@GwtCompatible(emulated=true) public final class Multimaps extends Object
Multimap.
See the Guava User Guide article on Multimaps.
| Modifier and Type | Method and Description |
|---|---|
static <K |
asMap(ListMultimap
|
static <K |
asMap(Multimap
Returns
multimap.asMap().
|
static <K |
asMap(SetMultimap
|
static <K |
asMap(SortedSetMultimap
Returns
multimap.asMap(), with its type corrected from
Map<K, Collection<V>> to
Map<K, SortedSet<V>>.
|
static <K |
filterEntries(Multimap
Returns a multimap containing the mappings in
unfiltered that satisfy a predicate.
|
static <K |
filterEntries(SetMultimap
Returns a multimap containing the mappings in
unfiltered that satisfy a predicate.
|
static <K |
filterKeys(ListMultimap
Returns a multimap containing the mappings in
unfiltered whose keys satisfy a predicate.
|
static <K |
filterKeys(Multimap
Returns a multimap containing the mappings in
unfiltered whose keys satisfy a predicate.
|
static <K |
filterKeys(SetMultimap
Returns a multimap containing the mappings in
unfiltered whose keys satisfy a predicate.
|
static <K |
filterValues(Multimap
Returns a multimap containing the mappings in
unfiltered whose values satisfy a predicate.
|
static <K |
filterValues(SetMultimap
Returns a multimap containing the mappings in
unfiltered whose values satisfy a predicate.
|
static <K |
forMap(Map
Returns a multimap view of the specified map.
|
static <K |
index(Iterable
Creates an index
ImmutableListMultimap that contains the results of applying a specified function to each item in an
Iterable of values.
|
static <K |
index(Iterator
Creates an index
ImmutableListMultimap that contains the results of applying a specified function to each item in an
Iterator of values.
|
static <K |
invertFrom(Multimap
Copies each key-value mapping in
source into
dest, with its key and value reversed.
|
static <K |
newListMultimap(Map
Creates a new
ListMultimap that uses the provided map and factory.
|
static <K |
newMultimap(Map
Creates a new
Multimap backed by
map, whose internal value collections are generated by
factory.
|
static <K |
newSetMultimap(Map
Creates a new
SetMultimap that uses the provided map and factory.
|
static <K |
newSortedSetMultimap(Map
Creates a new
SortedSetMultimap that uses the provided map and factory.
|
static <K |
synchronizedListMultimap(ListMultimap
Returns a synchronized (thread-safe)
ListMultimap backed by the specified multimap.
|
static <K |
synchronizedMultimap(Multimap
Returns a synchronized (thread-safe) multimap backed by the specified multimap.
|
static <K |
synchronizedSetMultimap(SetMultimap
Returns a synchronized (thread-safe)
SetMultimap backed by the specified multimap.
|
static <K |
synchronizedSortedSetMultimap(SortedSetMultimap
Returns a synchronized (thread-safe)
SortedSetMultimap backed by the specified multimap.
|
static <K |
transformEntries(ListMultimap
Returns a view of a
ListMultimap whose values are derived from the original multimap's entries.
|
static <K |
transformEntries(Multimap
Returns a view of a multimap whose values are derived from the original multimap's entries.
|
static <K |
transformValues(ListMultimap
Returns a view of a
ListMultimap where each value is transformed by a function.
|
static <K |
transformValues(Multimap
Returns a view of a multimap where each value is transformed by a function.
|
static <K |
unmodifiableListMultimap(ImmutableListMultimap
Deprecated.
no need to use this
|
static <K |
unmodifiableListMultimap(ListMultimap
Returns an unmodifiable view of the specified
ListMultimap.
|
static <K |
unmodifiableMultimap(ImmutableMultimap
Deprecated.
no need to use this
|
static <K |
unmodifiableMultimap(Multimap
Returns an unmodifiable view of the specified multimap.
|
static <K |
unmodifiableSetMultimap(ImmutableSetMultimap
Deprecated.
no need to use this
|
static <K |
unmodifiableSetMultimap(SetMultimap
Returns an unmodifiable view of the specified
SetMultimap.
|
static <K |
unmodifiableSortedSetMultimap(SortedSetMultimap
Returns an unmodifiable view of the specified
SortedSetMultimap.
|
public static <K,V> Multimap <K ,V> newMultimap(Map <K ,Collection <V>> map, Supplier <? extends Collection <V>> factory)
Multimap backed by
map, whose internal value collections are generated by
factory.
