001/* 002 * Copyright (C) 2007 The Guava Authors 003 * 004 * Licensed under the Apache License, Version 2.0 (the "License"); 005 * you may not use this file except in compliance with the License. 006 * You may obtain a copy of the License at 007 * 008 * http://www.apache.org/licenses/LICENSE-2.0 009 * 010 * Unless required by applicable law or agreed to in writing, software 011 * distributed under the License is distributed on an "AS IS" BASIS, 012 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 013 * See the License for the specific language governing permissions and 014 * limitations under the License. 015 */ 016 017package com.google.common.collect; 018 019import static com.google.common.base.Preconditions.checkPositionIndex; 020import static com.google.common.base.Preconditions.checkState; 021import static java.util.Collections.unmodifiableList; 022import static java.util.Objects.requireNonNull; 023 024import com.google.common.annotations.GwtCompatible; 025import com.google.common.annotations.GwtIncompatible; 026import com.google.errorprone.annotations.CanIgnoreReturnValue; 027import com.google.j2objc.annotations.WeakOuter; 028import java.io.IOException; 029import java.io.ObjectInputStream; 030import java.io.ObjectOutputStream; 031import java.io.Serializable; 032import java.util.AbstractSequentialList; 033import java.util.Collection; 034import java.util.ConcurrentModificationException; 035import java.util.Iterator; 036import java.util.List; 037import java.util.ListIterator; 038import java.util.Map; 039import java.util.Map.Entry; 040import java.util.NoSuchElementException; 041import java.util.Set; 042import javax.annotation.CheckForNull; 043import org.checkerframework.checker.nullness.qual.Nullable; 044 045/** 046 * An implementation of {@code ListMultimap} that supports deterministic iteration order for both 047 * keys and values. The iteration order is preserved across non-distinct key values. For example, 048 * for the following multimap definition: 049 * 050 * <pre>{@code 051 * Multimap<K, V> multimap = LinkedListMultimap.create(); 052 * multimap.put(key1, foo); 053 * multimap.put(key2, bar); 054 * multimap.put(key1, baz); 055 * }</pre> 056 * 057 * ... the iteration order for {@link #keys()} is {@code [key1, key2, key1]}, and similarly for 058 * {@link #entries()}. Unlike {@link LinkedHashMultimap}, the iteration order is kept consistent 059 * between keys, entries and values. For example, calling: 060 * 061 * <pre>{@code 062 * multimap.remove(key1, foo); 063 * }</pre> 064 * 065 * <p>changes the entries iteration order to {@code [key2=bar, key1=baz]} and the key iteration 066 * order to {@code [key2, key1]}. The {@link #entries()} iterator returns mutable map entries, and 067 * {@link #replaceValues} attempts to preserve iteration order as much as possible. 068 * 069 * <p>The collections returned by {@link #keySet()} and {@link #asMap} iterate through the keys in 070 * the order they were first added to the multimap. Similarly, {@link #get}, {@link #removeAll}, and 071 * {@link #replaceValues} return collections that iterate through the values in the order they were 072 * added. The collections generated by {@link #entries()}, {@link #keys()}, and {@link #values} 073 * iterate across the key-value mappings in the order they were added to the multimap. 074 * 075 * <p>The {@link #values()} and {@link #entries()} methods both return a {@code List}, instead of 076 * the {@code Collection} specified by the {@link ListMultimap} interface. 077 * 078 * <p>The methods {@link #get}, {@link #keySet()}, {@link #keys()}, {@link #values}, {@link 079 * #entries()}, and {@link #asMap} return collections that are views of the multimap. If the 080 * multimap is modified while an iteration over any of those collections is in progress, except 081 * through the iterator's methods, the results of the iteration are undefined. 082 * 083 * <p>Keys and values may be null. All optional multimap methods are supported, and all returned 084 * views are modifiable. 