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/*
* Copyright (C) 2007 Google Inc.
*
* 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 com.google.common.annotations.GwtCompatible;
import com.google.common.base.Objects;
import com.google.common.base.Preconditions;
import static com.google.common.base.Preconditions.checkArgument;
import static com.google.common.base.Preconditions.checkState;
import static com.google.common.collect.Multisets.setCountImpl;
import java.io.IOException;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
import java.io.Serializable;
import java.util.AbstractCollection;
import java.util.AbstractMap;
import java.util.AbstractSequentialList;
import java.util.AbstractSet;
import java.util.Collection;
import static java.util.Collections.unmodifiableList;
import java.util.HashSet;
import java.util.Iterator;
import java.util.List;
import java.util.ListIterator;
import java.util.Map;
import java.util.Map.Entry;
import java.util.NoSuchElementException;
import java.util.Set;
import javax.annotation.Nullable;
/**
* An implementation of {@code ListMultimap} that supports deterministic
* iteration order for both keys and values. The iteration order is preserved
* across non-distinct key values. For example, for the following multimap
* definition: {@code
*
* Multimap multimap = LinkedListMultimap.create();
* multimap.put(key1, foo);
* multimap.put(key2, bar);
* multimap.put(key1, baz);}
*
* ... the iteration order for {@link #keys()} is {@code [key1, key2, key1]},
* and similarly for {@link #entries()}. Unlike {@link LinkedHashMultimap}, the
* iteration order is kept consistent between keys, entries and values. For
* example, calling: {@code
*
* map.remove(key1, foo);}
*
* changes the entries iteration order to {@code [key2=bar, key1=baz]} and the
* key iteration order to {@code [key2, key1]}. The {@link #entries()} iterator
* returns mutable map entries, and {@link #replaceValues} attempts to preserve
* iteration order as much as possible.
*
* The collections returned by {@link #keySet} and {@link #asMap} iterate
* through the keys in the order they were first added to the multimap.
* Similarly, {@link #get}, {@link #removeAll}, and {@link #replaceValues}
* return collections that iterate through the values in the order they were
* added. The collections generated by {@link #entries}, {@link #keys}, and
* {@link #values} iterate across the key-value mappings in the order they were
* added to the multimap.
*
*
Keys and values may be null. All optional multimap methods are supported,
* and all returned views are modifiable.
*
*
The methods {@link #get}, {@link #keySet}, {@link #keys}, {@link #values},
* {@link #entries}, and {@link #asMap} return collections that are views of the
* multimap. If the multimap is modified while an iteration over any of those
* collections is in progress, except through the iterator's own {@code remove}
* operation, the results of the iteration are undefined.
*
*
This class is not threadsafe when any concurrent operations update the
* multimap. Concurrent read operations will work correctly. To allow concurrent
* update operations, wrap your multimap with a call to {@link
* Multimaps#synchronizedListMultimap}.
*
* @author Mike Bostock
*/
@GwtCompatible(serializable = true)
public final class LinkedListMultimap
implements ListMultimap, Serializable {
/*
* Order is maintained using a linked list containing all key-value pairs. In
* addition, a series of disjoint linked lists of "siblings", each containing
* the values for a specific key, is used to implement {@link
* ValueForKeyIterator} in constant time.
*/
private static final class Node {
final K key;
V value;
Node next; // the next node (with any key)
Node previous; // the previous node (with any key)
Node nextSibling; // the next node with the same key
Node previousSibling; // the previous node with the same key
Node(@Nullable K key, @Nullable V value) {
this.key = key;
this.value = value;
}
@Override public String toString() {
return key + "=" + value;
}
}
private transient Node head; // the head for all keys
private transient Node tail; // the tail for all keys
private transient Multiset keyCount; // the number of values for each key
private transient Map> keyToKeyHead; // the head for a given key
private transient Map> keyToKeyTail; // the tail for a given key
/**
* Creates a new, empty {@code LinkedListMultimap} with the default initial
* capacity.
*/
public static LinkedListMultimap create() {
return new LinkedListMultimap();
}
/**
* Constructs an empty {@code LinkedListMultimap} with enough capacity to hold
* the specified number of keys without rehashing.
*
* @param expectedKeys the expected number of distinct keys
* @throws IllegalArgumentException if {@code expectedKeys} is negative
*/
public static LinkedListMultimap create(int expectedKeys) {
return new LinkedListMultimap(expectedKeys);
}
/**
* Constructs a {@code LinkedListMultimap} with the same mappings as the
* specified {@code Multimap}. The new multimap has the same
* {@link Multimap#entries()} iteration order as the input multimap.
