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This artifact provides a single jar that contains all classes required to use remote EJB and JMS, including all dependencies. It is intended for use by those not using maven, maven users should just import the EJB and JMS BOM's instead (shaded JAR's cause lots of problems with maven, as it is very easy to inadvertently end up with different versions on classes on the class path).

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/*
 * Copyright (C) 2007 The Guava Authors
 *
 * 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 com.google.common.collect;

import static com.google.common.base.Preconditions.checkArgument;
import static com.google.common.base.Preconditions.checkNotNull;
import static com.google.common.collect.CollectPreconditions.checkNonnegative;

import com.google.common.annotations.GwtCompatible;
import com.google.common.annotations.GwtIncompatible;
import com.google.common.annotations.J2ktIncompatible;
import com.google.common.base.Predicate;
import com.google.common.base.Predicates;
import com.google.common.collect.Collections2.FilteredCollection;
import com.google.common.math.IntMath;
import com.google.errorprone.annotations.CanIgnoreReturnValue;
import com.google.errorprone.annotations.DoNotCall;
import com.google.errorprone.annotations.concurrent.LazyInit;
import java.io.Serializable;
import java.util.AbstractSet;
import java.util.Arrays;
import java.util.BitSet;
import java.util.Collection;
import java.util.Collections;
import java.util.Comparator;
import java.util.EnumSet;
import java.util.HashSet;
import java.util.Iterator;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.NavigableSet;
import java.util.NoSuchElementException;
import java.util.Set;
import java.util.SortedSet;
import java.util.TreeSet;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.CopyOnWriteArraySet;
import java.util.function.Consumer;
import java.util.stream.Collector;
import java.util.stream.Stream;
import javax.annotation.CheckForNull;
import org.checkerframework.checker.nullness.qual.NonNull;
import org.checkerframework.checker.nullness.qual.Nullable;

/**
 * Static utility methods pertaining to {@link Set} instances. Also see this class's counterparts
 * {@link Lists}, {@link Maps} and {@link Queues}.
 *
 * 

See the Guava User Guide article on {@code Sets}. * * @author Kevin Bourrillion * @author Jared Levy * @author Chris Povirk * @since 2.0 */ @GwtCompatible(emulated = true) @ElementTypesAreNonnullByDefault public final class Sets { private Sets() {} /** * {@link AbstractSet} substitute without the potentially-quadratic {@code removeAll} * implementation. */ abstract static class ImprovedAbstractSet extends AbstractSet { @Override public boolean removeAll(Collection c) { return removeAllImpl(this, c); } @Override public boolean retainAll(Collection c) { return super.retainAll(checkNotNull(c)); // GWT compatibility } } /** * Returns an immutable set instance containing the given enum elements. Internally, the returned * set will be backed by an {@link EnumSet}. * *

The iteration order of the returned set follows the enum's iteration order, not the order in * which the elements are provided to the method. * * @param anElement one of the elements the set should contain * @param otherElements the rest of the elements the set should contain * @return an immutable set containing those elements, minus duplicates */ // http://code.google.com/p/google-web-toolkit/issues/detail?id=3028 @GwtCompatible(serializable = true) public static > ImmutableSet immutableEnumSet( E anElement, E... otherElements) { return ImmutableEnumSet.asImmutable(EnumSet.of(anElement, otherElements)); } /** * Returns an immutable set instance containing the given enum elements. Internally, the returned * set will be backed by an {@link EnumSet}. * *

The iteration order of the returned set follows the enum's iteration order, not the order in * which the elements appear in the given collection. * * @param elements the elements, all of the same {@code enum} type, that the set should contain * @return an immutable set containing those elements, minus duplicates */ // http://code.google.com/p/google-web-toolkit/issues/detail?id=3028 @GwtCompatible(serializable = true) public static > ImmutableSet immutableEnumSet(Iterable elements) { if (elements instanceof ImmutableEnumSet) { return (ImmutableEnumSet) elements; } else if (elements instanceof Collection) { Collection collection = (Collection) elements; if (collection.isEmpty()) { return ImmutableSet.of(); } else { return ImmutableEnumSet.asImmutable(EnumSet.copyOf(collection)); } } else { Iterator itr = elements.iterator(); if (itr.hasNext()) { EnumSet enumSet = EnumSet.of(itr.next()); Iterators.addAll(enumSet, itr); return ImmutableEnumSet.asImmutable(enumSet); } else { return ImmutableSet.of(); } } } /** * Returns a {@code Collector} that accumulates the input elements into a new {@code ImmutableSet} * with an implementation specialized for enums. Unlike {@link ImmutableSet#toImmutableSet}, the * resulting set will iterate over elements in their enum definition order, not encounter order. * * @since 21.0 */ public static > Collector> toImmutableEnumSet() { return CollectCollectors.toImmutableEnumSet(); } /** * Returns a new, mutable {@code EnumSet} instance containing the given elements in their * natural order. This method behaves identically to {@link EnumSet#copyOf(Collection)}, but also * accepts non-{@code Collection} iterables and empty iterables. */ public static > EnumSet newEnumSet( Iterable iterable, Class elementType) { EnumSet set = EnumSet.noneOf(elementType); Iterables.addAll(set, iterable); return set; } // HashSet /** * Creates a mutable, initially empty {@code HashSet} instance. * *

Note: if mutability is not required, use {@link ImmutableSet#of()} instead. If {@code * E} is an {@link Enum} type, use {@link EnumSet#noneOf} instead. Otherwise, strongly consider * using a {@code LinkedHashSet} instead, at the cost of increased memory footprint, to get * deterministic iteration behavior. * *

Note: this method is now unnecessary and should be treated as deprecated. Instead, * use the {@code HashSet} constructor directly, taking advantage of "diamond" syntax. */ public static HashSet newHashSet() { return new HashSet(); } /** * Creates a mutable {@code HashSet} instance initially containing the given elements. * *

Note: if elements are non-null and won't be added or removed after this point, use * {@link ImmutableSet#of()} or {@link ImmutableSet#copyOf(Object[])} instead. If {@code E} is an * {@link Enum} type, use {@link EnumSet#of(Enum, Enum[])} instead. Otherwise, strongly consider * using a {@code LinkedHashSet} instead, at the cost of increased memory footprint, to get * deterministic iteration behavior. * *

This method is just a small convenience, either for {@code newHashSet(}{@link Arrays#asList * asList}{@code (...))}, or for creating an empty set then calling {@link Collections#addAll}. * This method is not actually very useful and will likely be deprecated in the future. */ public static HashSet newHashSet(E... elements) { HashSet set = newHashSetWithExpectedSize(elements.length); Collections.addAll(set, elements); return set; } /** * Creates a mutable {@code HashSet} instance containing the given elements. A very thin * convenience for creating an empty set then calling {@link Collection#addAll} or {@link * Iterables#addAll}. * *

Note: if mutability is not required and the elements are non-null, use {@link * ImmutableSet#copyOf(Iterable)} instead. (Or, change {@code elements} to be a {@link * FluentIterable} and call {@code elements.toSet()}.) * *

Note: if {@code E} is an {@link Enum} type, use {@link #newEnumSet(Iterable, Class)} * instead. * *

Note: if {@code elements} is a {@link Collection}, you don't need this method. * Instead, use the {@code HashSet} constructor directly, taking advantage of "diamond" syntax. * *

Overall, this method is not very useful and will likely be deprecated in the future. */ public static HashSet newHashSet(Iterable elements) { return (elements instanceof Collection) ? new HashSet((Collection) elements) : newHashSet(elements.iterator()); } /** * Creates a mutable {@code HashSet} instance containing the given elements. A very thin * convenience for creating an empty set and then calling {@link Iterators#addAll}. * *

