/*
 * Copyright (c) 2018 Goldman Sachs.
 * 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.Serializable;
import java.util.Collection;
import java.util.Collections;

import org.eclipse.collections.api.FloatIterable;
import org.eclipse.collections.api.DoubleIterable;
import org.eclipse.collections.api.LazyFloatIterable;
import org.eclipse.collections.api.LazyDoubleIterable;
import org.eclipse.collections.api.RichIterable;
import org.eclipse.collections.api.bag.MutableBag;
import org.eclipse.collections.api.bag.primitive.MutableFloatBag;
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.function.primitive.DoubleToFloatFunction;
import org.eclipse.collections.api.block.predicate.primitive.FloatPredicate;
import org.eclipse.collections.api.block.predicate.primitive.DoubleFloatPredicate;
import org.eclipse.collections.api.block.procedure.primitive.FloatProcedure;
import org.eclipse.collections.api.block.procedure.primitive.DoubleFloatProcedure;
import org.eclipse.collections.api.block.procedure.primitive.DoubleProcedure;
import org.eclipse.collections.api.collection.primitive.MutableFloatCollection;
import org.eclipse.collections.api.iterator.MutableFloatIterator;
import org.eclipse.collections.api.list.primitive.MutableFloatList;
import org.eclipse.collections.api.map.MutableMap;
import org.eclipse.collections.api.map.primitive.ImmutableDoubleFloatMap;
import org.eclipse.collections.api.map.primitive.DoubleFloatMap;
import org.eclipse.collections.api.map.primitive.MutableDoubleFloatMap;
import org.eclipse.collections.api.map.primitive.MutableFloatDoubleMap;
import org.eclipse.collections.api.set.primitive.MutableDoubleSet;
import org.eclipse.collections.api.set.primitive.MutableFloatSet;
import org.eclipse.collections.api.tuple.primitive.DoubleFloatPair;
import org.eclipse.collections.impl.SynchronizedRichIterable;
import org.eclipse.collections.impl.factory.primitive.DoubleFloatMaps;
import org.eclipse.collections.impl.set.mutable.primitive.SynchronizedDoubleSet;
import org.eclipse.collections.impl.collection.mutable.primitive.SynchronizedFloatCollection;

A synchronized view of a MutableDoubleFloatMap. It is imperative that the user manually synchronize on the collection when iterating over it using the MutableFloatIterator as per Collections.synchronizedCollection(Collection<Object>).

This file was automatically generated from template file synchronizedPrimitivePrimitiveMap.stg.

See Also:
Since:3.1.
/** * A synchronized view of a {@link MutableDoubleFloatMap}. It is imperative that the user manually synchronize on the collection when iterating over it using the * {@link MutableFloatIterator} as per {@link Collections#synchronizedCollection(Collection)}. * <p> * This file was automatically generated from template file synchronizedPrimitivePrimitiveMap.stg. * * @see MutableDoubleFloatMap#asSynchronized() * @see MutableMap#asSynchronized() * @since 3.1. */
public class SynchronizedDoubleFloatMap implements MutableDoubleFloatMap, Serializable { private static final long serialVersionUID = 1L; private final Object lock; private final MutableDoubleFloatMap map; public SynchronizedDoubleFloatMap(MutableDoubleFloatMap map) { this(map, null); } public SynchronizedDoubleFloatMap(MutableDoubleFloatMap map, Object newLock) { if (map == null) { throw new IllegalArgumentException("Cannot create a SynchronizedDoubleFloatMap on a null map"); } this.map = map; this.lock = newLock == null ? this : newLock; } @Override public void clear() { synchronized (this.lock) { this.map.clear(); } } @Override public void put(double key, float value) { synchronized (this.lock) { this.map.put(key, value); } } @Override public void putPair(DoubleFloatPair keyValuePair) { synchronized (this.lock) { this.map.put(keyValuePair.getOne(), keyValuePair.getTwo()); } } @Override public void putAll(DoubleFloatMap map) { synchronized (this.lock) { this.map.putAll(map); } } @Override public void removeKey(double key) { synchronized (this.lock) { this.map.removeKey(key); } } @Override public void remove(double key) { synchronized (this.lock) { this.map.remove(key); } } @Override public float removeKeyIfAbsent(double key, float value) { synchronized (this.lock) { return this.map.removeKeyIfAbsent(key, value); } } @Override public float getIfAbsentPut(double key, float value) { synchronized (this.lock) { return