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Learn more about: queue Class |
queue Class |
11/04/2016 |
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A template container adaptor class that provides a restriction of functionality for some underlying container type, limiting access to the front and back elements. Elements can be added at the back or removed from the front, and elements can be inspected at either end of the queue
.
template <class Type, class Container = deque <Type>>
class queue
Type
The element data type to be stored in the queue
.
Container
The type of the underlying container used to implement the queue
.
The elements of class Type
stipulated in the first template parameter of a queue
object are synonymous with value_type
and must match the type of element in the underlying container class Container
stipulated by the second template parameter. The Type
must be assignable, so that it is possible to copy objects of that type and to assign values to variables of that type.
Suitable underlying container classes for queue
include deque
and list
, or any other sequence container that supports the operations of front
, back
, push_back
, and pop_front
. The underlying container class is encapsulated within the container adaptor, which exposes only the limited set of the sequence container member functions as a public interface.
The queue
objects are equality comparable if and only if the elements of class Type
are equality comparable, and are less-than comparable if and only if the elements of class Type
are less-than comparable.
There are three types of container adaptors defined by the C++ Standard Library: stack
, queue
, and priority_queue
. Each restricts the functionality of some underlying container class to provide a precisely controlled interface to a standard data structure.
-
The
stack
class supports a last-in, first-out (LIFO) data structure. A good analog to keep in mind would be a stack of plates. Elements (plates) may be inserted, inspected, or removed only from the top of the stack, which is the last element at the end of the base container. The restriction to accessing only the top element is the reason for using thestack
class. -
The
queue
class supports a first-in, first-out (FIFO) data structure. A good analog to keep in mind would be people lining up for a bank teller. Elements (people) may be added to the back of the line and are removed from the front of the line. Both the front and the back of a line may be inspected. The restriction to accessing only thefront
andback
elements in this way is the reason for using thequeue
class. -
The
priority_queue
class orders its elements so that the largest element is always at the top position. It supports insertion of an element and the inspection and removal of the top element. A good analog to keep in mind would be people lining up where they are arranged by age, height, or some other criterion.
Name | Description |
---|---|
queue |
Constructs a queue that is empty or that is a copy of a base container object. |
Name | Description |
---|---|
container_type |
A type that provides the base container to be adapted by the queue . |
size_type |
An unsigned integer type that can represent the number of elements in a queue . |
value_type |
A type that represents the type of object stored as an element in a queue . |
Name | Description |
---|---|
back |
Returns a reference to the last and most recently added element at the back of the queue . |
empty |
Tests if the queue is empty. |
front |
Returns a reference to the first element at the front of the queue . |
pop |
Removes an element from the front of the queue . |
push |
Adds an element to the back of the queue . |
size |
Returns the number of elements in the queue . |
Returns a reference to the last and most recently added element at the back of the queue
.
reference back();
const_reference back() const;
The last element of the queue
. If the queue
is empty, the return value is undefined.
If the return value of back
is assigned to a const_reference
, the queue
object cannot be modified. If the return value of back
is assigned to a reference
, the queue
object can be modified.
When compiled by using _ITERATOR_DEBUG_LEVEL
defined as 1 or 2, a runtime error will occur if you attempt to access an element in an empty queue
. See Checked Iterators for more information.
// queue_back.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main( )
{
using namespace std;
queue <int> q1;
q1.push( 10 );
q1.push( 11 );
int& i = q1.back( );
const int& ii = q1.front( );
cout << "The integer at the back of queue q1 is " << i
<< "." << endl;
cout << "The integer at the front of queue q1 is " << ii
<< "." << endl;
}
A type that provides the base container to be adapted.
typedef Container container_type;
The type is a synonym for the template parameter Container
. Two C++ Standard Library sequence container classes—the list
class and the default deque
class—meet the requirements to be used as the base container for a queue
object. User-defined types satisfying the requirements may also be used.
For more information on Container
, see the Remarks section of the queue Class
topic.
See the example for queue
for an example of how to declare and use container_type
.
Tests if a queue
is empty.
bool empty() const;
true
if the queue
is empty; false
if the queue
is nonempty.
// queue_empty.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main( )
{
using namespace std;
// Declares queues with default deque base container
queue <int> q1, q2;
q1.push( 1 );
if ( q1.empty( ) )
cout << "The queue q1 is empty." << endl;
else
cout << "The queue q1 is not empty." << endl;
if ( q2.empty( ) )
cout << "The queue q2 is empty." << endl;
else
cout << "The queue q2 is not empty." << endl;
}
The queue q1 is not empty.
The queue q2 is empty.
Returns a reference to the first element at the front of the queue
.
reference front();
const_reference front() const;
The first element of the queue
. If the queue
is empty, the return value is undefined.
If the return value of front
is assigned to a const_reference
, the queue
object cannot be modified. If the return value of front
is assigned to a reference
, the queue
object can be modified.
