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// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc.  All rights reserved.
// https://developers.google.com/protocol-buffers/
//
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// modification, are permitted provided that the following conditions are
// met:
//
//     * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//     * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
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// contributors may be used to endorse or promote products derived from
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//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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package com.google.protobuf;

import java.util.AbstractMap;
import java.util.AbstractSet;
import java.util.ArrayList;
import java.util.Collections;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.NoSuchElementException;
import java.util.Set;
import java.util.SortedMap;
import java.util.TreeMap;

/**
 * A custom map implementation from FieldDescriptor to Object optimized to minimize the number of
 * memory allocations for instances with a small number of mappings. The implementation stores the
 * first {@code k} mappings in an array for a configurable value of {@code k}, allowing direct
 * access to the corresponding {@code Entry}s without the need to create an Iterator. The remaining
 * entries are stored in an overflow map. Iteration over the entries in the map should be done as
 * follows:
 *
 * 
{@code
 * for (int i = 0; i < fieldMap.getNumArrayEntries(); i++) {
 *   process(fieldMap.getArrayEntryAt(i));
 * }
 * for (Map.Entry entry : fieldMap.getOverflowEntries()) {
 *   process(entry);
 * }
 * }
* * The resulting iteration is in order of ascending field tag number. The object returned by {@link * #entrySet()} adheres to the same contract but is less efficient as it necessarily involves * creating an object for iteration. * *

The tradeoff for this memory efficiency is that the worst case running time of the {@code * put()} operation is {@code O(k + lg n)}, which happens when entries are added in descending * order. {@code k} should be chosen such that it covers enough common cases without adversely * affecting larger maps. In practice, the worst case scenario does not happen for extensions * because extension fields are serialized and deserialized in order of ascending tag number, but * the worst case scenario can happen for DynamicMessages. * *

The running time for all other operations is similar to that of {@code TreeMap}. * *

Instances are not thread-safe until {@link #makeImmutable()} is called, after which any * modifying operation will result in an {@link UnsupportedOperationException}. * * @author [email protected] Darick Tong */ // This class is final for all intents and purposes because the constructor is // private. However, the FieldDescriptor-specific logic is encapsulated in // a subclass to aid testability of the core logic. class SmallSortedMap, V> extends AbstractMap { /** * Creates a new instance for mapping FieldDescriptors to their values. The {@link * #makeImmutable()} implementation will convert the List values of any repeated fields to * unmodifiable lists. * * @param arraySize The size of the entry array containing the lexicographically smallest * mappings. */ static > SmallSortedMap newFieldMap(int arraySize) { return new SmallSortedMap(arraySize) { @Override @SuppressWarnings("unchecked") public void makeImmutable() { if (!isImmutable()) { for (int i = 0; i < getNumArrayEntries(); i++) { final Map.Entry entry = getArrayEntryAt(i); if (entry.getKey().isRepeated()) { final List value = (List) entry.getValue(); entry.setValue(Collections.unmodifiableList(value)); } } for (Map.Entry entry : getOverflowEntries()) { if (entry.getKey().isRepeated()) { final List value = (List) entry.getValue(); entry.setValue(Collections.unmodifiableList(value)); } } } super.makeImmutable(); } }; } /** * Creates a new instance for testing. * * @param arraySize The size of the entry array containing the lexicographically smallest * mappings. */ static , V> SmallSortedMap newInstanceForTest(int arraySize) { return new SmallSortedMap(arraySize); } private final int maxArraySize; // The "entry array" is actually a List because generic arrays are not // allowed. ArrayList also nicely handles the entry shifting on inserts and // removes. private List entryList; private Map overflowEntries; private boolean isImmutable; // The EntrySet is a stateless view of the Map. It's initialized the first // time it is requested and reused henceforth. private volatile EntrySet lazyEntrySet; private Map overflowEntriesDescending; private volatile DescendingEntrySet lazyDescendingEntrySet; /** * @code arraySize Size of the array in which the lexicographically smallest mappings are stored. * (i.e. the {@code k} referred to in the class documentation). */ private SmallSortedMap(int arraySize) { this.maxArraySize = arraySize; this.entryList = Collections.emptyList(); this.overflowEntries = Collections.emptyMap(); this.overflowEntriesDescending = Collections.emptyMap(); } /** Make this map immutable from this point forward. */ public void makeImmutable() { if (!isImmutable) { // Note: There's no need to wrap the entryList in an unmodifiableList // because none of the list's accessors are exposed. The iterator() of // overflowEntries, on the other hand, is exposed so it must be made // unmodifiable. overflowEntries = overflowEntries.isEmpty() ? Collections.emptyMap() : Collections.unmodifiableMap(overflowEntries); overflowEntriesDescending = overflowEntriesDescending.isEmpty() ? Collections.emptyMap() : Collections.unmodifiableMap(overflowEntriesDescending); isImmutable = true; } } /** @return Whether {@link #makeImmutable()} has been called. */ public boolean isImmutable() { return isImmutable; } /** @return The number of entries in the entry array. */ public int getNumArrayEntries() { return entryList.size(); } /** @return The array entry at the given {@code index}. */ public Map.Entry getArrayEntryAt(int index) { return entryList.get(index); } /** @return There number of overflow entries. */ public int getNumOverflowEntries() { return overflowEntries.size(); } /** @return An iterable over the overflow entries. */ public Iterable> getOverflowEntries() { return overflowEntries.isEmpty() ? EmptySet.>iterable() : overflowEntries.entrySet(); } Iterable> getOverflowEntriesDescending() { return overflowEntriesDescending.isEmpty() ? EmptySet.>iterable() : overflowEntriesDescending.entrySet(); } @Override public int size() { return entryList.size() + overflowEntries.size(); } /** * The implementation throws a {@code ClassCastException} if o is not an object of type {@code K}. * *

