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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) 2012 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.checkNotNull;
import static com.google.common.collect.CollectPreconditions.checkRemove;
import static com.google.common.collect.CompactHashing.UNSET;
import static com.google.common.collect.Hashing.smearedHash;
import static java.util.Objects.requireNonNull;

import com.google.common.annotations.GwtIncompatible;
import com.google.common.annotations.J2ktIncompatible;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Objects;
import com.google.common.base.Preconditions;
import com.google.common.primitives.Ints;
import com.google.errorprone.annotations.CanIgnoreReturnValue;
import java.io.IOException;
import java.io.InvalidObjectException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.util.AbstractSet;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.ConcurrentModificationException;
import java.util.Iterator;
import java.util.LinkedHashSet;
import java.util.NoSuchElementException;
import java.util.Set;
import java.util.Spliterator;
import java.util.Spliterators;
import java.util.function.Consumer;
import javax.annotation.CheckForNull;
import org.checkerframework.checker.nullness.qual.Nullable;

/**
 * CompactHashSet is an implementation of a Set. All optional operations (adding and removing) are
 * supported. The elements can be any objects.
 *
 * 

{@code contains(x)}, {@code add(x)} and {@code remove(x)}, are all (expected and amortized) * constant time operations. Expected in the hashtable sense (depends on the hash function doing a * good job of distributing the elements to the buckets to a distribution not far from uniform), and * amortized since some operations can trigger a hash table resize. * *

Unlike {@code java.util.HashSet}, iteration is only proportional to the actual {@code size()}, * which is optimal, and not the size of the internal hashtable, which could be much larger * than {@code size()}. Furthermore, this structure only depends on a fixed number of arrays; {@code * add(x)} operations do not create objects for the garbage collector to deal with, and for * every element added, the garbage collector will have to traverse {@code 1.5} references on * average, in the marking phase, not {@code 5.0} as in {@code java.util.HashSet}. * *

If there are no removals, then {@link #iterator iteration} order is the same as insertion * order. Any removal invalidates any ordering guarantees. * *

This class should not be assumed to be universally superior to {@code java.util.HashSet}. * Generally speaking, this class reduces object allocation and memory consumption at the price of * moderately increased constant factors of CPU. Only use this class when there is a specific reason * to prioritize memory over CPU. * * @author Dimitris Andreou * @author Jon Noack */ @GwtIncompatible // not worth using in GWT for now @ElementTypesAreNonnullByDefault class CompactHashSet extends AbstractSet implements Serializable { // TODO(user): cache all field accesses in local vars /** Creates an empty {@code CompactHashSet} instance. */ public static CompactHashSet create() { return new CompactHashSet<>(); } /** * Creates a mutable {@code CompactHashSet} instance containing the elements of the given * collection in unspecified order. * * @param collection the elements that the set should contain * @return a new {@code CompactHashSet} containing those elements (minus duplicates) */ public static CompactHashSet create( Collection collection) { CompactHashSet set = createWithExpectedSize(collection.size()); set.addAll(collection); return set; } /** * Creates a mutable {@code CompactHashSet} instance containing the given elements in * unspecified order. * * @param elements the elements that the set should contain * @return a new {@code CompactHashSet} containing those elements (minus duplicates) */ @SafeVarargs public static CompactHashSet create(E... elements) { CompactHashSet set = createWithExpectedSize(elements.length); Collections.addAll(set, elements); return set; } /** * Creates a {@code CompactHashSet} instance, with a high enough "initial capacity" that it * should hold {@code expectedSize} elements without growth. * * @param expectedSize the number of elements you expect to add to the returned set * @return a new, empty {@code CompactHashSet} with enough capacity to hold {@code expectedSize} * elements without resizing * @throws IllegalArgumentException if {@code expectedSize} is negative */ public static CompactHashSet createWithExpectedSize( int expectedSize) { return new CompactHashSet<>(expectedSize); } /** * Maximum allowed false positive probability of detecting a hash flooding attack given random * input. */ @VisibleForTesting( ) static final double HASH_FLOODING_FPP = 0.001; /** * Maximum allowed length of a hash table bucket before falling back to a j.u.LinkedHashSet based * implementation. Experimentally determined. */ private static final int MAX_HASH_BUCKET_LENGTH = 9; // See CompactHashMap for a detailed description of how the following fields work. That // description talks about `keys`, `values`, and `entries`; here the `keys` and `values` arrays // are replaced by a single `elements` array but everything else works similarly. /** * The hashtable object. This can be either: * *

