void BenchMarkKeyGen(const char *name, AuthenticatedKeyAgreementDomain &d, double timeTotal, bool pc=false) { SecByteBlock priv(d.EphemeralPrivateKeyLength()), pub(d.EphemeralPublicKeyLength()); const clock_t start = clock(); unsigned int i; double timeTaken; for (timeTaken=(double)0, i=0; timeTaken < timeTotal; timeTaken = double(clock() - start) / CLOCK_TICKS_PER_SECOND, i++) d.GenerateEphemeralKeyPair(GlobalRNG(), priv, pub); OutputResultOperations(name, "Key-Pair Generation", pc, i, timeTaken); if (!pc && d.GetMaterial().SupportsPrecomputation()) { d.AccessMaterial().Precompute(16); BenchMarkKeyGen(name, d, timeTotal, true); } }
bool AuthenticatedKeyAgreementValidate(AuthenticatedKeyAgreementDomain &d) { if (d.GetCryptoParameters().Validate(GlobalRNG(), 3)) cout << "passed authenticated key agreement domain parameters validation" << endl; else { cout << "FAILED authenticated key agreement domain parameters invalid" << endl; return false; } SecByteBlock spriv1(d.StaticPrivateKeyLength()), spriv2(d.StaticPrivateKeyLength()); SecByteBlock epriv1(d.EphemeralPrivateKeyLength()), epriv2(d.EphemeralPrivateKeyLength()); SecByteBlock spub1(d.StaticPublicKeyLength()), spub2(d.StaticPublicKeyLength()); SecByteBlock epub1(d.EphemeralPublicKeyLength()), epub2(d.EphemeralPublicKeyLength()); SecByteBlock val1(d.AgreedValueLength()), val2(d.AgreedValueLength()); d.GenerateStaticKeyPair(GlobalRNG(), spriv1, spub1); d.GenerateStaticKeyPair(GlobalRNG(), spriv2, spub2); d.GenerateEphemeralKeyPair(GlobalRNG(), epriv1, epub1); d.GenerateEphemeralKeyPair(GlobalRNG(), epriv2, epub2); memset(val1.begin(), 0x10, val1.size()); memset(val2.begin(), 0x11, val2.size()); if (!(d.Agree(val1, spriv1, epriv1, spub2, epub2) && d.Agree(val2, spriv2, epriv2, spub1, epub1))) { cout << "FAILED authenticated key agreement failed" << endl; return false; } if (!VerifyBufsEqual(val1.begin(), val2.begin(), d.AgreedValueLength())) { cout << "FAILED authenticated agreed values not equal" << endl; return false; } cout << "passed authenticated key agreement" << endl; return true; }
void BenchMarkAgreement(const char *name, AuthenticatedKeyAgreementDomain &d, double timeTotal, bool pc=false) { SecByteBlock spriv1(d.StaticPrivateKeyLength()), spriv2(d.StaticPrivateKeyLength()); SecByteBlock epriv1(d.EphemeralPrivateKeyLength()), epriv2(d.EphemeralPrivateKeyLength()); SecByteBlock spub1(d.StaticPublicKeyLength()), spub2(d.StaticPublicKeyLength()); SecByteBlock epub1(d.EphemeralPublicKeyLength()), epub2(d.EphemeralPublicKeyLength()); d.GenerateStaticKeyPair(GlobalRNG(), spriv1, spub1); d.GenerateStaticKeyPair(GlobalRNG(), spriv2, spub2); d.GenerateEphemeralKeyPair(GlobalRNG(), epriv1, epub1); d.GenerateEphemeralKeyPair(GlobalRNG(), epriv2, epub2); SecByteBlock val(d.AgreedValueLength()); const clock_t start = clock(); unsigned int i; double timeTaken; for (timeTaken=(double)0, i=0; timeTaken < timeTotal; timeTaken = double(clock() - start) / CLOCK_TICKS_PER_SECOND, i+=2) { d.Agree(val, spriv1, epriv1, spub2, epub2); d.Agree(val, spriv2, epriv2, spub1, epub1); } OutputResultOperations(name, "Key Agreement", pc, i, timeTaken); }