Exemplo n.º 1
0
        public static double[] ClassicalAttackXORAPUFMultiRecovered(int bitNumber, int attackRepeatNumber, InvariantData invData, VariantData[] variantDataArray)
        {
            //Create the XOR APUF for parallel runs
            XORArbiterPUF[] xArray = new XORArbiterPUF[attackRepeatNumber];
            for (int i = 0; i < xArray.Length; i++)
            {
                xArray[i] = (XORArbiterPUF)invData.GetPUFatIndex(i);
            }

            sbyte[][] trainingData         = invData.GetTrainingData();        //these will be phi vectors
            sbyte[][] allTrainingResponses = invData.GetTrainingResponseAll(); //first index PUF, second index sample

            //create the objective function for parallel runs
            ObjectiveFunctionResponseXOR[] rObjArray = new ObjectiveFunctionResponseXOR[attackRepeatNumber];
            for (int i = 0; i < rObjArray.Length; i++)
            {
                rObjArray[i] = new ObjectiveFunctionResponseXOR();
            }
            double[][] solutionList = new double[attackRepeatNumber][];

            Random[] randomGeneratorArray = new Random[attackRepeatNumber];
            for (int r = 0; r < attackRepeatNumber; r++)
            {
                randomGeneratorArray[r] = new Random((int)DateTime.Now.Ticks);
                System.Threading.Thread.Sleep(10); //prevent the random number generators from being the same
            }

            var watch = System.Diagnostics.Stopwatch.StartNew();

            Parallel.For(0, attackRepeatNumber, a =>
            {
                Random randomGenerator   = randomGeneratorArray[a];                 //remove the dependences for parallelization
                int dimensionNumber      = (bitNumber + 1) * xArray[a].GetPUFNum(); //the weights of all the XOR APUFs
                sbyte[] trainingResponse = allTrainingResponses[a];
                //Generate the first solution randomly for CMA-ES
                double[] firstSolution = new double[dimensionNumber];
                for (int i = 0; i < firstSolution.Length; i++)
                {
                    firstSolution[i] = randomGenerator.NextDouble();
                }
                Console.Out.WriteLine("Beginning CMA-ES run # " + a.ToString());
                //CMAESCandidate solutionCMAES = CMAESMethods.ComputeCMAES(dimensionNumber, rObjArray[a], trainingData, trainingResponse, firstSolution, randomGenerator);
                CMAESCandidate solutionCMAES = CMAESMethods.RecoveredCMAES(randomGenerator, a, rObjArray[a], invData, variantDataArray[a]);
                double solutionVal           = solutionCMAES.GetObjectiveFunctionValue();
                solutionList[a] = solutionCMAES.GetWeightVector(); //store the solution in independent memory
                Console.Out.WriteLine("CMA-ES on core " + a.ToString() + " finished.");
                //Console.Out.WriteLine("Final training value is "+solutionVal.ToString());
                //}
            });
            watch.Stop();
            Console.Out.WriteLine("Elapsed Time is " + watch.ElapsedMilliseconds.ToString());

            //measure the accuracy
            Random randomGenerator2 = new Random((int)DateTime.Now.Ticks);
            double averageAccuracy  = 0;

            double[] solutionAccuracies = new double[attackRepeatNumber];
            for (int a = 0; a < solutionList.Length; a++)
            {
                sbyte[][] testingData     = new sbyte[AppConstants.TestingSize][]; //these will be phi vectors
                sbyte[]   testingResponse = new sbyte[AppConstants.TestingSize];
                DataGeneration.GenerateTrainingData(xArray[a], testingData, testingResponse, randomGenerator2);
                double accMeasures = rObjArray[0].ObjFunValue(solutionList[a], testingData, testingResponse);
                solutionAccuracies[a] = accMeasures;
                averageAccuracy       = averageAccuracy + accMeasures;
            }
            averageAccuracy = averageAccuracy / (double)attackRepeatNumber;
            Console.Out.WriteLine("The average accuracy for the XOR APUF is " + averageAccuracy.ToString());
            return(solutionAccuracies);
        }
Exemplo n.º 2
0
        //Attack different XOR APUFs (same type) in parallel
        //public static void RepeatAttackOnePUFType()
        //{
        //    int attackNumber = 40;

        //    double[] currentAccuracies = ClassicalAttackXORAPUFMulti(bitNumber, xorNumber, AppConstants.CoreNumber);
        //}

        //int bitNumber = 128;
        //int xorNumber = 4;
        //Runs attack multiple times, each time it is on a DIFFERENT XOR APUF
        public static double[] ClassicalAttackXORAPUFMulti(int bitNumber, int numXOR, int attackRepeatNumber)
        {
            //Generate a PUF
            double aPUFMean      = 0.0;
            double aPUFVar       = 1.0;
            double aPUFMeanNoise = 0.0;
            double aPUFNoiseVar  = 0.0;

