There are n-pairs and therefore 2n people. everyone has one unique number ranging from 1 to 2n. All these 2n persons are arranged in random fashion in an Array of size 2n. We are also given who is partner of whom. Find the minimum number of swaps required to arrange these pairs such that all pairs become adjacent to each other.
Example:
Input: n = 3 pairs[] = {1->3, 2->6, 4->5} // 1 is partner of 3 and so on arr[] = {3, 5, 6, 4, 1, 2} Output: 2 We can get {3, 1, 5, 4, 6, 2} by swapping 5 & 6, and 6 & 1
We strongly recommend you to minimize your browser and try this yourself first.
The idea is to start from first and second elements and recur for remaining elements. Below are detailed steps/
1) If first and second elements are pair, then simply recur for remaining n-1 pairs and return the value returned by recursive call. 2) If first and second are NOT pair, then there are two ways to arrange. So try both of them return the minimum of two. a) Swap second with pair of first and recur for n-1 elements. Let the value returned by recursive call be 'a'. b) Revert the changes made by previous step. c) Swap first with pair of second and recur for n-1 elements. Let the value returned by recursive call be 'b'. d) Revert the changes made by previous step before returning control to parent call. e) Return 1 + min(a, b)
Example: Below is the implementation of above algorithm.
// C++ program to find minimum number of swaps required so that // all pairs become adjacent. #include<bits/stdc++.h> using namespace std;
// This function updates indexes of elements 'a' and 'b' void updateindex( int index[], int a, int ai, int b, int bi)
{ index[a] = ai;
index[b] = bi;
} // This function returns minimum number of swaps required to arrange // all elements of arr[i..n] become arranged int minSwapsUtil( int arr[], int pairs[], int index[], int i, int n)
{ // If all pairs processed so no swapping needed return 0
if (i > n) return 0;
// If current pair is valid so DO NOT DISTURB this pair
// and move ahead.
if (pairs[arr[i]] == arr[i+1])
return minSwapsUtil(arr, pairs, index, i+2, n);
// If we reach here, then arr[i] and arr[i+1] don't form a pair
// Swap pair of arr[i] with arr[i+1] and recursively compute
// minimum swap required if this move is made.
int one = arr[i+1];
int indextwo = i+1;
int indexone = index[pairs[arr[i]]];
int two = arr[index[pairs[arr[i]]]];
swap(arr[i+1], arr[indexone]);
updateindex(index, one, indexone, two, indextwo);
int a = minSwapsUtil(arr, pairs, index, i+2, n);
// Backtrack to previous configuration. Also restore the
// previous indices, of one and two
swap(arr[i+1], arr[indexone]);
updateindex(index, one, indextwo, two, indexone);
one = arr[i], indexone = index[pairs[arr[i+1]]];
// Now swap arr[i] with pair of arr[i+1] and recursively
// compute minimum swaps required for the subproblem
// after this move
two = arr[index[pairs[arr[i+1]]]], indextwo = i;
swap(arr[i], arr[indexone]);
updateindex(index, one, indexone, two, indextwo);
int b = minSwapsUtil(arr, pairs, index, i+2, n);
// Backtrack to previous configuration. Also restore
// the previous indices, of one and two
swap(arr[i], arr[indexone]);
updateindex(index, one, indextwo, two, indexone);
// Return minimum of two cases
return 1 + min(a, b);
} // Returns minimum swaps required int minSwaps( int n, int pairs[], int arr[])
{ int index[2*n + 1]; // To store indices of array elements
// Store index of each element in array index
for ( int i = 1; i <= 2*n; i++)
index[arr[i]] = i;
// Call the recursive function
return minSwapsUtil(arr, pairs, index, 1, 2*n);
} // Driver program int main()
{ // For simplicity, it is assumed that arr[0] is
// not used. The elements from index 1 to n are
// only valid elements
int arr[] = {0, 3, 5, 6, 4, 1, 2};
// if (a, b) is pair than we have assigned elements
// in array such that pairs[a] = b and pairs[b] = a
int pairs[] = {0, 3, 6, 1, 5, 4, 2};
int m = sizeof (arr)/ sizeof (arr[0]);
int n = m/2; // Number of pairs n is half of total elements
// If there are n elements in array, then
// there are n pairs
cout << "Min swaps required is " << minSwaps(n, pairs, arr);
return 0;
} |
// Java program to find minimum number // of swaps required so that // all pairs become adjacent. class GFG {
// This function updates indexes // of elements 'a' and 'b' static void updateindex( int index[], int a,
int ai, int b, int bi)
{ index[a] = ai;
index[b] = bi;
} // This function returns minimum number // of swaps required to arrange // all elements of arr[i..n] become arranged static int minSwapsUtil( int arr[], int pairs[],
int index[], int i, int n)
{ // If all pairs processed so
// no swapping needed return 0
if (i > n)
return 0 ;
// If current pair is valid so
// DO NOT DISTURB this pair
// and move ahead.
