()), // = dummy
cmT: Some(cmT),
r: Some(Fr::one()),
F: test_F_circuit,
x: Some(u_i1_x),
};
} else {
// get challenge from transcript (since this is a test, we skip absorbing values to
// the transcript for simplicity)
let r_bits = tr.get_challenge_nbits(N_BITS_CHALLENGE);
let r_Fr = Fr::from_bigint(BigInteger::from_bits_le(&r_bits)).unwrap();
check_instance_relation(&r1cs, &w_i, &u_i).unwrap();
check_instance_relation(&r1cs, &W_i, &U_i).unwrap();
// U_{i+1}
(W_i1, U_i1, _T, cmT) = NIFS::<Projective>::prove(
&pedersen_params,
r_Fr,
&r1cs,
&w_i,
&u_i,
&W_i,
&U_i,
)
.unwrap();
check_instance_relation(&r1cs, &W_i1, &U_i1).unwrap();
// folded instance output (public input, x)
// u_{i+1}.x = H(i+1, z_0, z_{i+1}, U_{i+1})
u_i1_x = U_i1
.hash(&poseidon_config, i + Fr::one(), z_0, z_i1)
.unwrap();
augmented_F_circuit = AugmentedFCircuit::<Projective, TestFCircuit<Fr>> {
poseidon_config: poseidon_config.clone(),
i: Some(i),
z_0: Some(z_0),
z_i: Some(z_i),
u_i: Some(u_i),
U_i: Some(U_i.clone()),
U_i1: Some(U_i1.clone()),
cmT: Some(cmT),
r: Some(r_Fr),
F: test_F_circuit,
x: Some(u_i1_x),
};
}
let cs = ConstraintSystem::<Fr>::new_ref();
augmented_F_circuit
.generate_constraints(cs.clone())
.unwrap();
let is_satisfied = cs.is_satisfied().unwrap();
if !is_satisfied {
println!("{:?}", cs.which_is_unsatisfied());
}
assert!(is_satisfied);
cs.finalize();
let cs = cs.into_inner().unwrap();
// notice that here we use 'Z' (uppercase) to denote the 'z-vector' as in the paper,
// not the value 'z_i' (lowercase) which is the next state
let Z_i1 = extract_z::<Fr>(&cs);
let (w_i1, x_i1) = r1cs.split_z(&Z_i1);
assert_eq!(x_i1.len(), 1);
assert_eq!(x_i1[0], u_i1_x);
// compute committed instances, w_{i+1}, u_{i+1}, which will be used as w_i, u_i, so we
// assign them directly to w_i, u_i.
w_i = Witness::<Projective>::new(w_i1.clone(), r1cs.A.n_rows);
u_i = w_i.commit(&pedersen_params, vec![u_i1_x]);
check_instance_relation(&r1cs, &w_i, &u_i).unwrap();
check_instance_relation(&r1cs, &W_i1, &U_i1).unwrap();
// set values for next iteration
i += Fr::one();
test_F_circuit.step_native(); // advance the F circuit state
(z_i, z_i1) = test_F_circuit.public();
U_i = U_i1.clone();
W_i = W_i1.clone();
}
}
}

+ 24
- 6
src/folding/nova/mod.rs

@ -7,8 +7,10 @@ use ark_ec::{CurveGroup, Group};
use ark_std::fmt::Debug;
use ark_std::{One, Zero};
use crate::ccs::r1cs::R1CS;
use crate::folding::circuits::nonnative::point_to_nonnative_limbs;
use crate::pedersen::{Params as PedersenParams, Pedersen};
use crate::utils::vec::is_zero_vec;
use crate::Error;
pub mod circuits;
@ -27,12 +29,12 @@ where
<C as Group>::ScalarField: Absorb,
<C as ark_ec::CurveGroup>::BaseField: ark_ff::PrimeField,
{
pub fn empty() -> Self {
CommittedInstance {
pub fn dummy(io_len: usize) -> Self {
Self {
cmE: C::zero(),
u: C::ScalarField::one(),
u: C::ScalarField::zero(),
cmW: C::zero(),
x: Vec::new(),
x: vec![C::ScalarField::zero(); io_len],
}
}
@ -81,7 +83,7 @@ where
pub fn new(w: Vec<C::ScalarField>, e_len: usize) -> Self {
Self {
E: vec![C::ScalarField::zero(); e_len],
rE: C::ScalarField::one(),
rE: C::ScalarField::zero(), // because we use C::zero() as cmE
W: w,
rW: C::ScalarField::one(),
}
@ -91,7 +93,10 @@ where
params: &PedersenParams<C>,
x: Vec<C::ScalarField>,
) -> CommittedInstance<C> {
let cmE = Pedersen::commit(params, &self.E, &self.rE);
let mut cmE = C::zero();
if !is_zero_vec::<C::ScalarField>(&self.E) {
cmE = Pedersen::commit(params, &self.E, &self.rE);
}
let cmW = Pedersen::commit(params, &self.W, &self.rW);
CommittedInstance {
cmE,
@ -101,3 +106,16 @@ where
}
}
}
pub fn check_instance_relation<C: CurveGroup>(
r1cs: &R1CS<C::ScalarField>,
W: &Witness<C>,
U: &CommittedInstance<C>,
) -> Result<(), Error> {
let mut rel_r1cs = r1cs.clone().relax();
rel_r1cs.u = U.u;
rel_r1cs.E = W.E.clone();
let Z: Vec<C::ScalarField> = [vec![U.u], U.x.to_vec(), W.W.to_vec()].concat();
rel_r1cs.check_relation(&Z)
}

