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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 com.google.common.collect.NullnessCasts.uncheckedCastNullableTToT;
import static com.google.common.collect.NullnessCasts.unsafeNull;
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 com.google.errorprone.annotations.concurrent.LazyInit;
import com.google.j2objc.annotations.WeakOuter;
import java.io.IOException;
import java.io.InvalidObjectException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.util.AbstractMap;
import java.util.Arrays;
import java.util.Collection;
import java.util.ConcurrentModificationException;
import java.util.Iterator;
import java.util.LinkedHashMap;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Set;
import java.util.Spliterator;
import java.util.Spliterators;
import java.util.function.BiConsumer;
import java.util.function.BiFunction;
import java.util.function.Consumer;
import javax.annotation.CheckForNull;
import org.checkerframework.checker.nullness.qual.Nullable;

/**
 * CompactHashMap is an implementation of a Map. All optional operations (put and remove) are
 * supported. Null keys and values are supported.
 *
 * 

{@code containsKey(k)}, {@code put(k, v)} and {@code remove(k)} 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.HashMap}, 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 places significantly reduced load on the garbage * collector by only using a constant number of internal objects. * *

If there are no removals, then iteration order for the {@link #entrySet}, {@link #keySet}, and * {@link #values} views 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.HashMap}. * 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 Louis Wasserman * @author Jon Noack */ @GwtIncompatible // not worth using in GWT for now @ElementTypesAreNonnullByDefault class CompactHashMap extends AbstractMap implements Serializable { /* * TODO: Make this a drop-in replacement for j.u. versions, actually drop them in, and test the * world. Figure out what sort of space-time tradeoff we're actually going to get here with the * *Map variants. This class is particularly hard to benchmark, because the benefit is not only in * less allocation, but also having the GC do less work to scan the heap because of fewer * references, which is particularly hard to quantify. */ /** Creates an empty {@code CompactHashMap} instance. */ public static CompactHashMap create() { return new CompactHashMap<>(); } /** * Creates a {@code CompactHashMap} 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 CompactHashMap} with enough capacity to hold {@code expectedSize} * elements without resizing * @throws IllegalArgumentException if {@code expectedSize} is negative */ public static CompactHashMap createWithExpectedSize(int expectedSize) { return new CompactHashMap<>(expectedSize); } private static final Object NOT_FOUND = new Object(); /** * 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.LinkedHashMap-based * implementation. Experimentally determined. */ private static final int MAX_HASH_BUCKET_LENGTH = 9; // The way the `table`, `entries`, `keys`, and `values` arrays work together is as follows. // // The `table` array always has a size that is a power of 2. The hashcode of a key in the map // is masked in order to correspond to the current table size. For example, if the table size // is 128 then the mask is 127 == 0x7f, keeping the bottom 7 bits of the hash value. // If a key hashes to 0x89abcdef the mask reduces it to 0x89abcdef & 0x7f == 0x6f. We'll call this // the "short hash". // // The `keys`, `values`, and `entries` arrays always have the same size as each other. They can be // seen as fields of an imaginary `Entry` object like this: // // class Entry { // int hash; // Entry next; // K key; // V value; // } // // The imaginary `hash` and `next` values are combined into a single `int` value in the `entries` // array. The top bits of this value are the remaining bits of the hash value that were not used // in the short hash. We saw that a mask of 0x7f would keep the 7-bit value 0x6f from a full // hashcode of 0x89abcdef. The imaginary `hash` value would then be the remaining top 25 bits, // 0x89abcd80. To this is added (or'd) the `next` value, which is an index within `entries` // (and therefore within `keys` and `values`) of another entry that has the same short hash // value. In our example, it would be another entry for a key whose short hash is also 0x6f. // // Essentially, then, `table[h]` gives us the start of a linked list in `entries`, where every // element of the list has the short hash value h. // // A wrinkle here is that the value 0 (called UNSET in the code) is used as the equivalent of a // null pointer. If `table[h] == 0` that means there are no keys in the map whose short hash is h. // If the `next` bits in `entries[i]` are 0 that means there are no further entries for the given // short hash. But 0 is also a valid index in `entries`, so we add 1 to these indices before // putting them in `table` or in `next` bits, and subtract 1 again when we need an index value. // // The elements of `keys`, `values`, and `entries` are added sequentially, so that elements 0 to // `size() - 1` are used and remaining elements are not. This makes iteration straightforward. // Removing an entry generally involves moving the last element of each array to where the removed // entry was, and adjusting index links accordingly. /** * 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 keys, values, and entries arrays *
