WAP to Check That Binary Representation of Given Number is Palindrome of NOt

Here i Found an Algorithm for This

Algorithm
take two varible i -0 & j=N (number)
keep storing bits of number from lsb in reverse order (e.g. shift i left & do or operation with j&1 (mind shud click this the way to extract right most set bit from number :)
keep shifting j right while j is not equals to 0

Explaintion

The first while loop reverses the rightmost bits of the number, stopping after the leftmost 1-bit. It does this by anding out the low-order bit of the number j and oring it into a new number, i. Then j is shifted right. E.g., the number j = 01101 becomes 01011. If the number j matches the input number, then the input number is a palindrome, and the procedure returns TRUE. If the reversed number is less than the input number, it may be that the input number has trailing zeros. E.g., 0110 has reversal 0011. Since this is less than the input number, we shift it left until it is no longer less, giving 0110. Since this equals the input number, we call the number a palindrome. If you don't want to consider the leading zeros, then you leave out the second while loop and say that the number 0110 is not a palindrome.


#include

bool isPalindrome(int N)
{
int i = 0, j = N;
while(j)
{
i = (i << 1) | (j & 1); j >>= 1;
}
return(i == N);
}

int main()
{
printf( " %d ", isPalindrome(9));

}


TC O(logn) as You Know that n=logk(base 2)
Sc O(1)
Run Here http://ideone.com/ddovS


Most Optimized Way can Be Find Here http://www-graphics.stanford.edu/~seander/bithacks.html#BitReverseTable in O(1) :)

WAP Search An Element in N-Ary Tree Efficiently

Given an n-ary tree , you have to search for an element in the tree without using recursion.
int FindNum(node *head, int num)
{

}

Note: Review Needed...??

Using BFS is Absolutely Efficient Way to Solve it..kep in Mind Recursion(DFS) is not good because it needs memory stack.

#include
#include
#define MAX_Q_SIZE 500
 
/* A binary tree node has data, pointer to left child
   and a pointer to right child */
struct node
{
    int data;
    struct node *child[];
   
};
 
/* frunction prototypes */
struct node** createQueue(int *, int *);
void enQueue(struct node **, int *, struct node *);
struct node *deQueue(struct node **, int *);
 
/* Given a binary tree, print its nodes in level order
   using array for implementing queue */
void printLevelOrder(struct node* root,int val)
{
  int rear, front;
  struct node **queue = createQueue(&front, &rear);
  struct node *temp_node = root;
  int i=0;
  while(temp_node)
  {
     if(temp_node->data==val)
printf("item found");
else
printf(" Item DNE");

  i=0;
    /*Enqueue left child */
if(temp_node->child[i])
{
     while(temp_node->child[i)
{
       enQueue(queue, &rear, temp_node->left);
i++;
}
 
    
 
    /*Dequeue node and make it temp_node*/
    temp_node = deQueue(queue, &front);
  }
}
 
/*UTILITY FUNCTIONS*/
struct node** createQueue(int *front, int *rear)
{
  struct node **queue =
   (struct node **)malloc(sizeof(struct node*)*MAX_Q_SIZE); 
 
  *front = *rear = 0;
  return queue;
}
 
void enQueue(struct node **queue, int *rear, struct node *new_node)
{
  queue[*rear] = new_node;
  (*rear)++;
}    
 
struct node *deQueue(struct node **queue, int *front)
{
  (*front)++;
  return queue[*front - 1];
}    
 
/* Helper function that allocates a new node with the
   given data and NULL left and right pointers. */
struct node* newNode(int data)
{
  struct node* node = (struct node*)
                       malloc(sizeof(struct node));
  node->data = data;
  node->left = NULL;
  node->right = NULL;
 
  return(node);
}
 
/* Driver program to test above functions*/
int main()
{
  struct node *root = newNode(11);
int i=0,j=0;int k=1;
for(i=0;i<4;i++)
{
for(j=0;j<4;j++)
{
   root->child[i]= newNode(k);
k++;
}
k++;
root=root->child[i];
}
  
  printf("Level Order traversal of binary tree is \n");
  printLevelOrder(root);
 
  getchar();
  return 0;
}

TC O(nlogn)
SC O(1)
Run Here

WAP to convert a given string to its palindrome string by appending min chars at the right side of string.