Note: if mutability is not required and the elements are non-null, use {@link * ImmutableSet#copyOf(Iterator)} instead. * *

Note: if {@code E} is an {@link Enum} type, you should create an {@link EnumSet} * instead. * *

Overall, this method is not very useful and will likely be deprecated in the future. */ public static HashSet newHashSet(Iterator elements) { HashSet set = newHashSet(); Iterators.addAll(set, elements); return set; } /** * Returns a new hash set using the smallest initial table size that can hold {@code expectedSize} * elements without resizing. Note that this is not what {@link HashSet#HashSet(int)} does, but it * is what most users want and expect it to do. * *

This behavior can't be broadly guaranteed, but has been tested with OpenJDK 1.7 and 1.8. * * @param expectedSize the number of elements you expect to add to the returned set * @return a new, empty hash set with enough capacity to hold {@code expectedSize} elements * without resizing * @throws IllegalArgumentException if {@code expectedSize} is negative */ public static HashSet newHashSetWithExpectedSize( int expectedSize) { return new HashSet(Maps.capacity(expectedSize)); } /** * Creates a thread-safe set backed by a hash map. The set is backed by a {@link * ConcurrentHashMap} instance, and thus carries the same concurrency guarantees. * *

Unlike {@code HashSet}, this class does NOT allow {@code null} to be used as an element. The * set is serializable. * * @return a new, empty thread-safe {@code Set} * @since 15.0 */ public static Set newConcurrentHashSet() { return Platform.newConcurrentHashSet(); } /** * Creates a thread-safe set backed by a hash map and containing the given elements. The set is * backed by a {@link ConcurrentHashMap} instance, and thus carries the same concurrency * guarantees. * *

Unlike {@code HashSet}, this class does NOT allow {@code null} to be used as an element. The * set is serializable. * * @param elements the elements that the set should contain * @return a new thread-safe set containing those elements (minus duplicates) * @throws NullPointerException if {@code elements} or any of its contents is null * @since 15.0 */ public static Set newConcurrentHashSet(Iterable elements) { Set set = newConcurrentHashSet(); Iterables.addAll(set, elements); return set; } // LinkedHashSet /** * Creates a mutable, empty {@code LinkedHashSet} instance. * *

Note: if mutability is not required, use {@link ImmutableSet#of()} instead. * *

Note: this method is now unnecessary and should be treated as deprecated. Instead, * use the {@code LinkedHashSet} constructor directly, taking advantage of "diamond" syntax. * * @return a new, empty {@code LinkedHashSet} */ public static LinkedHashSet newLinkedHashSet() { return new LinkedHashSet(); } /** * Creates a mutable {@code LinkedHashSet} instance containing the given elements in order. * *

Note: if mutability is not required and the elements are non-null, use {@link * ImmutableSet#copyOf(Iterable)} instead. * *

Note: if {@code elements} is a {@link Collection}, you don't need this method. * Instead, use the {@code LinkedHashSet} constructor directly, taking advantage of "diamond" syntax. * *

Overall, this method is not very useful and will likely be deprecated in the future. * * @param elements the elements that the set should contain, in order * @return a new {@code LinkedHashSet} containing those elements (minus duplicates) */ public static LinkedHashSet newLinkedHashSet( Iterable elements) { if (elements instanceof Collection) { return new LinkedHashSet((Collection) elements); } LinkedHashSet set = newLinkedHashSet(); Iterables.addAll(set, elements); return set; } /** * Creates a {@code LinkedHashSet} instance, with a high enough "initial capacity" that it * should hold {@code expectedSize} elements without growth. This behavior cannot be * broadly guaranteed, but it is observed to be true for OpenJDK 1.7. It also can't be guaranteed * that the method isn't inadvertently oversizing the returned set. * * @param expectedSize the number of elements you expect to add to the returned set * @return a new, empty {@code LinkedHashSet} with enough capacity to hold {@code expectedSize} * elements without resizing * @throws IllegalArgumentException if {@code expectedSize} is negative * @since 11.0 */ public static LinkedHashSet newLinkedHashSetWithExpectedSize( int expectedSize) { return new LinkedHashSet(Maps.capacity(expectedSize)); } // TreeSet /** * Creates a mutable, empty {@code TreeSet} instance sorted by the natural sort ordering of * its elements. * *

Note: if mutability is not required, use {@link ImmutableSortedSet#of()} instead. * *

Note: this method is now unnecessary and should be treated as deprecated. Instead, * use the {@code TreeSet} constructor directly, taking advantage of "diamond" syntax. * * @return a new, empty {@code TreeSet} */ public static TreeSet newTreeSet() { return new TreeSet(); } /** * Creates a mutable {@code TreeSet} instance containing the given elements sorted by their * natural ordering. * *

Note: if mutability is not required, use {@link ImmutableSortedSet#copyOf(Iterable)} * instead. * *

Note: If {@code elements} is a {@code SortedSet} with an explicit comparator, this * method has different behavior than {@link TreeSet#TreeSet(SortedSet)}, which returns a {@code * TreeSet} with that comparator. * *

Note: this method is now unnecessary and should be treated as deprecated. Instead, * use the {@code TreeSet} constructor directly, taking advantage of "diamond" syntax. * *

This method is just a small convenience for creating an empty set and then calling {@link * Iterables#addAll}. This method is not very useful and will likely be deprecated in the future. * * @param elements the elements that the set should contain * @return a new {@code TreeSet} containing those elements (minus duplicates) */ public static TreeSet newTreeSet(Iterable elements) { TreeSet set = newTreeSet(); Iterables.addAll(set, elements); return set; } /** * Creates a mutable, empty {@code TreeSet} instance with the given comparator. * *

Note: if mutability is not required, use {@code * ImmutableSortedSet.orderedBy(comparator).build()} instead. * *

Note: this method is now unnecessary and should be treated as deprecated. Instead, * use the {@code TreeSet} constructor directly, taking advantage of "diamond" syntax. One caveat to this is that the {@code TreeSet} * constructor uses a null {@code Comparator} to mean "natural ordering," whereas this factory * rejects null. Clean your code accordingly. * * @param comparator the comparator to use to sort the set * @return a new, empty {@code TreeSet} * @throws NullPointerException if {@code comparator} is null */ public static TreeSet newTreeSet( Comparator comparator) { return new TreeSet(checkNotNull(comparator)); } /** * Creates an empty {@code Set} that uses identity to determine equality. It compares object * references, instead of calling {@code equals}, to determine whether a provided object matches * an element in the set. For example, {@code contains} returns {@code false} when passed an * object that equals a set member, but isn't the same instance. This behavior is similar to the * way {@code IdentityHashMap} handles key lookups. * * @since 8.0 */ public static Set newIdentityHashSet() { return Collections.newSetFromMap(Maps.newIdentityHashMap()); } /** * Creates an empty {@code CopyOnWriteArraySet} instance. * *