+ 69
- 22
src/folding/nova/nifs.rs

@ -181,19 +181,55 @@ where
}
#[cfg(test)]
mod tests {
pub mod tests {
use super::*;
use crate::ccs::r1cs::tests::{get_test_r1cs, get_test_z};
use crate::transcript::poseidon::{tests::poseidon_test_config, PoseidonTranscript};
use ark_ff::PrimeField;
use ark_pallas::{Fr, Projective};
use ark_std::UniformRand;
use ark_std::{ops::Mul, UniformRand, Zero};
use crate::ccs::r1cs::tests::{get_test_r1cs, get_test_z};
use crate::transcript::poseidon::{tests::poseidon_test_config, PoseidonTranscript};
use crate::utils::vec::vec_scalar_mul;
pub fn check_relaxed_r1cs<F: PrimeField>(r1cs: &R1CS<F>, z: &[F], u: &F, E: &[F]) -> bool {
let Az = mat_vec_mul_sparse(&r1cs.A, z);
let Bz = mat_vec_mul_sparse(&r1cs.B, z);
let Cz = mat_vec_mul_sparse(&r1cs.C, z);
hadamard(&Az, &Bz).unwrap() == vec_add(&vec_scalar_mul(&Cz, u), E).unwrap()
}
// fold 2 dummy instances and check that the folded instance holds the relaxed R1CS relation
#[test]
fn test_nifs_fold_dummy() {
let r1cs = get_test_r1cs::<Fr>();
let z1 = get_test_z(3);
let (w1, x1) = r1cs.split_z(&z1);
pub fn check_relaxed_r1cs<F: PrimeField>(r1cs: &R1CS<F>, z: Vec<F>, u: F, E: &[F]) {
let Az = mat_vec_mul_sparse(&r1cs.A, &z);
let Bz = mat_vec_mul_sparse(&r1cs.B, &z);
let Cz = mat_vec_mul_sparse(&r1cs.C, &z);
assert_eq!(hadamard(&Az, &Bz), vec_add(&vec_scalar_mul(&Cz, &u), E));
let mut rng = ark_std::test_rng();
let pedersen_params = Pedersen::<Projective>::new_params(&mut rng, r1cs.A.n_cols);
// dummy instance, witness and public inputs zeroes
let w_dummy = Witness::<Projective>::new(vec![Fr::zero(); w1.len()], r1cs.A.n_rows);
let mut u_dummy = w_dummy.commit(&pedersen_params, vec![Fr::zero(); x1.len()]);
u_dummy.u = Fr::zero();
let w_i = w_dummy.clone();
let u_i = u_dummy.clone();
let W_i = w_dummy.clone();
let U_i = u_dummy.clone();
let z_dummy = vec![Fr::zero(); z1.len()];
assert!(check_relaxed_r1cs(&r1cs, &z_dummy, &u_i.u, &w_i.E));
assert!(check_relaxed_r1cs(&r1cs, &z_dummy, &U_i.u, &W_i.E));
let r_Fr = Fr::from(3_u32);
let (W_i1, U_i1, _, _) =
NIFS::<Projective>::prove(&pedersen_params, r_Fr, &r1cs, &w_i, &u_i, &W_i, &U_i)
.unwrap();
let z: Vec<Fr> = [vec![U_i1.u], U_i1.x.to_vec(), W_i1.W.to_vec()].concat();
assert_eq!(z.len(), z1.len());
assert!(check_relaxed_r1cs(&r1cs, &z, &U_i1.u, &W_i1.E));
}
// fold 2 instances into one
@ -218,11 +254,12 @@ mod tests {
let ci2 = w2.commit(&pedersen_params, x2.clone());
// NIFS.P
let (w3, _, T, cmT) =
let (w3, ci3_aux, T, cmT) =
NIFS::<Projective>::prove(&pedersen_params, r, &r1cs, &w1, &ci1, &w2, &ci2).unwrap();
// NIFS.V
let ci3 = NIFS::<Projective>::verify(r, &ci1, &ci2, &cmT);
assert_eq!(ci3, ci3_aux);
// naive check that the folded witness satisfies the relaxed r1cs
let z3: Vec<Fr> = [vec![ci3.u], ci3.x.to_vec(), w3.W.to_vec()].concat();
@ -230,9 +267,9 @@ mod tests {
let z3_aux = vec_add(&z1, &vec_scalar_mul(&z2, &r)).unwrap();
assert_eq!(z3, z3_aux);
// check that relations hold for the 2 inputted instances and the folded one
check_relaxed_r1cs(&r1cs, z1, ci1.u, &w1.E);
check_relaxed_r1cs(&r1cs, z2, ci2.u, &w2.E);
check_relaxed_r1cs(&r1cs, z3, ci3.u, &w3.E);
assert!(check_relaxed_r1cs(&r1cs, &z1, &ci1.u, &w1.E));
assert!(check_relaxed_r1cs(&r1cs, &z2, &ci2.u, &w2.E));
assert!(check_relaxed_r1cs(&r1cs, &z3, &ci3.u, &w3.E));
// check that folded commitments from folded instance (ci) are equal to folding the
// use folded rE, rW to commit w3
@ -240,6 +277,10 @@ mod tests {
assert_eq!(ci3_expected.cmE, ci3.cmE);
assert_eq!(ci3_expected.cmW, ci3.cmW);
// next equalities should hold since we started from two cmE of zero-vector E's
assert_eq!(ci3.cmE, cmT.mul(r));
assert_eq!(w3.E, vec_scalar_mul(&T, &r));
// NIFS.Verify_Folded_Instance:
NIFS::<Projective>::verify_folded_instance(r, &ci1, &ci2, &ci3, &cmT).unwrap();
@ -259,6 +300,7 @@ mod tests {
&cmT,
)
.unwrap();
NIFS::<Projective>::verify_commitments(
&mut transcript_v,
&pedersen_params,
@ -281,12 +323,12 @@ mod tests {
// prepare the running instance
let mut running_instance_w = Witness::<Projective>::new(w.clone(), r1cs.A.n_rows);
let mut running_committed_instance = running_instance_w.commit(&pedersen_params, x);
check_relaxed_r1cs(
assert!(check_relaxed_r1cs(
&r1cs,
z,
running_committed_instance.u,
&z,
&running_committed_instance.u,
&running_instance_w.E,
);
));
let num_iters = 10;
for i in 0..num_iters {
@ -295,12 +337,12 @@ mod tests {
let (w, x) = r1cs.split_z(&incomming_instance_z);
let incomming_instance_w = Witness::<Projective>::new(w.clone(), r1cs.A.n_rows);
let incomming_committed_instance = incomming_instance_w.commit(&pedersen_params, x);
check_relaxed_r1cs(
assert!(check_relaxed_r1cs(
&r1cs,
incomming_instance_z.clone(),
incomming_committed_instance.u,
&incomming_instance_z.clone(),
&incomming_committed_instance.u,
&incomming_instance_w.E,
);
));
let r = Fr::rand(&mut rng); // folding challenge would come from the transcript
@ -331,7 +373,12 @@ mod tests {
]
.concat();
check_relaxed_r1cs(&r1cs, folded_z, folded_committed_instance.u, &folded_w.E);
assert!(check_relaxed_r1cs(
&r1cs,
&folded_z,
&folded_committed_instance.u,
&folded_w.E
));
// set running_instance for next loop iteration
running_instance_w = folded_w;

