Class SynchronizedBiMap<K,V>
- All Implemented Interfaces:
Serializable
,Cloneable
,Iterable<V>
,Map<K,V>
,BiMap<K,V>
,MutableBiMap<K,V>
,InternalIterable<V>
,MapIterable<K,V>
,MutableMapIterable<K,V>
,RichIterable<V>
public class SynchronizedBiMap<K,V> extends AbstractSynchronizedMapIterable<K,V> implements MutableBiMap<K,V>, Serializable
- See Also:
- Serialized Form
-
Nested Class Summary
-
Method Summary
Modifier and Type Method Description MutableBiMap<K,V>
asSynchronized()
Returns a synchronized wrapper backed by this map.MutableBiMap<K,V>
asUnmodifiable()
Returns an unmodifiable view of this map.MutableBiMap<K,V>
clone()
<K2, V2> MutableBiMap<K2,V2>
collect(Function2<? super K,? super V,Pair<K2,V2>> function)
For each key and value of the map the function is evaluated.<R> MutableBiMap<K,R>
collectValues(Function2<? super K,? super V,? extends R> function)
For each key and value of the map the function is evaluated.Set<Map.Entry<K,V>>
entrySet()
MutableSetMultimap<V,K>
flip()
Given a map from Domain->
Range return a multimap from Range->
Domain.MutableBiMap<V,K>
flipUniqueValues()
Return the MapIterable that is obtained by flipping the direction of this map and making the associations from value to key.V
forcePut(K key, V value)
Similar toMutableBiMap.put(Object, Object)
, except that it quietly removes any existing entry with the same value before putting the key-value pair.<V1> MutableSetMultimap<V1,V>
groupBy(Function<? super V,? extends V1> function)
For each element of the iterable, the function is evaluated and the results of these evaluations are collected into a new multimap, where the transformed value is the key and the original values are added to the same (or similar) species of collection as the source iterable.<V1> MutableSetMultimap<V1,V>
groupByEach(Function<? super V,? extends Iterable<V1>> function)
Similar toRichIterable.groupBy(Function)
, except the result of evaluating function will return a collection of keys for each value.<VV> MutableBiMap<VV,V>
groupByUniqueKey(Function<? super V,? extends VV> function)
For each element of the iterable, the function is evaluated and he results of these evaluations are collected into a new map, where the transformed value is the key.MutableBiMap<V,K>
inverse()
Returns an inversed view of this BiMap, where the associations are in the direction of this bimap's values to keys.Set<K>
keySet()
RichIterable<K>
keysView()
Returns an unmodifiable lazy iterable wrapped around the keySet for the map.MutableBiMap<K,V>
newEmpty()
Creates a new instance of the same type, using the default capacity and growth parameters.static <K, V> SynchronizedBiMap<K,V>
of(MutableBiMap<K,V> map)
This method will take a MutableBiMap and wrap it directly in a SynchronizedBiMap.PartitionMutableSet<V>
partition(Predicate<? super V> predicate)
Filters a collection into a PartitionedIterable based on the evaluation of the predicate.<P> PartitionMutableSet<V>
partitionWith(Predicate2<? super V,? super P> predicate, P parameter)
Filters a collection into a PartitionIterable based on the evaluation of the predicate.MutableSet<V>
reject(Predicate<? super V> predicate)
Returns all elements of the source collection that return false when evaluating of the predicate.MutableBiMap<K,V>
reject(Predicate2<? super K,? super V> predicate)
For each key and value of the map the predicate is evaluated, if the result of the evaluation is false, that key and value are returned in a new map.<P> MutableSet<V>
rejectWith(Predicate2<? super V,? super P> predicate, P parameter)
Similar toRichIterable.reject(Predicate)
, except with an evaluation parameter for the second generic argument inPredicate2
.MutableSet<V>
select(Predicate<? super V> predicate)
Returns all elements of the source collection that return true when evaluating the predicate.MutableBiMap<K,V>
select(Predicate2<? super K,? super V> predicate)
For each key and value of the map the predicate is evaluated, if the result of the evaluation is true, that key and value are returned in a new map.<S> MutableSet<S>
