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use bellperson::{
gadgets::{boolean::AllocatedBit, num::AllocatedNum},
ConstraintSystem, SynthesisError,
};
use ff::{PrimeField, PrimeFieldBits};
use nova_snark::{gadgets::ecc::AllocatedPoint, traits::circuit::StepCircuit};
use subtle::Choice;
// An affine point coordinate that is on the curve.
#[derive(Clone, Copy, Debug)]
pub struct Coordinate<F>
where
F: PrimeField<Repr = [u8; 32]>,
{
pub x: F,
pub y: F,
pub is_infinity: bool,
}
impl<F> Coordinate<F>
where
F: PrimeField<Repr = [u8; 32]>,
{
// New affine point coordiante on the curve so is_infinity = false.
pub fn new(x: F, y: F) -> Self {
Self {
x,
y,
is_infinity: false,
}
}
}
// An ECDSA signature
#[derive(Clone, Debug)]
pub struct EcdsaSignature<Fb, Fs>
where
Fb: PrimeField<Repr = [u8; 32]>,
Fs: PrimeField<Repr = [u8; 32]> + PrimeFieldBits,
{
pk: Coordinate<Fb>, // public key
r: Coordinate<Fb>, // (r, s) is the ECDSA signature
s: Fs,
c: Fs, // hash of the message
g: Coordinate<Fb>, // generator of the group; could be omitted if Nova's traits allow accessing the generator
}
impl<Fb, Fs> EcdsaSignature<Fb, Fs>
where
Fb: PrimeField<Repr = [u8; 32]>,
Fs: PrimeField<Repr = [u8; 32]> + PrimeFieldBits,
{
pub fn new(pk: Coordinate<Fb>, r: Coordinate<Fb>, s: Fs, c: Fs, g: Coordinate<Fb>) -> Self {
Self { pk, r, s, c, g }
}
}
// An ECDSA signature proof that we will use on the primary curve
#[derive(Clone, Debug)]
pub struct EcdsaCircuit<F>
where
F: PrimeField<Repr = [u8; 32]>,
{
pub r: Coordinate<F>,
pub g: Coordinate<F>,
pub pk: Coordinate<F>,
pub c: F,
pub s: F,
pub c_bits: Vec<Choice>,
pub s_bits: Vec<Choice>,
}
impl<F> EcdsaCircuit<F>
where
F: PrimeField<Repr = [u8; 32]>,
{
// Creates a new [`EcdsaCircuit<Fb, Fs>`]. The base and scalar field elements from the curve
// field used by the signature are converted to scalar field elements from the cyclic curve
// field used by the circuit.
pub fn new<Fb, Fs>(num_steps: usize, signatures: &[EcdsaSignature<Fb, Fs>]) -> (Vec<F>, Vec<Self>)
where
Fb: PrimeField<Repr = [u8; 32]>,
Fs: PrimeField<Repr = [u8; 32]> + PrimeFieldBits,
{
let mut z0 = Vec::new();
let mut circuits = Vec::new();
for (i, signature) in signatures.iter().enumerate().take(num_steps) {
let r = Coordinate::new(
F::from_repr(signature.r.x.to_repr()).unwrap(),
F::from_repr(signature.r.y.to_repr()).unwrap(),
);
let g = Coordinate::new(
F::from_repr(signature.g.x.to_repr()).unwrap(),
F::from_repr(signature.g.y.to_repr()).unwrap(),
);
let pk = Coordinate::new(
F::from_repr(signature.pk.x.to_repr()).unwrap(),
F::from_repr(signature.pk.y.to_repr()).unwrap(),
);
let c_bits = Self::to_le_bits(&signature.c);
let s_bits = Self::to_le_bits(&signature.s);
let c = F::from_repr(signature.c.to_repr()).unwrap();
let s = F::from_repr(signature.s.to_repr()).unwrap();
let circuit = EcdsaCircuit {
r,
g,
pk,
c,
s,
c_bits,
s_bits,
};
circuits.push(circuit);
if i == 0 {
z0 = vec![r.x, r.y, g.x, g.y, pk.x, pk.y, c, s];
}
}
(z0, circuits)
}
// Converts the scalar field element from the curve used by the signature to a bit represenation
// for later use in scalar multiplication using the cyclic curve used by the circuit.
