status-go/vendor/github.com/kilic/bls12-381/fp2.go

package bls12381

import (
	"errors"
	"math/big"
)

type fp2Temp struct {
	t [4]*fe
}

type fp2 struct {
	fp2Temp
}

func newFp2Temp() fp2Temp {
	t := [4]*fe{}
	for i := 0; i < len(t); i++ {
		t[i] = &fe{}
	}
	return fp2Temp{t}
}

func newFp2() *fp2 {
	t := newFp2Temp()
	return &fp2{t}
}

func (e *fp2) fromBytes(in []byte) (*fe2, error) {
	if len(in) != 96 {
		return nil, errors.New("input string should be larger than 96 bytes")
	}
	c1, err := fromBytes(in[:48])
	if err != nil {
		return nil, err
	}
	c0, err := fromBytes(in[48:])
	if err != nil {
		return nil, err
	}
	return &fe2{*c0, *c1}, nil
}

func (e *fp2) toBytes(a *fe2) []byte {
	out := make([]byte, 96)
	copy(out[:48], toBytes(&a[1]))
	copy(out[48:], toBytes(&a[0]))
	return out
}

func (e *fp2) new() *fe2 {
	return new(fe2).zero()
}

func (e *fp2) zero() *fe2 {
	return new(fe2).zero()
}

func (e *fp2) one() *fe2 {
	return new(fe2).one()
}

func (e *fp2) fromMont(c, a *fe2) {
	fromMont(&c[0], &a[0])
	fromMont(&c[1], &a[1])
}

func (e *fp2) add(c, a, b *fe2) {
	add(&c[0], &a[0], &b[0])
	add(&c[1], &a[1], &b[1])
}

func (e *fp2) addAssign(a, b *fe2) {
	addAssign(&a[0], &b[0])
	addAssign(&a[1], &b[1])
}

func (e *fp2) ladd(c, a, b *fe2) {
	ladd(&c[0], &a[0], &b[0])
	ladd(&c[1], &a[1], &b[1])
}

func (e *fp2) double(c, a *fe2) {
	double(&c[0], &a[0])
	double(&c[1], &a[1])
}

func (e *fp2) doubleAssign(a *fe2) {
	doubleAssign(&a[0])
	doubleAssign(&a[1])
}

func (e *fp2) ldouble(c, a *fe2) {
	ldouble(&c[0], &a[0])
	ldouble(&c[1], &a[1])
}

func (e *fp2) sub(c, a, b *fe2) {
	sub(&c[0], &a[0], &b[0])
	sub(&c[1], &a[1], &b[1])
}

func (e *fp2) subAssign(c, a *fe2) {
	subAssign(&c[0], &a[0])
	subAssign(&c[1], &a[1])
}

func (e *fp2) neg(c, a *fe2) {
	neg(&c[0], &a[0])
	neg(&c[1], &a[1])
}

func (e *fp2) conjugate(c, a *fe2) {
	c[0].set(&a[0])
	neg(&c[1], &a[1])
}

func (e *fp2) mul(c, a, b *fe2) {
	t := e.t
	mul(t[1], &a[0], &b[0])
	mul(t[2], &a[1], &b[1])
	add(t[0], &a[0], &a[1])
	add(t[3], &b[0], &b[1])
	sub(&c[0], t[1], t[2])
	addAssign(t[1], t[2])
	mul(t[0], t[0], t[3])
	sub(&c[1], t[0], t[1])
}

func (e *fp2) mulAssign(a, b *fe2) {
	t := e.t
	mul(t[1], &a[0], &b[0])
	mul(t[2], &a[1], &b[1])
	add(t[0], &a[0], &a[1])
	add(t[3], &b[0], &b[1])
	sub(&a[0], t[1], t[2])
	addAssign(t[1], t[2])
	mul(t[0], t[0], t[3])
	sub(&a[1], t[0], t[1])
}

func (e *fp2) square(c, a *fe2) {
	t := e.t
	ladd(t[0], &a[0], &a[1])
	sub(t[1], &a[0], &a[1])
	ldouble(t[2], &a[0])
	mul(&c[0], t[0], t[1])
	mul(&c[1], t[2], &a[1])
}

