public void UpdateWitnessTest() { // TODO: test deletion RAParameters rap = RA.RAParameters; FieldZqElement[] revoked = rap.group.FieldZq.GetRandomElements(5, true); GroupElement oldAccumulator = null; RevocationWitness oldWitness = null; // a 2nd RA with matching key and params RevocationAuthority RA2 = new RevocationAuthority(rap, RA.PrivateKey); HashSet <FieldZqElement> revokedSet2 = new HashSet <FieldZqElement>(); HashSet <FieldZqElement> revokedSet = null; for (int i = 0; i < revoked.Length; i++) { // add some revoked values, and update the accumulator and witness revokedSet = new HashSet <FieldZqElement>(new FieldZqElement[] { revoked[i] }); RA.UpdateAccumulator(revokedSet); GroupElement accumulator = RA.Accumulator; RevocationWitness witness = RevocationUser.UpdateWitness(rap, xid, revoked[i], null, oldAccumulator, accumulator, oldWitness); // update the revoked values with the accumulated revoked set, and have RA2 calculate the witness // for the user; they should match RA2.Accumulator = null; // reset the accumulator of RA2 revokedSet2.Add(revoked[i]); RA2.UpdateAccumulator(revokedSet2); GroupElement accumulator2 = RA2.Accumulator; RevocationWitness witness2 = RA2.ComputeRevocationWitness(revokedSet2, xid); Assert.AreEqual(accumulator, accumulator2, "accumulators are different"); Assert.AreEqual(witness.d, witness2.d, "witness d values are different"); Assert.AreEqual(witness.W, witness2.W, "witness W values are different"); Assert.AreEqual(witness.Q, witness2.Q, "witness Q values are different"); oldWitness = witness; oldAccumulator = accumulator; } }
public void AccumulatorTest() { RevocationAuthority RA = RevocationAuthority.GenerateRevocationAuthority(SubgroupParameterSets.ParamSet_SG_2048256_V1Name, "SHA-256"); FieldZq Zq = RA.RAParameters.group.FieldZq; GroupElement emptyAccumulator = RA.Accumulator; HashSet <FieldZqElement> revokedValues1 = new HashSet <FieldZqElement>(Zq.GetRandomElements(5, false)); // add and remove values, accumulator should be empty RA.UpdateAccumulator(revokedValues1, revokedValues1); Assert.AreEqual(emptyAccumulator, RA.Accumulator); // again with different API RA.UpdateAccumulator(revokedValues1, null); RA.UpdateAccumulator(null, revokedValues1); Assert.AreEqual(emptyAccumulator, RA.Accumulator); // add and remove values, accumulator should be as it started // fill in some values RA.UpdateAccumulator(revokedValues1); GroupElement V = RA.Accumulator; // add more values HashSet <FieldZqElement> revokedValues2 = new HashSet <FieldZqElement>(Zq.GetRandomElements(5, false)); RA.UpdateAccumulator(revokedValues2); // remove the last set of values, accumulator should be as it was before RA.UpdateAccumulator(null, revokedValues2); Assert.AreEqual(V, RA.Accumulator); // add private key negation to revocation set try { var privateKeyNegation = new HashSet <FieldZqElement>(); privateKeyNegation.Add(RA.PrivateKey.Negate()); RA.UpdateAccumulator(privateKeyNegation, null); Assert.Fail("Exception expected"); } catch (ArgumentException) { // expected } }