if (pairs[arr[i]] == arr[i + 1 ])
return minSwapsUtil(arr, pairs, index, i + 2 , n);
// If we reach here, then arr[i] and
// arr[i+1] don't form a pair
// Swap pair of arr[i] with arr[i+1]
// and recursively compute minimum swap
// required if this move is made.
int one = arr[i + 1 ];
int indextwo = i + 1 ;
int indexone = index[pairs[arr[i]]];
int two = arr[index[pairs[arr[i]]]];
arr[i + 1 ] = arr[i + 1 ] ^ arr[indexone] ^
(arr[indexone] = arr[i + 1 ]);
updateindex(index, one, indexone, two, indextwo);
int a = minSwapsUtil(arr, pairs, index, i + 2 , n);
// Backtrack to previous configuration.
// Also restore the previous
// indices, of one and two
arr[i + 1 ] = arr[i + 1 ] ^ arr[indexone] ^
(arr[indexone] = arr[i + 1 ]);
updateindex(index, one, indextwo, two, indexone);
one = arr[i];
indexone = index[pairs[arr[i + 1 ]]];
// Now swap arr[i] with pair of arr[i+1]
// and recursively compute minimum swaps
// required for the subproblem
// after this move
two = arr[index[pairs[arr[i + 1 ]]]];
indextwo = i;
arr[i] = arr[i] ^ arr[indexone] ^ (arr[indexone] = arr[i]);
updateindex(index, one, indexone, two, indextwo);
int b = minSwapsUtil(arr, pairs, index, i + 2 , n);
// Backtrack to previous configuration. Also restore
// the previous indices, of one and two
arr[i] = arr[i] ^ arr[indexone] ^ (arr[indexone] = arr[i]);
updateindex(index, one, indextwo, two, indexone);
// Return minimum of two cases
return 1 + Math.min(a, b);
} // Returns minimum swaps required static int minSwaps( int n, int pairs[], int arr[])
{ // To store indices of array elements
int index[] = new int [ 2 * n + 1 ];
// Store index of each element in array index
for ( int i = 1 ; i <= 2 * n; i++)
index[arr[i]] = i;
// Call the recursive function
return minSwapsUtil(arr, pairs, index, 1 , 2 * n);
} // Driver code public static void main(String[] args) {
// For simplicity, it is assumed that arr[0] is
// not used. The elements from index 1 to n are
// only valid elements
int arr[] = { 0 , 3 , 5 , 6 , 4 , 1 , 2 };
// if (a, b) is pair than we have assigned elements
// in array such that pairs[a] = b and pairs[b] = a
int pairs[] = { 0 , 3 , 6 , 1 , 5 , 4 , 2 };
int m = pairs.length;
// Number of pairs n is half of total elements
int n = m / 2 ;
// If there are n elements in array, then
// there are n pairs
System.out.print( "Min swaps required is " +
minSwaps(n, pairs, arr));
} } // This code is contributed by Anant Agarwal. |
# Python program to find # minimum number of swaps # required so that # all pairs become adjacent. # This function updates # indexes of elements 'a' and 'b' def updateindex(index,a,ai,b,bi):
index[a] = ai
index[b] = bi
# This function returns minimum # number of swaps required to arrange # all elements of arr[i..n] # become arranged def minSwapsUtil(arr,pairs,index,i,n):
# If all pairs processed so
# no swapping needed return 0
if (i > n):
return 0
# If current pair is valid so
# DO NOT DISTURB this pair
# and move ahead.
if (pairs[arr[i]] = = arr[i + 1 ]):
return minSwapsUtil(arr, pairs, index, i + 2 , n)
# If we reach here, then arr[i]
# and arr[i+1] don't form a pair
# Swap pair of arr[i] with
# arr[i+1] and recursively compute
# minimum swap required
# if this move is made.
one = arr[i + 1 ]
indextwo = i + 1
indexone = index[pairs[arr[i]]]
two = arr[index[pairs[arr[i]]]]
arr[i + 1 ],arr[indexone] = arr[indexone],arr[i + 1 ]
updateindex(index, one, indexone, two, indextwo)
a = minSwapsUtil(arr, pairs, index, i + 2 , n)