Example
e.g. i/p is abc , o/p should be abcba
i/p is aaba , o/p should be aabaa.

aaba is not a palindrome

aaaa is a palindorme (so it does not require anything)

aabaa is also a palindrome (so it does not require anything)

Example 1:
-------------
str = abcbad;
revStr = dabcba;
output = abcbadabcba

Example 2:
----------------
str = abcb;
revStr = bcba;
output = abcba;

Ecample 3
str = rrrr
revstr=rrrr
output=rrrr

You have a note to write by cutting and pasting necessary letters from the book, write an algorithm to see if you can write the note.

import java.util.*;
import java.io.*;

public class NoteChecker
{

private final File noteFile;
private final File bookFile;

private int noteTotalLength = 0;

private void checkIfFileExists(File file)
{
if( ! file.exists() )
{
throw new IllegalArgumentException("File doesn't exists '" + file.getPath() + "'");
}
}

public NoteChecker(String noteFilePath, String bookFilePath){
super();

noteFile = new File(noteFilePath);
checkIfFileExists(noteFile);

bookFile = new File(bookFilePath);
checkIfFileExists(bookFile);
}

private int[] getRequiredLetters()
{

final int[] requiredLetters = new int[128];

Scanner noteSc = null;

try{

noteSc = new Scanner(noteFile);

while( noteSc.hasNextLine() ){
String line = noteSc.nextLine();

for(int i =0; i < line.length(); i++ ){
char ch = line.charAt(i);
++requiredLetters[ch];
++noteTotalLength;
}
}
}
catch(Exception ex ){
ex.printStackTrace();
return requiredLetters;
}
finally {
if( noteSc != null ){
noteSc.close();
}
}

return requiredLetters;
}

public boolean canCreateNote()
{

final int[] requiredLetters = getRequiredLetters();

Scanner bookSc = null;

try
{

bookSc = new Scanner(bookFile);

while( bookSc.hasNextLine() )
{
String line = bookSc.nextLine();

for(int i =0; i < line.length() && noteTotalLength > 0; i++ )
{
char ch = line.charAt(i);

if( requiredLetters[ch] > 0 )
{
--requiredLetters[ch];
--noteTotalLength;
}
}
}
}
catch(Exception ex)
{

ex.printStackTrace();
return false;
}
finally
{
if( bookSc != null )
{
bookSc.close();
}
}
return noteTotalLength == 0 ? true : false;
}



public static void main(String a[])
{

NoteChecker ob=new NoteChecker("E:/ubuntu/note.txt","E:/ubuntu/Input.txt");
System.out.println(ob.canCreateNote());


}
}
Above Solution is provided By Max

TC O(m+n)
SC O(1)

WAP to Find Maximum and minimum of an array using minimum number of comparisons

Write a C function to return minimum and maximum in an array. You program should make minimum number of comparisons.

First of all, how do we return multiple values from a C function? We can do it either using structures or pointers.

We have created a structure named pair (which contains min and max) to return multiple values.

?
struct pair
{
int min;
int max;
};
And the function declaration becomes: struct pair getMinMax(int arr[], int n) where arr[] is the array of size n whose minimum and maximum are needed.


Method 1

Initialize values of min and max as minimum and maximum of the first two elements respectively. Starting from 3rd, compare each element with max and min, and change max and min accordingly (i.e., if the element is smaller than min then change min, else if the element is greater than max then change max, else ignore the element)

/* structure is used to return two values from minMax() */
#include
struct pair
{
int min;
int max;
};

struct pair getMinMax(int arr[], int n)
{
struct pair minmax;
int i;

/*If there is only one element then return it as min and max both*/
if(n == 1)
{
minmax.max = arr[0];
minmax.min = arr[0];
return minmax;
}

/* If there are more than one elements, then initialize min
and max*/
if(arr[0] > arr[1])
{
minmax.max = arr[0];
minmax.min = arr[1];
}
else
{
minmax.max = arr[0];
minmax.min = arr[1];
}

for(i = 2; i {
if(arr[i] > minmax.max)
minmax.max = arr[i];

else if(arr[i] < minmax.min)
minmax.min = arr[i];
}

return minmax;
}

/* Driver program to test above function */
int main()
{
int arr[] = {1000, 11, 445, 1, 330, 3000};
int arr_size = 6;
struct pair minmax = getMinMax (arr, arr_size);
printf("\nMinimum element is %d", minmax.min);
printf("\nMaximum element is %d", minmax.max);
getchar();
}

Time Complexity: O(n)
Space Complexity O(1)
Run Here https://ideone.com/yFZNJ

In this method, total number of comparisons is 1 + 2(n-2) in worst case and 1 + n – 2 in best case.
In the above implementation, worst case occurs when elements are sorted in descending order and best case occurs when elements are sorted in ascending order.



