/** Checks to see if all the real eigenvectors are linearly independent of each other. */
  public void testVectorsLinearlyIndependent(SymmetricQRAlgorithmDecomposition alg) {
    int N = alg.getNumberOfEigenvalues();

    // create a matrix out of the eigenvectors
    Matrix A = Matrix.create(N, N);

    int off = 0;
    for (int i = 0; i < N; i++) {
      AVector v = alg.getEigenVector(i);

      // it can only handle real eigenvectors
      if (v == null) off++;
      else {
        for (int j = 0; j < N; j++) {
          A.set(i - off, j, v.get(j));
        }
      }
    }

    // see if there are any real eigenvectors
    if (N == off) return;

    //        A.reshape(N-off,N, false);
    A = A.reshape(N - off, N);

    AltLU lu = new AltLU();
    lu._decompose(A);
    assertFalse(lu.isSingular());
    //        assertTrue(MatrixFeatures.isRowsLinearIndependent(A));
  }
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 @Override
 public void setRow(int i, AVector row) {
   int cc = checkColumnCount(row.length());
   for (int j = 0; j < cc; i++) {
     data[index(i, j)] = row.unsafeGet(i);
   }
 }
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 @Override
 public AVector asVector() {
   AVector v = Vector0.INSTANCE;
   for (INDArray a : slices) {
     v = v.join(a.asVector());
   }
   return v;
 }
Esempio n. 4
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  @Test
  public void testOuterProducts() {
    AVector v = Vectorz.createUniformRandomVector(5);
    INDArray a = v.outerProduct(v);
    assertTrue(a instanceof AMatrix);

    AMatrix m = (AMatrix) a;
    AVector v2 = v.clone();
    v2.square();
    assertEquals(v2, m.getLeadingDiagonal());
  }
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 @Override
 public void transformInPlace(AVector v) {
   if (v instanceof AArrayVector) {
     transformInPlace((AArrayVector) v);
     return;
   }
   if (v.length() != dimensions)
     throw new IllegalArgumentException(ErrorMessages.incompatibleShapes(this, v));
   for (int i = 0; i < dimensions; i++) {
     v.unsafeSet(i, v.unsafeGet(i) * unsafeGetDiagonalValue(i));
   }
 }
 /**
  * Get the rth threshold.
  *
  * @param thresholdIndex The index of the threshold
  * @return the rth threshold.
  */
 public double getThreshold(int thresholdIndex) {
   double tr = t1;
   if (thresholdIndex < 0) {
     return Double.NEGATIVE_INFINITY;
   } else if (thresholdIndex == 0) {
     return tr;
   } else if (thresholdIndex > beta.length()) {
     return Double.POSITIVE_INFINITY;
   } else {
     for (int k = 0; k < thresholdIndex; k++) tr += Math.exp(beta.get(k));
     return tr;
   }
 }
    /**
     * The constructor of OrdRecParameter. It use the quantized values of rating to initialize t1
     * and beta. Each threshold is initialized as the mean of two contiguous rating values. Since
     * the index of quantizer is always an successive non-negative integer begin from 0, so t1 will
     * initialize as 0.5, and the interval between two thresholds will be 1.
     *
     * @param qtz The quantizer for ratings
     */
    private OrdRecModel(Quantizer qtz) {
      qtzValues = qtz.getValues();
      levelCount = qtzValues.length();
      t1 = (qtzValues.get(0) + qtzValues.get(1)) / 2;
      beta = Vector.createLength(levelCount - 2);

      double tr = t1;
      for (int i = 1; i <= beta.length(); i++) {
        double trnext = (qtzValues.get(i) + qtzValues.get(i + 1)) * 0.5;
        beta.set(i - 1, Math.log(trnext - tr));
        tr = trnext;
      }
    }
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  @Test
  public void testNonZeroCount() {
    AVector v = Vectorz.createUniformRandomVector(5);
    v.add(1);
    assertEquals(v.length(), v.nonZeroCount());

    v.scale(0.0);
    assertEquals(0, v.nonZeroCount());
  }
  /** Sees if the pair of eigenvalue and eigenvector was found in the decomposition. */
  public void testForEigenpair(
      SymmetricQRAlgorithmDecomposition alg, double valueReal, double valueImg, double... vector) {
    int N = alg.getNumberOfEigenvalues();

    int numMatched = 0;
    for (int i = 0; i < N; i++) {
      Vector2 c = alg.getEigenvalue(i);

      if (Math.abs(c.x - valueReal) < 1e-4 && Math.abs(c.y - valueImg) < 1e-4) {

        //                if( c.isReal() ) {
        if (Math.abs(c.y - 0) < 1e-8)
          if (vector.length > 0) {
            AVector v = alg.getEigenVector(i);
            AMatrix e = Matrix.createFromRows(vector);
            e = e.getTranspose();

