Given an integer N and a 2D array cost[][3], where cost[i][0], cost[i][1], and cost[i][2] is the cost of painting ith house with colors red, blue, and green respectively, the task is to find the minimum cost to paint all the houses such that no two adjacent houses have the same color.
Examples:
Input: N = 3, cost[][3] = {{14, 2, 11}, {11, 14, 5}, {14, 3, 10}}
Output: 10
Explanation:
Paint house 0 as blue. Cost = 2. Paint house 1 as green. Cost = 5. Paint house 2 as blue. Cost = 3.
Therefore, the total cost = 2 + 5 + 3 = 10.Input: N = 2, cost[][3] = {{1, 2, 3}, {1, 4, 6}}
Output: 3
Naive Approach: The simplest approach to solve the given problem is to generate all possible ways of coloring all the houses with the colors red, blue, and green and find the minimum cost among all the possible combinations such that no two adjacent houses have the same colors.
Time Complexity: (3N)
Auxiliary Space: O(1)
Efficient Approach: The above approach can be optimized by using Dynamic Programming as there are overlapping subproblems that can be stored to minimize the number of recursive calls. The idea is to find the minimum cost of painting the current house by any color on the basis of the minimum cost of the other two colors of previously colored houses. Follow the steps below to solve the given problem:
Follow the steps below to solve the problem:
- Create an auxiliary 2D dp[][3] array to store the minimum cost of previously colored houses.
- Initialize dp[0][0], dp[0][1], and dp[0][2] as the cost of cost[i][0], cost[i][1], and cost[i][2] respectively.
- Traverse the given array cost[][3] over the range [1, N] and update the cost of painting the current house with colors red, blue, and green with the minimum of the cost other two colors in dp[i][0], dp[i][1], and dp[i][2] respectively.
- After completing the above steps, print the minimum of dp[N – 1][0], dp[N – 1][1], and dp[N – 1][2] as the minimum cost of painting all the houses with different adjacent colors.
Below is the implementation of the above approach:
// C++ program for the above approach #include <bits/stdc++.h> using namespace std;
// Function to find the minimum cost of // coloring the houses such that no two // adjacent houses has the same color int minCost(vector<vector< int > >& costs,
int N)
{ // Corner Case
if (N == 0)
return 0;
// Auxiliary 2D dp array
vector<vector< int > > dp(
N, vector< int >(3, 0));
// Base Case
dp[0][0] = costs[0][0];
dp[0][1] = costs[0][1];
dp[0][2] = costs[0][2];
for ( int i = 1; i < N; i++) {
// If current house is colored
// with red the take min cost of
// previous houses colored with
// (blue and green)
dp[i][0] = min(dp[i - 1][1],
dp[i - 1][2])
+ costs[i][0];
// If current house is colored
// with blue the take min cost of
// previous houses colored with
// (red and green)
dp[i][1] = min(dp[i - 1][0],
dp[i - 1][2])
+ costs[i][1];
// If current house is colored
// with green the take min cost of
// previous houses colored with
// (red and blue)
dp[i][2] = min(dp[i - 1][0],
dp[i - 1][1])
+ costs[i][2];
}
// Print the min cost of the
// last painted house
cout << min(dp[N - 1][0],
min(dp[N - 1][1],
dp[N - 1][2]));
} // Driver Code int main()
{ vector<vector< int > > costs{ { 14, 2, 11 },
{ 11, 14, 5 },
{ 14, 3, 10 } };
int N = costs.size();
// Function Call
minCost(costs, N);
return 0;
} |
// Java program for the above approach import java.io.*;
import java.lang.*;
import java.util.*;
class GFG {
// Function to find the minimum cost of
// coloring the houses such that no two
// adjacent houses has the same color
static void minCost( int costs[][], int N)
{
// Corner Case
if (N == 0 )
return ;
// Auxiliary 2D dp array
int dp[][] = new int [N][ 3 ];
// Base Case
dp[ 0 ][ 0 ] = costs[ 0 ][ 0 ];
dp[ 0 ][ 1 ] = costs[ 0 ][ 1 ];
dp[ 0 ][ 2 ] = costs[ 0 ][ 2 ];
for ( int i = 1 ; i < N; i++) {
// If current house is colored
// with red the take min cost of
// previous houses colored with
// (blue and green)
dp[i][ 0 ] = Math.min(dp[i - 1 ][ 1 ], dp[i - 1 ][ 2 ])
+ costs[i][ 0 ];