METHOD 2 (Tournament Method) (Efficient)

Divide the array into two parts and compare the maximums and minimums of the the two parts to get the maximum and the minimum of the the whole array.

Pair MaxMin(array, array_size)
if array_size = 1
return element as both max and min
else if arry_size = 2
one comparison to determine max and min
return that pair
else /* array_size > 2 */
recur for max and min of left half
recur for max and min of right half
one comparison determines true max of the two candidates
one comparison determines true min of the two candidates
return the pair of max and min
Implementation

/* structure is used to return two values from minMax() */
#include
struct pair
{
int min;
int max;
};

struct pair getMinMax(int arr[], int low, int high)
{
struct pair minmax, mml, mmr;
int mid;

/* If there is only on element */
if(low == high)
{
minmax.max = arr[low];
minmax.min = arr[low];
return minmax;
}

/* If there are two elements */
if(high == low + 1)
{
if(arr[low] > arr[high])
{
minmax.max = arr[low];
minmax.min = arr[high];
}
else
{
minmax.max = arr[high];
minmax.min = arr[low];
}
return minmax;
}

/* If there are more than 2 elements */
mid = (low + high)/2;
mml = getMinMax(arr, low, mid);
mmr = getMinMax(arr, mid+1, high);

/* compare minimums of two parts*/
if(mml.min < mmr.min)
minmax.min = mml.min;
else
minmax.min = mmr.min;

/* compare maximums of two parts*/
if(mml.max > mmr.max)
minmax.max = mml.max;
else
minmax.max = mmr.max;

return minmax;
}

/* Driver program to test above function */
int main()
{
int arr[] = {1000, 11, 445, 1, 330, 3000};
int arr_size = 6;
struct pair minmax = getMinMax(arr, 0, arr_size-1);
printf("\nMinimum element is %d", minmax.min);
printf("\nMaximum element is %d", minmax.max);
getchar();
}

Number of Instruction Executed less
Time Complexity: O(n)
Space Complexity
Run Here https://ideone.com/jB3tu

Total number of comparisons: let number of comparisons be T(n). T(n) can be written as follows:
Algorithmic Paradigm: Divide and Conquer

T(n) = T(floor(n/2)) + T(ceil(n/2)) + 2
T(2) = 1
T(1) = 0
If n is a power of 2, then we can write T(n) as:

T(n) = 2T(n/2) + 2
After solving above recursion, we get

T(n) = 3/2n -2
Thus, the approach does 3/2n -2 comparisons if n is a power of 2. And it does more than 3/2n -2 comparisons if n is not a power of 2.

WAP to generate the Dyck Word from given string.??

A Dyck word is a string consisting of n X's and n Y's such that no initial segment of the string has more Y's than X's

It Can Be Solved by Catalan Number Cn=2nCn/(n+1)=2n!/n!*n+1!

Cn is the number of Dyck words of length 2n. A For example, the following are the Dyck words of length 6:

XXXYYY XYXXYY XYXYXY XXYYXY XXYXYY.


class DyckWord
{
public static void printDyckWord(int xnum, int ynum, char[] str, int count)
{
if (xnum < 0 || ynum < xnum) return; // invalid state
if (xnum == 0 && ynum == 0)
{
System.out.println(str); // found one, so print it
}
else
{
if (xnum > 0) { // try a left paren, if there are some available
str[count] = 'X';
printDyckWord(xnum - 1, ynum, str, count + 1);
}
if (ynum > xnum) { // try a right paren, if there’s a matching left
str[count] = 'Y';
printDyckWord(xnum, ynum - 1, str, count + 1);
}
}
}

public static void printDyckWord(int count)
{
char[] str = new char[count*2];//As DyckWord is 2n length nX + nY
printDyckWord(count, count, str, 0);
}
public static void main(String a[])
{
printDyckWord(3);
}
}

Time Complexity O(n)
Space Complexity O(1)
Run Here http://www.ideone.com/pBgGO

WAP to Calculate the next Smallest Prime Number From Given Number Efficiently

Given a number n, compute the smallest prime that is bigger than n. For example, n=8, then the smallest prime that bigger than 8 is 11. n=23 o/p is 29 & so on

#include

int power(int x, int y)
{
int temp;
if( y == 0)
return 1;
temp = power(x, y/2);
if (y%2 == 0)
return temp*temp;
else
return x*temp*temp;
}


double sqrt(const double s)
{

double xn = s / 2.0;
double lastX = 0.0;