            Matrix t = Matrix.create(v.length(), 1);
            t.setColumn(0, v);
            double error = diffNormF(e, t);
            //                        CommonOps.changeSign(e);
            e.multiply(-1);
            double error2 = diffNormF(e, t);

            if (error < 1e-3 || error2 < 1e-3) numMatched++;
          } else {
            numMatched++;
          }
        else if (Math.abs(c.y - 0) > 1e-8) {
          numMatched++;
        }
      }
    }

    assertEquals(1, numMatched);
  }
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  /**
   * Pushes an input vector through the LSTM and gets an output. Cell state and recurrent result
   * value are updated.
   *
   * @param input The input vector to push through
   * @return The result vector
   */
  public AVector step(AVector input) {

    // concatenate result vector onto the end of input vector, dimension zero as it is 1-dimensional
    // AVector
    // System.out.println(input);
    // System.out.println(result);
    input = input.join(result);
    if (input.length() != weights[0].getShape(1)) {
      throw new RuntimeException(
          "Input was the wrong shape! Input ( + last out) was "
              + input.length()
              + "but weights were "
              + weights[0].getShape(1));
    }
    // System.out.println(input);
    // System.out.println(input.rows());
    /* There are 4 layers in LSTM, in order of sig(0) sig(1) sig(2) tanh(3) */
    // For each sigmoid layer, multiply its weight matrix by the input vector, add its bias vector,
    // and perform sigmoid operation on resultant vector
    for (int i = 0; i < 3; i++) {
      // System.out.println(weights[i].columns());
      // The "columns" of the weights 3d matrix should represent the two-dimensional matrices for
      // each of the activations.
      sigmoidMult1[i] = weights[i].innerProduct(input);
      // System.out.println(sigmoidMult1[i]);
      sigmoidMult1[i].add(biases[i]);
      // System.out.println(sigmoidMult1[i]);
      sigmoidLayers[i] = Operations.Sigmoid.operate(sigmoidMult1[i]);
      // System.out.println(sigmoidLayers[i]);

    }
    // Calculate tanh layer in same fashion as sigmoid layer, but with tanh activation function
    tanhLayer = weights[3].innerProduct(input);
    tanhLayer.add(biases[3]);
    tanhLayer = Operations.Tanh.operate(tanhLayer);

    // do the first element-wise multiplication: sigmoid layer 1 and the current cell state
    sigmoidLayers[0].multiply(cellState);
    // System.out.println("multiplication of forget and cell state: " + sigmoidLayers[0]);
    // do the second element-wise multiplication: sigmoid layer 2 and the tanh layer
    sigmoidLayers[1].multiply(tanhLayer);
    // System.out.println("multiplication of input and activation layer: " + sigmoidLayers[1]);
    sigmoidLayers[0].add(sigmoidLayers[1]);
    // System.out.println("addition of " + sigmoidLayers[1]);
    cellState = sigmoidLayers[0];
    sigmoidLayers[0] = null;
    sigmoidLayers[1] = null;

    AVector tanhOp = Operations.Tanh.operate(cellState.copy());
    sigmoidLayers[2].multiply(tanhOp);
    result = sigmoidLayers[2];
    sigmoidLayers[2] = null;

    return result.copy();
  }
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 @Override
 public boolean load(INDArray data, String loadPath) {
   boolean found = true;
   switch (loadPath) {
     case "activate_b":
       activationBiases = (AVector) data;
       break;
     case "activate_w":
       activationWeights = (AMatrix) data;
       break;
     case "forget_b":
       forgetBiases = (AVector) data;
       break;
     case "forget_w":
       forgetWeights = (AMatrix) data;
       break;
     case "input_b":
       inputBiases = (AVector) data;
       break;
     case "input_w":
       inputWeights = (AMatrix) data;
       break;
     case "out_b":
       outputBiases = (AVector) data;
       break;
     case "out_w":
       outputWeights = (AMatrix) data;
       break;
     case "initialstate":
       AVector dataCast = (AVector) data;
       cellState = dataCast.subVector(0, (dataCast.length() / 2)).dense();
       // System.out.println(cellState);
       result = dataCast.subVector(dataCast.length() / 2, dataCast.length() / 2).dense();
       break;
     default:
       found = false;
       break;
   }
   initWeights();
   initBiases();
   return found;
 }
Esempio n. 12
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    /** The train function of OrdRec. Get all parameters after learning process. */
    @SuppressWarnings("ConstantConditions")
    private void train(SparseVector ratings, MutableSparseVector scores) {

