mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
synced 2024-12-25 08:05:17 +00:00
537 lines
19 KiB
Go
537 lines
19 KiB
Go
package crypto_test
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import (
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"fmt"
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"math/big"
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"testing"
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"filippo.io/edwards25519"
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"github.com/stretchr/testify/assert"
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"source.quilibrium.com/quilibrium/monorepo/node/crypto"
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)
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func TestGeneratePermutationMatrix(t *testing.T) {
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m := crypto.GeneratePermutationMatrix(6)
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for _, x := range m {
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ySum := byte(0x00)
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for _, y := range x {
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ySum += y.Bytes()[0]
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}
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assert.Equal(t, ySum, byte(0x01))
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}
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for x := 0; x < len(m); x++ {
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xSum := byte(0x00)
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for y := 0; y < len(m); y++ {
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xSum += m[y][x].Bytes()[0]
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}
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assert.Equal(t, xSum, byte(0x01))
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}
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}
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func verifyLagrange(t *testing.T, shares []*edwards25519.Scalar, expected *edwards25519.Scalar, total, threshold int) {
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var result *edwards25519.Scalar
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for i := 1; i <= total-threshold+1; i++ {
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var reconstructedSum *edwards25519.Scalar
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for j := 0; j < threshold; j++ {
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oneLENumBytes := crypto.BigIntToLEBytes(big.NewInt(1))
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coeffNum, _ := edwards25519.NewScalar().SetCanonicalBytes(oneLENumBytes)
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coeffDenom, _ := edwards25519.NewScalar().SetCanonicalBytes(oneLENumBytes)
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for k := 0; k < threshold; k++ {
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if j != k {
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ikBytes := crypto.BigIntToLEBytes(big.NewInt(int64(i + k)))
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ijBytes := crypto.BigIntToLEBytes(big.NewInt(int64(i + j)))
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ikScalar, _ := edwards25519.NewScalar().SetCanonicalBytes(ikBytes)
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ijScalar, _ := edwards25519.NewScalar().SetCanonicalBytes(ijBytes)
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coeffNum.Multiply(coeffNum, ikScalar)
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ikScalar.Subtract(ikScalar, ijScalar)
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coeffDenom.Multiply(coeffDenom, ikScalar)
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}
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}
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coeffDenom.Invert(coeffDenom)
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coeffNum.Multiply(coeffNum, coeffDenom)
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reconstructedFrag := edwards25519.NewScalar().Multiply(coeffNum, shares[i+j-1])
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if reconstructedSum == nil {
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reconstructedSum = reconstructedFrag
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} else {
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reconstructedSum.Add(reconstructedSum, reconstructedFrag)
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}
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}
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if result == nil {
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result = reconstructedSum
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assert.Equal(t, expected.Bytes(), result.Bytes())
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} else if result.Equal(reconstructedSum) == 0 {
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fmt.Println("mismatched reconstruction")
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t.FailNow()
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}
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}
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}
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func TestGenerateShamirMatrix(t *testing.T) {
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m := crypto.GeneratePermutationMatrix(6)
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sm := crypto.ShamirSplitMatrix(m, 10, 3)
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for xi, x := range sm {
