concurrent_unordered_multimap Class
The concurrent_unordered_multimap class is an concurrency-safe container that controls a varying-length sequence of elements of type std::pair<const K, _Element_type>. The sequence is represented in a way that enables concurrency-safe append, element access, iterator access and iterator traversal operations. Here, concurrency-safe means pointers or iterators are always valid. It's not a guarantee of element initialization, or of a particular traversal order.
Syntax
template <typename K,
typename _Element_type,
typename _Hasher = std::hash<K>,
typename key_equality = std::equal_to<K>,
typename _Allocator_type = std::allocator<std::pair<const K,
_Element_type>>
>,
typename key_equality = std::equal_to<K>,
typename _Allocator_type = std::allocator<std::pair<const K,
_Element_type>>> class concurrent_unordered_multimap : public details::_Concurrent_hash<details::_Concurrent_unordered_map_traits<K,
_Element_type,
details::_Hash_compare<K,
_Hasher,
key_equality>,
_Allocator_type,
true>>;
Parameters
K
The key type.
_Element_type
The mapped type.
_Hasher
The hash function object type. This argument is optional and the default value is std::hash<K>.
key_equality
The equality comparison function object type. This argument is optional and the default value is std::equal_to<K>.
_Allocator_type
The type that represents the stored allocator object that encapsulates details about the allocation and deallocation of memory for the concurrent vector. This argument is optional and the default value is std::allocator<std::pair<K, _Element_type>>.
Members
Public Typedefs
| Name | Description |
|---|---|
allocator_type |
The type of an allocator for managing storage. |
const_iterator |
The type of a constant iterator for the controlled sequence. |
const_local_iterator |
The type of a constant bucket iterator for the controlled sequence. |
const_pointer |
The type of a constant pointer to an element. |
const_reference |
The type of a constant reference to an element. |
difference_type |
The type of a signed distance between two elements. |
hasher |
The type of the hash function. |
iterator |
The type of an iterator for the controlled sequence. |
key_equal |
The type of the comparison function. |
key_type |
The type of an ordering key. |
local_iterator |
The type of a bucket iterator for the controlled sequence. |
mapped_type |
The type of a mapped value associated with each key. |
pointer |
The type of a pointer to an element. |
reference |
The type of a reference to an element. |
size_type |
The type of an unsigned distance between two elements. |
value_type |
The type of an element. |
Public Constructors
| Name | Description |
|---|---|
| concurrent_unordered_multimap | Overloaded. Constructs a concurrent unordered multimap. |
Public Methods
| Name | Description |
|---|---|
| hash_function | Returns the stored hash function object. |
| insert | Overloaded. Adds elements to the concurrent_unordered_multimap object. |
| key_eq | Returns the stored equality comparison function object. |
| swap | Swaps the contents of two concurrent_unordered_multimap objects. This method is not concurrency-safe. |
| unsafe_erase | Overloaded. Removes elements from the concurrent_unordered_multimap at specified positions. This method is not concurrency-safe. |
Public Operators
| Name | Description |
|---|---|
| operator= | Overloaded. Assigns the contents of another concurrent_unordered_multimap object to this one. This method is not concurrency-safe. |
Remarks
For detailed information on the concurrent_unordered_multimap class, see Parallel Containers and Objects.
Inheritance Hierarchy
_Traits
_Concurrent_hash
concurrent_unordered_multimap
Requirements
Header: concurrent_unordered_map.h
Namespace: concurrency
begin
Returns an iterator pointing to the first element in the concurrent container. This method is concurrency safe.
iterator begin();
const_iterator begin() const;
Return Value
An iterator to the first element in the concurrent container.
cbegin
Returns a const iterator pointing to the first element in the concurrent container. This method is concurrency safe.
const_iterator cbegin() const;
Return Value
A const iterator to the first element in the concurrent container.
cend
Returns a const iterator pointing to the location succeeding the last element in the concurrent container. This method is concurrency safe.
const_iterator cend() const;
Return Value
A const iterator to the location succeeding the last element in the concurrent container.
clear
Erases all the elements in the concurrent container. This function is not concurrency safe.
void clear();
concurrent_unordered_multimap
Constructs a concurrent unordered multimap.
explicit concurrent_unordered_multimap(
size_type _Number_of_buckets = 8,
const hasher& _Hasher = hasher(),
const key_equal& key_equality = key_equal(),
const allocator_type& _Allocator = allocator_type());
concurrent_unordered_multimap(
const allocator_type& _Allocator);
template <typename _Iterator>
concurrent_unordered_multimap(_Iterator _Begin,
_Iterator _End,
size_type _Number_of_buckets = 8,
const hasher& _Hasher = hasher(),
const key_equal& key_equality = key_equal(),
const allocator_type& _Allocator = allocator_type());
concurrent_unordered_multimap(
const concurrent_unordered_multimap& _Umap);
concurrent_unordered_multimap(
const concurrent_unordered_multimap& _Umap,
const allocator_type& _Allocator);
concurrent_unordered_multimap(
concurrent_unordered_multimap&& _Umap);
Parameters
_Iterator
The type of the input iterator.