    *
  • another java.util.Map 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 key 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). */ @VisibleForTesting @CheckForNull transient int[] entries; /** * The keys of the entries in the map, in the range of [0, size()). The keys in [size(), * keys.length) are all {@code null}. */ @VisibleForTesting @CheckForNull transient @Nullable Object[] keys; /** * The values of the entries in the map, in the range of [0, size()). The values in [size(), * values.length) are all {@code null}. */ @VisibleForTesting @CheckForNull transient @Nullable Object[] values; /** * 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. * *

For a new instance, where the arrays above have not yet been allocated, the value of {@code * metadata} is the size that the arrays should be allocated with. Once the arrays have been * allocated, the value of {@code metadata} combines the number of bits in the "short hash", in * its bottom {@value CompactHashing#HASH_TABLE_BITS_MAX_BITS} bits, with a modification count in * the remaining bits that is used to detect concurrent modification during iteration. */ private transient int metadata; /** The number of elements contained in the set. */ private transient int size; /** Constructs a new empty instance of {@code CompactHashMap}. */ CompactHashMap() { init(CompactHashing.DEFAULT_SIZE); } /** * Constructs a new instance of {@code CompactHashMap} with the specified capacity. * * @param expectedSize the initial capacity of this {@code CompactHashMap}. */ CompactHashMap(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. */ 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.keys = new Object[expectedSize]; this.values = new Object[expectedSize]; return expectedSize; } @SuppressWarnings("unchecked") @VisibleForTesting @CheckForNull Map delegateOrNull() { if (table instanceof Map) { return (Map) table; } return null; } Map createHashFloodingResistantDelegate(int tableSize) { return new LinkedHashMap<>(tableSize, 1.0f); } @CanIgnoreReturnValue Map convertToHashFloodingResistantImplementation() { Map newDelegate = createHashFloodingResistantDelegate(hashTableMask() + 1); for (int i = firstEntryIndex(); i >= 0; i = getSuccessor(i)) { newDelegate.put(key(i), value(i)); } this.table = newDelegate; this.entries = null; this.keys = null; this.values = null; incrementModCount(); return newDelegate; } /** 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; } /** * Mark an access of the specified entry. Used only in {@code CompactLinkedHashMap} for LRU * ordering. */ void accessEntry(int index) { // no-op by default } @CanIgnoreReturnValue @Override @CheckForNull public V put(@ParametricNullness K key, @ParametricNullness V value) { if (needsAllocArrays()) { allocArrays(); } Map delegate = delegateOrNull(); if (delegate != null) { return delegate.put(key, value); } int[] entries = requireEntries(); @Nullable Object[] keys = requireKeys(); @Nullable Object[] values = requireValues(); int newEntryIndex = this.size; // current size, and pointer to the entry to be appended int newSize = newEntryIndex + 1; int hash = smearedHash(key); 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(key, keys[entryIndex])) { @SuppressWarnings("unchecked") // known to be a V V oldValue = (V) values[entryIndex]; values[entryIndex] = value; accessEntry(entryIndex); return oldValue; } next = CompactHashing.getNext(entry, mask); bucketLength++; } while (next != UNSET); if (bucketLength >= MAX_HASH_BUCKET_LENGTH) { return convertToHashFloodingResistantImplementation().put(key, value); } 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, key, value, hash, mask); this.size = newSize; incrementModCount(); return null; } /** * Creates a fresh entry with the specified object at the specified position in the entry arrays. */ void insertEntry( int entryIndex, @ParametricNullness K key, @ParametricNullness V value, int hash, int mask) { this.setEntry(entryIndex, CompactHashing.maskCombine(hash, UNSET, mask)); this.setKey(entryIndex, key); this.setValue(entryIndex, value); } /** 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.keys = Arrays.copyOf(requireKeys(), newCapacity); this.values = Arrays.copyOf(requireValues(), 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 `oldTable` to construct its replacement, ``newTable`. The entries do not move, so // the `keys` and `values` arrays do not need to change. But