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/*
 * Copyright 2014-2024 Real Logic Limited.
 *
 * 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
 *
 * https://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 com.fluxtion.agrona.collections;

import com.fluxtion.agrona.generation.DoNotSub;

import java.lang.reflect.Array;
import java.util.AbstractSet;
import java.util.Arrays;
import java.util.Collection;
import java.util.Iterator;
import java.util.NoSuchElementException;
import java.util.Set;
import java.util.function.IntConsumer;
import java.util.function.IntPredicate;
import java.util.function.Predicate;

import static com.fluxtion.agrona.BitUtil.findNextPositivePowerOfTwo;
import static com.fluxtion.agrona.collections.CollectionUtil.validateLoadFactor;

/**
 * Open-addressing with linear-probing expandable hash set. Allocation free in steady state use when expanded.
 * 

* By storing elements as int primitives this significantly reduces memory consumption compared with Java's builtin * HashSet<Integer>. It implements Set<Integer> for convenience, but calling * functionality via those methods can add boxing overhead to your usage. *

* This class is not Threadsafe. *

* This HashSet caches its iterator object by default, so nested iteration is not supported. You can override this * behaviour at construction by indicating that the iterator should not be cached. * * @see IntIterator * @see Set */ public class IntHashSet extends AbstractSet { /** * The initial capacity used when none is specified in the constructor. */ @DoNotSub public static final int DEFAULT_INITIAL_CAPACITY = 8; static final int MISSING_VALUE = -1; private final boolean shouldAvoidAllocation; private boolean containsMissingValue; private final float loadFactor; @DoNotSub private int resizeThreshold; // NB: excludes missing value @DoNotSub private int sizeOfArrayValues; private int[] values; private IntIterator iterator; /** * Construct a hash set with {@link #DEFAULT_INITIAL_CAPACITY}, {@link Hashing#DEFAULT_LOAD_FACTOR}, iterator * caching support and {@code -1} as a missing value. */ public IntHashSet() { this(DEFAULT_INITIAL_CAPACITY); } /** * Construct a hash set with a proposed capacity, {@link Hashing#DEFAULT_LOAD_FACTOR}, iterator * caching support and {@code -1} as a missing value. * * @param proposedCapacity for the initial capacity of the set. */ public IntHashSet( @DoNotSub final int proposedCapacity) { this(proposedCapacity, Hashing.DEFAULT_LOAD_FACTOR, true); } /** * Construct a hash set with a proposed initial capacity, load factor, iterator caching support and {@code -1} as a * missing value. * * @param proposedCapacity for the initial capacity of the set. * @param loadFactor to be used for resizing. */ public IntHashSet( @DoNotSub final int proposedCapacity, final float loadFactor) { this(proposedCapacity, loadFactor, true); } /** * Construct a hash set with a proposed initial capacity, load factor, iterator caching support and {@code -1} as a * missing value. * * @param proposedCapacity for the initial capacity of the set. * @param loadFactor to be used for resizing. * @param shouldAvoidAllocation should the iterator be cached to avoid further allocation. */ public IntHashSet( @DoNotSub final int proposedCapacity, final float loadFactor, final boolean shouldAvoidAllocation) { validateLoadFactor(loadFactor); this.shouldAvoidAllocation = shouldAvoidAllocation; this.loadFactor = loadFactor; sizeOfArrayValues = 0; @DoNotSub final int capacity = findNextPositivePowerOfTwo(Math.max(DEFAULT_INITIAL_CAPACITY, proposedCapacity)); resizeThreshold = (int)(capacity * loadFactor); // @DoNotSub values = new int[capacity]; Arrays.fill(values, MISSING_VALUE); } /** * Get the load factor beyond which the set will increase size. * * @return load factor for when the set should increase size. */ public float loadFactor() { return loadFactor; } /** * Get the total capacity for the set to which the load factor with be a fraction of. * * @return the total capacity for the set. */ @DoNotSub public int capacity() { return values.length; } /** * Get the actual threshold which when reached the map will resize. * This is a function of the current capacity and load factor. * * @return the threshold when the map will resize. */ @DoNotSub public int resizeThreshold() { return resizeThreshold; } /** * {@inheritDoc} */ public boolean add(final Integer value) { return add(value.intValue()); } /** * Primitive specialised overload of {this#add(Integer)}. * * @param value the value to add. * @return true if the collection has changed, false otherwise. */ public boolean add(final int value) { if (MISSING_VALUE == value) { final boolean previousContainsMissingValue = this.containsMissingValue; containsMissingValue = true; return !previousContainsMissingValue; } final int[] values = this.values; @DoNotSub final int mask = values.length - 1; @DoNotSub int index = Hashing.hash(value, mask); int oldValue; while (MISSING_VALUE != (oldValue = values[index])) { if (oldValue == value) { return false; } index = next(index, mask); } values[index] = value; sizeOfArrayValues++; if (sizeOfArrayValues > resizeThreshold) { increaseCapacity(); } return true; } private void increaseCapacity() { @DoNotSub final int newCapacity = values.length * 2; if (newCapacity < 0) { throw new IllegalStateException("max capacity reached at size=" + size()); } rehash(newCapacity); } private void rehash(@DoNotSub final int newCapacity) { @DoNotSub final int capacity = newCapacity; @DoNotSub final int mask = newCapacity - 1; /* @DoNotSub */ resizeThreshold = (int)(newCapacity * loadFactor); final int[] tempValues = new int[capacity]; Arrays.fill(tempValues, MISSING_VALUE); final int[] values = this.values; for (final int value : values) { if (MISSING_VALUE != value) { @DoNotSub int newHash = Hashing.hash(value, mask); while (MISSING_VALUE != tempValues[newHash]) { newHash = ++newHash & mask; } tempValues[newHash] = value; } } this.values = tempValues; } /** * {@inheritDoc} */ public boolean remove(final Object value) { return remove((int)value); } /** * Specialised version of {this#remove(Object)} for int. * * @param value the value to remove. * @return true if the value was present, false otherwise. */ public boolean remove(final int value) { if (MISSING_VALUE == value) { final boolean previousContainsMissingValue = this.containsMissingValue; containsMissingValue = false; return previousContainsMissingValue; } final int[] values = this.values; @DoNotSub final int mask = values.length - 1; @DoNotSub int index = Hashing.hash(value, mask); int oldValue; while (MISSING_VALUE != (oldValue = values[index])) { if (oldValue == value) { values[index] = MISSING_VALUE; compactChain(index); sizeOfArrayValues--; return true; } index = next(index, mask); } return false; } @DoNotSub private static int next(final int index, final int mask) { return (index + 1) & mask; } @SuppressWarnings("FinalParameters") @DoNotSub void compactChain(int deleteIndex) { final int[] values = this.values; @DoNotSub final int mask = values.length - 1; @DoNotSub int index = deleteIndex; while (true) { index = next(index, mask); final int value = values[index]; if (MISSING_VALUE == value) { return; } @DoNotSub final int hash = Hashing.hash(value, mask); if ((index < hash && (hash <= deleteIndex || deleteIndex <= index)) || (hash <= deleteIndex && deleteIndex <= index)) { values[deleteIndex] = value; values[index] = MISSING_VALUE; deleteIndex = index; } } } /** * Compact the backing arrays by rehashing with a capacity just larger than current size * and giving consideration to the load factor. */ public void compact() { @DoNotSub final int idealCapacity = (int)Math.round(size() * (1.0 / loadFactor)); rehash(findNextPositivePowerOfTwo(Math.max(DEFAULT_INITIAL_CAPACITY, idealCapacity))); } /** * {@inheritDoc} */ public boolean contains(final Object value) { return contains((int)value); } /** * Contains method that does not box values. * * @param value to be checked for if the set contains it. * @return true if the value is contained in the set otherwise false. * @see Collection#contains(Object) */ public boolean contains(final int value) { if (MISSING_VALUE == value) { return containsMissingValue; } @DoNotSub final int mask = values.length - 1; @DoNotSub int index = Hashing.hash(value, mask); int existingValue; while (MISSING_VALUE != (existingValue = values[index])) { if (existingValue == value) { return true; } index = next(index, mask); } return false; } /** * {@inheritDoc} */ @DoNotSub public int size() { return sizeOfArrayValues + (containsMissingValue ? 1 : 0); } /** * {@inheritDoc} */ public boolean isEmpty() { return size() == 0; } /** * {@inheritDoc} */ public void clear() { if (size() > 0) { Arrays.fill(values, MISSING_VALUE); sizeOfArrayValues = 0; containsMissingValue = false; } } /** * {@inheritDoc} */ public boolean addAll(final Collection coll) { boolean added = false; for (final Integer value : coll) { added |= add(value); } return added; } /** * Alias for {@link #addAll(Collection)} for the specialized case when adding another IntHashSet, * avoids boxing and allocations. * * @param coll containing the values to be added. * @return {@code true} if this set changed as a result of the call. */ public boolean addAll(final IntHashSet coll) { boolean acc = false; for (final int value : coll.values) { if (MISSING_VALUE != value) { acc |= add(value); } } if (coll.containsMissingValue) { acc |= add(MISSING_VALUE); } return acc; } /** * IntHashSet specialised variant of {this#containsAll(Collection)}. * * @param coll int hash set to compare against. * @return true if every element in other is in this. */ public boolean containsAll(final IntHashSet coll) { for (final int value : coll.values) { if (MISSING_VALUE != value && !contains(value)) { return false; } } return containsMissingValue || !coll.containsMissingValue; } /** * Fast Path set difference for comparison with another IntHashSet. *