            //Create the XOR APUF for parallel runs
            XORArbiterPUF xPUF = new XORArbiterPUF(numXOR, bitNumber, aPUFMean, aPUFVar, aPUFMeanNoise, aPUFNoiseVar);

            XORArbiterPUF[] xArray = new XORArbiterPUF[attackRepeatNumber];
            for (int i = 0; i < xArray.Length; i++)
            {
                xArray[i] = new XORArbiterPUF(numXOR, bitNumber, aPUFMean, aPUFVar, aPUFMeanNoise, aPUFNoiseVar);
            }

            sbyte[][] trainingData         = new sbyte[AppConstants.TrainingSize][]; //these will be phi vectors
            sbyte[][] allTrainingResponses = new sbyte[attackRepeatNumber][];        //first index PUF, second index sample

            for (int i = 0; i < attackRepeatNumber; i++)
            {
                allTrainingResponses[i] = new sbyte[AppConstants.TrainingSize];
            }
            Random[] rGenArray = new Random[AppConstants.CoreNumber];
            for (int i = 0; i < AppConstants.CoreNumber; i++)
            {
                rGenArray[i] = new Random((int)DateTime.Now.Ticks);
                System.Threading.Thread.Sleep(10); //prevent the random number generators from being the same
            }
            DataGeneration.GenerateTrainingDataParallel(xArray, trainingData, allTrainingResponses, rGenArray);
            Console.Out.WriteLine("Data Generation Complete.");

            //create the objective function for parallel runs
            ObjectiveFunctionResponseXOR[] rObjArray = new ObjectiveFunctionResponseXOR[attackRepeatNumber];
            for (int i = 0; i < rObjArray.Length; i++)
            {
                rObjArray[i] = new ObjectiveFunctionResponseXOR();
            }
            double[][] solutionList = new double[attackRepeatNumber][];

            Random[] randomGeneratorArray = new Random[attackRepeatNumber];
            for (int r = 0; r < attackRepeatNumber; r++)
            {
                randomGeneratorArray[r] = new Random((int)DateTime.Now.Ticks);
                System.Threading.Thread.Sleep(10); //prevent the random number generators from being the same
            }

            //time to save the invariant data
            //if (AppConstants.IsLargeData == false)
            //{
            InvariantData invD      = new InvariantData(trainingData, allTrainingResponses, xArray);
            string        dayString = System.DateTime.Today.ToString();

            dayString = dayString.Replace(@"/", "-");
            dayString = dayString.Replace(" ", string.Empty);
            dayString = dayString.Replace(":", string.Empty);
            string          invariantDataFileName = "InvariantData" + dayString;
            string          fName = AppConstants.SaveDir + invariantDataFileName;
            FileInfo        fi    = new FileInfo(fName);
            Stream          str   = fi.Open(FileMode.OpenOrCreate, FileAccess.Write);
            BinaryFormatter bf    = new BinaryFormatter();

            invD.Serialize(bf, str);
            str.Close();

            var watch = System.Diagnostics.Stopwatch.StartNew();

            Parallel.For(0, attackRepeatNumber, a =>
            {
                Random randomGenerator   = randomGeneratorArray[a];                 //remove the dependences for parallelization
                int dimensionNumber      = (bitNumber + 1) * xArray[a].GetPUFNum(); //the weights of all the XOR APUFs
                sbyte[] trainingResponse = allTrainingResponses[a];
                //Generate the first solution randomly for CMA-ES
                double[] firstSolution = new double[dimensionNumber];
                for (int i = 0; i < firstSolution.Length; i++)
                {
                    firstSolution[i] = randomGenerator.NextDouble();
                }
                Console.Out.WriteLine("Beginning CMA-ES run # " + a.ToString());
                //CMAESCandidate solutionCMAES = CMAESMethods.ComputeCMAES(dimensionNumber, rObjArray[a], trainingData, trainingResponse, firstSolution, randomGenerator);
                CMAESCandidate solutionCMAES = CMAESMethods.ComputeCMAESRecoverable(dimensionNumber, rObjArray[a], trainingData, trainingResponse, firstSolution, randomGenerator, a);
                double solutionVal           = solutionCMAES.GetObjectiveFunctionValue();
                solutionList[a] = solutionCMAES.GetWeightVector(); //store the solution in independent memory
                Console.Out.WriteLine("CMA-ES on core " + a.ToString() + " finished.");
            });
            watch.Stop();
            Console.Out.WriteLine("Elapsed Time is " + watch.ElapsedMilliseconds.ToString());

