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Merge pull request #18 from mmaker/master 

Add clear_cofactor.
This commit is contained in:
ebfull 2019-12-10 14:12:33 -07:00 committed by GitHub
parent b3d1fe1fad 948b1997af
commit e32494e720
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92
src/g1.rs
View File

@ -735,6 +735,34 @@ impl G1Projective {
acc
}
/// Multiply `self` by `crate::BLS_X`, using double and add.
fn mul_by_x(&self) -> G1Projective {
let mut xself = G1Projective::identity();
// NOTE: in BLS12-381 we can just skip the first bit.
let mut x = crate::BLS_X >> 1;
let mut tmp = *self;
while x != 0 {
tmp = tmp.double();
if x % 2 == 1 {
xself += tmp;
}
x >>= 1;
}
// finally, flip the sign
if crate::BLS_X_IS_NEGATIVE {
xself = -xself;
}
xself
}
/// Multiplies by $(1 - z)$, where $z$ is the parameter of BLS12-381, which
/// [suffices to clear](https://ia.cr/2019/403) the cofactor and map
/// elliptic curve points to elements of $\mathbb{G}\_1$.
pub fn clear_cofactor(&self) -> G1Projective {
self - self.mul_by_x()
}
/// Converts a batch of `G1Projective` elements into `G1Affine` elements. This
/// function will panic if `p.len() != q.len()`.
pub fn batch_normalize(p: &[Self], q: &mut [G1Affine]) {
@ -1303,6 +1331,70 @@ fn test_is_torsion_free() {
assert!(bool::from(G1Affine::generator().is_torsion_free()));
}
#[test]
fn test_mul_by_x() {
// multiplying by `x` a point in G1 is the same as multiplying by
// the equivalent scalar.
let generator = G1Projective::generator();
let x = if crate::BLS_X_IS_NEGATIVE {
-Scalar::from(crate::BLS_X)
} else {
Scalar::from(crate::BLS_X)
};
assert_eq!(generator.mul_by_x(), generator * x);
let point = G1Projective::generator() * Scalar::from(42);
assert_eq!(point.mul_by_x(), point * x);
}
#[test]
fn test_clear_cofactor() {
// the generator (and the identity) are always on the curve,
// even after clearing the cofactor
let generator = G1Projective::generator();
assert!(bool::from(generator.clear_cofactor().is_on_curve()));
let id = G1Projective::identity();
assert!(bool::from(id.clear_cofactor().is_on_curve()));
let point = G1Projective {
x: Fp::from_raw_unchecked([
0x48af5ff540c817f0,
0xd73893acaf379d5a,
0xe6c43584e18e023c,
0x1eda39c30f188b3e,
0xf618c6d3ccc0f8d8,
0x0073542cd671e16c,
]),
y: Fp::from_raw_unchecked([
0x57bf8be79461d0ba,
0xfc61459cee3547c3,
0x0d23567df1ef147b,
0x0ee187bcce1d9b64,
0xb0c8cfbe9dc8fdc1,
0x1328661767ef368b,
]),
z: Fp::from_raw_unchecked([
0x3d2d1c670671394e,
0x0ee3a800a2f7c1ca,
0x270f4f21da2e5050,
0xe02840a53f1be768,
0x55debeb597512690,
0x08bd25353dc8f791,
]),
};
assert!(bool::from(point.is_on_curve()));
assert!(!bool::from(G1Affine::from(point).is_torsion_free()));
let cleared_point = point.clear_cofactor();
assert!(bool::from(cleared_point.is_on_curve()));
assert!(bool::from(G1Affine::from(cleared_point).is_torsion_free()));
// in BLS12-381 the cofactor in G1 can be
// cleared multiplying by (1-x)
let h_eff = Scalar::from(1) + Scalar::from(crate::BLS_X);