selectInstancesOf(Class<S> clazz)
Returns all elements of the source collection that are instances of the Classclazz
.<P> MutableSet<V>
selectWith(Predicate2<? super V,? super P> predicate, P parameter)
Similar toRichIterable.select(Predicate)
, except with an evaluation parameter for the second generic argument inPredicate2
.MutableBiMap<K,V>
tap(Procedure<? super V> procedure)
Executes the Procedure for each element in the iterable and returnsthis
.ImmutableBiMap<K,V>
toImmutable()
Converts the BiMap to an ImmutableBiMap.Collection<V>
values()
RichIterable<V>
valuesView()
Returns an unmodifiable lazy iterable wrapped around the values for the map.MutableBiMap<K,V>
withAllKeyValueArguments(Pair<? extends K,? extends V>... keyValuePairs)
Convenience var-args version of withAllKeyValuesMutableBiMap<K,V>
withAllKeyValues(Iterable<? extends Pair<? extends K,? extends V>> keyValues)
This method allows mutable, fixed size, and immutable maps the ability to add elements to their existing elements.MutableBiMap<K,V>
withKeyValue(K key, V value)
This method allows mutable, fixed size, and immutable maps the ability to add elements to their existing elements.MutableBiMap<K,V>
withMap(Map<? extends K,? extends V> map)
Similar toMap.putAll(Map)
, but returns this instead of voidMutableBiMap<K,V>
withoutAllKeys(Iterable<? extends K> keys)
This method allows mutable, fixed size, and immutable maps the ability to remove elements from their existing elements.MutableBiMap<K,V>
withoutKey(K key)
This method allows mutable, fixed size, and immutable maps the ability to remove elements from their existing elements.<S> MutableSet<Pair<V,S>>
zip(Iterable<S> that)
Deprecated.in 8.0.MutableSet<Pair<V,Integer>>
zipWithIndex()
Deprecated.in 8.0.Methods inherited from class org.eclipse.collections.impl.map.AbstractSynchronizedMapIterable
add, aggregateBy, aggregateBy, aggregateInPlaceBy, clear, containsKey, containsValue, countBy, countByEach, countByWith, detect, detectOptional, forEachKey, forEachKeyValue, forEachValue, get, getIfAbsent, getIfAbsentPut, getIfAbsentPut, getIfAbsentPutWith, getIfAbsentPutWithKey, getIfAbsentValue, getIfAbsentWith, ifPresentApply, keyValuesView, put, putAll, putPair, remove, removeAllKeys, removeIf, removeKey, sumByDouble, sumByFloat, sumByInt, sumByLong, updateValue, updateValueWith
Methods inherited from class org.eclipse.collections.impl.collection.AbstractSynchronizedRichIterable
allSatisfy, allSatisfyWith, anySatisfy, anySatisfyWith, appendString, appendString, appendString, asLazy, chunk, collect, collect, collectBoolean, collectBoolean, collectByte, collectByte, collectChar, collectChar, collectDouble, collectDouble, collectFloat, collectFloat, collectIf, collectIf, collectInt, collectInt, collectLong, collectLong, collectShort, collectShort, collectWith, collectWith, contains, containsAll, containsAllArguments, containsAllIterable, count, countBy, countByEach, countByWith, countWith, detect, detectIfNone, detectOptional, detectWith, detectWithIfNone, detectWithOptional, each, equals, flatCollect, flatCollect, flatCollectBoolean, flatCollectByte, flatCollectChar, flatCollectDouble, flatCollectFloat, flatCollectInt, flatCollectLong, flatCollectShort, forEachWith, forEachWithIndex, getFirst, getLast, getOnly, groupBy, groupByEach, groupByUniqueKey, hashCode, injectInto, injectInto, injectInto, injectInto, injectInto, into, isEmpty, iterator, makeString, makeString, makeString, max, max, maxBy, maxByOptional, maxOptional, maxOptional, min, min, minBy, minByOptional, minOptional, minOptional, noneSatisfy, noneSatisfyWith, notEmpty, reject, rejectWith, select, selectWith, size, sumOfDouble, sumOfFloat, sumOfInt, sumOfLong, toArray, toArray, toBag, toBiMap, toList, toMap, toMap, toSet, toSortedBag, toSortedBag, toSortedBagBy, toSortedList, toSortedList, toSortedListBy, toSortedMap, toSortedMap, toSortedMapBy, toSortedSet, toSortedSet, toSortedSetBy, toString, zip, zipWithIndex