Warning: do not use this method when the collections returned by
factory implement either
List or
Set! Use the more specific method
newListMultimap(java.util.Map<K, java.util.Collection<V>>, com.google.common.base.Supplier<? extends java.util.List<V>>),
newSetMultimap(java.util.Map<K, java.util.Collection<V>>, com.google.common.base.Supplier<? extends java.util.Set<V>>) or
newSortedSetMultimap(java.util.Map<K, java.util.Collection<V>>, com.google.common.base.Supplier<? extends java.util.SortedSet<V>>) instead, to avoid very surprising behavior from
Multimap.equals(java.lang.Object) .
The factory-generated and map classes determine the multimap iteration order. They also specify the behavior of the equals, hashCode, and toString methods for the multimap and its returned views. However, the multimap's get method returns instances of a different class than factory.get() does.
The multimap is serializable if map, factory, the collections generated by factory, and the multimap contents are all serializable.
The multimap is not threadsafe when any concurrent operations update the multimap, even if map and the instances generated by factory are. Concurrent read operations will work correctly. To allow concurrent update operations, wrap the multimap with a call to synchronizedMultimap(com.google.common.collect.Multimap<K, V>).
Call this method only when the simpler methods ArrayListMultimap, HashMultimap, LinkedHashMultimap, LinkedListMultimap, TreeMultimap, and TreeMultimap won't suffice.
Note: the multimap assumes complete ownership over of map and the collections returned by factory. Those objects should not be manually updated and they should not use soft, weak, or phantom references.
map - place to store the mapping from each key to its corresponding values
factory - supplier of new, empty collections that will each hold all values for a given key
IllegalArgumentException - if
map is not empty
public static <K,V> ListMultimap <K ,V> newListMultimap(Map <K ,Collection <V>> map, Supplier <? extends List <V>> factory)
ListMultimap that uses the provided map and factory. It can generate a multimap based on arbitrary
Map and
List classes.
The factory-generated and map classes determine the multimap iteration order. They also specify the behavior of the equals, hashCode, and toString methods for the multimap and its returned views. The multimap's get, removeAll, and replaceValues methods return RandomAccess lists if the factory does. However, the multimap's get method returns instances of a different class than does factory.get().
The multimap is serializable if map, factory, the lists generated by factory, and the multimap contents are all serializable.
The multimap is not threadsafe when any concurrent operations update the multimap, even if map and the instances generated by factory are. Concurrent read operations will work correctly. To allow concurrent update operations, wrap the multimap with a call to synchronizedListMultimap(com.google.common.collect.ListMultimap<K, V>).
Call this method only when the simpler methods ArrayListMultimap and LinkedListMultimap won't suffice.
Note: the multimap assumes complete ownership over of map and the lists returned by factory. Those objects should not be manually updated, they should be empty when provided, and they should not use soft, weak, or phantom references.
map - place to store the mapping from each key to its corresponding values
factory - supplier of new, empty lists that will each hold all values for a given key
IllegalArgumentException - if
map is not empty
public static <K,V> SetMultimap <K ,V> newSetMultimap(Map <K ,Collection <V>> map, Supplier <? extends Set <V>> factory)
SetMultimap that uses the provided map and factory. It can generate a multimap based on arbitrary
Map and
Set classes.
The factory-generated and map classes determine the multimap iteration order. They also specify the behavior of the equals, hashCode, and toString methods for the multimap and its returned views. However, the multimap's get method returns instances of a different class than factory.get() does.
The multimap is serializable if map, factory, the sets generated by factory, and the multimap contents are all serializable.