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for yi, y := range x {
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verifyLagrange(t, y, m[xi][yi], 10, 3)
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}
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}
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}
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func TestMatrixDotProduct(t *testing.T) {
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zeroBytes := crypto.BigIntToLEBytes(big.NewInt(0))
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oneBytes := crypto.BigIntToLEBytes(big.NewInt(1))
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twoBytes := crypto.BigIntToLEBytes(big.NewInt(2))
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threeBytes := crypto.BigIntToLEBytes(big.NewInt(3))
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fourBytes := crypto.BigIntToLEBytes(big.NewInt(4))
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zero, _ := edwards25519.NewScalar().SetCanonicalBytes(zeroBytes)
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one, _ := edwards25519.NewScalar().SetCanonicalBytes(oneBytes)
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two, _ := edwards25519.NewScalar().SetCanonicalBytes(twoBytes)
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three, _ := edwards25519.NewScalar().SetCanonicalBytes(threeBytes)
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four, _ := edwards25519.NewScalar().SetCanonicalBytes(fourBytes)
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aMatrix := [][]*edwards25519.Scalar{
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{two, two},
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{zero, three},
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{zero, four},
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}
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bMatrix := [][]*edwards25519.Scalar{
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{two, one, two},
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{three, two, four},
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}
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abMatrix := crypto.GenerateDotProduct(aMatrix, bMatrix)
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assert.Equal(t, byte(0x0a), abMatrix[0][0].Bytes()[0])
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assert.Equal(t, byte(0x06), abMatrix[0][1].Bytes()[0])
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assert.Equal(t, byte(0x0c), abMatrix[0][2].Bytes()[0])
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assert.Equal(t, byte(0x09), abMatrix[1][0].Bytes()[0])
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assert.Equal(t, byte(0x06), abMatrix[1][1].Bytes()[0])
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assert.Equal(t, byte(0x0c), abMatrix[1][2].Bytes()[0])
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assert.Equal(t, byte(0x0c), abMatrix[2][0].Bytes()[0])
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assert.Equal(t, byte(0x08), abMatrix[2][1].Bytes()[0])
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assert.Equal(t, byte(0x10), abMatrix[2][2].Bytes()[0])
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}
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func TestGenerateRandomBeaverTripleMatrixShares(t *testing.T) {
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beaverTripleShares := crypto.GenerateRandomBeaverTripleMatrixShares(6, 10, 3)
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uMatrixShares := beaverTripleShares[0]
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vMatrixShares := beaverTripleShares[1]
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uvMatrixShares := beaverTripleShares[2]
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uMatrix := crypto.InterpolateMatrixShares(uMatrixShares, []int{1, 2, 3})
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vMatrix := crypto.InterpolateMatrixShares(vMatrixShares, []int{1, 2, 3})
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uvMatrix := crypto.InterpolateMatrixShares(uvMatrixShares, []int{1, 2, 3})
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for x := 0; x < len(uMatrixShares); x++ {
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for y := 0; y < len(uMatrixShares[0]); y++ {
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verifyLagrange(t, uMatrixShares[x][y], uMatrix[x][y], 10, 3)
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verifyLagrange(t, vMatrixShares[x][y], vMatrix[x][y], 10, 3)
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verifyLagrange(t, uvMatrixShares[x][y], uvMatrix[x][y], 10, 3)
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}
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}
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uvCheck := crypto.GenerateDotProduct(uMatrix, vMatrix)
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assert.Equal(t, uvMatrix, uvCheck)
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}
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func TestPermutationMatrix(t *testing.T) {
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permutationMatrix1 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix2 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix3 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix4 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix := crypto.GenerateDotProduct(permutationMatrix1, permutationMatrix2)