Note: if you need an immutable empty {@link Set}, use {@link Collections#emptySet} * instead. * * @return a new, empty {@code CopyOnWriteArraySet} * @since 12.0 */ @J2ktIncompatible @GwtIncompatible // CopyOnWriteArraySet public static CopyOnWriteArraySet newCopyOnWriteArraySet() { return new CopyOnWriteArraySet(); } /** * Creates a {@code CopyOnWriteArraySet} instance containing the given elements. * * @param elements the elements that the set should contain, in order * @return a new {@code CopyOnWriteArraySet} containing those elements * @since 12.0 */ @J2ktIncompatible @GwtIncompatible // CopyOnWriteArraySet public static CopyOnWriteArraySet newCopyOnWriteArraySet( Iterable elements) { // We copy elements to an ArrayList first, rather than incurring the // quadratic cost of adding them to the COWAS directly. Collection elementsCollection = (elements instanceof Collection) ? (Collection) elements : Lists.newArrayList(elements); return new CopyOnWriteArraySet(elementsCollection); } /** * Creates an {@code EnumSet} consisting of all enum values that are not in the specified * collection. If the collection is an {@link EnumSet}, this method has the same behavior as * {@link EnumSet#complementOf}. Otherwise, the specified collection must contain at least one * element, in order to determine the element type. If the collection could be empty, use {@link * #complementOf(Collection, Class)} instead of this method. * * @param collection the collection whose complement should be stored in the enum set * @return a new, modifiable {@code EnumSet} containing all values of the enum that aren't present * in the given collection * @throws IllegalArgumentException if {@code collection} is not an {@code EnumSet} instance and * contains no elements */ @J2ktIncompatible @GwtIncompatible public static > EnumSet complementOf(Collection collection) { if (collection instanceof EnumSet) { return EnumSet.complementOf((EnumSet) collection); } checkArgument( !collection.isEmpty(), "collection is empty; use the other version of this method"); Class type = collection.iterator().next().getDeclaringClass(); return makeComplementByHand(collection, type); } /** * Creates an {@code EnumSet} consisting of all enum values that are not in the specified * collection. This is equivalent to {@link EnumSet#complementOf}, but can act on any input * collection, as long as the elements are of enum type. * * @param collection the collection whose complement should be stored in the {@code EnumSet} * @param type the type of the elements in the set * @return a new, modifiable {@code EnumSet} initially containing all the values of the enum not * present in the given collection */ @GwtIncompatible public static > EnumSet complementOf( Collection collection, Class type) { checkNotNull(collection); return (collection instanceof EnumSet) ? EnumSet.complementOf((EnumSet) collection) : makeComplementByHand(collection, type); } @GwtIncompatible private static > EnumSet makeComplementByHand( Collection collection, Class type) { EnumSet result = EnumSet.allOf(type); result.removeAll(collection); return result; } /** * Returns a set backed by the specified map. The resulting set displays the same ordering, * concurrency, and performance characteristics as the backing map. In essence, this factory * method provides a {@link Set} implementation corresponding to any {@link Map} implementation. * There is no need to use this method on a {@link Map} implementation that already has a * corresponding {@link Set} implementation (such as {@link java.util.HashMap} or {@link * java.util.TreeMap}). * *

Each method invocation on the set returned by this method results in exactly one method * invocation on the backing map or its {@code keySet} view, with one exception. The {@code * addAll} method is implemented as a sequence of {@code put} invocations on the backing map. * *

The specified map must be empty at the time this method is invoked, and should not be * accessed directly after this method returns. These conditions are ensured if the map is created * empty, passed directly to this method, and no reference to the map is retained, as illustrated * in the following code fragment: * *

{@code
   * Set identityHashSet = Sets.newSetFromMap(
   *     new IdentityHashMap());
   * }
   *
   * 

The returned set is serializable if the backing map is. * * @param map the backing map * @return the set backed by the map * @throws IllegalArgumentException if {@code map} is not empty * @deprecated Use {@link Collections#newSetFromMap} instead. */ @Deprecated public static Set newSetFromMap( Map map) { return Collections.newSetFromMap(map); } /** * An unmodifiable view of a set which may be backed by other sets; this view will change as the * backing sets do. Contains methods to copy the data into a new set which will then remain * stable. There is usually no reason to retain a reference of type {@code SetView}; typically, * you either use it as a plain {@link Set}, or immediately invoke {@link #immutableCopy} or * {@link #copyInto} and forget the {@code SetView} itself. * * @since 2.0 */ public abstract static class SetView extends AbstractSet { private SetView() {} // no subclasses but our own /** * Returns an immutable copy of the current contents of this set view. Does not support null * elements. * *

Warning: this may have unexpected results if a backing set of this view uses a * nonstandard notion of equivalence, for example if it is a {@link TreeSet} using a comparator * that is inconsistent with {@link Object#equals(Object)}. */ @SuppressWarnings("nullness") // Unsafe, but we can't fix it now. public ImmutableSet<@NonNull E> immutableCopy() { return ImmutableSet.copyOf((SetView<@NonNull E>) this); } /** * Copies the current contents of this set view into an existing set. This method has equivalent * behavior to {@code set.addAll(this)}, assuming that all the sets involved are based on the * same notion of equivalence. * * @return a reference to {@code set}, for convenience */ // Note: S should logically extend Set but can't due to either // some javac bug or some weirdness in the spec, not sure which. @CanIgnoreReturnValue public > S copyInto(S set) { set.addAll(this); return set; } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @CanIgnoreReturnValue @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final boolean add(@ParametricNullness E e) { throw new UnsupportedOperationException(); } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @CanIgnoreReturnValue @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final boolean remove(@CheckForNull Object object) { throw new UnsupportedOperationException(); } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @CanIgnoreReturnValue @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final boolean addAll(Collection newElements) { throw new UnsupportedOperationException(); } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @CanIgnoreReturnValue @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final boolean removeAll(Collection oldElements) { throw new UnsupportedOperationException(); } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @CanIgnoreReturnValue @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final boolean removeIf(java.util.function.Predicate filter) { throw new UnsupportedOperationException(); } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @CanIgnoreReturnValue @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final boolean retainAll(Collection elementsToKeep) { throw new UnsupportedOperationException(); } /** * Guaranteed to throw an exception and leave the collection unmodified. * * @throws UnsupportedOperationException always * @deprecated Unsupported operation. */ @Deprecated @Override @DoNotCall("Always throws UnsupportedOperationException") public final void clear() { throw new UnsupportedOperationException(); } /** * Scope the return type to {@link UnmodifiableIterator} to ensure this is an unmodifiable view. * * @since 20.0 (present with return type {@link Iterator} since 2.0) */ @Override public abstract UnmodifiableIterator iterator(); } /** * Returns an unmodifiable view of the union of two sets. The returned set contains all * elements that are contained in either backing set. Iterating over the returned set iterates * first over all the elements of {@code set1}, then over each element of {@code set2}, in order, * that is not contained in {@code set1}. * *

Results are undefined if {@code set1} and {@code set2} are sets based on different * equivalence relations, for example if {@code set1} is a {@link HashSet} and {@code set2} is a * {@link TreeSet} or the {@link Map#keySet} of an {@code IdentityHashMap}. */ public static SetView union( final Set set1, final Set set2) { checkNotNull(set1, "set1"); checkNotNull(set2, "set2"); return new SetView() { @Override public int size() { int size = set1.size(); for (E e : set2) { if (!set1.contains(e)) { size++; } } return size; } @Override public boolean isEmpty() { return set1.isEmpty() && set2.isEmpty(); } @Override public UnmodifiableIterator iterator() { return new AbstractIterator() { final Iterator itr1 = set1.iterator(); final Iterator itr2 = set2.iterator(); @Override @CheckForNull protected E computeNext() { if (itr1.hasNext()) { return itr1.next(); } while (itr2.hasNext()) { E e = itr2.next(); if (!set1.contains(e)) { return e; } } return endOfData(); } }; } @Override public Stream stream() { return Stream.concat(set1.stream(), set2.stream().filter((E e) -> !set1.contains(e))); } @Override public Stream parallelStream() { return stream().parallel(); } @Override public boolean contains(@CheckForNull Object object) { return set1.contains(object) || set2.contains(object); } @Override public > S copyInto(S set) { set.addAll(set1); set.addAll(set2); return set; } @Override @SuppressWarnings({"nullness", "unchecked"}) // see supertype public ImmutableSet<@NonNull E> immutableCopy() { ImmutableSet.Builder<@NonNull E> builder = new ImmutableSet.Builder<@NonNull E>() .addAll((Iterable<@NonNull E>) set1) .addAll((Iterable<@NonNull E>) set2); return (ImmutableSet<@NonNull E>) builder.build(); } }; } /** * Returns an unmodifiable view of the intersection of two sets. The returned set contains * all elements that are contained by both backing sets. The iteration order of the returned set * matches that of {@code set1}. * *