assert_eq!(point.clear_cofactor(), point * h_eff);
}
#[test]
fn test_batch_normalize() {
let a = G1Projective::generator().double();

283
src/g2.rs
View File

@ -827,6 +827,108 @@ impl G2Projective {
acc
}
fn psi(&self) -> G2Projective {
// 1 / ((u+1) ^ ((q-1)/3))
let psi_coeff_x = Fp2 {
c0: Fp::zero(),
c1: Fp::from_raw_unchecked([
0x890dc9e4867545c3,
0x2af322533285a5d5,
0x50880866309b7e2c,
0xa20d1b8c7e881024,
0x14e4f04fe2db9068,
0x14e56d3f1564853a,
]),
};
// 1 / ((u+1) ^ (p-1)/2)
let psi_coeff_y = Fp2 {
c0: Fp::from_raw_unchecked([
0x3e2f585da55c9ad1,
0x4294213d86c18183,
0x382844c88b623732,
0x92ad2afd19103e18,
0x1d794e4fac7cf0b9,
0x0bd592fc7d825ec8,
]),
c1: Fp::from_raw_unchecked([
0x7bcfa7a25aa30fda,
0xdc17dec12a927e7c,
0x2f088dd86b4ebef1,
0xd1ca2087da74d4a7,
0x2da2596696cebc1d,
0x0e2b7eedbbfd87d2,
]),
};
G2Projective {
// x = frobenius(x)/((u+1)^((p-1)/3))
x: self.x.frobenius_map() * psi_coeff_x,
// y = frobenius(y)/(u+1)^((p-1)/2)
y: self.y.frobenius_map() * psi_coeff_y,
// z = frobenius(z)
z: self.z.frobenius_map(),
}
}
fn psi2(&self) -> G2Projective {
// 1 / 2 ^ ((q-1)/3)
let psi2_coeff_x = Fp2 {
c0: Fp::from_raw_unchecked([
0xcd03c9e48671f071,
0x5dab22461fcda5d2,
0x587042afd3851b95,
0x8eb60ebe01bacb9e,
0x03f97d6e83d050d2,
0x18f0206554638741,
]),
c1: Fp::zero(),
};
G2Projective {
// x = frobenius^2(x)/2^((p-1)/3)
x: self.x.frobenius_map().frobenius_map() * psi2_coeff_x,
// y = -frobenius^2(y)
y: self.y.frobenius_map().frobenius_map().neg(),
// z = z
z: self.z,
}
}
/// Multiply `self` by `crate::BLS_X`, using double and add.
fn mul_by_x(&self) -> G2Projective {
let mut xself = G2Projective::identity();
// NOTE: in BLS12-381 we can just skip the first bit.
let mut x = crate::BLS_X >> 1;
let mut acc = *self;
while x != 0 {
acc = acc.double();
if x % 2 == 1 {
xself += acc;
}
x >>= 1;
}
// finally, flip the sign
if crate::BLS_X_IS_NEGATIVE {
xself = -xself;
}
xself
}
/// Clears the cofactor, using [Budroni-Pintore](https://ia.cr/2017/419).
/// This is equivalent to multiplying by $h\_\textrm{eff} = 3(z^2 - 1) \cdot
/// h_2$, where $h_2$ is the cofactor of $\mathbb{G}\_2$ and $z$ is the
/// parameter of BLS12-381.
pub fn clear_cofactor(&self) -> G2Projective {
let t1 = self.mul_by_x(); // [x] P
let t2 = self.psi(); // psi(P)
self.double().psi2() // psi^2(2P)
+ (t1 + t2).mul_by_x() // psi^2(2P) + [x^2] P + [x] psi(P)
- t1 // psi^2(2P) + [x^2 - x] P + [x] psi(P)
- t2 // psi^2(2P) + [x^2 - x] P + [x - 1] psi(P)
- self // psi^2(2P) + [x^2 - x - 1] P + [x - 1] psi(P)
}
/// Converts a batch of `G2Projective` elements into `G2Affine` elements. This
/// function will panic if `p.len() != q.len()`.
pub fn batch_normalize(p: &[Self], q: &mut [G2Affine]) {
@ -1551,6 +1653,187 @@ fn test_is_torsion_free() {
assert!(bool::from(G2Affine::generator().is_torsion_free()));
}
#[test]
fn test_mul_by_x() {
// multiplying by `x` a point in G2 is the same as multiplying by
// the equivalent scalar.