_Number_of_buckets
The initial number of buckets for this unordered multimap.
_Hasher
The hash function for this unordered multimap.
key_equality
The equality comparison function for this unordered multimap.
_Allocator
The allocator for this unordered multimap.
_Begin
The position of the first element in the range of elements to be copied.
_End
The position of the first element beyond the range of elements to be copied.
_Umap
The source concurrent_unordered_multimap object to copy elements from.
Remarks
All constructors store an allocator object _Allocator and initialize the unordered multimap.
The first constructor specifies an empty initial multimap and explicitly specifies the number of buckets, hash function, equality function and allocator type to be used.
The second constructor specifies an allocator for the unordered multimap.
The third constructor specifies values supplied by the iterator range [ _Begin, _End).
The fourth and fifth constructors specify a copy of the concurrent unordered multimap _Umap.
The last constructor specifies a move of the concurrent unordered multimap _Umap.
count
Counts the number of elements matching a specified key. This function is concurrency safe.
size_type count(const key_type& KVal) const;
Parameters
KVal
The key to search for.
Return Value
The number of times number of times the key appears in the container.
empty
Tests whether no elements are present. This method is concurrency safe.
bool empty() const;
Return Value
true if the concurrent container is empty, false otherwise.
Remarks
In the presence of concurrent inserts, whether or not the concurrent container is empty may change immediately after calling this function, before the return value is even read.
end
Returns an iterator pointing to the location succeeding the last element in the concurrent container. This method is concurrency safe.
iterator end();
const_iterator end() const;
Return Value
An iterator to the location succeeding the last element in the concurrent container.
equal_range
Finds a range that matches a specified key. This function is concurrency safe.
std::pair<iterator,
iterator> equal_range(
const key_type& KVal);
std::pair<const_iterator,
const_iterator> equal_range(
const key_type& KVal) const;
Parameters
KVal
The key value to search for.
Return Value
A pair where the first element is an iterator to the beginning and the second element is an iterator to the end of the range.
Remarks
It is possible for concurrent inserts to cause additional keys to be inserted after the begin iterator and before the end iterator.
find
Finds an element that matches a specified key. This function is concurrency safe.
iterator find(const key_type& KVal);
const_iterator find(const key_type& KVal) const;
Parameters
KVal
The key value to search for.
Return Value
An iterator pointing to the location of the first element that matched the key provided, or the iterator end() if no such element exists.
get_allocator
Returns the stored allocator object for this concurrent container. This method is concurrency safe.
allocator_type get_allocator() const;
Return Value
The stored allocator object for this concurrent container.
hash_function
Returns the stored hash function object.
hasher hash_function() const;
Return Value
The stored hash function object.
insert
Adds elements to the concurrent_unordered_multimap object.
iterator insert(
const value_type& value);
iterator insert(
const_iterator _Where,
const value_type& value);
template<class _Iterator>
void insert(_Iterator first,
_Iterator last);
template<class V>
iterator insert(
V&& value);
template<class V>
typename std::enable_if<!std::is_same<const_iterator,
typename std::remove_reference<V>::type>::value,
iterator>::type insert(
const_iterator _Where,
V&& value);
Parameters
_Iterator
The iterator type used for insertion.
V
The type of the value inserted into the map.
value
The value to be inserted.
_Where
The starting location to search for an insertion point.
first
The beginning of the range to insert.
last
The end of the range to insert.
Return Value
An iterator pointing to the insertion location.
Remarks
The first member function inserts the element value in the controlled sequence, then returns the iterator that designates the inserted element.
The second member function returns insert( value), using _Where as a starting place within the controlled sequence to search for the insertion point.
The third member function inserts the sequence of element values from the range [ first, last).
The last two member functions behave the same as the first two, except that value is used to construct the inserted value.
key_eq
Returns the stored equality comparison function object.
key_equal key_eq() const;
Return Value
The stored equality comparison function object.
load_factor
Computes and returns the current load factor of the container. The load factor is the number of elements in the container divided by the number of buckets.
float load_factor() const;
Return Value
The load factor for the container.
max_load_factor
Gets or sets the maximum load factor of the container. The maximum load factor is the largest number of elements than can be in any bucket before the container grows its internal table.
float max_load_factor() const;
void max_load_factor(float _Newmax);
Parameters
_Newmax
Return Value
The first member function returns the stored maximum load factor. The second member function does not return a value but throws an out_of_range exception if the supplied load factor is invalid..
max_size
Returns the maximum size of the concurrent container, determined by the allocator. This method is concurrency safe.
size_type max_size() const;
Return Value
The maximum number of elements that can be inserted into this concurrent container.
