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oj! Algorithms - ojAlgo - is Open Source Java code that has to do with mathematics, linear algebra and optimisation.

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/*
 * Copyright 1997-2022 Optimatika
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy
 * of this software and associated documentation files (the "Software"), to deal
 * in the Software without restriction, including without limitation the rights
 * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
 * copies of the Software, and to permit persons to whom the Software is
 * furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
 * SOFTWARE.
 */
package org.ojalgo.function.special;

import static org.ojalgo.function.constant.PrimitiveMath.*;

import java.math.BigDecimal;
import java.math.MathContext;

/**
 * Math utilities missing from {@link Math}.
 *
 * @author apete
 */
public abstract class MissingMath {

    public static double acosh(final double arg) {
        return Math.log(arg + Math.sqrt(arg * arg - 1.0));
    }

    public static double asinh(final double arg) {
        return Math.log(arg + Math.sqrt(arg * arg + 1.0));
    }

    /**
     * 

* https://math.stackexchange.com/questions/1098487/atan2-faster-approximation/1105038 *

*

* This is about 10x faster than {@link Math#atan2(double, double)} *

*/ public static double atan2(final double y, final double x) { if (y == 0.0 && x == 0.0) { return 0.0; } double ay = Math.abs(y); double ax = Math.abs(x); double a = Math.min(ay, ax) / Math.max(ay, ax); double s = a * a; double retVal = ((-0.0464964749 * s + 0.15931422) * s - 0.327622764) * s * a + a; if (ay > ax) { retVal = 1.570796326794897 - retVal; } if (x < 0.0) { retVal = 3.141592653589793 - retVal; } if (y < 0.0) { retVal = -retVal; } return retVal; } public static double atanh(final double arg) { return Math.log((1.0 + arg) / (1.0 - arg)) / 2.0; } public static BigDecimal divide(final BigDecimal numerator, final BigDecimal denominator) { return numerator.divide(denominator, MathContext.DECIMAL128); } /** * 13! does not fit in an int, and 21! does not fit in a * long - that's why this method returns a double. */ public static double factorial(final int arg) { if (arg < 0) { throw new IllegalArgumentException(); } if (arg < 2) { return ONE; } if (arg < 13) { return MissingMath.factorialInt(arg); } if (arg < 21) { return MissingMath.factorialLong(arg); } return MissingMath.factorialDouble(arg); } /** * Greatest Common Denominator */ public static int gcd(final int val1, final int val2) { int retVal = 1; int abs1 = Math.abs(val1); int abs2 = Math.abs(val2); int tmpMax = Math.max(abs1, abs2); int tmpMin = Math.min(abs1, abs2); while (tmpMin != 0) { retVal = tmpMin; tmpMin = tmpMax % tmpMin; tmpMax = retVal; } return retVal; } public static int gcd(final int val1, final int... vals) { int retVal = val1; if (retVal == 1) { return 1; } for (int i = 0; i < vals.length; i++) { retVal = MissingMath.gcd(retVal, vals[i]); if (retVal == 1) { return 1; } } return retVal; } public static int gcd(final int[] vals) { return MissingMath.gcd(vals[0], vals); } public static long gcd(final long val1, final long... vals) { long retVal = val1; if (retVal == 1L) { return 1L; } for (int i = 0; i < vals.length; i++) { retVal = MissingMath.gcd(retVal, vals[i]); if (retVal == 1L) { return 1L; } } return retVal; } /** * Greatest Common Denominator */ public static long gcd(final long val1, final long val2) { long retVal = 1L; long abs1 = Math.abs(val1); long abs2 = Math.abs(val2); long tmpMax = Math.max(abs1, abs2); long tmpMin = Math.min(abs1, abs2); while (tmpMin != 0L) { retVal = tmpMin; tmpMin = tmpMax % tmpMin; tmpMax = retVal; } return retVal; } public static long gcd(final long[] vals) { return MissingMath.gcd(vals[0], vals); } public static BigDecimal hypot(final BigDecimal arg1, final BigDecimal arg2) { BigDecimal prod1 = arg1.multiply(arg1); BigDecimal prod2 = arg2.multiply(arg2); return MissingMath.root(prod1.add(prod2), 2); } public static double hypot(final double arg1, final