/*
 * Copyright (c) 2018 Goldman Sachs and others.
 * All rights reserved. This program and the accompanying materials
 * are made available under the terms of the Eclipse Public License v1.0
 * and Eclipse Distribution License v. 1.0 which accompany this distribution.
 * The Eclipse Public License is available at http://www.eclipse.org/legal/epl-v10.html
 * and the Eclipse Distribution License is available at
 * http://www.eclipse.org/org/documents/edl-v10.php.
 */

package org.eclipse.collections.impl.map.mutable.primitive;

import java.io.Externalizable;
import java.io.IOException;
import java.io.ObjectInput;
import java.io.ObjectOutput;
import java.lang.reflect.Array;
import java.util.Arrays;
import java.util.Collection;
import java.util.Iterator;
import java.util.NoSuchElementException;
import java.util.Set;

import org.eclipse.collections.api.FloatIterable;
import org.eclipse.collections.api.LazyFloatIterable;
import org.eclipse.collections.api.LazyIterable;
import org.eclipse.collections.api.RichIterable;
import org.eclipse.collections.api.bag.primitive.MutableFloatBag;
import org.eclipse.collections.api.block.HashingStrategy;
import org.eclipse.collections.api.block.function.primitive.FloatFunction;
import org.eclipse.collections.api.block.function.primitive.FloatFunction0;
import org.eclipse.collections.api.block.function.primitive.FloatToFloatFunction;
import org.eclipse.collections.api.block.function.primitive.FloatToObjectFunction;
import org.eclipse.collections.api.block.function.primitive.ObjectFloatToObjectFunction;
import org.eclipse.collections.api.block.predicate.primitive.FloatPredicate;
import org.eclipse.collections.api.block.predicate.primitive.ObjectFloatPredicate;
import org.eclipse.collections.api.block.procedure.Procedure;
import org.eclipse.collections.api.block.procedure.Procedure2;
import org.eclipse.collections.api.block.procedure.primitive.FloatProcedure;
import org.eclipse.collections.api.block.procedure.primitive.ObjectFloatProcedure;
import org.eclipse.collections.api.collection.MutableCollection;
import org.eclipse.collections.api.collection.primitive.ImmutableFloatCollection;
import org.eclipse.collections.api.collection.primitive.MutableFloatCollection;
import org.eclipse.collections.api.iterator.FloatIterator;
import org.eclipse.collections.api.iterator.MutableFloatIterator;
import org.eclipse.collections.api.list.MutableList;
import org.eclipse.collections.api.list.primitive.MutableFloatList;
import org.eclipse.collections.api.map.primitive.ImmutableObjectFloatMap;
import org.eclipse.collections.api.map.primitive.MutableObjectFloatMap;
import org.eclipse.collections.api.map.primitive.MutableFloatObjectMap;
import org.eclipse.collections.api.map.primitive.ObjectFloatMap;
import org.eclipse.collections.api.set.primitive.FloatSet;
import org.eclipse.collections.api.set.primitive.MutableFloatSet;
import org.eclipse.collections.api.tuple.primitive.ObjectFloatPair;
import org.eclipse.collections.impl.bag.mutable.primitive.FloatHashBag;
import org.eclipse.collections.impl.collection.mutable.primitive.SynchronizedFloatCollection;
import org.eclipse.collections.impl.collection.mutable.primitive.UnmodifiableFloatCollection;
import org.eclipse.collections.impl.lazy.AbstractLazyIterable;
import org.eclipse.collections.impl.factory.Lists;
import org.eclipse.collections.impl.factory.primitive.FloatBags;
import org.eclipse.collections.impl.factory.primitive.FloatLists;
import org.eclipse.collections.impl.factory.primitive.ObjectFloatMaps;
import org.eclipse.collections.impl.factory.primitive.FloatObjectMaps;
import org.eclipse.collections.impl.lazy.primitive.LazyFloatIterableAdapter;
import org.eclipse.collections.impl.list.mutable.FastList;
import org.eclipse.collections.impl.list.mutable.primitive.FloatArrayList;
import org.eclipse.collections.impl.set.mutable.primitive.FloatHashSet;
import org.eclipse.collections.api.block.procedure.primitive.ObjectIntProcedure;
import org.eclipse.collections.impl.tuple.primitive.PrimitiveTuples;
This file was automatically generated from template file objectPrimitiveHashMapWithHashingStrategy.stg.
Since:7.0.
/** * This file was automatically generated from template file objectPrimitiveHashMapWithHashingStrategy.stg. * * @since 7.0. */
public class ObjectFloatHashMapWithHashingStrategy<K> implements MutableObjectFloatMap<K>, Externalizable { public static final float EMPTY_VALUE = 0.0f; private static final long serialVersionUID = 1L; private static final int OCCUPIED_DATA_RATIO = 2; private static final int OCCUPIED_SENTINEL_RATIO = 4; private static final int DEFAULT_INITIAL_CAPACITY = 8; private static final Object NULL_KEY = new Object() { @Override public boolean equals(Object obj) { throw new RuntimeException("Possible corruption through unsynchronized concurrent modification."); } @Override public int hashCode() { throw new RuntimeException("Possible corruption through unsynchronized concurrent modification."); } @Override public String toString() { return "ObjectFloatHashMapWithHashingStrategy.NULL_KEY"; } }; private static final Object REMOVED_KEY = new Object() { @Override public boolean equals(Object obj) { throw new RuntimeException("Possible corruption through unsynchronized concurrent modification."); } @Override public int hashCode() { throw new RuntimeException("Possible corruption through unsynchronized concurrent modification."); } @Override public String toString() { return "ObjectFloatHashMapWithHashingStrategy.REMOVED_KEY"; } }; private Object[] keys; private float[] values; private int occupiedWithData; private int occupiedWithSentinels; private HashingStrategy<? super K> hashingStrategy;
Deprecated:Use ObjectFloatHashMapWithHashingStrategy(HashingStrategy) instead.
