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Feat: Eisenstein integers #543

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merged 12 commits into from
Oct 8, 2024
Merged

Feat: Eisenstein integers #543

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2a834f5
feat: implement Eisenstein integers arithmetic
yelhousni Sep 20, 2024
dda7a27
feat: half-GCD for Eisenstein integers
yelhousni Sep 21, 2024
6f69c7e
test: half-GCD test with bigger integers
yelhousni Sep 21, 2024
9b31869
style: clean comments
yelhousni Sep 21, 2024
705a31a
refactor: move eisenstein under field/
yelhousni Sep 24, 2024
7febb56
fix: apply review suggestions
yelhousni Sep 25, 2024
12d53bf
fix: makes linter happy
yelhousni Sep 25, 2024
fa1b905
fix: consider all possible remainders
yelhousni Sep 26, 2024
9a81265
Merge branch 'master' into feat/eisenstein
yelhousni Sep 27, 2024
13fa612
fix: use sqrt in eisenstein halfgcd condition
yelhousni Sep 27, 2024
507de62
perf(eisentein/half-GCD): only 1 remainder option
yelhousni Oct 3, 2024
2e01a9f
refactor: apply review suggestions
yelhousni Oct 3, 2024
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155 changes: 155 additions & 0 deletions field/eisenstein/eisenstein.go
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// The Eisenstein integers form a commutative ring of algebraic integers in the
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// algebraic number field Q(ω) – the third cyclotomic field. These are of the
// form z = a + bω, where a and b are integers and ω is a primitive third root
// of unity i.e. ω²+ω+1 = 0.
package eisenstein

import (
"math/big"
)

// A ComplexNumber represents an arbitrary-precision Eisenstein integer.
type ComplexNumber struct {
A0, A1 big.Int
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}

// String implements Stringer interface for fancy printing
func (z *ComplexNumber) String() string {
return z.A0.String() + "+(" + z.A1.String() + "*ω)"
}

// Equal returns true if z equals x, false otherwise
func (z *ComplexNumber) Equal(x *ComplexNumber) bool {
return z.A0.Cmp(&x.A0) == 0 && z.A1.Cmp(&x.A1) == 0
}

// Set sets z to x, and returns z.
func (z *ComplexNumber) Set(x *ComplexNumber) *ComplexNumber {
z.A0.Set(&x.A0)
z.A1.Set(&x.A1)
return z
}

// SetZero sets z to 0, and returns z.
func (z *ComplexNumber) SetZero() *ComplexNumber {
z.A0 = *big.NewInt(0)
z.A1 = *big.NewInt(0)
return z
}

// SetOne sets z to 1, and returns z.
func (z *ComplexNumber) SetOne() *ComplexNumber {
z.A0 = *big.NewInt(1)
z.A1 = *big.NewInt(0)
return z
}

// Neg sets z to the negative of x, and returns z.
func (z *ComplexNumber) Neg(x *ComplexNumber) *ComplexNumber {
z.A0.Neg(&x.A0)
z.A1.Neg(&x.A1)
return z
}

// Conjugate sets z to the conjugate of x, and returns z.
func (z *ComplexNumber) Conjugate(x *ComplexNumber) *ComplexNumber {
z.A0.Sub(&x.A0, &x.A1)
z.A1.Neg(&x.A1)
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return z
}

// Add sets z to the sum of x and y, and returns z.
func (z *ComplexNumber) Add(x, y *ComplexNumber) *ComplexNumber {
z.A0.Add(&x.A0, &y.A0)
z.A1.Add(&x.A1, &y.A1)
return z
}

// Sub sets z to the difference of x and y, and returns z.
func (z *ComplexNumber) Sub(x, y *ComplexNumber) *ComplexNumber {
z.A0.Sub(&x.A0, &y.A0)
z.A1.Sub(&x.A1, &y.A1)
return z
}

// Mul sets z to the product of x and y, and returns z.
//
// Given that ω²+ω+1=0, the explicit formula is:
//
// (x0+x1ω)(y0+y1ω) = (x0y0-x1y1) + (x0y1+x1y0-x1y1)ω
func (z *ComplexNumber) Mul(x, y *ComplexNumber) *ComplexNumber {
var t [3]big.Int
var z0, z1 big.Int
t[0].Mul(&x.A0, &y.A0)
t[1].Mul(&x.A1, &y.A1)
z0.Sub(&t[0], &t[1])
t[0].Mul(&x.A0, &y.A1)
t[2].Mul(&x.A1, &y.A0)
t[0].Add(&t[0], &t[2])
z1.Sub(&t[0], &t[1])
z.A0.Set(&z0)
z.A1.Set(&z1)
return z
}

// Norm returns the norm of z.
//
// The explicit formula is:
//
// N(x0+x1ω) = x0² + x1² - x0*x1
func (z *ComplexNumber) Norm() *big.Int {
norm := new(big.Int)
temp := new(big.Int)
norm.Add(
norm.Mul(&z.A0, &z.A0),
temp.Mul(&z.A1, &z.A1),
)
norm.Sub(
norm,
temp.Mul(&z.A0, &z.A1),
)
return norm
}

// Quo sets z to the quotient of x and y, and returns z.
func (z *ComplexNumber) Quo(x, y *ComplexNumber) *ComplexNumber {
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norm := y.Norm()
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z.Conjugate(y)
z.Mul(x, z)
z.A0.Div(&z.A0, norm)
z.A1.Div(&z.A1, norm)
return z
}
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// HalfGCD returns the rational reconstruction of a, b.
// This outputs w, v, u s.t. w = a*u + b*v.
func HalfGCD(a, b *ComplexNumber) [3]*ComplexNumber {

var aRun, bRun, u, v, u_, v_, quotient, remainder, t, t1, t2 ComplexNumber

aRun.Set(a)
bRun.Set(b)
u.SetOne()
v.SetZero()
u_.SetZero()
v_.SetOne()
nbits := a.Norm().BitLen() / 2

for aRun.Norm().BitLen() > nbits {
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quotient.Quo(&aRun, &bRun)
t.Mul(&bRun, &quotient)
remainder.Sub(&aRun, &t)
t.Mul(&u_, &quotient)
t1.Sub(&u, &t)
t.Mul(&v_, &quotient)
t2.Sub(&v, &t)
aRun.Set(&bRun)
u.Set(&u_)
v.Set(&v_)
bRun.Set(&remainder)
u_.Set(&t1)
v_.Set(&t2)
}

return [3]*ComplexNumber{&aRun, &v, &u}
}
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