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package java.util;
import java.util.function.IntFunction;
import java.util.function.Predicate;
import java.util.stream.Stream;
import java.util.stream.StreamSupport;
The root interface in the collection hierarchy. A collection
represents a group of objects, known as its elements. Some
collections allow duplicate elements and others do not. Some are ordered
and others unordered. The JDK does not provide any direct implementations of this interface: it provides implementations of more specific subinterfaces like Set
and List
. This interface is typically used to pass collections around and manipulate them where maximum generality is desired. Bags or multisets (unordered collections that may contain
duplicate elements) should implement this interface directly.
All general-purpose Collection
implementation classes (which typically implement Collection
indirectly through one of its subinterfaces) should provide two "standard" constructors: a void (no arguments) constructor, which creates an empty collection, and a constructor with a single argument of type Collection
, which creates a new collection with the same elements as its argument. In effect, the latter constructor allows the user to copy any collection, producing an equivalent collection of the desired implementation type. There is no way to enforce this convention (as interfaces cannot contain constructors) but all of the general-purpose Collection
implementations in the Java platform libraries comply.
Certain methods are specified to be
optional. If a collection implementation doesn't implement a particular operation, it should define the corresponding method to throw UnsupportedOperationException
. Such methods are marked "optional operation" in method specifications of the collections interfaces.
Some collection implementations have restrictions on the elements that they may contain. For example, some implementations prohibit null elements, and some have restrictions on the types of their elements. Attempting to add an ineligible element throws an unchecked exception, typically NullPointerException
or ClassCastException
. Attempting to query the presence of an ineligible element may throw an exception, or it may simply return false; some implementations will exhibit the former behavior and some will exhibit the latter. More generally, attempting an operation on an ineligible element whose completion would not result in the insertion of an ineligible element into the collection may throw an exception or it may succeed, at the option of the implementation. Such exceptions are marked as "optional" in the specification for this interface.
It is up to each collection to determine its own synchronization
policy. In the absence of a stronger guarantee by the
implementation, undefined behavior may result from the invocation
of any method on a collection that is being mutated by another
thread; this includes direct invocations, passing the collection to
a method that might perform invocations, and using an existing
iterator to examine the collection.
Many methods in Collections Framework interfaces are defined in terms of the equals
method. For example, the specification for the contains(Object o)
method says: "returns true
if and only if this collection contains at least one element e
such that (o==null ? e==null : o.equals(e))
." This specification should not be construed to imply that invoking Collection.contains
with a non-null argument o
will cause o.equals(e)
to be invoked for any element e
. Implementations are free to implement optimizations whereby the equals
invocation is avoided, for example, by first comparing the hash codes of the two elements. (The Object.hashCode()
specification guarantees that two objects with unequal hash codes cannot be equal.) More generally, implementations of the various Collections Framework interfaces are free to take advantage of the specified behavior of underlying Object
methods wherever the implementor deems it appropriate.
Some collection operations which perform recursive traversal of the collection may fail with an exception for self-referential instances where the collection directly or indirectly contains itself. This includes the clone()
, equals()
, hashCode()
and toString()
methods. Implementations may optionally handle the self-referential scenario, however most current implementations do not do so.
View Collections
Most collections manage storage for elements they contain. By contrast, view
collections themselves do not store elements, but instead they rely on a backing collection to store the actual elements. Operations that are not handled by the view collection itself are delegated to the backing collection. Examples of view collections include the wrapper collections returned by methods such as Collections.checkedCollection
, Collections.synchronizedCollection
, and Collections.unmodifiableCollection
. Other examples of view collections include collections that provide a different representation of the same elements, for example, as provided by List.subList
, NavigableSet.subSet
, or Map.entrySet
. Any changes made to the backing collection are visible in the view collection. Correspondingly, any changes made to the view collection — if changes are permitted — are written through to the backing collection. Although they technically aren't collections, instances of Iterator
and ListIterator
can also allow modifications to be written through to the backing collection, and in some cases, modifications to the backing collection will be visible to the Iterator during iteration.
Unmodifiable Collections
Certain methods of this interface are considered "destructive" and are called "mutator" methods in that they modify the group of objects contained within the collection on which they operate. They can be specified to throw UnsupportedOperationException
if this collection implementation does not support the operation. Such methods should (but are not required to) throw an UnsupportedOperationException
if the invocation would have no effect on the collection. For example, consider a collection that does not support the add
operation. What will happen if the addAll
method is invoked on this collection, with an empty collection as the argument? The addition of zero elements has no effect, so it is permissible for this collection simply to do nothing and not to throw an exception. However, it is recommended that such cases throw an exception unconditionally, as throwing only in certain cases can lead to programming errors.
An unmodifiable collection is a collection, all of whose mutator methods (as defined above) are specified to throw UnsupportedOperationException
. Such a collection thus cannot be modified by calling any methods on it. For a collection to be properly unmodifiable, any view collections derived from it must also be unmodifiable. For example, if a List is unmodifiable, the List returned by List.subList
is also unmodifiable.
An unmodifiable collection is not necessarily immutable. If the contained elements are mutable, the entire collection is clearly mutable, even though it might be unmodifiable. For example, consider two unmodifiable lists containing mutable elements. The result of calling list1.equals(list2)
might differ from one call to the next if the elements had been mutated, even though both lists are unmodifiable. However, if an unmodifiable collection contains all immutable elements, it can be considered effectively immutable.
Unmodifiable View Collections
An unmodifiable view collection is a collection that is unmodifiable and that is also a view onto a backing collection. Its mutator methods throw UnsupportedOperationException
, as described above, while reading and querying methods are delegated to the backing collection. The effect is to provide read-only access to the backing collection. This is useful for a component to provide users with read access to an internal collection, while preventing them from modifying such collections unexpectedly. Examples of unmodifiable view collections are those returned by the Collections.unmodifiableCollection
, Collections.unmodifiableList
, and related methods.
