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// implementation of https://eprint.iacr.org/2016/260.pdf
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package groth16
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import (
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"fmt"
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"math/big"
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"github.com/arnaucube/go-snark/bn128"
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"github.com/arnaucube/go-snark/circuitcompiler"
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"github.com/arnaucube/go-snark/fields"
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"github.com/arnaucube/go-snark/r1csqap"
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)
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// Setup is the data structure holding the Trusted Setup data. The Setup.Toxic sub struct must be destroyed after the GenerateTrustedSetup function is completed
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type Setup struct {
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Toxic struct {
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T *big.Int // trusted setup secret
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Kalpha *big.Int
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Kbeta *big.Int
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Kgamma *big.Int
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Kdelta *big.Int
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}
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// public
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Pk struct { // Proving Key
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BACDelta [][3]*big.Int // {( βui(x)+αvi(x)+wi(x) ) / γ } from 0 to l
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Z []*big.Int
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G1 struct {
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Alpha [3]*big.Int
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Beta [3]*big.Int
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Delta [3]*big.Int
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At [][3]*big.Int // {a(τ)} from 0 to m
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BACGamma [][3]*big.Int // {( βui(x)+αvi(x)+wi(x) ) / δ } from l+1 to m
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}
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G2 struct {
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Beta [3][2]*big.Int
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Gamma [3][2]*big.Int
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Delta [3][2]*big.Int
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BACGamma [][3][2]*big.Int // {( βui(x)+αvi(x)+wi(x) ) / δ } from l+1 to m
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}
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PowersTauDelta [][3]*big.Int // powers of τ encrypted in G1 curve, divided by δ
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}
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Vk struct {
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IC [][3]*big.Int
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G1 struct {
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Alpha [3]*big.Int
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}
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G2 struct {
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Beta [3][2]*big.Int
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Gamma [3][2]*big.Int
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Delta [3][2]*big.Int
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}
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}
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}
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// Proof contains the parameters to proof the zkSNARK
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type Proof struct {
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PiA [3]*big.Int
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PiB [3][2]*big.Int
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PiC [3]*big.Int
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}
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type utils struct {
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Bn bn128.Bn128
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FqR fields.Fq
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PF r1csqap.PolynomialField
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}
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// Utils is the data structure holding the BN128, FqR Finite Field over R, PolynomialField, that will be used inside the snarks operations
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var Utils = prepareUtils()
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func prepareUtils() utils {
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bn, err := bn128.NewBn128()
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if err != nil {
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panic(err)
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}
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// new Finite Field
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fqR := fields.NewFq(bn.R)
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// new Polynomial Field
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pf := r1csqap.NewPolynomialField(fqR)
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return utils{
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Bn: bn,
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FqR: fqR,
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PF: pf,
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}
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}
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// GenerateTrustedSetup generates the Trusted Setup from a compiled Circuit. The Setup.Toxic sub data structure must be destroyed
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func GenerateTrustedSetup(witnessLength int, circuit circuitcompiler.Circuit, alphas, betas, gammas [][]*big.Int) (Setup, error) {
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var setup Setup
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var err error
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// generate random t value
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setup.Toxic.T, err = Utils.FqR.Rand()
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if err != nil {
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return Setup{}, err
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}
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setup.Toxic.Kalpha, err = Utils.FqR.Rand()
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if err != nil {
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return Setup{}, err
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}
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setup.Toxic.Kbeta, err = Utils.FqR.Rand()
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if err != nil {
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return Setup{}, err
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}
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setup.Toxic.Kgamma, err = Utils.FqR.Rand()
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if err != nil {
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return Setup{}, err
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}
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setup.Toxic.Kdelta, err = Utils.FqR.Rand()