The multimap is not threadsafe when any concurrent operations update the multimap, even if map and the instances generated by factory are. Concurrent read operations will work correctly. To allow concurrent update operations, wrap the multimap with a call to synchronizedSetMultimap(com.google.common.collect.SetMultimap<K, V>).
Call this method only when the simpler methods HashMultimap, LinkedHashMultimap, TreeMultimap, and TreeMultimap won't suffice.
Note: the multimap assumes complete ownership over of map and the sets returned by factory. Those objects should not be manually updated and they should not use soft, weak, or phantom references.
map - place to store the mapping from each key to its corresponding values
factory - supplier of new, empty sets that will each hold all values for a given key
IllegalArgumentException - if
map is not empty
public static <K,V> SortedSetMultimap <K ,V> newSortedSetMultimap(Map <K ,Collection <V>> map, Supplier <? extends SortedSet <V>> factory)
SortedSetMultimap that uses the provided map and factory. It can generate a multimap based on arbitrary
Map and
SortedSet classes.
The factory-generated and map classes determine the multimap iteration order. They also specify the behavior of the equals, hashCode, and toString methods for the multimap and its returned views. However, the multimap's get method returns instances of a different class than factory.get() does.
The multimap is serializable if map, factory, the sets generated by factory, and the multimap contents are all serializable.
The multimap is not threadsafe when any concurrent operations update the multimap, even if map and the instances generated by factory are. Concurrent read operations will work correctly. To allow concurrent update operations, wrap the multimap with a call to synchronizedSortedSetMultimap(com.google.common.collect.SortedSetMultimap<K, V>).
Call this method only when the simpler methods TreeMultimap and TreeMultimap won't suffice.
Note: the multimap assumes complete ownership over of map and the sets returned by factory. Those objects should not be manually updated and they should not use soft, weak, or phantom references.
map - place to store the mapping from each key to its corresponding values
factory - supplier of new, empty sorted sets that will each hold all values for a given key
IllegalArgumentException - if
map is not empty
public static <K,V ,M extends Multimap <K ,V>> M invertFrom(Multimap <? extends V ,? extends K> source, M dest)
source into
dest, with its key and value reversed.
If source is an ImmutableMultimap, consider using ImmutableMultimap instead.
source - any multimap
dest - the multimap to copy into; usually empty
dest
public static <K,V> Multimap <K ,V> synchronizedMultimap(Multimap <K ,V> multimap)
It is imperative that the user manually synchronize on the returned multimap when accessing any of its collection views:
Multimap<K, V> multimap = Multimaps.synchronizedMultimap( HashMultimap.<K, V>create()); ... Collection<V> values = multimap.get(key); // Needn't be in synchronized block ... synchronized (multimap) { // Synchronizing on multimap, not values! Iterator<V> i = values.iterator(); // Must be in synchronized block while (i.hasNext()) { foo(i.next()); } }
Failure to follow this advice may result in non-deterministic behavior.
Note that the generated multimap's Multimap and Multimap methods return collections that aren't synchronized.
The returned multimap will be serializable if the specified multimap is serializable.
multimap - the multimap to be wrapped in a synchronized view
public static <K,V> Multimap <K ,V> unmodifiableMultimap(Multimap <K ,V> delegate)
UnsupportedOperationException.
Note that the generated multimap's Multimap and Multimap methods return collections that are modifiable.
The returned multimap will be serializable if the specified multimap is serializable.
delegate - the multimap for which an unmodifiable view is to be returned
@Deprecated public static <K,V> Multimap <K ,V> unmodifiableMultimap(ImmutableMultimap <K ,V> delegate)
public static <K,V> SetMultimap <K ,V> synchronizedSetMultimap(SetMultimap <K ,V> multimap)
SetMultimap backed by the specified multimap.
You must follow the warnings described in synchronizedMultimap(com.google.common.collect.Multimap<K, V>).
The returned multimap will be serializable if the specified multimap is serializable.
multimap - the multimap to be wrapped
public static <K,V> SetMultimap <K ,V> unmodifiableSetMultimap(SetMultimap <K ,V> delegate)
SetMultimap. Query operations on the returned multimap "read through" to the specified multimap, and attempts to modify the returned multimap, either directly or through the multimap's views, result in an
UnsupportedOperationException.