            //measure the accuracy
            Random randomGenerator2 = new Random((int)DateTime.Now.Ticks);
            double averageAccuracy  = 0;

            double[] solutionAccuracies = new double[attackRepeatNumber];
            for (int a = 0; a < solutionList.Length; a++)
            {
                sbyte[][] testingData     = new sbyte[AppConstants.TestingSize][]; //these will be phi vectors
                sbyte[]   testingResponse = new sbyte[AppConstants.TestingSize];
                DataGeneration.GenerateTrainingData(xArray[a], testingData, testingResponse, randomGenerator2);
                double accMeasures = rObjArray[0].ObjFunValue(solutionList[a], testingData, testingResponse);
                solutionAccuracies[a] = accMeasures;
                averageAccuracy       = averageAccuracy + accMeasures;
            }
            averageAccuracy = averageAccuracy / (double)attackRepeatNumber;
            Console.Out.WriteLine("The average accuracy for the XOR APUF is " + averageAccuracy.ToString());
            return(solutionAccuracies);
        }
Exemplo n.º 3
0
        //Run the CMA-ES from a recovered file
        public static CMAESCandidate RecoveredCMAES(Random randomGenerator, int coreNumberForSaving, PUFObjectiveFunction pFunction, InvariantData invData, VariantData varData)
        {
            double stopFitness = 0.98;
            //non-specific variables (used by each core)
            int stopeval = invData.GetMaxEval();

            sbyte[][] trainingData = invData.GetTrainingData();
            sbyte[]   targets      = invData.GetTrainingResponseForPUF(coreNumberForSaving);

            //core specific variables (specific to each run of CMA-ES)
            int             counteval           = varData.GetCurrentEval();
            int             n                   = varData.GetDimensionNum();
            int             lambdaVal           = varData.GetLambda();
            Matrix <double> xMean               = varData.GetXMean();
            Matrix <double> D                   = varData.GetD();
            Matrix <double> B                   = varData.GetB();
            double          sigma               = varData.GetSigma();
            Matrix <double> weights             = varData.GetWeights();
            Matrix <double> ps                  = varData.GetPS();
            double          cs                  = varData.GetCS();
            double          mueff               = varData.GetMueff();
            double          cc                  = varData.GetCC();
            Matrix <double> pc                  = varData.GetPC();
            Matrix <double> invsqrtC            = varData.GetInvSqrtC();
            Matrix <double> C                   = varData.GetMatrixC();
            double          mu                  = varData.GetMu();
            double          c1                  = varData.GetC1();
            double          cmu                 = varData.GetCmu();
            double          damps               = varData.GetDamps();
            double          chiN                = varData.GetChiN();
            double          eigeneval           = varData.GetEigenVal();
            CMAESCandidate  globalBestCandidate = varData.GetGlobalBest();

            Matrix <double> oneOverD = Matrix <double> .Build.Dense(n, 1); //Don't need to copy this because we get it from D

            //just a sanity check
            if (varData.coreNumber != coreNumberForSaving)
            {
                throw new Exception("The saved core number and current core number don't match.");
            }

            //the next 40 lines contain the 20 lines of interesting code
            //CMAESCandidate[] candidateArray = new CMAESCandidate[lambdaVal];
            List <CMAESCandidate> candidateArray = new List <CMAESCandidate>();

            for (int i = 0; i < lambdaVal; i++)
            {
                candidateArray.Add(new CMAESCandidate());
            }

            while (counteval < stopeval)
            {
                Matrix <double> arx = Matrix <double> .Build.Dense(n, lambdaVal);

                //fill in the initial solutions
                for (int i = 0; i < lambdaVal; i++)
                {
                    Matrix <double> randD = Matrix <double> .Build.Dense(n, 1);

                    for (int j = 0; j < n; j++)
                    {
                        randD[j, 0] = D[j, 0] * GenerateRandomNormalVariableForCMAES(randomGenerator, 0, 1.0);
                    }
                    Matrix <double> inputVector      = xMean + sigma * B * randD;
                    double[]        tempWeightVector = new double[inputVector.RowCount];
                    for (int k = 0; k < inputVector.RowCount; k++)
                    {
                        tempWeightVector[k] = inputVector[k, 0];
                    }
                    candidateArray[i] = new CMAESCandidate(tempWeightVector, trainingData, targets, pFunction);
                    counteval         = counteval + 1;
                }
                candidateArray.Sort(); //This maybe problematic, not sure about sorting in C#
                candidateArray.Reverse();
                Matrix <double> xOld = xMean.Clone();
                //Get the new mean value
                Matrix <double> arxSubset = Matrix <double> .Build.Dense(n, (int)mu); //in Maltab this variable would be "arx(:,arindex(1:mu))