    *
  • a byte[], short[], or int[], with size a power of two, created by * CompactHashing.createTable, whose values are either *
      *
    • UNSET, meaning "null pointer" *
    • one plus an index into the entries and elements array *
    *
  • another java.util.Set delegate implementation. In most modern JDKs, normal java.util hash * collections intelligently fall back to a binary search tree if hash table collisions are * detected. Rather than going to all the trouble of reimplementing this ourselves, we * simply switch over to use the JDK implementation wholesale if probable hash flooding is * detected, sacrificing the compactness guarantee in very rare cases in exchange for much * more reliable worst-case behavior. *
  • null, if no entries have yet been added to the map *
*/ @CheckForNull private transient Object table; /** * Contains the logical entries, in the range of [0, size()). The high bits of each int are the * part of the smeared hash of the element not covered by the hashtable mask, whereas the low bits * are the "next" pointer (pointing to the next entry in the bucket chain), which will always be * less than or equal to the hashtable mask. * *
   * hash  = aaaaaaaa
   * mask  = 00000fff
   * next  = 00000bbb
   * entry = aaaaabbb
   * 
* *

The pointers in [size(), entries.length) are all "null" (UNSET). */ @CheckForNull private transient int[] entries; /** * The elements contained in the set, in the range of [0, size()). The elements in [size(), * elements.length) are all {@code null}. */ @VisibleForTesting @CheckForNull transient @Nullable Object[] elements; /** * Keeps track of metadata like the number of hash table bits and modifications of this data * structure (to make it possible to throw ConcurrentModificationException in the iterator). Note * that we choose not to make this volatile, so we do less of a "best effort" to track such * errors, for better performance. */ private transient int metadata; /** The number of elements contained in the set. */ private transient int size; /** Constructs a new empty instance of {@code CompactHashSet}. */ CompactHashSet() { init(CompactHashing.DEFAULT_SIZE); } /** * Constructs a new instance of {@code CompactHashSet} with the specified capacity. * * @param expectedSize the initial capacity of this {@code CompactHashSet}. */ CompactHashSet(int expectedSize) { init(expectedSize); } /** Pseudoconstructor for serialization support. */ void init(int expectedSize) { Preconditions.checkArgument(expectedSize >= 0, "Expected size must be >= 0"); // Save expectedSize for use in allocArrays() this.metadata = Ints.constrainToRange(expectedSize, 1, CompactHashing.MAX_SIZE); } /** Returns whether arrays need to be allocated. */ @VisibleForTesting boolean needsAllocArrays() { return table == null; } /** Handle lazy allocation of arrays. */ @CanIgnoreReturnValue int allocArrays() { Preconditions.checkState(needsAllocArrays(), "Arrays already allocated"); int expectedSize = metadata; int buckets = CompactHashing.tableSize(expectedSize); this.table = CompactHashing.createTable(buckets); setHashTableMask(buckets - 1); this.entries = new int[expectedSize]; this.elements = new Object[expectedSize]; return expectedSize; } @SuppressWarnings("unchecked") @VisibleForTesting @CheckForNull Set delegateOrNull() { if (table instanceof Set) { return (Set) table; } return null; } private Set createHashFloodingResistantDelegate(int tableSize) { return new LinkedHashSet<>(tableSize, 1.0f); } @VisibleForTesting @CanIgnoreReturnValue Set convertToHashFloodingResistantImplementation() { Set newDelegate = createHashFloodingResistantDelegate(hashTableMask() + 1); for (int i = firstEntryIndex(); i >= 0; i = getSuccessor(i)) { newDelegate.add(element(i)); } this.table = newDelegate; this.entries = null; this.elements = null; incrementModCount(); return newDelegate; } @VisibleForTesting boolean isUsingHashFloodingResistance() { return delegateOrNull() != null; } /** Stores the hash table mask as the number of bits needed to represent an index. */ private void setHashTableMask(int mask) { int