*
* @param multimap the multimap whose contents are copied to this multimap
*/
public static LinkedListMultimap create(
Multimap extends K, ? extends V> multimap) {
return new LinkedListMultimap(multimap);
}
private LinkedListMultimap() {
keyCount = LinkedHashMultiset.create();
keyToKeyHead = Maps.newHashMap();
keyToKeyTail = Maps.newHashMap();
}
private LinkedListMultimap(int expectedKeys) {
keyCount = LinkedHashMultiset.create(expectedKeys);
keyToKeyHead = Maps.newHashMapWithExpectedSize(expectedKeys);
keyToKeyTail = Maps.newHashMapWithExpectedSize(expectedKeys);
}
private LinkedListMultimap(Multimap extends K, ? extends V> multimap) {
this(multimap.keySet().size());
putAll(multimap);
}
/**
* Adds a new node for the specified key-value pair before the specified
* {@code nextSibling} element, or at the end of the list if {@code
* nextSibling} is null. Note: if {@code nextSibling} is specified, it MUST be
* for an node for the same {@code key}!
*/
private Node addNode(
@Nullable K key, @Nullable V value, @Nullable Node nextSibling) {
Node node = new Node(key, value);
if (head == null) { // empty list
head = tail = node;
keyToKeyHead.put(key, node);
keyToKeyTail.put(key, node);
} else if (nextSibling == null) { // non-empty list, add to tail
tail.next = node;
node.previous = tail;
Node keyTail = keyToKeyTail.get(key);
if (keyTail == null) { // first for this key
keyToKeyHead.put(key, node);
} else {
keyTail.nextSibling = node;
node.previousSibling = keyTail;
}
keyToKeyTail.put(key, node);
tail = node;
} else { // non-empty list, insert before nextSibling
node.previous = nextSibling.previous;
node.previousSibling = nextSibling.previousSibling;
node.next = nextSibling;
node.nextSibling = nextSibling;
if (nextSibling.previousSibling == null) { // nextSibling was key head
keyToKeyHead.put(key, node);
} else {
nextSibling.previousSibling.nextSibling = node;
}
if (nextSibling.previous == null) { // nextSibling was head
head = node;
} else {
nextSibling.previous.next = node;
}
nextSibling.previous = node;
nextSibling.previousSibling = node;
}
keyCount.add(key);
return node;
}
/**
* Removes the specified node from the linked list. This method is only
* intended to be used from the {@code Iterator} classes. See also {@link
* LinkedListMultimap#removeAllNodes(Object)}.
*/
private void removeNode(Node node) {
if (node.previous != null) {
node.previous.next = node.next;
} else { // node was head
head = node.next;
}
if (node.next != null) {
node.next.previous = node.previous;
} else { // node was tail
tail = node.previous;
}
if (node.previousSibling != null) {
node.previousSibling.nextSibling = node.nextSibling;
} else if (node.nextSibling != null) { // node was key head
keyToKeyHead.put(node.key, node.nextSibling);
} else {
keyToKeyHead.remove(node.key); // don't leak a key-null entry
}
if (node.nextSibling != null) {
node.nextSibling.previousSibling = node.previousSibling;
} else if (node.previousSibling != null) { // node was key tail
keyToKeyTail.put(node.key, node.previousSibling);
} else {
keyToKeyTail.remove(node.key); // don't leak a key-null entry
}
keyCount.remove(node.key);
}
/** Removes all nodes for the specified key. */
private void removeAllNodes(@Nullable Object key) {
for (Iterator i = new ValueForKeyIterator(key); i.hasNext();) {
i.next();
i.remove();
}
}
/** Helper method for verifying that an iterator element is present. */
private static void checkElement(@Nullable Object node) {
if (node == null) {
throw new NoSuchElementException();
}
}
/** An {@code Iterator} over all nodes. */
private class NodeIterator implements Iterator> {
Node next = head;
Node current;
public boolean hasNext() {
return next != null;
}
public Node next() {
checkElement(next);
current = next;
next = next.next;
return current;
}
public void remove() {
checkState(current != null);
removeNode(current);
current = null;
}
}
/** An {@code Iterator} over distinct keys in key head order. */
private class DistinctKeyIterator implements Iterator {
final Set seenKeys = new HashSet(Maps.capacity(keySet().size()));
Node next = head;
Node current;
public boolean hasNext() {
return next != null;
}
public K next() {
checkElement(next);
current = next;
seenKeys.add(current.key);
do { // skip ahead to next unseen key
next = next.next;
} while ((next != null) && !seenKeys.add(next.key));
return current.key;
}
public void remove() {
checkState(current != null);
removeAllNodes(current.key);
current = null;
}
}
/** A {@code ListIterator} over values for a specified key. */
private class ValueForKeyIterator implements ListIterator {
final Object key;
int nextIndex;
Node next;
Node current;
Node previous;
/** Constructs a new iterator over all values for the specified key. */
ValueForKeyIterator(@Nullable Object key) {
this.key = key;
next = keyToKeyHead.get(key);
}
/**
* Constructs a new iterator over all values for the specified key starting
* at the specified index. This constructor is optimized so that it starts
* at either the head or the tail, depending on which is closer to the
* specified index. This allows adds to the tail to be done in constant
* time.