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permutationMatrix = crypto.GenerateDotProduct(permutationMatrix, permutationMatrix3)
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permutationMatrix = crypto.GenerateDotProduct(permutationMatrix, permutationMatrix4)
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one, _ := edwards25519.NewScalar().SetCanonicalBytes(crypto.BigIntToLEBytes(big.NewInt(1)))
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for x := 0; x < 6; x++ {
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sumX := edwards25519.NewScalar()
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for y := 0; y < 6; y++ {
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sumX.Add(sumX, permutationMatrix[x][y])
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}
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assert.Equal(t, sumX, one)
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}
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for y := 0; y < 6; y++ {
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sumY := edwards25519.NewScalar()
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for x := 0; x < 6; x++ {
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sumY.Add(sumY, permutationMatrix[x][y])
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}
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assert.Equal(t, sumY, one)
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}
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}
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func TestPermutationSharing(t *testing.T) {
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permutationMatrix1 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix2 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix3 := crypto.GeneratePermutationMatrix(6)
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permutationMatrix4 := crypto.GeneratePermutationMatrix(6)
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permutationMatrixShares1 := crypto.ShamirSplitMatrix(permutationMatrix1, 4, 3)
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permutationMatrixShares2 := crypto.ShamirSplitMatrix(permutationMatrix2, 4, 3)
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permutationMatrixShares3 := crypto.ShamirSplitMatrix(permutationMatrix3, 4, 3)
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permutationMatrixShares4 := crypto.ShamirSplitMatrix(permutationMatrix4, 4, 3)
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inverseShareMatrix1 := make([][][]*edwards25519.Scalar, 4)
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inverseShareMatrix2 := make([][][]*edwards25519.Scalar, 4)
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inverseShareMatrix3 := make([][][]*edwards25519.Scalar, 4)
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inverseShareMatrix4 := make([][][]*edwards25519.Scalar, 4)
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for i := 0; i < 4; i++ {
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inverseShareMatrix1[i] = make([][]*edwards25519.Scalar, 6)
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inverseShareMatrix2[i] = make([][]*edwards25519.Scalar, 6)
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inverseShareMatrix3[i] = make([][]*edwards25519.Scalar, 6)
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inverseShareMatrix4[i] = make([][]*edwards25519.Scalar, 6)
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for x := 0; x < 6; x++ {
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inverseShareMatrix1[i][x] = make([]*edwards25519.Scalar, 6)
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inverseShareMatrix2[i][x] = make([]*edwards25519.Scalar, 6)
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inverseShareMatrix3[i][x] = make([]*edwards25519.Scalar, 6)
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inverseShareMatrix4[i][x] = make([]*edwards25519.Scalar, 6)
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for y := 0; y < 6; y++ {
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inverseShareMatrix1[i][x][y] = permutationMatrixShares1[x][y][i]
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inverseShareMatrix2[i][x][y] = permutationMatrixShares2[x][y][i]
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inverseShareMatrix3[i][x][y] = permutationMatrixShares3[x][y][i]
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inverseShareMatrix4[i][x][y] = permutationMatrixShares4[x][y][i]
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}
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}
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}
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beaverTripleShares1 := crypto.GenerateRandomBeaverTripleMatrixShares(6, 4, 3)
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beaverTripleShares2 := crypto.GenerateRandomBeaverTripleMatrixShares(6, 4, 3)
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beaverTripleShares3 := crypto.GenerateRandomBeaverTripleMatrixShares(6, 4, 3)
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beaverTriplesAShares1 := beaverTripleShares1[0]
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beaverTriplesBShares1 := beaverTripleShares1[1]
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beaverTriplesABShares1 := beaverTripleShares1[2]
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beaverTriplesAShares2 := beaverTripleShares2[0]
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beaverTriplesBShares2 := beaverTripleShares2[1]
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beaverTriplesABShares2 := beaverTripleShares2[2]