Methods inherited from interface org.eclipse.collections.api.InternalIterable
forEach, forEachWith, forEachWithIndex
Methods inherited from interface java.util.Map
clear, compute, computeIfAbsent, computeIfPresent, containsKey, containsValue, equals, forEach, get, hashCode, isEmpty, merge, putAll, putIfAbsent, remove, remove, replace, replace, replaceAll, size
Methods inherited from interface org.eclipse.collections.api.map.MapIterable
containsKey, containsValue, detect, detectOptional, equals, forEachKey, forEachKeyValue, forEachValue, get, getIfAbsent, getIfAbsentValue, getIfAbsentWith, hashCode, ifPresentApply, keyValuesView, parallelStream, spliterator, stream, toString
Methods inherited from interface org.eclipse.collections.api.map.MutableMapIterable
add, aggregateBy, aggregateBy, aggregateInPlaceBy, countBy, countByEach, countByWith, getIfAbsentPut, getIfAbsentPut, getIfAbsentPutWith, getIfAbsentPutWithKey, getOrDefault, putPair, removeAllKeys, removeIf, removeKey, sumByDouble, sumByFloat, sumByInt, sumByLong, updateValue, updateValueWith
Methods inherited from interface org.eclipse.collections.api.RichIterable
aggregateBy, allSatisfy, allSatisfyWith, anySatisfy, anySatisfyWith, appendString, appendString, appendString, asLazy, chunk, collect, collect, collectBoolean, collectBoolean, collectByte, collectByte, collectChar, collectChar, collectDouble, collectDouble, collectFloat, collectFloat, collectIf, collectIf, collectInt, collectInt, collectLong, collectLong, collectShort, collectShort, collectWith, collectWith, contains, containsAll, containsAllArguments, containsAllIterable, containsBy, count, countBy, countByEach, countByWith, countWith, detect, detectIfNone, detectOptional, detectWith, detectWithIfNone, detectWithOptional, each, flatCollect, flatCollect, flatCollectBoolean, flatCollectByte, flatCollectChar, flatCollectDouble, flatCollectFloat, flatCollectInt, flatCollectLong, flatCollectShort, flatCollectWith, flatCollectWith, forEach, getAny, getFirst, getLast, getOnly, groupBy, groupByAndCollect, groupByEach, groupByUniqueKey, injectInto, injectInto, injectInto, injectInto, injectInto, into, isEmpty, makeString, makeString, makeString, max, max, maxBy, maxByOptional, maxOptional, maxOptional, min, min, minBy, minByOptional, minOptional, minOptional, noneSatisfy, noneSatisfyWith, notEmpty, reduce, reduceInPlace, reduceInPlace, reject, rejectWith, select, selectWith, size, summarizeDouble, summarizeFloat, summarizeInt, summarizeLong, sumOfDouble, sumOfFloat, sumOfInt, sumOfLong, toArray, toArray, toBag, toBiMap, toList, toMap, toMap, toSet, toSortedBag, toSortedBag, toSortedBagBy, toSortedList, toSortedList, toSortedListBy, toSortedMap, toSortedMap, toSortedMapBy, toSortedSet, toSortedSet, toSortedSetBy, zip, zipWithIndex
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Method Details
-
of
This method will take a MutableBiMap and wrap it directly in a SynchronizedBiMap. -
forcePut
Description copied from interface:MutableBiMap
Similar toMutableBiMap.put(Object, Object)
, except that it quietly removes any existing entry with the same value before putting the key-value pair.- Specified by:
forcePut
in interfaceMutableBiMap<K,V>
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asSynchronized
Description copied from interface:MutableMapIterable
Returns a synchronized wrapper backed by this map. This is the equivalent of callingCollections.synchronizedMap(this)
only with the more feature rich return type ofMutableMapIterable
.The preferred way of iterating over a synchronized map is to use the forEachKey(), forEachValue() and forEachKeyValue() methods which are properly synchronized internally.
MutableMap synchedMap = map.asSynchronized(); synchedMap.forEachKey(key -> ... ); synchedMap.forEachValue(value -> ... ); synchedMap.forEachKeyValue((key, value) -> ... );
If you want to iterate imperatively over the keySet(), values(), or entrySet(), you will need to protect the iteration by wrapping the code in a synchronized block on the map.