Note that changes to the backing collection might still be possible,
and if they occur, they are visible through the unmodifiable view. Thus,
an unmodifiable view collection is not necessarily immutable. However,
if the backing collection of an unmodifiable view is effectively immutable,
or if the only reference to the backing collection is through an
unmodifiable view, the view can be considered effectively immutable.
Serializability of Collections
Serializability of collections is optional. As such, none of the collections interfaces are declared to implement the Serializable
interface. However, serializability is regarded as being generally useful, so most collection implementations are serializable.
The collection implementations that are public classes (such as ArrayList
or HashMap
) are declared to implement the Serializable
interface if they are in fact serializable. Some collections implementations are not public classes, such as the unmodifiable collections. In such cases, the
serializability of such collections is described in the specification of the method
that creates them, or in some other suitable place. In cases where the serializability
of a collection is not specified, there is no guarantee about the serializability of such
collections. In particular, many view collections are not serializable.
A collection implementation that implements the Serializable
interface cannot be guaranteed to be serializable. The reason is that in general, collections contain elements of other types, and it is not possible to determine statically whether instances of some element type are actually serializable. For example, consider a serializable Collection<E>
, where E
does not implement the Serializable
interface. The collection may be serializable, if it contains only elements of some serializable subtype of E
, or if it is empty. Collections are thus said to be conditionally serializable, as the serializability of the collection
as a whole depends on whether the collection itself is serializable and on whether all
contained elements are also serializable.
An additional case occurs with instances of SortedSet
and SortedMap
. These collections can be created with a Comparator
that imposes an ordering on the set elements or map keys. Such a collection is serializable only if the provided Comparator
is also serializable.
This interface is a member of the
Java Collections Framework.
Author: Josh Bloch, Neal Gafter Type parameters: - <E> – the type of elements in this collection
See Also: Implementation Requirements: The default method implementations (inherited or otherwise) do not apply any synchronization protocol. If a Collection
implementation has a specific synchronization protocol, then it must override default implementations to apply that protocol. Since: 1.2
/**
* The root interface in the <i>collection hierarchy</i>. A collection
* represents a group of objects, known as its <i>elements</i>. Some
* collections allow duplicate elements and others do not. Some are ordered
* and others unordered. The JDK does not provide any <i>direct</i>
* implementations of this interface: it provides implementations of more
* specific subinterfaces like {@code Set} and {@code List}. This interface
* is typically used to pass collections around and manipulate them where
* maximum generality is desired.
*
* <p><i>Bags</i> or <i>multisets</i> (unordered collections that may contain
* duplicate elements) should implement this interface directly.
*
* <p>All general-purpose {@code Collection} implementation classes (which
* typically implement {@code Collection} indirectly through one of its
* subinterfaces) should provide two "standard" constructors: a void (no
* arguments) constructor, which creates an empty collection, and a
* constructor with a single argument of type {@code Collection}, which
* creates a new collection with the same elements as its argument. In
* effect, the latter constructor allows the user to copy any collection,
* producing an equivalent collection of the desired implementation type.
* There is no way to enforce this convention (as interfaces cannot contain
* constructors) but all of the general-purpose {@code Collection}
* implementations in the Java platform libraries comply.
*
* <p>Certain methods are specified to be
* <i>optional</i>. If a collection implementation doesn't implement a
* particular operation, it should define the corresponding method to throw
* {@code UnsupportedOperationException}. Such methods are marked "optional
* operation" in method specifications of the collections interfaces.
*
* <p><a id="optional-restrictions"></a>Some collection implementations
* have restrictions on the elements that they may contain.
* For example, some implementations prohibit null elements,
* and some have restrictions on the types of their elements. Attempting to
* add an ineligible element throws an unchecked exception, typically
* {@code NullPointerException} or {@code ClassCastException}. Attempting
* to query the presence of an ineligible element may throw an exception,
* or it may simply return false; some implementations will exhibit the former
* behavior and some will exhibit the latter. More generally, attempting an
* operation on an ineligible element whose completion would not result in
* the insertion of an ineligible element into the collection may throw an
* exception or it may succeed, at the option of the implementation.
* Such exceptions are marked as "optional" in the specification for this
* interface.
*
* <p>It is up to each collection to determine its own synchronization
* policy. In the absence of a stronger guarantee by the
* implementation, undefined behavior may result from the invocation
* of any method on a collection that is being mutated by another
* thread; this includes direct invocations, passing the collection to
* a method that might perform invocations, and using an existing
* iterator to examine the collection.
*
* <p>Many methods in Collections Framework interfaces are defined in
* terms of the {@link Object#equals(Object) equals} method. For example,
* the specification for the {@link #contains(Object) contains(Object o)}
* method says: "returns {@code true} if and only if this collection
* contains at least one element {@code e} such that
* {@code (o==null ? e==null : o.equals(e))}." This specification should
* <i>not</i> be construed to imply that invoking {@code Collection.contains}
* with a non-null argument {@code o} will cause {@code o.equals(e)} to be
* invoked for any element {@code e}. Implementations are free to implement
* optimizations whereby the {@code equals} invocation is avoided, for
* example, by first comparing the hash codes of the two elements. (The
* {@link Object#hashCode()} specification guarantees that two objects with
* unequal hash codes cannot be equal.) More generally, implementations of
* the various Collections Framework interfaces are free to take advantage of
* the specified behavior of underlying {@link Object} methods wherever the
* implementor deems it appropriate.
*
* <p>Some collection operations which perform recursive traversal of the
* collection may fail with an exception for self-referential instances where
* the collection directly or indirectly contains itself. This includes the
* {@code clone()}, {@code equals()}, {@code hashCode()} and {@code toString()}
* methods. Implementations may optionally handle the self-referential scenario,
* however most current implementations do not do so.
