204 lines
5.9 KiB
Go
204 lines
5.9 KiB
Go
// Copyright (c) 2014-2015 The btcsuite developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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// This file is ignored during the regular build due to the following build tag.
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// This build tag is set during go generate.
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// +build gensecp256k1
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package btcec
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// References:
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// [GECC]: Guide to Elliptic Curve Cryptography (Hankerson, Menezes, Vanstone)
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import (
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"encoding/binary"
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"math/big"
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)
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// secp256k1BytePoints are dummy points used so the code which generates the
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// real values can compile.
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var secp256k1BytePoints = ""
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// getDoublingPoints returns all the possible G^(2^i) for i in
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// 0..n-1 where n is the curve's bit size (256 in the case of secp256k1)
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// the coordinates are recorded as Jacobian coordinates.
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func (curve *KoblitzCurve) getDoublingPoints() [][3]fieldVal {
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doublingPoints := make([][3]fieldVal, curve.BitSize)
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// initialize px, py, pz to the Jacobian coordinates for the base point
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px, py := curve.bigAffineToField(curve.Gx, curve.Gy)
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pz := new(fieldVal).SetInt(1)
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for i := 0; i < curve.BitSize; i++ {
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doublingPoints[i] = [3]fieldVal{*px, *py, *pz}
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// P = 2*P
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curve.doubleJacobian(px, py, pz, px, py, pz)
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}
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return doublingPoints
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}
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// SerializedBytePoints returns a serialized byte slice which contains all of
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// the possible points per 8-bit window. This is used to when generating
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// secp256k1.go.
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func (curve *KoblitzCurve) SerializedBytePoints() []byte {
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doublingPoints := curve.getDoublingPoints()
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// Segregate the bits into byte-sized windows
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serialized := make([]byte, curve.byteSize*256*3*10*4)
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offset := 0
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for byteNum := 0; byteNum < curve.byteSize; byteNum++ {
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// Grab the 8 bits that make up this byte from doublingPoints.
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startingBit := 8 * (curve.byteSize - byteNum - 1)
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computingPoints := doublingPoints[startingBit : startingBit+8]
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// Compute all points in this window and serialize them.
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for i := 0; i < 256; i++ {
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px, py, pz := new(fieldVal), new(fieldVal), new(fieldVal)
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for j := 0; j < 8; j++ {
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if i>>uint(j)&1 == 1 {
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curve.addJacobian(px, py, pz, &computingPoints[j][0],
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&computingPoints[j][1], &computingPoints[j][2], px, py, pz)
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}
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}
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for i := 0; i < 10; i++ {
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binary.LittleEndian.PutUint32(serialized[offset:], px.n[i])
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offset += 4
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}
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for i := 0; i < 10; i++ {
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binary.LittleEndian.PutUint32(serialized[offset:], py.n[i])
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offset += 4
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}
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for i := 0; i < 10; i++ {
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binary.LittleEndian.PutUint32(serialized[offset:], pz.n[i])
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offset += 4
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}
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}
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}
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return serialized
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}
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// sqrt returns the square root of the provided big integer using Newton's
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// method. It's only compiled and used during generation of pre-computed
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// values, so speed is not a huge concern.
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func sqrt(n *big.Int) *big.Int {
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// Initial guess = 2^(log_2(n)/2)
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guess := big.NewInt(2)
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guess.Exp(guess, big.NewInt(int64(n.BitLen()/2)), nil)
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// Now refine using Newton's method.
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big2 := big.NewInt(2)
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prevGuess := big.NewInt(0)
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for {
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prevGuess.Set(guess)
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guess.Add(guess, new(big.Int).Div(n, guess))
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guess.Div(guess, big2)
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if guess.Cmp(prevGuess) == 0 {
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break
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}
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}
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return guess
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}
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// EndomorphismVectors runs the first 3 steps of algorithm 3.74 from [GECC] to
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// generate the linearly independent vectors needed to generate a balanced
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// length-two representation of a multiplier such that k = k1 + k2λ (mod N) and
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// returns them. Since the values will always be the same given the fact that N
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// and λ are fixed, the final results can be accelerated by storing the
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// precomputed values with the curve.
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func (curve *KoblitzCurve) EndomorphismVectors() (a1, b1, a2, b2 *big.Int) {
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bigMinus1 := big.NewInt(-1)
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// This section uses an extended Euclidean algorithm to generate a
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// sequence of equations:
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// s[i] * N + t[i] * λ = r[i]
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nSqrt := sqrt(curve.N)
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u, v := new(big.Int).Set(curve.N), new(big.Int).Set(curve.lambda)
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x1, y1 := big.NewInt(1), big.NewInt(0)
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x2, y2 := big.NewInt(0), big.NewInt(1)
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q, r := new(big.Int), new(big.Int)
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qu, qx1, qy1 := new(big.Int), new(big.Int), new(big.Int)
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s, t := new(big.Int), new(big.Int)
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ri, ti := new(big.Int), new(big.Int)
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a1, b1, a2, b2 = new(big.Int), new(big.Int), new(big.Int), new(big.Int)
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found, oneMore := false, false
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for u.Sign() != 0 {
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// q = v/u
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q.Div(v, u)
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// r = v - q*u
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qu.Mul(q, u)
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r.Sub(v, qu)
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// s = x2 - q*x1
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qx1.Mul(q, x1)
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s.Sub(x2, qx1)
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// t = y2 - q*y1
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qy1.Mul(q, y1)
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t.Sub(y2, qy1)
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// v = u, u = r, x2 = x1, x1 = s, y2 = y1, y1 = t
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v.Set(u)
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u.Set(r)
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x2.Set(x1)
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x1.Set(s)
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y2.Set(y1)
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y1.Set(t)
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// As soon as the remainder is less than the sqrt of n, the
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// values of a1 and b1 are known.
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if !found && r.Cmp(nSqrt) < 0 {
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// When this condition executes ri and ti represent the
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// r[i] and t[i] values such that i is the greatest
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// index for which r >= sqrt(n). Meanwhile, the current
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// r and t values are r[i+1] and t[i+1], respectively.
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// a1 = r[i+1], b1 = -t[i+1]
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a1.Set(r)
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b1.Mul(t, bigMinus1)
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found = true
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oneMore = true
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// Skip to the next iteration so ri and ti are not
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// modified.
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continue
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} else if oneMore {
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// When this condition executes ri and ti still
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// represent the r[i] and t[i] values while the current
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// r and t are r[i+2] and t[i+2], respectively.
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// sum1 = r[i]^2 + t[i]^2
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rSquared := new(big.Int).Mul(ri, ri)
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tSquared := new(big.Int).Mul(ti, ti)
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sum1 := new(big.Int).Add(rSquared, tSquared)
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// sum2 = r[i+2]^2 + t[i+2]^2
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r2Squared := new(big.Int).Mul(r, r)
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t2Squared := new(big.Int).Mul(t, t)
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sum2 := new(big.Int).Add(r2Squared, t2Squared)
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// if (r[i]^2 + t[i]^2) <= (r[i+2]^2 + t[i+2]^2)
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if sum1.Cmp(sum2) <= 0 {
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// a2 = r[i], b2 = -t[i]
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a2.Set(ri)
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b2.Mul(ti, bigMinus1)
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} else {
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// a2 = r[i+2], b2 = -t[i+2]
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a2.Set(r)
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b2.Mul(t, bigMinus1)
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}
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// All done.
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break
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}
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ri.Set(r)
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ti.Set(t)
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}
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return a1, b1, a2, b2
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}
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