- Specified by:
asSynchronized
in interfaceMutableBiMap<K,V>
- Specified by:
asSynchronized
in interfaceMutableMapIterable<K,V>
- See Also:
Collections.synchronizedMap(Map)
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asUnmodifiable
Description copied from interface:MutableMapIterable
Returns an unmodifiable view of this map. This is the equivalent of usingCollections.unmodifiableMap(this)
only with a return type that supports the full iteration protocols available onMutableMapIterable
. Methods which would mutate the underlying map will throw UnsupportedOperationExceptions.- Specified by:
asUnmodifiable
in interfaceMutableBiMap<K,V>
- Specified by:
asUnmodifiable
in interfaceMutableMapIterable<K,V>
- Returns:
- an unmodifiable view of this map.
- See Also:
Collections.unmodifiableMap(Map)
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clone
- Specified by:
clone
in interfaceMutableBiMap<K,V>
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tap
Description copied from interface:RichIterable
Executes the Procedure for each element in the iterable and returnsthis
.Example using a Java 8 lambda expression:
RichIterable<Person> tapped = people.tap(person -> LOGGER.info(person.getName()));
Example using an anonymous inner class:
RichIterable<Person> tapped = people.tap(new Procedure<Person>() { public void value(Person person) { LOGGER.info(person.getName()); } });
- Specified by:
tap
in interfaceBiMap<K,V>
- Specified by:
tap
in interfaceMapIterable<K,V>
- Specified by:
tap
in interfaceMutableBiMap<K,V>
- Specified by:
tap
in interfaceMutableMapIterable<K,V>
- Specified by:
tap
in interfaceRichIterable<K>
- Overrides:
tap
in classAbstractSynchronizedMapIterable<K,V>
- See Also:
RichIterable.each(Procedure)
,RichIterable.forEach(Procedure)
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collect
public <K2, V2> MutableBiMap<K2,V2> collect(Function2<? super K,? super V,Pair<K2,V2>> function)Description copied from interface:BiMap
For each key and value of the map the function is evaluated. The results of these evaluations are returned in a new map. The map returned will use the values projected from the function rather than the original values.MapIterable<String, String> collected = peopleByCity.collect((City city, Person person) -> Pair.of(city.getCountry(), person.getAddress().getCity()));
Implementations are expected to delegate toMutableBiMap.put(Object, Object)
,ImmutableBiMap.newWithKeyValue(Object, Object)
, or equivalent, notMutableBiMap.forcePut(Object, Object)
. -
collectValues
Description copied from interface:BiMap
For each key and value of the map the function is evaluated. The results of these evaluations are returned in a new map. The map returned will use the values projected from the function rather than the original values.MapIterable<City, String> collected = peopleByCity.collectValues((City city, Person person) -> person.getFirstName() + " " + person.getLastName());
Implementations are expected to delegate toMutableBiMap.put(Object, Object)
,ImmutableBiMap.newWithKeyValue(Object, Object)
, or equivalent, notMutableBiMap.forcePut(Object, Object)
.- Specified by:
collectValues
in interfaceBiMap<K,V>
- Specified by:
collectValues
in interfaceMapIterable<K,V>
- Specified by:
collectValues
in interfaceMutableBiMap<K,V>
- Specified by:
collectValues
in interfaceMutableMapIterable<K,V>
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select
Description copied from interface:RichIterable
Returns all elements of the source collection that return true when evaluating the predicate. This method is also commonly called filter.Example using a Java 8 lambda expression:
RichIterable<Person> selected = people.select(person -> person.getAddress().getCity().equals("London"));
Example using an anonymous inner class:
RichIterable<Person> selected = people.select(new Predicate<Person>() { public boolean accept(Person person) { return person.getAddress().getCity().equals("London"); } });
- Specified by:
select
in interfaceBiMap<K,V>
- Specified by:
select
in interfaceMutableBiMap<K,V>
- Specified by:
select
in interfaceMutableMapIterable<K,V>
- Specified by:
select
in interfaceRichIterable<K>
- Overrides:
select
in classAbstractSynchronizedMapIterable<K,V>
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select
Description copied from interface:MapIterable
For each key and value of the map the predicate is evaluated, if the result of the evaluation is true, that key and value are returned in a new map.MapIterable<City, Person> selected = peopleByCity.select((city, person) -> city.getName().equals("Anytown") && person.getLastName().equals("Smith"));