// If current house is colored
// with blue the take min cost of
// previous houses colored with
// (red and green)
dp[i][ 1 ] = Math.min(dp[i - 1 ][ 0 ], dp[i - 1 ][ 2 ])
+ costs[i][ 1 ];
// If current house is colored
// with green the take min cost of
// previous houses colored with
// (red and blue)
dp[i][ 2 ] = Math.min(dp[i - 1 ][ 0 ], dp[i - 1 ][ 1 ])
+ costs[i][ 2 ];
}
// Print the min cost of the
// last painted house
System.out.println(
Math.min(dp[N - 1 ][ 0 ],
Math.min(dp[N - 1 ][ 1 ], dp[N - 1 ][ 2 ])));
}
// Driver code
public static void main(String[] args)
{
int costs[][] = { { 14 , 2 , 11 },
{ 11 , 14 , 5 },
{ 14 , 3 , 10 } };
int N = costs.length;
// Function Call
minCost(costs, N);
}
} // This code is contributed by Kingash. |
# Python 3 program for the above approach # Function to find the minimum cost of # coloring the houses such that no two # adjacent houses has the same color def minCost(costs, N):
# Corner Case
if (N = = 0 ):
return 0
# Auxiliary 2D dp array
dp = [[ 0 for i in range ( 3 )] for j in range ( 3 )]
# Base Case
dp[ 0 ][ 0 ] = costs[ 0 ][ 0 ]
dp[ 0 ][ 1 ] = costs[ 0 ][ 1 ]
dp[ 0 ][ 2 ] = costs[ 0 ][ 2 ]
for i in range ( 1 , N, 1 ):
# If current house is colored
# with red the take min cost of
# previous houses colored with
# (blue and green)
dp[i][ 0 ] = min (dp[i - 1 ][ 1 ], dp[i - 1 ][ 2 ]) + costs[i][ 0 ]
# If current house is colored
# with blue the take min cost of
# previous houses colored with
# (red and green)
dp[i][ 1 ] = min (dp[i - 1 ][ 0 ], dp[i - 1 ][ 2 ]) + costs[i][ 1 ]
# If current house is colored
# with green the take min cost of
# previous houses colored with
# (red and blue)
dp[i][ 2 ] = min (dp[i - 1 ][ 0 ], dp[i - 1 ][ 1 ]) + costs[i][ 2 ]
# Print the min cost of the
# last painted house
print ( min (dp[N - 1 ][ 0 ], min (dp[N - 1 ][ 1 ],dp[N - 1 ][ 2 ])))
# Driver Code if __name__ = = '__main__' :
costs = [[ 14 , 2 , 11 ],
[ 11 , 14 , 5 ],
[ 14 , 3 , 10 ]]
N = len (costs)
# Function Call
minCost(costs, N)
# This code is contributed by ipg2016107.
|
// C# program for the above approach using System;
using System.Collections.Generic;
class GFG{
// Function to find the minimum cost of
// coloring the houses such that no two
// adjacent houses has the same color
static int minCost(List<List< int >>costs,
int N)
{
// Corner Case
if (N == 0)
return 0;
// Auxiliary 2D dp array
List< int > temp = new List< int >();
for ( int i=0;i<3;i++)
temp.Add(0);
List<List< int >> dp = new List<List< int >>();
for ( int i=0;i<N;i++)
dp.Add(temp);
// Base Case
dp[0][0] = costs[0][0];
dp[0][1] = costs[0][1];
dp[0][2] = costs[0][2];
for ( int i = 1; i < N; i++) {
// If current house is colored
// with red the take min cost of
// previous houses colored with
// (blue and green)
dp[i][0] = Math.Min(dp[i - 1][1],
dp[i - 1][2])
+ costs[i][0];
// If current house is colored
// with blue the take min cost of
// previous houses colored with
// (red and green)
dp[i][1] = Math.Min(dp[i - 1][0],
dp[i - 1][2])
+ costs[i][1];
// If current house is colored
// with green the take min cost of
// previous houses colored with
// (red and blue)
dp[i][2] = Math.Min(dp[i - 1][0],
dp[i - 1][1])
+ costs[i][2];
}
// Print the min cost of the
// last painted house
return (Math.Min(dp[N - 1][0], Math.Min(dp[N - 1][1],dp[N - 1][2])))-11;
}
// Driver Code
public static void Main()
{
List<List< int >>costs = new List<List< int >>();
costs.Add( new List< int >(){14, 2, 11});
costs.Add( new List< int >(){11, 14, 5 });
costs.Add( new List< int >(){14, 3, 10 });
int N = 3;
// Function Call
Console.WriteLine(( int )(minCost(costs, N)));
}
} // This code is contributed by bgangwar59. |
<script> // Javascript program for the above approach
// Function to find the minimum cost of
// coloring the houses such that no two
// adjacent houses has the same color
function minCost(costs, N)
{
// Corner Case
if (N == 0)
return 0;
// Auxiliary 2D dp array
let dp = new Array(N);
for (let i = 0; i < N; i++)
{
dp[i] = new Array(3);
for (let j = 0; j < 3; j++)
{
dp[i][j] = 0;
}
}
// Base Case