public void ProtocolTest() { Stopwatch sw = new Stopwatch(); sw.Start(); bool[] bools = new bool[] { true, false }; foreach (bool isSubgroupConstruction in bools) { foreach (bool supportDevice in bools) { foreach (int DSize in new int[] { 0, 2, 5 }) { foreach (bool isLite in bools) { string filename = "TestVectorData\\testvectors_"; if (isSubgroupConstruction) { filename += "SG"; } else { filename += "EC"; } if (supportDevice) { filename += "_Device"; } filename += ("_D" + DSize); if (isLite) { filename += "_lite"; } filename += "_doc.txt"; var vectors = GetTestVectors(filename); IssuerKeyAndParameters ikap = LoadIssuerKeyAndParameters(isSubgroupConstruction, vectors["GroupName"], supportDevice, vectors); FieldZq Zq = ikap.IssuerParameters.Zq; // replace random y0/g0 with test vector values ikap.PrivateKey = Zq.GetElement(HexToBytes(vectors["y0"])); ikap.IssuerParameters.G[0] = CreateGroupElement(ikap.IssuerParameters.Gq, vectors["g0"]); Assert.AreEqual(ikap.IssuerParameters.G[0], ikap.IssuerParameters.Gq.G.Exponentiate(ikap.PrivateKey), "g0 computation"); IssuerParameters ip = ikap.IssuerParameters; ip.Verify(); /* * issuance */ byte[][] A = new byte[][] { HexToBytes(vectors["A1"]), HexToBytes(vectors["A2"]), HexToBytes(vectors["A3"]), HexToBytes(vectors["A4"]), HexToBytes(vectors["A5"]) }; Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["x1"])), ProtocolHelper.ComputeXi(ip, 0, A[0]), "x1"); Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["x2"])), ProtocolHelper.ComputeXi(ip, 1, A[1]), "x2"); Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["x3"])), ProtocolHelper.ComputeXi(ip, 2, A[2]), "x3"); Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["x4"])), ProtocolHelper.ComputeXi(ip, 3, A[3]), "x4"); Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["x5"])), ProtocolHelper.ComputeXi(ip, 4, A[4]), "x5"); byte[] TI = HexToBytes(vectors["TI"]); Assert.IsTrue(HexToBytes(vectors["P"]).SequenceEqual(ip.Digest(supportDevice)), "P"); Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["xt"])), ProtocolHelper.ComputeXt(ip, TI, supportDevice), "xt"); IDevice device = null; GroupElement hd = null; if (supportDevice) { device = new VirtualDevice(ip, Zq.GetElement(HexToBytes(vectors["xd"])), Zq.GetElement(HexToBytes(vectors["wdPrime"]))); IDevicePresentationContext context = device.GetPresentationContext(); // Test device responses Assert.AreEqual(CreateGroupElement(ip.Gq, vectors["hd"]), device.GetDevicePublicKey(), "hd"); Assert.AreEqual(CreateGroupElement(ip.Gq, vectors["ad"]), context.GetInitialWitness(), "ad"); Assert.AreEqual(Zq.GetElement(HexToBytes(vectors["rdPrime"])), context.GetDeviceResponse(HexToBytes(vectors["md"]), HexToBytes(vectors["cp"]), ip.HashFunctionOID), "rdPrime"); hd = CreateGroupElement(ip.Gq, vectors["hd"]); } IssuerProtocolParameters ipp = new IssuerProtocolParameters(ikap); ipp.Attributes = A; ipp.NumberOfTokens = 1; ipp.TokenInformation = TI; ipp.DevicePublicKey = hd; ipp.PreGeneratedW = new FieldZqElement[] { Zq.GetElement(HexToBytes(vectors["w"])) }; Issuer issuer = ipp.CreateIssuer(); byte[] PI = HexToBytes(vectors["PI"]); ProverProtocolParameters ppp = new ProverProtocolParameters(ip); ppp.Attributes = A; ppp.NumberOfTokens = 1; ppp.TokenInformation = TI; ppp.ProverInformation = PI; ppp.DevicePublicKey = hd; ppp.ProverRandomData = new ProverRandomData( new FieldZqElement[] { Zq.GetElement(HexToBytes(vectors["alpha"])) }, new FieldZqElement[] { Zq.GetElement(HexToBytes(vectors["beta1"])) }, new FieldZqElement[] { Zq.GetElement(HexToBytes(vectors["beta2"])) }); Prover prover = ppp.CreateProver(); FirstIssuanceMessage msg1 = issuer.GenerateFirstMessage(); Assert.AreEqual(msg1.sigmaZ, CreateGroupElement(ip.Gq, vectors["sigmaZ"]), "sigmaZ"); Assert.AreEqual(msg1.sigmaA[0], CreateGroupElement(ip.Gq, vectors["sigmaA"]), "sigmaA"); Assert.AreEqual(msg1.sigmaB[0], CreateGroupElement(ip.Gq, vectors["sigmaB"]), "sigmaB"); SecondIssuanceMessage msg2 = prover.GenerateSecondMessage(msg1); Assert.AreEqual(msg2.sigmaC[0], Zq.GetElement(HexToBytes(vectors["sigmaC"])), "sigmaC"); ThirdIssuanceMessage msg3 = issuer.GenerateThirdMessage(msg2); Assert.AreEqual(msg3.sigmaR[0], Zq.GetElement(HexToBytes(vectors["sigmaR"])), "sigmaR"); UProveKeyAndToken[] upkt = prover.GenerateTokens(msg3); Assert.AreEqual(upkt[0].PrivateKey, Zq.GetElement(HexToBytes(vectors["alphaInverse"])), "alphaInverse"); UProveToken token = upkt[0].Token; Assert.AreEqual(token.H, CreateGroupElement(ip.Gq, vectors["h"]), "h"); Assert.AreEqual(token.SigmaZPrime, CreateGroupElement(ip.Gq, vectors["sigmaZPrime"]), "sigmaZPrime"); Assert.AreEqual(token.SigmaCPrime, Zq.GetElement(HexToBytes(vectors["sigmaCPrime"])), "sigmaCPrime"); Assert.AreEqual(token.SigmaRPrime, Zq.GetElement(HexToBytes(vectors["sigmaRPrime"])), "sigmaRPrime"); Assert.IsTrue(HexToBytes(vectors["UIDt"]).SequenceEqual(ProtocolHelper.ComputeTokenID(ip, token)), "UIDt"); Assert.IsTrue(supportDevice == token.IsDeviceProtected); /* * presentation */ int[] disclosed = new int[] { }; if (vectors.ContainsKey("D") && vectors["D"].Length > 0) { disclosed = Array.ConvertAll <string, int>(vectors["D"].Split(','), new Converter <string, int>(stringToInt)); } int[] undisclosed = new int[5 - disclosed.Length]; int dIndex = 0, uIndex = 0; for (int i = 1; i <= 5; i++) { if (disclosed.Length > 0 && disclosed[dIndex] == i) { dIndex++; } else { undisclosed[uIndex++] = i; } } int[] committed = new int[] { }; if (vectors.ContainsKey("C") && vectors["C"].Length > 0) { committed = Array.ConvertAll <string, int>(vectors["C"].Split(','), new Converter <string, int>(stringToInt)); } byte[] m = HexToBytes(vectors["m"]); byte[] md = HexToBytes(vectors["md"]); IDevicePresentationContext deviceContext = null; if (supportDevice) { deviceContext = device.GetPresentationContext(); } int p = 0; if (vectors.ContainsKey("p") && !int.TryParse(vectors["p"], out p)) { p = PresentationProof.DeviceAttributeIndex; } byte[] s = vectors.ContainsKey("s") ? HexToBytes(vectors["s"]) : null; int commitmentIndex = committed.Length > 0 ? committed[0] : 0; ProverPresentationProtocolParameters pppp = new ProverPresentationProtocolParameters(ip, disclosed, m, upkt[0], A); pppp.Committed = committed; pppp.PseudonymAttributeIndex = p; pppp.PseudonymScope = s; pppp.DeviceMessage = md; pppp.DeviceContext = deviceContext; FieldZqElement[] w = new FieldZqElement[undisclosed.Length]; for (int i = 0; i < undisclosed.Length; i++) { w[i] = Zq.GetElement(HexToBytes(vectors["w" + undisclosed[i]])); } FieldZqElement[] tildeO = new FieldZqElement[committed.Length]; FieldZqElement[] tildeW = new FieldZqElement[committed.Length]; for (int i = 0; i < committed.Length; i++) { tildeO[i] = Zq.GetElement(HexToBytes(vectors["tildeO" + committed[i]])); tildeW[i] = Zq.GetElement(HexToBytes(vectors["tildeW" + committed[i]])); } pppp.RandomData = new ProofGenerationRandomData( Zq.GetElement(HexToBytes(vectors["w0"])), w, supportDevice ? Zq.GetElement(HexToBytes(vectors["wd"])) : null, tildeO, tildeW); CommitmentPrivateValues cpv; PresentationProof proof = PresentationProof.Generate(pppp, out cpv); Assert.IsTrue(HexToBytes(vectors["a"]).SequenceEqual(proof.A), "a"); if (vectors.ContainsKey("gs")) { Assert.AreEqual(ProtocolHelper.GenerateScopeElement(ip.Gq, s), CreateGroupElement(ip.Gq, vectors["gs"])); Assert.IsTrue(HexToBytes(vectors["ap"]).SequenceEqual(proof.Ap), "ap"); Assert.AreEqual(proof.Ps, CreateGroupElement(ip.Gq, vectors["Ps"]), "Ps"); } for (int i = 0; i < disclosed.Length; i++) { Assert.IsTrue(HexToBytes(vectors["A" + disclosed[i]]).SequenceEqual(proof.DisclosedAttributes[i]), "A" + disclosed[i]); } Assert.AreEqual(proof.R[0], Zq.GetElement(HexToBytes(vectors["r0"])), "r0"); for (int i = 0; i < undisclosed.Length; i++) { Assert.AreEqual(proof.R[i + 1], Zq.GetElement(HexToBytes(vectors["r" + undisclosed[i]])), "r" + undisclosed[i]); } if (supportDevice) { Assert.AreEqual(proof.R[proof.R.Length - 1], Zq.GetElement(HexToBytes(vectors["rd"])), "rd"); } for (int i = 0; i < committed.Length; i++) { Assert.AreEqual(proof.Commitments[i].TildeR, Zq.GetElement(HexToBytes(vectors["tildeR" + committed[i]])), "tildeR" + committed[i]); Assert.IsTrue(cpv.TildeO.Length == committed.Length); Assert.AreEqual(cpv.TildeO[i], Zq.GetElement(HexToBytes(vectors["tildeO" + committed[i]])), "tildeO" + committed[i]); } VerifierPresentationProtocolParameters vppp = new VerifierPresentationProtocolParameters(ip, disclosed, m, upkt[0].Token); vppp.Committed = committed; vppp.PseudonymAttributeIndex = p; vppp.PseudonymScope = s; vppp.DeviceMessage = md; proof.Verify(vppp); #if TEST_ID_ESCROW if (committed.Length > 0) { IDEscrowParams escrowParams = new IDEscrowParams(ip); IDEscrowPrivateKey escrowPrivateKey = new IDEscrowPrivateKey(Zq.GetElement(HexToBytes(vectors["ie_x"]))); IDEscrowPublicKey escrowPublicKey = new IDEscrowPublicKey(escrowParams, escrowPrivateKey); Assert.AreEqual(escrowPublicKey.H, CreateGroupElement(ip.Gq, vectors["ie_H"]), "ie_H"); byte[] additionalInfo = HexToBytes(vectors["ie_additionalInfo"]); int ie_bIndex = int.Parse(vectors["ie_b"]); IDEscrowCiphertext ctext = IDEscrowFunctions.VerifiableEncrypt( escrowParams, escrowPublicKey, HexToBytes(vectors["UIDt"]), proof.Commitments[0].TildeC, ProtocolHelper.ComputeXi(ip, ie_bIndex - 1, A[ie_bIndex - 1]), cpv.TildeO[0], additionalInfo, new IDEscrowFunctions.IDEscrowProofGenerationRandomData( Zq.GetElement(HexToBytes(vectors["ie_r"])), Zq.GetElement(HexToBytes(vectors["ie_xbPrime"])), Zq.GetElement(HexToBytes(vectors["ie_rPrime"])), Zq.GetElement(HexToBytes(vectors["ie_obPrime"])))); Assert.IsTrue(IDEscrowFunctions.UProveVerify(escrowParams, ctext, proof, upkt[0].Token, escrowPublicKey)); Assert.AreEqual(ctext.E1, CreateGroupElement(ip.Gq, vectors["ie_E1"]), "ie_E1"); Assert.AreEqual(ctext.E2, CreateGroupElement(ip.Gq, vectors["ie_E2"]), "ie_E2"); Assert.AreEqual(ctext.proof.c, Zq.GetElement(HexToBytes(vectors["ie_c"])), "ie_c"); Assert.AreEqual(ctext.proof.rR, Zq.GetElement(HexToBytes(vectors["ie_rr"])), "ie_rr"); Assert.AreEqual(ctext.proof.rXb, Zq.GetElement(HexToBytes(vectors["ie_rxb"])), "ie_rxb"); Assert.AreEqual(ctext.proof.rOb, Zq.GetElement(HexToBytes(vectors["ie_rob"])), "ie_rob"); GroupElement PE = IDEscrowFunctions.Decrypt(escrowParams, ctext, escrowPrivateKey); } #endif #if TEST_DVA_REVOCATION if (committed.Length > 0) { RAParameters raParams = new RAParameters(ip.Gq.GroupName, CreateGroupElement(ip.Gq, vectors["r_K"]), ip.UidH); FieldZqElement delta = Zq.GetElement(HexToBytes(vectors["r_delta"])); RevocationAuthority RA = new RevocationAuthority(raParams, delta); HashSet <FieldZqElement> revoked = new HashSet <FieldZqElement>(); for (int i = 1; i <= 4; i++) { revoked.Add(Zq.GetElement(HexToBytes(vectors["r_R" + i]))); } RA.UpdateAccumulator(revoked, null); Assert.AreEqual(RA.Accumulator, CreateGroupElement(ip.Gq, vectors["r_V"]), "r_V"); int r_id = 0; int.TryParse(vectors["r_id"], out r_id); RevocationWitness witness = RA.ComputeRevocationWitness(revoked, Zq.GetElement(HexToBytes(vectors["x" + r_id]))); Assert.AreEqual(witness.d, Zq.GetElement(HexToBytes(vectors["r_d"])), "r_d"); Assert.AreEqual(witness.W, CreateGroupElement(ip.Gq, vectors["r_W"]), "r_W"); Assert.AreEqual(witness.Q, CreateGroupElement(ip.Gq, vectors["r_Q"]), "r_Q"); NonRevocationProof nrProof = RevocationUser.GenerateNonRevocationProof( raParams, witness, proof.Commitments[0].TildeC, ProtocolHelper.ComputeXi(ip, r_id - 1, A[r_id - 1]), cpv.TildeO[0], new NonRevocationProofGenerationRandomData(new FieldZqElement[] { Zq.GetElement(HexToBytes(vectors["r_t1"])), Zq.GetElement(HexToBytes(vectors["r_t2"])), Zq.GetElement(HexToBytes(vectors["r_k1"])), Zq.GetElement(HexToBytes(vectors["r_k2"])), Zq.GetElement(HexToBytes(vectors["r_k3"])), Zq.GetElement(HexToBytes(vectors["r_k4"])), Zq.GetElement(HexToBytes(vectors["r_k5"])), Zq.GetElement(HexToBytes(vectors["r_k6"])) })); Assert.AreEqual(nrProof.X, CreateGroupElement(ip.Gq, vectors["r_X"]), "r_X"); Assert.AreEqual(nrProof.Y, CreateGroupElement(ip.Gq, vectors["r_Y"]), "r_Y"); Assert.AreEqual(nrProof.Cd, CreateGroupElement(ip.Gq, vectors["r_Cd"]), "r_Cd"); Assert.AreEqual(nrProof.cPrime, Zq.GetElement(HexToBytes(vectors["r_cPrime"])), "r_cPrime"); Assert.AreEqual(nrProof.s[0], Zq.GetElement(HexToBytes(vectors["r_s1"])), "r_s1"); Assert.AreEqual(nrProof.s[1], Zq.GetElement(HexToBytes(vectors["r_s2"])), "r_s2"); Assert.AreEqual(nrProof.s[2], Zq.GetElement(HexToBytes(vectors["r_s3"])), "r_s3"); Assert.AreEqual(nrProof.s[3], Zq.GetElement(HexToBytes(vectors["r_s4"])), "r_s4"); Assert.AreEqual(nrProof.s[4], Zq.GetElement(HexToBytes(vectors["r_s5"])), "r_s5"); Assert.AreEqual(nrProof.s[5], Zq.GetElement(HexToBytes(vectors["r_s6"])), "r_s6"); // validate proof RA.VerifyNonRevocationProof(ip, 0, proof, nrProof); } #endif #if TEST_SET_MEMBERSHIP if (committed.Length > 0) { int sm_x_index = 0; int.TryParse(vectors["sm_x_index"], out sm_x_index); int sm_n = 0; int.TryParse(vectors["sm_n"], out sm_n); int sm_i = 0; int.TryParse(vectors["sm_i"], out sm_i); byte[][] setValues = new byte[sm_n][]; FieldZqElement[] sm_c = new FieldZqElement[sm_n - 1]; FieldZqElement[] sm_r = new FieldZqElement[sm_n - 1]; int randomIndex = 0; for (int i = 1; i <= sm_n; i++) { if (i == sm_i) { setValues[i - 1] = HexToBytes(vectors["A" + sm_x_index]); } else { setValues[i - 1] = HexToBytes(vectors["sm_s" + i]); sm_c[randomIndex] = Zq.GetElement(HexToBytes(vectors["sm_c" + i])); sm_r[randomIndex] = Zq.GetElement(HexToBytes(vectors["sm_r" + i])); randomIndex++; } } SetMembershipProofGenerationRandomData smRandom = new SetMembershipProofGenerationRandomData(sm_c, sm_r, Zq.GetElement(HexToBytes(vectors["sm_w"]))); SetMembershipProof setMembershipProof = SetMembershipProof.Generate(pppp, proof, cpv, sm_x_index, setValues, smRandom); for (int i = 1; i <= sm_n; i++) { Assert.AreEqual(setMembershipProof.a[i - 1], CreateGroupElement(ip.Gq, vectors["sm_a" + i]), "sm_a" + i); if (i < sm_n) // no c_n in the proof { Assert.AreEqual(setMembershipProof.c[i - 1], Zq.GetElement(HexToBytes(vectors["sm_c" + i])), "sm_c" + i); } Assert.AreEqual(setMembershipProof.r[i - 1], Zq.GetElement(HexToBytes(vectors["sm_r" + i])), "sm_r" + i); } if (!SetMembershipProof.Verify(vppp, proof, setMembershipProof, sm_x_index, setValues)) { throw new InvalidUProveArtifactException("Invalid set membership proof"); } } #endif } } } } sw.Stop(); Debug.WriteLine("Protocol Test Elapsed Time: " + sw.ElapsedMilliseconds + "ms"); }