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selectWith
Description copied from interface:RichIterable
Similar toRichIterable.select(Predicate)
, except with an evaluation parameter for the second generic argument inPredicate2
.E.g. return a
Collection
of Person elements where the person has an age greater than or equal to 18 yearsExample using a Java 8 lambda expression:
RichIterable<Person> selected = people.selectWith((Person person, Integer age) -> person.getAge()>= age, Integer.valueOf(18));
Example using an anonymous inner class:
RichIterable<Person> selected = people.selectWith(new Predicate2<Person, Integer>() { public boolean accept(Person person, Integer age) { return person.getAge()>= age; } }, Integer.valueOf(18));
- Specified by:
selectWith
in interfaceBiMap<K,V>
- Specified by:
selectWith
in interfaceMutableBiMap<K,V>
- Specified by:
selectWith
in interfaceMutableMapIterable<K,V>
- Specified by:
selectWith
in interfaceRichIterable<K>
- Overrides:
selectWith
in classAbstractSynchronizedMapIterable<K,V>
- Parameters:
predicate
- aPredicate2
to use as the select criteriaparameter
- a parameter to pass in for evaluation of the second argumentP
inpredicate
- See Also:
RichIterable.select(Predicate)
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selectInstancesOf
Description copied from interface:RichIterable
Returns all elements of the source collection that are instances of the Classclazz
.RichIterable<Integer> integers = List.mutable.with(new Integer(0), new Long(0L), new Double(0.0)).selectInstancesOf(Integer.class);
- Specified by:
selectInstancesOf
in interfaceBiMap<K,V>
- Specified by:
selectInstancesOf
in interfaceMutableBiMap<K,V>
- Specified by:
selectInstancesOf
in interfaceMutableMapIterable<K,V>
- Specified by:
selectInstancesOf
in interfaceRichIterable<K>
- Overrides:
selectInstancesOf
in classAbstractSynchronizedMapIterable<K,V>
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reject
Description copied from interface:RichIterable
Returns all elements of the source collection that return false when evaluating of the predicate. This method is also sometimes called filterNot and is the equivalent of calling iterable.select(Predicates.not(predicate)).Example using a Java 8 lambda expression:
RichIterable<Person> rejected = people.reject(person -> person.person.getLastName().equals("Smith"));
Example using an anonymous inner class:
RichIterable<Person> rejected = people.reject(new Predicate<Person>() { public boolean accept(Person person) { return person.person.getLastName().equals("Smith"); } });
- Specified by:
reject
in interfaceBiMap<K,V>
- Specified by:
reject
in interfaceMutableBiMap<K,V>
- Specified by:
reject
in interfaceMutableMapIterable<K,V>
- Specified by:
reject
in interfaceRichIterable<K>
- Overrides:
reject
in classAbstractSynchronizedMapIterable<K,V>
- Parameters:
predicate
- aPredicate
to use as the reject criteria- Returns:
- a RichIterable that contains elements that cause
Predicate.accept(Object)
method to evaluate to false
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reject
Description copied from interface:MapIterable
For each key and value of the map the predicate is evaluated, if the result of the evaluation is false, that key and value are returned in a new map.MapIterable<City, Person> rejected = peopleByCity.reject((city, person) -> city.getName().equals("Anytown") && person.getLastName().equals("Smith"));
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rejectWith
Description copied from interface:RichIterable
Similar toRichIterable.reject(Predicate)
, except with an evaluation parameter for the second generic argument inPredicate2
.E.g. return a
Collection
of Person elements where the person has an age greater than or equal to 18 yearsExample using a Java 8 lambda expression:
RichIterable<Person> rejected = people.rejectWith((Person person, Integer age) -> person.getAge() < age, Integer.valueOf(18));
Example using an anonymous inner class:
MutableList<Person> rejected = people.rejectWith(new Predicate2<Person, Integer>() { public boolean accept(Person person, Integer age) { return person.getAge() < age; } }, Integer.valueOf(18));
- Specified by:
rejectWith
in interfaceBiMap<K,V>
- Specified by:
rejectWith
in interfaceMutableBiMap<K,V>
- Specified by:
rejectWith
in interfaceMutableMapIterable<K,V>
- Specified by:
rejectWith
in interfaceRichIterable<K>
- Overrides:
rejectWith
