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fastutil extends the Java Collections Framework by providing type-specific maps, sets, lists, and queues with a small memory footprint and fast operations; it provides also big (64-bit) arrays, sets, and lists, sorting algorithms, fast, practical I/O classes for binary and text files, and facilities for memory mapping large files. This jar (fastutil-core.jar) contains data structures based on integers, longs, doubles, and objects, only; fastutil.jar contains all classes. If you have both jars in your dependencies, this jar should be excluded.

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/*
 * Copyright (C) 2002-2022 Sebastiano Vigna
 *
 * 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 it.unimi.dsi.fastutil;

/** Common code for all hash-based classes. */

public class HashCommon {

	protected HashCommon() {}

	/** 232 · φ, φ = (√5 − 1)/2. */
	private static final int INT_PHI = 0x9E3779B9;
	/** The reciprocal of {@link #INT_PHI} modulo 232. */
	private static final int INV_INT_PHI = 0x144cbc89;
	/** 264 · φ, φ = (√5 − 1)/2. */
	private static final long LONG_PHI = 0x9E3779B97F4A7C15L;
	/** The reciprocal of {@link #LONG_PHI} modulo 264. */
	private static final long INV_LONG_PHI = 0xf1de83e19937733dL;

	/** Avalanches the bits of an integer by applying the finalisation step of MurmurHash3.
	 *
	 * 

This method implements the finalisation step of Austin Appleby's MurmurHash3. * Its purpose is to avalanche the bits of the argument to within 0.25% bias. * * @param x an integer. * @return a hash value with good avalanching properties. */ public static int murmurHash3(int x) { x ^= x >>> 16; x *= 0x85ebca6b; x ^= x >>> 13; x *= 0xc2b2ae35; x ^= x >>> 16; return x; } /** Avalanches the bits of a long integer by applying the finalisation step of MurmurHash3. * *

This method implements the finalisation step of Austin Appleby's MurmurHash3. * Its purpose is to avalanche the bits of the argument to within 0.25% bias. * * @param x a long integer. * @return a hash value with good avalanching properties. */ public static long murmurHash3(long x) { x ^= x >>> 33; x *= 0xff51afd7ed558ccdL; x ^= x >>> 33; x *= 0xc4ceb9fe1a85ec53L; x ^= x >>> 33; return x; } /** Quickly mixes the bits of an integer. * *

This method mixes the bits of the argument by multiplying by the golden ratio and * xorshifting the result. It is borrowed from Koloboke, and * it has slightly worse behaviour than {@link #murmurHash3(int)} (in open-addressing hash tables the average number of probes * is slightly larger), but it's much faster. * * @param x an integer. * @return a hash value obtained by mixing the bits of {@code x}. * @see #invMix(int) */ public static int mix(final int x) { final int h = x * INT_PHI; return h ^ (h >>> 16); } /** The inverse of {@link #mix(int)}. This method is mainly useful to create unit tests. * * @param x an integer. * @return a value that passed through {@link #mix(int)} would give {@code x}. */ public static int invMix(final int x) { return (x ^ x >>> 16) * INV_INT_PHI; } /** Quickly mixes the bits of a long integer. * *

This method mixes the bits of the argument by multiplying by the golden ratio and * xorshifting twice the result. It is borrowed from Koloboke, and * it has slightly worse behaviour than {@link #murmurHash3(long)} (in open-addressing hash tables the average number of probes * is slightly larger), but it's much faster. * * @param x a long integer. * @return a hash value obtained by mixing the bits of {@code x}. */ public static long mix(final long x) { long h = x * LONG_PHI; h ^= h >>> 32; return h ^ (h >>> 16); } /** The inverse of {@link #mix(long)}. This method is mainly useful to create unit tests. * * @param x a long integer. * @return a value that passed through {@link #mix(long)} would give {@code x}. */ public static long invMix(long x) { x ^= x >>> 32; x ^= x >>> 16; return (x ^ x >>> 32) * INV_LONG_PHI; } /** Returns the hash code that would be returned by {@link Float#hashCode()}. * * @param f a float. * @return the same code as {@link Float#hashCode() new Float(f).hashCode()}. */ public static int float2int(final float f) { return Float.floatToRawIntBits(f); } /** Returns the hash code that would be returned by {@link Double#hashCode()}. * * @param d a double. * @return the same code as {@link Double#hashCode() new Double(f).hashCode()}. */ public static int double2int(final double d) { final long l = Double.doubleToRawLongBits(d); return (int)(l ^ (l >>> 32)); } /** Returns the hash code that would be returned by {@link Long#hashCode()}. * * @param l a long. * @return the same code as {@link Long#hashCode() new Long(f).hashCode()}. */ public static int long2int(final long l) { return (int)(l ^ (l >>> 32)); } /** Returns the least power of two greater than or equal to the specified value. * *

Note that this function will return 1 when the argument is 0. * * @param x an integer smaller than or equal to 230. * @return the least power of two greater than or equal to the specified value. */ public static int nextPowerOfTwo(int x) { return 1 << (32 - Integer.numberOfLeadingZeros(x - 1)); } /** Returns the least power of two greater than or equal to the specified value. * *

Note that this function will return 1 when the argument is 0. * * @param x a long integer smaller than or equal to 262. * @return the least power of two greater than or equal to the specified value. */ public static long nextPowerOfTwo(long x) { return 1L << (64 - Long.numberOfLeadingZeros(x - 1)); } /** Returns the maximum number of entries that can be filled before rehashing. * * @param n the size of the backing array. * @param f the load factor. * @return the maximum number of entries before rehashing. */ public static int maxFill(final int n, final float f) { /* We must guarantee that there is always at least * one free entry (even with pathological load factors). */ return Math.min((int)Math.ceil(n * f), n - 1); } /** Returns the maximum number of entries that can be filled before rehashing. * * @param n the size of the backing array. * @param f the load factor. * @return the maximum number of entries before rehashing. */ public static long maxFill(final long n, final float f) { /* We must guarantee that there is always at least * one free entry (even with pathological load factors). */ return Math.min((long)Math.ceil(n * f), n - 1); } /** Returns the least power of two smaller than or equal to 230 and larger than or equal to {@code Math.ceil(expected / f)}. * * @param expected the expected number of elements in a hash table. * @param f the load factor. * @return the minimum possible size for a backing array. * @throws IllegalArgumentException if the necessary size is larger than 230. */ public static int arraySize(final int expected, final float f) { final long s = Math.max(2, nextPowerOfTwo((long)Math.ceil(expected / f))); if (s > (1 << 30)) throw new IllegalArgumentException("Too large (" + expected + " expected elements with load factor " + f + ")"); return (int)s; } /** Returns the least power of two larger than or equal to {@code Math.ceil(expected / f)}. * * @param expected the expected number of elements in a hash table. * @param f the load factor. * @return the minimum possible size for a backing big array. */ public static long bigArraySize(final long expected, final float f) { return nextPowerOfTwo((long)Math.ceil(expected / f)); } }





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