std::unordered_map::unordered_map
| (1) | ||
| explicit unordered_map( size_type bucket_count = /*implementation-defined*/, const Hash& hash = Hash(), |
(since C++11) (until C++14) |
|
| unordered_map() : unordered_map( size_type(/*implementation-defined*/) ) {} explicit unordered_map( size_type bucket_count, |
(since C++14) | |
| unordered_map( size_type bucket_count, const Allocator& alloc ) |
(1) | (since C++14) |
| explicit unordered_map( const Allocator& alloc ); |
(1) | (since C++11) |
| template< class InputIt > unordered_map( InputIt first, InputIt last, |
(2) | (since C++11) |
| template< class InputIt > unordered_map( InputIt first, InputIt last, |
(2) | (since C++14) |
| template< class InputIt > unordered_map( InputIt first, InputIt last, |
(2) | (since C++14) |
| unordered_map( const unordered_map& other ); |
(3) | (since C++11) |
| unordered_map( const unordered_map& other, const Allocator& alloc ); |
(3) | (since C++11) |
| unordered_map( unordered_map&& other ); |
(4) | (since C++11) |
| unordered_map( unordered_map&& other, const Allocator& alloc ); |
(4) | (since C++11) |
| unordered_map( std::initializer_list<value_type> init, size_type bucket_count = /*implementation-defined*/, |
(5) | (since C++11) |
| unordered_map( std::initializer_list<value_type> init, size_type bucket_count, |
(5) | (since C++14) |
| unordered_map( std::initializer_list<value_type> init, size_type bucket_count, |
(5) | (since C++14) |
Constructs new container from a variety of data sources. Optionally uses user supplied bucket_count as a minimal number of buckets to create, hash as the hash function, equal as the function to compare keys and alloc as the allocator.
max_load_factor() to 1.0. For the default constructor, the number of buckets is implementation-defined.[first, last). Sets max_load_factor() to 1.0. if multiple elements in the range have keys that compare equivalent, it is unspecified which element is inserted (pending LWG2844)other, copies the load factor, the predicate, and the hash function as well. If alloc is not provided, allocator is obtained by calling std::allocator_traits<allocator_type>::select_on_container_copy_construction(other.get_allocator()).other using move semantics. If alloc is not provided, allocator is obtained by move-construction from the allocator belonging to other.init, same as unordered_map(init.begin(), init.end()).Parameters
| alloc | - | allocator to use for all memory allocations of this container |
| bucket_count | - | minimal number of buckets to use on initialization. If it is not specified, implementation-defined default value is used |
| hash | - | hash function to use |
| equal | - | comparison function to use for all key comparisons of this container |
| first, last | - | the range to copy the elements from |
| other | - | another container to be used as source to initialize the elements of the container with |
| init | - | initializer list to initialize the elements of the container with |
| Type requirements | ||
-InputIt must meet the requirements of InputIterator.
| ||
Complexity
first and lastotheralloc is given and alloc != other.get_allocator(), then linear.initNotes
other remain valid, but refer to elements that are now in *this. The current standard makes this guarantee via the blanket statement in §23.2.1[container.requirements.general]/12, and a more direct guarantee is under consideration via LWG 2321.
Example
#include <unordered_map> #include <vector> #include <bitset> #include <string> #include <utility> struct Key { std::string first; std::string second; }; struct KeyHash { std::size_t operator()(const Key& k) const { return std::hash<std::string>()(k.first) ^ (std::hash<std::string>()(k.second) << 1); } }; struct KeyEqual { bool operator()(const Key& lhs, const Key& rhs) const { return lhs.first == rhs.first && lhs.second == rhs.second; } }; struct Foo { Foo(int val_) : val(val_) {} int val; bool operator==(const Foo &rhs) const { return val == rhs.val; } }; namespace std { template<> struct hash<Foo> { std::size_t operator()(const Foo &f) const { return std::hash<int>{}(f.val); } }; } int main() { // default constructor: empty map std::unordered_map<std::string, std::string> m1; // list constructor std::unordered_map<int, std::string> m2 = { {1, "foo"}, {3, "bar"}, {2, "baz"}, }; // copy constructor std::unordered_map<int, std::string> m3 = m2; // move constructor std::unordered_map<int, std::string> m4 = std::move(m2); // range constructor std::vector<std::pair<std::bitset<8>, int>> v = { {0x12, 1}, {0x01,-1} }; std::unordered_map<std::bitset<8>, double> m5(v.begin(), v.end()); //Option 1 for a constructor with a custom Key type // Define the KeyHash and KeyEqual structs and use them in the template std::unordered_map<Key, std::string, KeyHash, KeyEqual> m6 = { { {"John", "Doe"}, "example"}, { {"Mary", "Sue"}, "another"} }; //Option 2 for a constructor with a custom Key type // Define a const == operator for the class/struct and specialize std::hash // structure in the std namespace std::unordered_map<Foo, std::string> m7 = { { Foo(1), "One"}, { 2, "Two"}, { 3, "Three"} }; //Option 3: Use lambdas // Note that the initial bucket count has to be passed to the constructor struct Goo {int val; }; auto hash = [](const Goo &g){ return std::hash<int>{}(g.val); }; auto comp = [](const Goo &l, const Goo &r){ return l.val == r.val; }; std::unordered_map<Goo, double, decltype(hash), decltype(comp)> m8(10, hash, comp); }
See also
| assigns values to the container (public member function) |