public Main() { try { BufferedReader in; in = new BufferedReader(new InputStreamReader(System.in)); // Used for CCC int numLights = Integer.parseInt(in.readLine()); int[] states = new int[numLights]; for (int i = 0; i < numLights; i++) { states[i] = Integer.parseInt(in.readLine()); } ArrayDeque<Scenario> Q = new ArrayDeque<Scenario>(); HashMap<String, Integer> dp = new HashMap<String, Integer>(); int moves = 0; Q.addLast(new Scenario(states)); while (!Q.isEmpty()) { int size = Q.size(); for (int q = 0; q < size; q++) { Scenario temp = Q.removeFirst(); if (isEmpty(temp.states)) { System.out.println(moves); return; } else { for (int i = 0; i < temp.states.length; i++) { if (temp.states[i] == 0) { int[] newArr = Arrays.copyOf(temp.states, temp.states.length); newArr[i] = 1; newArr = fixArray(newArr); String arr = ""; for (int p = 0; p < newArr.length; p++) arr += newArr[p]; if (dp.get(arr) == null) { dp.put(arr, moves); Q.addLast(new Scenario(newArr)); } else { int val = dp.get(arr); if (val != 0 && moves < val) { dp.put(arr, moves); Q.addLast(new Scenario(newArr)); } } // outputArr(newArr); } } } } moves++; } } catch (IOException e) { System.out.println("IO: General"); } }
/* * We incorporate the ability to create an arbitrary network structure. * We use array of arrays of doubles for each inter-layer matrix * Thus, between each layer, we need a matrix of weights. * Num rows * num columns in matrix = nodes in layer below * nodes in layer above * * We use the Math library's pow function to raise to exponent: double pow(double base, double exponent) * * Hidden Nodes in current Layer (j) * previous layers nodes[ ] * Features [ Wij ] * (i) [ ] * * I set up a matrix with dimensions: [ nodes in previous layer ] [ nodes in next layer ] * * Since we are traveling through one layer at a time, we need to have another data structure * that will be outputs for this layer * * I use for loops to initialize array of arrays ( allocated necessary memory) * Please note that: number of layers + 1 = number of weight arrays needed */ public void train(Matrix features, Matrix labels) throws Exception { double[] recentAccuracies = new double[5]; int currentAccuracyIndex = 0; double currentAccuracy = 0; Random rand = new Random(); // SHUFFLE labels, features together features.shuffle(rand, labels); // need to map 0,1, or 2 to the three dimensional vectors, DO N-OF-K-ENCODING FOR THE // BACKPROPAGATION Matrix newNOfKLabelsMatrix = new Matrix(); newNOfKLabelsMatrix.setSize( labels.rows(), labels.valueCount(0)); // I HARD CODE IN THAT THERE SHOULD BE 3 OUTPUT NODES for (int row = 0; row < newNOfKLabelsMatrix.rows(); row++) { // for each instance for (int k = 0; k < labels.valueCount(0); k++) { if (labels.get(row, 0) == k) { for (int m = 0; m < labels.valueCount(0); m++) { newNOfKLabelsMatrix.set(row, m, 0); } newNOfKLabelsMatrix.set(row, k, 1); } } } labels = newNOfKLabelsMatrix; // IMMEDIATELY SAVE SOME OF THIS, NEVER WILL TRAIN ON THESE // STICK THESE INTO A VALIDATION SET // ONCE MSE STARTS TO INCREASE AGAIN ON THE VALIDATION SET, WE'VE GONE TOO FAR int numRowsToGetIntoTrainingSet = (int) (features.rows() * validationSetPercentageOfData); Matrix featuresForTrainingTrimmed = new Matrix(); featuresForTrainingTrimmed.setSize(numRowsToGetIntoTrainingSet, features.cols()); Matrix