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/*
 * 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.math3.distribution;

import org.apache.commons.math3.exception.NotStrictlyPositiveException;
import org.apache.commons.math3.exception.util.LocalizedFormats;
import org.apache.commons.math3.random.RandomGenerator;
import org.apache.commons.math3.random.Well19937c;
import org.apache.commons.math3.util.FastMath;

/**
 * Implementation of the Zipf distribution.
 * 

* Parameters: * For a random variable {@code X} whose values are distributed according to this * distribution, the probability mass function is given by *

 *   P(X = k) = H(N,s) * 1 / k^s    for {@code k = 1,2,...,N}.
 * 
* {@code H(N,s)} is the normalizing constant * which corresponds to the generalized harmonic number of order N of s. *

*

    *
  • {@code N} is the number of elements
  • *
  • {@code s} is the exponent
  • *
* @see Zipf's law (Wikipedia) * @see Generalized harmonic numbers */ public class ZipfDistribution extends AbstractIntegerDistribution { /** Serializable version identifier. */ private static final long serialVersionUID = -140627372283420404L; /** Number of elements. */ private final int numberOfElements; /** Exponent parameter of the distribution. */ private final double exponent; /** Cached numerical mean */ private double numericalMean = Double.NaN; /** Whether or not the numerical mean has been calculated */ private boolean numericalMeanIsCalculated = false; /** Cached numerical variance */ private double numericalVariance = Double.NaN; /** Whether or not the numerical variance has been calculated */ private boolean numericalVarianceIsCalculated = false; /** The sampler to be used for the sample() method */ private transient ZipfRejectionInversionSampler sampler; /** * Create a new Zipf distribution with the given number of elements and * exponent. *

* Note: this constructor will implicitly create an instance of * {@link Well19937c} as random generator to be used for sampling only (see * {@link #sample()} and {@link #sample(int)}). In case no sampling is * needed for the created distribution, it is advised to pass {@code null} * as random generator via the appropriate constructors to avoid the * additional initialisation overhead. * * @param numberOfElements Number of elements. * @param exponent Exponent. * @exception NotStrictlyPositiveException if {@code numberOfElements <= 0} * or {@code exponent <= 0}. */ public ZipfDistribution(final int numberOfElements, final double exponent) { this(new Well19937c(), numberOfElements, exponent); } /** * Creates a Zipf distribution. * * @param rng Random number generator. * @param numberOfElements Number of elements. * @param exponent Exponent. * @exception NotStrictlyPositiveException if {@code numberOfElements <= 0} * or {@code exponent <= 0}. * @since 3.1 */ public ZipfDistribution(RandomGenerator rng, int numberOfElements, double exponent) throws NotStrictlyPositiveException { super(rng); if (numberOfElements <= 0) { throw new NotStrictlyPositiveException(LocalizedFormats.DIMENSION, numberOfElements); } if (exponent <= 0) { throw new NotStrictlyPositiveException(LocalizedFormats.EXPONENT, exponent); } this.numberOfElements = numberOfElements; this.exponent = exponent; } /** * Get the number of elements (e.g. corpus size) for the distribution. * * @return the number of elements */ public int getNumberOfElements() { return numberOfElements; } /** * Get the exponent characterizing the distribution. * * @return the exponent */ public double getExponent() { return exponent; } /** {@inheritDoc} */ public double probability(final int x) { if (x <= 0 || x > numberOfElements) { return 0.0; } return (1.0 / FastMath.pow(x, exponent)) / generalizedHarmonic(numberOfElements, exponent); } /** {@inheritDoc} */ @Override public double logProbability(int x) { if (x <= 0 || x > numberOfElements) { return Double.NEGATIVE_INFINITY; } return -FastMath.log(x) * exponent - FastMath.log(generalizedHarmonic(numberOfElements, exponent)); } /** {@inheritDoc} */ public double cumulativeProbability(final int x) { if (x <= 0) { return 0.0; } else if (x >= numberOfElements) { return 1.0; } return generalizedHarmonic(x, exponent) / generalizedHarmonic(numberOfElements, exponent); } /** * {@inheritDoc} * * For number of elements {@code N} and exponent {@code s}, the mean is * {@code Hs1 / Hs}, where *

