mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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575 lines
13 KiB
Go
575 lines
13 KiB
Go
//
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// Copyright (c) 2019 harmony-one
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//
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// SPDX-License-Identifier: MIT
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//
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package iqc
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import (
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"math/big"
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)
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type ClassGroup struct {
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a *big.Int
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b *big.Int
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c *big.Int
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d *big.Int
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}
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func NewClassGroup(a, b, c *big.Int) *ClassGroup {
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return &ClassGroup{a: a, b: b, c: c}
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}
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func (cg *ClassGroup) Clone() *ClassGroup {
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return &ClassGroup{a: cg.a, b: cg.b, c: cg.c}
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}
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func NewClassGroupFromAbDiscriminant(a, b, discriminant *big.Int) *ClassGroup {
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//z = b*b-discriminant
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z := new(big.Int).Sub(new(big.Int).Mul(b, b), discriminant)
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//z = z // 4a
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c := FloorDivision(z, new(big.Int).Mul(a, big.NewInt(4)))
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return NewClassGroup(a, b, c)
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}
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func NewClassGroupFromBytesDiscriminant(buf []byte, discriminant *big.Int) (*ClassGroup, bool) {
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int_size_bits := discriminant.BitLen()
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//add additional one byte for sign
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int_size := (int_size_bits + 16) >> 4
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//make sure the input byte buffer size matches with discriminant's
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if len(buf) != int_size*2 {
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return nil, false
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}
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a := decodeTwosComplement(buf[:int_size])
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b := decodeTwosComplement(buf[int_size:])
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if a.Cmp(big.NewInt(0)) == 0 {
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return nil, false
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}
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return NewClassGroupFromAbDiscriminant(a, b, discriminant), true
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}
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func IdentityForDiscriminant(d *big.Int) *ClassGroup {
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return NewClassGroupFromAbDiscriminant(big.NewInt(1), big.NewInt(1), d)
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}
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func (group *ClassGroup) Normalized() *ClassGroup {
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a := new(big.Int).Set(group.a)
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b := new(big.Int).Set(group.b)
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c := new(big.Int).Set(group.c)
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//if b > -a && b <= a:
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if (b.Cmp(new(big.Int).Neg(a)) == 1) && (b.Cmp(a) < 1) {
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return group
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}
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//r = (a - b) // (2 * a)
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r := new(big.Int).Sub(a, b)
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r = FloorDivision(r, new(big.Int).Mul(a, big.NewInt(2)))
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//b, c = b + 2 * r * a, a * r * r + b * r + c
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t := new(big.Int).Mul(big.NewInt(2), r)
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t.Mul(t, a)
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oldB := new(big.Int).Set(b)
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b.Add(b, t)
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x := new(big.Int).Mul(a, r)
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x.Mul(x, r)
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y := new(big.Int).Mul(oldB, r)
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c.Add(c, x)
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c.Add(c, y)
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return NewClassGroup(a, b, c)
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}
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func (group *ClassGroup) Reduced() *ClassGroup {
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g := group.Normalized()
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a := new(big.Int).Set(g.a)
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b := new(big.Int).Set(g.b)
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c := new(big.Int).Set(g.c)
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//while a > c or (a == c and b < 0):
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for (a.Cmp(c) == 1) || ((a.Cmp(c) == 0) && (b.Sign() == -1)) {
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//s = (c + b) // (c + c)
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s := new(big.Int).Add(c, b)
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s = FloorDivision(s, new(big.Int).Add(c, c))
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//a, b, c = c, -b + 2 * s * c, c * s * s - b * s + a
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oldA := new(big.Int).Set(a)
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oldB := new(big.Int).Set(b)