/** * @deprecated Use ObjectFloatHashMapWithHashingStrategy(HashingStrategy) instead. */
@Deprecated public ObjectFloatHashMapWithHashingStrategy() { } public ObjectFloatHashMapWithHashingStrategy(HashingStrategy<? super K> hashingStrategy) { this.hashingStrategy = hashingStrategy; this.allocateTable(DEFAULT_INITIAL_CAPACITY << 1); } public ObjectFloatHashMapWithHashingStrategy(HashingStrategy<? super K> hashingStrategy, int initialCapacity) { if (initialCapacity < 0) { throw new IllegalArgumentException("initial capacity cannot be less than 0"); } this.hashingStrategy = hashingStrategy; int capacity = this.smallestPowerOfTwoGreaterThan(this.fastCeil(initialCapacity * OCCUPIED_DATA_RATIO)); this.allocateTable(capacity); } public ObjectFloatHashMapWithHashingStrategy(HashingStrategy<? super K> hashingStrategy, ObjectFloatMap<? extends K> map) { this(hashingStrategy, Math.max(map.size(), DEFAULT_INITIAL_CAPACITY)); this.putAll(map); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newMap(HashingStrategy<? super K> hashingStrategy) { return new ObjectFloatHashMapWithHashingStrategy<>(hashingStrategy); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newMap(HashingStrategy<? super K> hashingStrategy, ObjectFloatMap<K> map) { return new ObjectFloatHashMapWithHashingStrategy<>(hashingStrategy, map); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newMap(ObjectFloatHashMapWithHashingStrategy<K> map) { return new ObjectFloatHashMapWithHashingStrategy<>(map.hashingStrategy, map); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newWithKeysValues(HashingStrategy<? super K> hashingStrategy, K key1, float value1) { return new ObjectFloatHashMapWithHashingStrategy<K>(hashingStrategy, 1).withKeyValue(key1, value1); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newWithKeysValues(HashingStrategy<? super K> hashingStrategy, K key1, float value1, K key2, float value2) { return new ObjectFloatHashMapWithHashingStrategy<K>(hashingStrategy, 2).withKeysValues(key1, value1, key2, value2); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newWithKeysValues(HashingStrategy<? super K> hashingStrategy, K key1, float value1, K key2, float value2, K key3, float value3) { return new ObjectFloatHashMapWithHashingStrategy<K>(hashingStrategy, 3).withKeysValues(key1, value1, key2, value2, key3, value3); } public static <K> ObjectFloatHashMapWithHashingStrategy<K> newWithKeysValues(HashingStrategy<? super K> hashingStrategy, K key1, float value1, K key2, float value2, K key3, float value3, K key4, float value4) { return new ObjectFloatHashMapWithHashingStrategy<K>(hashingStrategy, 4).withKeysValues(key1, value1, key2, value2, key3, value3, key4, value4); } private int smallestPowerOfTwoGreaterThan(int n) { return n > 1 ? Integer.highestOneBit(n - 1) << 1 : 1; } private int fastCeil(float v) { int possibleResult = (int) v; if (v - possibleResult > 0.0F) { possibleResult++; } return possibleResult; } @Override public boolean equals(Object obj) { if (this == obj) { return true; } if (!(obj instanceof ObjectFloatMap)) { return false; } ObjectFloatMap<K> other = (ObjectFloatMap<K>) obj; if (this.size() != other.size()) { return false; } for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && (!other.containsKey(this.toNonSentinel(this.keys[i])) || Float.compare(this.values[i], other.getOrThrow(this.toNonSentinel(this.keys[i]))) != 0)) { return false; } } return true; } @Override public int hashCode() { int result = 0; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result += this.hashingStrategy.computeHashCode(this.toNonSentinel(this.keys[i])) ^ Float.floatToIntBits(this.values[i]); } } return result; } @Override public String toString() { StringBuilder appendable = new StringBuilder(); appendable.append("{"); boolean first = true; for (int i = 0; i < this.keys.length; i++) { Object key = this.keys[i]; if (isNonSentinel(key)) { if (!first) { appendable.append(", "); } appendable.append(this.toNonSentinel(key)).append("=").append(this.values[i]); first = false; } } appendable.append("}"); return appendable.toString(); } @Override public int size() { return this.occupiedWithData; } @Override public boolean isEmpty() { return this.size() == 0; } @Override public boolean notEmpty() { return this.size() != 0; } @Override public String makeString() { return this.makeString(", "); } @Override public String makeString(String separator) { return this.makeString("", separator, ""); } @Override public String makeString(String start, String separator, String end) { Appendable stringBuilder = new StringBuilder(); this.appendString(stringBuilder, start, separator, end); return stringBuilder.toString(); } @Override public void appendString(Appendable appendable) { this.appendString(appendable, ", "); } @Override public void appendString(Appendable appendable, String separator) { this.appendString(appendable, "", separator, ""); } @Override public void appendString(Appendable appendable, String start, String separator, String end) { try { appendable.append(start); boolean first = true; for (int i = 0; i < this.keys.length; i++) { Object key = this.keys[i]; if (isNonSentinel(key)) { if (!first) { appendable.append(separator); } appendable.append(String.valueOf(String.valueOf(this.values[i]))); first = false; } } appendable.append(end); } catch (IOException e) { throw new RuntimeException(e); } } @Override public MutableFloatIterator floatIterator() { return new InternalFloatIterator(); } @Override public float[] toArray() { float[] result = new float[this.size()]; int index = 0; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result[index] = this.values[i]; index++; } } return result; } @Override public boolean contains(float value) { return this.containsValue(value); } @Override public boolean containsAll(float... source) { for (float item : source) { if (!this.containsValue(item)) { return false; } } return true; } @Override public boolean containsAll(FloatIterable source) { return this.containsAll(source.toArray()); } @Override public void clear() { this.occupiedWithData = 0; this.occupiedWithSentinels = 0; Arrays.fill(this.keys, null); Arrays.fill(this.values, EMPTY_VALUE); } @Override public void put(K key, float value) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { // key already present in map this.values[index] = value; return; } this.addKeyValueAtIndex(key, value, index); } @Override public void putAll(ObjectFloatMap<? extends K> map) { map.forEachKeyValue(this::put); } @Override public void removeKey(K key) { int index = this.probe(key); this.removeKeyAtIndex(key, index); } public void removeKeyAtIndex(K key, int index) { if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { this.keys[index] = REMOVED_KEY; this.values[index] = EMPTY_VALUE; this.occupiedWithData--; this.occupiedWithSentinels++; } } @Override public void remove(Object key) { this.removeKey((K) key); } @Override public float removeKeyIfAbsent(K key, float value) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { this.keys[index] = REMOVED_KEY; float oldValue = this.values[index]; this.values[index] = EMPTY_VALUE; this.occupiedWithData--; this.occupiedWithSentinels++; return oldValue; } return value; } @Override public float getIfAbsentPut(K key, float value) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { return this.values[index]; } this.addKeyValueAtIndex(key, value, index); return value; } @Override public float getIfAbsentPut(K key, FloatFunction0 function) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { return this.values[index]; } float value = function.value(); this.addKeyValueAtIndex(key, value, index); return value; } @Override public <P> float getIfAbsentPutWith(K key, FloatFunction<? super P> function, P parameter) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { return this.values[index]; } float value = function.floatValueOf(parameter); this.addKeyValueAtIndex(key, value, index); return value; } @Override public float getIfAbsentPutWithKey(K key, FloatFunction<? super K> function) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { return this.values[index]; } float value = function.floatValueOf(key); this.addKeyValueAtIndex(key, value, index); return value; } @Override public float updateValue(K key, float initialValueIfAbsent, FloatToFloatFunction function) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { this.values[index] = function.valueOf(this.values[index]); return this.values[index]; } float value = function.valueOf(initialValueIfAbsent); this.addKeyValueAtIndex(key, value, index); return value; } private void addKeyValueAtIndex(K key, float value, int index) { if (this.keys[index] == REMOVED_KEY) { --this.occupiedWithSentinels; } this.keys[index] = toSentinelIfNull(key); this.values[index] = value; ++this.occupiedWithData; if (this.occupiedWithData + this.occupiedWithSentinels > this.maxOccupiedWithData()) { this.rehashAndGrow(); } } @Override public float addToValue(K key, float toBeAdded) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { this.values[index] += toBeAdded; return this.values[index]; } this.addKeyValueAtIndex(key, toBeAdded, index); return toBeAdded; } @Override public ObjectFloatHashMapWithHashingStrategy<K> withKeyValue(K key1, float value1) { this.put(key1, value1); return this; } public ObjectFloatHashMapWithHashingStrategy<K> withKeysValues(K key1, float value1, K key2, float value2) { this.put(key1, value1); this.put(key2, value2); return this; } public ObjectFloatHashMapWithHashingStrategy<K> withKeysValues(K key1, float value1, K key2, float value2, K key3, float value3) { this.put(key1, value1); this.put(key2, value2); this.put(key3, value3); return this; } public ObjectFloatHashMapWithHashingStrategy<K> withKeysValues(K key1, float value1, K key2, float value2, K key3, float value3, K key4, float value4) { this.put(key1, value1); this.put(key2, value2); this.put(key3, value3); this.put(key4, value4); return this; } @Override public ObjectFloatHashMapWithHashingStrategy<K> withoutKey(K key) { this.removeKey(key); return this; } @Override public ObjectFloatHashMapWithHashingStrategy<K> withoutAllKeys(Iterable<? extends K> keys) { for (K key : keys) { this.removeKey(key); } return this; } @Override public MutableObjectFloatMap<K> asUnmodifiable() { return new UnmodifiableObjectFloatMap<>(this); } @Override public MutableObjectFloatMap<K> asSynchronized() { return new SynchronizedObjectFloatMap<>(this); } @Override public ImmutableObjectFloatMap<K> toImmutable() { return ObjectFloatMaps.immutable.withAll(this); } @Override public float get(Object key) { return this.getIfAbsent(key, EMPTY_VALUE); } @Override public float getOrThrow(Object key) { int index = this.probe(key); if (isNonSentinel(this.keys[index])) { return this.values[index]; } throw new IllegalStateException("Key " + key + " not present."); } @Override public float getIfAbsent(Object key, float ifAbsent) { int index = this.probe(key); if (isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key)) { return this.values[index]; } return ifAbsent; } @Override public boolean containsKey(Object key) { int index = this.probe(key); return isNonSentinel(this.keys[index]) && this.nullSafeEquals(this.toNonSentinel(this.keys[index]), key); } @Override public boolean containsValue(float value) { for (int i = 0; i < this.values.length; i++) { if (isNonSentinel(this.keys[i]) && Float.compare(this.values[i], value) == 0) { return true; } } return false; } @Override public void forEach(FloatProcedure procedure) { this.each(procedure); } @Override public void each(FloatProcedure procedure) { this.forEachValue(procedure); } @Override