double arg2) { if (Double.isNaN(arg1) || Double.isNaN(arg2)) { return Double.NaN; } double abs1 = Math.abs(arg1); double abs2 = Math.abs(arg2); double retVal = 0.0; if (abs1 > abs2) { retVal = abs1 * MissingMath.sqrt1px2(abs2 / abs1); } else if (abs2 > 0.0) { retVal = abs2 * MissingMath.sqrt1px2(abs1 / abs2); } return retVal; } /** * For very small arguments (regardless of sign) the replacement is returned instead */ public static double log10(final double arg, final double replacement) { if (Math.abs(arg) < Double.MIN_NORMAL) { return replacement; } return Math.log10(arg); } public static double logistic(final double arg) { return 1.0 / (1.0 + Math.exp(-arg)); } public static double logit(final double arg) { return Math.log(1.0 / (1.0 - arg)); } public static double max(final double... values) { double retVal = values[0]; for (int i = values.length; i-- != 1;) { retVal = values[i] > retVal ? values[i] : retVal; } return retVal; } public static double max(final double a, final double b) { return Math.max(a, b); } public static double max(final double a, final double b, final double c) { return Math.max(Math.max(a, b), c); } public static double max(final double a, final double b, final double c, final double d) { return Math.max(Math.max(a, b), Math.max(c, d)); } public static int max(final int... values) { int retVal = values[0]; for (int i = values.length; i-- != 1;) { retVal = values[i] > retVal ? values[i] : retVal; } return retVal; } public static int max(final int a, final int b) { return Math.max(a, b); } public static int max(final int a, final int b, final int c) { return Math.max(Math.max(a, b), c); } public static int max(final int a, final int b, final int c, final int d) { return Math.max(Math.max(a, b), Math.max(c, d)); } public static long max(final long... values) { long retVal = values[0]; for (int i = values.length; i-- != 1;) { retVal = values[i] > retVal ? values[i] : retVal; } return retVal; } public static long max(final long a, final long b) { return Math.max(a, b); } public static long max(final long a, final long b, final long c) { return Math.max(Math.max(a, b), c); } public static long max(final long a, final long b, final long c, final long d) { return Math.max(Math.max(a, b), Math.max(c, d)); } public static double min(final double... values) { double retVal = values[0]; for (int i = values.length; i-- != 1;) { retVal = values[i] < retVal ? values[i] : retVal; } return retVal; } public static double min(final double a, final double b) { return Math.min(a, b); } public static double min(final double a, final double b, final double c) { return Math.min(Math.min(a, b), c); } public static double min(final double a, final double b, final double c, final double d) { return Math.min(Math.min(a, b), Math.min(c, d)); } public static int min(final int... values) { int retVal = values[0]; for (int i = values.length; i-- != 1;) { retVal = values[i] < retVal ? values[i] : retVal; } return retVal; } public static int min(final int a, final int b) { return Math.min(a, b); } public static int min(final int a, final int b, final int c) { return Math.min(Math.min(a, b), c); } public static int min(final int a, final int b, final int c, final int d) { return Math.min(Math.min(a, b), Math.min(c, d)); } public static long min(final long... values) { long retVal = values[0]; for (int i = values.length; i-- != 1;) { retVal = values[i] < retVal ? values[i] : retVal; } return retVal; } public static long min(final long a, final long b) { return Math.min(a, b); } public static long min(final long a, final long b, final long c) { return Math.min(Math.min(a, b), c); } public static long min(final long a, final long b, final long c, final long d) { return Math.min(Math.min(a, b), Math.min(c, d)); } public static double norm(final double... values) { double retVal = Math.abs(values[0]); for (int i = values.length; i-- != 1;) { retVal = values[i] > retVal ? Math.abs(values[i]) : retVal; } return retVal; } public static double norm(final double a, final double b) { return Math.max(Math.abs(a), Math.abs(b)); } public