* Note: garbage free in the identical case, allocates otherwise. * * @param other the other set to subtract. * @return null if identical, otherwise the set of differences. */ public IntHashSet difference(final IntHashSet other) { IntHashSet difference = null; final int[] values = this.values; for (final int value : values) { if (MISSING_VALUE != value && !other.contains(value)) { if (null == difference) { difference = new IntHashSet(); } difference.add(value); } } if (containsMissingValue && !other.containsMissingValue) { if (null == difference) { difference = new IntHashSet(); } difference.add(MISSING_VALUE); } return difference; } /** * {@inheritDoc} */ public boolean removeIf(final Predicate filter) { return super.removeIf(filter); } /** * Removes all the elements of this collection that satisfy the given predicate. *

* NB: Renamed from removeIf to avoid overloading on parameter types of lambda * expression, which doesn't play well with type inference in lambda expressions. * * @param filter which returns {@code true} for elements to be removed. * @return {@code true} if any elements were removed. */ public boolean removeIfInt(final IntPredicate filter) { boolean removed = false; final IntIterator iterator = iterator(); while (iterator.hasNext()) { if (filter.test(iterator.nextValue())) { iterator.remove(); removed = true; } } return removed; } /** * {@inheritDoc} */ public boolean removeAll(final Collection coll) { boolean removed = false; for (final Object value : coll) { removed |= remove(value); } return removed; } /** * Alias for {@link #removeAll(Collection)} for the specialized case when removing another IntHashSet, * avoids boxing and allocations. * * @param coll containing the values to be removed. * @return {@code true} if this set changed as a result of the call. */ public boolean removeAll(final IntHashSet coll) { boolean removed = false; for (final int value : coll.values) { if (MISSING_VALUE != value) { removed |= remove(value); } } if (coll.containsMissingValue) { removed |= remove(MISSING_VALUE); } return removed; } /** * {@inheritDoc} */ public boolean retainAll(final Collection coll) { boolean removed = false; final int[] values = this.values; @DoNotSub final int length = values.length; @DoNotSub int i = 0; for (; i < length; i++) { final int value = values[i]; if (MISSING_VALUE != value && !coll.contains(value)) { values[i] = MISSING_VALUE; sizeOfArrayValues--; removed = true; } } if (removed && sizeOfArrayValues > 0) { @DoNotSub final int newCapacity = Math.max(DEFAULT_INITIAL_CAPACITY, findNextPositivePowerOfTwo(sizeOfArrayValues)); rehash(newCapacity); } if (containsMissingValue && !coll.contains(MISSING_VALUE)) { containsMissingValue = false; removed = true; } return removed; } /** * Alias for {@link #retainAll(Collection)} for the specialized case when retaining on another IntHashSet, * avoids boxing and allocations. * * @param coll containing elements to be retained in this set. * @return {@code true} if this set changed as a result of the call. */ public boolean retainAll(final IntHashSet coll) { boolean removed = false; @DoNotSub final int length = values.length; @DoNotSub int i = 0; for (; i < length; i++) { final int value = values[i]; if (MISSING_VALUE != value && !coll.contains(value)) { values[i] = MISSING_VALUE; sizeOfArrayValues--; removed = true; } } if (removed && sizeOfArrayValues > 0) { @DoNotSub final int newCapacity = Math.max(DEFAULT_INITIAL_CAPACITY, findNextPositivePowerOfTwo(sizeOfArrayValues)); rehash(newCapacity); } if (containsMissingValue && !coll.contains(MISSING_VALUE)) { containsMissingValue = false; removed = true; } return removed; } /** * {@inheritDoc} */ public IntIterator iterator() { IntIterator iterator = this.iterator; if (null == iterator) { iterator = new IntIterator(); if (shouldAvoidAllocation) { this.iterator = iterator; } } return iterator.reset(); } /** * Iterate over the collection without boxing. * * @param action to be taken for each element. */ public void forEachInt(final IntConsumer action) { if (sizeOfArrayValues > 0) { final int[] values = this.values; for (final int v : values) { if (MISSING_VALUE != v) { action.accept(v); } } } if (containsMissingValue) { action.accept(MISSING_VALUE); } } /** * Copy values from another {@link IntHashSet} into this one. * * @param that set to copy values from. */ public void copy(final IntHashSet that) { if (values.length != that.values.length) { throw new IllegalArgumentException("cannot copy object: masks not equal"); } System.arraycopy(that.values, 