mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
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397 lines
14 KiB
Go
397 lines
14 KiB
Go
//
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// Copyright Coinbase, Inc. All Rights Reserved.
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//
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// SPDX-License-Identifier: Apache-2.0
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//
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// Package bulletproof implements the zero knowledge protocol bulletproofs as defined in https://eprint.iacr.org/2017/1066.pdf
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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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// InnerProductProver is the struct used to create InnerProductProofs
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// It specifies which curve to use and holds precomputed generators
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// See NewInnerProductProver() for prover initialization.
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type InnerProductProver struct {
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curve curves.Curve
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generators ippGenerators
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}
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// InnerProductProof contains necessary output for the inner product proof
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// a and b are the final input vectors of scalars, they should be of length 1
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// Ls and Rs are calculated per recursion of the IPP and are necessary for verification
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// See section 3.1 on pg 15 of https://eprint.iacr.org/2017/1066.pdf
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type InnerProductProof struct {
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a, b curves.Scalar
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capLs, capRs []curves.Point
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curve *curves.Curve
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}
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// ippRecursion is the same as IPP but tracks recursive a', b', g', h' and Ls and Rs
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// It should only be used internally by InnerProductProver.Prove()
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// See L35 on pg 16 of https://eprint.iacr.org/2017/1066.pdf
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type ippRecursion struct {
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a, b []curves.Scalar
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c curves.Scalar
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capLs, capRs []curves.Point
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g, h []curves.Point
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u, capP curves.Point
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transcript *merlin.Transcript
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}
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// NewInnerProductProver initializes a new prover
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// It uses the specified domain to generate generators for vectors of at most maxVectorLength
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// A prover can be used to construct inner product proofs for vectors of length less than or equal to maxVectorLength
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// A prover is defined by an explicit curve.
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func NewInnerProductProver(maxVectorLength int, domain []byte, curve curves.Curve) (*InnerProductProver, error) {
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generators, err := getGeneratorPoints(maxVectorLength, domain, curve)
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if err != nil {
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return nil, errors.Wrap(err, "ipp getGenerators")
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}
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return &InnerProductProver{curve: curve, generators: *generators}, nil
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}
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// NewInnerProductProof initializes a new InnerProductProof for a specified curve
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// This should be used in tandem with UnmarshalBinary() to convert a marshaled proof into the struct.
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func NewInnerProductProof(curve *curves.Curve) *InnerProductProof {
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var capLs, capRs []curves.Point
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newProof := InnerProductProof{
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a: curve.NewScalar(),
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b: curve.NewScalar(),
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capLs: capLs,
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capRs: capRs,
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curve: curve,
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}
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return &newProof
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}
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// rangeToIPP takes the output of a range proof and converts it into an inner product proof
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// See section 4.2 on pg 20
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// The conversion specifies generators to use (g and hPrime), as well as the two vectors l, r of which the inner product is tHat
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// Additionally, note that the P used for the IPP is in fact P*h^-mu from the range proof.
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func (prover *InnerProductProver) rangeToIPP(proofG, proofH []curves.Point, l, r []curves.Scalar, tHat curves.Scalar, capPhmuinv, u curves.Point, transcript *merlin.Transcript) (*InnerProductProof, error) {
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// Note that P as a witness is only g^l * h^r
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// P needs to be in the form of g^l * h^r * u^<l,r>
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// Calculate the final P including the u^<l,r> term
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utHat := u.Mul(tHat)
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capP := capPhmuinv.Add(utHat)
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// Use params to prove inner product
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recursionParams := &ippRecursion{
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a: l,
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b: r,
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capLs: []curves.Point{},
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capRs: []curves.Point{},
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c: tHat,
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g: proofG,
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h: proofH,
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capP: capP,
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u: u,
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transcript: transcript,
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}
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return prover.proveRecursive(recursionParams)
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}
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// getP returns the initial P value given two scalars a,b and point u
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// This method should only be used for testing
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// See (3) on page 13 of https://eprint.iacr.org/2017/1066.pdf
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func (prover *InnerProductProver) getP(a, b []curves.Scalar, u curves.Point) (curves.Point, error) {
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// Vectors must have length power of two
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if !isPowerOfTwo(len(a)) {
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return nil, errors.New("ipp vector length must be power of two")
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}
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// Generator vectors must be same length
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if len(prover.generators.G) != len(prover.generators.H) {
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return nil, errors.New("ipp generator lengths of g and h must be equal")
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}
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// Inner product requires len(a) == len(b) else error is returned
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c, err := innerProduct(a, b)
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if err != nil {
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return nil, errors.Wrap(err, "ipp getInnerProduct")
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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 := prover.generators.G[0:len(a)]
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proofH := prover.generators.H[0:len(b)]
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// initial P = g^a * h^b * u^(a dot b) (See (3) on page 13 of https://eprint.iacr.org/2017/1066.pdf)
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ga := prover.curve.NewGeneratorPoint().SumOfProducts(proofG, a)
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hb := prover.curve.NewGeneratorPoint().SumOfProducts(proofH, b)
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uadotb := u.Mul(c)
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capP := ga.Add(hb).Add(uadotb)
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return capP, nil
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}
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// Prove executes the prover protocol on pg 16 of https://eprint.iacr.org/2017/1066.pdf
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// It generates an inner product proof for vectors a and b, using u to blind the inner product in P
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// A transcript is used for the Fiat Shamir heuristic.