+ 25
- 12
src/frontend/arkworks/mod.rs

@ -8,6 +8,17 @@ use crate::utils::vec::SparseMatrix;
/// extracts arkworks ConstraintSystem matrices into crate::utils::vec::SparseMatrix format, and
/// extracts public inputs and witness into z vector. Returns a tuple containing (R1CS, z).
pub fn extract_r1cs_and_z<F: PrimeField>(cs: &ConstraintSystem<F>) -> (R1CS<F>, Vec<F>) {
let r1cs = extract_r1cs(cs);
// z = (1, x, w)
let z = extract_z(cs);
(r1cs, z)
}
/// extracts arkworks ConstraintSystem matrices into crate::utils::vec::SparseMatrix format as R1CS
/// struct.
pub fn extract_r1cs<F: PrimeField>(cs: &ConstraintSystem<F>) -> R1CS<F> {
let m = cs.to_matrices().unwrap();
let n_rows = cs.num_constraints;
@ -29,23 +40,23 @@ pub fn extract_r1cs_and_z(cs: &ConstraintSystem) -> (R1CS,
coeffs: m.c,
};
R1CS::<F> {
l: cs.num_instance_variables - 1, // -1 to substract the first '1'
A,
B,
C,
}
}
/// extracts public inputs and witness into z vector from arkworks ConstraintSystem.
pub fn extract_z<F: PrimeField>(cs: &ConstraintSystem<F>) -> Vec<F> {
// z = (1, x, w)
let z: Vec<F> = [
[
// 1 is already included in cs.instance_assignment
cs.instance_assignment.clone(),
cs.witness_assignment.clone(),
]
.concat();
(
R1CS::<F> {
l: cs.num_instance_variables,
A,
B,
C,
},
z,
)
.concat()
}
#[cfg(test)]
@ -96,5 +107,7 @@ pub mod tests {
let (r1cs, z) = extract_r1cs_and_z::<Fr>(&cs);
r1cs.check_relation(&z).unwrap();
// ensure that number of public inputs (l) is 1
assert_eq!(r1cs.l, 1);
}
}

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