mirror of
https://github.com/cheat/cheat.git
synced 2024-11-25 15:31:36 +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).
172 lines
4.5 KiB
Go
172 lines
4.5 KiB
Go
package goldilocks
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import (
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"errors"
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"fmt"
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fp "github.com/cloudflare/circl/math/fp448"
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)
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// Point is a point on the Goldilocks Curve.
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type Point struct{ x, y, z, ta, tb fp.Elt }
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func (P Point) String() string {
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return fmt.Sprintf("x: %v\ny: %v\nz: %v\nta: %v\ntb: %v", P.x, P.y, P.z, P.ta, P.tb)
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}
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// FromAffine creates a point from affine coordinates.
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func FromAffine(x, y *fp.Elt) (*Point, error) {
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P := &Point{
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x: *x,
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y: *y,
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z: fp.One(),
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ta: *x,
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tb: *y,
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}
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if !(Curve{}).IsOnCurve(P) {
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return P, errors.New("point not on curve")
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}
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return P, nil
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}
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// isLessThan returns true if 0 <= x < y, and assumes that slices are of the
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// same length and are interpreted in little-endian order.
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func isLessThan(x, y []byte) bool {
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i := len(x) - 1
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for i > 0 && x[i] == y[i] {
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i--
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}
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return x[i] < y[i]
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}
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// FromBytes returns a point from the input buffer.
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func FromBytes(in []byte) (*Point, error) {
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if len(in) < fp.Size+1 {
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return nil, errors.New("wrong input length")
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}
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err := errors.New("invalid decoding")
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P := &Point{}
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signX := in[fp.Size] >> 7
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copy(P.y[:], in[:fp.Size])
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p := fp.P()
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if !isLessThan(P.y[:], p[:]) {
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return nil, err
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}
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u, v := &fp.Elt{}, &fp.Elt{}
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one := fp.One()
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fp.Sqr(u, &P.y) // u = y^2
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fp.Mul(v, u, ¶mD) // v = dy^2
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fp.Sub(u, u, &one) // u = y^2-1
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fp.Sub(v, v, &one) // v = dy^2-1
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isQR := fp.InvSqrt(&P.x, u, v) // x = sqrt(u/v)
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if !isQR {
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return nil, err
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}
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fp.Modp(&P.x) // x = x mod p
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if fp.IsZero(&P.x) && signX == 1 {
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return nil, err
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}
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if signX != (P.x[0] & 1) {
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fp.Neg(&P.x, &P.x)
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}
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P.ta = P.x
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P.tb = P.y
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P.z = fp.One()
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return P, nil
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}
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// IsIdentity returns true is P is the identity Point.
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func (P *Point) IsIdentity() bool {
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return fp.IsZero(&P.x) && !fp.IsZero(&P.y) && !fp.IsZero(&P.z) && P.y == P.z
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}
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// IsEqual returns true if P is equivalent to Q.
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func (P *Point) IsEqual(Q *Point) bool {
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l, r := &fp.Elt{}, &fp.Elt{}
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fp.Mul(l, &P.x, &Q.z)
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fp.Mul(r, &Q.x, &P.z)
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fp.Sub(l, l, r)
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b := fp.IsZero(l)
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fp.Mul(l, &P.y, &Q.z)
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fp.Mul(r, &Q.y, &P.z)
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fp.Sub(l, l, r)
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b = b && fp.IsZero(l)
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fp.Mul(l, &P.ta, &P.tb)
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fp.Mul(l, l, &Q.z)
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fp.Mul(r, &Q.ta, &Q.tb)
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fp.Mul(r, r, &P.z)
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fp.Sub(l, l, r)
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b = b && fp.IsZero(l)
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return b
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}
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// Neg obtains the inverse of the Point.
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func (P *Point) Neg() { fp.Neg(&P.x, &P.x); fp.Neg(&P.ta, &P.ta) }
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// ToAffine returns the x,y affine coordinates of P.
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func (P *Point) ToAffine() (x, y fp.Elt) {
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fp.Inv(&P.z, &P.z) // 1/z
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fp.Mul(&P.x, &P.x, &P.z) // x/z
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fp.Mul(&P.y, &P.y, &P.z) // y/z
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fp.Modp(&P.x)
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fp.Modp(&P.y)
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fp.SetOne(&P.z)
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P.ta = P.x
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P.tb = P.y
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return P.x, P.y
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}
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// ToBytes stores P into a slice of bytes.
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func (P *Point) ToBytes(out []byte) error {
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if len(out) < fp.Size+1 {
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return errors.New("invalid decoding")
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}
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x, y := P.ToAffine()
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out[fp.Size] = (x[0] & 1) << 7
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return fp.ToBytes(out[:fp.Size], &y)
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}
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// MarshalBinary encodes the receiver into a binary form and returns the result.
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func (P *Point) MarshalBinary() (data []byte, err error) {
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data = make([]byte, fp.Size+1)
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err = P.ToBytes(data[:fp.Size+1])
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return data, err
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}
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// UnmarshalBinary must be able to decode the form generated by MarshalBinary.
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func (P *Point) UnmarshalBinary(data []byte) error { Q, err := FromBytes(data); *P = *Q; return err }
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// Double sets P = 2Q.
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func (P *Point) Double() { P.Add(P) }
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// Add sets P =P+Q..
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func (P *Point) Add(Q *Point) {
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// This is formula (5) from "Twisted Edwards Curves Revisited" by
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// Hisil H., Wong K.KH., Carter G., Dawson E. (2008)
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// https://doi.org/10.1007/978-3-540-89255-7_20
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x1, y1, z1, ta1, tb1 := &P.x, &P.y, &P.z, &P.ta, &P.tb
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x2, y2, z2, ta2, tb2 := &Q.x, &Q.y, &Q.z, &Q.ta, &Q.tb
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x3, y3, z3, E, H := &P.x, &P.y, &P.z, &P.ta, &P.tb
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A, B, C, D := &fp.Elt{}, &fp.Elt{}, &fp.Elt{}, &fp.Elt{}
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t1, t2, F, G := C, D, &fp.Elt{}, &fp.Elt{}
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fp.Mul(t1, ta1, tb1) // t1 = ta1*tb1
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fp.Mul(t2, ta2, tb2) // t2 = ta2*tb2
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fp.Mul(A, x1, x2) // A = x1*x2
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fp.Mul(B, y1, y2) // B = y1*y2
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fp.Mul(C, t1, t2) // t1*t2
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fp.Mul(C, C, ¶mD) // C = d*t1*t2
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fp.Mul(D, z1, z2) // D = z1*z2
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fp.Add(F, x1, y1) // x1+y1
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fp.Add(E, x2, y2) // x2+y2
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fp.Mul(E, E, F) // (x1+y1)*(x2+y2)
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fp.Sub(E, E, A) // (x1+y1)*(x2+y2)-A
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fp.Sub(E, E, B) // E = (x1+y1)*(x2+y2)-A-B
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fp.Sub(F, D, C) // F = D-C
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fp.Add(G, D, C) // G = D+C
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fp.Sub(H, B, A) // H = B-A
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fp.Mul(z3, F, G) // Z = F * G
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fp.Mul(x3, E, F) // X = E * F
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fp.Mul(y3, G, H) // Y = G * H, T = E * H
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}
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