because the "short hash" now has a // different number of bits, we must rewrite each element of `entries` so that its contribution // to the full hashcode reflects the change, and so that its `next` link corresponds to the new // linked list of entries with the new short hash. for (int oldTableIndex = 0; oldTableIndex <= oldMask; oldTableIndex++) { int oldNext = CompactHashing.tableGet(oldTable, oldTableIndex); // Each element of `oldTable` is the head of a (possibly empty) linked list of elements in // `entries`. The `oldNext` loop is going to traverse that linked list. // We need to rewrite the `next` link of each of the elements so that it is in the appropriate // linked list starting from `newTable`. In general, each element from the old linked list // belongs to a different linked list from `newTable`. We insert each element in turn at the // head of its appropriate `newTable` linked list. while (oldNext != UNSET) { int entryIndex = oldNext - 1; int oldEntry = entries[entryIndex]; // Rebuild the full 32-bit hash using entry hashPrefix and oldTableIndex ("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; } private int indexOf(@CheckForNull Object key) { if (needsAllocArrays()) { return -1; } int hash = smearedHash(key); int mask = hashTableMask(); int next = CompactHashing.tableGet(requireTable(), hash & mask); if (next == UNSET) { return -1; } int hashPrefix = CompactHashing.getHashPrefix(hash, mask); do { int entryIndex = next - 1; int entry = entry(entryIndex); if (CompactHashing.getHashPrefix(entry, mask) == hashPrefix && Objects.equal(key, key(entryIndex))) { return entryIndex; } next = CompactHashing.getNext(entry, mask); } while (next != UNSET); return -1; } @Override public boolean containsKey(@CheckForNull Object key) { Map delegate = delegateOrNull(); return (delegate != null) ? delegate.containsKey(key) : indexOf(key) != -1; } @Override @CheckForNull public V get(@CheckForNull Object key) { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.get(key); } int index = indexOf(key); if (index == -1) { return null; } accessEntry(index); return value(index); } @CanIgnoreReturnValue @SuppressWarnings("unchecked") // known to be a V @Override @CheckForNull public V remove(@CheckForNull Object key) { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.remove(key); } Object oldValue = removeHelper(key); return (oldValue == NOT_FOUND) ? null : (V) oldValue; } private @Nullable Object removeHelper(@CheckForNull Object key) { if (needsAllocArrays()) { return NOT_FOUND; } int mask = hashTableMask(); int index = CompactHashing.remove( key, /* value= */ null, mask, requireTable(), requireEntries(), requireKeys(), /* values= */ null); if (index == -1) { return NOT_FOUND; } Object oldValue = value(index); moveLastEntry(index, mask); size--; incrementModCount(); return oldValue; } /** * 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[] keys = requireKeys(); @Nullable Object[] values = requireValues(); int srcIndex = size() - 1; if (dstIndex < srcIndex) { // move last entry to deleted spot Object key = keys[srcIndex]; keys[dstIndex] = key; values[dstIndex] = values[srcIndex]; keys[srcIndex] = null; values[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(key) & 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 { keys[dstIndex] = null; values[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; } private abstract class Itr implements Iterator { int expectedMetadata = metadata; int currentIndex = firstEntryIndex(); int indexToRemove = -1; @Override public boolean hasNext() { return currentIndex >= 0; } @ParametricNullness abstract T getOutput(int entry); @Override @ParametricNullness public T next() { checkForConcurrentModification(); if (!hasNext()) { throw new NoSuchElementException(); } indexToRemove = currentIndex; T result = getOutput(currentIndex); currentIndex = getSuccessor(currentIndex); return result; } @Override public void remove() { checkForConcurrentModification(); checkRemove(indexToRemove >= 0); incrementExpectedModCount(); CompactHashMap.this.remove(key(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 void replaceAll(BiFunction function) { checkNotNull(function); Map delegate = delegateOrNull(); if (delegate != null) { delegate.replaceAll(function); } else { for (int i = 0; i < size; i++) { setValue(i, function.apply(key(i), value(i))); } } } @LazyInit @CheckForNull private transient Set keySetView; @Override public Set keySet() { return (keySetView == null) ? keySetView = createKeySet() : keySetView; } Set createKeySet() { return new KeySetView(); } @WeakOuter class KeySetView extends Maps.KeySet { KeySetView() { super(CompactHashMap.this); } @Override public @Nullable Object[] toArray() { if (needsAllocArrays()) { return new Object[0]; } Map delegate = delegateOrNull(); return (delegate != null) ? delegate.keySet().toArray() : ObjectArrays.copyAsObjectArray(requireKeys(), 0, size); } @Override @SuppressWarnings("nullness") // b/192354773 in our checker affects toArray