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a = new(big.Int).Set(c)
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b.Neg(b)
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x := new(big.Int).Mul(big.NewInt(2), s)
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x.Mul(x, c)
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b.Add(b, x)
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c.Mul(c, s)
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c.Mul(c, s)
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oldB.Mul(oldB, s)
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c.Sub(c, oldB)
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c.Add(c, oldA)
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}
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return NewClassGroup(a, b, c).Normalized()
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}
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func (group *ClassGroup) identity() *ClassGroup {
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return NewClassGroupFromAbDiscriminant(big.NewInt(1), big.NewInt(1), group.Discriminant())
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}
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func (group *ClassGroup) Discriminant() *big.Int {
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if group.d == nil {
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d := new(big.Int).Set(group.b)
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d.Mul(d, d)
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a := new(big.Int).Set(group.a)
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a.Mul(a, group.c)
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a.Mul(a, big.NewInt(4))
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d.Sub(d, a)
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group.d = d
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}
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return group.d
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}
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func (group *ClassGroup) Multiply(other *ClassGroup) *ClassGroup {
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//a1, b1, c1 = self.reduced()
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x := group.Reduced()
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//a2, b2, c2 = other.reduced()
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y := other.Reduced()
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//g = (b2 + b1) // 2
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g := new(big.Int).Add(x.b, y.b)
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g = FloorDivision(g, big.NewInt(2))
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//h = (b2 - b1) // 2
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h := new(big.Int).Sub(y.b, x.b)
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h = FloorDivision(h, big.NewInt(2))
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//w = mod.gcd(a1, a2, g)
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w1 := allInputValueGCD(y.a, g)
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w := allInputValueGCD(x.a, w1)
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//j = w
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j := new(big.Int).Set(w)
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//r = 0
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r := big.NewInt(0)
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//s = a1 // w
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s := FloorDivision(x.a, w)
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//t = a2 // w
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t := FloorDivision(y.a, w)
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//u = g // w
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u := FloorDivision(g, w)
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//k_temp, constant_factor = mod.solve_mod(t * u, h * u + s * c1, s * t)
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b := new(big.Int).Mul(h, u)
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sc := new(big.Int).Mul(s, x.c)
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b.Add(b, sc)
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k_temp, constant_factor, solvable := SolveMod(new(big.Int).Mul(t, u), b, new(big.Int).Mul(s, t))
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if !solvable {
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return nil
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}
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//n, constant_factor_2 = mod.solve_mod(t * constant_factor, h - t * k_temp, s)
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n, _, solvable := SolveMod(new(big.Int).Mul(t, constant_factor), new(big.Int).Sub(h, new(big.Int).Mul(t, k_temp)), s)
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if !solvable {
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return nil
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}
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//k = k_temp + constant_factor * n
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k := new(big.Int).Add(k_temp, new(big.Int).Mul(constant_factor, n))
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//l = (t * k - h) // s
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l := FloorDivision(new(big.Int).Sub(new(big.Int).Mul(t, k), h), s)
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//m = (t * u * k - h * u - s * c1) // (s * t)
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tuk := new(big.Int).Mul(t, u)
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tuk.Mul(tuk, k)
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hu := new(big.Int).Mul(h, u)
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tuk.Sub(tuk, hu)
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tuk.Sub(tuk, sc)
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st := new(big.Int).Mul(s, t)
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m := FloorDivision(tuk, st)
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//a3 = s * t - r * u
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ru := new(big.Int).Mul(r, u)
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a3 := st.Sub(st, ru)
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//b3 = (j * u + m * r) - (k * t + l * s)
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ju := new(big.Int).Mul(j, u)
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mr := new(big.Int).Mul(m, r)
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ju = ju.Add(ju, mr)
