std::deque
From cppreference.com
| Defined in header <deque>
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| template< class T, |
(1) | |
| namespace pmr { template <class T> |
(2) | (since C++17) |
std::deque (double-ended queue) is an indexed sequence container that allows fast insertion and deletion at both its beginning and its end. In addition, insertion and deletion at either end of a deque never invalidates pointers or references to the rest of the elements.
As opposed to std::vector, the elements of a deque are not stored contiguously: typical implementations use a sequence of individually allocated fixed-size arrays.
The storage of a deque is automatically expanded and contracted as needed. Expansion of a deque is cheaper than the expansion of a std::vector because it does not involve copying of the existing elements to a new memory location.
The complexity (efficiency) of common operations on deques is as follows:
- Random access - constant O(1)
- Insertion or removal of elements at the end or beginning - constant O(1)
- Insertion or removal of elements - linear O(n)
std::deque meets the requirements of Template:concept, Template:concept, Template:concept and Template:concept.
Contents |
Template parameters
| T | - | The type of the elements.
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| Allocator | - | An allocator that is used to acquire/release memory and to construct/destroy the elements in that memory. The type must meet the requirements of Allocator. The behavior is undefined(until C++20)The program is ill-formed(since C++20) if Allocator::value_type is not the same as T.
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Iterator invalidation
| This section is incomplete |
There are still a few inaccuracies in this section, refer to individual member function pages for more detail
| Operations | Invalidated |
|---|---|
| All read only operations | Never |
| swap, std::swap | The past-the-end iterator may be invalidated (implementation defined) |
| shrink_to_fit, clear, insert, emplace, push_front, push_back, emplace_front, emplace_back | Always |
| erase | If erasing at begin - only erased elements If erasing at end - only erased elements and the past-the-end iterator |
| resize | If the new size is smaller than the old one : only erased elements and the past-the-end iterator If the new size is bigger than the old one : all iterators are invalidated |
| pop_front | Only to the element erased |
| pop_back | Only to the element erased and the past-the-end iterator |
Notes
- When inserting at either end of the deque, references are not invalidated by insert and emplace.
- push_front, push_back, emplace_front and emplace_back do not invalidate any references to elements of the deque.
- When erasing at either end of the deque, references to non-erased elements are not invalidated by erase, pop_front and pop_back.
- A call to resize with a smaller size does not invalidate any references to non-erased elements.
- A call to resize with a bigger size does not invalidate any references to elements of the deque.
- If a method is common to both deque and std::vector then the run-time complexity of deque's method is no worse than the complexity of std::vector's method (and in the case of inserting to the front, deque's complexity is better).
- Despite the run-time complexity advantage of deque over std::vector described above, the std::vector container does have some advantages over the deque container:
- Implementations of deque typically have a large overhead memory cost. For instance, the 64-bit GNU (resp. Apache, Microsoft) standard library implementation of deque uses a minimum of 656 (resp. 832, 128) bytes to store 1 object in a deque. This variability may also negatively affect portability.
- deque typically doesn't store its elements contiguously in memory, which may make interacting with older C or C++ code more difficult. This also means that std::vectors typically have better locality in memory. This lack of locality in space, however, may give deque an advantage when dealing with a large collection of objects.
- The better run-time complexity of some of deque's operations comes at the expense of additional book-keeping. In particular, many popular implementations of deque often store objects via an array of pointers-to-array so that accessing an element by passing an index to operator[], for instance, requires first finding the pointer that points to the array holding this element and then secondly finding the location of this element within this array.
Member types
| Member type | Definition | ||||
value_type
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T
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allocator_type
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Allocator
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size_type
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Unsigned integer type (usually std::size_t) | ||||
difference_type
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Signed integer type (usually std::ptrdiff_t) | ||||
reference
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value_type& | ||||
const_reference
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const value_type& | ||||
pointer
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const_pointer
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iterator
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LegacyRandomAccessIterator to value_type
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const_iterator
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LegacyRandomAccessIterator to const value_type | ||||
reverse_iterator
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std::reverse_iterator<iterator> | ||||
const_reverse_iterator
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std::reverse_iterator<const_iterator> |
Member functions
constructs the deque (public member function) | |
destructs the deque (public member function) | |
| assigns values to the container (public member function) | |
| assigns values to the container (public member function) | |
| returns the associated allocator (public member function) | |
Element access | |
| access specified element with bounds checking (public member function) | |
| access specified element (public member function) | |
| access the first element (public member function) | |
| access the last element (public member function) | |
Iterators | |
| (C++11) |
returns an iterator to the beginning (public member function) |
| (C++11) |
returns an iterator to the end (public member function) |
| (C++11) |
returns a reverse iterator to the beginning (public member function) |
| (C++11) |
returns a reverse iterator to the end (public member function) |
Capacity | |
| checks whether the container is empty (public member function) | |
| returns the number of elements (public member function) | |
| returns the maximum possible number of elements (public member function) | |
| (DR*) |
reduces memory usage by freeing unused memory (public member function) |
Modifiers | |
| clears the contents (public member function) | |
| inserts elements (public member function) | |
| (C++11) |
constructs element in-place (public member function) |
| erases elements (public member function) | |
| adds an element to the end (public member function) | |
| (C++11) |
constructs an element in-place at the end (public member function) |
| removes the last element (public member function) | |
| inserts an element to the beginning (public member function) | |
| (C++11) |
constructs an element in-place at the beginning (public member function) |
| removes the first element (public member function) | |
| changes the number of elements stored (public member function) | |
| swaps the contents (public member function) | |
Non-member functions
| (removed in C++20)(removed in C++20)(removed in C++20)(removed in C++20)(removed in C++20)(C++20) |
lexicographically compares the values of two deques (function template) |
| specializes the std::swap algorithm (function template) |
Example
Run this code
#include <iostream> #include <deque> int main() { // Create a deque containing integers std::deque<int> d = {7, 5, 16, 8}; // Add an integer to the beginning and end of the deque d.push_front(13); d.push_back(25); // Iterate and print values of deque for(int n : d) { std::cout << n << '\n'; } }
Output:
13 7 5 16 8 25
