Hope you already understand the concept of C++ Template which we
already have discussed in one of the chapters. The C++ STL (Standard
Template Library) is a powerful set of C++ template classes to provides
general-purpose templatized classes and functions that implement many
popular and commonly used algorithms and data structures like vectors,
lists, queues, and stacks.
At the core of the C++ Standard Template Library are following three well-structured components:
We will discuss about all the three C++ STL components in next
chapter while discussing C++ Standard Library. For now, keep in mind
that all the three components have a rich set of pre-defined functions
which help us in doing complicated tasks in very easy fashion.
Let us take the following program demonstrates the vector container (a C++ Standard Template) which is similar to an array with an exception that it automatically handles its own storage requirements in case it grows:
At the core of the C++ Standard Template Library are following three well-structured components:
Component | Description |
---|---|
Containers | Containers are used to manage collections of objects of a certain kind. There are several different types of containers like deque, list, vector, map etc. |
Algorithms | Algorithms act on containers. They provide the means by which you will perform initialization, sorting, searching, and transforming of the contents of containers. |
Iterators | Iterators are used to step through the elements of collections of objects. These collections may be containers or subsets of containers. |
Let us take the following program demonstrates the vector container (a C++ Standard Template) which is similar to an array with an exception that it automatically handles its own storage requirements in case it grows:
#include <iostream> #include <vector> using namespace std; int main() { // create a vector to store int vector<int> vec; int i; // display the original size of vec cout << "vector size = " << vec.size() << endl; // push 5 values into the vector for(i = 0; i < 5; i++){ vec.push_back(i); } // display extended size of vec cout << "extended vector size = " << vec.size() << endl; // access 5 values from the vector for(i = 0; i < 5; i++){ cout << "value of vec [" << i << "] = " << vec[i] << endl; } // use iterator to access the values vector<int>::iterator v = vec.begin(); while( v != vec.end()) { cout << "value of v = " << *v << endl; v++; } return 0; }When the above code is compiled and executed, it produces the following result:
vector size = 0 extended vector size = 5 value of vec [0] = 0 value of vec [1] = 1 value of vec [2] = 2 value of vec [3] = 3 value of vec [4] = 4 value of v = 0 value of v = 1 value of v = 2 value of v = 3 value of v = 4Here are following points to be noted related to various functions we used in the above example:
- The push_back( ) member function inserts value at the end of the vector, expanding its size as needed.
- The size( ) function displays the size of the vector.
- The function begin( ) returns an iterator to the start of the vector.
- The function end( ) returns an iterator to the end of the vector.
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