featuresValidationSet = new Matrix(); featuresValidationSet.setSize(features.rows() - numRowsToGetIntoTrainingSet, features.cols()); Matrix labelsForTrainingTrimmed = new Matrix(); labelsForTrainingTrimmed.setSize(numRowsToGetIntoTrainingSet, labels.cols()); Matrix labelsValidationSet = new Matrix(); labelsValidationSet.setSize(features.rows() - numRowsToGetIntoTrainingSet, labels.cols()); // LOOP THROUGH AND PUT MOST OF FEATURES INTO featuresForTrainingTrimmed for (int row = 0; row < features.rows(); row++) { for (int col = 0; col < features.cols(); col++) { if (row < numRowsToGetIntoTrainingSet) { featuresForTrainingTrimmed.set(row, col, features.get(row, col)); } else { featuresValidationSet.set(row - numRowsToGetIntoTrainingSet, col, features.get(row, col)); } } } // LOOP THROUGH AND PUT MOST OF FEATURES INTO featuresForTrainingTrimmed for (int row = 0; row < labels.rows(); row++) { for (int col = 0; col < labels.cols(); col++) { if (row < numRowsToGetIntoTrainingSet) { labelsForTrainingTrimmed.set(row, col, labels.get(row, col)); } else { labelsValidationSet.set(row - numRowsToGetIntoTrainingSet, col, labels.get(row, col)); } } } features = featuresForTrainingTrimmed; labels = labelsForTrainingTrimmed; // LOOP THROUGH AND PUT LEFTOVER PORTION OF FEATURES INTO validationSet arrayListOfEachLayersWeightMatrices = new ArrayList<double[][]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { // each layer double[][] specificLayersWeightMatrix; if (i == 0) { // first hidden layer (Each layer owns its own weights) specificLayersWeightMatrix = new double[features.cols()][numNodesPerHiddenLayer[i]]; // INPUTS are the rows } else if (i == numHiddenLayers) { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][labels.cols()]; // OUTPUTS ARE THE COLUMNS } else { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][numNodesPerHiddenLayer[i]]; } arrayListOfEachLayersWeightMatrices.add(specificLayersWeightMatrix); } changeInWeightMatricesForEveryLayer = new ArrayList<double[][]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { // each layer double[][] specificLayersWeightMatrix; if (i == 0) { // first hidden layer (Each layer owns its own weights) specificLayersWeightMatrix = new double[features.cols()][numNodesPerHiddenLayer[i]]; // INPUTS are the rows } else if (i == numHiddenLayers) { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][labels.cols()]; // OUTPUTS ARE THE COLUMNS } else { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][numNodesPerHiddenLayer[i]]; } changeInWeightMatricesForEveryLayer.add(specificLayersWeightMatrix); } // allocate space/ initialize the previous change in weights that we'll use for momentum temporaryStashChangeInWeightMatricesForEveryLayer = new ArrayList<double[][]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { // each layer double[][] specificLayersWeightMatrix; if (i == 0) { // first hidden layer (Each layer owns its own weights) specificLayersWeightMatrix = new double[features.cols()][numNodesPerHiddenLayer[i]]; // INPUTS are the rows } else if (i == numHiddenLayers) { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][labels.cols()]; // OUTPUTS ARE THE COLUMNS } else { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][numNodesPerHiddenLayer[i]]; } temporaryStashChangeInWeightMatricesForEveryLayer.add(specificLayersWeightMatrix); } // ALLOCATE