declarations public T[] toArray(T[] a) { if (needsAllocArrays()) { if (a.length > 0) { @Nullable Object[] unsoundlyCovariantArray = a; unsoundlyCovariantArray[0] = null; } return a; } Map delegate = delegateOrNull(); return (delegate != null) ? delegate.keySet().toArray(a) : ObjectArrays.toArrayImpl(requireKeys(), 0, size, a); } @Override public boolean remove(@CheckForNull Object o) { Map delegate = delegateOrNull(); return (delegate != null) ? delegate.keySet().remove(o) : CompactHashMap.this.removeHelper(o) != NOT_FOUND; } @Override public Iterator iterator() { return keySetIterator(); } @Override public Spliterator spliterator() { if (needsAllocArrays()) { return Spliterators.spliterator(new Object[0], Spliterator.DISTINCT | Spliterator.ORDERED); } Map delegate = delegateOrNull(); return (delegate != null) ? delegate.keySet().spliterator() : Spliterators.spliterator( requireKeys(), 0, size, Spliterator.DISTINCT | Spliterator.ORDERED); } @Override public void forEach(Consumer action) { checkNotNull(action); Map delegate = delegateOrNull(); if (delegate != null) { delegate.keySet().forEach(action); } else { for (int i = firstEntryIndex(); i >= 0; i = getSuccessor(i)) { action.accept(key(i)); } } } } Iterator keySetIterator() { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.keySet().iterator(); } return new Itr() { @Override @ParametricNullness K getOutput(int entry) { return key(entry); } }; } @Override public void forEach(BiConsumer action) { checkNotNull(action); Map delegate = delegateOrNull(); if (delegate != null) { delegate.forEach(action); } else { for (int i = firstEntryIndex(); i >= 0; i = getSuccessor(i)) { action.accept(key(i), value(i)); } } } @LazyInit @CheckForNull private transient Set> entrySetView; @Override public Set> entrySet() { return (entrySetView == null) ? entrySetView = createEntrySet() : entrySetView; } Set> createEntrySet() { return new EntrySetView(); } @WeakOuter class EntrySetView extends Maps.EntrySet { @Override Map map() { return CompactHashMap.this; } @Override public Iterator> iterator() { return entrySetIterator(); } @Override public Spliterator> spliterator() { Map delegate = delegateOrNull(); return (delegate != null) ? delegate.entrySet().spliterator() : CollectSpliterators.indexed( size, Spliterator.DISTINCT | Spliterator.ORDERED, MapEntry::new); } @Override public boolean contains(@CheckForNull Object o) { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.entrySet().contains(o); } else if (o instanceof Entry) { Entry entry = (Entry) o; int index = indexOf(entry.getKey()); return index != -1 && Objects.equal(value(index), entry.getValue()); } return false; } @Override public boolean remove(@CheckForNull Object o) { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.entrySet().remove(o); } else if (o instanceof Entry) { Entry entry = (Entry) o; if (needsAllocArrays()) { return false; } int mask = hashTableMask(); int index = CompactHashing.remove( entry.getKey(), entry.getValue(), mask, requireTable(), requireEntries(), requireKeys(), requireValues()); if (index == -1) { return false; } moveLastEntry(index, mask); size--; incrementModCount(); return true; } return false; } } Iterator> entrySetIterator() { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.entrySet().iterator(); } return new Itr>() { @Override Entry getOutput(int entry) { return new MapEntry(entry); } }; } final class MapEntry extends AbstractMapEntry { @ParametricNullness private final K key; private int lastKnownIndex; MapEntry(int index) { this.key = key(index); this.lastKnownIndex = index; } @Override @ParametricNullness public K getKey() { return key; } private void updateLastKnownIndex() { if (lastKnownIndex == -1 || lastKnownIndex >= size() || !Objects.equal(key, key(lastKnownIndex))) { lastKnownIndex = indexOf(key); } } @Override @ParametricNullness public V getValue() { Map delegate = delegateOrNull(); if (delegate != null) { /* * The cast is safe because the entry is present in the map. Or, if it has been removed by a * concurrent modification, behavior is undefined. */ return uncheckedCastNullableTToT(delegate.get(key)); } updateLastKnownIndex(); /* * If the entry has been removed from the map, we return null, even though that might not be a * valid value. That's the best we can do, short of holding a reference to the most recently * seen value. And while we *could* do that, we aren't required to: Map.Entry explicitly says * that behavior is undefined when the backing map is modified through another API. (It even * permits us to throw IllegalStateException. Maybe we should have done that, but we probably * shouldn't change now for fear of breaking people.) */ return (lastKnownIndex == -1) ? unsafeNull() : value(lastKnownIndex); } @Override @ParametricNullness public V setValue(@ParametricNullness V value) { Map delegate = delegateOrNull(); if (delegate != null) { return uncheckedCastNullableTToT(delegate.put(key, value)); // See discussion in getValue(). } updateLastKnownIndex(); if (lastKnownIndex == -1) { put(key, value); return unsafeNull(); // See discussion in getValue(). } else { V old = value(lastKnownIndex); CompactHashMap.this.setValue(lastKnownIndex, value); return old; } } } @Override public int size() { Map delegate = delegateOrNull(); return (delegate != null) ? delegate.size() : size; } @Override public boolean isEmpty() { return size() == 0; } @Override public boolean containsValue(@CheckForNull Object value) { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.containsValue(value); } for (int i = 0; i < size; i++) { if (Objects.equal(value, value(i))) { return true; } } return false; } @LazyInit @CheckForNull private transient Collection valuesView; @Override public Collection values() { return (valuesView == null) ? valuesView = createValues() : valuesView; } Collection createValues() { return new ValuesView(); } @WeakOuter class ValuesView extends Maps.Values { ValuesView() { super(CompactHashMap.this); } @Override public Iterator iterator() { return valuesIterator(); } @Override public void forEach(Consumer action) { checkNotNull(action); Map delegate = delegateOrNull(); if (delegate != null) { delegate.values().forEach(action); } else { for (int i = firstEntryIndex(); i >= 0; i = getSuccessor(i)) { action.accept(value(i)); } } } @Override public Spliterator spliterator() { if (needsAllocArrays()) { return Spliterators.spliterator(new Object[0], Spliterator.ORDERED); } Map delegate = delegateOrNull(); return (delegate != null) ? delegate.values().spliterator() : Spliterators.spliterator(requireValues(), 0, size, Spliterator.ORDERED); } @Override public @Nullable Object[] toArray() { if (needsAllocArrays()) { return new Object[0]; } Map delegate = delegateOrNull(); return (delegate != null) ? delegate.values().toArray() : ObjectArrays.copyAsObjectArray(requireValues(), 0, size); } @Override @SuppressWarnings("nullness") // b/192354773 in our checker affects toArray declarations public T[] toArray(T[] a) { if (needsAllocArrays()) { if (a.length > 0) { @Nullable Object[] unsoundlyCovariantArray = a; unsoundlyCovariantArray[0] = null; } return a; } Map delegate = delegateOrNull(); return (delegate != null) ? delegate.values().toArray(a) : ObjectArrays.toArrayImpl(requireValues(), 0, size, a); } } Iterator valuesIterator() { Map delegate = delegateOrNull(); if (delegate != null) { return delegate.values().iterator(); } return new Itr() { @Override @ParametricNullness V getOutput(int entry) { return value(entry); } }; } /** * Ensures that this {@code CompactHashMap} has the smallest representation in memory, given its * current size. */ public void trimToSize() { if (needsAllocArrays()) { return; } Map delegate = delegateOrNull(); if (delegate != null) { Map newDelegate = createHashFloodingResistantDelegate(size()); newDelegate.putAll(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(); Map 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(requireKeys(), 0, size, null); Arrays.fill(requireValues(), 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()); Iterator> entryIterator = entrySetIterator(); while (entryIterator.hasNext()) { Entry e = entryIterator.next(); stream.writeObject(e.getKey()); stream.writeObject(e.getValue()); } } @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++) { K key = (K) stream.readObject(); V value = (V) stream.readObject(); put(key, value); } } /* * The following methods are safe to call as long as both of the following hold: * * - allocArrays() has been called. Callers can confirm this by checking needsAllocArrays(). * * - The map has not switched to delegating to a java.util implementation to mitigate hash * flooding. Callers can confirm this by null-checking delegateOrNull(). * * In an ideal world, we would document why we know those things are true every time we call these * methods. But that is a bit too painful.... */ private Object requireTable() { return requireNonNull(table); } private int[] requireEntries() { return requireNonNull(entries); } private @Nullable Object[] requireKeys() { return requireNonNull(keys); } private @Nullable Object[] requireValues() { return requireNonNull(values); } /* * The following methods are safe to call as long as the conditions in the *previous* comment are * met *and* the index is less than size(). * * (The above explains when these methods are safe from a `nullness` perspective. From an * `unchecked` perspective, they're safe because we put only K/V elements into each array.) */ @SuppressWarnings("unchecked") private K key(int i) { return (K) requireKeys()[i]; } @SuppressWarnings("unchecked") private V value(int i) { return (V) requireValues()[i]; } private int entry(int i) { return requireEntries()[i]; } private void setKey(int i, K key) { requireKeys()[i] = key; } private void setValue(int i, V value) { requireValues()[i] = value; } private void setEntry(int i, int value) { requireEntries()[i] = value; } }





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