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sapling-crypto
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Implementation of group hash in the circuit.

This commit is contained in:
Sean Bowe 2017-12-18 11:34:15 -07:00
parent d143d3230a
commit 1e56289f19
No known key found for this signature in database
GPG Key ID: 95684257D8F8B031
2 changed files with 200 additions and 4 deletions
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52
src/circuit/boolean.rs
View File

@ -249,6 +249,28 @@ pub enum Boolean<Var> {
}
impl<Var: Copy> Boolean<Var> {
pub fn enforce_equal<E, CS>(
mut cs: CS,
a: &Self,
b: &Self
) -> Result<(), SynthesisError>
where E: Engine,
CS: ConstraintSystem<E, Variable=Var>
{
// TODO: this is just a cheap hack
let c = Self::xor(&mut cs, a, b)?;
Self::enforce_nand(&mut cs, &[c])
}
pub fn get_value(&self) -> Option<bool> {
match self {
&Boolean::Constant(c) => Some(c),
&Boolean::Is(ref v) => v.get_value(),
&Boolean::Not(ref v) => v.get_value().map(|b| !b)
}
}
/// Construct a boolean from a known constant
pub fn constant(b: bool) -> Self {
Boolean::Constant(b)
@ -578,6 +600,36 @@ mod test {
}
}
#[test]
fn test_enforce_equal() {
for a_bool in [false, true].iter().cloned() {
for b_bool in [false, true].iter().cloned() {
for a_neg in [false, true].iter().cloned() {
for b_neg in [false, true].iter().cloned() {
let mut cs = TestConstraintSystem::<Bls12>::new();
let mut a = Boolean::from(AllocatedBit::alloc(cs.namespace(|| "a"), Some(a_bool)).unwrap());
let mut b = Boolean::from(AllocatedBit::alloc(cs.namespace(|| "b"), Some(b_bool)).unwrap());
if a_neg {
a = a.not();
}
if b_neg {
b = b.not();
}
Boolean::enforce_equal(&mut cs, &a, &b).unwrap();
assert_eq!(
cs.is_satisfied(),
(a_bool ^ a_neg) == (b_bool ^ b_neg)
);
}
}
}
}
}
#[test]
fn test_boolean_negation() {
let mut cs = TestConstraintSystem::<Bls12>::new();

152
src/circuit/mont.rs
View File

@ -1,8 +1,7 @@
use pairing::{
Engine,
Field,
// TODO
// PrimeField
PrimeField
};
use bellman::{
@ -16,10 +15,15 @@ use super::{
};
use super::num::AllocatedNum;
use super::boolean::{
Boolean
};
use super::blake2s::blake2s;
use ::jubjub::{
JubjubEngine,
JubjubParams
JubjubParams,
montgomery
};
pub struct MontgomeryPoint<E: Engine, Var> {
@ -28,6 +32,79 @@ pub struct MontgomeryPoint<E: Engine, Var> {
}
impl<E: JubjubEngine, Var: Copy> MontgomeryPoint<E, Var> {
pub fn group_hash<CS>(
mut cs: CS,
tag: &[Boolean<Var>],
params: &E::Params
) -> Result<Self, SynthesisError>
where CS: ConstraintSystem<E, Variable=Var>
{
// This code is specialized for a field of this size
assert_eq!(E::Fr::NUM_BITS, 255);
assert!(tag.len() % 8 == 0);
// TODO: first block, personalization
//
// Perform BLAKE2s hash
let h = blake2s(cs.namespace(|| "blake2s"), tag)?;
// Read the x-coordinate
let x = AllocatedNum::from_bits_strict(
cs.namespace(|| "read x coordinate"),
&h[1..]
)?;
// Allocate the y-coordinate given the first bit
// of the hash as its parity ("sign bit").
let y = AllocatedNum::alloc(
cs.namespace(|| "y-coordinate"),
|| {
let s: bool = *h[0].get_value().get()?;
let x: E::Fr = *x.get_value().get()?;
let p = montgomery::Point::<E, _>::get_for_x(x, s, params);
let p = p.get()?;
let (_, y) = p.into_xy().expect("can't be the point at infinity");
Ok(y)
}
)?;
// Unpack the y-coordinate
let ybits = y.into_bits_strict(cs.namespace(|| "y-coordinate unpacking"))?;
// Enforce that the y-coordinate has the right sign
Boolean::enforce_equal(
cs.namespace(|| "correct sign constraint"),
&h[0],
&ybits[E::Fr::NUM_BITS as usize - 1]
)?;
// interpret the result as a point on the curve
let mut p = Self::interpret(
cs.namespace(|| "point interpretation"),
&x,
&y,
params
)?;
// Perform three doublings to move the point into the prime
// order subgroup.
for i in 0..3 {
// Assert the y-coordinate is nonzero (the doubling
// doesn't work for y=0).
p.y.assert_nonzero(
cs.namespace(|| format!("nonzero y-coordinate {}", i))
)?;
p = p.double(
cs.namespace(|| format!("doubling {}", i)),
params
)?;
}
Ok(p)
}
pub fn interpret<CS>(
mut cs: CS,
x: &AllocatedNum<E, Var>,
@ -172,7 +249,74 @@ mod test {
montgomery,
JubjubBls12
};
use super::{MontgomeryPoint, AllocatedNum};
use super::{MontgomeryPoint, AllocatedNum, Boolean};
use super::super::boolean::AllocatedBit;
use ::group_hash::group_hash;
#[test]
fn test_group_hash() {
let params = &JubjubBls12::new();
let rng = &mut XorShiftRng::from_seed([0x3dbe6259, 0x8d313d76, 0x3237db17, 0xe5bc0654]);
let mut num_errs = 0;
let mut num_unsatisfied = 0;
let mut num_satisfied = 0;
for _ in 0..100 {
let mut cs = TestConstraintSystem::<Bls12>::new();
let mut tag_bytes = vec![];
let mut tag = vec![];
for i in 0..10 {
let mut byte = 0;
for j in 0..8 {
byte <<= 1;
let b: bool = rng.gen();
if b {
byte |= 1;
}
tag.push(Boolean::from(
AllocatedBit::alloc(
cs.namespace(|| format!("bit {} {}", i, j)),
Some(b)
).unwrap()
));
}
tag_bytes.push(byte);
}
let p = MontgomeryPoint::group_hash(
cs.namespace(|| "gh"),
&tag,
params
);
let expected = group_hash::<Bls12>(&tag_bytes, params);
if p.is_err() {
assert!(expected.is_none());
num_errs += 1;
} else {
if !cs.is_satisfied() {
assert!(expected.is_none());
num_unsatisfied += 1;
} else {
let p = p.unwrap();
let (x, y) = expected.unwrap();
assert_eq!(p.x.get_value().unwrap(), x);
assert_eq!(p.y.get_value().unwrap(), y);
num_satisfied += 1;
}
}
}
assert_eq!(
(num_errs, num_unsatisfied, num_satisfied),
(47, 4, 49)
);
}
#[test]
fn test_interpret() {