                //This replaces line  arxSubset[:, i] = CandidateList[i].InputVector
                for (int i = 0; i < mu; i++)
                {
                    for (int j = 0; j < n; j++)
                    {
                        arxSubset[j, i] = candidateArray[i].GetWeightVector()[j];
                    }
                }
                xMean = arxSubset * weights; //Line 76 Matlab
                //Cumulation: Update evolution paths
                ps = (1 - cs) * ps + Math.Sqrt(cs * (2.0 - cs) * mueff) * invsqrtC * (xMean - xOld) / sigma;
                //Compute ps.^2 equivalent
                double psSquare = 0;
                for (int i = 0; i < ps.RowCount; i++)
                {
                    psSquare = psSquare + ps[i, 0] * ps[i, 0];
                }

                //Compute hsig
                double hSig         = 0.0;
                double term1ForHsig = psSquare / (1.0 - Math.Pow(1.0 - cs, 2.0 * counteval / lambdaVal)) / n;
                double term2ForHsig = 2.0 + 4.0 / (n + 1.0);
                if (term1ForHsig < term2ForHsig)
                {
                    hSig = 1.0;
                }
                //Compute pc, Line 82 Matlab
                pc = (1.0 - cc) * pc + hSig * Math.Sqrt(cc * (2.0 - cc) * mueff) * (xMean - xOld) / sigma;
                //Adapt covariance matrix C
                Matrix <double> repmatMatrix = Tile((int)mu, xOld); //NOT SURE IF THIS IS RIGHT IN C# FIX repmatMatrix = numpy.tile(xold, mu)
                Matrix <double> artmp        = (1.0 / sigma) * (arxSubset - repmatMatrix);
                // C = (1-c1-cmu) * C  + c1 * (pc * pc' + (1-hsig) * cc*(2-cc) * C) + cmu * artmp * diag(weights) * artmp' #This is the original Matlab line for reference
                C = (1.0 - c1 - cmu) * C + c1 * (pc * pc.Transpose() + (1 - hSig) * cc * (2.0 - cc) * C) + cmu * artmp * Diagonalize1DMatrix(weights) * artmp.Transpose();
                //Adapt step size sigma
                //sigma = sigma * Math.Exp((cs / damps) * (numpy.linalg.norm(ps) / chiN - 1))
                sigma = sigma * Math.Exp((cs / damps) * (ps.L2Norm() / chiN - 1)); //NOT SURE IF THIS IS RIGHT FIX IN C#
                //Update B and D from C
                if ((counteval - eigeneval) > (lambdaVal / (c1 + cmu) / n / 10.0))
                {
                    eigeneval = counteval;
                    //C = numpy.triu(C) + numpy.transpose(numpy.triu(C, 1)) #enforce symmetry
                    C = C.UpperTriangle() + C.StrictlyUpperTriangle().Transpose(); //NOT SURE IF THIS IS RIGHT FIX IN C#

                    //eigen decomposition
                    Evd <double> eigen = C.Evd();
                    B = eigen.EigenVectors;
                    Vector <System.Numerics.Complex> vectorEigenValues = eigen.EigenValues;
                    for (int i = 0; i < vectorEigenValues.Count; i++)
                    {
                        D[i, 0] = vectorEigenValues[i].Real;
                    }
                    //take sqrt of D
                    for (int i = 0; i < vectorEigenValues.Count; i++)
                    {
                        D[i, 0] = Math.Sqrt(D[i, 0]);
                    }

                    for (int i = 0; i < n; i++)
                    {
                        oneOverD[i, 0] = 1.0 / D[i, 0];
                    }
                    Matrix <double> middleTerm = Diagonalize1DMatrix(oneOverD); //#Built in Numpy function doesn't create the right size matrix in this case (ex: Numpy gives 1x1 but should be 5x5)
                    invsqrtC = B * middleTerm * B.Transpose();
                }

                globalBestCandidate = candidateArray[0];
                //Stopping condition
                if (globalBestCandidate.GetObjectiveFunctionValue() > stopFitness)
                {
                    return(globalBestCandidate);
                }

                //Time to save the state
                VariantData     varDataUpdated = new VariantData(coreNumberForSaving, counteval, n, lambdaVal, xMean, D, B, sigma, weights, ps, cs, mueff, cc, invsqrtC, C, mu, pc, c1, cmu, damps, chiN, eigeneval, globalBestCandidate);
                string          fname          = AppConstants.SaveDir + counteval.ToString() + "VariantData" + coreNumberForSaving.ToString();
                FileInfo        fi             = new FileInfo(fname);
                Stream          str            = fi.Open(FileMode.OpenOrCreate, FileAccess.Write);
                BinaryFormatter bf             = new BinaryFormatter();
                bf.Serialize(str, varDataUpdated);
                str.Close();

                Console.Out.WriteLine("Iteration #" + counteval.ToString());
                Console.Out.WriteLine("Current Value=" + (candidateArray[candidateArray.Count - 1].GetObjectiveFunctionValue()).ToString());
            }//end while loop
            return(globalBestCandidate); //just in case everything terminates
        }