let generator = G2Projective::generator();
let x = if crate::BLS_X_IS_NEGATIVE {
-Scalar::from(crate::BLS_X)
} else {
Scalar::from(crate::BLS_X)
};
assert_eq!(generator.mul_by_x(), generator * x);
let point = G2Projective::generator() * Scalar::from(42);
assert_eq!(point.mul_by_x(), point * x);
}
#[test]
fn test_psi() {
let generator = G2Projective::generator();
// `point` is a random point in the curve
let point = G2Projective {
x: Fp2 {
c0: Fp::from_raw_unchecked([
0xee4c8cb7c047eaf2,
0x44ca22eee036b604,
0x33b3affb2aefe101,
0x15d3e45bbafaeb02,
0x7bfc2154cd7419a4,
0x0a2d0c2b756e5edc,
]),
c1: Fp::from_raw_unchecked([
0xfc224361029a8777,
0x4cbf2baab8740924,
0xc5008c6ec6592c89,
0xecc2c57b472a9c2d,
0x8613eafd9d81ffb1,
0x10fe54daa2d3d495,
]),
},
y: Fp2 {
c0: Fp::from_raw_unchecked([
0x7de7edc43953b75c,
0x58be1d2de35e87dc,
0x5731d30b0e337b40,
0xbe93b60cfeaae4c9,
0x8b22c203764bedca,
0x01616c8d1033b771,
]),
c1: Fp::from_raw_unchecked([
0xea126fe476b5733b,
0x85cee68b5dae1652,
0x98247779f7272b04,
0xa649c8b468c6e808,
0xb5b9a62dff0c4e45,
0x1555b67fc7bbe73d,
]),
},
z: Fp2 {
c0: Fp::from_raw_unchecked([
0x0ef2ddffab187c0a,
0x2424522b7d5ecbfc,
0xc6f341a3398054f4,
0x5523ddf409502df0,
0xd55c0b5a88e0dd97,
0x066428d704923e52,
]),
c1: Fp::from_raw_unchecked([
0x538bbe0c95b4878d,
0xad04a50379522881,
0x6d5c05bf5c12fb64,
0x4ce4a069a2d34787,
0x59ea6c8d0dffaeaf,
0x0d42a083a75bd6f3,
]),
},
};
assert!(bool::from(point.is_on_curve()));
// psi2(P) = psi(psi(P))
assert_eq!(generator.psi2(), generator.psi().psi());
assert_eq!(point.psi2(), point.psi().psi());
// psi(P) is a morphism
assert_eq!(generator.double().psi(), generator.psi().double());
assert_eq!(point.psi() + generator.psi(), (point + generator).psi());
// psi(P) behaves in the same way on the same projective point
let mut normalized_point = [G2Affine::identity()];
G2Projective::batch_normalize(&[point], &mut normalized_point);
let normalized_point = G2Projective::from(normalized_point[0]);
assert_eq!(point.psi(), normalized_point.psi());
assert_eq!(point.psi2(), normalized_point.psi2());
}
#[test]
fn test_clear_cofactor() {
// `point` is a random point in the curve
let point = G2Projective {
x: Fp2 {
c0: Fp::from_raw_unchecked([
0xee4c8cb7c047eaf2,
0x44ca22eee036b604,
0x33b3affb2aefe101,
0x15d3e45bbafaeb02,
0x7bfc2154cd7419a4,
0x0a2d0c2b756e5edc,
]),
c1: Fp::from_raw_unchecked([
0xfc224361029a8777,
0x4cbf2baab8740924,
0xc5008c6ec6592c89,
0xecc2c57b472a9c2d,
0x8613eafd9d81ffb1,
0x10fe54daa2d3d495,
]),
},
y: Fp2 {
c0: Fp::from_raw_unchecked([
0x7de7edc43953b75c,
0x58be1d2de35e87dc,
0x5731d30b0e337b40,
0xbe93b60cfeaae4c9,
0x8b22c203764bedca,
0x01616c8d1033b771,
]),
c1: Fp::from_raw_unchecked([
0xea126fe476b5733b,
0x85cee68b5dae1652,
0x98247779f7272b04,
0xa649c8b468c6e808,
0xb5b9a62dff0c4e45,
0x1555b67fc7bbe73d,
]),
},
z: Fp2 {
c0: Fp::from_raw_unchecked([
0x0ef2ddffab187c0a,
0x2424522b7d5ecbfc,
0xc6f341a3398054f4,
0x5523ddf409502df0,
0xd55c0b5a88e0dd97,
0x066428d704923e52,
]),
c1: Fp::from_raw_unchecked([
0x538bbe0c95b4878d,
0xad04a50379522881,
0x6d5c05bf5c12fb64,
0x4ce4a069a2d34787,
0x59ea6c8d0dffaeaf,
0x0d42a083a75bd6f3,
]),
},
};
assert!(bool::from(point.is_on_curve()));
assert!(!bool::from(G2Affine::from(point).is_torsion_free()));
let cleared_point = point.clear_cofactor();
assert!(bool::from(cleared_point.is_on_curve()));
assert!(bool::from(G2Affine::from(cleared_point).is_torsion_free()));
// the generator (and the identity) are always on the curve,
// even after clearing the cofactor
let generator = G2Projective::generator();
assert!(bool::from(generator.clear_cofactor().is_on_curve()));
let id = G2Projective::identity();
assert!(bool::from(id.clear_cofactor().is_on_curve()));
// test the effect on q-torsion points multiplying by h_eff modulo |Scalar|
// h_eff % q = 0x2b116900400069009a40200040001ffff
let h_eff_modq: [u8; 32] = [
0xff, 0xff, 0x01, 0x00, 0x04, 0x00, 0x02, 0xa4, 0x09, 0x90, 0x06, 0x00, 0x04, 0x90, 0x16,
0xb1, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00,
];
assert_eq!(generator.clear_cofactor(), generator.multiply(&h_eff_modq));
assert_eq!(
cleared_point.clear_cofactor(),
cleared_point.multiply(&h_eff_modq)
);
}
#[test]
fn test_batch_normalize() {
let a = G2Projective::generator().double();