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pedersen.go
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pedersen.go
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//
// Copyright Coinbase, Inc. All Rights Reserved.
//
// SPDX-License-Identifier: Apache-2.0
//
package sharing
import (
"fmt"
"io"
"github.com/coinbase/kryptology/pkg/core/curves"
)
// Pedersen Verifiable Secret Sharing Scheme
type Pedersen struct {
threshold, limit uint32
curve *curves.Curve
generator curves.Point
}
type PedersenVerifier struct {
Generator curves.Point
Commitments []curves.Point
}
func (pv PedersenVerifier) Verify(share, blindShare *ShamirShare) error {
curve := curves.GetCurveByName(pv.Generator.CurveName())
if err := share.Validate(curve); err != nil {
return err
}
if err := blindShare.Validate(curve); err != nil {
return err
}
x := curve.Scalar.New(int(share.Id))
i := curve.Scalar.One()
rhs := pv.Commitments[0]
for j := 1; j < len(pv.Commitments); j++ {
i = i.Mul(x)
rhs = rhs.Add(pv.Commitments[j].Mul(i))
}
sc, _ := curve.Scalar.SetBytes(share.Value)
bsc, _ := curve.Scalar.SetBytes(blindShare.Value)
g := pv.Commitments[0].Generator().Mul(sc)
h := pv.Generator.Mul(bsc)
lhs := g.Add(h)
if lhs.Equal(rhs) {
return nil
} else {
return fmt.Errorf("not equal")
}
}
// PedersenResult contains all the data from calling Split
type PedersenResult struct {
Blinding curves.Scalar
BlindingShares, SecretShares []*ShamirShare
FeldmanVerifier *FeldmanVerifier
PedersenVerifier *PedersenVerifier
}
// NewPedersen creates a new pedersen VSS
func NewPedersen(threshold, limit uint32, generator curves.Point) (*Pedersen, error) {
if limit < threshold {
return nil, fmt.Errorf("limit cannot be less than threshold")
}
if threshold < 2 {
return nil, fmt.Errorf("threshold cannot be less than 2")
}
if limit > 255 {
return nil, fmt.Errorf("cannot exceed 255 shares")
}
curve := curves.GetCurveByName(generator.CurveName())
if curve == nil {
return nil, fmt.Errorf("invalid curve")
}
if generator == nil {
return nil, fmt.Errorf("invalid generator")
}
if !generator.IsOnCurve() || generator.IsIdentity() {
return nil, fmt.Errorf("invalid generator")
}
return &Pedersen{threshold, limit, curve, generator}, nil
}
// Split creates the verifiers, blinding and shares
func (pd Pedersen) Split(secret curves.Scalar, reader io.Reader) (*PedersenResult, error) {
// generate a random blinding factor
blinding := pd.curve.Scalar.Random(reader)
shamir := Shamir{pd.threshold, pd.limit, pd.curve}
// split the secret into shares
shares, poly := shamir.getPolyAndShares(secret, reader)
// split the blinding into shares
blindingShares, polyBlinding := shamir.getPolyAndShares(blinding, reader)
// Generate the verifiable commitments to the polynomial for the shares
blindedverifiers := make([]curves.Point, pd.threshold)
verifiers := make([]curves.Point, pd.threshold)
// ({p0 * G + b0 * H}, ...,{pt * G + bt * H})
for i, c := range poly.Coefficients {
s := pd.curve.ScalarBaseMult(c)
b := pd.generator.Mul(polyBlinding.Coefficients[i])
bv := s.Add(b)
blindedverifiers[i] = bv
verifiers[i] = s
}
verifier1 := &FeldmanVerifier{Commitments: verifiers}
verifier2 := &PedersenVerifier{Commitments: blindedverifiers, Generator: pd.generator}
return &PedersenResult{
blinding, blindingShares, shares, verifier1, verifier2,
}, nil
}
func (pd Pedersen) LagrangeCoeffs(shares map[uint32]*ShamirShare) (map[uint32]curves.Scalar, error) {
shamir := &Shamir{
threshold: pd.threshold,
limit: pd.limit,
curve: pd.curve,
}
identities := make([]uint32, 0)
for _, xi := range shares {
identities = append(identities, xi.Id)
}
return shamir.LagrangeCoeffs(identities)
}
func (pd Pedersen) Combine(shares ...*ShamirShare) (curves.Scalar, error) {
shamir := &Shamir{
threshold: pd.threshold,
limit: pd.limit,
curve: pd.curve,
}
return shamir.Combine(shares...)
}
func (pd Pedersen) CombinePoints(shares ...*ShamirShare) (curves.Point, error) {
shamir := &Shamir{
threshold: pd.threshold,
limit: pd.limit,
curve: pd.curve,
}
return shamir.CombinePoints(shares...)
}