*
* @throws IndexOutOfBoundsException if index is invalid
*/
public ValueForKeyIterator(@Nullable Object key, int index) {
int size = keyCount.count(key);
Preconditions.checkPositionIndex(index, size);
if (index >= (size / 2)) {
previous = keyToKeyTail.get(key);
nextIndex = size;
while (index++ < size) {
previous();
}
} else {
next = keyToKeyHead.get(key);
while (index-- > 0) {
next();
}
}
this.key = key;
current = null;
}
public boolean hasNext() {
return next != null;
}
public V next() {
checkElement(next);
previous = current = next;
next = next.nextSibling;
nextIndex++;
return current.value;
}
public boolean hasPrevious() {
return previous != null;
}
public V previous() {
checkElement(previous);
next = current = previous;
previous = previous.previousSibling;
nextIndex--;
return current.value;
}
public int nextIndex() {
return nextIndex;
}
public int previousIndex() {
return nextIndex - 1;
}
public void remove() {
checkState(current != null);
if (current != next) { // removing next element
previous = current.previousSibling;
nextIndex--;
} else {
next = current.nextSibling;
}
removeNode(current);
current = null;
}
public void set(V value) {
checkState(current != null);
current.value = value;
}
@SuppressWarnings("unchecked")
public void add(V value) {
previous = addNode((K) key, value, next);
nextIndex++;
current = null;
}
}
// Query Operations
public int size() {
return keyCount.size();
}
public boolean isEmpty() {
return head == null;
}
public boolean containsKey(@Nullable Object key) {
return keyToKeyHead.containsKey(key);
}
public boolean containsValue(@Nullable Object value) {
for (Iterator> i = new NodeIterator(); i.hasNext();) {
if (Objects.equal(i.next().value, value)) {
return true;
}
}
return false;
}
public boolean containsEntry(@Nullable Object key, @Nullable Object value) {
for (Iterator i = new ValueForKeyIterator(key); i.hasNext();) {
if (Objects.equal(i.next(), value)) {
return true;
}
}
return false;
}
// Modification Operations
/**
* Stores a key-value pair in the multimap.
*
* @param key key to store in the multimap
* @param value value to store in the multimap
* @return {@code true} always
*/
public boolean put(@Nullable K key, @Nullable V value) {
addNode(key, value, null);
return true;
}
public boolean remove(@Nullable Object key, @Nullable Object value) {
Iterator values = new ValueForKeyIterator(key);
while (values.hasNext()) {
if (Objects.equal(values.next(), value)) {
values.remove();
return true;
}
}
return false;
}
// Bulk Operations
public boolean putAll(@Nullable K key, Iterable extends V> values) {
boolean changed = false;
for (V value : values) {
changed |= put(key, value);
}
return changed;
}
public boolean putAll(Multimap extends K, ? extends V> multimap) {
boolean changed = false;
for (Entry extends K, ? extends V> entry : multimap.entries()) {
changed |= put(entry.getKey(), entry.getValue());
}
return changed;
}
/**
* {@inheritDoc}
*
* If any entries for the specified {@code key} already exist in the
* multimap, their values are changed in-place without affecting the iteration
* order.
*
*
The returned list is immutable and implements
* {@link java.util.RandomAccess}.
*/
public List replaceValues(@Nullable K key, Iterable extends V> values) {
List oldValues = getCopy(key);
ListIterator keyValues = new ValueForKeyIterator(key);
Iterator extends V> newValues = values.iterator();
// Replace existing values, if any.
while (keyValues.hasNext() && newValues.hasNext()) {
keyValues.next();
keyValues.set(newValues.next());
}
// Remove remaining old values, if any.
while (keyValues.hasNext()) {
keyValues.next();
keyValues.remove();
}
// Add remaining new values, if any.
while (newValues.hasNext()) {
keyValues.add(newValues.next());
}
return oldValues;
}
private List getCopy(@Nullable Object key) {
return unmodifiableList(Lists.newArrayList(new ValueForKeyIterator(key)));
}
/**
* {@inheritDoc}
*
* The returned list is immutable and implements
* {@link java.util.RandomAccess}.