{@inheritDoc} */ @Override public boolean containsKey(Object o) { @SuppressWarnings("unchecked") final K key = (K) o; return binarySearchInArray(key) >= 0 || overflowEntries.containsKey(key); } /** * The implementation throws a {@code ClassCastException} if o is not an object of type {@code K}. * *

{@inheritDoc} */ @Override public V get(Object o) { @SuppressWarnings("unchecked") final K key = (K) o; final int index = binarySearchInArray(key); if (index >= 0) { return entryList.get(index).getValue(); } return overflowEntries.get(key); } @Override public V put(K key, V value) { checkMutable(); final int index = binarySearchInArray(key); if (index >= 0) { // Replace existing array entry. return entryList.get(index).setValue(value); } ensureEntryArrayMutable(); final int insertionPoint = -(index + 1); if (insertionPoint >= maxArraySize) { // Put directly in overflow. return getOverflowEntriesMutable().put(key, value); } // Insert new Entry in array. if (entryList.size() == maxArraySize) { // Shift the last array entry into overflow. final Entry lastEntryInArray = entryList.remove(maxArraySize - 1); getOverflowEntriesMutable().put(lastEntryInArray.getKey(), lastEntryInArray.getValue()); } entryList.add(insertionPoint, new Entry(key, value)); return null; } @Override public void clear() { checkMutable(); if (!entryList.isEmpty()) { entryList.clear(); } if (!overflowEntries.isEmpty()) { overflowEntries.clear(); } } /** * The implementation throws a {@code ClassCastException} if o is not an object of type {@code K}. * *

{@inheritDoc} */ @Override public V remove(Object o) { checkMutable(); @SuppressWarnings("unchecked") final K key = (K) o; final int index = binarySearchInArray(key); if (index >= 0) { return removeArrayEntryAt(index); } // overflowEntries might be Collections.unmodifiableMap(), so only // call remove() if it is non-empty. if (overflowEntries.isEmpty()) { return null; } else { return overflowEntries.remove(key); } } private V removeArrayEntryAt(int index) { checkMutable(); final V removed = entryList.remove(index).getValue(); if (!overflowEntries.isEmpty()) { // Shift the first entry in the overflow to be the last entry in the // array. final Iterator> iterator = getOverflowEntriesMutable().entrySet().iterator(); entryList.add(new Entry(iterator.next())); iterator.remove(); } return removed; } /** * @param key The key to find in the entry array. * @return The returned integer position follows the same semantics as the value returned by * {@link java.util.Arrays#binarySearch()}. */ private int binarySearchInArray(K key) { int left = 0; int right = entryList.size() - 1; // Optimization: For the common case in which entries are added in // ascending tag order, check the largest element in the array before // doing a full binary search. if (right >= 0) { int cmp = key.compareTo(entryList.get(right).getKey()); if (cmp > 0) { return -(right + 2); // Insert point is after "right". } else if (cmp == 0) { return right; } } while (left <= right) { int mid = (left + right) / 2; int cmp = key.compareTo(entryList.get(mid).getKey()); if (cmp < 0) { right = mid - 1; } else if (cmp > 0) { left = mid + 1; } else { return mid; } } return -(left + 1); } /** * Similar to the AbstractMap implementation of {@code keySet()} and {@code values()}, the entry * set is created the first time this method is called, and returned in response to all subsequent * calls. * *