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beaverTriplesAShares3 := beaverTripleShares3[0]
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beaverTriplesBShares3 := beaverTripleShares3[1]
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beaverTriplesABShares3 := beaverTripleShares3[2]
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inverseBeaverTriplesAShares1 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesBShares1 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesABShares1 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesAShares2 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesBShares2 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesABShares2 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesAShares3 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesBShares3 := make([][][]*edwards25519.Scalar, 4)
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inverseBeaverTriplesABShares3 := make([][][]*edwards25519.Scalar, 4)
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for i := 0; i < 4; i++ {
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inverseBeaverTriplesAShares1[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesBShares1[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesABShares1[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesAShares2[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesBShares2[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesABShares2[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesAShares3[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesBShares3[i] = make([][]*edwards25519.Scalar, 6)
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inverseBeaverTriplesABShares3[i] = make([][]*edwards25519.Scalar, 6)
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for x := 0; x < 6; x++ {
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inverseBeaverTriplesAShares1[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesBShares1[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesABShares1[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesAShares2[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesBShares2[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesABShares2[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesAShares3[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesBShares3[i][x] = make([]*edwards25519.Scalar, 6)
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inverseBeaverTriplesABShares3[i][x] = make([]*edwards25519.Scalar, 6)
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for y := 0; y < 6; y++ {
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inverseBeaverTriplesAShares1[i][x][y] = beaverTriplesAShares1[x][y][i]
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inverseBeaverTriplesBShares1[i][x][y] = beaverTriplesBShares1[x][y][i]
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inverseBeaverTriplesABShares1[i][x][y] = beaverTriplesABShares1[x][y][i]
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inverseBeaverTriplesAShares2[i][x][y] = beaverTriplesAShares2[x][y][i]
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inverseBeaverTriplesBShares2[i][x][y] = beaverTriplesBShares2[x][y][i]
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inverseBeaverTriplesABShares2[i][x][y] = beaverTriplesABShares2[x][y][i]
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inverseBeaverTriplesAShares3[i][x][y] = beaverTriplesAShares3[x][y][i]
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inverseBeaverTriplesBShares3[i][x][y] = beaverTriplesBShares3[x][y][i]
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inverseBeaverTriplesABShares3[i][x][y] = beaverTriplesABShares3[x][y][i]
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}
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}
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}
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es1 := make([][][]*edwards25519.Scalar, 6)
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fs1 := make([][][]*edwards25519.Scalar, 6)
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es2 := make([][][]*edwards25519.Scalar, 6)
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fs2 := make([][][]*edwards25519.Scalar, 6)
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es3 := make([][][]*edwards25519.Scalar, 6)
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fs3 := make([][][]*edwards25519.Scalar, 6)
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for x := 0; x < 6; x++ {
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es1[x] = make([][]*edwards25519.Scalar, 6)
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fs1[x] = make([][]*edwards25519.Scalar, 6)
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es2[x] = make([][]*edwards25519.Scalar, 6)
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fs2[x] = make([][]*edwards25519.Scalar, 6)
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es3[x] = make([][]*edwards25519.Scalar, 6)
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fs3[x] = make([][]*edwards25519.Scalar, 6)
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for y := 0; y < 6; y++ {
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es1[x][y] = make([]*edwards25519.Scalar, 4)
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fs1[x][y] = make([]*edwards25519.Scalar, 4)
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es2[x][y] = make([]*edwards25519.Scalar, 4)
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fs2[x][y] = make([]*edwards25519.Scalar, 4)
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es3[x][y] = make([]*edwards25519.Scalar, 4)