*
* <h2><a id="view">View Collections</a></h2>
*
* <p>Most collections manage storage for elements they contain. By contrast, <i>view
* collections</i> themselves do not store elements, but instead they rely on a
* backing collection to store the actual elements. Operations that are not handled
* by the view collection itself are delegated to the backing collection. Examples of
* view collections include the wrapper collections returned by methods such as
* {@link Collections#checkedCollection Collections.checkedCollection},
* {@link Collections#synchronizedCollection Collections.synchronizedCollection}, and
* {@link Collections#unmodifiableCollection Collections.unmodifiableCollection}.
* Other examples of view collections include collections that provide a
* different representation of the same elements, for example, as
* provided by {@link List#subList List.subList},
* {@link NavigableSet#subSet NavigableSet.subSet}, or
* {@link Map#entrySet Map.entrySet}.
* Any changes made to the backing collection are visible in the view collection.
* Correspondingly, any changes made to the view collection — if changes
* are permitted — are written through to the backing collection.
* Although they technically aren't collections, instances of
* {@link Iterator} and {@link ListIterator} can also allow modifications
* to be written through to the backing collection, and in some cases,
* modifications to the backing collection will be visible to the Iterator
* during iteration.
*
* <h2><a id="unmodifiable">Unmodifiable Collections</a></h2>
*
* <p>Certain methods of this interface are considered "destructive" and are called
* "mutator" methods in that they modify the group of objects contained within
* the collection on which they operate. They can be specified to throw
* {@code UnsupportedOperationException} if this collection implementation
* does not support the operation. Such methods should (but are not required
* to) throw an {@code UnsupportedOperationException} if the invocation would
* have no effect on the collection. For example, consider a collection that
* does not support the {@link #add add} operation. What will happen if the
* {@link #addAll addAll} method is invoked on this collection, with an empty
* collection as the argument? The addition of zero elements has no effect,
* so it is permissible for this collection simply to do nothing and not to throw
* an exception. However, it is recommended that such cases throw an exception
* unconditionally, as throwing only in certain cases can lead to
* programming errors.
*
* <p>An <i>unmodifiable collection</i> is a collection, all of whose
* mutator methods (as defined above) are specified to throw
* {@code UnsupportedOperationException}. Such a collection thus cannot be
* modified by calling any methods on it. For a collection to be properly
* unmodifiable, any view collections derived from it must also be unmodifiable.
* For example, if a List is unmodifiable, the List returned by
* {@link List#subList List.subList} is also unmodifiable.
*
* <p>An unmodifiable collection is not necessarily immutable. If the
* contained elements are mutable, the entire collection is clearly
* mutable, even though it might be unmodifiable. For example, consider
* two unmodifiable lists containing mutable elements. The result of calling
* {@code list1.equals(list2)} might differ from one call to the next if
* the elements had been mutated, even though both lists are unmodifiable.
* However, if an unmodifiable collection contains all immutable elements,
* it can be considered effectively immutable.
*
* <h2><a id="unmodview">Unmodifiable View Collections</a></h2>
*
* <p>An <i>unmodifiable view collection</i> is a collection that is unmodifiable
* and that is also a view onto a backing collection. Its mutator methods throw
* {@code UnsupportedOperationException}, as described above, while
* reading and querying methods are delegated to the backing collection.
* The effect is to provide read-only access to the backing collection.
* This is useful for a component to provide users with read access to
* an internal collection, while preventing them from modifying such
* collections unexpectedly. Examples of unmodifiable view collections
* are those returned by the
* {@link Collections#unmodifiableCollection Collections.unmodifiableCollection},
* {@link Collections#unmodifiableList Collections.unmodifiableList}, and
* related methods.
*
* <p>Note that changes to the backing collection might still be possible,
* and if they occur, they are visible through the unmodifiable view. Thus,
* an unmodifiable view collection is not necessarily immutable. However,
* if the backing collection of an unmodifiable view is effectively immutable,
* or if the only reference to the backing collection is through an
* unmodifiable view, the view can be considered effectively immutable.
*
* <h2><a id="serializable">Serializability of Collections</a></h2>
*
* <p>Serializability of collections is optional. As such, none of the collections
* interfaces are declared to implement the {@link java.io.Serializable} interface.
* However, serializability is regarded as being generally useful, so most collection
* implementations are serializable.
*
* <p>The collection implementations that are public classes (such as {@code ArrayList}
* or {@code HashMap}) are declared to implement the {@code Serializable} interface if they
* are in fact serializable. Some collections implementations are not public classes,
* such as the <a href="#unmodifiable">unmodifiable collections.</a> In such cases, the
* serializability of such collections is described in the specification of the method
* that creates them, or in some other suitable place. In cases where the serializability
* of a collection is not specified, there is no guarantee about the serializability of such
* collections. In particular, many <a href="#view">view collections</a> are not serializable.
*
* <p>A collection implementation that implements the {@code Serializable} interface cannot
* be guaranteed to be serializable. The reason is that in general, collections
* contain elements of other types, and it is not possible to determine statically
* whether instances of some element type are actually serializable. For example, consider
* a serializable {@code Collection<E>}, where {@code E} does not implement the
* {@code Serializable} interface. The collection may be serializable, if it contains only
* elements of some serializable subtype of {@code E}, or if it is empty. Collections are
* thus said to be <i>conditionally serializable,</i> as the serializability of the collection
* as a whole depends on whether the collection itself is serializable and on whether all
* contained elements are also serializable.
*
* <p>An additional case occurs with instances of {@link SortedSet} and {@link SortedMap}.
* These collections can be created with a {@link Comparator} that imposes an ordering on
* the set elements or map keys. Such a collection is serializable only if the provided
* {@code Comparator} is also serializable.
*
* <p>This interface is a member of the
* <a href="{@docRoot}/java.base/java/util/package-summary.html#CollectionsFramework">
* Java Collections Framework</a>.
*
* @implSpec
* The default method implementations (inherited or otherwise) do not apply any
* synchronization protocol. If a {@code Collection} implementation has a
* specific synchronization protocol, then it must override default
* implementations to apply that protocol.