public void forEachValue(FloatProcedure procedure) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { procedure.value(this.values[i]); } } } @Override public void forEachKey(Procedure<? super K> procedure) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { procedure.value(this.toNonSentinel(this.keys[i])); } } } @Override public void forEachKeyValue(ObjectFloatProcedure<? super K> procedure) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { procedure.value(this.toNonSentinel(this.keys[i]), this.values[i]); } } } @Override public ObjectFloatHashMapWithHashingStrategy<K> select(ObjectFloatPredicate<? super K> predicate) { ObjectFloatHashMapWithHashingStrategy<K> result = ObjectFloatHashMapWithHashingStrategy.newMap(this.hashingStrategy); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && predicate.accept(this.toNonSentinel(this.keys[i]), this.values[i])) { result.put(this.toNonSentinel(this.keys[i]), this.values[i]); } } return result; } @Override public ObjectFloatHashMapWithHashingStrategy<K> reject(ObjectFloatPredicate<? super K> predicate) { ObjectFloatHashMapWithHashingStrategy<K> result = ObjectFloatHashMapWithHashingStrategy.newMap(this.hashingStrategy); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && !predicate.accept(this.toNonSentinel(this.keys[i]), this.values[i])) { result.put(this.toNonSentinel(this.keys[i]), this.values[i]); } } return result; } @Override public MutableFloatCollection select(FloatPredicate predicate) { FloatArrayList result = new FloatArrayList(); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && predicate.accept(this.values[i])) { result.add(this.values[i]); } } return result; } @Override public MutableFloatCollection reject(FloatPredicate predicate) { FloatArrayList result = new FloatArrayList(); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && !predicate.accept(this.values[i])) { result.add(this.values[i]); } } return result; } @Override public float detectIfNone(FloatPredicate predicate, float ifNone) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && predicate.accept(this.values[i])) { return this.values[i]; } } return ifNone; } @Override public <V> MutableCollection<V> collect(FloatToObjectFunction<? extends V> function) { MutableList<V> result = FastList.newList(this.size()); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result.add(function.valueOf(this.values[i])); } } return result; } @Override public int count(FloatPredicate predicate) { int count = 0; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && predicate.accept(this.values[i])) { count++; } } return count; } @Override public boolean anySatisfy(FloatPredicate predicate) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && predicate.accept(this.values[i])) { return true; } } return false; } @Override public boolean allSatisfy(FloatPredicate predicate) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && !predicate.accept(this.values[i])) { return false; } } return true; } @Override public boolean noneSatisfy(FloatPredicate predicate) { for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && predicate.accept(this.values[i])) { return false; } } return true; } @Override public <V> V injectInto(V injectedValue, ObjectFloatToObjectFunction<? super V, ? extends V> function) { V result = injectedValue; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result = function.valueOf(result, this.values[i]); } } return result; } @Override public RichIterable<FloatIterable> chunk(int size) { if (size <= 0) { throw new IllegalArgumentException("Size for groups must be positive but was: " + size); } MutableList<FloatIterable> result = Lists.mutable.empty(); if (this.notEmpty()) { FloatIterator iterator = this.floatIterator(); while (iterator.hasNext()) { MutableFloatBag batch = FloatBags.mutable.empty(); for (int i = 0; i < size && iterator.hasNext(); i++) { batch.add(iterator.next()); } result.add(batch); } } return result; } @Override public double sum() { double result = 0.0; double compensation = 0.0; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { double adjustedValue = this.values[i] - compensation; double nextSum = result + adjustedValue; compensation = nextSum - result - adjustedValue; result = nextSum; } } return result; } @Override public float max() { if (this.isEmpty()) { throw new NoSuchElementException(); } float max = 0.0f; boolean isMaxSet = false; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && (!isMaxSet || Float.compare(max, this.values[i]) < 0)) { max = this.values[i]; isMaxSet = true; } } return max; } @Override public float min() { if (this.isEmpty()) { throw new NoSuchElementException(); } float min = 0.0f; boolean isMinSet = false; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && (!isMinSet || Float.compare(this.values[i], min) < 0)) { min = this.values[i]; isMinSet = true; } } return min; } @Override public float maxIfEmpty(float defaultValue) { if (this.isEmpty()) { return defaultValue; } float max = 0.0f; boolean isMaxSet = false; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && (!isMaxSet || Float.compare(max, this.values[i]) < 0)) { max = this.values[i]; isMaxSet = true; } } return max; } @Override public float minIfEmpty(float defaultValue) { if (this.isEmpty()) { return defaultValue; } float min = 0.0f; boolean isMinSet = false; for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i]) && (!isMinSet || Float.compare(this.values[i], min) < 0)) { min = this.values[i]; isMinSet = true; } } return min; } @Override public double average() { if (this.isEmpty()) { throw new ArithmeticException(); } return this.sum() / (double) this.size(); } @Override public double median() { if (this.isEmpty()) { throw new ArithmeticException(); } float[] sortedArray = this.toSortedArray(); int middleIndex = sortedArray.length >> 