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C++ Unordered_multimap::bucket() Function
The C++ std::unordered_multimap::bucket() function is used to returns the bucket number where element with key k is located.
Bucket is a memory space in the container's hash table to which elements are assigned based on the hash value of their key. The size of the bucket is in the range of 0 to bucket_count-1.
Syntax
Following is the syntax of std::unordered_multimap::bucket() function.
size_type bucket(const Key& keyval) const;
Parameters
- k − It indicates the key whose bucket is to be located.
Return value
This function returns the unsigned integral type that is the order number of the bucket corresponding to key.
Example 1
In the following example let's see the usage of unordered_multimap::bucket() function.
#include <iostream>
#include <unordered_map>
using namespace std;
int main(void) {
unordered_multimap<char, int> umm = {
{'a', 1},
{'b', 2},
{'c', 3},
{'d', 4},
{'e', 5}
};
cout << "Unordered multimap contains following elements" << endl;
for (auto it = umm.begin(); it != umm.end(); ++it) {
cout << "Element " << "[" << it->first << " : "<< it->second << "] " << "is in " << umm.bucket(it->first) << " bucket." << endl;
}
return 0;
}
Output
Let us compile and run the above program, this will produce the following result −
Unordered multi-map contains following elements Element [e : 5] is in 1 bucket. Element [d : 4] is in 0 bucket. Element [c : 3] is in 4 bucket. Element [b : 2] is in 3 bucket. Element [a : 1] is in 2 bucket.
Example 2
Let's look at the following example, where we are going to create a unordered_multimap that stores the string values and applying the bucket() function to count the number of buckets assigned to each other.
#include <iostream>
#include <unordered_map>
using namespace std;
int main(void) {
unordered_multimap<string, string> umm = {
{"Aman", "Ranchi"},
{"Vivek", "Kanpur"},
{"Akash", "Daltonganj"},
{"Aman", "Ranchi"},
{"Vivek", "Kanpur"},
};
for (auto it = umm.begin(); it != umm.end(); ++it) {
cout << "Element " << "[" << it->first << " : "
<< it->second << "] " << "is in "
<< umm.bucket(it->first) << " bucket." << endl;
}
return 0;
}
Output
If we run the above code it will generate the following output −
Element [Akash : Daltonganj] is in 4 bucket. Element [Vivek : Kanpur] is in 4 bucket. Element [Vivek : Kanpur] is in 4 bucket. Element [Aman : Ranchi] is in 3 bucket. Element [Aman : Ranchi] is in 3 bucket.
Example 3
Consider the following example, where we are going to displaying the number of buckets of the iteration pointing to the first element of the container from unordered_multimap.
#include <iostream>
#include <unordered_map>
using namespace std;
int main(void) {
unordered_multimap<string, string> umm = {
{"Aman", "Ranchi"},
{"Vivek", "Kanpur"},
{"Akash", "Daltonganj"},
{"Aman", "Ranchi"},
{"Vivek", "Kanpur"},
};
// prints the bucket number of the beginning element
auto it = umm.begin();
// stores the bucket number of the key k
int number = umm.bucket(it->first);
cout << "The bucket number of key " << it->first << " is " << number;
return 0;
}
Output
Following is the output of the above code −
The bucket number of key Akash is 4
Example 4
Following is the example, where we are going to display the bucket number of the specified key from the current unordered_multimap.
#include <iostream>
#include <unordered_map>
using namespace std;
int main(void) {
unordered_multimap<char, int> umm = {
{'A', 1},
{'B', 2},
{'C', 3},
{'A', 1},
{'D', 4},
{'A', 1},
{'E', 5},
{'D', 4},
};
cout<<umm.bucket('A')<<endl;
cout<<umm.bucket('D')<<endl;
return 0;
}
Output
Output of the above code is as follows −
10 2