Given a weighting scale and an array of different positive weights where we have an infinite supply of each weight. Our task is to put weights on left and right pans of scale one by one in such a way that pans move to that side where weight is put i.e. each time, pans of scale moves to alternate sides.
- We are given another integer ‘steps’, times which we need to perform this operation.
- Another constraint is that we can’t put same weight consecutively i.e. if weight w is taken then in next step while putting the weight on opposite pan we can’t take w again.
Examples:
Let weight array is [7, 11] and steps = 3 then 7, 11, 7 is the sequence in which weights should be kept in order to move scale alternatively. Let another weight array is [2, 3, 5, 6] and steps = 10 then, 3, 2, 3, 5, 6, 5, 3, 2, 3 is the sequence in which weights should be kept in order to move scale alternatively.
This problem can be solved by doing DFS among scale states.
- We traverse among various DFS states for the solution where each DFS state will correspond to actual difference value between left and right pans and current step count.
- Instead of storing weights of both pans, we just store the difference residue value and each time chosen weight value should be greater than this difference and shouldn’t be equal to previously chosen value of weight.
- If it is, then we call the DFS method recursively with new difference value and one more step.
Please see below code for better understanding,
C++
// C++ program to print weights for alternating // the weighting scale #include <bits/stdc++.h> using namespace std; // DFS method to traverse among states of weighting scales bool dfs( int residue, int curStep, int wt[], int arr[], int N, int steps) { // If we reach to more than required steps, // return true if (curStep > steps) return true ; // Try all possible weights and choose one which // returns 1 afterwards for ( int i = 0; i < N; i++) { /* Try this weight only if it is greater than current residueand not same as previous chosen weight */ if (arr[i] > residue && arr[i] != wt[curStep - 1]) { // assign this weight to array and recur for // next state wt[curStep] = arr[i]; if (dfs(arr[i] - residue, curStep + 1, wt, arr, N, steps)) return true ; } } // if any weight is not possible, return false return false ; } // method prints weights for alternating scale and if // not possible prints 'not possible' void printWeightsOnScale( int arr[], int N, int steps) { int wt[steps]; // call dfs with current residue as 0 and current // steps as 0 if (dfs(0, 0, wt, arr, N, steps)) { for ( int i = 0; i < steps; i++) cout << wt[i] << " " ; cout << endl; } else cout << "Not possible\n" ; } // Driver code to test above methods int main() { int arr[] = {2, 3, 5, 6}; int N = sizeof (arr) / sizeof ( int ); int steps = 10; printWeightsOnScale(arr, N, steps); return 0; } |
Java
// Java program to print weights for alternating // the weighting scale class GFG { // DFS method to traverse among // states of weighting scales static boolean dfs( int residue, int curStep, int [] wt, int [] arr, int N, int steps) { // If we reach to more than required steps, // return true if (curStep >= steps) return true ; // Try all possible weights and // choose one which returns 1 afterwards for ( int i = 0 ; i < N; i++) { /* * Try this weight only if it is * greater than current residue * and not same as previous chosen weight */ if (curStep - 1 < 0 || (arr[i] > residue && arr[i] != wt[curStep - 1 ])) { // assign this weight to array and // recur for next state wt[curStep] = arr[i]; if (dfs(arr[i] - residue, curStep + 1 , wt, arr, N, steps)) return true ; } } // if any weight is not possible, // return false return false ; } // method prints weights for alternating scale // and if not possible prints 'not possible' static void printWeightOnScale( int [] arr, int N, int steps) { int [] wt = new int [steps]; // call dfs with current residue as 0 // and current steps as 0 if (dfs( 0 , 0 , wt, arr, N, steps)) { for ( int i = 0 ; i < steps; i++) System.out.print(wt[i] + " " ); System.out.println(); } else System.out.println( "Not Possible" ); } // Driver Code public static void main(String[] args) { int [] arr = { 2 , 3 , 5 , 6 }; int N = arr.length; int steps = 10 ; printWeightOnScale(arr, N, steps); } } // This code is contributed by // sanjeev2552 |
