src/main/java/org/apache/commons/math/distribution/AbstractContinuousDistribution.java - platform/external/apache-commons-math - Git at Google

 /*
  * Licensed to the Apache Software Foundation (ASF) under one or more
  * contributor license agreements.  See the NOTICE file distributed with
  * this work for additional information regarding copyright ownership.
  * The ASF licenses this file to You under the Apache License, Version 2.0
  * (the "License"); you may not use this file except in compliance with
  * the License.  You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */
 package org.apache.commons.math.distribution;

 import java.io.Serializable;

 import org.apache.commons.math.ConvergenceException;
 import org.apache.commons.math.MathException;
 import org.apache.commons.math.MathRuntimeException;
 import org.apache.commons.math.analysis.UnivariateRealFunction;
 import org.apache.commons.math.analysis.solvers.BrentSolver;
 import org.apache.commons.math.analysis.solvers.UnivariateRealSolverUtils;
 import org.apache.commons.math.FunctionEvaluationException;
 import org.apache.commons.math.exception.util.LocalizedFormats;
 import org.apache.commons.math.random.RandomDataImpl;
 import org.apache.commons.math.util.FastMath;

 /**
  * Base class for continuous distributions.  Default implementations are
  * provided for some of the methods that do not vary from distribution to
  * distribution.
  *
  * @version $Revision: 1073498 $ $Date: 2011-02-22 21:57:26 +0100 (mar. 22 févr. 2011) $
  */
 public abstract class AbstractContinuousDistribution
     extends AbstractDistribution
     implements ContinuousDistribution, Serializable {

     /** Serializable version identifier */
     private static final long serialVersionUID = -38038050983108802L;

     /**
      * RandomData instance used to generate samples from the distribution
      * @since 2.2
      */
     protected final RandomDataImpl randomData = new RandomDataImpl();

     /**
      * Solver absolute accuracy for inverse cumulative computation
      * @since 2.1
      */
     private double solverAbsoluteAccuracy = BrentSolver.DEFAULT_ABSOLUTE_ACCURACY;

     /**
      * Default constructor.
      */
     protected AbstractContinuousDistribution() {
         super();
     }

     /**
      * Return the probability density for a particular point.
      * @param x  The point at which the density should be computed.
      * @return  The pdf at point x.
      * @throws MathRuntimeException if the specialized class hasn't implemented this function
      * @since 2.1
      */
     public double density(double x) throws MathRuntimeException {
         throw new MathRuntimeException(new UnsupportedOperationException(),
                 LocalizedFormats.NO_DENSITY_FOR_THIS_DISTRIBUTION);
     }

     /**
      * For this distribution, X, this method returns the critical point x, such
      * that P(X &lt; x) = <code>p</code>.
      *
      * @param p the desired probability
      * @return x, such that P(X &lt; x) = <code>p</code>
      * @throws MathException if the inverse cumulative probability can not be
      *         computed due to convergence or other numerical errors.
      * @throws IllegalArgumentException if <code>p</code> is not a valid
      *         probability.
      */
     public double inverseCumulativeProbability(final double p)
         throws MathException {
         if (p < 0.0 || p > 1.0) {
             throw MathRuntimeException.createIllegalArgumentException(
                   LocalizedFormats.OUT_OF_RANGE_SIMPLE, p, 0.0, 1.0);
         }

         // by default, do simple root finding using bracketing and default solver.
         // subclasses can override if there is a better method.
         UnivariateRealFunction rootFindingFunction =
             new UnivariateRealFunction() {
             public double value(double x) throws FunctionEvaluationException {
                 double ret = Double.NaN;
                 try {
                     ret = cumulativeProbability(x) - p;
                 } catch (MathException ex) {
                     throw new FunctionEvaluationException(x, ex.getSpecificPattern(), ex.getGeneralPattern(), ex.getArguments());
                 }
                 if (Double.isNaN(ret)) {
                     throw new FunctionEvaluationException(x, LocalizedFormats.CUMULATIVE_PROBABILITY_RETURNED_NAN, x, p);
                 }
                 return ret;
             }
         };