085 * 086 * <p>This class is not threadsafe when any concurrent operations update the multimap. Concurrent 087 * read operations will work correctly. To allow concurrent update operations, wrap your multimap 088 * with a call to {@link Multimaps#synchronizedListMultimap}. 089 * 090 * <p>See the Guava User Guide article on <a href= 091 * "https://github.com/google/guava/wiki/NewCollectionTypesExplained#multimap"> {@code 092 * Multimap}</a>. 093 * 094 * @author Mike Bostock 095 * @since 2.0 096 */ 097@GwtCompatible(serializable = true, emulated = true) 098@ElementTypesAreNonnullByDefault 099public class LinkedListMultimap<K extends @Nullable Object, V extends @Nullable Object> 100 extends AbstractMultimap<K, V> implements ListMultimap<K, V>, Serializable { 101 /* 102 * Order is maintained using a linked list containing all key-value pairs. In 103 * addition, a series of disjoint linked lists of "siblings", each containing 104 * the values for a specific key, is used to implement {@link 105 * ValueForKeyIterator} in constant time. 106 */ 107 108 private static final class Node<K extends @Nullable Object, V extends @Nullable Object> 109 extends AbstractMapEntry<K, V> { 110 @ParametricNullness final K key; 111 @ParametricNullness V value; 112 @CheckForNull Node<K, V> next; // the next node (with any key) 113 @CheckForNull Node<K, V> previous; // the previous node (with any key) 114 @CheckForNull Node<K, V> nextSibling; // the next node with the same key 115 @CheckForNull Node<K, V> previousSibling; // the previous node with the same key 116 117 Node(@ParametricNullness K key, @ParametricNullness V value) { 118 this.key = key; 119 this.value = value; 120 } 121 122 @Override 123 @ParametricNullness 124 public K getKey() { 125 return key; 126 } 127 128 @Override 129 @ParametricNullness 130 public V getValue() { 131 return value; 132 } 133 134 @Override 135 @ParametricNullness 136 public V setValue(@ParametricNullness V newValue) { 137 V result = value; 138 this.value = newValue; 139 return result; 140 } 141 } 142 143 private static class KeyList<K extends @Nullable Object, V extends @Nullable Object> { 144 Node<K, V> head; 145 Node<K, V> tail; 146 int count; 147 148 KeyList(Node<K, V> firstNode) { 149 this.head = firstNode; 150 this.tail = firstNode; 151 firstNode.previousSibling = null; 152 firstNode.nextSibling = null; 153 this.count = 1; 154 } 155 } 156 157 @CheckForNull private transient Node<K, V> head; // the head for all keys 158 @CheckForNull private transient Node<K, V> tail; // the tail for all keys 159 private transient Map<K, KeyList<K, V>> keyToKeyList; 160 private transient int size; 161 162 /* 163 * Tracks modifications to keyToKeyList so that addition or removal of keys invalidates 164 * preexisting iterators. This does *not* track simple additions and removals of values 165 * that are not the first to be added or last to be removed for their key. 166 */ 167 private transient int modCount; 168 169 /** Creates a new, empty {@code LinkedListMultimap} with the default initial capacity. */ 170 public static <K extends @Nullable Object, V extends @Nullable Object> 171 LinkedListMultimap<K, V> create() { 172 return new LinkedListMultimap<>(); 173 } 174 175 /** 176 * Constructs an empty {@code LinkedListMultimap} with enough capacity to hold the specified 177 * number of keys without rehashing. 178 * 179 * @param expectedKeys the expected number of distinct keys 180 * @throws IllegalArgumentException if {@code expectedKeys} is negative 181 */ 182 public static <K extends @Nullable Object, V extends @Nullable Object> 183 LinkedListMultimap<K, V> create(int expectedKeys) { 184 return new LinkedListMultimap<>(expectedKeys); 185 } 186 187 /** 188 * Constructs a {@code LinkedListMultimap} with the same mappings as the specified {@code 189 * Multimap}. The new multimap has the same {@link Multimap#entries()} iteration order as the 190 * input multimap. 