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if err != nil {
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return Setup{}, err
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}
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// z pol
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zpol := []*big.Int{big.NewInt(int64(1))}
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for i := 1; i < len(alphas)-1; i++ {
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zpol = Utils.PF.Mul(
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zpol,
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[]*big.Int{
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Utils.FqR.Neg(
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big.NewInt(int64(i))),
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big.NewInt(int64(1)),
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})
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}
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setup.Pk.Z = zpol
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zt := Utils.PF.Eval(zpol, setup.Toxic.T)
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invDelta := Utils.FqR.Inverse(setup.Toxic.Kdelta)
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ztinvDelta := Utils.FqR.Mul(invDelta, zt)
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// encrypt t values with curve generators
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// powers of tau divided by delta
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var ptd [][3]*big.Int
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ini := Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, ztinvDelta)
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ptd = append(ptd, ini)
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tEncr := setup.Toxic.T
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for i := 1; i < len(zpol); i++ {
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ptd = append(ptd, Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, Utils.FqR.Mul(tEncr, ztinvDelta)))
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tEncr = Utils.FqR.Mul(tEncr, setup.Toxic.T)
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}
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// powers of τ encrypted in G1 curve, divided by δ
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// (G1 * τ) / δ
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setup.Pk.PowersTauDelta = ptd
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setup.Pk.G1.Alpha = Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, setup.Toxic.Kalpha)
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setup.Pk.G1.Beta = Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, setup.Toxic.Kbeta)
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setup.Pk.G1.Delta = Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, setup.Toxic.Kdelta)
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setup.Pk.G2.Beta = Utils.Bn.G2.MulScalar(Utils.Bn.G2.G, setup.Toxic.Kbeta)
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setup.Pk.G2.Delta = Utils.Bn.G2.MulScalar(Utils.Bn.G2.G, setup.Toxic.Kdelta)
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setup.Vk.G1.Alpha = Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, setup.Toxic.Kalpha)
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setup.Vk.G2.Beta = Utils.Bn.G2.MulScalar(Utils.Bn.G2.G, setup.Toxic.Kbeta)
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setup.Vk.G2.Gamma = Utils.Bn.G2.MulScalar(Utils.Bn.G2.G, setup.Toxic.Kgamma)
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setup.Vk.G2.Delta = Utils.Bn.G2.MulScalar(Utils.Bn.G2.G, setup.Toxic.Kdelta)
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for i := 0; i < len(circuit.Signals); i++ {
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// Pk.G1.At: {a(τ)} from 0 to m
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at := Utils.PF.Eval(alphas[i], setup.Toxic.T)
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a := Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, at)
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setup.Pk.G1.At = append(setup.Pk.G1.At, a)
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bt := Utils.PF.Eval(betas[i], setup.Toxic.T)
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g1bt := Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, bt)
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g2bt := Utils.Bn.G2.MulScalar(Utils.Bn.G2.G, bt)
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// G1.BACGamma: {( βui(x)+αvi(x)+wi(x) ) / δ } from l+1 to m in G1
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setup.Pk.G1.BACGamma = append(setup.Pk.G1.BACGamma, g1bt)
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// G2.BACGamma: {( βui(x)+αvi(x)+wi(x) ) / δ } from l+1 to m in G2
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setup.Pk.G2.BACGamma = append(setup.Pk.G2.BACGamma, g2bt)
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}
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zero3 := [3]*big.Int{Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero()}
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for i := 0; i < circuit.NPublic+1; i++ {
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setup.Pk.BACDelta = append(setup.Pk.BACDelta, zero3)
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}
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for i := circuit.NPublic + 1; i < circuit.NVars; i++ {
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// TODO calculate all at, bt, ct outside, to avoid repeating calculations
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at := Utils.PF.Eval(alphas[i], setup.Toxic.T)
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bt := Utils.PF.Eval(betas[i], setup.Toxic.T)
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ct := Utils.PF.Eval(gammas[i], setup.Toxic.T)
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c := Utils.FqR.Mul(
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invDelta,
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Utils.FqR.Add(
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Utils.FqR.Add(
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Utils.FqR.Mul(at, setup.Toxic.Kbeta),
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Utils.FqR.Mul(bt, setup.Toxic.Kalpha),
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),
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ct,
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),
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)
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g1c := Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, c)
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// Pk.BACDelta: {( βui(x)+αvi(x)+wi(x) ) / γ } from 0 to l
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setup.Pk.BACDelta = append(setup.Pk.BACDelta, g1c)
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}
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for i := 0; i <= circuit.NPublic; i++ {
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at := Utils.PF.Eval(alphas[i], setup.Toxic.T)
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bt := Utils.PF.Eval(betas[i], setup.Toxic.T)
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ct := Utils.PF.Eval(gammas[i], setup.Toxic.T)
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ic := Utils.FqR.Mul(
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Utils.FqR.Inverse(setup.Toxic.Kgamma),
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Utils.FqR.Add(
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Utils.FqR.Add(