Results are undefined if {@code set1} and {@code set2} are sets based on different * equivalence relations, for example if {@code set1} is a {@link HashSet} and {@code set2} is a * {@link TreeSet} or the {@link Map#keySet} of an {@code IdentityHashMap}. * *

Note: The returned view performs slightly better when {@code set1} is the smaller of * the two sets. If you have reason to believe one of your sets will generally be smaller than the * other, pass it first. Unfortunately, since this method sets the generic type of the returned * set based on the type of the first set passed, this could in rare cases force you to make a * cast, for example: * *

{@code
   * Set aFewBadObjects = ...
   * Set manyBadStrings = ...
   *
   * // impossible for a non-String to be in the intersection
   * SuppressWarnings("unchecked")
   * Set badStrings = (Set) Sets.intersection(
   *     aFewBadObjects, manyBadStrings);
   * }
   *
   * 

This is unfortunate, but should come up only very rarely. */ public static SetView intersection( final Set set1, final Set set2) { checkNotNull(set1, "set1"); checkNotNull(set2, "set2"); return new SetView() { @Override public UnmodifiableIterator iterator() { return new AbstractIterator() { final Iterator itr = set1.iterator(); @Override @CheckForNull protected E computeNext() { while (itr.hasNext()) { E e = itr.next(); if (set2.contains(e)) { return e; } } return endOfData(); } }; } @Override public Stream stream() { return set1.stream().filter(set2::contains); } @Override public Stream parallelStream() { return set1.parallelStream().filter(set2::contains); } @Override public int size() { int size = 0; for (E e : set1) { if (set2.contains(e)) { size++; } } return size; } @Override public boolean isEmpty() { return Collections.disjoint(set2, set1); } @Override public boolean contains(@CheckForNull Object object) { return set1.contains(object) && set2.contains(object); } @Override public boolean containsAll(Collection collection) { return set1.containsAll(collection) && set2.containsAll(collection); } }; } /** * Returns an unmodifiable view of the difference of two sets. The returned set contains * all elements that are contained by {@code set1} and not contained by {@code set2}. {@code set2} * may also contain elements not present in {@code set1}; these are simply ignored. The iteration * order of the returned set matches that of {@code set1}. * *

Results are undefined if {@code set1} and {@code set2} are sets based on different * equivalence relations, for example if {@code set1} is a {@link HashSet} and {@code set2} is a * {@link TreeSet} or the {@link Map#keySet} of an {@code IdentityHashMap}. */ public static SetView difference( final Set set1, final Set set2) { checkNotNull(set1, "set1"); checkNotNull(set2, "set2"); return new SetView() { @Override public UnmodifiableIterator iterator() { return new AbstractIterator() { final Iterator itr = set1.iterator(); @Override @CheckForNull protected E computeNext() { while (itr.hasNext()) { E e = itr.next(); if (!set2.contains(e)) { return e; } } return endOfData(); } }; } @Override public Stream stream() { return set1.stream().filter(e -> !set2.contains(e)); } @Override public Stream parallelStream() { return set1.parallelStream().filter(e -> !set2.contains(e)); } @Override public int size() { int size = 0; for (E e : set1) { if (!set2.contains(e)) { size++; } } return size; } @Override public boolean isEmpty() { return set2.containsAll(set1); } @Override public boolean contains(@CheckForNull Object element) { return set1.contains(element) && !set2.contains(element); } }; } /** * Returns an unmodifiable view of the symmetric difference of two sets. The returned set * contains all elements that are contained in either {@code set1} or {@code set2} but not in * both. The iteration order of the returned set is undefined. * *

Results are undefined if {@code set1} and {@code set2} are sets based on different * equivalence relations, for example if {@code set1} is a {@link HashSet} and {@code set2} is a * {@link TreeSet} or the {@link Map#keySet} of an {@code IdentityHashMap}. * * @since 3.0 */ public static SetView symmetricDifference( final Set set1, final Set set2) { checkNotNull(set1, "set1"); checkNotNull(set2, "set2"); return new SetView() { @Override public UnmodifiableIterator iterator() { final Iterator itr1 = set1.iterator(); final Iterator itr2 = set2.iterator(); return new AbstractIterator() { @Override @CheckForNull public E computeNext() { while (itr1.hasNext()) { E elem1 = itr1.next(); if (!set2.contains(elem1)) { return elem1; } } while (itr2.hasNext()) { E elem2 = itr2.next(); if (!set1.contains(elem2)) { return elem2; } } return endOfData(); } }; } @Override public int size() { int size = 0; for (E e : set1) { if (!set2.contains(e)) { size++; } } for (E e : set2) { if (!set1.contains(e)) { size++; } } return size; } @Override public boolean isEmpty() { return set1.equals(set2); } @Override public boolean contains(@CheckForNull Object element) { return set1.contains(element) ^ set2.contains(element); } }; } /** * Returns the elements of {@code unfiltered} that satisfy a predicate. The returned set is a live * view of {@code unfiltered}; changes to one affect the other. * *

The resulting set's iterator does not support {@code remove()}, but all other set methods * are supported. When given an element that doesn't satisfy the predicate, the set's {@code * add()} and {@code addAll()} methods throw an {@link IllegalArgumentException}. When methods * such as {@code removeAll()} and {@code clear()} are called on the filtered set, only elements * that satisfy the filter will be removed from the underlying set. * *

The returned set isn't threadsafe or serializable, even if {@code unfiltered} is. * *

Many of the filtered set's methods, such as {@code size()}, iterate across every element in * the underlying set and determine which elements satisfy the filter. When a live view is * not needed, it may be faster to copy {@code Iterables.filter(unfiltered, predicate)} and * use the copy. * *

Warning: {@code predicate} must be consistent with equals, as documented at * {@link Predicate#apply}. Do not provide a predicate such as {@code * Predicates.instanceOf(ArrayList.class)}, which is inconsistent with equals. (See {@link * Iterables#filter(Iterable, Class)} for related functionality.) * *

Java 8 users: many use cases for this method are better addressed by {@link * java.util.stream.Stream#filter}. This method is not being deprecated, but we gently encourage * you to migrate to streams. */ // TODO(kevinb): how to omit that last sentence when building GWT javadoc? public static Set filter( Set unfiltered, Predicate predicate) { if (unfiltered instanceof SortedSet) { return filter((SortedSet) unfiltered, predicate); } if (unfiltered instanceof FilteredSet) { // Support clear(), removeAll(), and retainAll() when filtering a filtered // collection. FilteredSet filtered = (FilteredSet) unfiltered; Predicate combinedPredicate = Predicates.and(filtered.predicate, predicate); return new FilteredSet((Set) filtered.unfiltered, combinedPredicate); } return new FilteredSet(checkNotNull(unfiltered), checkNotNull(predicate)); } /** * Returns the elements of a {@code SortedSet}, {@code unfiltered}, that satisfy a predicate. The * returned set is a live view of {@code unfiltered}; changes to one affect the other. * *

The resulting set's iterator does not support {@code remove()}, but all other set methods * are supported. When given an element that doesn't satisfy the predicate, the set's {@code * add()} and {@code addAll()} methods throw an {@link IllegalArgumentException}. When methods * such as {@code removeAll()} and {@code clear()} are called on the filtered set, only elements * that satisfy the filter will be removed from the underlying set. * *