1; if (sortedArray.length > 1 && (sortedArray.length & 1) == 0) { float first = sortedArray[middleIndex]; float second = sortedArray[middleIndex - 1]; return ((double) first + (double) second) / 2.0; } return (double) sortedArray[middleIndex]; } @Override public MutableFloatList toList() { MutableFloatList result = new FloatArrayList(this.size()); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result.add(this.values[i]); } } return result; } @Override public MutableFloatSet toSet() { MutableFloatSet result = new FloatHashSet(this.size()); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result.add(this.values[i]); } } return result; } @Override public MutableFloatBag toBag() { MutableFloatBag result = new FloatHashBag(this.size()); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { result.add(this.values[i]); } } return result; } @Override public LazyFloatIterable asLazy() { return new LazyFloatIterableAdapter(this); } @Override public float[] toSortedArray() { float[] array = this.toArray(); Arrays.sort(array); return array; } @Override public MutableFloatList toSortedList() { return this.toList().sortThis(); } @Override public void writeExternal(ObjectOutput out) throws IOException { out.writeObject(this.hashingStrategy); out.writeInt(this.size()); for (int i = 0; i < this.keys.length; i++) { if (isNonSentinel(this.keys[i])) { out.writeObject(this.toNonSentinel(this.keys[i])); out.writeFloat(this.values[i]); } } } @Override public void readExternal(ObjectInput in) throws IOException, ClassNotFoundException { this.hashingStrategy = (HashingStrategy<? super K>) in.readObject(); int size = in.readInt(); int capacity = this.smallestPowerOfTwoGreaterThan(this.fastCeil(size * OCCUPIED_DATA_RATIO)); this.allocateTable(capacity); for (int i = 0; i < size; i++) { this.put((K) in.readObject(), in.readFloat()); } } @Override public LazyIterable<K> keysView() { return new KeysView(); } @Override public RichIterable<ObjectFloatPair<K>> keyValuesView() { return new KeyValuesView(); } @Override public MutableFloatObjectMap<K> flipUniqueValues() { MutableFloatObjectMap<K> result = FloatObjectMaps.mutable.empty(); this.forEachKeyValue((key, value)-> { K oldKey = result.put(value, key); if (oldKey != null) { throw new IllegalStateException("Duplicate value: " + value + " found at key: " + oldKey + " and key: " + key); } }); return result; }
Rehashes every element in the set into a new backing table of the smallest possible size and eliminating removed sentinels.
/** * Rehashes every element in the set into a new backing table of the smallest possible size and eliminating removed sentinels. */
public void compact() { this.rehash(this.smallestPowerOfTwoGreaterThan(this.size())); } private void rehashAndGrow() { this.rehash(this.keys.length << 1); } private void rehash(int newCapacity) { int oldLength = this.keys.length; Object[] old = this.keys; float[] oldValues = this.values; this.allocateTable(newCapacity); this.occupiedWithData = 0; this.occupiedWithSentinels = 0; for (int i = 0; i < oldLength; i++) { if (isNonSentinel(old[i])) { this.put(this.toNonSentinel(old[i]), oldValues[i]); } } } // exposed for testing int probe(Object element) { int index = this.spread(element); int removedIndex = -1; if (isRemovedKey(this.keys[index])) { removedIndex = index; } else if (this.keys[index] == null || this.nullSafeEquals(this.toNonSentinel(this.keys[index]), element)) { return index; } int nextIndex = index; int probe = 17; // loop until an empty slot is reached while (true) { // Probe algorithm: 17*n*(n+1)/2 where n = no. of collisions nextIndex += probe; probe += 17; nextIndex &= this.keys.length - 1; if (isRemovedKey(this.keys[nextIndex])) { if (removedIndex == -1) { removedIndex = nextIndex; } } else if (this.nullSafeEquals(this.toNonSentinel(this.keys[nextIndex]), element)) { return nextIndex; } else if (this.keys[nextIndex] == null) { return removedIndex == -1 ? nextIndex : removedIndex; } } } // exposed for testing int spread(Object element) { // This function ensures that hashCodes that differ only by // constant multiples at each bit position have a bounded // number of collisions (approximately 8 at default load factor). K nonSentinelKey = this.toNonSentinel(element); int h = nonSentinelKey == null ? 0 : this.hashingStrategy.computeHashCode(nonSentinelKey); h ^= h >>> 20 ^ h >>> 12; h ^= h >>> 7 ^ h >>> 4; return h & (this.keys.length - 1); } private boolean nullSafeEquals(K value, Object other) { if (value == null) { if (other == null) { return true; } } else if (value != NULL_KEY && other != null) { if (this.hashingStrategy.equals(value, this.toNonSentinel(other))) { return true; } } return false; } private void allocateTable(int sizeToAllocate) { this.keys = new Object[sizeToAllocate]; this.values = new float[sizeToAllocate]; } private static boolean isRemovedKey(Object key) { return key == REMOVED_KEY; } private static <K> boolean isNonSentinel(K key) { return key != null && !isRemovedKey(key); } private K toNonSentinel(Object key) { return key == NULL_KEY ? null : (K) key; } private static Object toSentinelIfNull(Object key) { return key == null ? NULL_KEY : key; } private int maxOccupiedWithData() { int capacity = this.keys.length; // need at least one free slot for open addressing return Math.min(capacity - 1, capacity / OCCUPIED_DATA_RATIO); } private int maxOccupiedWithSentinels() { return this.keys.length / OCCUPIED_SENTINEL_RATIO; } private class InternalFloatIterator implements MutableFloatIterator { private int count; private int position; @Override public boolean hasNext() { return this.count != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public float next() { if (!this.hasNext()) { throw new NoSuchElementException(); } Object[] keys = ObjectFloatHashMapWithHashingStrategy.this.keys; while (!isNonSentinel(keys[this.position])) { this.position++; } float result = ObjectFloatHashMapWithHashingStrategy.this.values[this.position]; this.count++; this.position++; return result; } @Override public void remove() { if (this.position == 0 || !isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[this.position - 1])) { throw new IllegalStateException(); } ObjectFloatHashMapWithHashingStrategy.this.remove(ObjectFloatHashMapWithHashingStrategy.this.keys[this.position - 1]); this.count--; } } @Override public Set<K> keySet() { return new KeySet(); } @Override public MutableFloatCollection values() { return new ValuesCollection(); } private class KeySet implements Set<K> { @Override public boolean equals(Object obj) { if (obj instanceof Set) { Set<?> other = (Set<?>) obj; if (other.size() == this.size()) { return this.containsAll(other); } } return false; } @Override public int hashCode() { int hashCode = 0; Object[] table = ObjectFloatHashMapWithHashingStrategy.this.keys; for (int i = 0; i < table.length; i++) { Object key = table[i]; if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(key)) { K nonSentinelKey = ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(key); hashCode += nonSentinelKey == null ? 0 : ObjectFloatHashMapWithHashingStrategy.this.hashingStrategy.computeHashCode(nonSentinelKey); } } return hashCode; } @Override public int size() { return ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean isEmpty() { return ObjectFloatHashMapWithHashingStrategy.this.isEmpty(); } @Override public boolean contains(Object o) { return ObjectFloatHashMapWithHashingStrategy.this.containsKey(o); } @Override public Object[] toArray() { int size = ObjectFloatHashMapWithHashingStrategy.this.size(); Object[] result = new Object[size]; this.copyKeys(result); return result; } @Override public <T> T[] toArray(T[] result) { int size = ObjectFloatHashMapWithHashingStrategy.this.size(); if (result.length < size) { result = (T[]) Array.newInstance(result.getClass().getComponentType(), size); } this.copyKeys(result); if (size < result.length) { result[size] = null; } return result; } @Override public boolean add(K key) { throw new UnsupportedOperationException("Cannot call add() on " + this.getClass().getSimpleName()); } @Override public boolean remove(Object key) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); ObjectFloatHashMapWithHashingStrategy.this.removeKey((K) key); return oldSize != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean containsAll(Collection<?> collection) { for (Object aCollection : collection) { if (!ObjectFloatHashMapWithHashingStrategy.this.containsKey(aCollection)) { return false; } } return true; } @Override public boolean addAll(Collection<? extends K> collection) { throw new UnsupportedOperationException("Cannot call addAll() on " + this.getClass().getSimpleName()); } @Override public boolean retainAll(Collection<?> collection) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); Iterator<K> iterator = this.iterator(); while (iterator.hasNext()) { K next = iterator.next(); if (!collection.contains(next)) { iterator.remove(); } } return oldSize != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean removeAll(Collection<?> collection) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); for (Object object : collection) { ObjectFloatHashMapWithHashingStrategy.this.removeKey((K) object); } return oldSize != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public void clear() { ObjectFloatHashMapWithHashingStrategy.this.clear(); } @Override public Iterator<K> iterator() { return new KeySetIterator(); } private void copyKeys(Object[] result) { int count = 0; for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { Object key = ObjectFloatHashMapWithHashingStrategy.this.keys[i]; if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(key)) { result[count++] = ObjectFloatHashMapWithHashingStrategy.this.keys[i]; } } } } private class KeySetIterator implements Iterator<K> { private int count; private int position; private K currentKey; private boolean isCurrentKeySet; @Override public boolean hasNext() { return this.count < ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public K next() { if (!this.hasNext()) { throw new NoSuchElementException(); } this.count++; Object[] keys = ObjectFloatHashMapWithHashingStrategy.this.keys; while (!isNonSentinel(keys[this.position])) { this.position++; } this.currentKey = (K) ObjectFloatHashMapWithHashingStrategy.this.keys[this.position]; this.isCurrentKeySet = true; this.position++; return ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(this.currentKey); } @Override public void remove() { if (!this.isCurrentKeySet) { throw new IllegalStateException(); } this.isCurrentKeySet = false; this.count--; if (isNonSentinel(this.currentKey)) { int index = this.position - 1; ObjectFloatHashMapWithHashingStrategy.this.removeKeyAtIndex(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(this.currentKey), index); } else { ObjectFloatHashMapWithHashingStrategy.this.removeKey(this.currentKey); } } } private class ValuesCollection implements MutableFloatCollection { @Override public int size() { return ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean isEmpty() { return ObjectFloatHashMapWithHashingStrategy.this.isEmpty(); } @Override public boolean notEmpty() { return ObjectFloatHashMapWithHashingStrategy.this.notEmpty(); } @Override public String makeString() { return this.makeString(", "); } @Override public String makeString(String separator) { return this.makeString("", separator, ""); } @Override public String makeString(String start, String separator, String end) { Appendable stringBuilder = new StringBuilder(); this.appendString(stringBuilder, start, separator, end); return stringBuilder.toString(); } @Override public