this.map.getIfAbsentPut(key, value); } } @Override public float getIfAbsentPut(double key, FloatFunction0 function) { synchronized (this.lock) { return this.map.getIfAbsentPut(key, function); } } @Override public float getIfAbsentPutWithKey(double key, DoubleToFloatFunction function) { synchronized (this.lock) { return this.map.getIfAbsentPutWithKey(key, function); } } @Override public <P> float getIfAbsentPutWith(double key, FloatFunction<? super P> function, P parameter) { synchronized (this.lock) { return this.map.getIfAbsentPutWith(key, function, parameter); } } @Override public float updateValue(double key, float initialValueIfAbsent, FloatToFloatFunction function) { synchronized (this.lock) { return this.map.updateValue(key, initialValueIfAbsent, function); } } @Override public float get(double key) { synchronized (this.lock) { return this.map.get(key); } } @Override public float getIfAbsent(double key, float ifAbsent) { synchronized (this.lock) { return this.map.getIfAbsent(key, ifAbsent); } } @Override public float getOrThrow(double key) { synchronized (this.lock) { return this.map.getOrThrow(key); } } @Override public boolean containsKey(double key) { synchronized (this.lock) { return this.map.containsKey(key); } } @Override public boolean containsValue(float value) { synchronized (this.lock) { return this.map.containsValue(value); } } @Override public void forEachValue(FloatProcedure procedure) { synchronized (this.lock) { this.map.forEachValue(procedure); } } @Override public void forEachKey(DoubleProcedure procedure) { synchronized (this.lock) { this.map.forEachKey(procedure); } } @Override public void forEachKeyValue(DoubleFloatProcedure procedure) { synchronized (this.lock) { this.map.forEachKeyValue(procedure); } } @Override public LazyDoubleIterable keysView() { synchronized (this.lock) { return this.map.keysView(); } } @Override public RichIterable<DoubleFloatPair> keyValuesView() { synchronized (this.lock) { return SynchronizedRichIterable.of(this.map.keyValuesView(), this.lock).asLazy(); } } @Override public MutableFloatDoubleMap flipUniqueValues() { synchronized (this.lock) { return this.map.flipUniqueValues(); } } @Override public MutableDoubleFloatMap select(DoubleFloatPredicate predicate) { synchronized (this.lock) { return this.map.select(predicate); } } @Override public MutableDoubleFloatMap reject(DoubleFloatPredicate predicate) { synchronized (this.lock) { return this.map.reject(predicate); } }
This must be manually synchronized by the developer.
/** * This must be manually synchronized by the developer. */
@Override public MutableFloatIterator floatIterator() { return this.map.floatIterator(); } @Override public void forEach(FloatProcedure procedure) { this.each(procedure); }
Since:7.0.
/** * @since 7.0. */
@Override public void each(FloatProcedure procedure) { synchronized (this.lock) { this.map.forEach(procedure); } } @Override public int count(FloatPredicate predicate) { synchronized (this.lock) { return this.map.count(predicate); } } @Override public boolean anySatisfy(FloatPredicate predicate) { synchronized (this.lock) { return this.map.anySatisfy(predicate); } } @Override public boolean allSatisfy(FloatPredicate predicate) { synchronized (this.lock) { return this.map.allSatisfy(predicate); } } @Override public boolean noneSatisfy(FloatPredicate predicate) { synchronized (this.lock) { return this.map.noneSatisfy(predicate); } } @Override public MutableFloatBag select(FloatPredicate predicate) { synchronized (this.lock) { return this.map.select(predicate); } } @Override public MutableFloatBag reject(FloatPredicate predicate) { synchronized (this.lock) { return this.map.reject(predicate); } } @Override public <V> MutableBag<V> collect(FloatToObjectFunction<? extends V> function) { synchronized (this.lock) { return this.map.collect(function); } } @Override public float detectIfNone(FloatPredicate predicate, float ifNone) { synchronized (this.lock) { return this.map.detectIfNone(predicate, ifNone); } } @Override public double sum() { synchronized (this.lock) { return this.map.sum(); } } @Override public float max() { synchronized (this.lock) { return this.map.max(); } } @Override public float maxIfEmpty(float defaultValue) { synchronized (this.lock) { return this.map.maxIfEmpty(defaultValue); } } @Override public float min() { synchronized (this.lock) { return this.map.min(); } } @Override