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kt := new(big.Int).Mul(k, t)
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ls := new(big.Int).Mul(l, s)
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kt = kt.Add(kt, ls)
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b3 := ju.Sub(ju, kt)
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//c3 = k * l - j * m
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kl := new(big.Int).Mul(k, l)
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jm := new(big.Int).Mul(j, m)
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c3 := kl.Sub(kl, jm)
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return NewClassGroup(a3, b3, c3).Reduced()
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}
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func (group *ClassGroup) Pow(n int64) *ClassGroup {
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x := group.Clone()
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items_prod := group.identity()
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for n > 0 {
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if n&1 == 1 {
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items_prod = items_prod.Multiply(x)
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if items_prod == nil {
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return nil
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}
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}
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x = x.Square()
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if x == nil {
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return nil
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}
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n >>= 1
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}
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return items_prod
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}
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func (group *ClassGroup) BigPow(n *big.Int) *ClassGroup {
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x := group.Clone()
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items_prod := group.identity()
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p := new(big.Int).Set(n)
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for p.Sign() > 0 {
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if p.Bit(0) == 1 {
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items_prod = items_prod.Multiply(x)
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if items_prod == nil {
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return nil
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}
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}
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x = x.Square()
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if x == nil {
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return nil
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}
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p.Rsh(p, 1)
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}
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return items_prod
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}
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func (group *ClassGroup) Square() *ClassGroup {
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u, _, solvable := SolveMod(group.b, group.c, group.a)
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if !solvable {
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return nil
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}
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//A = a
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A := new(big.Int).Mul(group.a, group.a)
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//B = b − 2aµ,
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au := new(big.Int).Mul(group.a, u)
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B := new(big.Int).Sub(group.b, new(big.Int).Mul(au, big.NewInt(2)))
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//C = µ ^ 2 - (bµ−c)//a
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C := new(big.Int).Mul(u, u)
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m := new(big.Int).Mul(group.b, u)
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m = new(big.Int).Sub(m, group.c)
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m = FloorDivision(m, group.a)
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C = new(big.Int).Sub(C, m)
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return NewClassGroup(A, B, C).Reduced()
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}
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func (group *ClassGroup) SquareUsingMultiply() *ClassGroup {
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//a1, b1, c1 = self.reduced()
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x := group.Reduced()
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//g = b1
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g := x.b
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//h = 0
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h := big.NewInt(0)
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//w = mod.gcd(a1, g)
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w := allInputValueGCD(x.a, g)
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//j = w
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j := new(big.Int).Set(w)
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//r = 0
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r := big.NewInt(0)
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//s = a1 // w
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s := FloorDivision(x.a, w)
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//t = s
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t := s
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//u = g // w
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u := FloorDivision(g, w)
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//k_temp, constant_factor = mod.solve_mod(t * u, h * u + s * c1, s * t)
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b := new(big.Int).Mul(h, u)
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sc := new(big.Int).Mul(s, x.c)
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b.Add(b, sc)
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k_temp, constant_factor, solvable := SolveMod(new(big.Int).Mul(t, u), b, new(big.Int).Mul(s, t))
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if !solvable {
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return nil