Note that the generated multimap's Multimap and Multimap methods return collections that are modifiable.
The returned multimap will be serializable if the specified multimap is serializable.
delegate - the multimap for which an unmodifiable view is to be returned
@Deprecated public static <K,V> SetMultimap <K ,V> unmodifiableSetMultimap(ImmutableSetMultimap <K ,V> delegate)
public static <K,V> SortedSetMultimap <K ,V> synchronizedSortedSetMultimap(SortedSetMultimap <K ,V> multimap)
SortedSetMultimap backed by the specified multimap.
You must follow the warnings described in synchronizedMultimap(com.google.common.collect.Multimap<K, V>).
The returned multimap will be serializable if the specified multimap is serializable.
multimap - the multimap to be wrapped
public static <K,V> SortedSetMultimap <K ,V> unmodifiableSortedSetMultimap(SortedSetMultimap <K ,V> delegate)
SortedSetMultimap. Query operations on the returned multimap "read through" to the specified multimap, and attempts to modify the returned multimap, either directly or through the multimap's views, result in an
UnsupportedOperationException.
Note that the generated multimap's Multimap and Multimap methods return collections that are modifiable.
The returned multimap will be serializable if the specified multimap is serializable.
delegate - the multimap for which an unmodifiable view is to be returned
public static <K,V> ListMultimap <K ,V> synchronizedListMultimap(ListMultimap <K ,V> multimap)
ListMultimap backed by the specified multimap.
You must follow the warnings described in synchronizedMultimap(com.google.common.collect.Multimap<K, V>).
multimap - the multimap to be wrapped
public static <K,V> ListMultimap <K ,V> unmodifiableListMultimap(ListMultimap <K ,V> delegate)
ListMultimap. Query operations on the returned multimap "read through" to the specified multimap, and attempts to modify the returned multimap, either directly or through the multimap's views, result in an
UnsupportedOperationException.
Note that the generated multimap's Multimap and Multimap methods return collections that are modifiable.
The returned multimap will be serializable if the specified multimap is serializable.
delegate - the multimap for which an unmodifiable view is to be returned
@Deprecated public static <K,V> ListMultimap <K ,V> unmodifiableListMultimap(ImmutableListMultimap <K ,V> delegate)
@Beta public static <K,V> Map <K ,List <V>> asMap(ListMultimap <K ,V> multimap)
@Beta public static <K,V> Map <K ,Set <V>> asMap(SetMultimap <K ,V> multimap)
@Beta public static <K,V> Map <K ,SortedSet <V>> asMap(SortedSetMultimap <K ,V> multimap)
multimap.asMap(), with its type corrected from
Map<K, Collection<V>> to
Map<K, SortedSet<V>>.
@Beta public static <K,V> Map <K ,Collection <V>> asMap(Multimap <K ,V> multimap)
multimap.asMap(). This is provided for parity with the other more strongly-typed
asMap() implementations.
public static <K,V> SetMultimap <K ,V> forMap(Map <K ,V> map)
remove operation, or through the
setValue operation on a map entry returned by the iterator), the results of the iteration are undefined.
The multimap supports mapping removal, which removes the corresponding mapping from the map. It does not support any operations which might add mappings, such as put, putAll or replaceValues.
The returned multimap will be serializable if the specified map is serializable.
map - the backing map for the returned multimap view
public static <K,V1 ,V2> Multimap <K ,V2> transformValues(Multimap <K ,V1> fromMultimap, Function <? super V1 ,V2> function)
Multimap<String, Integer> multimap = ImmutableSetMultimap.of("a", 2, "b", -3, "b", -3, "a", 4, "c", 6); Function<Integer, String> square = new Function<Integer, String>() { public String apply(Integer in) { return Integer.toString(in * in); } }; Multimap<String, String> transformed = Multimaps.transformValues(multimap, square); System.out.println(transformed); ... prints
{a=[4, 16], b=[9, 9], c=[36]}.