*
* @param <E> the type of elements in this collection
*
* @author Josh Bloch
* @author Neal Gafter
* @see Set
* @see List
* @see Map
* @see SortedSet
* @see SortedMap
* @see HashSet
* @see TreeSet
* @see ArrayList
* @see LinkedList
* @see Vector
* @see Collections
* @see Arrays
* @see AbstractCollection
* @since 1.2
*/
public interface Collection<E> extends Iterable<E> {
// Query Operations
Returns the number of elements in this collection. If this collection contains more than Integer.MAX_VALUE
elements, returns Integer.MAX_VALUE
. Returns: the number of elements in this collection
/**
* Returns the number of elements in this collection. If this collection
* contains more than {@code Integer.MAX_VALUE} elements, returns
* {@code Integer.MAX_VALUE}.
*
* @return the number of elements in this collection
*/
int size();
Returns true
if this collection contains no elements. Returns: true
if this collection contains no elements
/**
* Returns {@code true} if this collection contains no elements.
*
* @return {@code true} if this collection contains no elements
*/
boolean isEmpty();
Returns true
if this collection contains the specified element. More formally, returns true
if and only if this collection contains at least one element e
such that Objects.equals(o, e)
. Params: - o – element whose presence in this collection is to be tested
Throws: - ClassCastException – if the type of the specified element
is incompatible with this collection
(optional)
- NullPointerException – if the specified element is null and this
collection does not permit null elements
(optional)
Returns: true
if this collection contains the specified element
/**
* Returns {@code true} if this collection contains the specified element.
* More formally, returns {@code true} if and only if this collection
* contains at least one element {@code e} such that
* {@code Objects.equals(o, e)}.
*
* @param o element whose presence in this collection is to be tested
* @return {@code true} if this collection contains the specified
* element
* @throws ClassCastException if the type of the specified element
* is incompatible with this collection
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
* @throws NullPointerException if the specified element is null and this
* collection does not permit null elements
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
*/
boolean contains(Object o);
Returns an iterator over the elements in this collection. There are no
guarantees concerning the order in which the elements are returned
(unless this collection is an instance of some class that provides a
guarantee).
Returns: an Iterator
over the elements in this collection
/**
* Returns an iterator over the elements in this collection. There are no
* guarantees concerning the order in which the elements are returned
* (unless this collection is an instance of some class that provides a
* guarantee).
*
* @return an {@code Iterator} over the elements in this collection
*/
Iterator<E> iterator();
Returns an array containing all of the elements in this collection. If this collection makes any guarantees as to what order its elements are returned by its iterator, this method must return the elements in the same order. The returned array's
runtime component type is Object
. The returned array will be "safe" in that no references to it are
maintained by this collection. (In other words, this method must
allocate a new array even if this collection is backed by an array).
The caller is thus free to modify the returned array.
API Note: This method acts as a bridge between array-based and collection-based APIs. It returns an array whose runtime type is Object[]
. Use toArray(T[])
to reuse an existing array, or use toArray(IntFunction)
to control the runtime type of the array. Returns: an array, whose runtime component
type is Object
, containing all of the elements in this collection
/**
* Returns an array containing all of the elements in this collection.
* If this collection makes any guarantees as to what order its elements
* are returned by its iterator, this method must return the elements in
* the same order. The returned array's {@linkplain Class#getComponentType
* runtime component type} is {@code Object}.
*
* <p>The returned array will be "safe" in that no references to it are
* maintained by this collection. (In other words, this method must
* allocate a new array even if this collection is backed by an array).
* The caller is thus free to modify the returned array.
*
* @apiNote
* This method acts as a bridge between array-based and collection-based APIs.
* It returns an array whose runtime type is {@code Object[]}.
* Use {@link #toArray(Object[]) toArray(T[])} to reuse an existing
* array, or use {@link #toArray(IntFunction)} to control the runtime type
* of the array.
*
* @return an array, whose {@linkplain Class#getComponentType runtime component
* type} is {@code Object}, containing all of the elements in this collection
*/
Object[] toArray();
Returns an array containing all of the elements in this collection;
the runtime type of the returned array is that of the specified array.
If the collection fits in the specified array, it is returned therein.
Otherwise, a new array is allocated with the runtime type of the
specified array and the size of this collection.
If this collection fits in the specified array with room to spare (i.e., the array has more elements than this collection), the element in the array immediately following the end of the collection is set to null
. (This is useful in determining the length of this collection only if the caller knows that this collection does not contain any null
elements.)
If this collection makes any guarantees as to what order its elements
are returned by its iterator, this method must return the elements in
the same order.
Params: - a – the array into which the elements of this collection are to be
stored, if it is big enough; otherwise, a new array of the same
runtime type is allocated for this purpose.
Type parameters: - <T> – the component type of the array to contain the collection
Throws: - ArrayStoreException – if the runtime type of any element in this collection is not assignable to the
runtime component type of the specified array
- NullPointerException – if the specified array is null
API Note: This method acts as a bridge between array-based and collection-based APIs. It allows an existing array to be reused under certain circumstances. Use toArray()
to create an array whose runtime type is Object[]
, or use toArray(IntFunction)
to control the runtime type of the array. Suppose x
is a collection known to contain only strings. The following code can be used to dump the collection into a previously allocated String
array:
String[] y = new String[SIZE];
...
y = x.toArray(y);
The return value is reassigned to the variable y
, because a new array will be allocated and returned if the collection x
has too many elements to fit into the existing array y
.
Note that toArray(new Object[0])
is identical in function to toArray()
.
Returns: an array containing all of the elements in this collection
/**
* Returns an array containing all of the elements in this collection;
* the runtime type of the returned array is that of the specified array.
* If the collection fits in the specified array, it is returned therein.
* Otherwise, a new array is allocated with the runtime type of the
* specified array and the size of this collection.
*
* <p>If this collection fits in the specified array with room to spare
* (i.e., the array has more elements than this collection), the element
* in the array immediately following the end of the collection is set to
* {@code null}. (This is useful in determining the length of this
* collection <i>only</i> if the caller knows that this collection does
* not contain any {@code null} elements.)
