mirror of
https://source.quilibrium.com/quilibrium/ceremonyclient.git
synced 2024-12-27 00:55:17 +00:00
201 lines
7.3 KiB
Go
201 lines
7.3 KiB
Go
package kos
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import (
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"crypto/rand"
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"testing"
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"github.com/stretchr/testify/require"
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"source.quilibrium.com/quilibrium/monorepo/nekryptology/pkg/core/curves"
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"source.quilibrium.com/quilibrium/monorepo/nekryptology/pkg/ot/base/simplest"
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"source.quilibrium.com/quilibrium/monorepo/nekryptology/pkg/ot/ottest"
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)
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func TestBinaryMult(t *testing.T) {
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for i := 0; i < 100; i++ {
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temp := make([]byte, 32)
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_, err := rand.Read(temp)
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require.NoError(t, err)
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expected := make([]byte, 32)
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copy(expected, temp)
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// this test is based on Fermat's little theorem.
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// the multiplicative group of units of a finite field has order |F| - 1
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// (in fact, it's necessarily cyclic; see e.g. https://math.stackexchange.com/a/59911, but this test doesn't rely on that fact)
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// thus raising any element to the |F|th power should yield that element itself.
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// this is a good test because it relies on subtle facts about the field structure, and will fail if anything goes wrong.
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for j := 0; j < 256; j++ {
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expected = binaryFieldMul(expected, expected)
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}
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require.Equal(t, temp, expected)
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}
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}
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func TestCOTExtension(t *testing.T) {
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const (
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// below are the "cryptographic parameters", including computational and statistical,
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// as well as the cOT block size parameters, which depend on these in a pre-defined way.
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// Kappa is the computational security parameter.
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Kappa = 256
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// KappaBytes is same as Kappa // 8, but avoids cpu division.
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KappaBytes = Kappa >> 3
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s = 80 // statistical security parameter.
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// L is the batch size used in the cOT functionality.
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L = 2*Kappa + 2*s
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// COtBlockSizeBytes is same as L // 8, but avoids cpu division.
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COtBlockSizeBytes = L >> 3
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// OtWidth is the number of scalars processed per "slot" of the cOT. by definition of this parameter,
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// for each of the receiver's choice bits, the sender will provide `OTWidth` scalars.
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// in turn, both the sender and receiver will obtain `OTWidth` shares _per_ slot / bit of the cOT.
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// by definition of the cOT, these "vectors of" scalars will add (componentwise) to the sender's original scalars.
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OtWidth = 2
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kappaOT = Kappa + s
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lPrime = L + kappaOT // length of pseudorandom seed expansion, used within cOT protocol
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cOtExtendedBlockSizeBytes = lPrime >> 3
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)
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curveInstances := []*curves.Curve{
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curves.K256(),
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curves.P256(),
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}
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for _, curve := range curveInstances {
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uniqueSessionId := [simplest.DigestSize]byte{}
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_, err := rand.Read(uniqueSessionId[:])
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require.NoError(t, err)
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baseOtSenderOutput, baseOtReceiverOutput, err := ottest.RunSimplestOT(curve, Kappa, uniqueSessionId)
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require.NoError(t, err)
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for i := 0; i < Kappa; i++ {
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require.Equal(t, baseOtReceiverOutput.OneTimePadDecryptionKey[i], baseOtSenderOutput.OneTimePadEncryptionKeys[i][baseOtReceiverOutput.RandomChoiceBits[i]])
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}
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sender := NewCOtSender(Kappa, s, baseOtReceiverOutput, curve)
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receiver := NewCOtReceiver(Kappa, s, baseOtSenderOutput, curve)
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choice := [COtBlockSizeBytes]byte{} // receiver's input, namely choice vector. just random
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_, err = rand.Read(choice[:])
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require.NoError(t, err)
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input := make([][]curves.Scalar, L) // sender's input, namely integer "sums" in case w_j == 1.
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for i := 0; i < L; i++ {
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input[i] = make([]curves.Scalar, OtWidth)
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for j := 0; j < OtWidth; j++ {
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input[i][j] = curve.Scalar.Random(rand.Reader)
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require.NoError(t, err)
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}
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}
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firstMessage, err := receiver.Round1Initialize(uniqueSessionId, choice[:])
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require.NoError(t, err)
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responseTau, err := sender.Round2Transfer(uniqueSessionId, input, firstMessage)
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require.NoError(t, err)
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err = receiver.Round3Transfer(responseTau)
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require.NoError(t, err)
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for j := 0; j < L; j++ {
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bit := simplest.ExtractBitFromByteVector(choice[:], j) == 1
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for k := 0; k < OtWidth; k++ {
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temp := sender.OutputAdditiveShares[j][k].Add(receiver.OutputAdditiveShares[j][k])
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if bit {
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require.Equal(t, temp, input[j][k])
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} else {
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require.Equal(t, temp, curve.Scalar.Zero())
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}
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}
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}
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}
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}
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func TestCOTExtensionStreaming(t *testing.T) {
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const (
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// below are the "cryptographic parameters", including computational and statistical,
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// as well as the cOT block size parameters, which depend on these in a pre-defined way.