public float minIfEmpty(float defaultValue) { synchronized (this.lock) { return this.map.minIfEmpty(defaultValue); } } @Override public double average() { synchronized (this.lock) { return this.map.average(); } } @Override public double median() { synchronized (this.lock) { return this.map.median(); } } @Override public float addToValue(double key, float toBeAdded) { synchronized (this.lock) { return this.map.addToValue(key, toBeAdded); } } @Override public float[] toSortedArray() { synchronized (this.lock) { return this.map.toSortedArray(); } } @Override public MutableFloatList toSortedList() { synchronized (this.lock) { return this.map.toSortedList(); } } @Override public float[] toArray() { synchronized (this.lock) { return this.map.toArray(); } } @Override public boolean contains(float value) { synchronized (this.lock) { return this.map.contains(value); } } @Override public boolean containsAll(float... source) { synchronized (this.lock) { return this.map.containsAll(source); } } @Override public boolean containsAll(FloatIterable source) { synchronized (this.lock) { return this.map.containsAll(source); } } @Override public MutableFloatList toList() { synchronized (this.lock) { return this.map.toList(); } } @Override public MutableFloatSet toSet() { synchronized (this.lock) { return this.map.toSet(); } } @Override public MutableFloatBag toBag() { synchronized (this.lock) { return this.map.toBag(); } } @Override public LazyFloatIterable asLazy() { synchronized (this.lock) { return this.map.asLazy(); } } @Override public MutableDoubleFloatMap withKeyValue(double key, float value) { synchronized (this.lock) { this.map.withKeyValue(key, value); } return this; } @Override public MutableDoubleFloatMap withoutKey(double key) { synchronized (this.lock) { this.map.withoutKey(key); } return this; } @Override public MutableDoubleFloatMap withoutAllKeys(DoubleIterable keys) { synchronized (this.lock) { this.map.withoutAllKeys(keys); } return this; } @Override public MutableDoubleFloatMap asUnmodifiable() { synchronized (this.lock) { return new UnmodifiableDoubleFloatMap(this); } } @Override public MutableDoubleFloatMap asSynchronized() { return this; } @Override public ImmutableDoubleFloatMap toImmutable() { synchronized (this.lock) { return DoubleFloatMaps.immutable.withAll(this); } } @Override public int size() { synchronized (this.lock) { return this.map.size(); } } @Override public boolean isEmpty() { synchronized (this.lock) { return this.map.isEmpty(); } } @Override public boolean notEmpty() { synchronized (this.lock) { return this.map.notEmpty(); } } @Override public MutableDoubleSet keySet() { synchronized (this.lock) { return SynchronizedDoubleSet.of(this.map.keySet(), this.lock); } } @Override public MutableFloatCollection values() { synchronized (this.lock) { return SynchronizedFloatCollection.of(this.map.values(), this.lock); } } @Override public boolean equals(Object otherMap) { synchronized (this.lock) { return this.map.equals(otherMap); } } @Override public int hashCode() { synchronized (this.lock) { return this.map.hashCode(); } } @Override public String toString() { synchronized (this.lock) { return this.map.toString(); } } @Override public String makeString() { synchronized (this.lock) { return this.map.makeString(); } } @Override public String makeString(String separator) { synchronized (this.lock) { return this.map.makeString(separator); } } @Override public String makeString(String start, String separator, String end) { synchronized (this.lock) { return this.map.makeString(start, separator, end); } } @Override public void appendString(Appendable appendable) { synchronized (this.lock) { this.map.appendString(appendable); } } @Override public void appendString(Appendable appendable, String separator) { synchronized (this.lock) { this.map.appendString(appendable, separator); } } @Override public void appendString(Appendable appendable, String start, String separator, String end) { synchronized (this.lock) { this.map.appendString(appendable, start, separator, end); } } @Override public <T> T injectInto(T injectedValue, ObjectFloatToObjectFunction<? super T, ? extends T> function) { synchronized (this.lock) { return this.map.injectInto(injectedValue, function); } } @Override public RichIterable<FloatIterable> chunk(int size) { synchronized (this.lock) { return this.map.chunk(size); } } }