{@inheritDoc} */ @Override public Set> entrySet() { if (lazyEntrySet == null) { lazyEntrySet = new EntrySet(); } return lazyEntrySet; } Set> descendingEntrySet() { if (lazyDescendingEntrySet == null) { lazyDescendingEntrySet = new DescendingEntrySet(); } return lazyDescendingEntrySet; } /** @throws UnsupportedOperationException if {@link #makeImmutable()} has has been called. */ private void checkMutable() { if (isImmutable) { throw new UnsupportedOperationException(); } } /** * @return a {@link SortedMap} to which overflow entries mappings can be added or removed. * @throws UnsupportedOperationException if {@link #makeImmutable()} has been called. */ private SortedMap getOverflowEntriesMutable() { checkMutable(); if (overflowEntries.isEmpty() && !(overflowEntries instanceof TreeMap)) { overflowEntries = new TreeMap(); overflowEntriesDescending = ((TreeMap) overflowEntries).descendingMap(); } return (SortedMap) overflowEntries; } /** Lazily creates the entry list. Any code that adds to the list must first call this method. */ private void ensureEntryArrayMutable() { checkMutable(); if (entryList.isEmpty() && !(entryList instanceof ArrayList)) { entryList = new ArrayList(maxArraySize); } } /** * Entry implementation that implements Comparable in order to support binary search within the * entry array. Also checks mutability in {@link #setValue()}. */ private class Entry implements Map.Entry, Comparable { private final K key; private V value; Entry(Map.Entry copy) { this(copy.getKey(), copy.getValue()); } Entry(K key, V value) { this.key = key; this.value = value; } @Override public K getKey() { return key; } @Override public V getValue() { return value; } @Override public int compareTo(Entry other) { return getKey().compareTo(other.getKey()); } @Override public V setValue(V newValue) { checkMutable(); final V oldValue = this.value; this.value = newValue; return oldValue; } @Override public boolean equals(Object o) { if (o == this) { return true; } if (!(o instanceof Map.Entry)) { return false; } Map.Entry other = (Map.Entry) o; return equals(key, other.getKey()) && equals(value, other.getValue()); } @Override public int hashCode() { return (key == null ? 0 : key.hashCode()) ^ (value == null ? 0 : value.hashCode()); } @Override public String toString() { return key + "=" + value; } /** equals() that handles null values. */ private boolean equals(Object o1, Object o2) { return o1 == null ? o2 == null : o1.equals(o2); } } /** Stateless view of the entries in the field map. */ private class EntrySet extends AbstractSet> { @Override public Iterator> iterator() { return new EntryIterator(); } @Override public int size() { return SmallSortedMap.this.size(); } /** * Throws a {@link ClassCastException} if o is not of the expected type. * *

{@inheritDoc} */ @Override public boolean contains(Object o) { @SuppressWarnings("unchecked") final Map.Entry entry = (Map.Entry) o; final V existing = get(entry.getKey()); final V value = entry.getValue(); return existing == value || (existing != null && existing.equals(value)); } @Override public boolean add(Map.Entry entry) { if (!contains(entry)) { put(entry.getKey(), entry.getValue()); return true; } return false; } /** * Throws a {@link ClassCastException} if o is not of the expected type. * *