Changes in the underlying multimap are reflected in this view. Conversely, this view supports removal operations, and these are reflected in the underlying multimap.
It's acceptable for the underlying multimap to contain null keys, and even null values provided that the function is capable of accepting null input. The transformed multimap might contain null values, if the function sometimes gives a null result.
The returned multimap is not thread-safe or serializable, even if the underlying multimap is. The equals and hashCode methods of the returned multimap are meaningless, since there is not a definition of equals or hashCode for general collections, and get() will return a general Collection as opposed to a List or a Set.
The function is applied lazily, invoked when needed. This is necessary for the returned multimap to be a view, but it means that the function will be applied many times for bulk operations like Multimap and Multimap.toString(). For this to perform well, function should be fast. To avoid lazy evaluation when the returned multimap doesn't need to be a view, copy the returned multimap into a new multimap of your choosing.
public static <K,V1 ,V2> Multimap <K ,V2> transformEntries(Multimap <K ,V1> fromMap, Maps .EntryTransformer <? super K ,? super V1 ,V2> transformer)
transformValues(com.google.common.collect.Multimap<K, V1>, com.google.common.base.Function<? super V1, V2>), this method's entry-transformation logic may depend on the key as well as the value.
All other properties of the transformed multimap, such as iteration order, are left intact. For example, the code:
SetMultimap<String, Integer> multimap = ImmutableSetMultimap.of("a", 1, "a", 4, "b", -6); EntryTransformer<String, Integer, String> transformer = new EntryTransformer<String, Integer, String>() { public String transformEntry(String key, Integer value) { return (value >= 0) ? key : "no" + key; } }; Multimap<String, String> transformed = Multimaps.transformEntries(multimap, transformer); System.out.println(transformed); ... prints
{a=[a, a], b=[nob]}.
Changes in the underlying multimap are reflected in this view. Conversely, this view supports removal operations, and these are reflected in the underlying multimap.
It's acceptable for the underlying multimap to contain null keys and null values provided that the transformer is capable of accepting null inputs. The transformed multimap might contain null values if the transformer sometimes gives a null result.
The returned multimap is not thread-safe or serializable, even if the underlying multimap is. The equals and hashCode methods of the returned multimap are meaningless, since there is not a definition of equals or hashCode for general collections, and get() will return a general Collection as opposed to a List or a Set.
The transformer is applied lazily, invoked when needed. This is necessary for the returned multimap to be a view, but it means that the transformer will be applied many times for bulk operations like Multimap and Object. For this to perform well, transformer should be fast. To avoid lazy evaluation when the returned multimap doesn't need to be a view, copy the returned multimap into a new multimap of your choosing.
Warning: This method assumes that for any instance k of EntryTransformer key type K, k.equals(k2) implies that k2 is also of type K. Using an EntryTransformer key type for which this may not hold, such as ArrayList, may risk a ClassCastException when calling methods on the transformed multimap.
public static <K,V1 ,V2> ListMultimap <K ,V2> transformValues(ListMultimap <K ,V1> fromMultimap, Function <? super V1 ,V2> function)
ListMultimap where each value is transformed by a function. All other properties of the multimap, such as iteration order, are left intact. For example, the code:
ListMultimap<String, Integer> multimap = ImmutableListMultimap.of("a", 4, "a", 16, "b", 9); Function<Integer, Double> sqrt = new Function<Integer, Double>() { public Double apply(Integer in) { return Math.sqrt((int) in); } }; ListMultimap<String, Double> transformed = Multimaps.transformValues(map, sqrt); System.out.println(transformed); ... prints
{a=[2.0, 4.0], b=[3.0]}.
Changes in the underlying multimap are reflected in this view. Conversely, this view supports removal operations, and these are reflected in the underlying multimap.
It's acceptable for the underlying multimap to contain null keys, and even null values provided that the function is capable of accepting null input. The transformed multimap might contain null values, if the function sometimes gives a null result.
The returned multimap is not thread-safe or serializable, even if the underlying multimap is.