// Looping this way ensures we perform only as many calculations as necessary.
// Can be replaced with a static for loop if you really want to.
while(xn != lastX) {
lastX = xn;
xn = (xn + s/xn) / 2.0;
}

return xn;

}
bool is_prime(int x)
{
if(x <= 1)
return false;
int s = (int) sqrt(x);
for(int i = 2; i <= s; i++)
if(x%i == 0)
return false;
return true;
}

int next_prime(int n)
{
int i=n+1;


/*The largest known Mersenne prime (243,112,609 − 1) is also the largest known prime
number,else // no such prime exist explain above
int pow=power(2,243112609)−1;
if(n>pow)
return 0; this line wont execute overflow*/

while(true)
{

if(is_prime(i))
break;
i++;

}
return i;
}
int main()
{
printf( " %d ", next_prime(23));
return 0;

}


TC of isprime is O(sqrt(n))
TC of sqrt is log(n)
TC of pow function is O(logn)
TC of next prime O(k*sqrt(n) where k is number of iteration used to find next smallest prime so k is constant & so overall time complexity of this algo is O(sqrt(n))

TC O(sqrt(n))
SC O(1)
Run Here https://ideone.com/5ViQe

Feel Free to Comment or Optimize the solution or if any issue with time complexity

WAP find Minimum Distance Between two Nodes In Binary Tree

Algorithm

Assume each node has parent pointer:
let distance d=0;
1. Start from the node 1 and find the distance of the node from root by traversing up. let it be d1.
2. start from node 2 and do the same. let this distance be d2.
3.if(d1>d2) then traverse d1-d2 nodes up from the node2. add d=d+(d1-d2)
4.now traverse up from each node from that place until both point to same node. while traversing up make d=d+2;
5. when both reaches to same node, it represents the common ancestor. so substract 1 from d.
6. now d represents the distance between two nodes.

Algo Suggested By sreenivas putta then I Coded It.

Efficiency Level:- Not Efficient (cause Parent Pointer Overhead)

#include
#include

/* A binary tree node has data, pointer to left child
and a pointer to right child */
struct node
{
int data;
struct node* left;
struct node* right;
struct node* parent;
};

/* Helper function that allocates a new node with the
given data and NULL left and right pointers. */
struct node* newNode(int data)
{
struct node* node = (struct node*)
malloc(sizeof(struct node));
node->data = data;
node->left = NULL;
node->right = NULL;

return(node);
}

int distance(struct node* root, struct node* n1,struct node* n2)
{
int d=0,d1=0,d2=0;
struct node* temp=n1;

while(temp->parent!=NULL)
{
temp=temp->parent;
d1++;

}
temp=n2;

while(temp->parent!=NULL)
{
temp=temp->parent;
d2++;

}
if(d1>d2)
{

d=d1-d2;
while((d1-d2)>0)
{

n1=n1->parent;
d1--;
}

}
else
{
d=d2-d1;
while((d2-d1)>0)
{
n2=n2->parent;
d2--;
}

}
while(n1!=n2)
{

n1=n1->parent;
n2=n2->parent;
d+=2;

}
return d;

}

/* Given a binary tree, print its nodes in inorder*/
void printPreorder(struct node* node)
{
if (node == NULL)
return;

/* first print data of node */
printf("%d ", node->data);

/* then recur on left sutree */
printPreorder(node->left);

/* now recur on right subtree */
printPreorder(node->right);
}

/* Driver program to test above functions*/
int main()
{
struct node *root = newNode(1);
root->parent=NULL;

root->left = newNode(2);
root->right = newNode(3);
root->left->parent=root;
root->right->parent=root;

root->left->left = newNode(4);
root->left->right = newNode(5);
root->left->left->parent=root->left;
root->left->right->parent=root->left;

root->left->left->left = newNode(6);
root->left->left->right = newNode(7);
root->left->left->left->parent= root->left->left;
root->left->left->right->parent= root->left->left;

root->left->right->left = newNode(8);
root->left->right->right = newNode(9);
root->left->right->left->parent= root->left->right;
root->left->right->right->parent= root->left->right;

root->right->left = newNode(10);
root->right->right = newNode(11);
root->right->left->parent=root->right;
root->right->right->parent=root->right;


root->right->left->left = newNode(12);
root->right->left->right = newNode(13);
root->right->left->left->parent=root->right->left;
root->right->left->right->parent=root->right->left;

root->right->right->left = newNode(14);
root->right->right->right = newNode(15);
root->right->right->left->parent=root->right->right;
root->right->right->right->parent=root->right->right;

//printf("\n Preorder traversal of binary tree is \n");
//printPreorder(root);

printf( " %d ", distance(root, root->left->left->left , root->right->right->right));

getchar();
return 0;
}

TC O(n)
Sc O(1)
Run Here https://ideone.com/aFNsP

Design The Data Structure & Algorithm to Show That Their Exist a Path (Connection Between Two Person on Facebook)

How would you design the data structures for a very large social network (Facebook, LinkedIn, etc)? Describe how you would design an algorithm to show the connection,
or path, between two people (e.g., Me -> Bob -> Susan -> Jason -> You).