func (e *fp2) squareAssign(a *fe2) {
	t := e.t
	ladd(t[0], &a[0], &a[1])
	sub(t[1], &a[0], &a[1])
	ldouble(t[2], &a[0])
	mul(&a[0], t[0], t[1])
	mul(&a[1], t[2], &a[1])
}

func (e *fp2) mulByNonResidue(c, a *fe2) {
	t := e.t
	sub(t[0], &a[0], &a[1])
	add(&c[1], &a[0], &a[1])
	c[0].set(t[0])
}

func (e *fp2) mulByB(c, a *fe2) {
	t := e.t
	double(t[0], &a[0])
	double(t[1], &a[1])
	doubleAssign(t[0])
	doubleAssign(t[1])
	sub(&c[0], t[0], t[1])
	add(&c[1], t[0], t[1])
}

func (e *fp2) inverse(c, a *fe2) {
	t := e.t
	square(t[0], &a[0])
	square(t[1], &a[1])
	addAssign(t[0], t[1])
	inverse(t[0], t[0])
	mul(&c[0], &a[0], t[0])
	mul(t[0], t[0], &a[1])
	neg(&c[1], t[0])
}

func (e *fp2) mulByFq(c, a *fe2, b *fe) {
	mul(&c[0], &a[0], b)
	mul(&c[1], &a[1], b)
}

func (e *fp2) exp(c, a *fe2, s *big.Int) {
	z := e.one()
	for i := s.BitLen() - 1; i >= 0; i-- {
		e.square(z, z)
		if s.Bit(i) == 1 {
			e.mul(z, z, a)
		}
	}
	c.set(z)
}

func (e *fp2) frobeniousMap(c, a *fe2, power uint) {
	c[0].set(&a[0])
	if power%2 == 1 {
		neg(&c[1], &a[1])
		return
	}
	c[1].set(&a[1])
}

func (e *fp2) frobeniousMapAssign(a *fe2, power uint) {
	if power%2 == 1 {
		neg(&a[1], &a[1])
		return
	}
}

func (e *fp2) sqrt(c, a *fe2) bool {
	u, x0, a1, alpha := &fe2{}, &fe2{}, &fe2{}, &fe2{}
	u.set(a)
	e.exp(a1, a, pMinus3Over4)
	e.square(alpha, a1)
	e.mul(alpha, alpha, a)
	e.mul(x0, a1, a)
	if alpha.equal(negativeOne2) {
		neg(&c[0], &x0[1])
		c[1].set(&x0[0])
		return true
	}
	e.add(alpha, alpha, e.one())
	e.exp(alpha, alpha, pMinus1Over2)
	e.mul(c, alpha, x0)
	e.square(alpha, c)
	return alpha.equal(u)
}

func (e *fp2) isQuadraticNonResidue(a *fe2) bool {
	c0, c1 := new(fe), new(fe)
	square(c0, &a[0])
	square(c1, &a[1])
	add(c1, c1, c0)
	return isQuadraticNonResidue(c1)
}
Feature/key compression (#1990) ## What has changed? I've introduced to the public binding functionality that will compress and decompress public keys of a variety of encoding and key types. This functionality supports all major byte encoding formats and the following EC public key types: - `secp256k1` pks - `bls12-381 g1` pks - `bls12-381 g2` pks ## Why make the change? We want shorter public (chat) keys and we want to be future proof and encoding agnostic. See the issue here https://github.com/status-im/status-go/issues/1937 --- * Added basic signature for compresspk and uncompresspk * Added basic encoding information * make vendor * formatted imports for the linter * Reformatted imports hoping linter likes it * This linter is capricious * Added check that the secp256k1 key is valid * Added test for valid key * Added multiformat/go-varint dep * Added public key type handling * Added key decompression with key type handling * Added handling for '0x' type indentifying * Added more robust testing * Less lint for the linting gods * make vendor for bls12_381 * Added bls12-381 compression tests * Added decompress key expected results * Refactor of typed and untyped keys in tests * Lint god appeasment * Refactor of sample public keys * Implemented bls12-381 decompression * gofmt * Renamed decode/encode funcs to be more descriptive * Added binary bindings for key de/compression * Refactor of func parameters gomobile is a bit tempermental using raw bytes as a parameter, so I've decided to use string only inputs and outputs * gofmt * Added function documentation * Moved multiformat de/compression into api/multiformat ns * Moved multiformat de/compression into api/multiformat ns * Changed compress to serialize on API 2020-06-23 10:47:17 +00:00			`package bls12381`