0, values, 0, values.length); this.sizeOfArrayValues = that.sizeOfArrayValues; this.containsMissingValue = that.containsMissingValue; } /** * {@inheritDoc} */ public String toString() { final StringBuilder sb = new StringBuilder(); sb.append('{'); final int[] values = this.values; for (final int value : values) { if (MISSING_VALUE != value) { sb.append(value).append(", "); } } if (containsMissingValue) { sb.append(MISSING_VALUE).append(", "); } if (sb.length() > 1) { sb.setLength(sb.length() - 2); } sb.append('}'); return sb.toString(); } /** * {@inheritDoc} */ @SuppressWarnings("unchecked") public T[] toArray(final T[] a) { final Class componentType = a.getClass().getComponentType(); if (!componentType.isAssignableFrom(Integer.class)) { throw new ArrayStoreException("cannot store Integers in array of type " + componentType); } @DoNotSub final int size = size(); final T[] arrayCopy = a.length >= size ? a : (T[])Array.newInstance(componentType, size); copyValues(arrayCopy); return arrayCopy; } /** * {@inheritDoc} */ public Object[] toArray() { final Object[] arrayCopy = new Object[size()]; copyValues(arrayCopy); return arrayCopy; } private void copyValues(final Object[] arrayCopy) { @DoNotSub int i = 0; final int[] values = this.values; for (final int value : values) { if (MISSING_VALUE != value) { arrayCopy[i++] = value; } } if (containsMissingValue) { arrayCopy[sizeOfArrayValues] = MISSING_VALUE; } } /** * {@inheritDoc} */ public boolean equals(final Object other) { if (other == this) { return true; } if (other instanceof IntHashSet) { final IntHashSet otherSet = (IntHashSet)other; return otherSet.containsMissingValue == containsMissingValue && otherSet.sizeOfArrayValues == sizeOfArrayValues && containsAll(otherSet); } if (!(other instanceof Set)) { return false; } final Set c = (Set)other; if (c.size() != size()) { return false; } try { return containsAll(c); } catch (final @DoNotSub ClassCastException | NullPointerException ignore) { return false; } } /** * {@inheritDoc} */ @DoNotSub public int hashCode() { @DoNotSub int hashCode = 0; for (final int value : values) { if (MISSING_VALUE != value) { hashCode += Integer.hashCode(value); } } if (containsMissingValue) { hashCode += Integer.hashCode(MISSING_VALUE); } return hashCode; } /** * Iterator which supports unboxed access to the values via {@link #nextValue()}. */ public final class IntIterator implements Iterator { @DoNotSub private int remaining; @DoNotSub private int positionCounter; @DoNotSub private int stopCounter; private boolean isPositionValid = false; IntIterator reset() { remaining = size(); final int[] values = IntHashSet.this.values; @DoNotSub final int length = values.length; @DoNotSub int i = length; if (MISSING_VALUE != values[length - 1]) { for (i = 0; i < length; i++) { if (MISSING_VALUE == values[i]) { break; } } } stopCounter = i; positionCounter = i + length; isPositionValid = false; return this; } /** * {@inheritDoc} */ public boolean hasNext() { return remaining > 0; } /** * Returns number of remaining (not yet visited) elements. * * @return number of remaining elements. */ @DoNotSub public int remaining() { return remaining; } /** * {@inheritDoc} */ public Integer next() { return nextValue(); } /** * Strongly typed alternative of {@link Iterator#next()} to avoid boxing. * * @return the next int value. */ public int nextValue() { if (remaining == 1 && containsMissingValue) { remaining = 0; isPositionValid = true; return MISSING_VALUE; } findNext(); final int[] values = IntHashSet.this.values; return values[position(values)]; } /** * {@inheritDoc} */ public void remove() { if (isPositionValid) { if (0 == remaining && containsMissingValue) { containsMissingValue = false; } else { final int[] values = IntHashSet.this.values; @DoNotSub final int position = position(values); values[position] = MISSING_VALUE; --sizeOfArrayValues; compactChain(position); } isPositionValid = false; } else { throw new IllegalStateException(); } } private void findNext() { final int[] values = IntHashSet.this.values; @DoNotSub final int mask = values.length - 1; isPositionValid = true; for (@DoNotSub int i = positionCounter - 1, stop = stopCounter; i >= stop; i--) { @DoNotSub final int index = i & mask; if (MISSING_VALUE != values[index]) { positionCounter = i; --remaining; return; } } isPositionValid = false; throw new NoSuchElementException(); } @DoNotSub private int position( final int[] values) { return positionCounter & (values.length - 1); } } }





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