      Vector dbeta = Vector.createLength(beta.length());
      double dt1;
      // n is the number of iteration;
      for (int j = 0; j < iterationCount; j++) {
        for (VectorEntry rating : ratings.fast()) {
          long iid = rating.getKey();
          double score = scores.get(iid);
          int r = quantizer.index(rating.getValue());

          double probEqualR = getProbEQ(score, r);
          double probLessR = getProbLE(score, r);
          double probLessR_1 = getProbLE(score, r - 1);

          dt1 =
              learningRate
                  / probEqualR
                  * (probLessR * (1 - probLessR) * derivateOfBeta(r, 0, t1)
                      - probLessR_1 * (1 - probLessR_1) * derivateOfBeta(r - 1, 0, t1)
                      - regTerm * t1);

          double dbetaK;
          for (int k = 0; k < beta.length(); k++) {
            dbetaK =
                learningRate
                    / probEqualR
                    * (probLessR * (1 - probLessR) * derivateOfBeta(r, k + 1, beta.get(k))
                        - probLessR_1
                            * (1 - probLessR_1)
                            * derivateOfBeta(r - 1, k + 1, beta.get(k))
                        - regTerm * beta.get(k));
            dbeta.set(k, dbetaK);
          }
          t1 = t1 + dt1;
          beta.add(dbeta);
        }
      }
    }
Esempio n. 13
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 @Override
 public double elementSum() {
   return vector.elementSum();
 }
  /**
   * Checks to see if an eigenvalue is complex then the eigenvector is null. If it is real it then
   * checks to see if the equation A*v = lambda*v holds true.
   */
  public void testPairsConsistent(SymmetricQRAlgorithmDecomposition alg, Matrix A) {
    //
    // System.out.println("-------------------------------------------------------------------------");
    int N = alg.getNumberOfEigenvalues();

    for (int i = 0; i < N; i++) {
      Vector2 c = alg.getEigenvalue(i);
      AVector v = alg.getEigenVector(i);

      if (Double.isInfinite(c.x)
          || Double.isNaN(c.x)
          || Double.isInfinite(c.y)
          || Double.isNaN(c.y)) fail("Uncountable eigenvalue");

      if (Math.abs(c.y) > 1e-20) {
        assertTrue(v == null);
      } else {
        assertTrue(v != null);
        //                if( MatrixFeatures.hasUncountable(v)) {
        //                    throw new RuntimeException("Egads");
        //                }
        assertFalse(v.hasUncountable());

        //                CommonOps.mult(A,v,tempA);
        Matrix ta = Matrix.create(A.rowCount(), 1);
        ta.setColumn(0, (v));
        AMatrix tempA = Multiplications.multiply(A, ta);
        //                CommonOps.scale(c.real,v,tempB);
        Matrix tb = Matrix.create(v.length(), 1);
        tb.setColumn(0, v);
        AMatrix tempB = tb.multiplyCopy(c.x);
        //                double max = NormOps.normPInf(A);
        double max = normPInf(A);
        if (max == 0) max = 1;

        double error = diffNormF(tempA, tempB) / max;

        if (error > 1e-12) {
          //                    System.out.println("Original matrix:");
          //                    System.out.println(A);
          //                    A.print();
          //                    System.out.println("Eigenvalue = "+c.x);
          //                    Eigenpair p = EigenOps.computeEigenVector(A,c.real);
          //                    p.vector.print();
          //                    v.print();
          //
          //
          //                    CommonOps.mult(A,p.vector,tempA);
          //                    CommonOps.scale(c.real,p.vector,tempB);
          //
          //                    max = NormOps.normPInf(A);
          //
          //                    System.out.println("error before = "+error);
          //                    error = SpecializedOps.diffNormF(tempA,tempB)/max;
          //                    System.out.println("error after = "+error);
          //                    A.print("%f");
          //                    System.out.println();
          fail("Error was too large");
        }

        assertTrue(error <= 1e-12);
      }
    }
  }
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 @Override
 public double dotProduct(AVector v) {
   if (v.length() != length) throw new IllegalArgumentException("Different vector lengths");
   return 0.0;
 }
Esempio n. 16
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 @Override
 public RowMatrix exactClone() {
   return new RowMatrix(vector.exactClone());
 }
Esempio n. 17
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 @Override
 public double get(int row, int column) {
   if (row != 0) throw new IndexOutOfBoundsException("Row: " + row);
   return vector.get(column);
 }
Esempio n. 18
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 @Override
 public void set(int row, int column, double value) {
   if (row != 0) throw new IndexOutOfBoundsException("Row: " + row);
   vector.set(column, value);
 }
Esempio n. 19
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 @Override
 public double calculateElement(int i, AVector v) {
   return v.unsafeGet(i) * unsafeGetDiagonalValue(i);
 }
Esempio n. 20
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 @Override
 public Vector toVector() {
   return vector.toVector();
 }
Esempio n. 21
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 @Override
 public int columnCount() {
   return vector.length();
 }
Esempio n. 22
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 @Override
 public void applyOp(Op op) {
   vector.applyOp(op);
 }
Esempio n. 23
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 @Override
 public void multiply(double factor) {
   vector.scale(factor);
 }
Esempio n. 24
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 @Override
 public void setColumn(int j, AVector col) {
   int rc = checkRowCount(col.length());
   col.getElements(data, j * rc);
 }
Esempio n. 25
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 @Override
 public long nonZeroCount() {
   return vector.nonZeroCount();
 }