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func (prover *InnerProductProver) Prove(a, b []curves.Scalar, u curves.Point, transcript *merlin.Transcript) (*InnerProductProof, error) {
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// Vectors must have length power of two
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if !isPowerOfTwo(len(a)) {
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return nil, errors.New("ipp vector length must be power of two")
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}
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// Generator vectors must be same length
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if len(prover.generators.G) != len(prover.generators.H) {
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return nil, errors.New("ipp generator lengths of g and h must be equal")
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}
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// Inner product requires len(a) == len(b) else error is returned
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c, err := innerProduct(a, b)
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if err != nil {
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return nil, errors.Wrap(err, "ipp getInnerProduct")
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}
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// Length of vectors must be less than the number of generators generated
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if len(a) > len(prover.generators.G) {
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return nil, 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 := prover.generators.G[0:len(a)]
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proofH := prover.generators.H[0:len(b)]
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// initial P = g^a * h^b * u^(a dot b) (See (3) on page 13 of https://eprint.iacr.org/2017/1066.pdf)
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ga := prover.curve.NewGeneratorPoint().SumOfProducts(proofG, a)
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hb := prover.curve.NewGeneratorPoint().SumOfProducts(proofH, b)
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uadotb := u.Mul(c)
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capP := ga.Add(hb).Add(uadotb)
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recursionParams := &ippRecursion{
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a: a,
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b: b,
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capLs: []curves.Point{},
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capRs: []curves.Point{},
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c: c,
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g: proofG,
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h: proofH,
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capP: capP,
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u: u,
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transcript: transcript,
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}
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return prover.proveRecursive(recursionParams)
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}
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// proveRecursive executes the recursion on pg 16 of https://eprint.iacr.org/2017/1066.pdf
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func (prover *InnerProductProver) proveRecursive(recursionParams *ippRecursion) (*InnerProductProof, error) {
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// length checks
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if len(recursionParams.a) != len(recursionParams.b) {
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return nil, errors.New("ipp proveRecursive a and b different lengths")
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}
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if len(recursionParams.g) != len(recursionParams.h) {
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return nil, errors.New("ipp proveRecursive g and h different lengths")
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}
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if len(recursionParams.a) != len(recursionParams.g) {
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return nil, errors.New("ipp proveRecursive scalar and point vectors different lengths")
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}
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// Base case (L14, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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if len(recursionParams.a) == 1 {
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proof := &InnerProductProof{
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a: recursionParams.a[0],
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b: recursionParams.b[0],
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capLs: recursionParams.capLs,
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capRs: recursionParams.capRs,
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curve: &prover.curve,
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}
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return proof, nil
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}
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// Split current state into low (first half) vs high (second half) vectors
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aLo, aHi, err := splitScalarVector(recursionParams.a)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams splitScalarVector")
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}
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bLo, bHi, err := splitScalarVector(recursionParams.b)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams splitScalarVector")
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}
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gLo, gHi, err := splitPointVector(recursionParams.g)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams splitPointVector")
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}
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hLo, hHi, err := splitPointVector(recursionParams.h)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams splitPointVector")
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}
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// c_l, c_r (L21,22, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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cL, err := innerProduct(aLo, bHi)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams innerProduct")
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}
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cR, err := innerProduct(aHi, bLo)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams innerProduct")
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}
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// L, R (L23,24, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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lga := prover.curve.Point.SumOfProducts(gHi, aLo)
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lhb := prover.curve.Point.SumOfProducts(hLo, bHi)
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ucL := recursionParams.u.Mul(cL)
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capL := lga.Add(lhb).Add(ucL)
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rga := prover.curve.Point.SumOfProducts(gLo, aHi)
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rhb := prover.curve.Point.SumOfProducts(hHi, bLo)
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ucR := recursionParams.u.Mul(cR)
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capR := rga.Add(rhb).Add(ucR)
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// Add L,R for verifier to use to calculate final g, h
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newL := recursionParams.capLs
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newL = append(newL, capL)
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newR := recursionParams.capRs
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newR = append(newR, capR)
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// Get x from L, R for non-interactive (See section 4.4 pg22 of https://eprint.iacr.org/2017/1066.pdf)
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// Note this replaces the interactive model, i.e. L36-28 of pg16 of https://eprint.iacr.org/2017/1066.pdf
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x, err := prover.calcx(capL, capR, recursionParams.transcript)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams calcx")
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}
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// Calculate recursive inputs
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xInv, err := x.Invert()
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams x.Invert")
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}
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// g', h' (L29,30, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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gLoxInverse := multiplyScalarToPointVector(xInv, gLo)
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gHix := multiplyScalarToPointVector(x, gHi)
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gPrime, err := multiplyPairwisePointVectors(gLoxInverse, gHix)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams multiplyPairwisePointVectors")
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}
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hLox := multiplyScalarToPointVector(x, hLo)