    *
  • {@code Hs1 = generalizedHarmonic(N, s - 1)},
  • *
  • {@code Hs = generalizedHarmonic(N, s)}.
  • *
*/ public double getNumericalMean() { if (!numericalMeanIsCalculated) { numericalMean = calculateNumericalMean(); numericalMeanIsCalculated = true; } return numericalMean; } /** * Used by {@link #getNumericalMean()}. * * @return the mean of this distribution */ protected double calculateNumericalMean() { final int N = getNumberOfElements(); final double s = getExponent(); final double Hs1 = generalizedHarmonic(N, s - 1); final double Hs = generalizedHarmonic(N, s); return Hs1 / Hs; } /** * {@inheritDoc} * * For number of elements {@code N} and exponent {@code s}, the mean is * {@code (Hs2 / Hs) - (Hs1^2 / Hs^2)}, where *
    *
  • {@code Hs2 = generalizedHarmonic(N, s - 2)},
  • *
  • {@code Hs1 = generalizedHarmonic(N, s - 1)},
  • *
  • {@code Hs = generalizedHarmonic(N, s)}.
  • *
*/ public double getNumericalVariance() { if (!numericalVarianceIsCalculated) { numericalVariance = calculateNumericalVariance(); numericalVarianceIsCalculated = true; } return numericalVariance; } /** * Used by {@link #getNumericalVariance()}. * * @return the variance of this distribution */ protected double calculateNumericalVariance() { final int N = getNumberOfElements(); final double s = getExponent(); final double Hs2 = generalizedHarmonic(N, s - 2); final double Hs1 = generalizedHarmonic(N, s - 1); final double Hs = generalizedHarmonic(N, s); return (Hs2 / Hs) - ((Hs1 * Hs1) / (Hs * Hs)); } /** * Calculates the Nth generalized harmonic number. See * Harmonic * Series. * * @param n Term in the series to calculate (must be larger than 1) * @param m Exponent (special case {@code m = 1} is the harmonic series). * @return the nth generalized harmonic number. */ private double generalizedHarmonic(final int n, final double m) { double value = 0; for (int k = n; k > 0; --k) { value += 1.0 / FastMath.pow(k, m); } return value; } /** * {@inheritDoc} * * The lower bound of the support is always 1 no matter the parameters. * * @return lower bound of the support (always 1) */ public int getSupportLowerBound() { return 1; } /** * {@inheritDoc} * * The upper bound of the support is the number of elements. * * @return upper bound of the support */ public int getSupportUpperBound() { return getNumberOfElements(); } /** * {@inheritDoc} * * The support of this distribution is connected. * * @return {@code true} */ public boolean isSupportConnected() { return true; } /** * {@inheritDoc} */ @Override public int sample() { if (sampler == null) { sampler = new ZipfRejectionInversionSampler(numberOfElements, exponent); } return sampler.sample(random); } /** * Utility class implementing a rejection inversion sampling method for a discrete, * bounded Zipf distribution that is based on the method described in *

* Wolfgang Hörmann and Gerhard Derflinger * "Rejection-inversion to generate variates from monotone discrete distributions." * ACM Transactions on Modeling and Computer Simulation (TOMACS) 6.3 (1996): 169-184. *

* The paper describes an algorithm for exponents larger than 1 (Algorithm ZRI). * The original method uses {@code H(x) := (v + x)^(1 - q) / (1 - q)} * as the integral of the hat function. This function is undefined for * q = 1, which is the reason for the limitation of the exponent. * If instead the integral function * {@code H(x) := ((v + x)^(1 - q) - 1) / (1 - q)} is used, * for which a meaningful limit exists for q = 1, * the method works for all positive exponents. *

