@GwtCompatible(serializable=true, emulated=true) public final class LinkedHashMultiset<E> extends AbstractCollection<E>
Multiset
implementation with predictable iteration order. Its iterator orders elements
according to when the first occurrence of the element was added. When the multiset contains
multiple instances of an element, those instances are consecutive in the iteration order. If all
occurrences of an element are removed, after which that element is added to the multiset, the
element will appear at the end of the iteration.
See the Guava User Guide article on Multiset
.
Multiset.Entry<E>
Modifier and Type | Method and Description |
---|---|
boolean |
add(E element)
Ensures that this collection contains the specified element (optional
operation).
|
int |
add(E element,
int occurrences)
Adds a number of occurrences of an element to this multiset.
|
boolean |
addAll(Collection<? extends E> elementsToAdd)
Adds all of the elements in the specified collection to this collection
(optional operation).
|
void |
clear()
Removes all of the elements from this collection (optional operation).
|
boolean |
contains(Object element)
Returns true if this collection contains the specified element.
|
int |
count(Object element)
Returns the number of occurrences of an element in this multiset (the count of the
element).
|
static <E> LinkedHashMultiset<E> |
create()
Creates a new, empty
LinkedHashMultiset using the default initial capacity. |
static <E> LinkedHashMultiset<E> |
create(int distinctElements)
Creates a new, empty
LinkedHashMultiset with the specified expected number of distinct
elements. |
static <E> LinkedHashMultiset<E> |
create(Iterable<? extends E> elements)
Creates a new
LinkedHashMultiset containing the specified elements. |
Set<E> |
elementSet()
Returns the set of distinct elements contained in this multiset.
|
Set<Multiset.Entry<E>> |
entrySet()
Returns a view of the contents of this multiset, grouped into
Multiset.Entry instances,
each providing an element of the multiset and the count of that element. |
boolean |
equals(Object object)
Indicates whether some other object is "equal to" this one.
|
void |
forEachEntry(ObjIntConsumer<? super E> action)
Runs the specified action for each distinct element in this multiset, and the number of
occurrences of that element.
|
int |
hashCode()
Returns a hash code value for the object.
|
boolean |
isEmpty()
Returns true if this collection contains no elements.
|
Iterator<E> |
iterator()
Returns an iterator over the elements contained in this collection.
|
boolean |
remove(Object element)
Removes a single instance of the specified element from this
collection, if it is present (optional operation).
|
int |
remove(Object element,
int occurrences)
Removes a number of occurrences of the specified element from this multiset.
|
boolean |
removeAll(Collection<?> elementsToRemove)
Removes all of this collection's elements that are also contained in the
specified collection (optional operation).
|
boolean |
retainAll(Collection<?> elementsToRetain)
Retains only the elements in this collection that are contained in the
specified collection (optional operation).
|
int |
setCount(E element,
int count)
Adds or removes the necessary occurrences of an element such that the element attains the
desired count.
|
boolean |
setCount(E element,
int oldCount,
int newCount)
Conditionally sets the count of an element to a new value, as described in
Multiset.setCount(Object, int) , provided that the element has the expected current count. |
int |
size()
Returns the number of elements in this collection.
|
String |
toString()
Returns a string representation of this collection.
|
containsAll, toArray, toArray
clone, finalize, getClass, notify, notifyAll, wait, wait, wait
containsAll, forEach, spliterator
parallelStream, removeIf, stream, toArray, toArray
public static <E> LinkedHashMultiset<E> create()
LinkedHashMultiset
using the default initial capacity.public static <E> LinkedHashMultiset<E> create(int distinctElements)
LinkedHashMultiset
with the specified expected number of distinct
elements.distinctElements
- the expected number of distinct elementsIllegalArgumentException
- if distinctElements
is negativepublic static <E> LinkedHashMultiset<E> create(Iterable<? extends E> elements)
LinkedHashMultiset
containing the specified elements.
This implementation is highly efficient when elements
is itself a Multiset
.
elements
- the elements that the multiset should containpublic Set<Multiset.Entry<E>> entrySet()
Multiset.Entry
instances,
each providing an element of the multiset and the count of that element. This set contains
exactly one entry for each distinct element in the multiset (thus it always has the same size
as the Multiset.elementSet()
). The order of the elements in the element set is unspecified.
The entry set is backed by the same data as the multiset, so any change to either is
immediately reflected in the other. However, multiset changes may or may not be reflected in
any Entry
instances already retrieved from the entry set (this is
implementation-dependent). Furthermore, implementations are not required to support
modifications to the entry set at all, and the Entry
instances themselves don't even
have methods for modification. See the specific implementation class for more details on how
its entry set handles modifications.