hashTableBits = Integer.SIZE - Integer.numberOfLeadingZeros(mask); metadata = CompactHashing.maskCombine(metadata, hashTableBits, CompactHashing.HASH_TABLE_BITS_MASK); } /** Gets the hash table mask using the stored number of hash table bits. */ private int hashTableMask() { return (1 << (metadata & CompactHashing.HASH_TABLE_BITS_MASK)) - 1; } void incrementModCount() { metadata += CompactHashing.MODIFICATION_COUNT_INCREMENT; } @CanIgnoreReturnValue @Override public boolean add(@ParametricNullness E object) { if (needsAllocArrays()) { allocArrays(); } Set delegate = delegateOrNull(); if (delegate != null) { return delegate.add(object); } int[] entries = requireEntries(); @Nullable Object[] elements = requireElements(); int newEntryIndex = this.size; // current size, and pointer to the entry to be appended int newSize = newEntryIndex + 1; int hash = smearedHash(object); int mask = hashTableMask(); int tableIndex = hash & mask; int next = CompactHashing.tableGet(requireTable(), tableIndex); if (next == UNSET) { // uninitialized bucket if (newSize > mask) { // Resize and add new entry mask = resizeTable(mask, CompactHashing.newCapacity(mask), hash, newEntryIndex); } else { CompactHashing.tableSet(requireTable(), tableIndex, newEntryIndex + 1); } } else { int entryIndex; int entry; int hashPrefix = CompactHashing.getHashPrefix(hash, mask); int bucketLength = 0; do { entryIndex = next - 1; entry = entries[entryIndex]; if (CompactHashing.getHashPrefix(entry, mask) == hashPrefix && Objects.equal(object, elements[entryIndex])) { return false; } next = CompactHashing.getNext(entry, mask); bucketLength++; } while (next != UNSET); if (bucketLength >= MAX_HASH_BUCKET_LENGTH) { return convertToHashFloodingResistantImplementation().add(object); } if (newSize > mask) { // Resize and add new entry mask = resizeTable(mask, CompactHashing.newCapacity(mask), hash, newEntryIndex); } else { entries[entryIndex] = CompactHashing.maskCombine(entry, newEntryIndex + 1, mask); } } resizeMeMaybe(newSize); insertEntry(newEntryIndex, object, hash, mask); this.size = newSize; incrementModCount(); return true; } /** * Creates a fresh entry with the specified object at the specified position in the entry arrays. */ void insertEntry(int entryIndex, @ParametricNullness E object, int hash, int mask) { setEntry(entryIndex, CompactHashing.maskCombine(hash, UNSET, mask)); setElement(entryIndex, object); } /** Resizes the entries storage if necessary. */ private void resizeMeMaybe(int newSize) { int entriesSize = requireEntries().length; if (newSize > entriesSize) { // 1.5x but round up to nearest odd (this is optimal for memory consumption on Android) int newCapacity = Math.min(CompactHashing.MAX_SIZE, (entriesSize + Math.max(1, entriesSize >>> 1)) | 1); if (newCapacity != entriesSize) { resizeEntries(newCapacity); } } } /** * Resizes the internal entries array to the specified capacity, which may be greater or less than * the current capacity. */ void resizeEntries(int newCapacity) { this.entries = Arrays.copyOf(requireEntries(), newCapacity); this.elements = Arrays.copyOf(requireElements(), newCapacity); } @CanIgnoreReturnValue private int resizeTable(int oldMask, int newCapacity, int targetHash, int targetEntryIndex) { Object newTable = CompactHashing.createTable(newCapacity); int newMask = newCapacity - 1; if (targetEntryIndex != UNSET) { // Add target first; it must be last in the chain because its entry hasn't yet been created CompactHashing.tableSet(newTable, targetHash & newMask, targetEntryIndex + 1); } Object oldTable = requireTable(); int[] entries = requireEntries(); // Loop over current hashtable for (int oldTableIndex = 0; oldTableIndex <= oldMask; oldTableIndex++) { int oldNext = CompactHashing.tableGet(oldTable, oldTableIndex); while (oldNext != UNSET) { int entryIndex = oldNext - 1; int oldEntry = entries[entryIndex]; // Rebuild hash using entry hashPrefix and tableIndex ("hashSuffix") int hash = CompactHashing.getHashPrefix(oldEntry, oldMask) | oldTableIndex; int newTableIndex = hash & newMask; int newNext = CompactHashing.tableGet(newTable, newTableIndex); CompactHashing.tableSet(newTable, newTableIndex, oldNext); entries[entryIndex] = CompactHashing.maskCombine(hash, newNext, newMask); oldNext = CompactHashing.getNext(oldEntry, oldMask); } } this.table = newTable; setHashTableMask(newMask); return newMask; } @Override public boolean contains(@CheckForNull Object object) { if (needsAllocArrays()) { return false; } Set delegate = delegateOrNull(); if (delegate != null) { return delegate.contains(object); } int hash = smearedHash(object); int mask = hashTableMask(); int next = CompactHashing.tableGet(requireTable(), hash & mask); if (next == UNSET) { return false; } int hashPrefix = CompactHashing.getHashPrefix(hash, mask); do { int entryIndex = next - 1; int entry = entry(entryIndex); if (CompactHashing.getHashPrefix(entry, mask) == hashPrefix && Objects.equal(object, element(entryIndex))) { return true; } next = CompactHashing.getNext(entry, mask); } while (next != UNSET); return false; } @CanIgnoreReturnValue @Override public boolean remove(@CheckForNull Object object) { if (needsAllocArrays()) { return false; } Set delegate = delegateOrNull(); if (delegate != null) { return delegate.remove(object); } int mask = hashTableMask(); int index = CompactHashing.remove( object, /* value= */ null, mask, requireTable(), requireEntries(), requireElements(), /* values= */ null); if (index == -1) { return false; } moveLastEntry(index, mask); size--; incrementModCount(); return true; } /** * Moves the last entry in the entry array into {@code dstIndex}, and nulls out its old position. */ void moveLastEntry(int dstIndex, int mask) { Object table = requireTable(); int[] entries = requireEntries(); @Nullable Object[] elements = requireElements(); int srcIndex = size() - 1; if (dstIndex < srcIndex) { // move last entry to deleted spot Object object = elements[srcIndex]; elements[dstIndex] = object; elements[srcIndex] = null; // move the last entry to the removed spot, just like we moved the element entries[dstIndex] = entries[srcIndex]; entries[srcIndex] = 0; // also need to update whoever's "next" pointer was pointing to the last entry place int tableIndex = smearedHash(object) & mask; int next = CompactHashing.tableGet(table, tableIndex); int srcNext = srcIndex + 1; if (next == srcNext) { // we need to update the root pointer CompactHashing.tableSet(table, tableIndex, dstIndex + 1); } else { // we need to update a pointer in an entry int entryIndex; int entry; do { entryIndex = next - 1; entry = entries[entryIndex]; next = CompactHashing.getNext(entry, mask); } while (next != srcNext); // here, entries[entryIndex] points to the old entry location; update it entries[entryIndex] = CompactHashing.maskCombine(entry, dstIndex + 1, mask); } } else { elements[dstIndex] = null; entries[dstIndex] = 0; } } int firstEntryIndex() { return isEmpty() ? -1 : 0; } int getSuccessor(int entryIndex) { return (entryIndex + 1 < size) ? entryIndex + 1 : -1; } /** * Updates the index an iterator is pointing to after a call to remove: returns the index of the * entry that should be looked at after a removal on indexRemoved, with indexBeforeRemove as the * index that *was* the next entry that would be looked at. */ int adjustAfterRemove(int indexBeforeRemove, @SuppressWarnings("unused") int indexRemoved) { return indexBeforeRemove - 1; } @Override public Iterator iterator() { Set delegate = delegateOrNull(); if (delegate != null) { return delegate.iterator(); } return new Iterator() { int expectedMetadata = metadata; int currentIndex = firstEntryIndex(); int indexToRemove = -1; @Override public boolean hasNext() { return currentIndex >= 0; } @Override @ParametricNullness public E next() { checkForConcurrentModification(); if (!hasNext()) { throw new NoSuchElementException(); } indexToRemove = currentIndex; E result = element(currentIndex); currentIndex = getSuccessor(currentIndex); return result; } @Override public void remove() { checkForConcurrentModification(); checkRemove(indexToRemove >= 0); incrementExpectedModCount(); CompactHashSet.this.remove(element(indexToRemove)); currentIndex = adjustAfterRemove(currentIndex, indexToRemove); indexToRemove = -1; } void incrementExpectedModCount() { expectedMetadata += CompactHashing.MODIFICATION_COUNT_INCREMENT; } private void checkForConcurrentModification() { if (metadata != expectedMetadata) { throw new ConcurrentModificationException(); } } }; } @Override public Spliterator spliterator() { if (needsAllocArrays()) { return Spliterators.spliterator(new Object[0], Spliterator.DISTINCT | Spliterator.ORDERED); } Set delegate = delegateOrNull(); return (delegate != null) ? delegate.spliterator() : Spliterators.spliterator( requireElements(), 0, size, Spliterator.DISTINCT | Spliterator.ORDERED); } @Override public void forEach(Consumer action) { checkNotNull(action); Set delegate = delegateOrNull(); if (delegate != null) { delegate.forEach(action); } else { for (int i = firstEntryIndex(); i >= 0; i = getSuccessor(i)) { action.accept(element(i)); } } } @Override public int size() { Set delegate = delegateOrNull(); return (delegate != null) ? delegate.size() : size; } @Override public boolean isEmpty() { return size() == 0; } @Override public @Nullable Object[] toArray() { if (needsAllocArrays()) { return new Object[0]; } Set delegate = delegateOrNull(); return (delegate != null) ? delegate.toArray() : Arrays.copyOf(requireElements(), size); } @CanIgnoreReturnValue @Override @SuppressWarnings("nullness") // b/192354773 in our checker affects toArray declarations public T[] toArray(T[] a) { if (needsAllocArrays()) { if (a.length > 0) { a[0] = null; } return a; } Set delegate = delegateOrNull(); return (delegate != null) ? delegate.toArray(a) : ObjectArrays.toArrayImpl(requireElements(), 0, size, a); } /** * Ensures that this {@code CompactHashSet} has the smallest representation in memory, given its * current size. */ public void trimToSize() { if (needsAllocArrays()) { return; } Set delegate = delegateOrNull(); if (delegate != null) { Set newDelegate = createHashFloodingResistantDelegate(size()); newDelegate.addAll(delegate); this.table = newDelegate; return; } int size = this.size; if (size < requireEntries().length) { resizeEntries(size); } int minimumTableSize = CompactHashing.tableSize(size); int mask = hashTableMask(); if (minimumTableSize < mask) { // smaller table size will always be less than current mask resizeTable(mask, minimumTableSize, UNSET, UNSET); } } @Override public void clear() { if (needsAllocArrays()) { return; } incrementModCount(); Set delegate = delegateOrNull(); if (delegate != null) { metadata = Ints.constrainToRange(size(), CompactHashing.DEFAULT_SIZE, CompactHashing.MAX_SIZE); delegate.clear(); // invalidate any iterators left over! table = null; size = 0; } else { Arrays.fill(requireElements(), 0, size, null); CompactHashing.tableClear(requireTable()); Arrays.fill(requireEntries(), 0, size, 0); this.size = 0; } } @J2ktIncompatible private void writeObject(ObjectOutputStream stream) throws IOException { stream.defaultWriteObject(); stream.writeInt(size()); for (E e : this) { stream.writeObject(e); } } @SuppressWarnings("unchecked") @J2ktIncompatible private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { stream.defaultReadObject(); int elementCount = stream.readInt(); if (elementCount < 0) { throw new InvalidObjectException("Invalid size: " + elementCount); } init(elementCount); for (int i = 0; i < elementCount; i++) { E element = (E) stream.readObject(); add(element); } } /* * For discussion of the safety of the following methods, see the comments near the end of * CompactHashMap. */ private Object requireTable() { return requireNonNull(table); } private int[] requireEntries() { return requireNonNull(entries); } private @Nullable Object[] requireElements() { return requireNonNull(elements); } @SuppressWarnings("unchecked") private E element(int i) { return (E) requireElements()[i]; } private int entry(int i) { return requireEntries()[i]; } private void setElement(int i, E value) { requireElements()[i] = value; } private void setEntry(int i, int value) { requireEntries()[i] = value; } }





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