         // Try to bracket root, test domain endpoints if this fails
         double lowerBound = getDomainLowerBound(p);
         double upperBound = getDomainUpperBound(p);
         double[] bracket = null;
         try {
             bracket = UnivariateRealSolverUtils.bracket(
                     rootFindingFunction, getInitialDomain(p),
                     lowerBound, upperBound);
         }  catch (ConvergenceException ex) {
             /*
              * Check domain endpoints to see if one gives value that is within
              * the default solver's defaultAbsoluteAccuracy of 0 (will be the
              * case if density has bounded support and p is 0 or 1).
              */
             if (FastMath.abs(rootFindingFunction.value(lowerBound)) < getSolverAbsoluteAccuracy()) {
                 return lowerBound;
             }
             if (FastMath.abs(rootFindingFunction.value(upperBound)) < getSolverAbsoluteAccuracy()) {
                 return upperBound;
             }
             // Failed bracket convergence was not because of corner solution
             throw new MathException(ex);
         }

         // find root
         double root = UnivariateRealSolverUtils.solve(rootFindingFunction,
                 // override getSolverAbsoluteAccuracy() to use a Brent solver with
                 // absolute accuracy different from BrentSolver default
                 bracket[0],bracket[1], getSolverAbsoluteAccuracy());
         return root;
     }

     /**
      * Reseeds the random generator used to generate samples.
      *
      * @param seed the new seed
      * @since 2.2
      */
     public void reseedRandomGenerator(long seed) {
         randomData.reSeed(seed);
     }

     /**
      * Generates a random value sampled from this distribution. The default
      * implementation uses the
      * <a href="http://en.wikipedia.org/wiki/Inverse_transform_sampling"> inversion method.</a>
      *
      * @return random value
      * @since 2.2
      * @throws MathException if an error occurs generating the random value
      */
     public double sample() throws MathException {
         return randomData.nextInversionDeviate(this);
     }

     /**
      * Generates a random sample from the distribution.  The default implementation
      * generates the sample by calling {@link #sample()} in a loop.
      *
      * @param sampleSize number of random values to generate
      * @since 2.2
      * @return an array representing the random sample
      * @throws MathException if an error occurs generating the sample
      * @throws IllegalArgumentException if sampleSize is not positive
      */
     public double[] sample(int sampleSize) throws MathException {
         if (sampleSize <= 0) {
             MathRuntimeException.createIllegalArgumentException(LocalizedFormats.NOT_POSITIVE_SAMPLE_SIZE, sampleSize);
         }
         double[] out = new double[sampleSize];
         for (int i = 0; i < sampleSize; i++) {
             out[i] = sample();
         }
         return out;
     }

     /**
      * Access the initial domain value, based on <code>p</code>, used to
      * bracket a CDF root.  This method is used by
      * {@link #inverseCumulativeProbability(double)} to find critical values.
      *
      * @param p the desired probability for the critical value
      * @return initial domain value
      */
     protected abstract double getInitialDomain(double p);

     /**
      * Access the domain value lower bound, based on <code>p</code>, used to
      * bracket a CDF root.  This method is used by
      * {@link #inverseCumulativeProbability(double)} to find critical values.
      *
      * @param p the desired probability for the critical value
      * @return domain value lower bound, i.e.
      *         P(X &lt; <i>lower bound</i>) &lt; <code>p</code>
      */
     protected abstract double getDomainLowerBound(double p);

     /**
      * Access the domain value upper bound, based on <code>p</code>, used to
      * bracket a CDF root.  This method is used by
      * {@link #inverseCumulativeProbability(double)} to find critical values.
      *
      * @param p the desired probability for the critical value
      * @return domain value upper bound, i.e.
      *         P(X &lt; <i>upper bound</i>) &gt; <code>p</code>
      */
     protected abstract double getDomainUpperBound(double p);

     /**
      * Returns the solver absolute accuracy for inverse cumulative computation.
      *
      * @return the maximum absolute error in inverse cumulative probability estimates
      * @since 2.1
      */
     protected double getSolverAbsoluteAccuracy() {
         return solverAbsoluteAccuracy;
     }