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// Kappa is the computational security parameter.
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Kappa = 256
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// KappaBytes is same as Kappa // 8, but avoids cpu division.
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KappaBytes = Kappa >> 3
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s = 80 // statistical security parameter.
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// L is the batch size used in the cOT functionality.
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L = 2*Kappa + 2*s
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// COtBlockSizeBytes is same as L // 8, but avoids cpu division.
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COtBlockSizeBytes = L >> 3
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// OtWidth is the number of scalars processed per "slot" of the cOT. by definition of this parameter,
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// for each of the receiver's choice bits, the sender will provide `OTWidth` scalars.
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// in turn, both the sender and receiver will obtain `OTWidth` shares _per_ slot / bit of the cOT.
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// by definition of the cOT, these "vectors of" scalars will add (componentwise) to the sender's original scalars.
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OtWidth = 2
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kappaOT = Kappa + s
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lPrime = L + kappaOT // length of pseudorandom seed expansion, used within cOT protocol
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cOtExtendedBlockSizeBytes = lPrime >> 3
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)
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curve := curves.K256()
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hashKeySeed := [simplest.DigestSize]byte{}
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_, err := rand.Read(hashKeySeed[:])
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require.NoError(t, err)
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baseOtReceiver, err := simplest.NewReceiver(curve, Kappa, hashKeySeed)
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require.NoError(t, err)
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sender := NewCOtSender(Kappa, s, baseOtReceiver.Output, curve)
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baseOtSender, err := simplest.NewSender(curve, Kappa, hashKeySeed)
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require.NoError(t, err)
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receiver := NewCOtReceiver(Kappa, s, baseOtSender.Output, curve)
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// first run the seed OT
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senderPipe, receiverPipe := simplest.NewPipeWrappers()
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errorsChannel := make(chan error, 2)
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go func() {
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errorsChannel <- simplest.SenderStreamOTRun(baseOtSender, senderPipe)
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}()
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go func() {
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errorsChannel <- simplest.ReceiverStreamOTRun(baseOtReceiver, receiverPipe)
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}()
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for i := 0; i < 2; i++ {
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require.Nil(t, <-errorsChannel)
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}
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for i := 0; i < Kappa; i++ {
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require.Equal(t, baseOtReceiver.Output.OneTimePadDecryptionKey[i], baseOtSender.Output.OneTimePadEncryptionKeys[i][baseOtReceiver.Output.RandomChoiceBits[i]])
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}
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// begin test of cOT extension. first populate both parties' inputs randomly
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choice := make([]byte, COtBlockSizeBytes) // receiver's input, namely choice vector. just random
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_, err = rand.Read(choice[:])
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require.NoError(t, err)
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input := make([][]curves.Scalar, L) // sender's input, namely integer "sums" in case w_j == 1. random for the test
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for i := 0; i < L; i++ {
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input[i] = make([]curves.Scalar, OtWidth)
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for j := 0; j < OtWidth; j++ {
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input[i][j] = curve.Scalar.Random(rand.Reader)
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require.NoError(t, err)
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}
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}
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// now actually run it, stream-wise
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go func() {
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errorsChannel <- SenderStreamCOtRun(sender, hashKeySeed, input, receiverPipe)
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}()
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go func() {
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errorsChannel <- ReceiverStreamCOtRun(receiver, hashKeySeed, choice, senderPipe)
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}()
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for i := 0; i < 2; i++ {
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require.Nil(t, <-errorsChannel)
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}
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for j := 0; j < L; j++ {
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bit := simplest.ExtractBitFromByteVector(choice[:], j) == 1
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for k := 0; k < OtWidth; k++ {
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temp := sender.OutputAdditiveShares[j][k].Add(receiver.OutputAdditiveShares[j][k])
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if bit {
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require.Equal(t, temp, input[j][k])
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} else {
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require.Equal(t, temp, curve.Scalar.Zero())
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}
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}
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}
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}
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