*/
public List removeAll(@Nullable Object key) {
List oldValues = getCopy(key);
removeAllNodes(key);
return oldValues;
}
public void clear() {
head = null;
tail = null;
keyCount.clear();
keyToKeyHead.clear();
keyToKeyTail.clear();
}
// Views
/**
* {@inheritDoc}
*
* If the multimap is modified while an iteration over the list is in
* progress (except through the iterator's own {@code add}, {@code set} or
* {@code remove} operations) the results of the iteration are undefined.
*
*
The returned list is not serializable and does not have random access.
*/
public List get(final @Nullable K key) {
return new AbstractSequentialList() {
@Override public int size() {
return keyCount.count(key);
}
@Override public ListIterator listIterator(int index) {
return new ValueForKeyIterator(key, index);
}
@Override public boolean removeAll(Collection> c) {
return Iterators.removeAll(iterator(), c);
}
@Override public boolean retainAll(Collection> c) {
return Iterators.retainAll(iterator(), c);
}
};
}
private transient Set keySet;
public Set keySet() {
Set result = keySet;
if (result == null) {
keySet = result = new AbstractSet() {
@Override public int size() {
return keyCount.elementSet().size();
}
@Override public Iterator iterator() {
return new DistinctKeyIterator();
}
@Override public boolean contains(Object key) { // for performance
return keyCount.contains(key);
}
};
}
return result;
}
private transient Multiset keys;
public Multiset keys() {
Multiset result = keys;
if (result == null) {
keys = result = new MultisetView();
}
return result;
}
private class MultisetView extends AbstractCollection
implements Multiset {
@Override public int size() {
return keyCount.size();
}
@Override public Iterator iterator() {
final Iterator> nodes = new NodeIterator();
return new Iterator() {
public boolean hasNext() {
return nodes.hasNext();
}
public K next() {
return nodes.next().key;
}
public void remove() {
nodes.remove();
}
};
}
public int count(@Nullable Object key) {
return keyCount.count(key);
}
public int add(@Nullable K key, int occurrences) {
throw new UnsupportedOperationException();
}
public int remove(@Nullable Object key, int occurrences) {
checkArgument(occurrences >= 0);
int oldCount = count(key);
Iterator values = new ValueForKeyIterator(key);
while ((occurrences-- > 0) && values.hasNext()) {
values.next();
values.remove();
}
return oldCount;
}
public int setCount(K element, int count) {
return setCountImpl(this, element, count);
}
public boolean setCount(K element, int oldCount, int newCount) {
return setCountImpl(this, element, oldCount, newCount);
}
@Override public boolean removeAll(Collection> c) {
return Iterators.removeAll(iterator(), c);
}
@Override public boolean retainAll(Collection> c) {
return Iterators.retainAll(iterator(), c);
}
public Set elementSet() {
return keySet();
}
public Set> entrySet() {
// TODO: lazy init?
return new AbstractSet>() {
@Override public int size() {
return keyCount.elementSet().size();
}
@Override public Iterator> iterator() {
final Iterator keyIterator = new DistinctKeyIterator();
return new Iterator>() {
public boolean hasNext() {
return keyIterator.hasNext();
}
public Entry next() {
final K key = keyIterator.next();
return new Multisets.AbstractEntry() {
public K getElement() {
return key;
}
public int getCount() {
return keyCount.count(key);
}
};
}
public void remove() {
keyIterator.remove();
}
};
}
};
}
@Override public boolean equals(@Nullable Object object) {
return keyCount.equals(object);
}
@Override public int hashCode() {
return keyCount.hashCode();
}
@Override public String toString() {
return keyCount.toString(); // XXX observe order?
}
}
private transient Collection valuesCollection;
/**
* {@inheritDoc}
*
* The iterator generated by the returned collection traverses the values
* in the order they were added to the multimap.
*/
public Collection values() {
Collection result = valuesCollection;
if (result == null) {
valuesCollection = result = new AbstractCollection() {
@Override public int size() {
return keyCount.size();
}
@Override public Iterator iterator() {
final Iterator> nodes = new NodeIterator();
return new Iterator() {
public boolean hasNext() {
return nodes.hasNext();
}
public V next() {
return nodes.next().value;
}
public void remove() {
nodes.remove();
}
};
}
};
}
return result;
}
private transient Collection> entries;
/**
* {@inheritDoc}
*
* The iterator generated by the returned collection traverses the entries
* in the order they were added to the multimap.