in classAbstractSynchronizedMapIterable<K,V>
- Parameters:
predicate
- aPredicate2
to use as the select criteriaparameter
- a parameter to pass in for evaluation of the second argumentP
inpredicate
- See Also:
RichIterable.select(Predicate)
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partition
Description copied from interface:RichIterable
Filters a collection into a PartitionedIterable based on the evaluation of the predicate.Example using a Java 8 lambda expression:
PartitionIterable<Person> newYorkersAndNonNewYorkers = people.partition(person -> person.getAddress().getState().getName().equals("New York"));
Example using an anonymous inner class:
PartitionIterable<Person> newYorkersAndNonNewYorkers = people.partition(new Predicate<Person>() { public boolean accept(Person person) { return person.getAddress().getState().getName().equals("New York"); } });
- Specified by:
partition
in interfaceBiMap<K,V>
- Specified by:
partition
in interfaceMutableBiMap<K,V>
- Specified by:
partition
in interfaceMutableMapIterable<K,V>
- Specified by:
partition
in interfaceRichIterable<K>
- Overrides:
partition
in classAbstractSynchronizedMapIterable<K,V>
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partitionWith
public <P> PartitionMutableSet<V> partitionWith(Predicate2<? super V,? super P> predicate, P parameter)Description copied from interface:RichIterable
Filters a collection into a PartitionIterable based on the evaluation of the predicate.Example using a Java 8 lambda expression:
PartitionIterable<Person> newYorkersAndNonNewYorkers = people.partitionWith((Person person, String state) -> person.getAddress().getState().getName().equals(state), "New York");
Example using an anonymous inner class:
PartitionIterable<Person> newYorkersAndNonNewYorkers = people.partitionWith(new Predicate2<Person, String>() { public boolean accept(Person person, String state) { return person.getAddress().getState().getName().equals(state); } }, "New York");
- Specified by:
partitionWith
in interfaceBiMap<K,V>
- Specified by:
partitionWith
in interfaceMutableBiMap<K,V>
- Specified by:
partitionWith
in interfaceRichIterable<K>
- Overrides:
partitionWith
in classAbstractSynchronizedRichIterable<V>
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groupBy
Description copied from interface:RichIterable
For each element of the iterable, the function is evaluated and the results of these evaluations are collected into a new multimap, where the transformed value is the key and the original values are added to the same (or similar) species of collection as the source iterable.Example using a Java 8 method reference:
Multimap<String, Person> peopleByLastName = people.groupBy(Person::getLastName);
Example using an anonymous inner class:
Multimap<String, Person> peopleByLastName = people.groupBy(new Function<Person, String>() { public String valueOf(Person person) { return person.getLastName(); } });
- Specified by:
groupBy
in interfaceBiMap<K,V>
- Specified by:
groupBy
in interfaceMutableBiMap<K,V>
- Specified by:
groupBy
in interfaceMutableMapIterable<K,V>
- Specified by:
groupBy
in interfaceRichIterable<K>
- Overrides:
groupBy
in classAbstractSynchronizedMapIterable<K,V>
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groupByEach
public <V1> MutableSetMultimap<V1,V> groupByEach(Function<? super V,? extends Iterable<V1>> function)Description copied from interface:RichIterable
Similar toRichIterable.groupBy(Function)
, except the result of evaluating function will return a collection of keys for each value.- Specified by:
groupByEach
in interfaceBiMap<K,V>
- Specified by:
groupByEach
in interfaceMutableBiMap<K,V>
- Specified by:
groupByEach
in interfaceMutableMapIterable<K,V>
- Specified by:
groupByEach
in interfaceRichIterable<K>
- Overrides:
groupByEach
in classAbstractSynchronizedMapIterable<K,V>
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flip
Description copied from interface:MapIterable
Given a map from Domain->
Range return a multimap from Range->
Domain. We chose the name 'flip' rather than 'invert' or 'transpose' since this method does not have the property of applying twice returns the original.Since the keys in the input are unique, the values in the output are unique, so the return type should be a SetMultimap. However since SetMultimap and SortedSetMultimap don't inherit from one another, SetMultimap here does not allow SortedMapIterable to have a SortedSetMultimap return. Thus we compromise and call this Multimap, even though all implementations will be a SetMultimap or SortedSetMultimap.