191 * 192 * @param multimap the multimap whose contents are copied to this multimap 193 */ 194 public static <K extends @Nullable Object, V extends @Nullable Object> 195 LinkedListMultimap<K, V> create(Multimap<? extends K, ? extends V> multimap) { 196 return new LinkedListMultimap<>(multimap); 197 } 198 199 LinkedListMultimap() { 200 this(12); 201 } 202 203 private LinkedListMultimap(int expectedKeys) { 204 keyToKeyList = Platform.newHashMapWithExpectedSize(expectedKeys); 205 } 206 207 private LinkedListMultimap(Multimap<? extends K, ? extends V> multimap) { 208 this(multimap.keySet().size()); 209 putAll(multimap); 210 } 211 212 /** 213 * Adds a new node for the specified key-value pair before the specified {@code nextSibling} 214 * element, or at the end of the list if {@code nextSibling} is null. Note: if {@code nextSibling} 215 * is specified, it MUST be for an node for the same {@code key}! 216 */ 217 @CanIgnoreReturnValue 218 private Node<K, V> addNode( 219 @ParametricNullness K key, 220 @ParametricNullness V value, 221 @CheckForNull Node<K, V> nextSibling) { 222 Node<K, V> node = new Node<>(key, value); 223 if (head == null) { // empty list 224 head = tail = node; 225 keyToKeyList.put(key, new KeyList<K, V>(node)); 226 modCount++; 227 } else if (nextSibling == null) { // non-empty list, add to tail 228 // requireNonNull is safe because the list is non-empty. 229 requireNonNull(tail).next = node; 230 node.previous = tail; 231 tail = node; 232 KeyList<K, V> keyList = keyToKeyList.get(key); 233 if (keyList == null) { 234 keyToKeyList.put(key, keyList = new KeyList<>(node)); 235 modCount++; 236 } else { 237 keyList.count++; 238 Node<K, V> keyTail = keyList.tail; 239 keyTail.nextSibling = node; 240 node.previousSibling = keyTail; 241 keyList.tail = node; 242 } 243 } else { // non-empty list, insert before nextSibling 244 /* 245 * requireNonNull is safe as long as callers pass a nextSibling that (a) has the same key and 246 * (b) is present in the multimap. (And they do, except maybe in case of concurrent 247 * modification, in which case all bets are off.) 248 */ 249 KeyList<K, V> keyList = requireNonNull(keyToKeyList.get(key)); 250 keyList.count++; 251 node.previous = nextSibling.previous; 252 node.previousSibling = nextSibling.previousSibling; 253 node.next = nextSibling; 254 node.nextSibling = nextSibling; 255 if (nextSibling.previousSibling == null) { // nextSibling was key head 256 keyList.head = node; 257 } else { 258 nextSibling.previousSibling.nextSibling = node; 259 } 260 if (nextSibling.previous == null) { // nextSibling was head 261 head = node; 262 } else { 263 nextSibling.previous.next = node; 264 } 265 nextSibling.previous = node; 266 nextSibling.previousSibling = node; 267 } 268 size++; 269 return node; 270 } 271 272 /** 273 * Removes the specified node from the linked list. This method is only intended to be used from 274 * the {@code Iterator} classes. See also {@link LinkedListMultimap#removeAllNodes(Object)}. 275 */ 276 private void removeNode(Node<K, V> node) { 277 if (node.previous != null) { 278 node.previous.next = node.next; 279 } else { // node was head 280 head = node.next; 281 } 282 if (node.next != null) { 283 node.next.previous = node.previous; 284 } else { // node was tail 285 tail = node.previous; 286 } 287 if (node.previousSibling == null && node.nextSibling == null) { 288 /* 289 * requireNonNull is safe as long as we call removeNode only for nodes that are still in the 290 * Multimap. This should be the case (except in case of concurrent modification, when all bets 291 * are off). 292 */ 293 KeyList<K, V> keyList = requireNonNull(keyToKeyList.remove(node.key)); 294 keyList.count = 0; 295 modCount++; 296 } else { 297 // requireNonNull is safe (under the conditions listed in the comment in the branch above). 