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fs3[x][y] = make([]*edwards25519.Scalar, 4)
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for i := 0; i < 4; i++ {
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es1[x][y][i] = edwards25519.NewScalar().Subtract(inverseShareMatrix1[i][x][y], inverseBeaverTriplesAShares1[i][x][y])
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fs1[x][y][i] = edwards25519.NewScalar().Subtract(inverseShareMatrix2[i][x][y], inverseBeaverTriplesBShares1[i][x][y])
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es2[x][y][i] = edwards25519.NewScalar().Subtract(inverseShareMatrix2[i][x][y], inverseBeaverTriplesAShares2[i][x][y])
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fs2[x][y][i] = edwards25519.NewScalar().Subtract(inverseShareMatrix3[i][x][y], inverseBeaverTriplesBShares2[i][x][y])
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es3[x][y][i] = edwards25519.NewScalar().Subtract(inverseShareMatrix3[i][x][y], inverseBeaverTriplesAShares3[i][x][y])
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fs3[x][y][i] = edwards25519.NewScalar().Subtract(inverseShareMatrix4[i][x][y], inverseBeaverTriplesBShares3[i][x][y])
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}
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}
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}
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// e = a - u
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// f = b - v
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// (a - u)(b - v) = -ab + ub + av - uv + (ab-av) + (ab - ub) + uv
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e1 := crypto.InterpolateMatrixShares(es1, []int{1, 2, 3, 4})
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f1 := crypto.InterpolateMatrixShares(fs1, []int{1, 2, 3, 4})
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e2 := crypto.InterpolateMatrixShares(es2, []int{1, 2, 3, 4})
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f2 := crypto.InterpolateMatrixShares(fs2, []int{1, 2, 3, 4})
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e3 := crypto.InterpolateMatrixShares(es3, []int{1, 2, 3, 4})
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f3 := crypto.InterpolateMatrixShares(fs3, []int{1, 2, 3, 4})
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// mul(a, b) => <e> = <a> - <u>, <f> = <b> - <v>, <c> = -i * e * f + f * <a> + e * <b> + <z>
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ef1 := crypto.GenerateDotProduct(e1, f1)
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ef2 := crypto.GenerateDotProduct(e2, f2)
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ef3 := crypto.GenerateDotProduct(e3, f3)
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fa1 := make([][][]*edwards25519.Scalar, 4)
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fa2 := make([][][]*edwards25519.Scalar, 4)
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fa3 := make([][][]*edwards25519.Scalar, 4)
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eb1 := make([][][]*edwards25519.Scalar, 4)
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eb2 := make([][][]*edwards25519.Scalar, 4)
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eb3 := make([][][]*edwards25519.Scalar, 4)
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cs1 := make([][][]*edwards25519.Scalar, 4)
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cs2 := make([][][]*edwards25519.Scalar, 4)
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cs3 := make([][][]*edwards25519.Scalar, 4)
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// cs := make([][][]*edwards25519.Scalar, 4)
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inverseCS1 := make([][][]*edwards25519.Scalar, 6)
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inverseCS3 := make([][][]*edwards25519.Scalar, 6)
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for i := 0; i < 4; i++ {
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fa1[i] = crypto.GenerateDotProduct(inverseShareMatrix1[i], f1)
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eb1[i] = crypto.GenerateDotProduct(e1, inverseShareMatrix2[i])
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fa2[i] = crypto.GenerateDotProduct(inverseShareMatrix2[i], f2)
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eb2[i] = crypto.GenerateDotProduct(e2, inverseShareMatrix3[i])
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fa3[i] = crypto.GenerateDotProduct(inverseShareMatrix3[i], f3)
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eb3[i] = crypto.GenerateDotProduct(e3, inverseShareMatrix4[i])
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cs1[i] = crypto.AddMatrices(crypto.ScalarMult(-1, ef1), fa1[i], eb1[i], inverseBeaverTriplesABShares1[i])
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cs2[i] = crypto.AddMatrices(crypto.ScalarMult(-1, ef2), fa2[i], eb2[i], inverseBeaverTriplesABShares2[i])
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cs3[i] = crypto.AddMatrices(crypto.ScalarMult(-1, ef3), fa3[i], eb3[i], inverseBeaverTriplesABShares3[i])
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}
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for x := 0; x < 6; x++ {
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inverseCS1[x] = make([][]*edwards25519.Scalar, 6)
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inverseCS3[x] = make([][]*edwards25519.Scalar, 6)
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for y := 0; y < 6; y++ {
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inverseCS1[x][y] = make([]*edwards25519.Scalar, 4)