			`import (`
			`"errors"`
			`"math/big"`
			`)`

			`type fp2Temp struct {`
			`t [4]*fe`
			`}`

			`type fp2 struct {`
			`fp2Temp`
			`}`

			`func newFp2Temp() fp2Temp {`
			`t := [4]*fe{}`
			`for i := 0; i < len(t); i++ {`
			`t[i] = &fe{}`
			`}`
			`return fp2Temp{t}`
			`}`

			`func newFp2() *fp2 {`
			`t := newFp2Temp()`
			`return &fp2{t}`
			`}`

			`func (e fp2) fromBytes(in []byte) (fe2, error) {`
			`if len(in) != 96 {`
			`return nil, errors.New("input string should be larger than 96 bytes")`
			`}`
			`c1, err := fromBytes(in[:48])`
			`if err != nil {`
			`return nil, err`
			`}`
			`c0, err := fromBytes(in[48:])`
			`if err != nil {`
			`return nil, err`
			`}`
			`return &fe2{c0, c1}, nil`
			`}`

			`func (e fp2) toBytes(a fe2) []byte {`
			`out := make([]byte, 96)`
			`copy(out[:48], toBytes(&a[1]))`
			`copy(out[48:], toBytes(&a[0]))`
			`return out`
			`}`

			`func (e fp2) new() fe2 {`
			`return new(fe2).zero()`
			`}`

			`func (e fp2) zero() fe2 {`
			`return new(fe2).zero()`
			`}`

			`func (e fp2) one() fe2 {`
			`return new(fe2).one()`
			`}`

			`func (e fp2) fromMont(c, a fe2) {`
			`fromMont(&c[0], &a[0])`
			`fromMont(&c[1], &a[1])`
			`}`

			`func (e fp2) add(c, a, b fe2) {`
			`add(&c[0], &a[0], &b[0])`
			`add(&c[1], &a[1], &b[1])`
			`}`

			`func (e fp2) addAssign(a, b fe2) {`
			`addAssign(&a[0], &b[0])`
			`addAssign(&a[1], &b[1])`
			`}`

			`func (e fp2) ladd(c, a, b fe2) {`
			`ladd(&c[0], &a[0], &b[0])`
			`ladd(&c[1], &a[1], &b[1])`
			`}`

			`func (e fp2) double(c, a fe2) {`
			`double(&c[0], &a[0])`
			`double(&c[1], &a[1])`
			`}`

			`func (e fp2) doubleAssign(a fe2) {`
			`doubleAssign(&a[0])`
			`doubleAssign(&a[1])`
			`}`

			`func (e fp2) ldouble(c, a fe2) {`
			`ldouble(&c[0], &a[0])`
			`ldouble(&c[1], &a[1])`
			`}`

			`func (e fp2) sub(c, a, b fe2) {`
			`sub(&c[0], &a[0], &b[0])`
			`sub(&c[1], &a[1], &b[1])`
			`}`

			`func (e fp2) subAssign(c, a fe2) {`
			`subAssign(&c[0], &a[0])`
			`subAssign(&c[1], &a[1])`
			`}`

			`func (e fp2) neg(c, a fe2) {`
			`neg(&c[0], &a[0])`
			`neg(&c[1], &a[1])`
			`}`

			`func (e fp2) conjugate(c, a fe2) {`
			`c[0].set(&a[0])`
			`neg(&c[1], &a[1])`
			`}`

			`func (e fp2) mul(c, a, b fe2) {`
			`t := e.t`
			`mul(t[1], &a[0], &b[0])`
			`mul(t[2], &a[1], &b[1])`
			`add(t[0], &a[0], &a[1])`
			`add(t[3], &b[0], &b[1])`
			`sub(&c[0], t[1], t[2])`
			`addAssign(t[1], t[2])`
			`mul(t[0], t[0], t[3])`
			`sub(&c[1], t[0], t[1])`
			`}`