SPACE FOR DELTA ( INTERMEDIATE VALUES THAT WE USE TO UPDATE THE WEIGHTS) arrayListOfEachLayersDeltaArray = new ArrayList<double[]>(); // EACH LAYER HAS AN ARRAY OF DELTA VALUES for (int i = 0; i < numHiddenLayers + 2; i++) { // each layer // OF COURSE WE COULD HAVE DONE numHiddenLayers + 1, but I want // consistency with fnet ArrayList double[] specificLayersDeltaArray; if (i == 0) { // first hidden layer (Each layer owns its own weights) specificLayersDeltaArray = new double[features.cols()]; // INPUTS are the rows } else if (i == (numHiddenLayers + 1)) { // specificLayersDeltaArray = new double[ numNodesPerHiddenLayer[ i-1 ] ] ; //[ // numNodesPerHiddenLayer[ labels.cols() ] ] ; // OUTPUTS ARE THE COLUMNS specificLayersDeltaArray = new double[labels.cols()]; // FIND OUT # NODES AT EACH LEVEL } else { specificLayersDeltaArray = new double[numNodesPerHiddenLayer[i - 1]]; } arrayListOfEachLayersDeltaArray.add(specificLayersDeltaArray); } previousChangeInWeightMatricesForEachLayer = new ArrayList<double[][]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { // each layer double[][] specificLayersWeightMatrix; if (i == 0) { // first hidden layer (Each layer owns its own weights) specificLayersWeightMatrix = new double[features.cols()][numNodesPerHiddenLayer[i]]; // INPUTS are the rows } else if (i == numHiddenLayers) { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][labels.cols()]; // OUTPUTS ARE THE COLUMNS } else { specificLayersWeightMatrix = new double[numNodesPerHiddenLayer[i - 1]][numNodesPerHiddenLayer[i]]; } previousChangeInWeightMatricesForEachLayer.add(specificLayersWeightMatrix); } // INITIALIZE ALL OF PREVIOUS DELTA VALUES TO 0 [ THIS IS DONE AUTOMATICALLY, CAN DELETE ALL OF // THIS CODE ] // initialize all weights randomly ( small random weights with 0 mean) double[][] currentLayersWeightMatrix; for (int i = 0; i < numNodesPerHiddenLayer.length + 1; i++) { // scroll across each layer currentLayersWeightMatrix = arrayListOfEachLayersWeightMatrices.get(i); for (int j = 0; j < currentLayersWeightMatrix.length; j++) { for (int k = 0; k < currentLayersWeightMatrix[j].length; k++) { currentLayersWeightMatrix[j][k] = (2 * rand.nextDouble()) - 1; } } } // GO THROUGH AND ADD THE SPECIFIC WEIGHTS // Initial Weights: // PUT ALL BIAS WEIGHTS INTO ARRAYLIST (ONE ARRAY FOR EACH LAYER'S BIAS WEIGHTS) biasWeightsAcrossAllLayers = new ArrayList<double[]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { if (i < numHiddenLayers) { double[] biasArrayToBeAdded = new double[numNodesPerHiddenLayer[i]]; biasWeightsAcrossAllLayers.add(biasArrayToBeAdded); } else { double[] biasArrayForOutputNodesToBeAdded = new double[labels.cols()]; biasWeightsAcrossAllLayers.add(biasArrayForOutputNodesToBeAdded); } } double[] currentBiasLayersWeightArray; for (int i = 0; i < numNodesPerHiddenLayer.length + 1; i++) { // scroll across each layer currentBiasLayersWeightArray = biasWeightsAcrossAllLayers.get(i); for (int j = 0; j < currentBiasLayersWeightArray.length; j++) { currentBiasLayersWeightArray[j] = (2 * rand.nextDouble()) - 1; } } // We'll need to store the previous bias weights previousBiasChangeInWeightsAcrossAllLayers = new ArrayList<double[]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { if (i < numHiddenLayers) { double[] biasArrayToBeAdded = new double[numNodesPerHiddenLayer[i]]; previousBiasChangeInWeightsAcrossAllLayers.add(biasArrayToBeAdded); } else { double[] biasArrayForOutputNodesToBeAdded = new double[labels.cols()]; previousBiasChangeInWeightsAcrossAllLayers.add(biasArrayForOutputNodesToBeAdded); } } // temporarily stashed bias weights across all layers temporarilyStashedChangeInBiasWeightsAcrossAllLayers = new ArrayList<double[]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { if (i < numHiddenLayers) { double[] biasArrayToBeAdded = new double[numNodesPerHiddenLayer[i]]; temporarilyStashedChangeInBiasWeightsAcrossAllLayers.add(biasArrayToBeAdded); } else { double[] biasArrayForOutputNodesToBeAdded = new double[labels.cols()]; temporarilyStashedChangeInBiasWeightsAcrossAllLayers.add(biasArrayForOutputNodesToBeAdded); } } changeInBiasArrayForEveryLayer = new ArrayList<double[]>(); for (int i = 0; i < numHiddenLayers + 1; i++) { if (i < numHiddenLayers) { double[] biasArrayToBeAdded = new double[numNodesPerHiddenLayer[i]]; changeInBiasArrayForEveryLayer.add(biasArrayToBeAdded); } else { double[] biasArrayForOutputNodesToBeAdded = new double[labels.cols()]; changeInBiasArrayForEveryLayer.add(biasArrayForOutputNodesToBeAdded); } } // INITIALIZE BIAS FOR HIDDEN AND OUTPUT NEURONS // Stochastic weight update // SOMEHOW GOT TO INITIALIZE ALL OF THIS, ADD BLANKS, SO THAT LATER WE CAN // storedFNetForEachLayer.set( i, blah ); storedFNetForEachLayer = new ArrayList<double[]>(); // f_net is the output that is fed into the next layer for (int i = 0; i < numHiddenLayers + 2; i++) { // WE HAVE ONE MORE layer of fnet( consider inputs as fnet) double[] thisLayersFNetValues; // COULD DO IF/ELSE STATEMENTS IF WE ARE LOOKING AT INPUTS, OR THEN HIDDEN NODES, if (i == 0) { thisLayersFNetValues = new double[features.cols()]; // FIND OUT # NODES AT EACH LEVEL } else if (i == numHiddenLayers + 1) { // OR IS IT +1 thisLayersFNetValues = new double[labels.cols()]; // FIND OUT # NODES AT EACH LEVEL } else { thisLayersFNetValues = new double[numNodesPerHiddenLayer[i - 1]]; // FIND OUT # NODES AT EACH LEVEL } storedFNetForEachLayer.add(thisLayersFNetValues); } // -----BEGIN THE TRAINING----- double netValAtNode = 0; double fOfNetValAtNode = 0; for (int epoch = 0; epoch < 10000; epoch++) { // For each epoch, cap it at 10000, we want to avoid infinite loop System.out.println("---Epoch " + epoch + "---"); for (int instance = 0; instance < features.rows(); instance++) { // later we will swap this Matrix for featuresForTrainingTrimmed // GO FORWARD // --------------------------------------------------------------------------------------------------------------------- // System.out.println("Forward propagating..."); for (int layer = 0; layer < numHiddenLayers + 2; layer++) { // HERE LAYER DENOTES HIDDEN LAYER if (layer == 0) { storedFNetForEachLayer.set( layer, Arrays.copyOf(features.row(instance), features.row(0).length)); continue; } double[] thisLayersFNetValues = storedFNetForEachLayer.get( layer); // make a new array of doubles CAN I PLEASE DELETE THIS LINE OF CODE for (int node = 0; node < storedFNetForEachLayer.get(layer).length; node++) { netValAtNode = 0; // FIND THE CROSS PRODUCT; // use a for loop to multiply each col of weights vector by each col of // outputsFromPreviousLayer for (int colInInputVector = 0; colInInputVector < storedFNetForEachLayer.get(layer - 1).length; colInInputVector++) { netValAtNode += (storedFNetForEachLayer.get(layer - 1)[colInInputVector] * arrayListOfEachLayersWeightMatrices.get(layer - 1)[colInInputVector][node]); } netValAtNode += (biasWeightsAcrossAllLayers.get(layer - 1)[node]); if (netValAtNode < 0) { // make special function fOfNetValAtNode = (1 / (1 + Math.pow(Math.E, (-1 * netValAtNode)))); } else { // normal fOfNetValAtNode = (1 / (1 + (1 / (Math.pow( Math.E, (netValAtNode)))))); // if it was positive, then we raise to neg // exponent } thisLayersFNetValues[node] = fOfNetValAtNode; // stick it into the object } storedFNetForEachLayer.set( layer, thisLayersFNetValues); // or if we are editing object, this is not even necessary // DOUBLE CHECK } // ---NOW FOR THIS INSTANCE, GO // BACKWARDS----------------------------------------------------------------------------------------------------------------------- // System.out.println("Back propagating..."); // UPDATE THE WEIGHTS for (int layer = numHiddenLayers + 1; layer > 0; layer--) { // ACROSS EACH LAYER BACKWARD if (layer == numHiddenLayers + 1) { // THIS IS AN OUTPUT LAYER for (int node = 0; node < labels.cols(); node++) { double deltaArrayForThisLayer[] = arrayListOfEachLayersDeltaArray.get(layer); deltaArrayForThisLayer[node] = ((labels.get(instance, node) - storedFNetForEachLayer.get(layer)[node]) * (storedFNetForEachLayer.get(layer)[node]) * (1 - (storedFNetForEachLayer.get(layer)[node]))); // should automatically be set since we get the objects address from heap memory, and // change it for (int inputToThisNode = 0; inputToThisNode < numNodesPerHiddenLayer[layer - 2] + 1; inputToThisNode++) { double changeInWeightBetweenIJ = 0; if (inputToThisNode == numNodesPerHiddenLayer[layer - 2]) { // this is a bias node changeInWeightBetweenIJ = (learningRate * 1 * arrayListOfEachLayersDeltaArray .get(layer)[node]); // NEED TO ADD STUFF FOR MOMENTUM double[] thisLayersBiasWeights = changeInBiasArrayForEveryLayer.get( layer - 1); // NEED TO ADD STUFF FOR MOMENTUM thisLayersBiasWeights[node] = (changeInWeightBetweenIJ); // NEED TO ADD STUFF FOR MOMENTUM } else { changeInWeightBetweenIJ = (learningRate * storedFNetForEachLayer.get(layer - 1)[inputToThisNode] * arrayListOfEachLayersDeltaArray.get(layer)[node]); // double[][] thisLayersWeightMatrix = // arrayListOfEachLayersWeightMatrices.get(layer-1); // thisLayersWeightMatrix[inputToThisNode][node] += ( changeInWeightBetweenIJ ); double[][] changeInWeightsMatrixForThisLayer = changeInWeightMatricesForEveryLayer.get(layer - 1); changeInWeightsMatrixForThisLayer[inputToThisNode][node] = changeInWeightBetweenIJ; } } } } else { for (int node = 0; node < numNodesPerHiddenLayer[layer - 1] + 1; node++) { // ACROSS EACH HIDDEN LAYER (ie these are not output nodes) double deltaArrayForThisLayer[] = arrayListOfEachLayersDeltaArray.get(layer); if (node == numNodesPerHiddenLayer[layer - 1]) { // this is a bias node // change in weight = learningRate * } else { // this is not a bias node double summedOutgoingWeightsCrossOutputDelta = 0; for (int outgoingEdgeToOutgoingNode = 0; outgoingEdgeToOutgoingNode < arrayListOfEachLayersDeltaArray.get(layer + 1).length; outgoingEdgeToOutgoingNode++) { summedOutgoingWeightsCrossOutputDelta += (arrayListOfEachLayersDeltaArray.get(layer + 1)[outgoingEdgeToOutgoingNode] * arrayListOfEachLayersWeightMatrices .get(layer)[node][outgoingEdgeToOutgoingNode]); } deltaArrayForThisLayer[node] = ((summedOutgoingWeightsCrossOutputDelta) * (storedFNetForEachLayer.get(layer)[node]) * (1 - (storedFNetForEachLayer.get(layer)[node]))); // should automatically be set since we get the objects address from heap memory, // and change it if (layer == 1) { // need a for loop across the neural net's input nodes for (int inputToTheNeuralNet = 0; inputToTheNeuralNet < features.cols() + 1; inputToTheNeuralNet++) { double changeInWeightBetweenIJ = 0; if (inputToTheNeuralNet == features.cols()) { // then we know that this is our bias node changeInWeightBetweenIJ = (learningRate * 1 * arrayListOfEachLayersDeltaArray .get(layer)[node]); // NEED TO ADD STUFF FOR MOMENTUM double[] thisLayersBiasWeights = changeInBiasArrayForEveryLayer.get( layer - 1); // NEED TO ADD STUFF FOR MOMENTUM thisLayersBiasWeights[node] = (changeInWeightBetweenIJ); // NEED TO ADD STUFF FOR MOMENTUM } else { changeInWeightBetweenIJ = (learningRate * storedFNetForEachLayer.get(layer - 1)[inputToTheNeuralNet] * arrayListOfEachLayersDeltaArray.get(layer)[node]); double[][] changeInWeightsMatrixForThisLayer = changeInWeightMatricesForEveryLayer.get(layer - 1); changeInWeightsMatrixForThisLayer[inputToTheNeuralNet][node] = changeInWeightBetweenIJ; } } } else { for (int inputToThisNode = 0; inputToThisNode < numNodesPerHiddenLayer[layer - 2] + 1; inputToThisNode++) { double changeInWeightBetweenIJ = 0; if (inputToThisNode == numNodesPerHiddenLayer[layer - 2]) { // this is a bias node changeInWeightBetweenIJ = (learningRate * 1 * arrayListOfEachLayersDeltaArray .get(layer)[node]); // NEED TO ADD STUFF FOR MOMENTUM double[] thisLayersBiasWeights = changeInBiasArrayForEveryLayer.get( layer - 1); // NEED TO ADD STUFF FOR MOMENTUM thisLayersBiasWeights[node] = (changeInWeightBetweenIJ); // NEED TO ADD STUFF FOR MOMENTUM } else { changeInWeightBetweenIJ = (learningRate * storedFNetForEachLayer.get(layer - 1)[inputToThisNode] * arrayListOfEachLayersDeltaArray.get(layer)[node]); // double[][] thisLayersWeightMatrix = // arrayListOfEachLayersWeightMatrices.get(layer-1); // thisLayersWeightMatrix[inputToThisNode][node] += ( changeInWeightBetweenIJ // ); double[][] changeInWeightsMatrixForThisLayer = changeInWeightMatricesForEveryLayer.get(layer - 1); changeInWeightsMatrixForThisLayer[inputToThisNode][node] = changeInWeightBetweenIJ; } } } } } } } // System.out.printf( "e_0=%.17f, e_1=%.17f, e_2=%.17f, e_3=%.17f\n" , // arrayListOfEachLayersDeltaArray.get(2)[0], arrayListOfEachLayersDeltaArray.get(1)[0] , // arrayListOfEachLayersDeltaArray.get(1)[1] , // arrayListOfEachLayersDeltaArray.get(1)[2]); // System.out.println("Descending Gradient..."); // // PUT TEMPORARILY STASHED INTO PREVIOUS // // ONLY HERE SHOULD WE PUT IN THE STASHED WEIGHTS INTO THE PREVIOUS-STASH-SPOT // // PUT STASHED INTO PREVIOUS // // // update the bias weights // GET NEW CHANGE IN WEIGHT THANKS TO MOMENTUM, PLACE IN PREVIOUS SPOT // should be changeInBiasArrayForEveryLayer not for (int w = 0; w < previousBiasChangeInWeightsAcrossAllLayers.size(); w++) { for (int y = 0; y < previousBiasChangeInWeightsAcrossAllLayers.get(w).length; y++) { double