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inverseCS3[x][y] = make([]*edwards25519.Scalar, 4)
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for i := 0; i < 4; i++ {
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inverseCS1[x][y][i] = cs1[i][x][y]
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inverseCS3[x][y][i] = cs3[i][x][y]
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}
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}
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}
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c1 := crypto.InterpolateMatrixShares(inverseCS1, []int{1, 2, 3, 4})
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c3 := crypto.InterpolateMatrixShares(inverseCS3, []int{1, 2, 3, 4})
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c := crypto.GenerateDotProduct(c1, c3)
|
|
ab := crypto.GenerateDotProduct(permutationMatrix1, permutationMatrix2)
|
|
abc := crypto.GenerateDotProduct(ab, permutationMatrix3)
|
|
abcd := crypto.GenerateDotProduct(abc, permutationMatrix4)
|
|
|
|
for x := 0; x < 6; x++ {
|
|
for y := 0; y < 6; y++ {
|
|
assert.ElementsMatch(t, c[x][y].Bytes(), abcd[x][y].Bytes())
|
|
}
|
|
}
|
|
}
|
|
|
|
// func TestIlanBeaverMultiMatrixSharing(t *testing.T) {
|
|
// fmt.Println("start")
|
|
// start := time.Now()
|
|
// ri := [65][][][]*edwards25519.Scalar{}
|
|
// rj := [65][][][]*edwards25519.Scalar{}
|
|
|
|
// next := time.Now()
|
|
// diff := next.Sub(start)
|
|
// fmt.Println(diff)
|
|
// start = next
|
|
// fmt.Println("generating random and inverse matrices")
|
|
// var wg sync.WaitGroup
|
|
|
|
// for i := 0; i <= 64; i++ {
|
|
// wg.Add(1)
|
|
|
|
// i := i
|
|
|
|
// go func() {
|
|
// defer wg.Done()
|
|
// rs := crypto.GenerateRandomMatrixAndInverseShares(80, 4, 3)
|
|
// ri[i] = make([][][]*edwards25519.Scalar, 4)
|
|
// rj[i] = make([][][]*edwards25519.Scalar, 4)
|
|
// for j := 0; j < 4; j++ {
|
|
// ri[i][j] = make([][]*edwards25519.Scalar, 80)
|
|
// rj[i][j] = make([][]*edwards25519.Scalar, 80)
|
|
// for x := 0; x < 80; x++ {
|
|
// ri[i][j][x] = make([]*edwards25519.Scalar, 80)
|
|
// rj[i][j][x] = make([]*edwards25519.Scalar, 80)
|
|
// for y := 0; y < 80; y++ {
|
|
// ri[i][j][x][y] = rs[0][x][y][j]
|
|
// rj[i][j][x][y] = rs[1][x][y][j]
|
|
// }
|
|
// }
|
|
// }
|
|
// }()
|
|
// }
|
|
|
|
// wg.Wait()
|
|
|
|
// next = time.Now()
|
|
// diff = next.Sub(start)
|
|
// fmt.Println(diff)
|
|
// start = next
|
|
// fmt.Println("generating permutation matrices")
|
|
// rxr := [64][][][]*edwards25519.Scalar{}
|
|
|
|
// for i := 1; i <= 64; i++ {
|
|
// wg.Add(1)
|
|
|
|
// i := i
|
|
|
|
// go func() {
|
|
// defer wg.Done()
|
|
// x := crypto.GeneratePermutationMatrix(80)
|
|
// xs := crypto.ShamirSplitMatrix(x, 4, 3)
|
|
// ixs := make([][][]*edwards25519.Scalar, 4)
|
|
// rxr[i-1] = make([][][]*edwards25519.Scalar, 4)
|
|
// for j := 0; j < 4; j++ {
|
|
// ixs[j] = make([][]*edwards25519.Scalar, 80)
|
|
// rxr[i-1][j] = make([][]*edwards25519.Scalar, 80)
|
|
// for x := 0; x < 80; x++ {
|
|
// ixs[j][x] = make([]*edwards25519.Scalar, 80)
|
|
// rxr[i-1][j][x] = make([]*edwards25519.Scalar, 80)
|
|
// for y := 0; y < 80; y++ {
|
|
// ixs[j][x][y] = xs[x][y][j]
|
|
// }
|
|
// }
|
|
// }
|
|
// for j := 0; j < 4; j++ {
|
|
// rxrij := crypto.GenerateDotProduct(ri[i-1][j], ixs[j])
|
|
// rxr[i-1][j] = crypto.GenerateDotProduct(rxrij, rj[i][j])
|
|
// }
|
|
// }()
|
|
// }
|
|
|
|
// wg.Wait()
|
|
|
|
// next = time.Now()
|
|
// diff = next.Sub(start)
|
|
// fmt.Println(diff)
|
|
// start = next
|
|
// fmt.Println("swapping elements for interpolation")
|
|
// irxr := [64][][][]*edwards25519.Scalar{}
|
|
// for i := 0; i < 64; i++ {
|
|
// wg.Add(1)
|
|
|
|
// i := i
|
|
|
|
// go func() {
|
|
// defer wg.Done()
|
|
// irxr[i] = make([][][]*edwards25519.Scalar, 80)
|
|
// for x := 0; x < 80; x++ {
|
|
// irxr[i][x] = make([][]*edwards25519.Scalar, 80)
|
|
// for y := 0; y < 80; y++ {
|
|
// irxr[i][x][y] = make([]*edwards25519.Scalar, 4)
|
|
// for j := 0; j < 4; j++ {
|
|
// irxr[i][x][y][j] = rxr[i][j][x][y]
|
|
// }
|
|
// }
|
|
// }
|
|
// }()
|
|
// }
|
|
|
|
// wg.Wait()
|
|
|
|
// rxri := [][]*edwards25519.Scalar{}
|
|
|
|
// next = time.Now()
|
|
// diff = next.Sub(start)
|
|
// fmt.Println(diff)
|
|
// start = next
|
|
// fmt.Println("interpolating")
|
|
|
|
// for i := 0; i < 64; i++ {
|
|
// next := crypto.InterpolateMatrixShares(irxr[i], []int{1, 2, 3})
|
|
// if i == 0 {
|
|
// rxri = next
|
|
// } else {
|
|
// rxri = crypto.GenerateDotProduct(rxri, next)
|
|
// }
|
|
// }
|
|
|
|
// rpms := make([][][]*edwards25519.Scalar, 4)
|
|
// next = time.Now()
|
|
// diff = next.Sub(start)
|
|
// fmt.Println(diff)
|
|
// start = next
|
|
// fmt.Println("generating intermediary dot products")
|
|
|
|
// for i := 1; i <= 4; i++ {
|
|
// rpms[i-1] = crypto.GenerateDotProduct(crypto.GenerateDotProduct(rj[0][i-1], rxri), ri[64][i-1])
|
|
// }
|
|
|
|
// final := make([][][]*edwards25519.Scalar, 80)
|
|
// for x := 0; x < 80; x++ {
|
|
// final[x] = make([][]*edwards25519.Scalar, 80)
|
|
// for y := 0; y < 80; y++ {
|
|
// final[x][y] = make([]*edwards25519.Scalar, 4)
|
|
// for j := 0; j < 4; j++ {
|
|
// final[x][y][j] = rpms[j][x][y]
|
|
// }
|
|
// }
|
|
// }
|
|
|
|
// next = time.Now()
|
|
// diff = next.Sub(start)
|
|
// fmt.Println(diff)
|
|
// start = next
|
|
// fmt.Println("final interpolation")
|
|
// rpm := crypto.InterpolateMatrixShares(final, []int{1, 2, 3})
|
|
|
|
// for x := 0; x < 80; x++ {
|
|
// for y := 0; y < 80; y++ {
|
|
// fmt.Printf("%x, ", rpm[x][y].Bytes()[0])
|
|
// }
|
|
// fmt.Println()
|
|
// }
|
|
// t.Fail()
|
|
// }
|