Remarks
This upper bound value may actually be higher than what the container can actually hold.
operator=
Assigns the contents of another concurrent_unordered_multimap object to this one. This method is not concurrency-safe.
concurrent_unordered_multimap& operator= (const concurrent_unordered_multimap& _Umap);
concurrent_unordered_multimap& operator= (concurrent_unordered_multimap&& _Umap);
Parameters
_Umap
The source concurrent_unordered_multimap object.
Return Value
A reference to this concurrent_unordered_multimap object.
Remarks
After erasing any existing elements in a concurrent unordered multimap, operator= either copies or moves the contents of _Umap into the concurrent unordered multimap.
rehash
Rebuilds the hash table.
void rehash(size_type _Buckets);
Parameters
_Buckets
The desired number of buckets.
Remarks
The member function alters the number of buckets to be at least _Buckets and rebuilds the hash table as needed. The number of buckets must be a power of 2. If not a power of 2, it will be rounded up to the next largest power of 2.
It throws an out_of_range exception if the number of buckets is invalid (either 0 or greater than the maximum number of buckets).
size
Returns the number of elements in this concurrent container. This method is concurrency safe.
size_type size() const;
Return Value
The number of items in the container.
Remarks
In the presence of concurrent inserts, the number of elements in the concurrent container may change immediately after calling this function, before the return value is even read.
swap
Swaps the contents of two concurrent_unordered_multimap objects. This method is not concurrency-safe.
void swap(concurrent_unordered_multimap& _Umap);
Parameters
_Umap
The concurrent_unordered_multimap object to swap with.
unsafe_begin
Returns an iterator to the first element in this container for a specific bucket.
local_iterator unsafe_begin(size_type _Bucket);
const_local_iterator unsafe_begin(size_type _Bucket) const;
Parameters
_Bucket
The bucket index.
Return Value
An iterator pointing to the beginning of the bucket.
unsafe_bucket
Returns the bucket index that a specific key maps to in this container.
size_type unsafe_bucket(const key_type& KVal) const;
Parameters
KVal
The element key being searched for.
Return Value
The bucket index for the key in this container.
unsafe_bucket_count
Returns the current number of buckets in this container.
size_type unsafe_bucket_count() const;
Return Value
The current number of buckets in this container.
unsafe_bucket_size
Returns the number of items in a specific bucket of this container.
size_type unsafe_bucket_size(size_type _Bucket);
Parameters
_Bucket
The bucket to search for.
Return Value
The current number of buckets in this container.
unsafe_cbegin
Returns an iterator to the first element in this container for a specific bucket.
const_local_iterator unsafe_cbegin(size_type _Bucket) const;
Parameters
_Bucket
The bucket index.
Return Value
An iterator pointing to the beginning of the bucket.
unsafe_cend
Returns an iterator to the location succeeding the last element in a specific bucket.
const_local_iterator unsafe_cend(size_type _Bucket) const;
Parameters
_Bucket
The bucket index.
Return Value
An iterator pointing to the beginning of the bucket.
unsafe_end
Returns an iterator to the last element in this container for a specific bucket.
local_iterator unsafe_end(size_type _Bucket);
const_local_iterator unsafe_end(size_type _Bucket) const;
Parameters
_Bucket
The bucket index.
Return Value
An iterator pointing to the end of the bucket.
unsafe_erase
Removes elements from the concurrent_unordered_multimap at specified positions. This method is not concurrency-safe.
iterator unsafe_erase(
const_iterator _Where);
size_type unsafe_erase(
const key_type& KVal);
iterator unsafe_erase(
const_iterator first,
const_iterator last);
Parameters
_Where
The iterator position to erase from.
KVal
The key value to erase.
first
last
Iterators.
Return Value
The first two member functions return an iterator that designates the first element remaining beyond any elements removed, or concurrent_unordered_multimap::end() if no such element exists. The third member function returns the number of elements it removes.
Remarks
The first member function removes the element of the controlled sequence pointed to by _Where. The second member function removes the elements in the range [ _Begin, _End).
The third member function removes the elements in the range delimited by concurrent_unordered_multimap::equal_range(KVal).
unsafe_max_bucket_count
Returns the maximum number of buckets in this container.
size_type unsafe_max_bucket_count() const;
Return Value
The maximum number of buckets in this container.
See also
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