The returned set isn't threadsafe or serializable, even if {@code unfiltered} is. * *

Many of the filtered set's methods, such as {@code size()}, iterate across every element in * the underlying set and determine which elements satisfy the filter. When a live view is * not needed, it may be faster to copy {@code Iterables.filter(unfiltered, predicate)} and * use the copy. * *

Warning: {@code predicate} must be consistent with equals, as documented at * {@link Predicate#apply}. Do not provide a predicate such as {@code * Predicates.instanceOf(ArrayList.class)}, which is inconsistent with equals. (See {@link * Iterables#filter(Iterable, Class)} for related functionality.) * * @since 11.0 */ public static SortedSet filter( SortedSet unfiltered, Predicate predicate) { if (unfiltered instanceof FilteredSet) { // Support clear(), removeAll(), and retainAll() when filtering a filtered // collection. FilteredSet filtered = (FilteredSet) unfiltered; Predicate combinedPredicate = Predicates.and(filtered.predicate, predicate); return new FilteredSortedSet((SortedSet) filtered.unfiltered, combinedPredicate); } return new FilteredSortedSet(checkNotNull(unfiltered), checkNotNull(predicate)); } /** * Returns the elements of a {@code NavigableSet}, {@code unfiltered}, that satisfy a predicate. * The returned set is a live view of {@code unfiltered}; changes to one affect the other. * *

The resulting set's iterator does not support {@code remove()}, but all other set methods * are supported. When given an element that doesn't satisfy the predicate, the set's {@code * add()} and {@code addAll()} methods throw an {@link IllegalArgumentException}. When methods * such as {@code removeAll()} and {@code clear()} are called on the filtered set, only elements * that satisfy the filter will be removed from the underlying set. * *

The returned set isn't threadsafe or serializable, even if {@code unfiltered} is. * *

Many of the filtered set's methods, such as {@code size()}, iterate across every element in * the underlying set and determine which elements satisfy the filter. When a live view is * not needed, it may be faster to copy {@code Iterables.filter(unfiltered, predicate)} and * use the copy. * *

Warning: {@code predicate} must be consistent with equals, as documented at * {@link Predicate#apply}. Do not provide a predicate such as {@code * Predicates.instanceOf(ArrayList.class)}, which is inconsistent with equals. (See {@link * Iterables#filter(Iterable, Class)} for related functionality.) * * @since 14.0 */ @GwtIncompatible // NavigableSet @SuppressWarnings("unchecked") public static NavigableSet filter( NavigableSet unfiltered, Predicate predicate) { if (unfiltered instanceof FilteredSet) { // Support clear(), removeAll(), and retainAll() when filtering a filtered // collection. FilteredSet filtered = (FilteredSet) unfiltered; Predicate combinedPredicate = Predicates.and(filtered.predicate, predicate); return new FilteredNavigableSet((NavigableSet) filtered.unfiltered, combinedPredicate); } return new FilteredNavigableSet(checkNotNull(unfiltered), checkNotNull(predicate)); } private static class FilteredSet extends FilteredCollection implements Set { FilteredSet(Set unfiltered, Predicate predicate) { super(unfiltered, predicate); } @Override public boolean equals(@CheckForNull Object object) { return equalsImpl(this, object); } @Override public int hashCode() { return hashCodeImpl(this); } } private static class FilteredSortedSet extends FilteredSet implements SortedSet { FilteredSortedSet(SortedSet unfiltered, Predicate predicate) { super(unfiltered, predicate); } @Override @CheckForNull public Comparator comparator() { return ((SortedSet) unfiltered).comparator(); } @Override public SortedSet subSet(@ParametricNullness E fromElement, @ParametricNullness E toElement) { return new FilteredSortedSet( ((SortedSet) unfiltered).subSet(fromElement, toElement), predicate); } @Override public SortedSet headSet(@ParametricNullness E toElement) { return new FilteredSortedSet(((SortedSet) unfiltered).headSet(toElement), predicate); } @Override public SortedSet tailSet(@ParametricNullness E fromElement) { return new FilteredSortedSet(((SortedSet) unfiltered).tailSet(fromElement), predicate); } @Override @ParametricNullness public E first() { return Iterators.find(unfiltered.iterator(), predicate); } @Override @ParametricNullness public E last() { SortedSet sortedUnfiltered = (SortedSet) unfiltered; while (true) { E element = sortedUnfiltered.last(); if (predicate.apply(element)) { return element; } sortedUnfiltered = sortedUnfiltered.headSet(element); } } } @GwtIncompatible // NavigableSet private static class FilteredNavigableSet extends FilteredSortedSet implements NavigableSet { FilteredNavigableSet(NavigableSet unfiltered, Predicate predicate) { super(unfiltered, predicate); } NavigableSet unfiltered() { return (NavigableSet) unfiltered; } @Override @CheckForNull public E lower(@ParametricNullness E e) { return Iterators.find(unfiltered().headSet(e, false).descendingIterator(), predicate, null); } @Override @CheckForNull public E floor(@ParametricNullness E e) { return Iterators.find(unfiltered().headSet(e, true).descendingIterator(), predicate, null); } @Override @CheckForNull public E ceiling(@ParametricNullness E e) { return Iterables.find(unfiltered().tailSet(e, true), predicate, null); } @Override @CheckForNull public E higher(@ParametricNullness E e) { return Iterables.find(unfiltered().tailSet(e, false), predicate, null); } @Override @CheckForNull public E pollFirst() { return Iterables.removeFirstMatching(unfiltered(), predicate); } @Override @CheckForNull public E pollLast() { return Iterables.removeFirstMatching(unfiltered().descendingSet(), predicate); } @Override public NavigableSet descendingSet() { return Sets.filter(unfiltered().descendingSet(), predicate); } @Override public Iterator descendingIterator() { return Iterators.filter(unfiltered().descendingIterator(), predicate); } @Override @ParametricNullness public E last() { return Iterators.find(unfiltered().descendingIterator(), predicate); } @Override public NavigableSet subSet( @ParametricNullness E fromElement, boolean fromInclusive, @ParametricNullness E toElement, boolean toInclusive) { return filter( unfiltered().subSet(fromElement, fromInclusive, toElement, toInclusive), predicate); } @Override public NavigableSet headSet(@ParametricNullness E toElement, boolean inclusive) { return filter(unfiltered().headSet(toElement, inclusive), predicate); } @Override public NavigableSet tailSet(@ParametricNullness E fromElement, boolean inclusive) { return filter(unfiltered().tailSet(fromElement, inclusive), predicate); } } /** * Returns every possible list that can be formed by choosing one element from each of the given * sets in order; the "n-ary Cartesian * product" of the sets. For example: * *

{@code
   * Sets.cartesianProduct(ImmutableList.of(
   *     ImmutableSet.of(1, 2),
   *     ImmutableSet.of("A", "B", "C")))
   * }
* *

returns a set containing six lists: * *

    *
  • {@code ImmutableList.of(1, "A")} *
  • {@code ImmutableList.of(1, "B")} *
  • {@code ImmutableList.of(1, "C")} *
  • {@code ImmutableList.of(2, "A")} *
  • {@code ImmutableList.of(2, "B")} *
  • {@code ImmutableList.of(2, "C")} *
* *

The result is guaranteed to be in the "traditional", lexicographical order for Cartesian * products that you would get from nesting for loops: * *

{@code
   * for (B b0 : sets.get(0)) {
   *   for (B b1 : sets.get(1)) {
   *     ...
   *     ImmutableList tuple = ImmutableList.of(b0, b1, ...);
   *     // operate on tuple
   *   }
   * }
   * }
* *