*
* <p>If this collection makes any guarantees as to what order its elements
* are returned by its iterator, this method must return the elements in
* the same order.
*
* @apiNote
* This method acts as a bridge between array-based and collection-based APIs.
* It allows an existing array to be reused under certain circumstances.
* Use {@link #toArray()} to create an array whose runtime type is {@code Object[]},
* or use {@link #toArray(IntFunction)} to control the runtime type of
* the array.
*
* <p>Suppose {@code x} is a collection known to contain only strings.
* The following code can be used to dump the collection into a previously
* allocated {@code String} array:
*
* <pre>
* String[] y = new String[SIZE];
* ...
* y = x.toArray(y);</pre>
*
* <p>The return value is reassigned to the variable {@code y}, because a
* new array will be allocated and returned if the collection {@code x} has
* too many elements to fit into the existing array {@code y}.
*
* <p>Note that {@code toArray(new Object[0])} is identical in function to
* {@code toArray()}.
*
* @param <T> the component type of the array to contain the collection
* @param a the array into which the elements of this collection are to be
* stored, if it is big enough; otherwise, a new array of the same
* runtime type is allocated for this purpose.
* @return an array containing all of the elements in this collection
* @throws ArrayStoreException if the runtime type of any element in this
* collection is not assignable to the {@linkplain Class#getComponentType
* runtime component type} of the specified array
* @throws NullPointerException if the specified array is null
*/
<T> T[] toArray(T[] a);
Returns an array containing all of the elements in this collection, using the provided generator
function to allocate the returned array. If this collection makes any guarantees as to what order its elements
are returned by its iterator, this method must return the elements in
the same order.
Params: - generator – a function which produces a new array of the desired
type and the provided length
Type parameters: - <T> – the component type of the array to contain the collection
Throws: - ArrayStoreException – if the runtime type of any element in this collection is not assignable to the
runtime component type of the generated array
- NullPointerException – if the generator function is null
API Note: This method acts as a bridge between array-based and collection-based APIs. It allows creation of an array of a particular runtime type. Use toArray()
to create an array whose runtime type is Object[]
, or use toArray(T[])
to reuse an existing array. Suppose x
is a collection known to contain only strings. The following code can be used to dump the collection into a newly allocated array of String
:
String[] y = x.toArray(String[]::new);
Implementation Requirements: The default implementation calls the generator function with zero and then passes the resulting array to toArray(T[])
. Returns: an array containing all of the elements in this collection Since: 11
/**
* Returns an array containing all of the elements in this collection,
* using the provided {@code generator} function to allocate the returned array.
*
* <p>If this collection makes any guarantees as to what order its elements
* are returned by its iterator, this method must return the elements in
* the same order.
*
* @apiNote
* This method acts as a bridge between array-based and collection-based APIs.
* It allows creation of an array of a particular runtime type. Use
* {@link #toArray()} to create an array whose runtime type is {@code Object[]},
* or use {@link #toArray(Object[]) toArray(T[])} to reuse an existing array.
*
* <p>Suppose {@code x} is a collection known to contain only strings.
* The following code can be used to dump the collection into a newly
* allocated array of {@code String}:
*
* <pre>
* String[] y = x.toArray(String[]::new);</pre>
*
* @implSpec
* The default implementation calls the generator function with zero
* and then passes the resulting array to {@link #toArray(Object[]) toArray(T[])}.
*
* @param <T> the component type of the array to contain the collection
* @param generator a function which produces a new array of the desired
* type and the provided length
* @return an array containing all of the elements in this collection
* @throws ArrayStoreException if the runtime type of any element in this
* collection is not assignable to the {@linkplain Class#getComponentType
* runtime component type} of the generated array
* @throws NullPointerException if the generator function is null
* @since 11
*/
default <T> T[] toArray(IntFunction<T[]> generator) {
return toArray(generator.apply(0));
}
// Modification Operations
Ensures that this collection contains the specified element (optional operation). Returns true
if this collection changed as a result of the call. (Returns false
if this collection does not permit duplicates and already contains the specified element.) 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.
Params: - e – element whose presence in this collection is to be ensured
Throws: - UnsupportedOperationException – if the
add
operation is not supported by this collection - ClassCastException – if the class of the specified element
prevents it from being added to this collection
- NullPointerException – if the specified element is null and this
collection does not permit null elements
- IllegalArgumentException – if some property of the element
prevents it from being added to this collection
- IllegalStateException – if the element cannot be added at this
time due to insertion restrictions
Returns: true
if this collection changed as a result of the call
/**
* Ensures that this collection contains the specified element (optional
* operation). Returns {@code true} if this collection changed as a
* result of the call. (Returns {@code false} if this collection does
* not permit duplicates and already contains the specified element.)<p>
*
* 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 {@code 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.<p>
*
* If a collection refuses to add a particular element for any reason
* other than that it already contains the element, it <i>must</i> throw
* an exception (rather than returning {@code false}). This preserves
* the invariant that a collection always contains the specified element
* after this call returns.
*
* @param e element whose presence in this collection is to be ensured
* @return {@code true} if this collection changed as a result of the
* call
* @throws UnsupportedOperationException if the {@code add} operation
* is not supported by this collection
* @throws ClassCastException if the class of the specified element
* prevents it from being added to this collection
* @throws NullPointerException if the specified element is null and this
* collection does not permit null elements
* @throws IllegalArgumentException if some property of the element
* prevents it from being added to this collection
* @throws IllegalStateException if the element cannot be added at this
* time due to insertion restrictions
*/
boolean add(E e);
Removes a single instance of the specified element from this collection, if it is present (optional operation). More formally, removes an element e
such that Objects.equals(o, e)
, if this collection contains one or more such elements. Returns true
if this collection contained the specified element (or equivalently, if this collection changed as a result of the call). Params: - o – element to be removed from this collection, if present
Throws: - ClassCastException – if the type of the specified element
is incompatible with this collection
(optional)
- NullPointerException – if the specified element is null and this
collection does not permit null elements
(optional)
- UnsupportedOperationException – if the
remove
operation is not supported by this collection
Returns: true
if an element was removed as a result of this call
/**
* Removes a single instance of the specified element from this
* collection, if it is present (optional operation). More formally,
* removes an element {@code e} such that
* {@code Objects.equals(o, e)}, if
* this collection contains one or more such elements. Returns
* {@code true} if this collection contained the specified element (or
* equivalently, if this collection changed as a result of the call).