currentChangeInWeightVal = changeInBiasArrayForEveryLayer.get(w)[y]; double[] fullBiasWeightList = biasWeightsAcrossAllLayers.get(w); double previousXYCoordInBiasWeightMatrix = previousBiasChangeInWeightsAcrossAllLayers.get(w)[y]; double thisIsTheWeightChangeIncludingMomentum = (currentChangeInWeightVal + (momentum * previousXYCoordInBiasWeightMatrix)); fullBiasWeightList[y] += thisIsTheWeightChangeIncludingMomentum; double[] arrayOfPreviousBiases = previousBiasChangeInWeightsAcrossAllLayers.get(w); arrayOfPreviousBiases[y] = thisIsTheWeightChangeIncludingMomentum; } } // GET NEW CHANGE IN WEIGHT THANKS TO MOMENTUM, PLACE IN PREVIOUS SPOT // We update the weights ( by adding the changes in weights to the weight matrices) after // every layer has been processed for (int w = 0; w < arrayListOfEachLayersWeightMatrices.size(); w++) { for (int y = 0; y < arrayListOfEachLayersWeightMatrices.get(w).length; y++) { for (int z = 0; z < arrayListOfEachLayersWeightMatrices.get(w)[y].length; z++) { double currentXYCoordInMatrix = changeInWeightMatricesForEveryLayer.get(w)[y][z]; double[] fullWeightListForLayer = arrayListOfEachLayersWeightMatrices.get(w)[y]; double previousXYCoordInChangeInWeightMatrix = previousChangeInWeightMatricesForEachLayer.get(w)[y][z]; double thisIsTheWeightChangeIncludingMomentum = (currentXYCoordInMatrix + (previousXYCoordInChangeInWeightMatrix * momentum)); fullWeightListForLayer[z] += thisIsTheWeightChangeIncludingMomentum; double[][] arrayOfPreviousBiases = previousChangeInWeightMatricesForEachLayer.get(w); arrayOfPreviousBiases[y][z] = thisIsTheWeightChangeIncludingMomentum; // newWeight(at next round t+1) = learningRate * delta_at_node_we_feed_into * Xi + // momentum_parameter * change_in_weight_at_t // momentum goes into the weight updates ( not in the change in weights) } } } // System.out.printf( "w_0=%.17f, w_1=%.17f, w_2=%.17f, w_3=%.17f, w_4=%.17f, // w_5=%.17f,\n w_6=%.17f, w_7=%.17f, w_8=%.17f, w_9=%.17f," + // "w_10=%.17f, w_11=%.17f,\n w_12=%.17f\n" , // biasWeightsAcrossAllLayers.get(1)[0], // arrayListOfEachLayersWeightMatrices.get(1)[0][0] , // arrayListOfEachLayersWeightMatrices.get(1)[1][0] , // arrayListOfEachLayersWeightMatrices.get(1)[2][0] , biasWeightsAcrossAllLayers.get(0)[0], // arrayListOfEachLayersWeightMatrices.get(0)[0][0], // arrayListOfEachLayersWeightMatrices.get(0)[1][0], biasWeightsAcrossAllLayers.get(0)[1], // arrayListOfEachLayersWeightMatrices.get(0)[0][1], // arrayListOfEachLayersWeightMatrices.get(0)[1][1], // arrayListOfEachLayersWeightMatrices.get(0)[0][2], // biasWeightsAcrossAllLayers.get(0)[2], // arrayListOfEachLayersWeightMatrices.get(0)[0][2], // arrayListOfEachLayersWeightMatrices.get(0)[1][2]); // // ONLY AFTER THIS POINT HAS EVERY LAYER BEEN PROCESSED } // if( STOPPING CRITERIA MET ) { // HAVE TO USE THE VALIDATION SET THIS TIME FOR THE STOPPING // CRITERION currentAccuracy = calculateMSEOnValidationSet(featuresValidationSet, labelsValidationSet); // currentAccuracy = calculateMSEOnValidationSet( features , labels ); // On the training set // now System.out.println(" Current MSE on epoch # " + epoch + " is: " + currentAccuracy); currentAccuracyIndex++; recentAccuracies[currentAccuracyIndex % 5] = currentAccuracy; double sumAccuracies = 0; if (currentAccuracyIndex > 5) { for (int i = 0; i < recentAccuracies.length; i++) { sumAccuracies += Math.abs(recentAccuracies[currentAccuracyIndex % 5] - recentAccuracies[i]); } if (sumAccuracies < 0.01) { // we only stop training when measureAccuracy after 5 epochs does not increase // by 0.01 break; } } // In theory, it would be wise here to go back to the old best weights because now we're // already overfitting if the stopping criterion is met features.shuffle( rand, labels); // MUST SHUFFLE DATA ROWS AFTER EACH EPOCH,labels is the buddy matrix } return; }
/* * We feed in */ public void predict(double[] features, double[] labels) throws Exception { double netValAtNode = 0; double fOfNetValAtNode = 0; // ALL I HAVE TO DO IS SEND IT FORWARD THROUGH THE NETWORK // only get one instance at a time for (int layer = 0; layer < numHiddenLayers + 2; layer++) { // HERE LAYER DENOTES HIDDEN LAYER if (layer == 0) { storedFNetForEachLayer.set(layer, Arrays.copyOf(features, features.length)); continue; } double[] thisLayersFNetValues = storedFNetForEachLayer.get( layer); // make a new array of doubles CAN I PLEASE DELETE THIS LINE OF CODE for (int node = 0; node < storedFNetForEachLayer.get(layer).length; node++) { netValAtNode = 0; // FIND THE CROSS PRODUCT; // use a for loop to multiply each col of weights vector by each col of // outputsFromPreviousLayer for (int colInInputVector = 0; colInInputVector < storedFNetForEachLayer.get(layer - 1).length; colInInputVector++) { netValAtNode += (storedFNetForEachLayer.get(layer - 1)[colInInputVector] * arrayListOfEachLayersWeightMatrices.get(layer - 1)[colInInputVector][node]); } netValAtNode += (biasWeightsAcrossAllLayers.get(layer - 1)[node]); if (netValAtNode < 0) { // make special function fOfNetValAtNode = (1 / (1 + Math.pow(Math.E, (-1 * netValAtNode)))); } else { // normal fOfNetValAtNode = (1 / (1 + (1 / (Math.pow( Math.E, (netValAtNode)))))); // if it was positive, then we raise to neg // exponent } thisLayersFNetValues[node] = fOfNetValAtNode; // stick it into the object } storedFNetForEachLayer.set( layer, thisLayersFNetValues); // or if we are editing object, this is not even necessary DOUBLE // CHECK } // pick the output that the network says it is // return it // put what is beyond the hidden nodes into the labels matrix double maxPredictedFOfNetVal = -999999; int predictedClass = 0; double[] storedOutputNodeFNetValues = new double[storedFNetForEachLayer.get(numHiddenLayers + 1).length]; double[] storedOutputNodeTargetValues = new double[storedFNetForEachLayer.get(numHiddenLayers + 1).length]; for (int i = 0; i < storedFNetForEachLayer.get(numHiddenLayers + 1).length; i++) { if (labels.length > 1) { storedOutputNodeFNetValues[i] = storedFNetForEachLayer.get(numHiddenLayers + 1)[i]; storedOutputNodeTargetValues[i] = labels[i]; // time to go ahead and save what we had at each output node } if (storedFNetForEachLayer.get(numHiddenLayers + 1)[i] > maxPredictedFOfNetVal) { predictedClass = i; maxPredictedFOfNetVal = storedFNetForEachLayer.get(numHiddenLayers + 1)[i]; } } labels[0] = predictedClass; globalStoredOutputNodeFNetValues = storedOutputNodeFNetValues; globalStoredOutputNodeTargetValues = storedOutputNodeTargetValues; // labels is not expecting 0,1,0 IT IS EXPECTING 0,1,2 }
public Scenario(int[] states) { this.states = Arrays.copyOf(states, states.length); }