Invoking Multiset.Entry.getCount()
on an entry in the returned set always returns the
current count of that element in the multiset, as opposed to the count at the time the entry
was retrieved.
public void forEachEntry(ObjIntConsumer<? super E> action)
Multiset
Multiset
implementations, this may be more
efficient than iterating over the Multiset.entrySet()
either explicitly or with entrySet().forEach(action)
.forEachEntry
in interface Multiset<E>
public void clear()
java.util.AbstractCollection
This implementation iterates over this collection, removing each element using the Iterator.remove operation. Most implementations will probably choose to override this method for efficiency.
Note that this implementation will throw an UnsupportedOperationException if the iterator returned by this collection's iterator method does not implement the remove method and this collection is non-empty.
clear
in interface Collection<E>
public int size()
java.util.Collection
size
in interface Multiset<E>
size
in interface Collection<E>
size
in class AbstractCollection<E>
public Iterator<E> iterator()
java.util.AbstractCollection
iterator
in interface Multiset<E>
iterator
in interface Iterable<E>
iterator
in interface Collection<E>
iterator
in class AbstractCollection<E>
public int count(@NullableDecl Object element)
Multiset
Object.equals(java.lang.Object)
-based multiset, this gives the same result as
Collections.frequency(java.util.Collection<?>, java.lang.Object)
(which would presumably perform more poorly).
Note: the utility method Iterables.frequency(java.lang.Iterable<?>, java.lang.Object)
generalizes this operation; it
correctly delegates to this method when dealing with a multiset, but it can also accept any
other iterable type.
@CanIgnoreReturnValue public int add(@NullableDecl E element, int occurrences)
occurrences ==
1
, this method has the identical effect to Multiset.add(Object)
. This method is functionally
equivalent (except in the case of overflow) to the call addAll(Collections.nCopies(element, occurrences))
, which would presumably perform much more
poorly.add
in interface Multiset<E>
element
- the element to add occurrences of; may be null only if explicitly allowed by the
implementationoccurrences
- the number of occurrences of the element to add. May be zero, in which case
no change will be made.IllegalArgumentException
- if the call would result in more than Integer.MAX_VALUE
occurrences of element
in this multiset.@CanIgnoreReturnValue public int remove(@NullableDecl Object element, int occurrences)
Multiset
occurrences == 1
, this is functionally equivalent to the call remove(element)
.remove
in interface Multiset<E>
element
- the element to conditionally remove occurrences ofoccurrences
- the number of occurrences of the element to remove. May be zero, in which
case no change will be made.@CanIgnoreReturnValue public int setCount(@NullableDecl E element, int count)
Multiset
setCount
in interface Multiset<E>
element
- the element to add or remove occurrences of; may be null only if explicitly
allowed by the implementationcount
- the desired count of the element in this multisetpublic boolean isEmpty()
java.util.AbstractCollection
This implementation returns size() == 0.
isEmpty
in interface Collection<E>
isEmpty
in class AbstractCollection<E>
public boolean contains(@NullableDecl Object element)
java.util.AbstractCollection
This implementation iterates over the elements in the collection, checking each element in turn for equality with the specified element.
contains
in interface Multiset<E>
contains
in interface Collection<E>
contains
in class AbstractCollection<E>
element
- element whose presence in this collection is to be tested@CanIgnoreReturnValue public final boolean add(@NullableDecl E element)
java.util.AbstractCollection
Collections that support this operation may place limitations on what elements may be added to this collection. In particular, some collections will refuse to add null elements, and others will impose restrictions on the type of elements that may be added. Collection classes should clearly specify in their documentation any restrictions on what elements may be added.
If a collection refuses to add a particular element for any reason other than that it already contains the element, it must throw an exception (rather than returning false). This preserves the invariant that a collection always contains the specified element after this call returns.
This implementation always throws an UnsupportedOperationException.
add
in interface Multiset<E>
add
in interface Collection<E>
add
in class AbstractCollection<E>
element
- element whose presence in this collection is to be ensured@CanIgnoreReturnValue public final boolean remove(@NullableDecl Object element)
java.util.AbstractCollection
This implementation iterates over the collection looking for the specified element. If it finds the element, it removes the element from the collection using the iterator's remove method.
Note that this implementation throws an UnsupportedOperationException if the iterator returned by this collection's iterator method does not implement the remove method and this collection contains the specified object.
remove
in interface Multiset<E>
remove
in interface Collection<E>
remove
in class AbstractCollection<E>
element
- element to be removed from this collection, if present@CanIgnoreReturnValue public boolean setCount(@NullableDecl E element, int oldCount, int newCount)
Multiset
Multiset.setCount(Object, int)
, provided that the element has the expected current count. If the
current count is not oldCount
, no change is made.setCount
in interface Multiset<E>
element
- the element to conditionally set the count of; may be null only if explicitly
allowed by the implementationoldCount
- the expected present count of the element in this multisetnewCount
- the desired count of the element in this multisettrue
if the condition for modification was met. This implies that the multiset
was indeed modified, unless oldCount == newCount
.@CanIgnoreReturnValue public final boolean addAll(Collection<? extends E> elementsToAdd)
This implementation iterates over the specified collection, and adds each object returned by the iterator to this collection, in turn.
