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@ -26,7 +26,7 @@ func (p *PlonkChip) expPowerOf2Extension(x QuadraticExtension) QuadraticExtensio |
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func (p *PlonkChip) evalL0(x QuadraticExtension, xPowN QuadraticExtension) QuadraticExtension { |
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// L_0(x) = (x^n - 1) / (n * (x - 1))
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eval_zero_poly := p.qe.SubExtension( |
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evalZeroPoly := p.qe.SubExtension( |
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xPowN, |
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p.qe.ONE, |
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) |
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@ -35,7 +35,7 @@ func (p *PlonkChip) evalL0(x QuadraticExtension, xPowN QuadraticExtension) Quadr |
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p.qe.DEGREE_BITS_QE, |
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) |
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return p.qe.DivExtension( |
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eval_zero_poly, |
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evalZeroPoly, |
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denominator, |
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) |
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} |
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@ -43,17 +43,17 @@ func (p *PlonkChip) evalL0(x QuadraticExtension, xPowN QuadraticExtension) Quadr |
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func (p *PlonkChip) checkPartialProducts( |
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numerators []QuadraticExtension, |
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denominators []QuadraticExtension, |
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challengeNum uint64) []QuadraticExtension { |
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challengeNum uint64, |
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) []QuadraticExtension { |
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numPartProds := p.commonData.NumPartialProducts |
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quotDegreeFactor := p.commonData.QuotientDegreeFactor |
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productAccs := make([]QuadraticExtension, numPartProds+2) |
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productAccs := make([]QuadraticExtension, 0, numPartProds+2) |
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productAccs = append(productAccs, p.openings.PlonkZs[challengeNum]) |
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productAccs = append(productAccs, p.openings.PartialProducts[challengeNum*numPartProds:(challengeNum+1)*numPartProds]...) |
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productAccs = append(productAccs, p.openings.PlonkZsNext[challengeNum]) |
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partialProductChecks := make([]QuadraticExtension, numPartProds) |
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partialProductChecks := make([]QuadraticExtension, 0, numPartProds) |
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for i := uint64(0); i < numPartProds; i += 1 { |
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ppStartIdx := i * quotDegreeFactor |
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@ -71,49 +71,50 @@ func (p *PlonkChip) checkPartialProducts( |
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partialProductChecks = append(partialProductChecks, partialProductCheck) |
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} |
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return partialProductChecks |
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} |
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func (p *PlonkChip) evalVanishingPoly() []QuadraticExtension { |
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// Calculate the k[i] * x
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s_ids := make([]QuadraticExtension, p.commonData.Config.NumRoutedWires) |
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sIDs := make([]QuadraticExtension, p.commonData.Config.NumRoutedWires) |
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for i := uint64(0); i < p.commonData.Config.NumRoutedWires; i++ { |
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p.qe.ScalarMulExtension(p.proofChallenges.PlonkZeta, p.commonData.KIs[i]) |
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sIDs[i] = p.qe.ScalarMulExtension(p.proofChallenges.PlonkZeta, p.commonData.KIs[i]) |
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} |
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// Calculate zeta^n
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zeta_pow_n := p.expPowerOf2Extension(p.proofChallenges.PlonkZeta) |
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zetaPowN := p.expPowerOf2Extension(p.proofChallenges.PlonkZeta) |
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// Calculate L_0(zeta)
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l_0_zeta := p.evalL0(p.proofChallenges.PlonkZeta, zeta_pow_n) |
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l0Zeta := p.evalL0(p.proofChallenges.PlonkZeta, zetaPowN) |
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vanishing_z1_terms := make([]QuadraticExtension, p.commonData.Config.NumChallenges) |
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vanishing_partial_products_terms := make([]QuadraticExtension, p.commonData.Config.NumChallenges*p.commonData.NumPartialProducts) |
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numerator_values := make([]QuadraticExtension, p.commonData.Config.NumChallenges*p.commonData.Config.NumRoutedWires) |
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denominator_values := make([]QuadraticExtension, p.commonData.Config.NumChallenges*p.commonData.Config.NumRoutedWires) |
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vanishingZ1Terms := make([]QuadraticExtension, 0, p.commonData.Config.NumChallenges) |
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vanishingPartialProductsTerms := make([]QuadraticExtension, 0, p.commonData.Config.NumChallenges*p.commonData.NumPartialProducts) |
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for i := uint64(0); i < p.commonData.Config.NumChallenges; i++ { |
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// L_0(zeta) (Z(zeta) - 1) = 0
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z1_term := p.qe.SubExtension( |
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p.qe.MulExtension(l_0_zeta, p.openings.PlonkZs[i]), |
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l_0_zeta, |
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p.qe.MulExtension(l0Zeta, p.openings.PlonkZs[i]), |
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l0Zeta, |
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) |
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vanishing_z1_terms = append(vanishing_z1_terms, z1_term) |
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vanishingZ1Terms = append(vanishingZ1Terms, z1_term) |
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numeratorValues := make([]QuadraticExtension, 0, p.commonData.Config.NumRoutedWires) |
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denominatorValues := make([]QuadraticExtension, 0, p.commonData.Config.NumRoutedWires) |
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for j := uint64(0); j < p.commonData.Config.NumRoutedWires; j++ { |
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// The numerator is `beta * s_id + wire_value + gamma`, and the denominator is
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// `beta * s_sigma + wire_value + gamma`.
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wire_value_plus_gamma := p.qe.AddExtension( |
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wireValuePlusGamma := p.qe.AddExtension( |
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p.openings.Wires[j], |
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p.qe.FieldToQE(p.proofChallenges.PlonkGammas[i]), |
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) |
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numerator := p.qe.AddExtension( |
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p.qe.MulExtension( |
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p.qe.FieldToQE(p.proofChallenges.PlonkBetas[i]), |
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s_ids[j], |
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sIDs[j], |
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), |
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wire_value_plus_gamma, |
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wireValuePlusGamma, |
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) |
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denominator := p.qe.AddExtension( |
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@ -121,20 +122,20 @@ func (p *PlonkChip) evalVanishingPoly() []QuadraticExtension { |
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p.qe.FieldToQE(p.proofChallenges.PlonkBetas[i]), |
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p.openings.PlonkSigmas[j], |
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), |
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wire_value_plus_gamma, |
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wireValuePlusGamma, |
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) |
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numerator_values = append(numerator_values, numerator) |
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denominator_values = append(denominator_values, denominator) |
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numeratorValues = append(numeratorValues, numerator) |
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denominatorValues = append(denominatorValues, denominator) |
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} |
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vanishing_partial_products_terms = append( |
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vanishing_partial_products_terms, |
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p.checkPartialProducts(numerator_values, denominator_values, i)..., |
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vanishingPartialProductsTerms = append( |
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vanishingPartialProductsTerms, |
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p.checkPartialProducts(numeratorValues, denominatorValues, i)..., |
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) |
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} |
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return vanishing_partial_products_terms |
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return vanishingPartialProductsTerms |
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} |
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func (p *PlonkChip) Verify() { |
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Kevin Jue
3 years ago