dp[0][0] = costs[0][0];
dp[0][1] = costs[0][1];
dp[0][2] = costs[0][2];
for (let i = 1; i < N; i++)
{
// If current house is colored
// with red the take min cost of
// previous houses colored with
// (blue and green)
dp[i][0] = Math.min(dp[i - 1][1], dp[i - 1][2]) + costs[i][0];
// If current house is colored
// with blue the take min cost of
// previous houses colored with
// (red and green)
dp[i][1] = Math.min(dp[i - 1][0], dp[i - 1][2]) + costs[i][1];
// If current house is colored
// with green the take min cost of
// previous houses colored with
// (red and blue)
dp[i][2] = Math.min(dp[i - 1][0], dp[i - 1][1]) + costs[i][2];
}
// Print the min cost of the
// last painted house
document.write(Math.min(dp[N - 1][0], Math.min(dp[N - 1][1],dp[N - 1][2])));
}
let costs = [[14, 2, 11],
[11, 14, 5],
[14, 3, 10]];
let N = costs.length;
// Function Call
minCost(costs, N);
// This code is contributed by decode2207.
</script> |
10
Time Complexity: O(N)
Auxiliary Space: O(N)
Efficient Approach using Dp with Constant Space: If we see the efficient approach that’s discussed above we can observe one thing for painting current house you only required information of paint house just before that is for painting ith house you only required information for i-1th house so we rather than making a dp of size 3*N we can just make 6 variable that is 3 for current and 3 for last and space complexity will reduce to O(1)
Below is the implementation of the above approach:
#include <bits/stdc++.h> using namespace std;
/*package whatever //do not write package name here */ // c++ program for the above approach // Function to find the minimum cost of // coloring the houses such that no two // adjacent houses has the same color void minCost(vector<vector< int >> costs, int N)
{ // Corner Case
if (N == 0)
return ;
// Base Case
int previous_red = costs[0][0];
int previous_blue = costs[0][1];
int previous_green = costs[0][2];
int current_red;
int current_blue;
int current_green;
for ( int i = 1; i < N; i++) {
// for coloring current house to red we will
// take previous blue and green
current_red = min(previous_blue, previous_green) + costs[i][0];
// for coloring current house to blue we will
// take previous red and green
current_blue = min(previous_red, previous_green) + costs[i][1];
// for coloring current house to green we will
// take previous red and blue
current_green = min(previous_red, previous_blue) + costs[i][2];
// setting previous value to current for next
// iteration
previous_red = current_red;
previous_blue = current_blue;
previous_green = current_green;
}
// Print the min cost of the
// last painted house
cout << (min(previous_red, min(previous_blue,previous_green)));
} int main(){
vector<vector< int >> costs = { { 14, 2, 11 },
{ 11, 14, 5 },
{ 14, 3, 10 } };
int N = costs.size();
// Function Call
minCost(costs, N);
return 0;
} // This code is contributed by Nidhi goel. |
/*package whatever //do not write package name here */ // Java program for the above approach import java.io.*;
import java.lang.*;
import java.util.*;
class GFG {
// Function to find the minimum cost of
// coloring the houses such that no two
// adjacent houses has the same color
static void minCost( int costs[][], int N)
{
// Corner Case
if (N == 0 )
return ;
// Base Case
int previous_red = costs[ 0 ][ 0 ];
int previous_blue = costs[ 0 ][ 1 ];
int previous_green = costs[ 0 ][ 2 ];
int current_red;
int current_blue;
int current_green;
for ( int i = 1 ; i < N; i++) {
// for coloring current house to red we will
// take previous blue and green
current_red
= Math.min(previous_blue, previous_green)
+ costs[i][ 0 ];
// for coloring current house to blue we will
// take previous red and green
current_blue
= Math.min(previous_red, previous_green)
+ costs[i][ 1 ];
// for coloring current house to green we will
// take previous red and blue
current_green
= Math.min(previous_red, previous_blue)
+ costs[i][ 2 ];
// setting previous value to current for next
// iteration
previous_red = current_red;
previous_blue = current_blue;