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newEmpty
Description copied from interface:MutableMapIterable
Creates a new instance of the same type, using the default capacity and growth parameters.- Specified by:
newEmpty
in interfaceMutableBiMap<K,V>
- Specified by:
newEmpty
in interfaceMutableMapIterable<K,V>
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inverse
Description copied from interface:BiMap
Returns an inversed view of this BiMap, where the associations are in the direction of this bimap's values to keys. -
flipUniqueValues
Description copied from interface:MapIterable
Return the MapIterable that is obtained by flipping the direction of this map and making the associations from value to key.MapIterable<Integer, String> map = this.newMapWithKeysValues(1, "1", 2, "2", 3, "3"); MapIterable<String, Integer> result = map.flipUniqueValues(); Assert.assertTrue(result.equals(UnifiedMap.newWithKeysValues("1", 1, "2", 2, "3", 3)));
- Specified by:
flipUniqueValues
in interfaceBiMap<K,V>
- Specified by:
flipUniqueValues
in interfaceMapIterable<K,V>
- Specified by:
flipUniqueValues
in interfaceMutableBiMap<K,V>
- Specified by:
flipUniqueValues
in interfaceMutableMapIterable<K,V>
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keysView
Description copied from interface:MapIterable
Returns an unmodifiable lazy iterable wrapped around the keySet for the map.- Specified by:
keysView
in interfaceMapIterable<K,V>
-
valuesView
Description copied from interface:MapIterable
Returns an unmodifiable lazy iterable wrapped around the values for the map.- Specified by:
valuesView
in interfaceMapIterable<K,V>
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toImmutable
Description copied from interface:BiMap
Converts the BiMap to an ImmutableBiMap. If the bimap is immutable, it returns itself.- Specified by:
toImmutable
in interfaceBiMap<K,V>
- Specified by:
toImmutable
in interfaceMapIterable<K,V>
- Specified by:
toImmutable
in interfaceMutableMapIterable<K,V>
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zipWithIndex
Deprecated.in 8.0. UseOrderedIterable.zipWithIndex()
instead.Description copied from interface:RichIterable
Zips thisRichIterable
with its indices.- Specified by:
zipWithIndex
in interfaceBiMap<K,V>
- Specified by:
zipWithIndex
in interfaceMutableBiMap<K,V>
- Specified by:
zipWithIndex
in interfaceMutableMapIterable<K,V>
- Specified by:
zipWithIndex
in interfaceRichIterable<K>
- Overrides:
zipWithIndex
in classAbstractSynchronizedMapIterable<K,V>
- Returns:
- A new
RichIterable
containing pairs consisting of all elements of thisRichIterable
paired with their index. Indices start at 0. - See Also:
RichIterable.zip(Iterable)
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groupByUniqueKey
Description copied from interface:RichIterable
For each element of the iterable, the function is evaluated and he results of these evaluations are collected into a new map, where the transformed value is the key. The generated keys must each be unique, or else an exception is thrown.- Specified by:
groupByUniqueKey
in interfaceBiMap<K,V>
- Specified by:
groupByUniqueKey
in interfaceMutableBiMap<K,V>
- Specified by:
groupByUniqueKey
in interfaceMutableMapIterable<K,V>
- Specified by:
groupByUniqueKey
in interfaceRichIterable<K>
- Overrides:
groupByUniqueKey
in classAbstractSynchronizedMapIterable<K,V>
- See Also:
RichIterable.groupBy(Function)
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zip
Deprecated.in 8.0. UseOrderedIterable.zip(Iterable)
instead.Description copied from interface:RichIterable
Returns aRichIterable
formed from thisRichIterable
and anotherRichIterable
by combining corresponding elements in pairs. If one of the twoRichIterable
s is longer than the other, its remaining elements are ignored.- Specified by:
zip
in interfaceBiMap<K,V>
- Specified by:
zip
in interfaceMutableBiMap<K,V>
- Specified by:
zip
in interfaceMutableMapIterable<K,V>
- Specified by:
zip
in interfaceRichIterable<K>
- Overrides:
zip
in classAbstractSynchronizedMapIterable<K,V>
- Type Parameters:
S
- the type of the second half of the returned pairs- Parameters:
that
- TheRichIterable
providing the second half of each result pair- Returns:
- A new
RichIterable
containing pairs consisting of corresponding elements of thisRichIterable
and that. The length of the returnedRichIterable
is the minimum of the lengths of thisRichIterable
and that.
