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/*
 * JBoss, Home of Professional Open Source.
 * Copyright 2017 Red Hat, Inc., and individual contributors
 * as indicated by the @author tags.
 *
 * Licensed 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.wildfly.common.math;

import org.wildfly.common.Assert;

/**
 * Routines which are useful for hashcode computation, among other things.
 *
 * @author David M. Lloyd
 */
public final class HashMath {

    private static final int PRESELECTED_PRIME = 1299827;

    private HashMath() {
    }

    /**
     * Round the given value up to the next positive power of two.
     *
     * @param value the value (must not be negative and must be less than or equal to {@code 2^31})
     * @return the rounded power of two value
     */
    public static int roundToPowerOfTwo(int value) {
        Assert.checkMinimumParameter("value", 0, value);
        Assert.checkMaximumParameter("value", 0x4000_0000, value);
        return value <= 1 ? value : Integer.highestOneBit(value - 1) << 1;
    }

    /**
     * A hash function which combines an accumulated hash with a next hash such that {@code f(f(k, p2, b), p1, a) ≠ₙ f(f(k, p1, a), p2, b)}.
     * This function is suitable for object chains whose order affects the overall equality of the hash code.
     * 

* The exact algorithm is not specified and is therefore subject to change and should not be relied upon for hash * codes that persist outside of the JVM process. * * @param accumulatedHash the accumulated hash code of the previous stage * @param prime a prime multiplier * @param nextHash the hash code of the next single item * @return the new accumulated hash code */ public static int multiHashOrdered(int accumulatedHash, int prime, int nextHash) { return multiplyWrap(accumulatedHash, prime) + nextHash; } /** * A hash function which combines an accumulated hash with a next hash such that {@code f(f(k, p2, b), p1, a) = f(f(k, p1, a), p2, b)}. * This function is suitable for object chains whose order does not affect the overall equality of the hash code. *

* The exact algorithm is not specified and is therefore subject to change and should not be relied upon for hash * codes that persist outside of the JVM process. * * @param accumulatedHash the accumulated hash code of the previous stage * @param prime a prime multiplier * @param nextHash the hash code of the next single item * @return the new accumulated hash code */ public static int multiHashUnordered(int accumulatedHash, int prime, int nextHash) { return multiplyWrap(nextHash, prime) + accumulatedHash; } /** * A hash function which combines an accumulated hash with a next hash such that {@code f(f(k, b), a) ≠ₙ f(f(k, a), b)}. * This function is suitable for object chains whose order affects the overall equality of the hash code. *

* The exact algorithm is not specified and is therefore subject to change and should not be relied upon for hash * codes that persist outside of the JVM process. * * @param accumulatedHash the accumulated hash code of the previous stage * @param nextHash the hash code of the next single item * @return the new accumulated hash code */ public static int multiHashOrdered(int accumulatedHash, int nextHash) { return multiHashOrdered(accumulatedHash, PRESELECTED_PRIME, nextHash); } /** * A hash function which combines an accumulated hash with a next hash such that {@code f(f(k, b), a) = f(f(k, a), b)}. * This function is suitable for object chains whose order does not affect the overall equality of the hash code. *

* The exact algorithm is not specified and is therefore subject to change and should not be relied upon for hash * codes that persist outside of the JVM process. * * @param accumulatedHash the accumulated hash code of the previous stage * @param nextHash the hash code of the next single item * @return the new accumulated hash code */ public static int multiHashUnordered(int accumulatedHash, int nextHash) { return multiHashUnordered(accumulatedHash, PRESELECTED_PRIME, nextHash); } /** * Multiply two unsigned integers together. If the result overflows a 32-bit number, XOR the overflowed bits back into the result. * This operation is commutative, i.e. if we designate the {@code ⨰} symbol to represent this operation, then {@code a ⨰ b = b ⨰ a}. * This operation is not associative, i.e. {@code (a ⨰ b) ⨰ c ≠ₙ a ⨰ (b ⨰ c)} (the symbol {@code ≠ₙ} meaning "not necessarily equal to"), * therefore this operation is suitable for ordered combinatorial hash functions. * * @param a the first number to multiply * @param b the second number to multiply * @return the wrapped multiply result */ public static int multiplyWrap(int a, int b) { long r1 = (long) a * b; return (int) r1 ^ (int) (r1 >>> 32); } }





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