static double norm(final double a, final double b, final double c) { return Math.max(Math.max(Math.abs(a), Math.abs(b)), Math.abs(c)); } public static double norm(final double a, final double b, final double c, final double d) { return Math.max(Math.max(Math.abs(a), Math.abs(b)), Math.max(Math.abs(c), Math.abs(d))); } public static BigDecimal pow(final BigDecimal arg1, final BigDecimal arg2) { if (arg2.signum() == 0) { return BigDecimal.ONE; } if (arg1.signum() == 0) { return BigDecimal.ZERO; } if (arg2.compareTo(BigDecimal.ONE) == 0) { return arg1; } return BigDecimal.valueOf(Math.pow(arg1.doubleValue(), arg2.doubleValue())); } public static BigDecimal power(final BigDecimal arg, final int param) { switch (param) { case 0: return BigDecimal.ONE; case 1: return arg; case 2: return arg.multiply(arg, MathContext.DECIMAL128); case 3: return arg.multiply(arg).multiply(arg, MathContext.DECIMAL128); case 4: BigDecimal arg2 = arg.multiply(arg); return arg2.multiply(arg2, MathContext.DECIMAL128); default: return arg.pow(param, MathContext.DECIMAL128); } } public static double power(final double arg, int param) { if (param < 0) { return 1.0 / MissingMath.power(arg, -param); } double retVal = 1.0; while (param > 0) { retVal = retVal * arg; param--; } return retVal; } public static long power(final long arg, final int param) { if (param == 0) { return 1L; } if (param == 1) { return arg; } if (param == 2) { return arg * arg; } if (param < 0) { return Math.round(Math.pow(arg, param)); } long retVal = arg; for (int p = 1; p < param; p++) { retVal *= arg; } return retVal; } public static BigDecimal root(final BigDecimal arg, final int param) { if (param <= 0) { throw new IllegalArgumentException(); } if (param == 1) { return arg; } BigDecimal bigArg = arg.round(MathContext.DECIMAL128); BigDecimal bigParam = BigDecimal.valueOf(param); BigDecimal retVal = BigDecimal.ZERO; double primArg = bigArg.doubleValue(); if (!Double.isInfinite(primArg) && !Double.isNaN(primArg)) { retVal = BigDecimal.valueOf(Math.pow(primArg, 1.0 / param)); // Intial guess } BigDecimal shouldBeZero; while ((shouldBeZero = MissingMath.power(retVal, param).subtract(bigArg)).signum() != 0) { retVal = retVal.subtract(shouldBeZero.divide(bigParam.multiply(retVal.pow(param - 1)), MathContext.DECIMAL128)); } return retVal; } public static double root(final double arg, final int param) { if (param != 0) { return Math.pow(arg, 1.0 / param); } throw new IllegalArgumentException(); } public static int roundToInt(final double value) { return Math.toIntExact(Math.round(value)); } public static double scale(final double arg, int param) { if (param == 0) { return 1.0; } if (param < 0) { int factor = 1; while (param < 0) { factor *= 10; param++; } return Math.rint(factor / arg) * factor; } int factor = 1; while (param > 0) { factor *= 10; param--; } return Math.rint(factor * arg) / factor; } public static BigDecimal signum(final BigDecimal arg) { switch (arg.signum()) { case 1: return BigDecimal.ONE; case -1: return BigDecimal.ONE.negate(); default: return BigDecimal.ZERO; } } public static double sqrt1px2(final double arg) { return Math.sqrt(1.0 + arg * arg); } public static int toMinIntExact(final long... values) { return Math.toIntExact(MissingMath.min(values)); } public static int toMinIntExact(final long a, final long b) { return Math.toIntExact(Math.min(a, b)); } public static int toMinIntExact(final long a, final long b, final long c) { return Math.toIntExact(MissingMath.min(a, b, c)); } public static int toMinIntExact(final long a, final long b, final long c, final long d) { return Math.toIntExact(MissingMath.min(a, b, c, d)); } static double factorialDouble(final int arg) { double retVal = ONE; for (int i = 2; i <= arg; i++) { retVal *= i; } return retVal; } static int factorialInt(final int arg) { int retVal = 1; for (int i = 2; i <= arg; i++) { retVal *= i; } return retVal; } static long factorialLong(final int arg) { long retVal = 1L; for (int i = 2; i <= arg; i++) { retVal *= i; } return retVal; } }




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