mirror of
https://github.com/cheat/cheat.git
synced 2024-11-17 17:35:21 +01:00
80c91cbdee
Integrate `go-git` into the application, and use it to `git clone` cheatsheets when the installer runs. Previously, the installer required that `git` be installed on the system `PATH`, so this change has to big advantages: 1. It removes that system dependency on `git` 2. It paves the way for implementing the `--update` command Additionally, `cheat` now performs a `--depth=1` clone when installing cheatsheets, which should at least somewhat improve installation times (especially on slow network connections).
80 lines
2.2 KiB
Go
80 lines
2.2 KiB
Go
// Package goldilocks provides elliptic curve operations over the goldilocks curve.
|
|
package goldilocks
|
|
|
|
import fp "github.com/cloudflare/circl/math/fp448"
|
|
|
|
// Curve is the Goldilocks curve x^2+y^2=z^2-39081x^2y^2.
|
|
type Curve struct{}
|
|
|
|
// Identity returns the identity point.
|
|
func (Curve) Identity() *Point {
|
|
return &Point{
|
|
y: fp.One(),
|
|
z: fp.One(),
|
|
}
|
|
}
|
|
|
|
// IsOnCurve returns true if the point lies on the curve.
|
|
func (Curve) IsOnCurve(P *Point) bool {
|
|
x2, y2, t, t2, z2 := &fp.Elt{}, &fp.Elt{}, &fp.Elt{}, &fp.Elt{}, &fp.Elt{}
|
|
rhs, lhs := &fp.Elt{}, &fp.Elt{}
|
|
fp.Mul(t, &P.ta, &P.tb) // t = ta*tb
|
|
fp.Sqr(x2, &P.x) // x^2
|
|
fp.Sqr(y2, &P.y) // y^2
|
|
fp.Sqr(z2, &P.z) // z^2
|
|
fp.Sqr(t2, t) // t^2
|
|
fp.Add(lhs, x2, y2) // x^2 + y^2
|
|
fp.Mul(rhs, t2, ¶mD) // dt^2
|
|
fp.Add(rhs, rhs, z2) // z^2 + dt^2
|
|
fp.Sub(lhs, lhs, rhs) // x^2 + y^2 - (z^2 + dt^2)
|
|
eq0 := fp.IsZero(lhs)
|
|
|
|
fp.Mul(lhs, &P.x, &P.y) // xy
|
|
fp.Mul(rhs, t, &P.z) // tz
|
|
fp.Sub(lhs, lhs, rhs) // xy - tz
|
|
eq1 := fp.IsZero(lhs)
|
|
return eq0 && eq1
|
|
}
|
|
|
|
// Generator returns the generator point.
|
|
func (Curve) Generator() *Point {
|
|
return &Point{
|
|
x: genX,
|
|
y: genY,
|
|
z: fp.One(),
|
|
ta: genX,
|
|
tb: genY,
|
|
}
|
|
}
|
|
|
|
// Order returns the number of points in the prime subgroup.
|
|
func (Curve) Order() Scalar { return order }
|
|
|
|
// Double returns 2P.
|
|
func (Curve) Double(P *Point) *Point { R := *P; R.Double(); return &R }
|
|
|
|
// Add returns P+Q.
|
|
func (Curve) Add(P, Q *Point) *Point { R := *P; R.Add(Q); return &R }
|
|
|
|
// ScalarMult returns kP. This function runs in constant time.
|
|
func (e Curve) ScalarMult(k *Scalar, P *Point) *Point {
|
|
k4 := &Scalar{}
|
|
k4.divBy4(k)
|
|
return e.pull(twistCurve{}.ScalarMult(k4, e.push(P)))
|
|
}
|
|
|
|
// ScalarBaseMult returns kG where G is the generator point. This function runs in constant time.
|
|
func (e Curve) ScalarBaseMult(k *Scalar) *Point {
|
|
k4 := &Scalar{}
|
|
k4.divBy4(k)
|
|
return e.pull(twistCurve{}.ScalarBaseMult(k4))
|
|
}
|
|
|
|
// CombinedMult returns mG+nP, where G is the generator point. This function is non-constant time.
|
|
func (e Curve) CombinedMult(m, n *Scalar, P *Point) *Point {
|
|
m4 := &Scalar{}
|
|
n4 := &Scalar{}
|
|
m4.divBy4(m)
|
|
n4.divBy4(n)
|
|
return e.pull(twistCurve{}.CombinedMult(m4, n4, twistCurve{}.pull(P)))
|
|
}
|