# Backtrack to previous configuration.
# Also restore the
# previous indices,
# of one and two
arr[i + 1 ],arr[indexone] = arr[indexone],arr[i + 1 ]
updateindex(index, one, indextwo, two, indexone)
one = arr[i]
indexone = index[pairs[arr[i + 1 ]]]
# Now swap arr[i] with pair
# of arr[i+1] and recursively
# compute minimum swaps
# required for the subproblem
# after this move
two = arr[index[pairs[arr[i + 1 ]]]]
indextwo = i
arr[i],arr[indexone] = arr[indexone],arr[i]
updateindex(index, one, indexone, two, indextwo)
b = minSwapsUtil(arr, pairs, index, i + 2 , n)
# Backtrack to previous
# configuration. Also restore
# 3 the previous indices,
# of one and two
arr[i],arr[indexone] = arr[indexone],arr[i]
updateindex(index, one, indextwo, two, indexone)
# Return minimum of two cases
return 1 + min (a, b)
# Returns minimum swaps required def minSwaps(n,pairs,arr):
index = [] # To store indices of array elements
for i in range ( 2 * n + 1 + 1 ):
index.append( 0 )
# Store index of each
# element in array index
for i in range ( 1 , 2 * n + 1 ):
index[arr[i]] = i
# Call the recursive function
return minSwapsUtil(arr, pairs, index, 1 , 2 * n)
# Driver code # For simplicity, it is # assumed that arr[0] is # not used. The elements # from index 1 to n are # only valid elements arr = [ 0 , 3 , 5 , 6 , 4 , 1 , 2 ]
# if (a, b) is pair than # we have assigned elements # in array such that # pairs[a] = b and pairs[b] = a pairs = [ 0 , 3 , 6 , 1 , 5 , 4 , 2 ]
m = len (pairs)
n = m / / 2 # Number of pairs n
# is half of total elements
# If there are n # elements in array, then # there are n pairs print ( "Min swaps required is " ,minSwaps(n, pairs, arr))
# This code is contributed # by Anant Agarwal. |
// C# program to find minimum number // of swaps required so that // all pairs become adjacent. using System;
class GFG {
// This function updates indexes
// of elements 'a' and 'b'
public static void updateindex( int [] index, int a,
int ai, int b, int bi) {
index[a] = ai;
index[b] = bi;
}
// This function returns minimum number
// of swaps required to arrange
// all elements of arr[i..n] become arranged
public static int minSwapsUtil( int [] arr,
int [] pairs, int [] index, int i, int n) {
// If all pairs processed so
// no swapping needed return 0
if (i > n) {
return 0;
}
// If current pair is valid so
// DO NOT DISTURB this pair
// and move ahead.
if (pairs[arr[i]] == arr[i + 1]) {
return minSwapsUtil(arr, pairs,
index, i + 2, n);
}
// If we reach here, then arr[i] and
// arr[i+1] don't form a pair
// Swap pair of arr[i] with arr[i+1]
// and recursively compute minimum swap
// required if this move is made.
int one = arr[i + 1];
int indextwo = i + 1;
int indexone = index[pairs[arr[i]]];
int two = arr[index[pairs[arr[i]]]];
arr[i + 1] = arr[i + 1] ^ arr[indexone] ^
(arr[indexone] = arr[i + 1]);
updateindex(index, one, indexone, two, indextwo);
int a = minSwapsUtil(arr, pairs, index, i + 2, n);
// Backtrack to previous configuration.
// Also restore the previous
// indices, of one and two
arr[i + 1] = arr[i + 1] ^ arr[indexone] ^
(arr[indexone] = arr[i + 1]);
updateindex(index, one, indextwo, two, indexone);
one = arr[i];
indexone = index[pairs[arr[i + 1]]];
// Now swap arr[i] with pair of arr[i+1]
// and recursively compute minimum swaps
// required for the subproblem
// after this move
two = arr[index[pairs[arr[i + 1]]]];
indextwo = i;
arr[i] = arr[i] ^ arr[indexone] ^
(arr[indexone] = arr[i]);
updateindex(index, one, indexone, two, indextwo);
int b = minSwapsUtil(arr, pairs, index, i + 2, n);
// Backtrack to previous configuration.