The function is applied lazily, invoked when needed. This is necessary for the returned multimap to be a view, but it means that the function will be applied many times for bulk operations like Multimap and Multimap.toString(). For this to perform well, function should be fast. To avoid lazy evaluation when the returned multimap doesn't need to be a view, copy the returned multimap into a new multimap of your choosing.
public static <K,V1 ,V2> ListMultimap <K ,V2> transformEntries(ListMultimap <K ,V1> fromMap, Maps .EntryTransformer <? super K ,? super V1 ,V2> transformer)
ListMultimap whose values are derived from the original multimap's entries. In contrast to
transformValues(ListMultimap, Function), this method's entry-transformation logic may depend on the key as well as the value.
All other properties of the transformed multimap, such as iteration order, are left intact. For example, the code:
Multimap<String, Integer> multimap = ImmutableMultimap.of("a", 1, "a", 4, "b", 6); EntryTransformer<String, Integer, String> transformer = new EntryTransformer<String, Integer, String>() { public String transformEntry(String key, Integer value) { return key + value; } }; Multimap<String, String> transformed = Multimaps.transformEntries(multimap, transformer); System.out.println(transformed); ... prints
{"a"=["a1", "a4"], "b"=["b6"]}.
Changes in the underlying multimap are reflected in this view. Conversely, this view supports removal operations, and these are reflected in the underlying multimap.
It's acceptable for the underlying multimap to contain null keys and null values provided that the transformer is capable of accepting null inputs. The transformed multimap might contain null values if the transformer sometimes gives a null result.
The returned multimap is not thread-safe or serializable, even if the underlying multimap is.
The transformer is applied lazily, invoked when needed. This is necessary for the returned multimap to be a view, but it means that the transformer will be applied many times for bulk operations like Multimap and Object. For this to perform well, transformer should be fast. To avoid lazy evaluation when the returned multimap doesn't need to be a view, copy the returned multimap into a new multimap of your choosing.
Warning: This method assumes that for any instance k of EntryTransformer key type K, k.equals(k2) implies that k2 is also of type K. Using an EntryTransformer key type for which this may not hold, such as ArrayList, may risk a ClassCastException when calling methods on the transformed multimap.
public static <K,V> ImmutableListMultimap <K ,V> index(Iterable <V> values, Function <? super V ,K> keyFunction)
ImmutableListMultimap that contains the results of applying a specified function to each item in an
Iterable of values. Each value will be stored as a value in the resulting multimap, yielding a multimap with the same size as the input iterable. The key used to store that value in the multimap will be the result of calling the function on that value. The resulting multimap is created as an immutable snapshot. In the returned multimap, keys appear in the order they are first encountered, and the values corresponding to each key appear in the same order as they are encountered.
For example,
List<String> badGuys = Arrays.asList("Inky", "Blinky", "Pinky", "Pinky", "Clyde"); Function<String, Integer> stringLengthFunction = ...; Multimap<Integer, String> index = Multimaps.index(badGuys, stringLengthFunction); System.out.println(index);
prints
{4=[Inky], 6=[Blinky], 5=[Pinky, Pinky, Clyde]}
The returned multimap is serializable if its keys and values are all serializable.
values - the values to use when constructing the
ImmutableListMultimap
keyFunction - the function used to produce the key for each value
ImmutableListMultimap mapping the result of evaluating the function
keyFunction on each value in the input collection to that value
NullPointerException - if any of the following cases is true:
values is null keyFunction is null values is null keyFunction returns null for any element of values public static <K,V> ImmutableListMultimap <K ,V> index(Iterator <V> values, Function <? super V ,K> keyFunction)
ImmutableListMultimap that contains the results of applying a specified function to each item in an
Iterator of values. Each value will be stored as a value in the resulting multimap, yielding a multimap with the same size as the input iterator. The key used to store that value in the multimap will be the result of calling the function on that value. The resulting multimap is created as an immutable snapshot. In the returned multimap, keys appear in the order they are first encountered, and the values corresponding to each key appear in the same order as they are encountered.
