mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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188 lines
6.3 KiB
Go
188 lines
6.3 KiB
Go
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package bulletproof
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import (
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"github.com/gtank/merlin"
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"github.com/pkg/errors"
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"source.quilibrium.com/quilibrium/monorepo/nekryptology/pkg/core/curves"
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)
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// RangeVerifier is the struct used to verify RangeProofs
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// It specifies which curve to use and holds precomputed generators
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// See NewRangeVerifier() for verifier initialization.
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type RangeVerifier struct {
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curve curves.Curve
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generators *ippGenerators
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ippVerifier *InnerProductVerifier
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}
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// NewRangeVerifier initializes a new verifier
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// It uses the specified domain to generate generators for vectors of at most maxVectorLength
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// A verifier can be used to verify range proofs for vectors of length less than or equal to maxVectorLength
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// A verifier is defined by an explicit curve.
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func NewRangeVerifier(maxVectorLength int, rangeDomain, ippDomain []byte, curve curves.Curve) (*RangeVerifier, error) {
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generators, err := getGeneratorPoints(maxVectorLength, rangeDomain, curve)
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if err != nil {
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return nil, errors.Wrap(err, "range NewRangeProver")
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}
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ippVerifier, err := NewInnerProductVerifier(maxVectorLength, ippDomain, curve)
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if err != nil {
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return nil, errors.Wrap(err, "range NewRangeProver")
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}
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return &RangeVerifier{curve: curve, generators: generators, ippVerifier: ippVerifier}, nil
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}
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// Verify verifies the given range proof inputs
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// It implements the checking of L65 on pg 20
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// It also verifies the dot product of <l,r> using the inner product proof\
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// capV is a commitment to v using blinding factor gamma
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// n is the power that specifies the upper bound of the range, ie. 2^n
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// g, h, u are unique points used as generators for the blinding factor
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// transcript is a merlin transcript to be used for the fiat shamir heuristic.
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func (verifier *RangeVerifier) Verify(proof *RangeProof, capV curves.Point, proofGenerators RangeProofGenerators, n int, transcript *merlin.Transcript) (bool, error) {
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// Length of vectors must be less than the number of generators generated
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if n > len(verifier.generators.G) {
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return false, errors.New("ipp vector length must be less than maxVectorLength")
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}
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// In case where len(a) is less than number of generators precomputed by prover, trim to length
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proofG := verifier.generators.G[0:n]
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proofH := verifier.generators.H[0:n]
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// Calc y,z,x from Fiat Shamir heuristic
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y, z, err := calcyz(capV, proof.capA, proof.capS, transcript, verifier.curve)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof verify")
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}
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x, err := calcx(proof.capT1, proof.capT2, transcript, verifier.curve)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof verify")
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}
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wBytes := transcript.ExtractBytes([]byte("getw"), 64)
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w, err := verifier.curve.NewScalar().SetBytesWide(wBytes)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof prove")
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}
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// Calc delta(y,z)
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deltayz, err := deltayz(y, z, n, verifier.curve)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof verify")
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}
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// Check tHat: L65, pg20
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tHatIsValid := verifier.checktHat(proof, capV, proofGenerators.g, proofGenerators.h, deltayz, x, z)
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if !tHatIsValid {
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return false, errors.New("rangeproof verify tHat is invalid")
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}
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// Verify IPP
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hPrime, err := gethPrime(proofH, y, verifier.curve)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof verify")
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}
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capPhmu, err := getPhmu(proofG, hPrime, proofGenerators.h, proof.capA, proof.capS, x, y, z, proof.mu, n, verifier.curve)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof verify")
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}
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ippVerified, err := verifier.ippVerifier.VerifyFromRangeProof(proofG, hPrime, capPhmu, proofGenerators.u.Mul(w), proof.tHat, proof.ipp, transcript)
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if err != nil {
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return false, errors.Wrap(err, "rangeproof verify")
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}
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return ippVerified, nil
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}
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// L65, pg20.
