public SparseMatrix getRedundant() { SparseMatrix redMat = new SparseMatrix(this).multiply(this); int oldCard = 0; int card = redMat.cardinality(); int i = 0; // for(int r = 0; r < rowDim; r++){ // if(true){//transMat.hasRow(r)){ // transMat.add(r, r, 1.0); // } // if(true){//tcMat.hasRow(r)){ // tcMat.add(r, r, 1.0); // } // } while (card > oldCard) { // System.out.println("iter: "+i); i++; oldCard = card; redMat = redMat.add(redMat.multiply(this)); card = redMat.cardinality(); // System.out.println(tcMat.toString()); } return redMat; }
public SparseMatrix transitiveClosure() { SparseMatrix tcMat = new SparseMatrix(this); SparseMatrix transMat = new SparseMatrix(this); int oldCard = 0; int card = tcMat.cardinality(); int i = 0; // for(int r = 0; r < rowDim; r++){ // if(true){//transMat.hasRow(r)){ // transMat.add(r, r, 1.0); // } // if(true){//tcMat.hasRow(r)){ // tcMat.add(r, r, 1.0); // } // } while (card > oldCard) { // System.out.println("iter: "+i); i++; oldCard = card; tcMat = tcMat.add(tcMat.multiply(transMat)); card = tcMat.cardinality(); // System.out.println(tcMat.toString()); } return tcMat; }
public static void main(String[] args) { long start; long end; int card; double seconds; double megaTEPs; System.out.println("Working"); Random rand = new Random(); int dim = 16384; int num = dim * 10; SparseMatrix testMat = new SparseMatrix(dim, dim); for (int i = 0; i < num; i++) { if ((i % (1024 * 32 * 20) == 0)) System.out.println(i + " of " + num); int r = rand.nextInt(dim); int c = rand.nextInt(dim); // int r = (i+2659)*3571%dim; // int c = (i+2659)*2081%dim; testMat.add(r, c, 1.0); testMat.add(c, r, 1.0); // testMat.add(r, r, 1.0); // testMat.add(c, c, 1.0); // testMat.set(r, c, 1.0); // testMat.set(c, r, 1.0); } boolean isSymm = true; int sum = 0; for (int r = 0; r < dim; r++) { for (int c = 0; c < dim; c++) { double val = testMat.get(r, c); sum += val; if (val > 0.0) { if (testMat.get(c, r) == 0) { isSymm = false; } } } } System.out.println(sum + " " + testMat.cardinality() + " " + isSymm); // SparseMatrix testMat2 = new SparseMatrix(dim, dim); // for (int i = 0; i < num; i++) { // int r = rand.nextInt(dim); // int c = rand.nextInt(dim);testMat // testMat2.add(r, c, 1.0); // } // start = System.currentTimeMillis(); // SparseMatrix testMat3 = testMat.multiply(testMat2); // end = System.currentTimeMillis(); // System.out.println("Time: "+(end-start)); // System.out.println(testMat.cardinality()+" "+testMat.add(testMat2).cardinality()+" // "+testMat3.cardinality()); // start = System.currentTimeMillis(); // SparseMatrix apspRes = new SparseMatrix(testMat.rowDim, testMat.colDim); // int T = 1;testMat // for (int iter = 0; iter < T; iter++) { // apspRes = testMat.apsp(); // } // end = System.currentTimeMillis(); // System.out.println("Time: " + (end - start)); // card = testMat.cardinality(); // seconds = (double) (end - start) / 1000.0; // megaTEPs = card / seconds * dim / 1000000.0; // System.out.println("megaTEPs: " + megaTEPs); // System.out.println(testMat.toString()); // System.out.println(apspRes.toString()); // start = System.currentTimeMillis(); // Counter bfsRes = new Counter(); // int iterMax = dim; // for(int iter = 0; iter < iterMax; iter++){ // int init = iter; // bfsRes = testMat.bfs(init); // // System.out.println(bfsRes.toString()); // } // end = System.currentTimeMillis(); // System.out.println("Time: "+(end-start)); // card = testMat.cardinality(); // seconds = (double)(end-start)/1000.0; // megaTEPs = card/seconds*iterMax/1000000.0; // System.out.println("megaTEPs: "+megaTEPs); // System.out.println(init); // System.out.println(testMat.toString()); // System.out.println(bfsRes.toString()); // SparseMatrix testMatStoch = testMat.stochasticizeRows(); // double beta = 0.85; // ArrayList<Double> vector = new ArrayList<Double>(); // for(int i = 0; i < dim; i++){ // vector.add(0.0); // if(i == 0) vector.set(i,1.0); // } // ArrayList<Double> seedVector = new ArrayList<Double>(vector); // double svCard = 0; // for(int i = 0; i < dim; i++){ // svCard += seedVector.get(i); // } // ArrayList<Double> oldVector = new ArrayList<Double>(vector); // vector = (ArrayList<Double>) testMatStoch.multiply(vector); // double diff = 1; // int t = 0; // start = System.currentTimeMillis(); // while(diff > Math.pow(10.0, -10.0) && (diff < 3.99999 || diff > 4.00001) && t < 200){ // t += 1; // vector = (ArrayList<Double>) testMatStoch.multiply(vector); // double norm = 0; // for(int i = 0; i < dim; i++){ //// norm += vector.get(i)*vector.get(i); // norm += Math.abs(vector.get(i)); // } //// norm = Math.sqrt(norm); // for(int i = 0; i < dim; i++){r //// vector.set(i, // beta*vector.get(i)/norm+(1-beta)*seedVector.get(i));///Math.max(norm,1.0)); // vector.set(i, beta*vector.get(i)+(1-beta)*seedVector.get(i));///Math.max(norm,1.0)); // } // diff = 0; // for(int i = 0; i < dim; i++){ // diff +=(oldVector.get(i)-vector.get(i))*(oldVector.get(i)-vector.get(i)); // } // System.out.println(diff+" "+norm); //// System.out.println(vector.toString()); // // System.out.println(oldVector.toString()); // oldVector = new ArrayList<Double>(vector); // } //// System.out.println(testMatStoch.toStringValues()); // end = System.currentTimeMillis(); // System.out.println("Time: "+(end-start)+" iterations: "+t); // Counter sv = new Counter(); // sv.set(rand.nextInt(dim),1.0); // sv.set(0, 1.0); // SparseMatrix.PersonalizedPageRank(sv, testMat); // SparseMatrix laplacian = testMat.makeLaplacian(); // SparseMatrix normedLap = laplacian.stochasticizeRows(); // for(int i = 0; i < testMat.rowDim; i++){ // testMat.add(i,i,100.0); // } // SparseMatrix normedTest = testMat.stochasticizeRows(); // testMat = testMat.symmetric(); SparseMatrix orthogMat = new SparseMatrix(0, testMat.colDim); Counter topEig = SparseMatrix.ConstrainedEig(testMat, orthogMat); // Counter topEig = SparseMatrix.TopEig(testMat); // for(int i = 0; i < orthogMat.colDim; i++){ // orthogMat.set(0, i, 1.0); // } int topK = 10; for (int j = 0; j < topK; j++) { orthogMat.addRow(j, new Counter(topEig)); // double norm = testMat.multiply(topEig).norm(); // System.out.println("norm: "+norm); topEig = SparseMatrix.ConstrainedEig(testMat, orthogMat); } // orthogMat.addRow(topK, new Counter(topEig)); // for(int i: orthogMat.rows){ // Counter eig = orthogMat.getRow(i); // for(int j: orthogMat.rows){ // Counter eigOther = orthogMat.getRow(j); // double sim = eig.dot(eigOther); //// int sim = (int)(eig.dot(eigOther)+0.9999); // System.out.print(sim+" "); // } // System.out.println(); // } // SparseMatrix tcMin = testMat.minimize().transitiveClosure(); // SparseMatrix tcMat = testMat.transitiveClosure(); // System.out.println(tcMin.cardinality()+" "+tcMat.cardinality()); // testMat.add(0,0,1.0); // testMat.add(0,1,1.0); // testMat.add(1,1,1.0); // testMat.add(1,2,1.0); // testMat.add(2,2,1.0); // System.out.println(testMat.cardinality()); // for(int t = 0; t < 1000; t++){ // testMat = testMat.multiply(testMat); // System.out.println(testMat.cardinality()); // } // System.out.println(testMat.toString()); }