// Package blindsecp256k1 implements the Blind signature scheme explained at // "New Blind Signature Schemes Based on the (Elliptic Curve) Discrete // Logarithm Problem", by Hamid Mala & Nafiseh Nezhadansari // https://sci-hub.do/10.1109/ICCKE.2013.6682844 // // LICENSE can be found at https://github.com/arnaucube/go-blindsecp256k1/blob/master/LICENSE // package blindsecp256k1 // WARNING: WIP code import ( "bytes" "crypto/rand" "fmt" "math/big" "github.com/btcsuite/btcd/btcec" "github.com/ethereum/go-ethereum/crypto" ) var ( // G represents the base point of secp256k1 G *Point = &Point{ X: btcec.S256().Gx, Y: btcec.S256().Gy, } // N represents the order of G of secp256k1 N *big.Int = btcec.S256().N // B (from y^2 = x^3 + B) B *big.Int = btcec.S256().B // Q = (P+1)/4 Q = new(big.Int).Div(new(big.Int).Add(btcec.S256().P, big.NewInt(1)), big.NewInt(4)) ) // Point represents a point on the secp256k1 curve type Point struct { X *big.Int Y *big.Int } // Add performs the Point addition func (p *Point) Add(q *Point) *Point { x, y := btcec.S256().Add(p.X, p.Y, q.X, q.Y) return &Point{ X: x, Y: y, } } // Mul performs the Point scalar multiplication func (p *Point) Mul(scalar *big.Int) *Point { x, y := btcec.S256().ScalarMult(p.X, p.Y, scalar.Bytes()) return &Point{ X: x, Y: y, } } func (p *Point) Compress() [33]byte { xBytes := p.X.Bytes() sign := byte(0) if isOdd(p.Y) { sign = byte(1) } var b [33]byte copy(b[32-len(xBytes):32], xBytes) b[32] = sign return b } func isOdd(b *big.Int) bool { return b.Bit(0) != 0 } func squareMul(r, x *big.Int, bit bool) *big.Int { // r = new(big.Int).Mul(r, r) // r^2 r = new(big.Int).Exp(r, big.NewInt(2), N) if bit { r = new(big.Int).Mul(r, x) } return new(big.Int).Mod(r, N) } // https://en.wikipedia.org/wiki/Exponentiation_by_squaring func sqrtQ(x *big.Int) *big.Int { // xBytes := x.Bytes() qBytes := Q.Bytes() r := big.NewInt(1) // fmt.Println(hex.EncodeToString(qBytes)) for _, b := range qBytes { // fmt.Printf("%d, %x %d\n", i, b, r) // fmt.Printf("%x %s\n", b, r.String()) switch b { // Most common case, where all 8 bits are set. case 0xff: r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) // fmt.Printf("%x %s\n", b, r.String()) // First byte of Q (0x3f), where all but the top two bits are // set. Note that this case only applies six operations, since // the highest bit of Q resides in bit six of the first byte. We // ignore the first two bits, since squaring for these bits will // result in an invalid result. We forgo squaring f before the // first multiply, since 1^2 = 1. case 0x3f: r = new(big.Int).Mul(r, x) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) // Byte 28 of Q (0xbf), where only bit 7 is unset. case 0xbf: r = squareMul(r, x, true) r = squareMul(r, x, false) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, true) // Byte 31 of Q (0x0c), where only bits 3 and 4 are set. default: r = squareMul(r, x, false) r = squareMul(r, x, false) r = squareMul(r, x, false) r = squareMul(r, x, false) r = squareMul(r, x, true) r = squareMul(r, x, true) r = squareMul(r, x, false) r = squareMul(r, x, false) } } return r } // https://bitcointalk.org/index.php?topic=162805.msg1712294#msg1712294 // func (p *Point) Decompress(b [33]byte) error { func Decompress(b [33]byte) (*Point, error) { fmt.Println(b) x := new(big.Int).SetBytes(b[:32]) fmt.Println(x) var sign bool if b[32] == byte(1) { sign = true } // y2 = x3+ ax2 + b (where A==0, B==7) // compute x^3 + B mod p x3 := new(big.Int).Mul(x, x) x3 = new(big.Int).Mul(x3, x) // x3 := new(big.Int).Exp(x, big.NewInt(3), N) x3 = new(big.Int).Add(x3, B) x3 = new(big.Int).Mod(x3, N) // sqrt mod p of x^3 + B fmt.Println("x3", x3) y := new(big.Int).ModSqrt(x3, N) // y := sqrtQ(x3) if y == nil { return nil, fmt.Errorf("not sqrt mod of x^3") } fmt.Println("y", y) fmt.Println("y", new(big.Int).Sub(N, y)) fmt.Println("y", new(big.Int).Mod(new(big.Int).Neg(y), N)) if sign != isOdd(y) { y = new(big.Int).Sub(N, y) // TODO check if needed Mod } // check that y is a square root of x^3 + B y2 := new(big.Int).Mul(y, y) y2 = new(big.Int).Mod(y2, N) if !bytes.Equal(y2.Bytes(), x3.Bytes()) { return nil, fmt.Errorf("invalid square root") } if sign != isOdd(y) { return nil, fmt.Errorf("sign does not match oddness") } p := &Point{X: x, Y: y} // p = &Point{} // p.X = x // p.Y = y // fmt.Println("I", p.X, p.Y) return p, nil } // WIP func newRand() *big.Int { var b [32]byte _, err := rand.Read(b[:]) if err != nil { panic(err) } bi := new(big.Int).SetBytes(b[:]) return new(big.Int).Mod(bi, N) } // PrivateKey represents the signer's private key type PrivateKey big.Int // PublicKey represents the signer's public key type PublicKey Point // NewPrivateKey returns a new random private key func NewPrivateKey() *PrivateKey { k := newRand() sk := PrivateKey(*k) return &sk } // BigInt returns a *big.Int representation of the PrivateKey func (sk *PrivateKey) BigInt() *big.Int { return (*big.Int)(sk) } // Public returns the PublicKey from the PrivateKey func (sk *PrivateKey) Public() *PublicKey { Q := G.Mul(sk.BigInt()) pk := PublicKey(*Q) return &pk } // Point returns a *Point representation of the PublicKey func (pk *PublicKey) Point() *Point { return (*Point)(pk) } // NewRequestParameters returns a new random k (secret) & R (public) parameters func NewRequestParameters() (*big.Int, *Point) { k := newRand() return k, G.Mul(k) // R = kG } // BlindSign performs the blind signature on the given mBlinded using the // PrivateKey and the secret k values func (sk *PrivateKey) BlindSign(mBlinded *big.Int, k *big.Int) *big.Int { // TODO add pending checks // s' = dm' + k sBlind := new(big.Int).Add( new(big.Int).Mul(sk.BigInt(), mBlinded), k) return sBlind } // UserSecretData contains the secret values from the User (a, b, c) and the // public F type UserSecretData struct { A *big.Int B *big.Int F *Point // public (in the paper is R) } // Blind performs the blinding operation on m using signerR parameter func Blind(m *big.Int, signerR *Point) (*big.Int, *UserSecretData) { u := &UserSecretData{} u.A = newRand() u.B = newRand() // (R) F = aR' + bG aR := signerR.Mul(u.A) bG := G.Mul(u.B) u.F = aR.Add(bG) // TODO check that F != O (point at infinity) rx := new(big.Int).Mod(u.F.X, N) // m' = a^-1 rx h(m) ainv := new(big.Int).ModInverse(u.A, N) ainvrx := new(big.Int).Mul(ainv, rx) hBytes := crypto.Keccak256(m.Bytes()) h := new(big.Int).SetBytes(hBytes) mBlinded := new(big.Int).Mul(ainvrx, h) return mBlinded, u } // Signature contains the signature values S & F type Signature struct { S *big.Int F *Point } // Unblind performs the unblinding operation of the blinded signature for the // given message m and the UserSecretData func Unblind(sBlind, m *big.Int, u *UserSecretData) *Signature { // s = a s' + b as := new(big.Int).Mul(u.A, sBlind) s := new(big.Int).Add(as, u.B) return &Signature{ S: s, F: u.F, } } // Verify checks the signature of the message m for the given PublicKey func Verify(m *big.Int, s *Signature, q *PublicKey) bool { // TODO add pending checks sG := G.Mul(s.S) // sG hBytes := crypto.Keccak256(m.Bytes()) h := new(big.Int).SetBytes(hBytes) rx := new(big.Int).Mod(s.F.X, N) rxh := new(big.Int).Mul(rx, h) // rxhG := G.Mul(rxh) // originally the paper uses G rxhG := q.Point().Mul(rxh) right := s.F.Add(rxhG) // check sG == R + rx h(m) G (where R in this code is F) if bytes.Equal(sG.X.Bytes(), right.X.Bytes()) && bytes.Equal(sG.Y.Bytes(), right.Y.Bytes()) { return true } return false }