 }
	/*
	* Licensed to the Apache Software Foundation (ASF) under one or more
	* contributor license agreements. See the NOTICE file distributed with
	* this work for additional information regarding copyright ownership.
	* The ASF licenses this file to You under the Apache License, Version 2.0
	* (the "License"); you may not use this file except in compliance with
	* the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/
	package org.apache.commons.math.distribution;

	import java.io.Serializable;

	import org.apache.commons.math.ConvergenceException;
	import org.apache.commons.math.MathException;
	import org.apache.commons.math.MathRuntimeException;
	import org.apache.commons.math.analysis.UnivariateRealFunction;
	import org.apache.commons.math.analysis.solvers.BrentSolver;
	import org.apache.commons.math.analysis.solvers.UnivariateRealSolverUtils;
	import org.apache.commons.math.FunctionEvaluationException;
	import org.apache.commons.math.exception.util.LocalizedFormats;
	import org.apache.commons.math.random.RandomDataImpl;
	import org.apache.commons.math.util.FastMath;

	/**
	* Base class for continuous distributions. Default implementations are
	* provided for some of the methods that do not vary from distribution to
	* distribution.
	*
	* @version $Revision: 1073498 $ $Date: 2011-02-22 21:57:26 +0100 (mar. 22 févr. 2011) $
	*/
	public abstract class AbstractContinuousDistribution
	extends AbstractDistribution
	implements ContinuousDistribution, Serializable {

	/** Serializable version identifier */
	private static final long serialVersionUID = -38038050983108802L;

	/**
	* RandomData instance used to generate samples from the distribution
	* @since 2.2
	*/
	protected final RandomDataImpl randomData = new RandomDataImpl();

	/**
	* Solver absolute accuracy for inverse cumulative computation
	* @since 2.1
	*/
	private double solverAbsoluteAccuracy = BrentSolver.DEFAULT_ABSOLUTE_ACCURACY;

	/**
	* Default constructor.
	*/
	protected AbstractContinuousDistribution() {
	super();
	}

	/**
	* Return the probability density for a particular point.
	* @param x The point at which the density should be computed.
	* @return The pdf at point x.
	* @throws MathRuntimeException if the specialized class hasn't implemented this function
	* @since 2.1
	*/
	public double density(double x) throws MathRuntimeException {
	throw new MathRuntimeException(new UnsupportedOperationException(),
	LocalizedFormats.NO_DENSITY_FOR_THIS_DISTRIBUTION);
	}

	/**
	* For this distribution, X, this method returns the critical point x, such
	* that P(X < x) = <code>p</code>.
	*
	* @param p the desired probability
	* @return x, such that P(X < x) = <code>p</code>
	* @throws MathException if the inverse cumulative probability can not be
	* computed due to convergence or other numerical errors.
	* @throws IllegalArgumentException if <code>p</code> is not a valid
	* probability.
	*/
	public double inverseCumulativeProbability(final double p)
	throws MathException {
	if (p < 0.0 \|\| p > 1.0) {
	throw MathRuntimeException.createIllegalArgumentException(
	LocalizedFormats.OUT_OF_RANGE_SIMPLE, p, 0.0, 1.0);
	}

	// by default, do simple root finding using bracketing and default solver.
	// subclasses can override if there is a better method.
	UnivariateRealFunction rootFindingFunction =
	new UnivariateRealFunction() {
	public double value(double x) throws FunctionEvaluationException {
	double ret = Double.NaN;
	try {
	ret = cumulativeProbability(x) - p;
	} catch (MathException ex) {
	throw new FunctionEvaluationException(x, ex.getSpecificPattern(), ex.getGeneralPattern(), ex.getArguments());
	}
	if (Double.isNaN(ret)) {
	throw new FunctionEvaluationException(x, LocalizedFormats.CUMULATIVE_PROBABILITY_RETURNED_NAN, x, p);
	}
	return ret;
	}
	};