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Utils.FqR.Mul(at, setup.Toxic.Kbeta),
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Utils.FqR.Mul(bt, setup.Toxic.Kalpha),
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),
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ct,
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),
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)
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g1ic := Utils.Bn.G1.MulScalar(Utils.Bn.G1.G, ic)
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// used in verifier
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setup.Vk.IC = append(setup.Vk.IC, g1ic)
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}
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return setup, nil
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}
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// GenerateProofs generates all the parameters to proof the zkSNARK from the Circuit, Setup and the Witness
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func GenerateProofs(circuit circuitcompiler.Circuit, setup Setup, w []*big.Int, px []*big.Int) (Proof, error) {
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var proof Proof
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proof.PiA = [3]*big.Int{Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero()}
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proof.PiB = Utils.Bn.Fq6.Zero()
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proof.PiC = [3]*big.Int{Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero()}
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r, err := Utils.FqR.Rand()
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if err != nil {
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return Proof{}, err
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}
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s, err := Utils.FqR.Rand()
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if err != nil {
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return Proof{}, err
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}
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// piBG1 will hold all the same than proof.PiB but in G1 curve
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piBG1 := [3]*big.Int{Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero(), Utils.Bn.G1.F.Zero()}
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for i := 0; i < circuit.NVars; i++ {
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proof.PiA = Utils.Bn.G1.Add(proof.PiA, Utils.Bn.G1.MulScalar(setup.Pk.G1.At[i], w[i]))
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piBG1 = Utils.Bn.G1.Add(piBG1, Utils.Bn.G1.MulScalar(setup.Pk.G1.BACGamma[i], w[i]))
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proof.PiB = Utils.Bn.G2.Add(proof.PiB, Utils.Bn.G2.MulScalar(setup.Pk.G2.BACGamma[i], w[i]))
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}
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for i := circuit.NPublic + 1; i < circuit.NVars; i++ {
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proof.PiC = Utils.Bn.G1.Add(proof.PiC, Utils.Bn.G1.MulScalar(setup.Pk.BACDelta[i], w[i]))
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}
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// piA = (Σ from 0 to m (pk.A * w[i])) + pk.Alpha1 + r * δ
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proof.PiA = Utils.Bn.G1.Add(proof.PiA, setup.Pk.G1.Alpha)
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deltaR := Utils.Bn.G1.MulScalar(setup.Pk.G1.Delta, r)
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proof.PiA = Utils.Bn.G1.Add(proof.PiA, deltaR)
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// piBG1 = (Σ from 0 to m (pk.B1 * w[i])) + pk.g1.Beta + s * δ
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// piB = piB2 = (Σ from 0 to m (pk.B2 * w[i])) + pk.g2.Beta + s * δ
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piBG1 = Utils.Bn.G1.Add(piBG1, setup.Pk.G1.Beta)
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proof.PiB = Utils.Bn.G2.Add(proof.PiB, setup.Pk.G2.Beta)
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deltaSG1 := Utils.Bn.G1.MulScalar(setup.Pk.G1.Delta, s)
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piBG1 = Utils.Bn.G1.Add(piBG1, deltaSG1)
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deltaSG2 := Utils.Bn.G2.MulScalar(setup.Pk.G2.Delta, s)
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proof.PiB = Utils.Bn.G2.Add(proof.PiB, deltaSG2)
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hx := Utils.PF.DivisorPolynomial(px, setup.Pk.Z) // maybe move this calculation to a previous step
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// piC = (Σ from l+1 to m (w[i] * (pk.g1.Beta + pk.g1.Alpha + pk.C)) + h(tau)) / δ) + piA*s + r*piB - r*s*δ
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for i := 0; i < len(hx); i++ {
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proof.PiC = Utils.Bn.G1.Add(proof.PiC, Utils.Bn.G1.MulScalar(setup.Pk.PowersTauDelta[i], hx[i]))
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}
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proof.PiC = Utils.Bn.G1.Add(proof.PiC, Utils.Bn.G1.MulScalar(proof.PiA, s))
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proof.PiC = Utils.Bn.G1.Add(proof.PiC, Utils.Bn.G1.MulScalar(piBG1, r))
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negRS := Utils.FqR.Neg(Utils.FqR.Mul(r, s))
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proof.PiC = Utils.Bn.G1.Add(proof.PiC, Utils.Bn.G1.MulScalar(setup.Pk.G1.Delta, negRS))
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return proof, nil
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}
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// VerifyProof verifies over the BN128 the Pairings of the Proof
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func VerifyProof(circuit circuitcompiler.Circuit, setup Setup, proof Proof, publicSignals []*big.Int, debug bool) bool {
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icPubl := setup.Vk.IC[0]
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for i := 0; i < len(publicSignals); i++ {
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icPubl = Utils.Bn.G1.Add(icPubl, Utils.Bn.G1.MulScalar(setup.Vk.IC[i+1], publicSignals[i]))
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}
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if !Utils.Bn.Fq12.Equal(
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Utils.Bn.Pairing(proof.PiA, proof.PiB),
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Utils.Bn.Fq12.Mul(
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Utils.Bn.Pairing(setup.Vk.G1.Alpha, setup.Vk.G2.Beta),
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Utils.Bn.Fq12.Mul(
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Utils.Bn.Pairing(icPubl, setup.Vk.G2.Gamma),
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Utils.Bn.Pairing(proof.PiC, setup.Vk.G2.Delta)))) {
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if debug {
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fmt.Println("❌ groth16 verification not passed")
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}
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return false
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}
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if debug {
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fmt.Println("✓ groth16 verification passed")
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}
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return true
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}
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