Note that if any input set is empty, the Cartesian product will also be empty. If no sets at * all are provided (an empty list), the resulting Cartesian product has one element, an empty * list (counter-intuitive, but mathematically consistent). * *

Performance notes: while the cartesian product of sets of size {@code m, n, p} is a * set of size {@code m x n x p}, its actual memory consumption is much smaller. When the * cartesian set is constructed, the input sets are merely copied. Only as the resulting set is * iterated are the individual lists created, and these are not retained after iteration. * * @param sets the sets to choose elements from, in the order that the elements chosen from those * sets should appear in the resulting lists * @param any common base class shared by all axes (often just {@link Object}) * @return the Cartesian product, as an immutable set containing immutable lists * @throws NullPointerException if {@code sets}, any one of the {@code sets}, or any element of a * provided set is null * @throws IllegalArgumentException if the cartesian product size exceeds the {@code int} range * @since 2.0 */ public static Set> cartesianProduct(List> sets) { return CartesianSet.create(sets); } /** * Returns every possible list that can be formed by choosing one element from each of the given * sets in order; the "n-ary Cartesian * product" of the sets. For example: * *

{@code
   * Sets.cartesianProduct(
   *     ImmutableSet.of(1, 2),
   *     ImmutableSet.of("A", "B", "C"))
   * }
* *

returns a set containing six lists: * *

    *
  • {@code ImmutableList.of(1, "A")} *
  • {@code ImmutableList.of(1, "B")} *
  • {@code ImmutableList.of(1, "C")} *
  • {@code ImmutableList.of(2, "A")} *
  • {@code ImmutableList.of(2, "B")} *
  • {@code ImmutableList.of(2, "C")} *
* *

The result is guaranteed to be in the "traditional", lexicographical order for Cartesian * products that you would get from nesting for loops: * *

{@code
   * for (B b0 : sets.get(0)) {
   *   for (B b1 : sets.get(1)) {
   *     ...
   *     ImmutableList tuple = ImmutableList.of(b0, b1, ...);
   *     // operate on tuple
   *   }
   * }
   * }
* *

Note that if any input set is empty, the Cartesian product will also be empty. If no sets at * all are provided (an empty list), the resulting Cartesian product has one element, an empty * list (counter-intuitive, but mathematically consistent). * *

Performance notes: while the cartesian product of sets of size {@code m, n, p} is a * set of size {@code m x n x p}, its actual memory consumption is much smaller. When the * cartesian set is constructed, the input sets are merely copied. Only as the resulting set is * iterated are the individual lists created, and these are not retained after iteration. * * @param sets the sets to choose elements from, in the order that the elements chosen from those * sets should appear in the resulting lists * @param any common base class shared by all axes (often just {@link Object}) * @return the Cartesian product, as an immutable set containing immutable lists * @throws NullPointerException if {@code sets}, any one of the {@code sets}, or any element of a * provided set is null * @throws IllegalArgumentException if the cartesian product size exceeds the {@code int} range * @since 2.0 */ @SafeVarargs public static Set> cartesianProduct(Set... sets) { return cartesianProduct(Arrays.asList(sets)); } private static final class CartesianSet extends ForwardingCollection> implements Set> { private final transient ImmutableList> axes; private final transient CartesianList delegate; static Set> create(List> sets) { ImmutableList.Builder> axesBuilder = new ImmutableList.Builder<>(sets.size()); for (Set set : sets) { ImmutableSet copy = ImmutableSet.copyOf(set); if (copy.isEmpty()) { return ImmutableSet.of(); } axesBuilder.add(copy); } final ImmutableList> axes = axesBuilder.build(); ImmutableList> listAxes = new ImmutableList>() { @Override public int size() { return axes.size(); } @Override public List get(int index) { return axes.get(index).asList(); } @Override boolean isPartialView() { return true; } // redeclare to help optimizers with b/310253115 @SuppressWarnings("RedundantOverride") @Override @J2ktIncompatible // serialization @GwtIncompatible // serialization Object writeReplace() { return super.writeReplace(); } }; return new CartesianSet(axes, new CartesianList(listAxes)); } private CartesianSet(ImmutableList> axes, CartesianList delegate) { this.axes = axes; this.delegate = delegate; } @Override protected Collection> delegate() { return delegate; } @Override public boolean contains(@CheckForNull Object object) { if (!(object instanceof List)) { return false; } List list = (List) object; if (list.size() != axes.size()) { return false; } int i = 0; for (Object o : list) { if (!axes.get(i).contains(o)) { return false; } i++; } return true; } @Override public boolean equals(@CheckForNull Object object) { // Warning: this is broken if size() == 0, so it is critical that we // substitute an empty ImmutableSet to the user in place of this if (object instanceof CartesianSet) { CartesianSet that = (CartesianSet) object; return this.axes.equals(that.axes); } if (object instanceof Set) { Set that = (Set) object; return this.size() == that.size() && this.containsAll(that); } return false; } @Override public int hashCode() { // Warning: this is broken if size() == 0, so it is critical that we // substitute an empty ImmutableSet to the user in place of this // It's a weird formula, but tests prove it works. int adjust = size() - 1; for (int i = 0; i < axes.size(); i++) { adjust *= 31; adjust = ~~adjust; // in GWT, we have to deal with integer overflow carefully } int hash = 1; for (Set axis : axes) { hash = 31 * hash + (size() / axis.size() * axis.hashCode()); hash = ~~hash; } hash += adjust; return ~~hash; } } /** * Returns the set of all possible subsets of {@code set}. For example, {@code * powerSet(ImmutableSet.of(1, 2))} returns the set {@code {{}, {1}, {2}, {1, 2}}}. * *

Elements appear in these subsets in the same iteration order as they appeared in the input * set. The order in which these subsets appear in the outer set is undefined. Note that the power * set of the empty set is not the empty set, but a one-element set containing the empty set. * *

The returned set and its constituent sets use {@code equals} to decide whether two elements * are identical, even if the input set uses a different concept of equivalence. * *

Performance notes: while the power set of a set with size {@code n} is of size {@code * 2^n}, its memory usage is only {@code O(n)}. When the power set is constructed, the input set * is merely copied. Only as the power set is iterated are the individual subsets created, and * these subsets themselves occupy only a small constant amount of memory. * * @param set the set of elements to construct a power set from * @return the power set, as an immutable set of immutable sets * @throws IllegalArgumentException if {@code set} has more than 30 unique elements (causing the * power set size to exceed the {@code int} range) * @throws NullPointerException if {@code set} is or contains {@code null} * @see Power set article at Wikipedia * @since 4.0 */ @GwtCompatible(serializable = false) public static Set> powerSet(Set set) { return new PowerSet(set); } private static final class SubSet extends AbstractSet { private final ImmutableMap inputSet; private final int mask; SubSet(ImmutableMap inputSet, int mask) { this.inputSet = inputSet; this.mask = mask; } @Override public Iterator iterator() { return new UnmodifiableIterator() { final ImmutableList elements = inputSet.keySet().asList(); int remainingSetBits = mask; @Override public boolean hasNext() { return remainingSetBits != 0; } @Override public E next() { int index = Integer.numberOfTrailingZeros(remainingSetBits); if (index == 32) { throw new NoSuchElementException(); } remainingSetBits &= ~(1 << index); return elements.get(index); } }; } @Override public int size() { return Integer.bitCount(mask); } @Override public boolean contains(@CheckForNull Object o) { Integer index = inputSet.get(o); return index != null && (mask & (1 << index)) != 0; } } private static final class PowerSet extends AbstractSet> { final ImmutableMap inputSet; PowerSet(Set input) { checkArgument( input.size() <= 30, "Too many elements to create power set: %s > 30", input.size()); this.inputSet = Maps.indexMap(input); } @Override public int size() { return 1 << inputSet.size(); } @Override public boolean isEmpty() { return false; } @Override public Iterator> iterator() { return new AbstractIndexedListIterator>(size()) { @Override protected Set get(final int setBits) { return new SubSet(inputSet, setBits); } }; } @Override public boolean contains(@CheckForNull Object obj) { if (obj instanceof Set) { Set set = (Set) obj; return inputSet.keySet().containsAll(set); } return false; } @Override public boolean equals(@CheckForNull Object obj) { if (obj instanceof PowerSet) { PowerSet that = (PowerSet) obj; return inputSet.keySet().equals(that.inputSet.keySet()); } return super.equals(obj); } @Override public int hashCode() { /* * The sum of the sums of the hash codes in each subset is just the sum of * each input element's hash code times the number of sets that element * appears in. Each element appears in exactly half of the 2^n sets, so: */ return inputSet.keySet().hashCode() << (inputSet.size() - 1); } @Override public String toString() { return "powerSet(" + inputSet + ")"; } } /** * Returns the set of all subsets of {@code set} of size {@code size}. For example, {@code * combinations(ImmutableSet.of(1, 2, 3), 2)} returns the set {@code {{1, 2}, {1, 3}, {2, 3}}}. * *