298 KeyList<K, V> keyList = requireNonNull(keyToKeyList.get(node.key)); 299 keyList.count--; 300 301 if (node.previousSibling == null) { 302 // requireNonNull is safe because we checked that not *both* siblings were null. 303 keyList.head = requireNonNull(node.nextSibling); 304 } else { 305 node.previousSibling.nextSibling = node.nextSibling; 306 } 307 308 if (node.nextSibling == null) { 309 // requireNonNull is safe because we checked that not *both* siblings were null. 310 keyList.tail = requireNonNull(node.previousSibling); 311 } else { 312 node.nextSibling.previousSibling = node.previousSibling; 313 } 314 } 315 size--; 316 } 317 318 /** Removes all nodes for the specified key. */ 319 private void removeAllNodes(@ParametricNullness K key) { 320 Iterators.clear(new ValueForKeyIterator(key)); 321 } 322 323 /** An {@code Iterator} over all nodes. */ 324 private class NodeIterator implements ListIterator<Entry<K, V>> { 325 int nextIndex; 326 @CheckForNull Node<K, V> next; 327 @CheckForNull Node<K, V> current; 328 @CheckForNull Node<K, V> previous; 329 int expectedModCount = modCount; 330 331 NodeIterator(int index) { 332 int size = size(); 333 checkPositionIndex(index, size); 334 if (index >= (size / 2)) { 335 previous = tail; 336 nextIndex = size; 337 while (index++ < size) { 338 previous(); 339 } 340 } else { 341 next = head; 342 while (index-- > 0) { 343 next(); 344 } 345 } 346 current = null; 347 } 348 349 private void checkForConcurrentModification() { 350 if (modCount != expectedModCount) { 351 throw new ConcurrentModificationException(); 352 } 353 } 354 355 @Override 356 public boolean hasNext() { 357 checkForConcurrentModification(); 358 return next != null; 359 } 360 361 @CanIgnoreReturnValue 362 @Override 363 public Node<K, V> next() { 364 checkForConcurrentModification(); 365 if (next == null) { 366 throw new NoSuchElementException(); 367 } 368 previous = current = next; 369 next = next.next; 370 nextIndex++; 371 return current; 372 } 373 374 @Override 375 public void remove() { 376 checkForConcurrentModification(); 377 checkState(current != null, "no calls to next() since the last call to remove()"); 378 if (current != next) { // after call to next() 379 previous = current.previous; 380 nextIndex--; 381 } else { // after call to previous() 382 next = current.next; 383 } 384 removeNode(current); 385 current = null; 386 expectedModCount = modCount; 387 } 388 389 @Override 390 public boolean hasPrevious() { 391 checkForConcurrentModification(); 392 return previous != null; 393 } 394 395 @CanIgnoreReturnValue 396 @Override 397 public Node<K, V> previous() { 398 checkForConcurrentModification(); 399 if (previous == null) { 400 throw new NoSuchElementException(); 401 } 402 next = current = previous; 403 previous = previous.previous; 404 nextIndex--; 405 return current; 406 } 407 408 @Override 409 public int nextIndex() { 410 return nextIndex; 411 } 412 413 @Override 414 public int previousIndex() { 415 return nextIndex - 1; 416 } 417 418 @Override 419 public void set(Entry<K, V> e) { 420 throw new UnsupportedOperationException(); 421 } 422 423 @Override 424 public void add(Entry<K, V> e) { 425 throw new UnsupportedOperationException(); 426 } 427 428 void setValue(@ParametricNullness V value) { 429 checkState(current != null); 430 current.value = value; 431 } 432 } 433 434 /** An {@code Iterator} over distinct keys in key head order. */ 435 private class DistinctKeyIterator implements Iterator<K> { 436 final Set<K> seenKeys = Sets.<K>newHashSetWithExpectedSize(keySet().size()); 437 @CheckForNull Node<K, V> next = head; 438 @CheckForNull Node<K, V> current; 439 int expectedModCount = modCount; 440 441 private void checkForConcurrentModification() { 442 if (modCount != expectedModCount) { 443 throw new ConcurrentModificationException(); 444 } 445 } 446 447 @Override 448 public boolean hasNext() { 449 checkForConcurrentModification(); 450 return next != null; 451 } 452 453 @Override 454 @ParametricNullness 455 public K next() { 456 checkForConcurrentModification(); 457 if (next == null) { 458 throw new NoSuchElementException(); 459 } 460 current = next; 461 