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hHixInv := multiplyScalarToPointVector(xInv, hHi)
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hPrime, err := multiplyPairwisePointVectors(hLox, hHixInv)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams multiplyPairwisePointVectors")
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}
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// P' (L31, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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xSquare := x.Square()
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xInvSquare := xInv.Square()
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LxSquare := capL.Mul(xSquare)
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RxInvSquare := capR.Mul(xInvSquare)
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PPrime := LxSquare.Add(recursionParams.capP).Add(RxInvSquare)
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// a', b' (L33, 34, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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aLox := multiplyScalarToScalarVector(x, aLo)
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aHixIn := multiplyScalarToScalarVector(xInv, aHi)
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aPrime, err := addPairwiseScalarVectors(aLox, aHixIn)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams addPairwiseScalarVectors")
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}
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bLoxInv := multiplyScalarToScalarVector(xInv, bLo)
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bHix := multiplyScalarToScalarVector(x, bHi)
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bPrime, err := addPairwiseScalarVectors(bLoxInv, bHix)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams addPairwiseScalarVectors")
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}
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// c'
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cPrime, err := innerProduct(aPrime, bPrime)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams innerProduct")
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}
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// Make recursive call (L35, pg16 of https://eprint.iacr.org/2017/1066.pdf)
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recursiveIPP := &ippRecursion{
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a: aPrime,
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b: bPrime,
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capLs: newL,
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capRs: newR,
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c: cPrime,
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g: gPrime,
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h: hPrime,
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capP: PPrime,
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u: recursionParams.u,
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transcript: recursionParams.transcript,
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}
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out, err := prover.proveRecursive(recursiveIPP)
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if err != nil {
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return nil, errors.Wrap(err, "recursionParams proveRecursive")
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}
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return out, nil
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}
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// calcx uses a merlin transcript for Fiat Shamir
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// For each recursion, it takes the current state of the transcript and appends the newly calculated L and R values
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// A new scalar is then read from the transcript
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// See section 4.4 pg22 of https://eprint.iacr.org/2017/1066.pdf
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func (prover *InnerProductProver) calcx(capL, capR curves.Point, transcript *merlin.Transcript) (curves.Scalar, error) {
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// Add the newest capL and capR values to transcript
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transcript.AppendMessage([]byte("addRecursiveL"), capL.ToAffineUncompressed())
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transcript.AppendMessage([]byte("addRecursiveR"), capR.ToAffineUncompressed())
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// Read 64 bytes from, set to scalar
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outBytes := transcript.ExtractBytes([]byte("getx"), 64)
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x, err := prover.curve.NewScalar().SetBytesWide(outBytes)
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if err != nil {
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return nil, errors.Wrap(err, "calcx NewScalar SetBytesWide")
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}
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return x, nil
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}
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// MarshalBinary takes an inner product proof and marshals into bytes.
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func (proof *InnerProductProof) MarshalBinary() []byte {
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var out []byte
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out = append(out, proof.a.Bytes()...)
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out = append(out, proof.b.Bytes()...)
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for i, capLElem := range proof.capLs {
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capRElem := proof.capRs[i]
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out = append(out, capLElem.ToAffineCompressed()...)
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out = append(out, capRElem.ToAffineCompressed()...)
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}
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return out
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}
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// UnmarshalBinary takes bytes of a marshaled proof and writes them into an inner product proof
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// The inner product proof used should be from the output of NewInnerProductProof().
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func (proof *InnerProductProof) UnmarshalBinary(data []byte) error {
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scalarLen := len(proof.curve.NewScalar().Bytes())
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pointLen := len(proof.curve.NewGeneratorPoint().ToAffineCompressed())
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ptr := 0
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// Get scalars
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a, err := proof.curve.NewScalar().SetBytes(data[ptr : ptr+scalarLen])
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if err != nil {
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return errors.New("innerProductProof UnmarshalBinary SetBytes")
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}
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proof.a = a
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ptr += scalarLen
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b, err := proof.curve.NewScalar().SetBytes(data[ptr : ptr+scalarLen])
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if err != nil {
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return errors.New("innerProductProof UnmarshalBinary SetBytes")
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}
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proof.b = b
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ptr += scalarLen
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// Get points
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var capLs, capRs []curves.Point //nolint:prealloc // pointer arithmetic makes it too unreadable.
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for ptr < len(data) {
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capLElem, err := proof.curve.Point.FromAffineCompressed(data[ptr : ptr+pointLen])
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if err != nil {
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return errors.New("innerProductProof UnmarshalBinary FromAffineCompressed")
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}
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capLs = append(capLs, capLElem)
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ptr += pointLen
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capRElem, err := proof.curve.Point.FromAffineCompressed(data[ptr : ptr+pointLen])
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if err != nil {
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return errors.New("innerProductProof UnmarshalBinary FromAffineCompressed")
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}
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capRs = append(capRs, capRElem)
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ptr += pointLen
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}
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proof.capLs = capLs
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proof.capRs = capRs
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return nil
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}
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