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}
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//n, constant_factor_2 = mod.solve_mod(t * constant_factor, h - t * k_temp, s)
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n, _, solvable := SolveMod(new(big.Int).Mul(t, constant_factor), new(big.Int).Sub(h, new(big.Int).Mul(t, k_temp)), s)
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if !solvable {
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return nil
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}
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//k = k_temp + constant_factor * n
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k := new(big.Int).Add(k_temp, new(big.Int).Mul(constant_factor, n))
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//l = (t * k - h) // s
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l := FloorDivision(new(big.Int).Sub(new(big.Int).Mul(t, k), h), s)
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//m = (t * u * k - h * u - s * c1) // (s * t)
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tuk := new(big.Int).Mul(t, u)
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tuk.Mul(tuk, k)
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hu := new(big.Int).Mul(h, u)
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tuk.Sub(tuk, hu)
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tuk.Sub(tuk, sc)
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st := new(big.Int).Mul(s, t)
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m := FloorDivision(tuk, st)
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//a3 = s * t - r * u
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ru := new(big.Int).Mul(r, u)
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a3 := st.Sub(st, ru)
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//b3 = (j * u + m * r) - (k * t + l * s)
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ju := new(big.Int).Mul(j, u)
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mr := new(big.Int).Mul(m, r)
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ju = ju.Add(ju, mr)
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kt := new(big.Int).Mul(k, t)
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ls := new(big.Int).Mul(l, s)
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kt = kt.Add(kt, ls)
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b3 := ju.Sub(ju, kt)
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//c3 = k * l - j * m
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kl := new(big.Int).Mul(k, l)
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jm := new(big.Int).Mul(j, m)
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c3 := kl.Sub(kl, jm)
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return NewClassGroup(a3, b3, c3).Reduced()
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}
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// Serialize encodes a, b based on discriminant's size
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// using one more byte for sign if nessesary
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func (group *ClassGroup) Serialize() []byte {
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r := group.Reduced()
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int_size_bits := group.Discriminant().BitLen()
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int_size := (int_size_bits + 16) >> 4
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buf := make([]byte, int_size*2)
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copy(buf[:int_size], signBitFill(encodeTwosComplement(r.a), int_size))
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copy(buf[int_size:], signBitFill(encodeTwosComplement(r.b), int_size))
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return buf
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}
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func (group *ClassGroup) Equal(other *ClassGroup) bool {
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g := group.Reduced()
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o := other.Reduced()
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return (g.a.Cmp(o.a) == 0 && g.b.Cmp(o.b) == 0 && g.c.Cmp(o.c) == 0)
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}
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func FloorDivision(x, y *big.Int) *big.Int {
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var r big.Int
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q, _ := new(big.Int).QuoRem(x, y, &r)
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if (r.Sign() == 1 && y.Sign() == -1) || (r.Sign() == -1 && y.Sign() == 1) {
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q.Sub(q, big.NewInt(1))
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}
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return q
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}
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var bigOne = big.NewInt(1)
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func decodeTwosComplement(bytes []byte) *big.Int {
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if bytes[0]&0x80 == 0 {
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// non-negative
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return new(big.Int).SetBytes(bytes)
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}
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setyb := make([]byte, len(bytes))
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for i := range bytes {
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setyb[i] = bytes[i] ^ 0xff
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}
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n := new(big.Int).SetBytes(setyb)
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return n.Sub(n.Neg(n), bigOne)
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}
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func encodeTwosComplement(n *big.Int) []byte {
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if n.Sign() > 0 {
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bytes := n.Bytes()
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if bytes[0]&0x80 == 0 {
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return bytes
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}
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// add one more byte for positive sign
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buf := make([]byte, len(bytes)+1)
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copy(buf[1:], bytes)
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return buf