The member function returns a reference
to the first element of the controlled sequence, which must be nonempty.
When compiled by using _ITERATOR_DEBUG_LEVEL
defined as 1 or 2, a runtime error will occur if you attempt to access an element in an empty queue
. See Checked Iterators for more information.
// queue_front.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main() {
using namespace std;
queue <int> q1;
q1.push( 10 );
q1.push( 20 );
q1.push( 30 );
queue <int>::size_type i;
i = q1.size( );
cout << "The queue length is " << i << "." << endl;
int& ii = q1.back( );
int& iii = q1.front( );
cout << "The integer at the back of queue q1 is " << ii
<< "." << endl;
cout << "The integer at the front of queue q1 is " << iii
<< "." << endl;
}
Removes an element from the front of the queue
.
void pop();
The queue
must be nonempty to apply the member function. The top of the queue
is the position occupied by the most recently added element and is the last element at the end of the container.
// queue_pop.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main( )
{
using namespace std;
queue <int> q1, s2;
q1.push( 10 );
q1.push( 20 );
q1.push( 30 );
queue <int>::size_type i;
i = q1.size( );
cout << "The queue length is " << i << "." << endl;
i = q1.front( );
cout << "The element at the front of the queue is "
<< i << "." << endl;
q1.pop( );
i = q1.size( );
cout << "After a pop the queue length is "
<< i << "." << endl;
i = q1. front ( );
cout << "After a pop, the element at the front of the queue is "
<< i << "." << endl;
}
The queue length is 3.
The element at the front of the queue is 10.
After a pop the queue length is 2.
After a pop, the element at the front of the queue is 20.
Adds an element to the back of the queue
.
void push(const Type& val);
val
The element added to the back of the queue
.
The back of the queue
is the position occupied by the most recently added element and is the last element at the end of the container.
// queue_push.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main( )
{
using namespace std;
queue <int> q1;
q1.push( 10 );
q1.push( 20 );
q1.push( 30 );
queue <int>::size_type i;
i = q1.size( );
cout << "The queue length is " << i << "." << endl;
i = q1.front( );
cout << "The element at the front of the queue is "
<< i << "." << endl;
}
The queue length is 3.
The element at the front of the queue is 10.
Constructs a queue
that is empty or that is a copy of a base container object.
queue();
explicit queue(const container_type& right);
right
The const
container of which the constructed queue
is to be a copy.
The default base container for queue
is deque
. You can also specify list
as a base container, but you cannot specify vector
, because it lacks the required pop_front
member function.
// queue_queue.cpp
// compile with: /EHsc
#include <queue>
#include <vector>
#include <list>
#include <iostream>
int main( )
{
using namespace std;
// Declares queue with default deque base container
queue <char> q1;
// Explicitly declares a queue with deque base container
queue <char, deque<char> > q2;
// These lines don't cause an error, even though they
// declares a queue with a vector base container
queue <int, vector<int> > q3;
q3.push( 10 );
// but the following would cause an error because vector has
// no pop_front member function
// q3.pop( );
// Declares a queue with list base container
queue <int, list<int> > q4;
// The second member function copies elements from a container
list<int> li1;
li1.push_back( 1 );
li1.push_back( 2 );
queue <int, list<int> > q5( li1 );
cout << "The element at the front of queue q5 is "
<< q5.front( ) << "." << endl;
cout << "The element at the back of queue q5 is "
<< q5.back( ) << "." << endl;
}
The element at the front of queue q5 is 1.
The element at the back of queue q5 is 2.
Returns the number of elements in the queue
.
size_type size() const;
The current length of the queue
.
// queue_size.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main( )
{
using namespace std;
queue <int> q1, q2;
queue <int>::size_type i;
q1.push( 1 );
i = q1.size( );
cout << "The queue length is " << i << "." << endl;
q1.push( 2 );
i = q1.size( );
cout << "The queue length is now " << i << "." << endl;
}
The queue length is 1.
The queue length is now 2.
An unsigned integer type that can represent the number of elements in a queue
.
typedef typename Container::size_type size_type;
The type is a synonym for the size_type
of the base container adapted by the queue
.
See the example for queue::front
for an example of how to declare and use size_type
.
A type that represents the type of object stored as an element in a queue
.
typedef typename Container::value_type value_type;
The type is a synonym for the value_type
of the base container adapted by the queue
.
// queue_value_type.cpp
// compile with: /EHsc
#include <queue>
#include <iostream>
int main( )
{
using namespace std;
// Declares queues with default deque base container
queue<int>::value_type AnInt;
AnInt = 69;
cout << "The value_type is AnInt = " << AnInt << endl;
queue<int> q1;
q1.push(AnInt);
cout << "The element at the front of the queue is "
<< q1.front( ) << "." << endl;
}
The value_type is AnInt = 69
The element at the front of the queue is 69.
Thread Safety in the C++ Standard Library
C++ Standard Library Reference