Intro to Tutorial Challenges.cpp

Task:  About Tutorial Challenges
Many of the challenges on HackerRank are difficult and assume that you already know the relevant algorithms. These tutorial challenges are different. They break down algorithmic concepts into smaller challenges so that you can learn the algorithm by solving them. They are intended for those who already know some programming, however. You could be a student majoring in computer science, a self-taught programmer, or an experienced developer who wants an active algorithms review. Here's a great place to learn by doing!

The first series of challenges covers sorting. They are listed below:

Tutorial Challenges - Sorting

Insertion Sort challenges

    Insertion Sort 1 - Inserting
    Insertion Sort 2 - Sorting
    Correctness and loop invariant
    Running Time of Algorithms

Quicksort challenges

    Quicksort 1 - Partition
    Quicksort 2 - Sorting
    Quicksort In-place (advanced)
    Running time of Quicksort

Counting sort challenges

    Counting Sort 1 - Counting
    Counting Sort 2 - Simple sort
    Counting Sort 3 - Preparing
    Full Counting Sort (advanced)

There will also be some challenges where you'll get to apply what you've learned using the completed algorithms.

About the Challenges
Each challenge will describe a scenario and you will code a solution. As you progress through the challenges, you will learn some important concepts in algorithms. In each challenge, you will receive input on STDIN and you will need to print the correct output to STDOUT.

There may be time limits that will force you to make your code efficient. If you receive a "Terminated due to time out" message when you submit your solution, you'll need to reconsider your method. If you want to test your code locally, each test case can be downloaded, inputs and expected results, using hackos. You earn hackos as you solve challenges, and you can spend them on these tests.

For many challenges, helper methods (like an array) will be provided for you to process the input into a useful format. You can use these methods to get started with your program, or you can write your own input methods if you want. Your code just needs to print the right output to each test case.

Sample Challenge

This is a simple challenge to get things started. Given a sorted array (arr) and a number (V), can you print the index location of V in the array?

For example, if arr = [1,2,3] and V=3, you would print 2 for a zero-based index array.

If you are going to use the provided code for I/O, this next section is for you.

Function Description

Complete the introTutorial function in the editor below. It must return an integer representing the zero-based index of V.

introTutorial has the following parameter(s):

    arr: a sorted array of integers
    V: an integer to search for

The next section describes the input format. You can often skip it, if you are using included methods or code stubs.

Input Format

The first line contains an integer, V, a value to search for.
The next line contains an integer, n, the size of arr. The last line contains space-separated integers, each a value of arr[i] where 0<=i<=n.

Output Format

Output the index of V in the array.

The next section describes the constraints and ranges of the input. You should check this section to know the range of the input.


Solution:


#include <iostream>
#include <algorithm>
#include <vector>
using namespace std;

int BinarSearch(vector<int> &x, int low, int high, int b){
    if(low>high) return -1;
    int mid = low + (high - low)/2;
    if (b == x[mid]){
        return mid;
    }
    else if(b < x[mid]){
        return BinarSearch(x , low , mid-1, b);
    }
    else{
        return BinarSearch(x , mid+1, high, b);
    }
}

int main(){
    int v,n;
    cin>>v>>n;
    vector<int> x;
    for(int i=0;i<n;i++){
        int a;
        cin>>a;
        x.push_back(a);
    }
    int result = BinarSearch(x , 0 , n-1 , v);
    if(result!=-1){
        cout<<result;
    }
    return 0;
}