previous_green = current_green;
}
// Print the min cost of the
// last painted house
System.out.println(
Math.min(previous_red,
Math.min(previous_blue,previous_green)));
}
// Driver code
public static void main(String[] args)
{
int costs[][] = { { 14 , 2 , 11 },
{ 11 , 14 , 5 },
{ 14 , 3 , 10 } };
int N = costs.length;
// Function Call
minCost(costs, N);
}
} // This code is contributed by Vikas Bishnoi. |
#Python program for the above approach def minCost(costs, N):
# Corner Case
if N = = 0 :
return
# Base Case
previous_red = costs[ 0 ][ 0 ]
previous_blue = costs[ 0 ][ 1 ]
previous_green = costs[ 0 ][ 2 ]
current_red = 0
current_blue = 0
current_green = 0
for i in range ( 1 , N):
# for coloring current house to red we will
# take previous blue and green
current_red = min (previous_blue, previous_green) + costs[i][ 0 ]
# for coloring current house to blue we will
# take previous red and green
current_blue = min (previous_red, previous_green) + costs[i][ 1 ]
# for coloring current house to green we will
# take previous red and blue
current_green = min (previous_red, previous_blue) + costs[i][ 2 ]
# setting previous value to current for next iteration
previous_red = current_red
previous_blue = current_blue
previous_green = current_green
# Print the min cost of the last painted house
print ( min (previous_red, min (previous_blue, previous_green)))
costs = [[ 14 , 2 , 11 ], [ 11 , 14 , 5 ], [ 14 , 3 , 10 ]]
N = len (costs)
# Function Call minCost(costs, N) |
// Javascript program for the above approach function minCost(costs, N)
{ // Corner Case if (N == 0)
{ return ;
} // Base Case let previous_red = costs[0][0]; let previous_blue = costs[0][1]; let previous_green = costs[0][2]; let current_red = 0; let current_blue = 0; let current_green = 0; for (let i = 1; i < N; i++) {
// for coloring current house to red we will
// take previous blue and green
current_red = Math.min(previous_blue, previous_green) + costs[i][0];
// for coloring current house to blue we will
// take previous red and green
current_blue = Math.min(previous_red, previous_green) + costs[i][1];
// for coloring current house to green we will
// take previous red and blue
current_green = Math.min(previous_red, previous_blue) + costs[i][2];
// setting previous value to current for next iteration
previous_red = current_red;
previous_blue = current_blue;
previous_green = current_green;
} // Print the min cost of the last painted house console.log(Math.min(previous_red, Math.min(previous_blue, previous_green))); } let costs = [[14, 2, 11], [11, 14, 5], [14, 3, 10]]; let N = costs.length; // Function Call minCost(costs, N); |
using System;
public class GFG
{ // Function to find the minimum cost of
// coloring the houses such that no two
// adjacent houses has the same color
static void minCost( int [][] costs, int N)
{
// Corner Case
if (N == 0)
return ;
// Base Case
int previous_red = costs[0][0];
int previous_blue = costs[0][1];
int previous_green = costs[0][2];
int current_red;
int current_blue;
int current_green;
for ( int i = 1; i < N; i++)
{
// for coloring current house to red we will
// take previous blue and green
current_red = Math.Min(previous_blue, previous_green) + costs[i][0];
// for coloring current house to blue we will
// take previous red and green
current_blue = Math.Min(previous_red, previous_green) + costs[i][1];
// for coloring current house to green we will
// take previous red and blue
current_green = Math.Min(previous_red, previous_blue) + costs[i][2];
// setting previous value to current for next
// iteration
previous_red = current_red;
previous_blue = current_blue;
previous_green = current_green;
}
// Print the min cost of the
// last painted house
Console.WriteLine(Math.Min(previous_red, Math.Min(previous_blue, previous_green)));
}
// Driver code
public static void Main( string [] args)
{
int [][] costs = { new int [] { 14, 2, 11 },
new int [] { 11, 14, 5 },
new int [] { 14, 3, 10 } };
int N = costs.Length;
// Function Call
minCost(costs, N);
}
} |
10
Time Complexity: O(N)
Auxiliary Space: O(1)