Note that this implementation will throw an UnsupportedOperationException unless add is overridden (assuming the specified collection is non-empty).
This implementation is highly efficient when elementsToAdd
is itself a Multiset
.
addAll
in interface Collection<E>
addAll
in class AbstractCollection<E>
elementsToAdd
- collection containing elements to be added to this collectionAbstractCollection.add(Object)
@CanIgnoreReturnValue public final boolean removeAll(Collection<?> elementsToRemove)
java.util.AbstractCollection
This implementation iterates over this collection, checking each element returned by the iterator in turn to see if it's contained in the specified collection. If it's so contained, it's removed from this collection with the iterator's remove method.
Note that this implementation will throw an UnsupportedOperationException if the iterator returned by the iterator method does not implement the remove method and this collection contains one or more elements in common with the specified collection.
removeAll
in interface Multiset<E>
removeAll
in interface Collection<E>
removeAll
in class AbstractCollection<E>
elementsToRemove
- collection containing elements to be removed from this collectionAbstractCollection.remove(Object)
,
AbstractCollection.contains(Object)
@CanIgnoreReturnValue public final boolean retainAll(Collection<?> elementsToRetain)
java.util.AbstractCollection
This implementation iterates over this collection, checking each element returned by the iterator in turn to see if it's contained in the specified collection. If it's not so contained, it's removed from this collection with the iterator's remove method.
Note that this implementation will throw an UnsupportedOperationException if the iterator returned by the iterator method does not implement the remove method and this collection contains one or more elements not present in the specified collection.
retainAll
in interface Multiset<E>
retainAll
in interface Collection<E>
retainAll
in class AbstractCollection<E>
elementsToRetain
- collection containing elements to be retained in this collectionAbstractCollection.remove(Object)
,
AbstractCollection.contains(Object)
public Set<E> elementSet()
Multiset
If the element set supports any removal operations, these necessarily cause all occurrences of the removed element(s) to be removed from the multiset. Implementations are not expected to support the add operations, although this is possible.
A common use for the element set is to find the number of distinct elements in the multiset:
elementSet().size()
.
elementSet
in interface Multiset<E>
public final boolean equals(@NullableDecl Object object)
The equals
method implements an equivalence relation
on non-null object references:
x
, x.equals(x)
should return
true
.
x
and y
, x.equals(y)
should return true
if and only if
y.equals(x)
returns true
.
x
, y
, and z
, if
x.equals(y)
returns true
and
y.equals(z)
returns true
, then
x.equals(z)
should return true
.
x
and y
, multiple invocations of
x.equals(y)
consistently return true
or consistently return false
, provided no
information used in equals
comparisons on the
objects is modified.
x
,
x.equals(null)
should return false
.
The equals
method for class Object
implements
the most discriminating possible equivalence relation on objects;
that is, for any non-null reference values x
and
y
, this method returns true
if and only
if x
and y
refer to the same object
(x == y
has the value true
).
Note that it is generally necessary to override the hashCode
method whenever this method is overridden, so as to maintain the
general contract for the hashCode
method, which states
that equal objects must have equal hash codes.
This implementation returns true
if object
is a multiset of the same size
and if, for each element, the two multisets have the same count.
equals
in interface Multiset<E>
equals
in interface Collection<E>
equals
in class Object
object
- the reference object with which to compare.true
if this object is the same as the obj
argument; false
otherwise.Object.hashCode()
,
HashMap
public final int hashCode()
HashMap
.
The general contract of hashCode
is:
hashCode
method
must consistently return the same integer, provided no information
used in equals
comparisons on the object is modified.
This integer need not remain consistent from one execution of an
application to another execution of the same application.
equals(Object)
method, then calling the hashCode
method on each of
the two objects must produce the same integer result.
Object.equals(java.lang.Object)
method, then calling the hashCode
method on each of the
two objects must produce distinct integer results. However, the
programmer should be aware that producing distinct integer results
for unequal objects may improve the performance of hash tables.
As much as is reasonably practical, the hashCode method defined by
class Object
does return distinct integers for distinct
objects. (This is typically implemented by converting the internal
address of the object into an integer, but this implementation
technique is not required by the
Java™ programming language.)
This implementation returns the hash code of Multiset.entrySet()
.
hashCode
in interface Multiset<E>
hashCode
in interface Collection<E>
hashCode
in class Object
Object.equals(java.lang.Object)
,
System.identityHashCode(java.lang.Object)
public final String toString()
String.valueOf(Object)
.
This implementation returns the result of invoking toString
on Multiset.entrySet()
.
toString
in interface Multiset<E>
toString
in class AbstractCollection<E>
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