// Also restore the previous indices,
// of one and two
arr[i] = arr[i] ^ arr[indexone] ^
(arr[indexone] = arr[i]);
updateindex(index, one, indextwo, two, indexone);
// Return minimum of two cases
return 1 + Math.Min(a, b);
}
// Returns minimum swaps required
public static int minSwaps( int n, int [] pairs, int [] arr) {
// To store indices of array elements
int [] index = new int [2 * n + 1];
// Store index of each element in array index
for ( int i = 1; i <= 2 * n; i++) {
index[arr[i]] = i;
}
// Call the recursive function
return minSwapsUtil(arr, pairs, index, 1, 2 * n);
}
// Driver code public static void Main( string [] args)
{ // For simplicity, it is assumed that arr[0] is
// not used. The elements from index 1 to n are
// only valid elements
int [] arr = new int []
{
0,
3,
5,
6,
4,
1,
2
};
// if (a, b) is pair than we have assigned elements
// in array such that pairs[a] = b and pairs[b] = a
int [] pairs = new int []
{
0,
3,
6,
1,
5,
4,
2
};
int m = pairs.Length;
// Number of pairs n is half of total elements
int n = m / 2;
// If there are n elements in array, then
// there are n pairs
Console.Write( "Min swaps required is " +
minSwaps(n, pairs, arr));
} } // This code is contributed by Shrikant13 |
<script> // javascript program to find minimum number // of swaps required so that // all pairs become adjacent. // This function updates indexes
// of elements 'a' and 'b'
function updateindex(index , a , ai , b , bi) {
index[a] = ai;
index[b] = bi;
}
// This function returns minimum number
// of swaps required to arrange
// all elements of arr[i..n] become arranged
function minSwapsUtil(arr , pairs , index , i , n) {
// If all pairs processed so
// no swapping needed return 0
if (i > n)
return 0;
// If current pair is valid so
// DO NOT DISTURB this pair
// and move ahead.
if (pairs[arr[i]] == arr[i + 1])
return minSwapsUtil(arr, pairs, index, i + 2, n);
// If we reach here, then arr[i] and
// arr[i+1] don't form a pair
// Swap pair of arr[i] with arr[i+1]
// and recursively compute minimum swap
// required if this move is made.
var one = arr[i + 1];
var indextwo = i + 1;
var indexone = index[pairs[arr[i]]];
var two = arr[index[pairs[arr[i]]]];
arr[i + 1] = arr[i + 1] ^ arr[indexone] ^ (arr[indexone] = arr[i + 1]);
updateindex(index, one, indexone, two, indextwo);
var a = minSwapsUtil(arr, pairs, index, i + 2, n);
// Backtrack to previous configuration.
// Also restore the previous
// indices, of one and two
arr[i + 1] = arr[i + 1] ^ arr[indexone] ^ (arr[indexone] = arr[i + 1]);
updateindex(index, one, indextwo, two, indexone);
one = arr[i];
indexone = index[pairs[arr[i + 1]]];
// Now swap arr[i] with pair of arr[i+1]
// and recursively compute minimum swaps
// required for the subproblem
// after this move
two = arr[index[pairs[arr[i + 1]]]];
indextwo = i;
arr[i] = arr[i] ^ arr[indexone] ^ (arr[indexone] = arr[i]);
updateindex(index, one, indexone, two, indextwo);
var b = minSwapsUtil(arr, pairs, index, i + 2, n);
// Backtrack to previous configuration. Also restore
// the previous indices, of one and two
arr[i] = arr[i] ^ arr[indexone] ^ (arr[indexone] = arr[i]);
updateindex(index, one, indextwo, two, indexone);
// Return minimum of two cases
return 1 + Math.min(a, b);
}
// Returns minimum swaps required
function minSwaps(n , pairs , arr) {
// To store indices of array elements
var index = Array(2 * n + 1).fill(0);
// Store index of each element in array index
for (i = 1; i <= 2 * n; i++)
index[arr[i]] = i;
// Call the recursive function
return minSwapsUtil(arr, pairs, index, 1, 2 * n);
}
// Driver code
// For simplicity, it is assumed that arr[0] is
// not used. The elements from index 1 to n are
// only valid elements
var arr = [ 0, 3, 5, 6, 4, 1, 2 ];
// if (a, b) is pair than we have assigned elements
// in array such that pairs[a] = b and pairs[b] = a
var pairs = [ 0, 3, 6, 1, 5, 4, 2 ];
var m = pairs.length;
// Number of pairs n is half of total elements
var n = m / 2;
// If there are n elements in array, then
// there are n pairs
document.write( "Min swaps required is " + minSwaps(n, pairs, arr));
// This code contributed by aashish1995 </script> |
Output:
Min swaps required is 2
Time Complexity: O(N2)
Auxiliary Space: O(N)
Thanks to Gaurav Ahirwar for the above solution.