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func (*RangeVerifier) checktHat(proof *RangeProof, capV, g, h curves.Point, deltayz, x, z curves.Scalar) bool {
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// g^tHat * h^tau_x
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gtHat := g.Mul(proof.tHat)
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htaux := h.Mul(proof.taux)
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lhs := gtHat.Add(htaux)
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// V^z^2 * g^delta(y,z) * Tau_1^x * Tau_2^x^2
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capVzsquare := capV.Mul(z.Square())
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gdeltayz := g.Mul(deltayz)
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capTau1x := proof.capT1.Mul(x)
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capTau2xsquare := proof.capT2.Mul(x.Square())
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rhs := capVzsquare.Add(gdeltayz).Add(capTau1x).Add(capTau2xsquare)
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// Compare lhs =? rhs
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return lhs.Equal(rhs)
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}
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// gethPrime calculates new h prime generators as defined in L64 on pg20.
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func gethPrime(h []curves.Point, y curves.Scalar, curve curves.Curve) ([]curves.Point, error) {
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hPrime := make([]curves.Point, len(h))
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yInv, err := y.Invert()
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yInvn := getknVector(yInv, len(h), curve)
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if err != nil {
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return nil, errors.Wrap(err, "gethPrime")
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}
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for i, hElem := range h {
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hPrime[i] = hElem.Mul(yInvn[i])
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}
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return hPrime, nil
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}
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// Obtain P used for IPP verification
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// See L67 on pg20
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// Note P on L66 includes blinding factor hmu, this method removes that factor.
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func getPhmu(proofG, proofHPrime []curves.Point, h, capA, capS curves.Point, x, y, z, mu curves.Scalar, n int, curve curves.Curve) (curves.Point, error) {
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// h'^(z*y^n + z^2*2^n)
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zyn := multiplyScalarToScalarVector(z, getknVector(y, n, curve))
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zsquaretwon := multiplyScalarToScalarVector(z.Square(), get2nVector(n, curve))
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elemLastExponent, err := addPairwiseScalarVectors(zyn, zsquaretwon)
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if err != nil {
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return nil, errors.Wrap(err, "getPhmu")
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}
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lastElem := curve.Point.SumOfProducts(proofHPrime, elemLastExponent)
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// S^x
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capSx := capS.Mul(x)
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// g^-z --> -z*<1,g>
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onen := get1nVector(n, curve)
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zNeg := z.Neg()
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zinvonen := multiplyScalarToScalarVector(zNeg, onen)
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zgdotonen := curve.Point.SumOfProducts(proofG, zinvonen)
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// L66 on pg20
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P := capA.Add(capSx).Add(zgdotonen).Add(lastElem)
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hmu := h.Mul(mu)
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Phmu := P.Sub(hmu)
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return Phmu, nil
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}
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// Delta function for delta(y,z), See (39) on pg18.
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func deltayz(y, z curves.Scalar, n int, curve curves.Curve) (curves.Scalar, error) {
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// z - z^2
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zMinuszsquare := z.Sub(z.Square())
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// 1^n
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onen := get1nVector(n, curve)
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// <1^n, y^n>
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onendotyn, err := innerProduct(onen, getknVector(y, n, curve))
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if err != nil {
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return nil, errors.Wrap(err, "deltayz")
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}
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// (z - z^2)*<1^n, y^n>
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termFirst := zMinuszsquare.Mul(onendotyn)
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// <1^n, 2^n>
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onendottwon, err := innerProduct(onen, get2nVector(n, curve))
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if err != nil {
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return nil, errors.Wrap(err, "deltayz")
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}
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// z^3*<1^n, 2^n>
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termSecond := z.Cube().Mul(onendottwon)
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// (z - z^2)*<1^n, y^n> - z^3*<1^n, 2^n>
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out := termFirst.Sub(termSecond)
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return out, nil
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}
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