Approach:
Forget that we’re dealing with millions of users at first. Design this for the simple case.
We can construct a graph by assuming every person is a node and if there is an edge between
two nodes, then the two people are friends with each other.
class Person {
Person[] friends;
// Other info
}
If I want to find the connection between two people, I would start with one person and do a simple breadth first search.
But... oh no! Millions of users!
When we deal with a service the size of Orkut or Facebook, we cannot possibly keep all of our data on one machine. That means that our simple Person data structure from above doesn’t quite work—our friends may not live on the same machine as us. Instead, we can replace our list of friends with a list of their IDs, and traverse as follows:
1. For each friend ID: int machine_index = lookupMachineForUserID(id);
2. Go to machine machine_index
3. Person friend = lookupFriend(machine_index);
There are more optimizations and follow up questions here than we could possibly discuss, but here are just a few thoughts.
Optimization: Reduce Machine Jumps
Jumping from one machine to another is expensive. Instead of randomly jumping from machine
to machine with each friend, try to batch these jumps—e.g., if 5 of my friends live on one machine, I should look them up all at once.
Optimization: Smart Division of People and Machines
People are much more likely to be friends with people who live in the same country as them. Rather than randomly dividing people up across machines, try to divvy them up by country, city, state, etc. This will reduce the number of jumps.
Question: Breadth First Search usually requires “marking” a node as visited. How do you do that in

this case?
Usually, in BFS, we mark a node as visited by setting a flag visited in its node class. Here, we don’t want to do that (there could be multiple searches going on at the same time, so it’s bad to just edit our data). In this case, we could mimic the marking of nodes with a hash table to lookup a node id and whether or not it’s been visited.
Other Follow-Up Questions:
»»In the real world, servers fail. How does this affect you?
»»How could you take advantage of caching?
»»Do you search until the end of the graph (infinite)? How do you decide when to give up?
»»In real life, some people have more friends of friends than others, and are therefore more likely to make a path between you and someone else. How could you use this data to pick where you start traversing?
The following code demonstrates our algorithm:

import java.util.*;

public class Server
{
ArrayList machines = new ArrayList();
}

public class Machine {
public ArrayList persons = new ArrayList();
public int machineID;
}

public class Person {
private ArrayList friends;
private int ID;
private int machineID;
private String info;
private Server server = new Server();

public String getInfo() { return info; }
public void setInfo(String info) {
this.info = info;
}

public int[] getFriends() {
int[] temp = new int[friends.size()];
for (int i = 0; i < temp.length; i++) {
temp[i] = friends.get(i);
}
return temp;
}
public int getID() { return ID; }
public int getMachineID() { return machineID; }
public void addFriend(int id) { friends.add(id); }

// Look up a person given their ID and Machine ID
public Person lookUpFriend(int machineID, int ID)
{
for (Machine m : server.machines)
{
if (m.machineID == machineID)
{
(Person p : m.persons)
{
if (p.ID == ID){
return p;
}
}
}
}
return null;
}

// Look up a machine given the machine ID
public Machine lookUpMachine(int machineID)
{
for (Machine m:server.machines)
{
if (m.machineID == machineID)
return m;
}
return null;
}

public Person(int iD, int machineID)
{
ID = iD;
this.machineID = machineID;
}

}

Algorithm & Solution Given By Galye

WAP to Find Maximum Difference between two Index of array such that value at 1st index is less then value at 2nd Index, Efficiently

WAP to find out maximum j-i such that a[i]
Method 1

Algorithm
Use two loops. In the outer loop, pick elements one by one from left. In the inner loop, compare the picked element with the elements starting from right side. Stop the inner loop when you see an element greater than the picked element and keep updating the maximum j-i so far.