*
*
An entry's {@link Entry#getKey} method always returns the same key,
* regardless of what happens subsequently. As long as the corresponding
* key-value mapping is not removed from the multimap, {@link Entry#getValue}
* returns the value from the multimap, which may change over time, and {@link
* Entry#setValue} modifies that value. Removing the mapping from the
* multimap does not alter the value returned by {@code getValue()}, though a
* subsequent {@code setValue()} call won't update the multimap but will lead
* to a revised value being returned by {@code getValue()}.
*/
public Collection> entries() {
Collection> result = entries;
if (result == null) {
entries = result = new AbstractCollection>() {
@Override public int size() {
return keyCount.size();
}
@Override public Iterator> iterator() {
final Iterator> nodes = new NodeIterator();
return new Iterator>() {
public boolean hasNext() {
return nodes.hasNext();
}
public Entry next() {
final Node node = nodes.next();
return new AbstractMapEntry() {
@Override public K getKey() {
return node.key;
}
@Override public V getValue() {
return node.value;
}
@Override public V setValue(V value) {
V oldValue = node.value;
node.value = value;
return oldValue;
}
};
}
public void remove() {
nodes.remove();
}
};
}
};
}
return result;
}
private class AsMapEntries extends AbstractSet>> {
// TODO: Override contains() and remove() for better performance.
@Override public int size() {
return keyCount.elementSet().size();
}
@Override public Iterator>> iterator() {
final Iterator keyIterator = new DistinctKeyIterator();
return new Iterator>>() {
public boolean hasNext() {
return keyIterator.hasNext();
}
public Entry> next() {
final K key = keyIterator.next();
return new AbstractMapEntry>() {
@Override public K getKey() {
return key;
}
@Override public Collection getValue() {
return LinkedListMultimap.this.get(key);
}
};
}
public void remove() {
keyIterator.remove();
}
};
}
}
private transient Map> map;
public Map> asMap() {
Map> result = map;
if (result == null) {
map = result = new AbstractMap>() {
Set>> entrySet;
@Override public Set>> entrySet() {
Set>> result = entrySet;
if (result == null) {
entrySet = result = new AsMapEntries();
}
return result;
}
// The following methods are included for performance.
@Override public boolean containsKey(@Nullable Object key) {
return LinkedListMultimap.this.containsKey(key);
}
@SuppressWarnings("unchecked")
@Override public Collection get(@Nullable Object key) {
Collection collection = LinkedListMultimap.this.get((K) key);
return collection.isEmpty() ? null : collection;
}
@Override public Collection remove(@Nullable Object key) {
Collection collection = removeAll(key);
return collection.isEmpty() ? null : collection;
}
};
}
return result;
}
// Comparison and hashing
/**
* Compares the specified object to this multimap for equality.
*
* Two {@code ListMultimap} instances are equal if, for each key, they
* contain the same values in the same order. If the value orderings disagree,
* the multimaps will not be considered equal.
*/
@Override public boolean equals(@Nullable Object other) {
if (other == this) {
return true;
}
if (other instanceof Multimap) {
Multimap, ?> that = (Multimap, ?>) other;
return this.asMap().equals(that.asMap());
}
return false;
}
/**
* Returns the hash code for this multimap.
*
*
The hash code of a multimap is defined as the hash code of the map view,
* as returned by {@link Multimap#asMap}.
*/
@Override public int hashCode() {
return asMap().hashCode();
}
/**
* Returns a string representation of the multimap, generated by calling
* {@code toString} on the map returned by {@link Multimap#asMap}.
*
* @return a string representation of the multimap
*/
@Override public String toString() {
return asMap().toString();
}
/**
* @serialData the number of distinct keys, and then for each distinct key:
* the first key, the number of values for that key, and the key's values,
* followed by successive keys and values from the entries() ordering
*/
private void writeObject(ObjectOutputStream stream) throws IOException {
stream.defaultWriteObject();
stream.writeInt(size());
for (Entry entry : entries()) {
stream.writeObject(entry.getKey());
stream.writeObject(entry.getValue());
}
}
private void readObject(ObjectInputStream stream)
throws IOException, ClassNotFoundException {
stream.defaultReadObject();
keyCount = LinkedHashMultiset.create();
keyToKeyHead = Maps.newHashMap();
keyToKeyTail = Maps.newHashMap();
int size = stream.readInt();
for (int i = 0; i < size; i++) {
@SuppressWarnings("unchecked") // reading data stored by writeObject
K key = (K) stream.readObject();
@SuppressWarnings("unchecked") // reading data stored by writeObject
V value = (V) stream.readObject();
put(key, value);
}
}
private static final long serialVersionUID = 0;
}