Esempio n. 1
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        public IKdfMultiExpansionParameter CreateParameter(TwoStepMultiExpansionConfiguration kdfConfiguration)
        {
            var iterationCount      = _random.GetRandomInt(2, 5);
            var iterationParameters = new List <KdfMultiExpansionIterationParameter>();

            for (var i = 0; i < iterationCount; i++)
            {
                iterationParameters.Add(new KdfMultiExpansionIterationParameter(kdfConfiguration.L, _entropyProvider.GetEntropy(BitsOfEntropy)));
            }

            return(new KdfMultiExpansionParameterTwoStep()
            {
                Salt = kdfConfiguration.SaltMethod == MacSaltMethod.Default ?
                       new BitString(kdfConfiguration.SaltLen) :
                       _entropyProvider.GetEntropy(kdfConfiguration.SaltLen),
                Iv = kdfConfiguration.IvLen == 0 ?
                     null :
                     _entropyProvider.GetEntropy(kdfConfiguration.IvLen),
                KdfMode = kdfConfiguration.KdfMode,
                MacMode = kdfConfiguration.MacMode,
                CounterLen = kdfConfiguration.CounterLen,
                CounterLocation = kdfConfiguration.CounterLocation,
                Z = _entropyProvider.GetEntropy(BitsOfEntropy),
                IterationParameters = iterationParameters
            });
        }
Esempio n. 2
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        public KdfResult Kdf(KdfParameterOneStep param, BitString fixedInfo)
        {
            var result      = _kdfVisitor.Kdf(param, fixedInfo);
            var dkmBytesLen = result.DerivedKey.BitLength.CeilingDivide(BitString.BITSINBYTE);

            // Modify a random byte within DKM
            result.DerivedKey[_random.GetRandomInt(0, dkmBytesLen)] += 2;

            return(result);
        }
Esempio n. 3
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        public SharedSecretResponse Encrypt(PublicKey rsaPublicKey, BitString keyingMaterial, BitString additionalInput)
        {
            var keyingMaterialByteLen = keyingMaterial.BitLength.CeilingDivide(BitString.BITSINBYTE);

            var newKeyingMaterial = keyingMaterial.GetDeepCopy();

            // Modify a random byte in the keying material prior to executing the base method
            newKeyingMaterial[_random.GetRandomInt(0, keyingMaterialByteLen)] += 2;

            return(_kts.Encrypt(rsaPublicKey, newKeyingMaterial, additionalInput));
        }
        public SharedSecretResponse Encrypt(PublicKey rsaPublicKey, BitString keyingMaterial, BitString additionalInput)
        {
            var result = _kts.Encrypt(rsaPublicKey, keyingMaterial, additionalInput);

            var dkmByteLen = result.SharedSecretZ.BitLength.CeilingDivide(BitString.BITSINBYTE);

            // Modify a random byte in the result prior to returning
            result.SharedSecretZ[_random.GetRandomInt(0, dkmByteLen)] += 2;

            return(result);
        }
Esempio n. 5
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        public KdfResult Kdf(KdfParameterOneStep param, BitString fixedInfo)
        {
            var zBytesLen = param.Z.BitLength.CeilingDivide(BitString.BITSINBYTE);

            var modifiedParam = new KdfParameterOneStep()
            {
                L                  = param.L,
                Salt               = param.Salt,
                Z                  = param.Z.GetDeepCopy(),
                AuxFunction        = param.AuxFunction,
                FixedInfoPattern   = param.FixedInfoPattern,
                FixedInputEncoding = param.FixedInputEncoding
            };

            // Modify a random byte within Z
            modifiedParam.Z[_random.GetRandomInt(0, zBytesLen)] += 2;

            return(_kdfVisitor.Kdf(modifiedParam, fixedInfo));
        }
        private int GetNextRandomValue(bool isRecursiveInvoke = false)
        {
            int value = _random.GetRandomInt(_min, _max);

            if (IsWithinDomain(value) && !_returnedValues.Contains(value))
            {
                _returnedValues.Add(value);
                return(value);
            }

            // Find a value that falls within the domain
            // By adding and/or subtracting to the random value until encountering a value that
            // Is within the domain, and has not yet been used.
            for (int i = 1; i <= _increment * (_returnedValues.Count + 1); i++)
            {
                int addToValue = value + i;
                if (IsWithinDomain(addToValue) && !_returnedValues.Contains(addToValue))
                {
                    _returnedValues.Add(addToValue);
                    return(addToValue);
                }

                int subtractFromValue = value - i;
                if (IsWithinDomain(subtractFromValue) && !_returnedValues.Contains(subtractFromValue))
                {
                    _returnedValues.Add(subtractFromValue);
                    return(subtractFromValue);
                }
            }

            // If we hit this point and are not in a recursive invoke of the method
            // then the domain has been exhausted of values.
            // We can reset the "list" of values to produce (again) values from the original range.
            if (!isRecursiveInvoke)
            {
                _returnedValues.Clear();
                return(GetNextRandomValue(true));
            }

            // if however, this is a recursive call, then we have all ready attempted to do the above and we'll
            // never be able to produce values from the range in the conditions specified.
            // Rather than hit the stack overflow exception that is going to occur, fail out early.
            throw new ConstraintException("Requested condition for values from domain will never be satisfied.");
        }