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}
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if n.Sign() < 0 {
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// A negative number has to be converted to two's-complement form. So we
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// invert and subtract 1. If the most-significant-bit isn't set then
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// we'll need to pad the beginning with 0xff in order to keep the number
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// negative.
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nMinus1 := new(big.Int).Neg(n)
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nMinus1.Sub(nMinus1, bigOne)
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bytes := nMinus1.Bytes()
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if len(bytes) == 0 {
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// sneaky -1 value
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return []byte{0xff}
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}
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for i := range bytes {
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bytes[i] ^= 0xff
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}
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if bytes[0]&0x80 != 0 {
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return bytes
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}
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// add one more byte for negative sign
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buf := make([]byte, len(bytes)+1)
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buf[0] = 0xff
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copy(buf[1:], bytes)
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return buf
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}
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return []byte{}
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}
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func signBitFill(bytes []byte, targetLen int) []byte {
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if len(bytes) >= targetLen {
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return bytes
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}
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buf := make([]byte, targetLen)
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offset := targetLen - len(bytes)
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if bytes[0]&0x80 != 0 {
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for i := 0; i < offset; i++ {
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buf[i] = 0xff
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}
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}
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copy(buf[offset:], bytes)
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return buf
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}
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func EncodeBigIntBigEndian(a *big.Int) []byte {
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int_size_bits := a.BitLen()
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int_size := (int_size_bits + 16) >> 3
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return signBitFill(encodeTwosComplement(a), int_size)
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}
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// Return r, s, t such that gcd(a, b) = r = a * s + b * t
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func extendedGCD(a, b *big.Int) (r, s, t *big.Int) {
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//r0, r1 = a, b
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r0 := new(big.Int).Set(a)
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r1 := new(big.Int).Set(b)
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//s0, s1, t0, t1 = 1, 0, 0, 1
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s0 := big.NewInt(1)
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s1 := big.NewInt(0)
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t0 := big.NewInt(0)
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t1 := big.NewInt(1)
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//if r0 > r1:
|
||
//r0, r1, s0, s1, t0, t1 = r1, r0, t0, t1, s0, s1
|
||
if r0.Cmp(r1) == 1 {
|
||
oldR0 := new(big.Int).Set(r0)
|
||
r0 = r1
|
||
r1 = oldR0
|
||
oldS0 := new(big.Int).Set(s0)
|
||
s0 = t0
|
||
oldS1 := new(big.Int).Set(s1)
|
||
s1 = t1
|
||
t0 = oldS0
|
||
t1 = oldS1
|
||
}
|
||
|
||
//while r1 > 0:
|
||
for r1.Sign() == 1 {
|
||
//q, r = divmod(r0, r1)
|
||
r := big.NewInt(1)
|
||
bb := new(big.Int).Set(b)
|
||
q, r := bb.DivMod(r0, r1, r)
|
||
|
||
//r0, r1, s0, s1, t0, t1 = r1, r, s1, s0 - q * s1, t1, t0 - q * t1
|
||
r0 = r1
|
||
r1 = r
|
||
oldS0 := new(big.Int).Set(s0)
|
||
s0 = s1
|
||
s1 = new(big.Int).Sub(oldS0, new(big.Int).Mul(q, s1))
|
||
oldT0 := new(big.Int).Set(t0)
|
||
t0 = t1
|
||
t1 = new(big.Int).Sub(oldT0, new(big.Int).Mul(q, t1))
|
||
|
||
}
|
||
return r0, s0, t0
|
||
}
|
||
|
||
// wrapper around big.Int GCD to allow all input values for GCD
|
||
// as Golang big.Int GCD requires both a, b > 0
|
||
// If a == b == 0, GCD sets r = 0.
|
||
// If a == 0 and b != 0, GCD sets r = |b|
|
||
// If a != 0 and b == 0, GCD sets r = |a|
|
||
// Otherwise r = GCD(|a|, |b|)
|
||
func allInputValueGCD(a, b *big.Int) (r *big.Int) {
|
||
if a.Sign() == 0 {
|
||
return new(big.Int).Abs(b)
|
||
}
|
||
|
||
if b.Sign() == 0 {
|
||
return new(big.Int).Abs(a)
|
||
}
|
||
|
||
return new(big.Int).GCD(nil, nil, new(big.Int).Abs(a), new(big.Int).Abs(b))
|
||
}
|
||
|
||
// Solve ax == b mod m for x.
|
||
// Return s, t where x = s + k * t for integer k yields all solutions.
|
||
func SolveMod(a, b, m *big.Int) (s, t *big.Int, solvable bool) {
|
||
//g, d, e = extended_gcd(a, m)
|
||
//TODO: golang 1.x big.int GCD requires both a > 0 and m > 0, so we can't use it :(
|
||
//d := big.NewInt(0)
|
||
//e := big.NewInt(0)
|
||
//g := new(big.Int).GCD(d, e, a, m)
|
||
g, d, _ := extendedGCD(a, m)
|
||
if g.Cmp(big.NewInt(0)) == 0 {
|
||
return nil, nil, false
|
||
}
|
||
|
||
//q, r = divmod(b, g)
|
||
r := big.NewInt(1)
|
||
bb := new(big.Int).Set(b)
|
||
q, r := bb.DivMod(b, g, r)
|
||
|
||
//TODO: replace with utils.GetLogInstance().Error(...)
|
||
//if r != 0:
|
||
if r.Cmp(big.NewInt(0)) != 0 {
|
||
//panic(fmt.Sprintf("no solution to %s x = %s mod %s", a.String(), b.String(), m.String()))
|
||
return nil, nil, false
|
||
}
|
||
|
||
//assert b == q * g
|
||
//return (q * d) % m, m // g
|
||
q.Mul(q, d)
|
||
s = q.Mod(q, m)
|
||
t = FloorDivision(m, g)
|
||
return s, t, true
|
||
}
|