	// Try to bracket root, test domain endpoints if this fails
	double lowerBound = getDomainLowerBound(p);
	double upperBound = getDomainUpperBound(p);
	double[] bracket = null;
	try {
	bracket = UnivariateRealSolverUtils.bracket(
	rootFindingFunction, getInitialDomain(p),
	lowerBound, upperBound);
	} catch (ConvergenceException ex) {
	/*
	* Check domain endpoints to see if one gives value that is within
	* the default solver's defaultAbsoluteAccuracy of 0 (will be the
	* case if density has bounded support and p is 0 or 1).
	*/
	if (FastMath.abs(rootFindingFunction.value(lowerBound)) < getSolverAbsoluteAccuracy()) {
	return lowerBound;
	}
	if (FastMath.abs(rootFindingFunction.value(upperBound)) < getSolverAbsoluteAccuracy()) {
	return upperBound;
	}
	// Failed bracket convergence was not because of corner solution
	throw new MathException(ex);
	}

	// find root
	double root = UnivariateRealSolverUtils.solve(rootFindingFunction,
	// override getSolverAbsoluteAccuracy() to use a Brent solver with
	// absolute accuracy different from BrentSolver default
	bracket[0],bracket[1], getSolverAbsoluteAccuracy());
	return root;
	}

	/**
	* Reseeds the random generator used to generate samples.
	*
	* @param seed the new seed
	* @since 2.2
	*/
	public void reseedRandomGenerator(long seed) {
	randomData.reSeed(seed);
	}

	/**
	* Generates a random value sampled from this distribution. The default
	* implementation uses the
	* <a href="http://en.wikipedia.org/wiki/Inverse_transform_sampling"> inversion method.</a>
	*
	* @return random value
	* @since 2.2
	* @throws MathException if an error occurs generating the random value
	*/
	public double sample() throws MathException {
	return randomData.nextInversionDeviate(this);
	}

	/**
	* Generates a random sample from the distribution. The default implementation
	* generates the sample by calling {@link #sample()} in a loop.
	*
	* @param sampleSize number of random values to generate
	* @since 2.2
	* @return an array representing the random sample
	* @throws MathException if an error occurs generating the sample
	* @throws IllegalArgumentException if sampleSize is not positive
	*/
	public double[] sample(int sampleSize) throws MathException {
	if (sampleSize <= 0) {
	MathRuntimeException.createIllegalArgumentException(LocalizedFormats.NOT_POSITIVE_SAMPLE_SIZE, sampleSize);
	}
	double[] out = new double[sampleSize];
	for (int i = 0; i < sampleSize; i++) {
	out[i] = sample();
	}
	return out;
	}

	/**
	* Access the initial domain value, based on <code>p</code>, used to
	* bracket a CDF root. This method is used by
	* {@link #inverseCumulativeProbability(double)} to find critical values.
	*
	* @param p the desired probability for the critical value
	* @return initial domain value
	*/
	protected abstract double getInitialDomain(double p);

	/**
	* Access the domain value lower bound, based on <code>p</code>, used to
	* bracket a CDF root. This method is used by
	* {@link #inverseCumulativeProbability(double)} to find critical values.
	*
	* @param p the desired probability for the critical value
	* @return domain value lower bound, i.e.
	* P(X < <i>lower bound</i>) < <code>p</code>
	*/
	protected abstract double getDomainLowerBound(double p);

	/**
	* Access the domain value upper bound, based on <code>p</code>, used to
	* bracket a CDF root. This method is used by
	* {@link #inverseCumulativeProbability(double)} to find critical values.
	*
	* @param p the desired probability for the critical value
	* @return domain value upper bound, i.e.
	* P(X < <i>upper bound</i>) > <code>p</code>
	*/
	protected abstract double getDomainUpperBound(double p);

	/**
	* Returns the solver absolute accuracy for inverse cumulative computation.
	*
	* @return the maximum absolute error in inverse cumulative probability estimates
	* @since 2.1
	*/
	protected double getSolverAbsoluteAccuracy() {
	return solverAbsoluteAccuracy;
	}

	}