#include
/* For a given array arr[], returns the maximum j – i such that
arr[j] > arr[i] */
struct maxdif
{
int i;
int j;
int maxDiff;

};
struct maxdif maxIndexDiff(int a[],int n)
{
struct maxdif maxdif;
maxdif.maxDiff=-1;
int i=0,j=0;
for(i=0;i {
for(j=n-1;j>0;j--)
{
if(a[i] {
maxdif.i=i;
maxdif.j=j;
maxdif.maxDiff=j-i;
}
}
}
return maxdif;
}

int main()
{ int ar[]={9,2,3,4,5,6,7,8,20,1};
int n=sizeof(ar)/sizeof(int);
struct maxdif max_diff=maxIndexDiff(ar,n);
printf(" j=%d i=%d maximum difference=%d", max_diff.j,max_diff.i,max_diff.maxDiff);
return 0;
}

Worst Case O(n^2)
Input: {1, 2, 3, 4, 5, 6}
Output: 5 (j = 5, i = 0)

Best Case O(n)
Input: {6, 5, 4, 3, 2, 1}
Output: -1

Time Complexity: O(n^2)
Space Complexity O(1)
Run Here https://ideone.com/lzIEd

Method 2 (Algorithm Given By Celicom


Here is a draft O(N) algo to find max{j-i,A[j]>A[i]}.
For a given array of numbers A[N] (zero based),
1) Create array B[N]. Init it the following way:
B[0] = A[0];
for(i=1;i2) Create array C[N]. Init it this way:
C[N-1] = A[N-1];
for(i=N-2;i>=0;--i) C[i] = max(A[i],C[i+1]);
3) Let max_i_j = 0, i=j=0. Now, do this merge type of calculation on B and C:
while(jwhile(B[i] < C[j] && jmax_i_j = max(max_i_j,j-i);
i=i+1;j=j+1;
}

so To solve this problem, we need to get two optimum indexes of arr[]: left index i and right index j. For an element arr[i], we do not need to consider arr[i] for left index if there is an element smaller than arr[i] on left side of arr[i]. Similarly, if there is a greater element on right side of arr[j] then we do not need to consider this j for right index. So we construct two auxiliary arrays LMin[] and RMax[] such that LMin[i] holds the smallest element on left side of arr[i] including arr[i], and RMax[j] holds the greatest element on right side of arr[j] including arr[j]. After constructing these two auxiliary arrays, we traverse both of these arrays from left to right. While traversing LMin[] and RMa[] if we see that LMin[i] is greater than RMax[j], then we must move ahead in LMin[] (or do i++) because all elements on left of LMin[i] are greater than or equal to LMin[i]. Otherwise we must move ahead in RMax[j] to look for a greater j – i value.


#include
 
/* Utility Functions to get max and minimum of two integers */
int max(int x, int y)
{
    return x > y? x : y;
}
 
int min(int x, int y)
{
    return x < y? x : y;
}
 
/* For a given array arr[], returns the maximum j – i such that
    arr[j] > arr[i] */
int maxIndexDiff(int arr[], int n)
{
    int maxDiff;
    int i, j;
 
    int *LMin = (int *)malloc(sizeof(int)*n);
    int *RMax = (int *)malloc(sizeof(int)*n);
 
   /* Construct LMin[] such that LMin[i] stores the minimum value
       from (arr[0], arr[1], ... arr[i]) */
    LMin[0] = arr[0];
    for (i = 1; i < n; ++i)
        LMin[i] = min(arr[i], LMin[i-1]);
 
    /* Construct RMax[] such that RMax[j] stores the maximum value
       from (arr[j], arr[j+1], ..arr[n-1]) */
    RMax[n-1] = arr[n-1];
    for (j = n-2; j >= 0; --j)
        RMax[j] = max(arr[j], RMax[j+1]);
 
    /* Traverse both arrays from left to right to find optimum j - i
        This process is similar to merge() of MergeSort */
    i = 0, j = 0, maxDiff = -1;
    while (j < n && i < n)
    {
        if (LMin[i] < RMax[j])
        {
            maxDiff = max(maxDiff, j-i);
            j = j + 1;
        }
        else
            i = i+1;
    }
 
    return maxDiff;
}
 
/* Driver program to test above functions */
int main()
{
    int arr[] = {9,2,3,4,5,6,7,8,20,1};
    int n = sizeof(arr)/sizeof(arr[0]);
    int maxDiff = maxIndexDiff(arr, n);
    printf("\n %d", maxDiff);
    getchar();
    return 0;
}


Time Complexity O(n)
Space Complexity O(n)
Ryun Here https://ideone.com/vQOMi