seenKeys.add(current.key); 462 do { // skip ahead to next unseen key 463 next = next.next; 464 } while ((next != null) && !seenKeys.add(next.key)); 465 return current.key; 466 } 467 468 @Override 469 public void remove() { 470 checkForConcurrentModification(); 471 checkState(current != null, "no calls to next() since the last call to remove()"); 472 removeAllNodes(current.key); 473 current = null; 474 expectedModCount = modCount; 475 } 476 } 477 478 /** A {@code ListIterator} over values for a specified key. */ 479 private class ValueForKeyIterator implements ListIterator<V> { 480 @ParametricNullness final K key; 481 int nextIndex; 482 @CheckForNull Node<K, V> next; 483 @CheckForNull Node<K, V> current; 484 @CheckForNull Node<K, V> previous; 485 486 /** Constructs a new iterator over all values for the specified key. */ 487 ValueForKeyIterator(@ParametricNullness K key) { 488 this.key = key; 489 KeyList<K, V> keyList = keyToKeyList.get(key); 490 next = (keyList == null) ? null : keyList.head; 491 } 492 493 /** 494 * Constructs a new iterator over all values for the specified key starting at the specified 495 * index. This constructor is optimized so that it starts at either the head or the tail, 496 * depending on which is closer to the specified index. This allows adds to the tail to be done 497 * in constant time. 498 * 499 * @throws IndexOutOfBoundsException if index is invalid 500 */ 501 public ValueForKeyIterator(@ParametricNullness K key, int index) { 502 KeyList<K, V> keyList = keyToKeyList.get(key); 503 int size = (keyList == null) ? 0 : keyList.count; 504 checkPositionIndex(index, size); 505 if (index >= (size / 2)) { 506 previous = (keyList == null) ? null : keyList.tail; 507 nextIndex = size; 508 while (index++ < size) { 509 previous(); 510 } 511 } else { 512 next = (keyList == null) ? null : keyList.head; 513 while (index-- > 0) { 514 next(); 515 } 516 } 517 this.key = key; 518 current = null; 519 } 520 521 @Override 522 public boolean hasNext() { 523 return next != null; 524 } 525 526 @CanIgnoreReturnValue 527 @Override 528 @ParametricNullness 529 public V next() { 530 if (next == null) { 531 throw new NoSuchElementException(); 532 } 533 previous = current = next; 534 next = next.nextSibling; 535 nextIndex++; 536 return current.value; 537 } 538 539 @Override 540 public boolean hasPrevious() { 541 return previous != null; 542 } 543 544 @CanIgnoreReturnValue 545 @Override 546 @ParametricNullness 547 public V previous() { 548 if (previous == null) { 549 throw new NoSuchElementException(); 550 } 551 next = current = previous; 552 previous = previous.previousSibling; 553 nextIndex--; 554 return current.value; 555 } 556 557 @Override 558 public int nextIndex() { 559 return nextIndex; 560 } 561 562 @Override 563 public int previousIndex() { 564 return nextIndex - 1; 565 } 566 567 @Override 568 public void remove() { 569 checkState(current != null, "no calls to next() since the last call to remove()"); 570 if (current != next) { // after call to next() 571 previous = current.previousSibling; 572 nextIndex--; 573 } else { // after call to previous() 574 next = current.nextSibling; 575 } 576 removeNode(current); 577 current = null; 578 } 579 580 @Override 581 public void set(@ParametricNullness V value) { 582 checkState(current != null); 583 current.value = value; 584 } 585 586 @Override 587 public void add(@ParametricNullness V value) { 588 previous = addNode(key, value, next); 589 nextIndex++; 590 current = null; 591 } 592 } 593 594 // Query Operations 595 596 @Override 597 public int size() { 598 return size; 599 } 600 601 @Override 602 public boolean isEmpty() { 603 return head == null; 604 } 605 606 @Override 607 public boolean containsKey(@CheckForNull Object key) { 608 return keyToKeyList.containsKey(key); 609 } 610 611 @Override 612 public boolean containsValue(@CheckForNull Object value) { 613 return values().contains(value); 614 } 615 616 // Modification Operations 617 618 /** 619 * Stores a key-value pair in the multimap. 