fn to_le_bits<Fs>(fs: &Fs) -> Vec<Choice>
where
Fs: PrimeField<Repr = [u8; 32]> + PrimeFieldBits,
{
let bits = fs
.to_repr()
.iter()
.flat_map(|byte| (0..8).map(move |i| Choice::from((byte >> i) & 1u8)))
.collect::<Vec<Choice>>();
bits
}
// Synthesize a bit representation into circuit gadgets.
fn synthesize_bits<CS: ConstraintSystem<F>>(
cs: &mut CS,
bits: &[Choice],
) -> Result<Vec<AllocatedBit>, SynthesisError> {
let alloc_bits: Vec<AllocatedBit> = bits
.iter()
.enumerate()
.map(|(i, bit)| {
AllocatedBit::alloc(
cs.namespace(|| format!("bit {}", i)),
Some(bit.unwrap_u8() == 1u8),
)
})
.collect::<Result<Vec<AllocatedBit>, SynthesisError>>()
.unwrap();
Ok(alloc_bits)
}
}
impl<F> StepCircuit<F> for EcdsaCircuit<F>
where
F: PrimeField<Repr = [u8; 32]> + PrimeFieldBits,
{
fn arity(&self) -> usize {
8
}
// Prove knowledge of the sk used to generate the Ecdsa signature (R,s)
// with public key PK and message commitment c.
// [s]G == R + [c]PK
fn synthesize<CS: ConstraintSystem<F>>(
&self,
cs: &mut CS,
_z: &[AllocatedNum<F>],
) -> Result<Vec<AllocatedNum<F>>, SynthesisError> {
let g = AllocatedPoint::alloc(
cs.namespace(|| "G"),
Some((self.g.x, self.g.y, self.g.is_infinity)),
)?;
let s_bits = Self::synthesize_bits(&mut cs.namespace(|| "s_bits"), &self.s_bits)?;
let sg = g.scalar_mul(cs.namespace(|| "[s]G"), s_bits)?;
let r = AllocatedPoint::alloc(
cs.namespace(|| "R"),
Some((self.r.x, self.r.y, self.r.is_infinity)),
)?;
let c_bits = Self::synthesize_bits(&mut cs.namespace(|| "c_bits"), &self.c_bits)?;
let pk = AllocatedPoint::alloc(
cs.namespace(|| "PK"),
Some((self.pk.x, self.pk.y, self.pk.is_infinity)),
)?;
let cpk = pk.scalar_mul(&mut cs.namespace(|| "[c]PK"), c_bits)?;
let rcpk = cpk.add(&mut cs.namespace(|| "R + [c]PK"), &r)?;
let (rcpk_x, rcpk_y, _) = rcpk.get_coordinates();
let (sg_x, sg_y, _) = sg.get_coordinates();
cs.enforce(
|| "sg_x == rcpk_x",
|lc| lc + sg_x.get_variable(),
|lc| lc + CS::one(),
|lc| lc + rcpk_x.get_variable(),
);
cs.enforce(
|| "sg_y == rcpk_y",
|lc| lc + sg_y.get_variable(),
|lc| lc + CS::one(),
|lc| lc + rcpk_y.get_variable(),
);
let rx = AllocatedNum::alloc(cs.namespace(|| "rx"), || Ok(self.r.x))?;
let ry = AllocatedNum::alloc(cs.namespace(|| "ry"), || Ok(self.r.y))?;
let gx = AllocatedNum::alloc(cs.namespace(|| "gx"), || Ok(self.g.x))?;
let gy = AllocatedNum::alloc(cs.namespace(|| "gy"), || Ok(self.g.y))?;
let pkx = AllocatedNum::alloc(cs.namespace(|| "pkx"), || Ok(self.pk.x))?;
let pky = AllocatedNum::alloc(cs.namespace(|| "pky"), || Ok(self.pk.y))?;
let c = AllocatedNum::alloc(cs.namespace(|| "c"), || Ok(self.c))?;
let s = AllocatedNum::alloc(cs.namespace(|| "s"), || Ok(self.s))?;
Ok(vec![rx, ry, gx, gy, pkx, pky, c, s])
}
fn output(&self, _z: &[F]) -> Vec<F> {
vec![
self.r.x, self.r.y, self.g.x, self.g.y, self.pk.x, self.pk.y, self.c, self.s,
]
}
}