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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.
 */

/*
 * This is not the original file distributed by the Apache Software Foundation
 * It has been modified by the Hipparchus project
 */
package org.hipparchus.distribution;

import org.hipparchus.exception.MathIllegalArgumentException;

/**
 * Interface for discrete distributions.
 */
public interface IntegerDistribution {

    /**
     * For a random variable {@code X} whose values are distributed according to
     * this distribution, this method returns {@code log(P(X = x))}, where
     * {@code log} is the natural logarithm. In other words, this method
     * represents the logarithm of the probability mass function (PMF) for the
     * distribution. Note that due to the floating point precision and
     * under/overflow issues, this method will for some distributions be more
     * precise and faster than computing the logarithm of
     * {@link #probability(int)}.
     *
     * @param x the point at which the PMF is evaluated
     * @return the logarithm of the value of the probability mass function at {@code x}
     */
    double logProbability(int x);

    /**
     * For a random variable {@code X} whose values are distributed according
     * to this distribution, this method returns {@code P(X = x)}. In other
     * words, this method represents the probability mass function (PMF)
     * for the distribution.
     *
     * @param x the point at which the PMF is evaluated
     * @return the value of the probability mass function at {@code x}
     */
    double probability(int x);

    /**
     * For a random variable {@code X} whose values are distributed according
     * to this distribution, this method returns {@code P(x0 < X <= x1)}.
     *
     * @param x0 the exclusive lower bound
     * @param x1 the inclusive upper bound
     * @return the probability that a random variable with this distribution
     * will take a value between {@code x0} and {@code x1},
     * excluding the lower and including the upper endpoint
     * @throws MathIllegalArgumentException if {@code x0 > x1}
     */
    double probability(int x0, int x1) throws MathIllegalArgumentException;

    /**
     * For a random variable {@code X} whose values are distributed according
     * to this distribution, this method returns {@code P(X <= x)}.  In other
     * words, this method represents the (cumulative) distribution function
     * (CDF) for this distribution.
     *
     * @param x the point at which the CDF is evaluated
     * @return the probability that a random variable with this
     * distribution takes a value less than or equal to {@code x}
     */
    double cumulativeProbability(int x);

    /**
     * Computes the quantile function of this distribution.
     * For a random variable {@code X} distributed according to this distribution,
     * the returned value is
     * 
    *
  • inf{x in Z | P(X<=x) >= p} for {@code 0 < p <= 1},
  • *
  • inf{x in Z | P(X<=x) > 0} for {@code p = 0}.
  • *
* If the result exceeds the range of the data type {@code int}, * then {@code Integer.MIN_VALUE} or {@code Integer.MAX_VALUE} is returned. * * @param p the cumulative probability * @return the smallest {@code p}-quantile of this distribution * (largest 0-quantile for {@code p = 0}) * @throws MathIllegalArgumentException if {@code p < 0} or {@code p > 1} */ int inverseCumulativeProbability(double p) throws MathIllegalArgumentException; /** * Use this method to get the numerical value of the mean of this * distribution. * * @return the mean or {@code Double.NaN} if it is not defined */ double getNumericalMean(); /** * Use this method to get the numerical value of the variance of this * distribution. * * @return the variance (possibly {@code Double.POSITIVE_INFINITY} or * {@code Double.NaN} if it is not defined) */ double getNumericalVariance(); /** * Access the lower bound of the support. This method must return the same * value as {@code inverseCumulativeProbability(0)}. In other words, this * method must return *

inf {x in Z | P(X <= x) > 0}.

* * @return lower bound of the support ({@code Integer.MIN_VALUE} * for negative infinity) */ int getSupportLowerBound(); /** * Access the upper bound of the support. This method must return the same * value as {@code inverseCumulativeProbability(1)}. In other words, this * method must return *

inf {x in R | P(X <= x) = 1}.

* * @return upper bound of the support ({@code Integer.MAX_VALUE} * for positive infinity) */ int getSupportUpperBound(); /** * Use this method to get information about whether the support is * connected, i.e. whether all integers between the lower and upper bound of * the support are included in the support. * * @return whether the support is connected or not */ boolean isSupportConnected(); }




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