void appendString(Appendable appendable) { this.appendString(appendable, ", "); } @Override public void appendString(Appendable appendable, String separator) { this.appendString(appendable, "", separator, ""); } @Override public void appendString(Appendable appendable, String start, String separator, String end) { try { appendable.append(start); boolean first = true; for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { Object key = ObjectFloatHashMapWithHashingStrategy.this.keys[i]; if (isNonSentinel(key)) { if (!first) { appendable.append(separator); } appendable.append(String.valueOf(ObjectFloatHashMapWithHashingStrategy.this.values[i])); first = false; } } appendable.append(end); } catch (IOException e) { throw new RuntimeException(e); } } @Override public boolean add(float element) { throw new UnsupportedOperationException("Cannot call add() on " + this.getClass().getSimpleName()); } @Override public boolean addAll(float... source) { throw new UnsupportedOperationException("Cannot call addAll() on " + this.getClass().getSimpleName()); } @Override public boolean addAll(FloatIterable source) { throw new UnsupportedOperationException("Cannot call addAll() on " + this.getClass().getSimpleName()); } @Override public boolean remove(float item) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { if (isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i]) && Float.compare(item, ObjectFloatHashMapWithHashingStrategy.this.values[i]) == 0) { ObjectFloatHashMapWithHashingStrategy.this.removeKey((K) ObjectFloatHashMapWithHashingStrategy.this.keys[i]); } } return oldSize != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean removeAll(FloatIterable source) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); FloatIterator iterator = source.floatIterator(); while (iterator.hasNext()) { this.remove(iterator.next()); } return oldSize != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean removeAll(float... source) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); for (float item : source) { this.remove(item); } return oldSize != ObjectFloatHashMapWithHashingStrategy.this.size(); } @Override public boolean retainAll(FloatIterable source) { int oldSize = ObjectFloatHashMapWithHashingStrategy.this.size(); final FloatSet sourceSet = source instanceof FloatSet ? (FloatSet) source : source.toSet(); ObjectFloatHashMapWithHashingStrategy<K> retained = ObjectFloatHashMapWithHashingStrategy.this.select((K object, float value) -> sourceSet.contains(value)); if (retained.size() != oldSize) { ObjectFloatHashMapWithHashingStrategy.this.keys = retained.keys; ObjectFloatHashMapWithHashingStrategy.this.values = retained.values; ObjectFloatHashMapWithHashingStrategy.this.occupiedWithData = retained.occupiedWithData; ObjectFloatHashMapWithHashingStrategy.this.occupiedWithSentinels = retained.occupiedWithSentinels; return true; } return false; } @Override public boolean retainAll(float... source) { return this.retainAll(FloatHashSet.newSetWith(source)); } @Override public void clear() { ObjectFloatHashMapWithHashingStrategy.this.clear(); } @Override public MutableFloatCollection with(float element) { throw new UnsupportedOperationException("Cannot call with() on " + this.getClass().getSimpleName()); } @Override public MutableFloatCollection without(float element) { throw new UnsupportedOperationException("Cannot call without() on " + this.getClass().getSimpleName()); } @Override public MutableFloatCollection withAll(FloatIterable elements) { throw new UnsupportedOperationException("Cannot call withAll() on " + this.getClass().getSimpleName()); } @Override public MutableFloatCollection withoutAll(FloatIterable elements) { throw new UnsupportedOperationException("Cannot call withoutAll() on " + this.getClass().getSimpleName()); } @Override public MutableFloatCollection asUnmodifiable() { return UnmodifiableFloatCollection.of(this); } @Override public MutableFloatCollection asSynchronized() { return SynchronizedFloatCollection.of(this); } @Override public ImmutableFloatCollection toImmutable() { return FloatLists.immutable.withAll(this); } @Override public MutableFloatIterator floatIterator() { return ObjectFloatHashMapWithHashingStrategy.this.floatIterator(); } @Override public float[] toArray() { return ObjectFloatHashMapWithHashingStrategy.this.toArray(); } @Override public boolean contains(float value) { return ObjectFloatHashMapWithHashingStrategy.this.containsValue(value); } @Override public boolean containsAll(float... source) { return ObjectFloatHashMapWithHashingStrategy.this.containsAll(source); } @Override public boolean containsAll(FloatIterable source) { return ObjectFloatHashMapWithHashingStrategy.this.containsAll(source); } @Override public void forEach(FloatProcedure procedure) { ObjectFloatHashMapWithHashingStrategy.this.forEach(procedure); } @Override public void each(FloatProcedure procedure) { this.forEach(procedure); } @Override public MutableFloatCollection select(FloatPredicate predicate) { return ObjectFloatHashMapWithHashingStrategy.this.select(predicate); } @Override public MutableFloatCollection reject(FloatPredicate predicate) { return ObjectFloatHashMapWithHashingStrategy.this.reject(predicate); } @Override public <V> MutableCollection<V> collect(FloatToObjectFunction<? extends V> function) { return ObjectFloatHashMapWithHashingStrategy.this.collect(function); } @Override public <T> T injectInto(T injectedValue, ObjectFloatToObjectFunction<? super T, ? extends T> function) { return ObjectFloatHashMapWithHashingStrategy.this.injectInto(injectedValue, function); } @Override public RichIterable<FloatIterable> chunk(int size) { return ObjectFloatHashMapWithHashingStrategy.this.chunk(size); } @Override public float detectIfNone(FloatPredicate predicate, float ifNone) { return