Java Code Examples for org.apache.commons.math.MathRuntimeException#createIOException()

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** {@inheritDoc} */
@Override
public void writeExternal(final ObjectOutput out)
  throws IOException {

  try {
    // save the local attributes
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }
  final int dimension = (currentState == null) ? -1 : currentState.length;
  out.writeInt(dimension);
  for (int i = 0; i < dimension; ++i) {
    out.writeDouble(yDotKLast[0][i]);
    out.writeDouble(yDotKLast[1][i]);
    out.writeDouble(yDotKLast[2][i]);
  }

  // save the state of the base class
  super.writeExternal(out);

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/** Save the base state of the instance.
 * This method performs step finalization if it has not been done
 * before.
 * @param out stream where to save the state
 * @exception IOException in case of write error
 */
protected void writeBaseExternal(final ObjectOutput out)
  throws IOException {

  if (currentState == null) {
      out.writeInt(-1);
  } else {
      out.writeInt(currentState.length);
  }
  out.writeDouble(previousTime);
  out.writeDouble(currentTime);
  out.writeDouble(h);
  out.writeBoolean(forward);

  if (currentState != null) {
      for (int i = 0; i < currentState.length; ++i) {
          out.writeDouble(currentState[i]);
      }
  }

  out.writeDouble(interpolatedTime);

  // we do not store the interpolated state,
  // it will be recomputed as needed after reading

  // finalize the step (and don't bother saving the now true flag)
  try {
    finalizeStep();
  } catch (DerivativeException e) {
    throw MathRuntimeException.createIOException(e);
  }

}
 

/**
 * Fills binStats array (second pass through data file).
 * 
 * @param in object providing access to the data
 * @throws IOException  if an IO error occurs
 */
private void fillBinStats(Object in) throws IOException {
    // Load array of bin upper bounds -- evenly spaced from min - max
    double min = sampleStats.getMin();
    double max = sampleStats.getMax();
    double delta = (max - min)/(Double.valueOf(binCount)).doubleValue();
    double[] binUpperBounds = new double[binCount];
    binUpperBounds[0] = min + delta;
    for (int i = 1; i< binCount - 1; i++) {
        binUpperBounds[i] = binUpperBounds[i-1] + delta;
    }
    binUpperBounds[binCount -1] = max;

    // Initialize binStats ArrayList
    if (!binStats.isEmpty()) {
        binStats.clear();
    }
    for (int i = 0; i < binCount; i++) {
        SummaryStatistics stats = new SummaryStatistics();
        binStats.add(i,stats);
    }

    // Filling data in binStats Array
    DataAdapterFactory aFactory = new DataAdapterFactory();
    DataAdapter da = aFactory.getAdapter(in);
    try {
        da.computeBinStats(min, delta);
    } catch (IOException ioe) {
        // don't wrap exceptions which are already IOException
        throw ioe;
    } catch (RuntimeException rte) {
        // don't wrap RuntimeExceptions
        throw rte;
    } catch (Exception e) {
        throw MathRuntimeException.createIOException(e);
    }

    // Assign upperBounds based on bin counts
    upperBounds = new double[binCount];
    upperBounds[0] =
    ((double) binStats.get(0).getN()) / (double) sampleStats.getN();
    for (int i = 1; i < binCount-1; i++) {
        upperBounds[i] = upperBounds[i-1] +
        ((double) binStats.get(i).getN()) / (double) sampleStats.getN();
    }
    upperBounds[binCount-1] = 1.0d;
}
 

/**
 * Fills binStats array (second pass through data file).
 * 
 * @param in object providing access to the data
 * @throws IOException  if an IO error occurs
 */
private void fillBinStats(Object in) throws IOException {
    // Load array of bin upper bounds -- evenly spaced from min - max
    double min = sampleStats.getMin();
    double max = sampleStats.getMax();
    double delta = (max - min)/(Double.valueOf(binCount)).doubleValue();
    double[] binUpperBounds = new double[binCount];
    binUpperBounds[0] = min + delta;
    for (int i = 1; i< binCount - 1; i++) {
        binUpperBounds[i] = binUpperBounds[i-1] + delta;
    }
    binUpperBounds[binCount -1] = max;

    // Initialize binStats ArrayList
    if (!binStats.isEmpty()) {
        binStats.clear();
    }
    for (int i = 0; i < binCount; i++) {
        SummaryStatistics stats = new SummaryStatistics();
        binStats.add(i,stats);
    }

    // Filling data in binStats Array
    DataAdapterFactory aFactory = new DataAdapterFactory();
    DataAdapter da = aFactory.getAdapter(in);
    try {
        da.computeBinStats(min, delta);
    } catch (IOException ioe) {
        // don't wrap exceptions which are already IOException
        throw ioe;
    } catch (RuntimeException rte) {
        // don't wrap RuntimeExceptions
        throw rte;
    } catch (Exception e) {
        throw MathRuntimeException.createIOException(e);
    }

    // Assign upperBounds based on bin counts
    upperBounds = new double[binCount];
    upperBounds[0] =
    ((double) binStats.get(0).getN()) / (double) sampleStats.getN();
    for (int i = 1; i < binCount-1; i++) {
        upperBounds[i] = upperBounds[i-1] +
        ((double) binStats.get(i).getN()) / (double) sampleStats.getN();
    }
    upperBounds[binCount-1] = 1.0d;
}
 

/**
 * Fills binStats array (second pass through data file).
 * 
 * @param in object providing access to the data
 * @throws IOException  if an IO error occurs
 */
private void fillBinStats(Object in) throws IOException {
    // Load array of bin upper bounds -- evenly spaced from min - max
    double min = sampleStats.getMin();
    double max = sampleStats.getMax();
    double delta = (max - min)/(Double.valueOf(binCount)).doubleValue();
    double[] binUpperBounds = new double[binCount];
    binUpperBounds[0] = min + delta;
    for (int i = 1; i< binCount - 1; i++) {
        binUpperBounds[i] = binUpperBounds[i-1] + delta;
    }
    binUpperBounds[binCount -1] = max;

    // Initialize binStats ArrayList
    if (!binStats.isEmpty()) {
        binStats.clear();
    }
    for (int i = 0; i < binCount; i++) {
        SummaryStatistics stats = new SummaryStatistics();
        binStats.add(i,stats);
    }

    // Filling data in binStats Array
    DataAdapterFactory aFactory = new DataAdapterFactory();
    DataAdapter da = aFactory.getAdapter(in);
    try {
        da.computeBinStats(min, delta);
    } catch (IOException ioe) {
        // don't wrap exceptions which are already IOException
        throw ioe;
    } catch (RuntimeException rte) {
        // don't wrap RuntimeExceptions
        throw rte;
    } catch (Exception e) {
        throw MathRuntimeException.createIOException(e);
    }

    // Assign upperBounds based on bin counts
    upperBounds = new double[binCount];
    upperBounds[0] =
    ((double) binStats.get(0).getN()) / (double) sampleStats.getN();
    for (int i = 1; i < binCount-1; i++) {
        upperBounds[i] = upperBounds[i-1] +
        ((double) binStats.get(i).getN()) / (double) sampleStats.getN();
    }
    upperBounds[binCount-1] = 1.0d;
}