For example,
List<String> badGuys = Arrays.asList("Inky", "Blinky", "Pinky", "Pinky", "Clyde"); Function<String, Integer> stringLengthFunction = ...; Multimap<Integer, String> index = Multimaps.index(badGuys.iterator(), stringLengthFunction); System.out.println(index);
prints
{4=[Inky], 6=[Blinky], 5=[Pinky, Pinky, Clyde]}
The returned multimap is serializable if its keys and values are all serializable.
values - the values to use when constructing the
ImmutableListMultimap
keyFunction - the function used to produce the key for each value
ImmutableListMultimap mapping the result of evaluating the function
keyFunction on each value in the input collection to that value
NullPointerException - if any of the following cases is true:
values is null keyFunction is null values is null keyFunction returns null for any element of values public static <K,V> Multimap <K ,V> filterKeys(Multimap <K ,V> unfiltered, Predicate <? super K> keyPredicate)
unfiltered whose keys satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a key that doesn't satisfy the predicate, the multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose keys satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: keyPredicate must be consistent with equals, as documented at Predicate. Do not provide a predicate such as Predicates.instanceOf(ArrayList.class), which is inconsistent with equals.
public static <K,V> SetMultimap <K ,V> filterKeys(SetMultimap <K ,V> unfiltered, Predicate <? super K> keyPredicate)
unfiltered whose keys satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a key that doesn't satisfy the predicate, the multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose keys satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: keyPredicate must be consistent with equals, as documented at Predicate. Do not provide a predicate such as Predicates.instanceOf(ArrayList.class), which is inconsistent with equals.
public static <K,V> ListMultimap <K ,V> filterKeys(ListMultimap <K ,V> unfiltered, Predicate <? super K> keyPredicate)
unfiltered whose keys satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a key that doesn't satisfy the predicate, the multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose keys satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: keyPredicate must be consistent with equals, as documented at Predicate. Do not provide a predicate such as Predicates.instanceOf(ArrayList.class), which is inconsistent with equals.
public static <K,V> Multimap <K ,V> filterValues(Multimap <K ,V> unfiltered, Predicate <? super V> valuePredicate)
unfiltered whose values satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a value that doesn't satisfy the predicate, the multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose value satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: valuePredicate must be consistent with equals, as documented at Predicate. Do not provide a predicate such as Predicates.instanceOf(ArrayList.class), which is inconsistent with equals.
public static <K,V> SetMultimap <K ,V> filterValues(SetMultimap <K ,V> unfiltered, Predicate <? super V> valuePredicate)
unfiltered whose values satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a value that doesn't satisfy the predicate, the multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose value satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: valuePredicate must be consistent with equals, as documented at Predicate. Do not provide a predicate such as Predicates.instanceOf(ArrayList.class), which is inconsistent with equals.
public static <K,V> Multimap <K ,V> filterEntries(Multimap <K ,V> unfiltered, Predicate <? super Map .Entry <K ,V>> entryPredicate)
unfiltered that satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a key/value pair that doesn't satisfy the predicate, multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose keys satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: entryPredicate must be consistent with equals, as documented at Predicate.
public static <K,V> SetMultimap <K ,V> filterEntries(SetMultimap <K ,V> unfiltered, Predicate <? super Map .Entry <K ,V>> entryPredicate)
unfiltered that satisfy a predicate. The returned multimap is a live view of
unfiltered; changes to one affect the other.
The resulting multimap's views have iterators that don't support remove(), but all other methods are supported by the multimap and its views. When adding a key/value pair that doesn't satisfy the predicate, multimap's put(), putAll(), and replaceValues() methods throw an IllegalArgumentException.
When methods such as removeAll() and clear() are called on the filtered multimap or its views, only mappings whose keys satisfy the filter will be removed from the underlying multimap.
The returned multimap isn't threadsafe or serializable, even if unfiltered is.
Many of the filtered multimap's methods, such as size(), iterate across every key/value mapping in the underlying multimap and determine which satisfy the filter. When a live view is not needed, it may be faster to copy the filtered multimap and use the copy.
Warning: entryPredicate must be consistent with equals, as documented at Predicate.