*
* @param o element to be removed from this collection, if present
* @return {@code true} if an element was removed as a result of this call
* @throws ClassCastException if the type of the specified element
* is incompatible with this collection
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
* @throws NullPointerException if the specified element is null and this
* collection does not permit null elements
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
* @throws UnsupportedOperationException if the {@code remove} operation
* is not supported by this collection
*/
boolean remove(Object o);
// Bulk Operations
Returns true
if this collection contains all of the elements in the specified collection. Params: - c – collection to be checked for containment in this collection
Throws: - ClassCastException – if the types of one or more elements
in the specified collection are incompatible with this
collection
(optional)
- NullPointerException – if the specified collection contains one
or more null elements and this collection does not permit null
elements
(optional),
or if the specified collection is null.
See Also: Returns: true
if this collection contains all of the elements in the specified collection
/**
* Returns {@code true} if this collection contains all of the elements
* in the specified collection.
*
* @param c collection to be checked for containment in this collection
* @return {@code true} if this collection contains all of the elements
* in the specified collection
* @throws ClassCastException if the types of one or more elements
* in the specified collection are incompatible with this
* collection
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
* @throws NullPointerException if the specified collection contains one
* or more null elements and this collection does not permit null
* elements
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>),
* or if the specified collection is null.
* @see #contains(Object)
*/
boolean containsAll(Collection<?> c);
Adds all of the elements in the specified collection to this collection
(optional operation). The behavior of this operation is undefined if
the specified collection is modified while the operation is in progress.
(This implies that the behavior of this call is undefined if the
specified collection is this collection, and this collection is
nonempty.)
Params: - c – collection containing elements to be added to this collection
Throws: - UnsupportedOperationException – if the
addAll
operation is not supported by this collection - ClassCastException – if the class of an element of the specified
collection prevents it from being added to this collection
- NullPointerException – if the specified collection contains a
null element and this collection does not permit null elements,
or if the specified collection is null
- IllegalArgumentException – if some property of an element of the
specified collection prevents it from being added to this
collection
- IllegalStateException – if not all the elements can be added at
this time due to insertion restrictions
See Also: Returns: true
if this collection changed as a result of the call
/**
* Adds all of the elements in the specified collection to this collection
* (optional operation). The behavior of this operation is undefined if
* the specified collection is modified while the operation is in progress.
* (This implies that the behavior of this call is undefined if the
* specified collection is this collection, and this collection is
* nonempty.)
*
* @param c collection containing elements to be added to this collection
* @return {@code true} if this collection changed as a result of the call
* @throws UnsupportedOperationException if the {@code addAll} operation
* is not supported by this collection
* @throws ClassCastException if the class of an element of the specified
* collection prevents it from being added to this collection
* @throws NullPointerException if the specified collection contains a
* null element and this collection does not permit null elements,
* or if the specified collection is null
* @throws IllegalArgumentException if some property of an element of the
* specified collection prevents it from being added to this
* collection
* @throws IllegalStateException if not all the elements can be added at
* this time due to insertion restrictions
* @see #add(Object)
*/
boolean addAll(Collection<? extends E> c);
Removes all of this collection's elements that are also contained in the
specified collection (optional operation). After this call returns,
this collection will contain no elements in common with the specified
collection.
Params: - c – collection containing elements to be removed from this collection
Throws: - UnsupportedOperationException – if the
removeAll
method is not supported by this collection - ClassCastException – if the types of one or more elements
in this collection are incompatible with the specified
collection
(optional)
- NullPointerException – if this collection contains one or more
null elements and the specified collection does not support
null elements
(optional),
or if the specified collection is null
See Also: Returns: true
if this collection changed as a result of the call
/**
* Removes all of this collection's elements that are also contained in the
* specified collection (optional operation). After this call returns,
* this collection will contain no elements in common with the specified
* collection.
*
* @param c collection containing elements to be removed from this collection
* @return {@code true} if this collection changed as a result of the
* call
* @throws UnsupportedOperationException if the {@code removeAll} method
* is not supported by this collection
* @throws ClassCastException if the types of one or more elements
* in this collection are incompatible with the specified
* collection
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
* @throws NullPointerException if this collection contains one or more
* null elements and the specified collection does not support
* null elements
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>),
* or if the specified collection is null
* @see #remove(Object)
* @see #contains(Object)
*/
boolean removeAll(Collection<?> c);
Removes all of the elements of this collection that satisfy the given
predicate. Errors or runtime exceptions thrown during iteration or by
the predicate are relayed to the caller.
Params: - filter – a predicate which returns
true
for elements to be removed
Throws: - NullPointerException – if the specified filter is null
- UnsupportedOperationException – if elements cannot be removed
from this collection. Implementations may throw this exception if a
matching element cannot be removed or if, in general, removal is not
supported.
Implementation Requirements: The default implementation traverses all elements of the collection using its iterator
. Each matching element is removed using Iterator.remove()
. If the collection's iterator does not support removal then an UnsupportedOperationException
will be thrown on the first matching element. Returns: true
if any elements were removedSince: 1.8
/**
* Removes all of the elements of this collection that satisfy the given
* predicate. Errors or runtime exceptions thrown during iteration or by
* the predicate are relayed to the caller.