620 * 621 * @param key key to store in the multimap 622 * @param value value to store in the multimap 623 * @return {@code true} always 624 */ 625 @CanIgnoreReturnValue 626 @Override 627 public boolean put(@ParametricNullness K key, @ParametricNullness V value) { 628 addNode(key, value, null); 629 return true; 630 } 631 632 // Bulk Operations 633 634 /** 635 * {@inheritDoc} 636 * 637 * <p>If any entries for the specified {@code key} already exist in the multimap, their values are 638 * changed in-place without affecting the iteration order. 639 * 640 * <p>The returned list is immutable and implements {@link java.util.RandomAccess}. 641 */ 642 @CanIgnoreReturnValue 643 @Override 644 public List<V> replaceValues(@ParametricNullness K key, Iterable<? extends V> values) { 645 List<V> oldValues = getCopy(key); 646 ListIterator<V> keyValues = new ValueForKeyIterator(key); 647 Iterator<? extends V> newValues = values.iterator(); 648 649 // Replace existing values, if any. 650 while (keyValues.hasNext() && newValues.hasNext()) { 651 keyValues.next(); 652 keyValues.set(newValues.next()); 653 } 654 655 // Remove remaining old values, if any. 656 while (keyValues.hasNext()) { 657 keyValues.next(); 658 keyValues.remove(); 659 } 660 661 // Add remaining new values, if any. 662 while (newValues.hasNext()) { 663 keyValues.add(newValues.next()); 664 } 665 666 return oldValues; 667 } 668 669 private List<V> getCopy(@ParametricNullness K key) { 670 return unmodifiableList(Lists.newArrayList(new ValueForKeyIterator(key))); 671 } 672 673 /** 674 * {@inheritDoc} 675 * 676 * <p>The returned list is immutable and implements {@link java.util.RandomAccess}. 677 */ 678 @CanIgnoreReturnValue 679 @Override 680 public List<V> removeAll(@Nullable Object key) { 681 /* 682 * Safe because all we do is remove values for the key, not add them. (If we wanted to make sure 683 * to call getCopy and removeAllNodes only with a true K, then we could check containsKey first. 684 * But that check wouldn't eliminate the warnings.) 685 */ 686 @SuppressWarnings({"unchecked", "nullness"}) 687 K castKey = (K) key; 688 List<V> oldValues = getCopy(castKey); 689 removeAllNodes(castKey); 690 return oldValues; 691 } 692 693 @Override 694 public void clear() { 695 head = null; 696 tail = null; 697 keyToKeyList.clear(); 698 size = 0; 699 modCount++; 700 } 701 702 // Views 703 704 /** 705 * {@inheritDoc} 706 * 707 * <p>If the multimap is modified while an iteration over the list is in progress (except through 708 * the iterator's own {@code add}, {@code set} or {@code remove} operations) the results of the 709 * iteration are undefined. 710 * 711 * <p>The returned list is not serializable and does not have random access. 712 */ 713 @Override 714 public List<V> get(@ParametricNullness final K key) { 715 return new AbstractSequentialList<V>() { 716 @Override 717 public int size() { 718 KeyList<K, V> keyList = keyToKeyList.get(key); 719 return (keyList == null) ? 0 : keyList.count; 720 } 721 722 @Override 723 public ListIterator<V> listIterator(int index) { 724 return new ValueForKeyIterator(key, index); 725 } 726 }; 727 } 728 729 @Override 730 Set<K> createKeySet() { 731 @WeakOuter 732 class KeySetImpl extends Sets.ImprovedAbstractSet<K> { 733 @Override 734 public int size() { 735 return keyToKeyList.size(); 736 } 737 738 @Override 739 public Iterator<K> iterator() { 740 return new DistinctKeyIterator(); 741 } 742 743 @Override 744 public boolean contains(@CheckForNull Object key) { // for performance 745 return containsKey(key); 746 } 747 748 @Override 749 public boolean remove(@CheckForNull Object o) { // for performance 750 return !LinkedListMultimap.this.removeAll(o).isEmpty(); 751 } 752 } 753 return new KeySetImpl(); 754 } 755 756 @Override 757 Multiset<K> createKeys() { 758 return new Multimaps.Keys<K, V>(this); 759 } 760 761 /** 762 * {@inheritDoc} 763 * 764 * <p>The iterator generated by the returned collection traverses the values in the order they 765 * were added to the multimap. Because the values may have duplicates and follow the insertion 766 * ordering, this method returns a {@link List}, instead of the {@link Collection} specified in 767 * the {@link ListMultimap} interface. 