Elements appear in these subsets in the same iteration order as they appeared in the input * set. The order in which these subsets appear in the outer set is undefined. * *

The returned set and its constituent sets use {@code equals} to decide whether two elements * are identical, even if the input set uses a different concept of equivalence. * *

Performance notes: the memory usage of the returned set is only {@code O(n)}. When * the result set is constructed, the input set is merely copied. Only as the result set is * iterated are the individual subsets created. Each of these subsets occupies an additional O(n) * memory but only for as long as the user retains a reference to it. That is, the set returned by * {@code combinations} does not retain the individual subsets. * * @param set the set of elements to take combinations of * @param size the number of elements per combination * @return the set of all combinations of {@code size} elements from {@code set} * @throws IllegalArgumentException if {@code size} is not between 0 and {@code set.size()} * inclusive * @throws NullPointerException if {@code set} is or contains {@code null} * @since 23.0 */ public static Set> combinations(Set set, final int size) { final ImmutableMap index = Maps.indexMap(set); checkNonnegative(size, "size"); checkArgument(size <= index.size(), "size (%s) must be <= set.size() (%s)", size, index.size()); if (size == 0) { return ImmutableSet.>of(ImmutableSet.of()); } else if (size == index.size()) { return ImmutableSet.>of(index.keySet()); } return new AbstractSet>() { @Override public boolean contains(@CheckForNull Object o) { if (o instanceof Set) { Set s = (Set) o; return s.size() == size && index.keySet().containsAll(s); } return false; } @Override public Iterator> iterator() { return new AbstractIterator>() { final BitSet bits = new BitSet(index.size()); @Override @CheckForNull protected Set computeNext() { if (bits.isEmpty()) { bits.set(0, size); } else { int firstSetBit = bits.nextSetBit(0); int bitToFlip = bits.nextClearBit(firstSetBit); if (bitToFlip == index.size()) { return endOfData(); } /* * The current set in sorted order looks like * {firstSetBit, firstSetBit + 1, ..., bitToFlip - 1, ...} * where it does *not* contain bitToFlip. * * The next combination is * * {0, 1, ..., bitToFlip - firstSetBit - 2, bitToFlip, ...} * * This is lexicographically next if you look at the combinations in descending order * e.g. {2, 1, 0}, {3, 1, 0}, {3, 2, 0}, {3, 2, 1}, {4, 1, 0}... */ bits.set(0, bitToFlip - firstSetBit - 1); bits.clear(bitToFlip - firstSetBit - 1, bitToFlip); bits.set(bitToFlip); } final BitSet copy = (BitSet) bits.clone(); return new AbstractSet() { @Override public boolean contains(@CheckForNull Object o) { Integer i = index.get(o); return i != null && copy.get(i); } @Override public Iterator iterator() { return new AbstractIterator() { int i = -1; @Override @CheckForNull protected E computeNext() { i = copy.nextSetBit(i + 1); if (i == -1) { return endOfData(); } return index.keySet().asList().get(i); } }; } @Override public int size() { return size; } }; } }; } @Override public int size() { return IntMath.binomial(index.size(), size); } @Override public String toString() { return "Sets.combinations(" + index.keySet() + ", " + size + ")"; } }; } /** An implementation for {@link Set#hashCode()}. */ static int hashCodeImpl(Set s) { int hashCode = 0; for (Object o : s) { hashCode += o != null ? o.hashCode() : 0; hashCode = ~~hashCode; // Needed to deal with unusual integer overflow in GWT. } return hashCode; } /** An implementation for {@link Set#equals(Object)}. */ static boolean equalsImpl(Set s, @CheckForNull Object object) { if (s == object) { return true; } if (object instanceof Set) { Set o = (Set) object; try { return s.size() == o.size() && s.containsAll(o); } catch (NullPointerException | ClassCastException ignored) { return false; } } return false; } /** * Returns an unmodifiable view of the specified navigable set. This method allows modules to * provide users with "read-only" access to internal navigable sets. Query operations on the * returned set "read through" to the specified set, and attempts to modify the returned set, * whether direct or via its collection views, result in an {@code UnsupportedOperationException}. * *

The returned navigable set will be serializable if the specified navigable set is * serializable. * *

Java 8 users and later: Prefer {@link Collections#unmodifiableNavigableSet}. * * @param set the navigable set for which an unmodifiable view is to be returned * @return an unmodifiable view of the specified navigable set * @since 12.0 */ public static NavigableSet unmodifiableNavigableSet( NavigableSet set) { if (set instanceof ImmutableCollection || set instanceof UnmodifiableNavigableSet) { return set; } return new UnmodifiableNavigableSet(set); } static final class UnmodifiableNavigableSet extends ForwardingSortedSet implements NavigableSet, Serializable { private final NavigableSet delegate; private final SortedSet unmodifiableDelegate; UnmodifiableNavigableSet(NavigableSet delegate) { this.delegate = checkNotNull(delegate); this.unmodifiableDelegate = Collections.unmodifiableSortedSet(delegate); } @Override protected SortedSet delegate() { return unmodifiableDelegate; } // default methods not forwarded by ForwardingSortedSet @Override public boolean removeIf(java.util.function.Predicate filter) { throw new UnsupportedOperationException(); } @Override public Stream stream() { return delegate.stream(); } @Override public Stream parallelStream() { return delegate.parallelStream(); } @Override public void forEach(Consumer action) { delegate.forEach(action); } @Override @CheckForNull public E lower(@ParametricNullness E e) { return delegate.lower(e); } @Override @CheckForNull public E floor(@ParametricNullness E e) { return delegate.floor(e); } @Override @CheckForNull public E ceiling(@ParametricNullness E e) { return delegate.ceiling(e); } @Override @CheckForNull public E higher(@ParametricNullness E e) { return delegate.higher(e); } @Override @CheckForNull public E pollFirst() { throw new UnsupportedOperationException(); } @Override @CheckForNull public E pollLast() { throw new UnsupportedOperationException(); } @LazyInit @CheckForNull private transient UnmodifiableNavigableSet descendingSet; @Override public NavigableSet descendingSet() { UnmodifiableNavigableSet result = descendingSet; if (result == null) { result = descendingSet = new UnmodifiableNavigableSet(delegate.descendingSet()); result.descendingSet = this; } return result; } @Override public Iterator descendingIterator() { return Iterators.unmodifiableIterator(delegate.descendingIterator()); } @Override public NavigableSet subSet( @ParametricNullness E fromElement, boolean fromInclusive, @ParametricNullness E toElement, boolean toInclusive) { return unmodifiableNavigableSet( delegate.subSet(fromElement, fromInclusive, toElement, toInclusive)); } @Override public NavigableSet headSet(@ParametricNullness E toElement, boolean inclusive) { return unmodifiableNavigableSet(delegate.headSet(toElement, inclusive)); } @Override public NavigableSet tailSet(@ParametricNullness E fromElement, boolean inclusive) { return unmodifiableNavigableSet(delegate.tailSet(fromElement, inclusive)); } private static final long serialVersionUID = 0; } /** * Returns a synchronized (thread-safe) navigable set backed by the specified navigable set. In * order to guarantee serial access, it is critical that all access to the backing * navigable set is accomplished through the returned navigable set (or its views). * *