* The following implementation uses v := 0 and generates integral numbers * in the range [1, numberOfElements]. This is different to the original method * where v is defined to be positive and numbers are taken from [0, i_max]. * This explains why the implementation looks slightly different. * * @since 3.6 */ static final class ZipfRejectionInversionSampler { /** Exponent parameter of the distribution. */ private final double exponent; /** Number of elements. */ private final int numberOfElements; /** Constant equal to {@code hIntegral(1.5) - 1}. */ private final double hIntegralX1; /** Constant equal to {@code hIntegral(numberOfElements + 0.5)}. */ private final double hIntegralNumberOfElements; /** Constant equal to {@code 2 - hIntegralInverse(hIntegral(2.5) - h(2)}. */ private final double s; /** Simple constructor. * @param numberOfElements number of elements * @param exponent exponent parameter of the distribution */ ZipfRejectionInversionSampler(final int numberOfElements, final double exponent) { this.exponent = exponent; this.numberOfElements = numberOfElements; this.hIntegralX1 = hIntegral(1.5) - 1d; this.hIntegralNumberOfElements = hIntegral(numberOfElements + 0.5); this.s = 2d - hIntegralInverse(hIntegral(2.5) - h(2)); } /** Generate one integral number in the range [1, numberOfElements]. * @param random random generator to use * @return generated integral number in the range [1, numberOfElements] */ int sample(final RandomGenerator random) { while(true) { final double u = hIntegralNumberOfElements + random.nextDouble() * (hIntegralX1 - hIntegralNumberOfElements); // u is uniformly distributed in (hIntegralX1, hIntegralNumberOfElements] double x = hIntegralInverse(u); int k = (int)(x + 0.5); // Limit k to the range [1, numberOfElements] // (k could be outside due to numerical inaccuracies) if (k < 1) { k = 1; } else if (k > numberOfElements) { k = numberOfElements; } // Here, the distribution of k is given by: // // P(k = 1) = C * (hIntegral(1.5) - hIntegralX1) = C // P(k = m) = C * (hIntegral(m + 1/2) - hIntegral(m - 1/2)) for m >= 2 // // where C := 1 / (hIntegralNumberOfElements - hIntegralX1) if (k - x <= s || u >= hIntegral(k + 0.5) - h(k)) { // Case k = 1: // // The right inequality is always true, because replacing k by 1 gives // u >= hIntegral(1.5) - h(1) = hIntegralX1 and u is taken from // (hIntegralX1, hIntegralNumberOfElements]. // // Therefore, the acceptance rate for k = 1 is P(accepted | k = 1) = 1 // and the probability that 1 is returned as random value is // P(k = 1 and accepted) = P(accepted | k = 1) * P(k = 1) = C = C / 1^exponent // // Case k >= 2: // // The left inequality (k - x <= s) is just a short cut // to avoid the more expensive evaluation of the right inequality // (u >= hIntegral(k + 0.5) - h(k)) in many cases. // // If the left inequality is true, the right inequality is also true: // Theorem 2 in the paper is valid for all positive exponents, because // the requirements h'(x) = -exponent/x^(exponent + 1) < 0 and // (-1/hInverse'(x))'' = (1+1/exponent) * x^(1/exponent-1) >= 0 // are both fulfilled. // Therefore, f(x) := x - hIntegralInverse(hIntegral(x + 0.5) - h(x)) // is a non-decreasing function. If k - x <= s holds, // k - x <= s + f(k) - f(2) is obviously also true which is equivalent to // -x <= -hIntegralInverse(hIntegral(k + 0.5) - h(k)), // -hIntegralInverse(u) <= -hIntegralInverse(hIntegral(k + 0.5) - h(k)), // and finally u >= hIntegral(k + 0.5) - h(k). // // Hence, the right inequality determines the acceptance rate: // P(accepted | k = m) = h(m) / (hIntegrated(m+1/2) - hIntegrated(m-1/2)) // The probability that m is returned is given by // P(k = m and accepted) = P(accepted | k = m) * P(k = m) = C * h(m) = C / m^exponent. // // In both cases the probabilities are proportional to the probability mass function // of the Zipf distribution. return k; } } } /** * {@code H(x) :=} *

    *
  • {@code (x^(1-exponent) - 1)/(1 - exponent)}, if {@code exponent != 1}
  • *
  • {@code log(x)}, if {@code exponent == 1}
  • *
* H(x) is an integral function of h(x), * the derivative of H(x) is h(x). * * @param x free parameter * @return {@code H(x)} */ private double hIntegral(final double x) { final double logX = FastMath.log(x); return helper2((1d-exponent)*logX)*logX; } /** * {@code h(x) := 1/x^exponent} * * @param x free parameter * @return h(x) */ private double h(final double x) { return FastMath.exp(-exponent * FastMath.log(x)); } /** * The inverse function of H(x). * * @param x free parameter * @return y for which {@code H(y) = x} */ private double hIntegralInverse(final double x) { double t = x*(1d-exponent); if (t < -1d) { // Limit value to the range [-1, +inf). // t could be smaller than -1 in some rare cases due to numerical errors. t = -1; } return FastMath.exp(helper1(t)*x); } /** * Helper function that calculates {@code log(1+x)/x}. *

* A Taylor series expansion is used, if x is close to 0. * * @param x a value larger than or equal to -1 * @return {@code log(1+x)/x} */ static double helper1(final double x) { if (FastMath.abs(x)>1e-8) { return FastMath.log1p(x)/x; } else { return 1.-x*((1./2.)-x*((1./3.)-x*(1./4.))); } } /** * Helper function to calculate {@code (exp(x)-1)/x}. *

* A Taylor series expansion is used, if x is close to 0. * * @param x free parameter * @return {@code (exp(x)-1)/x} if x is non-zero, or 1 if x=0 */ static double helper2(final double x) { if (FastMath.abs(x)>1e-8) { return FastMath.expm1(x)/x; } else { return 1.+x*(1./2.)*(1.+x*(1./3.)*(1.+x*(1./4.))); } } } }





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