768 */ 769 @Override 770 public List<V> values() { 771 return (List<V>) super.values(); 772 } 773 774 @Override 775 List<V> createValues() { 776 @WeakOuter 777 class ValuesImpl extends AbstractSequentialList<V> { 778 @Override 779 public int size() { 780 return size; 781 } 782 783 @Override 784 public ListIterator<V> listIterator(int index) { 785 final NodeIterator nodeItr = new NodeIterator(index); 786 return new TransformedListIterator<Entry<K, V>, V>(nodeItr) { 787 @Override 788 @ParametricNullness 789 V transform(Entry<K, V> entry) { 790 return entry.getValue(); 791 } 792 793 @Override 794 public void set(@ParametricNullness V value) { 795 nodeItr.setValue(value); 796 } 797 }; 798 } 799 } 800 return new ValuesImpl(); 801 } 802 803 /** 804 * {@inheritDoc} 805 * 806 * <p>The iterator generated by the returned collection traverses the entries in the order they 807 * were added to the multimap. Because the entries may have duplicates and follow the insertion 808 * ordering, this method returns a {@link List}, instead of the {@link Collection} specified in 809 * the {@link ListMultimap} interface. 810 * 811 * <p>An entry's {@link Entry#getKey} method always returns the same key, regardless of what 812 * happens subsequently. As long as the corresponding key-value mapping is not removed from the 813 * multimap, {@link Entry#getValue} returns the value from the multimap, which may change over 814 * time, and {@link Entry#setValue} modifies that value. Removing the mapping from the multimap 815 * does not alter the value returned by {@code getValue()}, though a subsequent {@code setValue()} 816 * call won't update the multimap but will lead to a revised value being returned by {@code 817 * getValue()}. 818 */ 819 @Override 820 public List<Entry<K, V>> entries() { 821 return (List<Entry<K, V>>) super.entries(); 822 } 823 824 @Override 825 List<Entry<K, V>> createEntries() { 826 @WeakOuter 827 class EntriesImpl extends AbstractSequentialList<Entry<K, V>> { 828 @Override 829 public int size() { 830 return size; 831 } 832 833 @Override 834 public ListIterator<Entry<K, V>> listIterator(int index) { 835 return new NodeIterator(index); 836 } 837 } 838 return new EntriesImpl(); 839 } 840 841 @Override 842 Iterator<Entry<K, V>> entryIterator() { 843 throw new AssertionError("should never be called"); 844 } 845 846 @Override 847 Map<K, Collection<V>> createAsMap() { 848 return new Multimaps.AsMap<>(this); 849 } 850 851 /** 852 * @serialData the number of distinct keys, and then for each distinct key: the first key, the 853 * number of values for that key, and the key's values, followed by successive keys and values 854 * from the entries() ordering 855 */ 856 @GwtIncompatible // java.io.ObjectOutputStream 857 private void writeObject(ObjectOutputStream stream) throws IOException { 858 stream.defaultWriteObject(); 859 stream.writeInt(size()); 860 for (Entry<K, V> entry : entries()) { 861 stream.writeObject(entry.getKey()); 862 stream.writeObject(entry.getValue()); 863 } 864 } 865 866 @GwtIncompatible // java.io.ObjectInputStream 867 private void readObject(ObjectInputStream stream) throws IOException, ClassNotFoundException { 868 stream.defaultReadObject(); 869 keyToKeyList = CompactLinkedHashMap.create(); 870 int size = stream.readInt(); 871 for (int i = 0; i < size; i++) { 872 @SuppressWarnings("unchecked") // reading data stored by writeObject 873 K key = (K) stream.readObject(); 874 @SuppressWarnings("unchecked") // reading data stored by writeObject 875 V value = (V) stream.readObject(); 876 put(key, value); 877 } 878 } 879 880 @GwtIncompatible // java serialization not supported 881 private static final long serialVersionUID = 0; 882}