			`func (e fp2) mulAssign(a, b fe2) {`
			`t := e.t`
			`mul(t[1], &a[0], &b[0])`
			`mul(t[2], &a[1], &b[1])`
			`add(t[0], &a[0], &a[1])`
			`add(t[3], &b[0], &b[1])`
			`sub(&a[0], t[1], t[2])`
			`addAssign(t[1], t[2])`
			`mul(t[0], t[0], t[3])`
			`sub(&a[1], t[0], t[1])`
			`}`

			`func (e fp2) square(c, a fe2) {`
			`t := e.t`
			`ladd(t[0], &a[0], &a[1])`
			`sub(t[1], &a[0], &a[1])`
			`ldouble(t[2], &a[0])`
			`mul(&c[0], t[0], t[1])`
			`mul(&c[1], t[2], &a[1])`
			`}`

			`func (e fp2) squareAssign(a fe2) {`
			`t := e.t`
			`ladd(t[0], &a[0], &a[1])`
			`sub(t[1], &a[0], &a[1])`
			`ldouble(t[2], &a[0])`
			`mul(&a[0], t[0], t[1])`
			`mul(&a[1], t[2], &a[1])`
			`}`

			`func (e fp2) mulByNonResidue(c, a fe2) {`
			`t := e.t`
			`sub(t[0], &a[0], &a[1])`
			`add(&c[1], &a[0], &a[1])`
			`c[0].set(t[0])`
			`}`

			`func (e fp2) mulByB(c, a fe2) {`
			`t := e.t`
			`double(t[0], &a[0])`
			`double(t[1], &a[1])`
			`doubleAssign(t[0])`
			`doubleAssign(t[1])`
			`sub(&c[0], t[0], t[1])`
			`add(&c[1], t[0], t[1])`
			`}`

			`func (e fp2) inverse(c, a fe2) {`
			`t := e.t`
			`square(t[0], &a[0])`
			`square(t[1], &a[1])`
			`addAssign(t[0], t[1])`
			`inverse(t[0], t[0])`
			`mul(&c[0], &a[0], t[0])`
			`mul(t[0], t[0], &a[1])`
			`neg(&c[1], t[0])`
			`}`

			`func (e fp2) mulByFq(c, a fe2, b *fe) {`
			`mul(&c[0], &a[0], b)`
			`mul(&c[1], &a[1], b)`
			`}`

			`func (e fp2) exp(c, a fe2, s *big.Int) {`
			`z := e.one()`
			`for i := s.BitLen() - 1; i >= 0; i-- {`
			`e.square(z, z)`
			`if s.Bit(i) == 1 {`
			`e.mul(z, z, a)`
			`}`
			`}`
			`c.set(z)`
			`}`

			`func (e fp2) frobeniousMap(c, a fe2, power uint) {`
			`c[0].set(&a[0])`
			`if power%2 == 1 {`
			`neg(&c[1], &a[1])`
			`return`
			`}`
			`c[1].set(&a[1])`
			`}`

			`func (e fp2) frobeniousMapAssign(a fe2, power uint) {`
			`if power%2 == 1 {`
			`neg(&a[1], &a[1])`
			`return`
			`}`
			`}`

			`func (e fp2) sqrt(c, a fe2) bool {`
			`u, x0, a1, alpha := &fe2{}, &fe2{}, &fe2{}, &fe2{}`
			`u.set(a)`
			`e.exp(a1, a, pMinus3Over4)`
			`e.square(alpha, a1)`
			`e.mul(alpha, alpha, a)`
			`e.mul(x0, a1, a)`
			`if alpha.equal(negativeOne2) {`
			`neg(&c[0], &x0[1])`
			`c[1].set(&x0[0])`
			`return true`
			`}`
			`e.add(alpha, alpha, e.one())`
			`e.exp(alpha, alpha, pMinus1Over2)`
			`e.mul(c, alpha, x0)`
			`e.square(alpha, c)`
			`return alpha.equal(u)`
			`}`

			`func (e fp2) isQuadraticNonResidue(a fe2) bool {`
			`c0, c1 := new(fe), new(fe)`
			`square(c0, &a[0])`
			`square(c1, &a[1])`
			`add(c1, c1, c0)`
			`return isQuadraticNonResidue(c1)`
			`}`