*
* @implSpec
* The default implementation traverses all elements of the collection using
* its {@link #iterator}. Each matching element is removed using
* {@link Iterator#remove()}. If the collection's iterator does not
* support removal then an {@code UnsupportedOperationException} will be
* thrown on the first matching element.
*
* @param filter a predicate which returns {@code true} for elements to be
* removed
* @return {@code true} if any elements were removed
* @throws NullPointerException if the specified filter is null
* @throws UnsupportedOperationException if elements cannot be removed
* from this collection. Implementations may throw this exception if a
* matching element cannot be removed or if, in general, removal is not
* supported.
* @since 1.8
*/
default boolean removeIf(Predicate<? super E> filter) {
Objects.requireNonNull(filter);
boolean removed = false;
final Iterator<E> each = iterator();
while (each.hasNext()) {
if (filter.test(each.next())) {
each.remove();
removed = true;
}
}
return removed;
}
Retains only the elements in this collection that are contained in the
specified collection (optional operation). In other words, removes from
this collection all of its elements that are not contained in the
specified collection.
Params: - c – collection containing elements to be retained in this collection
Throws: - UnsupportedOperationException – if the
retainAll
operation is not supported by this collection - ClassCastException – if the types of one or more elements
in this collection are incompatible with the specified
collection
(optional)
- NullPointerException – if this collection contains one or more
null elements and the specified collection does not permit null
elements
(optional),
or if the specified collection is null
See Also: Returns: true
if this collection changed as a result of the call
/**
* Retains only the elements in this collection that are contained in the
* specified collection (optional operation). In other words, removes from
* this collection all of its elements that are not contained in the
* specified collection.
*
* @param c collection containing elements to be retained in this collection
* @return {@code true} if this collection changed as a result of the call
* @throws UnsupportedOperationException if the {@code retainAll} operation
* is not supported by this collection
* @throws ClassCastException if the types of one or more elements
* in this collection are incompatible with the specified
* collection
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>)
* @throws NullPointerException if this collection contains one or more
* null elements and the specified collection does not permit null
* elements
* (<a href="{@docRoot}/java.base/java/util/Collection.html#optional-restrictions">optional</a>),
* or if the specified collection is null
* @see #remove(Object)
* @see #contains(Object)
*/
boolean retainAll(Collection<?> c);
Removes all of the elements from this collection (optional operation).
The collection will be empty after this method returns.
Throws: - UnsupportedOperationException – if the
clear
operation is not supported by this collection
/**
* Removes all of the elements from this collection (optional operation).
* The collection will be empty after this method returns.
*
* @throws UnsupportedOperationException if the {@code clear} operation
* is not supported by this collection
*/
void clear();
// Comparison and hashing
Compares the specified object with this collection for equality. While the Collection
interface adds no stipulations to the general contract for the Object.equals
, programmers who implement the Collection
interface "directly" (in other words, create a class that is a Collection
but is not a Set
or a List
) must exercise care if they choose to override the Object.equals
. It is not necessary to do so, and the simplest course of action is to rely on Object
's implementation, but the implementor may wish to implement a "value comparison" in place of the default "reference comparison." (The List
and Set
interfaces mandate such value comparisons.)
The general contract for the Object.equals
method states that equals must be symmetric (in other words, a.equals(b)
if and only if b.equals(a)
). The contracts for List.equals
and Set.equals
state that lists are only equal to other lists, and sets to other sets. Thus, a custom equals
method for a collection class that implements neither the List
nor Set
interface must return false
when this collection is compared to any list or set. (By the same logic, it is not possible to write a class that correctly implements both the Set
and List
interfaces.)
Params: - o – object to be compared for equality with this collection
See Also: Returns: true
if the specified object is equal to this collection
/**
* Compares the specified object with this collection for equality. <p>
*
* While the {@code Collection} interface adds no stipulations to the
* general contract for the {@code Object.equals}, programmers who
* implement the {@code Collection} interface "directly" (in other words,
* create a class that is a {@code Collection} but is not a {@code Set}
* or a {@code List}) must exercise care if they choose to override the
* {@code Object.equals}. It is not necessary to do so, and the simplest
* course of action is to rely on {@code Object}'s implementation, but
* the implementor may wish to implement a "value comparison" in place of
* the default "reference comparison." (The {@code List} and
* {@code Set} interfaces mandate such value comparisons.)<p>
*
* The general contract for the {@code Object.equals} method states that
* equals must be symmetric (in other words, {@code a.equals(b)} if and
* only if {@code b.equals(a)}). The contracts for {@code List.equals}
* and {@code Set.equals} state that lists are only equal to other lists,
* and sets to other sets. Thus, a custom {@code equals} method for a
* collection class that implements neither the {@code List} nor
* {@code Set} interface must return {@code false} when this collection
* is compared to any list or set. (By the same logic, it is not possible
* to write a class that correctly implements both the {@code Set} and
* {@code List} interfaces.)
*
* @param o object to be compared for equality with this collection
* @return {@code true} if the specified object is equal to this
* collection
*
* @see Object#equals(Object)
* @see Set#equals(Object)
* @see List#equals(Object)
*/
boolean equals(Object o);
Returns the hash code value for this collection. While the Collection
interface adds no stipulations to the general contract for the Object.hashCode
method, programmers should take note that any class that overrides the Object.equals
method must also override the Object.hashCode
method in order to satisfy the general contract for the Object.hashCode
method. In particular, c1.equals(c2)
implies that c1.hashCode()==c2.hashCode()
. See Also: Returns: the hash code value for this collection
/**
* Returns the hash code value for this collection. While the
* {@code Collection} interface adds no stipulations to the general
* contract for the {@code Object.hashCode} method, programmers should
* take note that any class that overrides the {@code Object.equals}
* method must also override the {@code Object.hashCode} method in order
* to satisfy the general contract for the {@code Object.hashCode} method.
* In particular, {@code c1.equals(c2)} implies that
* {@code c1.hashCode()==c2.hashCode()}.