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withKeyValue
Description copied from interface:MutableMapIterable
This method allows mutable, fixed size, and immutable maps the ability to add elements to their existing elements. In order to support fixed size maps, a new instance of a map would have to be returned including the keys and values of the original plus the additional key and value. In the case of mutable maps, the original map is modified and then returned. In order to use this method properly with mutable and fixed size maps the following approach must be taken:map = map.withKeyValue("new key", "new value");
In the case of FixedSizeMap, a new instance will be returned by withKeyValue, and any variables that previously referenced the original map will need to be redirected to reference the new instance. In the case of a FastMap or UnifiedMap, you will be replacing the reference to map with map, since FastMap and UnifiedMap will both return "this" after calling put on themselves.- Specified by:
withKeyValue
in interfaceMutableBiMap<K,V>
- Specified by:
withKeyValue
in interfaceMutableMapIterable<K,V>
- See Also:
Map.put(Object, Object)
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withMap
Description copied from interface:MutableMapIterable
Similar toMap.putAll(Map)
, but returns this instead of void- Specified by:
withMap
in interfaceMutableBiMap<K,V>
- Specified by:
withMap
in interfaceMutableMapIterable<K,V>
- See Also:
Map.putAll(Map)
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withAllKeyValues
public MutableBiMap<K,V> withAllKeyValues(Iterable<? extends Pair<? extends K,? extends V>> keyValues)Description copied from interface:MutableMapIterable
This method allows mutable, fixed size, and immutable maps the ability to add elements to their existing elements. In order to support fixed size maps, a new instance of a map would have to be returned including the keys and values of the original plus all of the additional keys and values. In the case of mutable maps, the original map is modified and then returned. In order to use this method properly with mutable and fixed size maps the following approach must be taken:map = map.withAllKeyValues(FastList.newListWith(PairImpl.of("new key", "new value")));
In the case of FixedSizeMap, a new instance will be returned by withAllKeyValues, and any variables that previously referenced the original map will need to be redirected to reference the new instance. In the case of a FastMap or UnifiedMap, you will be replacing the reference to map with map, since FastMap and UnifiedMap will both return "this" after calling put on themselves.- Specified by:
withAllKeyValues
in interfaceMutableBiMap<K,V>
- Specified by:
withAllKeyValues
in interfaceMutableMapIterable<K,V>
- See Also:
Map.put(Object, Object)
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withAllKeyValueArguments
public MutableBiMap<K,V> withAllKeyValueArguments(Pair<? extends K,? extends V>... keyValuePairs)Description copied from interface:MutableMapIterable
Convenience var-args version of withAllKeyValues- Specified by:
withAllKeyValueArguments
in interfaceMutableBiMap<K,V>
- Specified by:
withAllKeyValueArguments
in interfaceMutableMapIterable<K,V>
- See Also:
MutableMapIterable.withAllKeyValues(Iterable)
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withoutKey
Description copied from interface:MutableMapIterable
This method allows mutable, fixed size, and immutable maps the ability to remove elements from their existing elements. In order to support fixed size maps, a new instance of a map would have to be returned including the keys and values of the original minus the key and value to be removed. In the case of mutable maps, the original map is modified and then returned. In order to use this method properly with mutable and fixed size maps the following approach must be taken:map = map.withoutKey("key");
In the case of FixedSizeMap, a new instance will be returned by withoutKey, and any variables that previously referenced the original map will need to be redirected to reference the new instance. In the case of a FastMap or UnifiedMap, you will be replacing the reference to map with map, since FastMap and UnifiedMap will both return "this" after calling remove on themselves.- Specified by:
withoutKey
in interfaceMutableBiMap<K,V>
- Specified by:
withoutKey
in interfaceMutableMapIterable<K,V>
- See Also:
Map.remove(Object)
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withoutAllKeys
Description copied from interface:MutableMapIterable
This method allows mutable, fixed size, and immutable maps the ability to remove elements from their existing elements. In order to support fixed size maps, a new instance of a map would have to be returned including the keys and values of the original minus all of the keys and values to be removed. In the case of mutable maps, the original map is modified and then returned. In order to use this method properly with mutable and fixed size maps the following approach must be taken:map = map.withoutAllKeys(FastList.newListWith("key1", "key2"));
In the case of FixedSizeMap, a new instance will be returned by withoutAllKeys, and any variables that previously referenced the original map will need to be redirected to reference the new instance. In the case of a FastMap or UnifiedMap, you will be replacing the reference to map with map, since FastMap and UnifiedMap will both return "this" after calling remove on themselves.- Specified by:
withoutAllKeys
in interfaceMutableBiMap<K,V>
- Specified by:
withoutAllKeys
in interfaceMutableMapIterable<K,V>
- See Also:
Map.remove(Object)
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keySet
-
values
-
entrySet
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