Python3
# Python3 program to print weights for # alternating the weighting scale # DFS method to traverse among states # of weighting scales def dfs(residue, curStep, wt, arr, N, steps): # If we reach to more than required # steps, return true if (curStep > = steps): return True # Try all possible weights and choose # one which returns 1 afterwards for i in range (N): # Try this weight only if it is greater # than current residueand not same as # previous chosen weight if (arr[i] > residue and arr[i] ! = wt[curStep - 1 ]): # assign this weight to array and # recur for next state wt[curStep] = arr[i] if (dfs(arr[i] - residue, curStep + 1 , wt, arr, N, steps)): return True # if any weight is not possible, # return false return False # method prints weights for alternating scale # and if not possible prints 'not possible' def printWeightsOnScale(arr, N, steps): wt = [ 0 ] * (steps) # call dfs with current residue as 0 # and current steps as 0 if (dfs( 0 , 0 , wt, arr, N, steps)): for i in range (steps): print (wt[i], end = " " ) else : print ( "Not possible" ) # Driver Code if __name__ = = '__main__' : arr = [ 2 , 3 , 5 , 6 ] N = len (arr) steps = 10 printWeightsOnScale(arr, N, steps) # This code is contributed by PranchalK |
C#
// C# program to print weights for alternating // the weighting scale using System; namespace GFG { class Program { // DFS method to traverse among states of weighting scales static bool dfs( int residue, int curStep, int [] wt, int [] arr, int N, int steps) { // If we reach to more than required steps, return true if (curStep >= steps) return true ; // Try all possible weights and choose one which returns 1 afterwards for ( int i = 0; i < N; i++) { /* * Try this weight only if it is greater than current residue * and not same as previous chosen weight */ if (curStep - 1 < 0 || (arr[i] > residue && arr[i] != wt[curStep - 1])) { // assign this weight to array and recur for next state wt[curStep] = arr[i]; if (dfs(arr[i] - residue, curStep + 1, wt, arr, N, steps)) return true ; } } // if any weight is not possible, return false return false ; } // method prints weights for alternating scale and // if not possible prints 'not possible' static void printWeightOnScale( int [] arr, int N, int steps) { int [] wt = new int [steps]; // call dfs with current residue as 0 and current steps as 0 if (dfs(0, 0, wt, arr, N, steps)) { for ( int i = 0; i < steps; i++) Console.Write(wt[i] + " " ); Console.WriteLine(); } else Console.WriteLine( "Not Possible" ); } static void Main( string [] args) { int [] arr = { 2, 3, 5, 6 }; int N = arr.Length; int steps = 10; printWeightOnScale(arr, N, steps); } } } |
Javascript
function dfs(residue, curStep, wt, arr, N, steps) { // If we reach to more than required steps, // return true if (curStep > steps) { return true ; } // Try all possible weights and choose one which // returns 1 afterwards for (let i = 0; i < N; i++) { /* Try this weight only if it is greater than current residue and not same as previous chosen weight */ if (arr[i] > residue && arr[i] !== wt[curStep - 1]) { // assign this weight to array and recur for // next state wt[curStep] = arr[i]; if (dfs(arr[i] - residue, curStep + 1, wt, arr, N, steps)) { return true ; } } } // if any weight is not possible, return false return false ; } function printWeightsOnScale(arr, N, steps) { const wt = new Array(steps); // call dfs with current residue as 0 and current // steps as 0 if (dfs(0, 1, wt, arr, N, steps)) { for (let i = 1; i <= steps; i++) { process.stdout.write(`${wt[i]} `); } console.log(); } else { console.log( "Not possible" ); } } const arr = [2, 3, 5, 6]; const N = arr.length; const steps = 10; printWeightsOnScale(arr, N, steps); // This code is contributed by divyansh2212 |
Output:
2 3 2 3 5 6 5 3 2 3
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