ObjectFloatHashMapWithHashingStrategy.this.detectIfNone(predicate, ifNone); } @Override public int count(FloatPredicate predicate) { return ObjectFloatHashMapWithHashingStrategy.this.count(predicate); } @Override public boolean anySatisfy(FloatPredicate predicate) { return ObjectFloatHashMapWithHashingStrategy.this.anySatisfy(predicate); } @Override public boolean allSatisfy(FloatPredicate predicate) { return ObjectFloatHashMapWithHashingStrategy.this.allSatisfy(predicate); } @Override public boolean noneSatisfy(FloatPredicate predicate) { return ObjectFloatHashMapWithHashingStrategy.this.noneSatisfy(predicate); } @Override public MutableFloatList toList() { return ObjectFloatHashMapWithHashingStrategy.this.toList(); } @Override public MutableFloatSet toSet() { return ObjectFloatHashMapWithHashingStrategy.this.toSet(); } @Override public MutableFloatBag toBag() { return ObjectFloatHashMapWithHashingStrategy.this.toBag(); } @Override public LazyFloatIterable asLazy() { return new LazyFloatIterableAdapter(this); } @Override public float[] toSortedArray() { return ObjectFloatHashMapWithHashingStrategy.this.toSortedArray(); } @Override public MutableFloatList toSortedList() { return ObjectFloatHashMapWithHashingStrategy.this.toSortedList(); } @Override public double sum() { return ObjectFloatHashMapWithHashingStrategy.this.sum(); } @Override public float max() { return ObjectFloatHashMapWithHashingStrategy.this.max(); } @Override public float maxIfEmpty(float defaultValue) { return ObjectFloatHashMapWithHashingStrategy.this.maxIfEmpty(defaultValue); } @Override public float min() { return ObjectFloatHashMapWithHashingStrategy.this.min(); } @Override public float minIfEmpty(float defaultValue) { return ObjectFloatHashMapWithHashingStrategy.this.minIfEmpty(defaultValue); } @Override public double average() { return ObjectFloatHashMapWithHashingStrategy.this.average(); } @Override public double median() { return ObjectFloatHashMapWithHashingStrategy.this.median(); }
Since:9.2.
/** * @since 9.2. */
@Override public MutableFloatCollection newEmpty() { return new FloatHashBag(); } } private class KeysView extends AbstractLazyIterable<K> { @Override public void each(Procedure<? super K> procedure) { ObjectFloatHashMapWithHashingStrategy.this.forEachKey(procedure); } @Override public void forEachWithIndex(ObjectIntProcedure<? super K> objectFloatProcedure) { int index = 0; for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i])) { objectFloatProcedure.value(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i]), index); index++; } } } @Override public <P> void forEachWith(Procedure2<? super K, ? super P> procedure, P parameter) { for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i])) { procedure.value(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i]), parameter); } } } @Override public Iterator<K> iterator() { return new InternalKeysViewIterator(); } public class InternalKeysViewIterator implements Iterator<K> { private int count; private int position; @Override public K next() { if (!this.hasNext()) { throw new NoSuchElementException(); } Object[] keys = ObjectFloatHashMapWithHashingStrategy.this.keys; while (!isNonSentinel(keys[this.position])) { this.position++; } K result = ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[this.position]); this.count++; this.position++; return result; } @Override public void remove() { throw new UnsupportedOperationException("Cannot call remove() on " + this.getClass().getSimpleName()); } @Override public boolean hasNext() { return this.count != ObjectFloatHashMapWithHashingStrategy.this.size(); } } } private class KeyValuesView extends AbstractLazyIterable<ObjectFloatPair<K>> { @Override public void each(Procedure<? super ObjectFloatPair<K>> procedure) { for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i])) { procedure.value(PrimitiveTuples.pair(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i]), ObjectFloatHashMapWithHashingStrategy.this.values[i])); } } } @Override public void forEachWithIndex(ObjectIntProcedure<? super ObjectFloatPair<K>> objectIntProcedure) { int index = 0; for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i])) { objectIntProcedure.value(PrimitiveTuples.pair(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i]), ObjectFloatHashMapWithHashingStrategy.this.values[i]), index); index++; } } } @Override public <P> void forEachWith(Procedure2<? super ObjectFloatPair<K>, ? super P> procedure, P parameter) { for (int i = 0; i < ObjectFloatHashMapWithHashingStrategy.this.keys.length; i++) { if (ObjectFloatHashMapWithHashingStrategy.isNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i])) { procedure.value(PrimitiveTuples.pair(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[i]), ObjectFloatHashMapWithHashingStrategy.this.values[i]), parameter); } } } @Override public Iterator<ObjectFloatPair<K>> iterator() { return new InternalKeyValuesIterator(); } public class InternalKeyValuesIterator implements Iterator<ObjectFloatPair<K>> { private int count; private int position; @Override public ObjectFloatPair<K> next() { if (!this.hasNext()) { throw new NoSuchElementException(); } Object[] keys = ObjectFloatHashMapWithHashingStrategy.this.keys; while (!isNonSentinel(keys[this.position])) { this.position++; } ObjectFloatPair<K> result = PrimitiveTuples.pair(ObjectFloatHashMapWithHashingStrategy.this.toNonSentinel(ObjectFloatHashMapWithHashingStrategy.this.keys[this.position]), ObjectFloatHashMapWithHashingStrategy.this.values[this.position]); this.count++; this.position++; return result; } @Override public void remove() { throw new UnsupportedOperationException("Cannot call remove() on " + this.getClass().getSimpleName()); } @Override public boolean hasNext() { return this.count != ObjectFloatHashMapWithHashingStrategy.this.size(); } } } }