@Beta public final class MinMaxPriorityQueue<E> extends AbstractQueue<E>
As a Queue
it functions exactly as a PriorityQueue
: its
head element -- the implicit target of the methods peek()
, poll()
and AbstractQueue.remove()
-- is defined as the least element in
the queue according to the queue's comparator. But unlike a regular priority
queue, the methods peekLast()
, pollLast()
and
removeLast()
are also provided, to act on the greatest element
in the queue instead.
A min-max priority queue can be configured with a maximum size. If so, each time the size of the queue exceeds that value, the queue automatically removes its greatest element according to its comparator (which might be the element that was just added). This is different from conventional bounded queues, which either block or reject new elements when full.
This implementation is based on the
min-max heap
developed by Atkinson, et al. Unlike many other double-ended priority queues,
it stores elements in a single array, as compact as the traditional heap data
structure used in PriorityQueue
.
This class is not thread-safe, and does not accept null elements.
Performance notes:
peek()
, peekFirst()
, peekLast()
, AbstractQueue.element()
, and size
are constant-time
offer(E)
, add(E)
, and
all the forms of poll()
and AbstractQueue.remove()
) run in O(log n) time
AbstractCollection.remove(Object)
and AbstractCollection.contains(java.lang.Object)
operations require
linear (O(n)
) time
PriorityQueue
, but
significantly slower.
Modifier and Type | Class and Description |
---|---|
static class |
MinMaxPriorityQueue.Builder<B>
The builder class used in creation of min-max priority queues.
|
Modifier and Type | Method and Description |
---|---|
boolean |
add(E element)
Adds the given element to this queue.
|
boolean |
addAll(Collection<? extends E> newElements) |
void |
clear() |
Comparator<? super E> |
comparator()
Returns the comparator used to order the elements in this queue.
|
static <E extends Comparable<E>> |
create()
Creates a new min-max priority queue with default settings: natural order,
no maximum size, no initial contents, and an initial expected size of 11.
|
static <E extends Comparable<E>> |
create(Iterable<? extends E> initialContents)
Creates a new min-max priority queue using natural order, no maximum size,
and initially containing the given elements.
|
static MinMaxPriorityQueue.Builder<Comparable> |
expectedSize(int expectedSize)
Creates and returns a new builder, configured to build
MinMaxPriorityQueue instances sized appropriately to hold expectedSize elements. |
Iterator<E> |
iterator()
Returns an iterator over the elements contained in this collection,
in no particular order.
|
static MinMaxPriorityQueue.Builder<Comparable> |
maximumSize(int maximumSize)
Creates and returns a new builder, configured to build
MinMaxPriorityQueue instances that are limited to maximumSize
elements. |
boolean |
offer(E element)
Adds the given element to this queue.
|
static <B> MinMaxPriorityQueue.Builder<B> |
orderedBy(Comparator<B> comparator)
Creates and returns a new builder, configured to build
MinMaxPriorityQueue instances that use comparator to determine the
least and greatest elements. |
E |
peek() |
E |
peekFirst()
Retrieves, but does not remove, the least element of this queue, or returns
null if the queue is empty. |
E |
peekLast()
Retrieves, but does not remove, the greatest element of this queue, or
returns
null if the queue is empty. |
E |
poll() |
E |
pollFirst()
Removes and returns the least element of this queue, or returns
null if the queue is empty. |
E |
pollLast()
Removes and returns the greatest element of this queue, or returns
null if the queue is empty. |
E |
removeFirst()
Removes and returns the least element of this queue.
|
E |
removeLast()
Removes and returns the greatest element of this queue.
|
int |
size() |
Object[] |
toArray() |
element, remove
contains, containsAll, isEmpty, remove, removeAll, retainAll, toArray, toString
clone, equals, finalize, getClass, hashCode, notify, notifyAll, wait, wait, wait
contains, containsAll, equals, hashCode, isEmpty, remove, removeAll, retainAll, toArray
public static <E extends Comparable<E>> MinMaxPriorityQueue<E> create()
public static <E extends Comparable<E>> MinMaxPriorityQueue<E> create(Iterable<? extends E> initialContents)
public static <B> MinMaxPriorityQueue.Builder<B> orderedBy(Comparator<B> comparator)
MinMaxPriorityQueue
instances that use comparator
to determine the
least and greatest elements.public static MinMaxPriorityQueue.Builder<Comparable> expectedSize(int expectedSize)
MinMaxPriorityQueue
instances sized appropriately to hold expectedSize
elements.public static MinMaxPriorityQueue.Builder<Comparable> maximumSize(int maximumSize)
MinMaxPriorityQueue
instances that are limited to maximumSize
elements. Each time a queue grows beyond this bound, it immediately
removes its greatest element (according to its comparator), which might be
the element that was just added.public int size()
size
in interface Collection<E>
size
in class AbstractCollection<E>
public boolean add(E element)
element
the queue will automatically evict its
greatest element (according to its comparator), which may be element
itself.add
in interface Collection<E>
add
in interface Queue<E>
add
in class AbstractQueue<E>
true
alwayspublic boolean addAll(Collection<? extends E> newElements)
addAll
in interface Collection<E>
addAll
in class AbstractQueue<E>
public boolean offer(E element)
element
the queue will automatically evict its
greatest element (according to its comparator), which may be element
itself.public E pollFirst()
null
if the queue is empty.public E removeFirst()
NoSuchElementException
- if the queue is emptypublic E peekFirst()
null
if the queue is empty.public E pollLast()
null
if the queue is empty.public E removeLast()
NoSuchElementException
- if the queue is emptypublic E peekLast()
null
if the queue is empty.public Iterator<E> iterator()
The iterator is fail-fast: If the MinMaxPriorityQueue is modified
at any time after the iterator is created, in any way except through the
iterator's own remove method, the iterator will generally throw a
ConcurrentModificationException
. Thus, in the face of concurrent
modification, the iterator fails quickly and cleanly, rather than risking
arbitrary, non-deterministic behavior at an undetermined time in the
future.
Note that the fail-fast behavior of an iterator cannot be guaranteed
as it is, generally speaking, impossible to make any hard guarantees in the
presence of unsynchronized concurrent modification. Fail-fast iterators
throw ConcurrentModificationException
on a best-effort basis.
Therefore, it would be wrong to write a program that depended on this
exception for its correctness: the fail-fast behavior of iterators
should be used only to detect bugs.
iterator
in interface Iterable<E>
iterator
in interface Collection<E>
iterator
in class AbstractCollection<E>
public void clear()
clear
in interface Collection<E>
clear
in class AbstractQueue<E>
public Object[] toArray()
toArray
in interface Collection<E>
toArray
in class AbstractCollection<E>
public Comparator<? super E> comparator()
PriorityQueue.comparator
, but returns Ordering.natural()
instead of null
to indicate natural ordering.Copyright © 2010-2013. All Rights Reserved.