*
* @return the hash code value for this collection
*
* @see Object#hashCode()
* @see Object#equals(Object)
*/
int hashCode();
Creates a Spliterator
over the elements in this collection. Implementations should document characteristic values reported by the spliterator. Such characteristic values are not required to be reported if the spliterator reports Spliterator.SIZED
and this collection contains no elements. The default implementation should be overridden by subclasses that can return a more efficient spliterator. In order to preserve expected laziness behavior for the stream()
and parallelStream()
methods, spliterators should either have the characteristic of IMMUTABLE
or CONCURRENT
, or be late-binding. If none of these is practical, the overriding class should describe the spliterator's documented policy of binding and structural interference, and should override the stream()
and parallelStream()
methods to create streams using a Supplier
of the spliterator, as in:
Stream<E> s = StreamSupport.stream(() -> spliterator(), spliteratorCharacteristics)
These requirements ensure that streams produced by the stream()
and parallelStream()
methods will reflect the contents of the collection as of initiation of the terminal stream operation.
Implementation Requirements:
The default implementation creates a
late-binding spliterator from the collection's Iterator
. The spliterator inherits the fail-fast properties of the collection's iterator.
The created Spliterator
reports Spliterator.SIZED
.
Implementation Note: The created Spliterator
additionally reports Spliterator.SUBSIZED
. If a spliterator covers no elements then the reporting of additional characteristic values, beyond that of SIZED
and SUBSIZED
, does not aid clients to control, specialize or simplify computation. However, this does enable shared use of an immutable and empty spliterator instance (see Spliterators.emptySpliterator()
) for empty collections, and enables clients to determine if such a spliterator covers no elements.
Returns: a Spliterator
over the elements in this collection Since: 1.8
/**
* Creates a {@link Spliterator} over the elements in this collection.
*
* Implementations should document characteristic values reported by the
* spliterator. Such characteristic values are not required to be reported
* if the spliterator reports {@link Spliterator#SIZED} and this collection
* contains no elements.
*
* <p>The default implementation should be overridden by subclasses that
* can return a more efficient spliterator. In order to
* preserve expected laziness behavior for the {@link #stream()} and
* {@link #parallelStream()} methods, spliterators should either have the
* characteristic of {@code IMMUTABLE} or {@code CONCURRENT}, or be
* <em><a href="Spliterator.html#binding">late-binding</a></em>.
* If none of these is practical, the overriding class should describe the
* spliterator's documented policy of binding and structural interference,
* and should override the {@link #stream()} and {@link #parallelStream()}
* methods to create streams using a {@code Supplier} of the spliterator,
* as in:
* <pre>{@code
* Stream<E> s = StreamSupport.stream(() -> spliterator(), spliteratorCharacteristics)
* }</pre>
* <p>These requirements ensure that streams produced by the
* {@link #stream()} and {@link #parallelStream()} methods will reflect the
* contents of the collection as of initiation of the terminal stream
* operation.
*
* @implSpec
* The default implementation creates a
* <em><a href="Spliterator.html#binding">late-binding</a></em> spliterator
* from the collection's {@code Iterator}. The spliterator inherits the
* <em>fail-fast</em> properties of the collection's iterator.
* <p>
* The created {@code Spliterator} reports {@link Spliterator#SIZED}.
*
* @implNote
* The created {@code Spliterator} additionally reports
* {@link Spliterator#SUBSIZED}.
*
* <p>If a spliterator covers no elements then the reporting of additional
* characteristic values, beyond that of {@code SIZED} and {@code SUBSIZED},
* does not aid clients to control, specialize or simplify computation.
* However, this does enable shared use of an immutable and empty
* spliterator instance (see {@link Spliterators#emptySpliterator()}) for
* empty collections, and enables clients to determine if such a spliterator
* covers no elements.
*
* @return a {@code Spliterator} over the elements in this collection
* @since 1.8
*/
@Override
default Spliterator<E> spliterator() {
return Spliterators.spliterator(this, 0);
}
Returns a sequential Stream
with this collection as its source. This method should be overridden when the spliterator()
method cannot return a spliterator that is IMMUTABLE
, CONCURRENT
, or late-binding. (See spliterator()
for details.)
Implementation Requirements: The default implementation creates a sequential Stream
from the collection's Spliterator
. Returns: a sequential Stream
over the elements in this collection Since: 1.8
/**
* Returns a sequential {@code Stream} with this collection as its source.
*
* <p>This method should be overridden when the {@link #spliterator()}
* method cannot return a spliterator that is {@code IMMUTABLE},
* {@code CONCURRENT}, or <em>late-binding</em>. (See {@link #spliterator()}
* for details.)
*
* @implSpec
* The default implementation creates a sequential {@code Stream} from the
* collection's {@code Spliterator}.
*
* @return a sequential {@code Stream} over the elements in this collection
* @since 1.8
*/
default Stream<E> stream() {
return StreamSupport.stream(spliterator(), false);
}
Returns a possibly parallel Stream
with this collection as its source. It is allowable for this method to return a sequential stream. This method should be overridden when the spliterator()
method cannot return a spliterator that is IMMUTABLE
, CONCURRENT
, or late-binding. (See spliterator()
for details.)
Implementation Requirements: The default implementation creates a parallel Stream
from the collection's Spliterator
. Returns: a possibly parallel Stream
over the elements in this collection Since: 1.8
/**
* Returns a possibly parallel {@code Stream} with this collection as its
* source. It is allowable for this method to return a sequential stream.
*
* <p>This method should be overridden when the {@link #spliterator()}
* method cannot return a spliterator that is {@code IMMUTABLE},
* {@code CONCURRENT}, or <em>late-binding</em>. (See {@link #spliterator()}
* for details.)
*
* @implSpec
* The default implementation creates a parallel {@code Stream} from the
* collection's {@code Spliterator}.
*
* @return a possibly parallel {@code Stream} over the elements in this
* collection
* @since 1.8
*/
default Stream<E> parallelStream() {
return StreamSupport.stream(spliterator(), true);
}
}