{@inheritDoc} */ @Override public boolean remove(Object o) { @SuppressWarnings("unchecked") final Map.Entry entry = (Map.Entry) o; if (contains(entry)) { SmallSortedMap.this.remove(entry.getKey()); return true; } return false; } @Override public void clear() { SmallSortedMap.this.clear(); } } private class DescendingEntrySet extends EntrySet { @Override public Iterator> iterator() { return new DescendingEntryIterator(); } } /** * Iterator implementation that switches from the entry array to the overflow entries * appropriately. */ private class EntryIterator implements Iterator> { private int pos = -1; private boolean nextCalledBeforeRemove; private Iterator> lazyOverflowIterator; @Override public boolean hasNext() { return (pos + 1) < entryList.size() || (!overflowEntries.isEmpty() && getOverflowIterator().hasNext()); } @Override public Map.Entry next() { nextCalledBeforeRemove = true; // Always increment pos so that we know whether the last returned value // was from the array or from overflow. if (++pos < entryList.size()) { return entryList.get(pos); } return getOverflowIterator().next(); } @Override public void remove() { if (!nextCalledBeforeRemove) { throw new IllegalStateException("remove() was called before next()"); } nextCalledBeforeRemove = false; checkMutable(); if (pos < entryList.size()) { removeArrayEntryAt(pos--); } else { getOverflowIterator().remove(); } } /** * It is important to create the overflow iterator only after the array entries have been * iterated over because the overflow entry set changes when the client calls remove() on the * array entries, which invalidates any existing iterators. */ private Iterator> getOverflowIterator() { if (lazyOverflowIterator == null) { lazyOverflowIterator = overflowEntries.entrySet().iterator(); } return lazyOverflowIterator; } } /** * Reverse Iterator implementation that switches from the entry array to the overflow entries * appropriately. */ private class DescendingEntryIterator implements Iterator> { private int pos = entryList.size(); private Iterator> lazyOverflowIterator; @Override public boolean hasNext() { return (pos > 0 && pos <= entryList.size()) || getOverflowIterator().hasNext(); } @Override public Map.Entry next() { if (getOverflowIterator().hasNext()) { return getOverflowIterator().next(); } return entryList.get(--pos); } @Override public void remove() { throw new UnsupportedOperationException(); } /** * It is important to create the overflow iterator only after the array entries have been * iterated over because the overflow entry set changes when the client calls remove() on the * array entries, which invalidates any existing iterators. */ private Iterator> getOverflowIterator() { if (lazyOverflowIterator == null) { lazyOverflowIterator = overflowEntriesDescending.entrySet().iterator(); } return lazyOverflowIterator; } } /** * Helper class that holds immutable instances of an Iterable/Iterator that we return when the * overflow entries is empty. This eliminates the creation of an Iterator object when there is * nothing to iterate over. */ private static class EmptySet { private static final Iterator ITERATOR = new Iterator() { @Override public boolean hasNext() { return false; } @Override public Object next() { throw new NoSuchElementException(); } @Override public void remove() { throw new UnsupportedOperationException(); } }; private static final Iterable ITERABLE = new Iterable() { @Override public Iterator iterator() { return ITERATOR; } }; @SuppressWarnings("unchecked") static Iterable iterable() { return (Iterable) ITERABLE; } } @Override public boolean equals(Object o) { if (this == o) { return true; } if (!(o instanceof SmallSortedMap)) { return super.equals(o); } SmallSortedMap other = (SmallSortedMap) o; final int size = size(); if (size != other.size()) { return false; } // Best effort try to avoid allocating an entry set. final int numArrayEntries = getNumArrayEntries(); if (numArrayEntries != other.getNumArrayEntries()) { return entrySet().equals(other.entrySet()); } for (int i = 0; i < numArrayEntries; i++) { if (!getArrayEntryAt(i).equals(other.getArrayEntryAt(i))) { return false; } } if (numArrayEntries != size) { return overflowEntries.equals(other.overflowEntries); } return true; } @Override public int hashCode() { int h = 0; final int listSize = getNumArrayEntries(); for (int i = 0; i < listSize; i++) { h += entryList.get(i).hashCode(); } // Avoid the iterator allocation if possible. if (getNumOverflowEntries() > 0) { h += overflowEntries.hashCode(); } return h; } }