It is imperative that the user manually synchronize on the returned sorted set when * iterating over it or any of its {@code descendingSet}, {@code subSet}, {@code headSet}, or * {@code tailSet} views. * *

{@code
   * NavigableSet set = synchronizedNavigableSet(new TreeSet());
   *  ...
   * synchronized (set) {
   *   // Must be in the synchronized block
   *   Iterator it = set.iterator();
   *   while (it.hasNext()) {
   *     foo(it.next());
   *   }
   * }
   * }
* *

or: * *

{@code
   * NavigableSet set = synchronizedNavigableSet(new TreeSet());
   * NavigableSet set2 = set.descendingSet().headSet(foo);
   *  ...
   * synchronized (set) { // Note: set, not set2!!!
   *   // Must be in the synchronized block
   *   Iterator it = set2.descendingIterator();
   *   while (it.hasNext())
   *     foo(it.next());
   *   }
   * }
   * }
* *

Failure to follow this advice may result in non-deterministic behavior. * *

The returned navigable set will be serializable if the specified navigable set is * serializable. * *

Java 8 users and later: Prefer {@link Collections#synchronizedNavigableSet}. * * @param navigableSet the navigable set to be "wrapped" in a synchronized navigable set. * @return a synchronized view of the specified navigable set. * @since 13.0 */ @GwtIncompatible // NavigableSet public static NavigableSet synchronizedNavigableSet( NavigableSet navigableSet) { return Synchronized.navigableSet(navigableSet); } /** Remove each element in an iterable from a set. */ static boolean removeAllImpl(Set set, Iterator iterator) { boolean changed = false; while (iterator.hasNext()) { changed |= set.remove(iterator.next()); } return changed; } static boolean removeAllImpl(Set set, Collection collection) { checkNotNull(collection); // for GWT if (collection instanceof Multiset) { collection = ((Multiset) collection).elementSet(); } /* * AbstractSet.removeAll(List) has quadratic behavior if the list size * is just more than the set's size. We augment the test by * assuming that sets have fast contains() performance, and other * collections don't. See * http://code.google.com/p/guava-libraries/issues/detail?id=1013 */ if (collection instanceof Set && collection.size() > set.size()) { return Iterators.removeAll(set.iterator(), collection); } else { return removeAllImpl(set, collection.iterator()); } } @GwtIncompatible // NavigableSet static class DescendingSet extends ForwardingNavigableSet { private final NavigableSet forward; DescendingSet(NavigableSet forward) { this.forward = forward; } @Override protected NavigableSet delegate() { return forward; } @Override @CheckForNull public E lower(@ParametricNullness E e) { return forward.higher(e); } @Override @CheckForNull public E floor(@ParametricNullness E e) { return forward.ceiling(e); } @Override @CheckForNull public E ceiling(@ParametricNullness E e) { return forward.floor(e); } @Override @CheckForNull public E higher(@ParametricNullness E e) { return forward.lower(e); } @Override @CheckForNull public E pollFirst() { return forward.pollLast(); } @Override @CheckForNull public E pollLast() { return forward.pollFirst(); } @Override public NavigableSet descendingSet() { return forward; } @Override public Iterator descendingIterator() { return forward.iterator(); } @Override public NavigableSet subSet( @ParametricNullness E fromElement, boolean fromInclusive, @ParametricNullness E toElement, boolean toInclusive) { return forward.subSet(toElement, toInclusive, fromElement, fromInclusive).descendingSet(); } @Override public SortedSet subSet(@ParametricNullness E fromElement, @ParametricNullness E toElement) { return standardSubSet(fromElement, toElement); } @Override public NavigableSet headSet(@ParametricNullness E toElement, boolean inclusive) { return forward.tailSet(toElement, inclusive).descendingSet(); } @Override public SortedSet headSet(@ParametricNullness E toElement) { return standardHeadSet(toElement); } @Override public NavigableSet tailSet(@ParametricNullness E fromElement, boolean inclusive) { return forward.headSet(fromElement, inclusive).descendingSet(); } @Override public SortedSet tailSet(@ParametricNullness E fromElement) { return standardTailSet(fromElement); } @SuppressWarnings("unchecked") @Override public Comparator comparator() { Comparator forwardComparator = forward.comparator(); if (forwardComparator == null) { return (Comparator) Ordering.natural().reverse(); } else { return reverse(forwardComparator); } } // If we inline this, we get a javac error. private static Ordering reverse(Comparator forward) { return Ordering.from(forward).reverse(); } @Override @ParametricNullness public E first() { return forward.last(); } @Override @ParametricNullness public E last() { return forward.first(); } @Override public Iterator iterator() { return forward.descendingIterator(); } @Override public @Nullable Object[] toArray() { return standardToArray(); } @Override @SuppressWarnings("nullness") // b/192354773 in our checker affects toArray declarations public T[] toArray(T[] array) { return standardToArray(array); } @Override public String toString() { return standardToString(); } } /** * Returns a view of the portion of {@code set} whose elements are contained by {@code range}. * *

This method delegates to the appropriate methods of {@link NavigableSet} (namely {@link * NavigableSet#subSet(Object, boolean, Object, boolean) subSet()}, {@link * NavigableSet#tailSet(Object, boolean) tailSet()}, and {@link NavigableSet#headSet(Object, * boolean) headSet()}) to actually construct the view. Consult these methods for a full * description of the returned view's behavior. * *

Warning: {@code Range}s always represent a range of values using the values' natural * ordering. {@code NavigableSet} on the other hand can specify a custom ordering via a {@link * Comparator}, which can violate the natural ordering. Using this method (or in general using * {@code Range}) with unnaturally-ordered sets can lead to unexpected and undefined behavior. * * @since 20.0 */ @GwtIncompatible // NavigableSet public static > NavigableSet subSet( NavigableSet set, Range range) { if (set.comparator() != null && set.comparator() != Ordering.natural() && range.hasLowerBound() && range.hasUpperBound()) { checkArgument( set.comparator().compare(range.lowerEndpoint(), range.upperEndpoint()) <= 0, "set is using a custom comparator which is inconsistent with the natural ordering."); } if (range.hasLowerBound() && range.hasUpperBound()) { return set.subSet( range.lowerEndpoint(), range.lowerBoundType() == BoundType.CLOSED, range.upperEndpoint(), range.upperBoundType() == BoundType.CLOSED); } else if (range.hasLowerBound()) { return set.tailSet(range.lowerEndpoint(), range.lowerBoundType() == BoundType.CLOSED); } else if (range.hasUpperBound()) { return set.headSet(range.upperEndpoint(), range.upperBoundType() == BoundType.CLOSED); } return checkNotNull(set); } }