Unbounded Knapsack (Repetition of items allowed) | Efficient Approach Last Updated : 23 Jul, 2025 Comments Improve Suggest changes Like Article Like Report Given an integer W, arrays val[] and wt[], where val[i] and wt[i] are the values and weights of the ith item, the task is to calculate the maximum value that can be obtained using weights not exceeding W. Note: Each weight can be included multiple times. Examples: Input: W = 4, val[] = {6, 18}, wt[] = {2, 3}Output: 18Explanation: The maximum value that can be obtained is 18, by selecting the 2nd item once. Input: W = 50, val[] = {6, 18}, wt[] = {2, 3}Output: 294 Recommended PracticeKnapsack with Duplicate ItemsTry It!Naive Approach: Refer to the previous post to solve the problem using traditional Unbounded Knapsack algorithm. Time Complexity: O(N * W)Auxiliary Space: O(W) Efficient Approach: The above approach can be optimized based on the following observations: Suppose the ith index gives us the maximum value per unit weight in the given data, which can be easily found in O(n).For any weight X, greater than or equal to wt[i], the maximum reachable value will be dp[X - wt[i]] + val[i].We can calculate the values of dp[] from 0 to wt[i] using the traditional algorithm and we can also calculate the number of instances of ith item we can fit in W weight.So the required answer will be val[i] * (W/wt[i]) + dp[W%wt[i]]. Below is the implementation of new algorithm. C++ // C++ program to implement optimized Unbounded Knapsack // algorithm #include <bits/stdc++.h> using namespace std; // Function to implement optimized // Unbounded Knapsack algorithm int unboundedKnapsackBetter(int W, vector<int> val, vector<int> wt) { // Stores most dense item int maxDenseIndex = 0; // Find the item with highest unit value // (if two items have same unit value then choose the // lighter item) for (int i = 1; i < val.size(); i++) { if (val[i] / wt[i] > val[maxDenseIndex] / wt[maxDenseIndex] || (val[i] / wt[i] == val[maxDenseIndex] / wt[maxDenseIndex] && wt[i] < wt[maxDenseIndex])) { maxDenseIndex = i; } } int dp[W + 1] = { 0 }; int counter = 0; bool breaked = false; int i = 0; for (i = 0; i <= W; i++) { for (int j = 0; j < wt.size(); j++) { if (wt[j] <= i) { dp[i] = max(dp[i], dp[i - wt[j]] + val[j]); } } if (i - wt[maxDenseIndex] >= 0 && dp[i] - dp[i - wt[maxDenseIndex]] == val[maxDenseIndex]) { counter += 1; if (counter >= wt[maxDenseIndex]) { breaked = true; break; } } else { counter = 0; } } if (!breaked) { return dp[W]; } else { int start = i - wt[maxDenseIndex] + 1; int times = (floor)((W - start) / wt[maxDenseIndex]); int index = (W - start) % wt[maxDenseIndex] + start; return (times * val[maxDenseIndex] + dp[index]); } } // Driver Code int main() { int W = 100; vector<int> val = { 10, 30, 20 }; vector<int> wt = { 5, 10, 15 }; cout << unboundedKnapsackBetter(W, val, wt); } // This code is contributed by ratiagrawal. Java import java.io.*; import java.lang.*; import java.util.*; // class to implement optimized Unbounded Knapsack algorithm class Main { // function to implement optimized Unbounded Knapsack // algorithm public static int unboundedKnapsackBetter(int W, int[] val, int[] wt) { // find the item with highest unit value int maxDenseIndex = 0; for (int i = 1; i < val.length; i++) { if (val[i] / wt[i] > val[maxDenseIndex] / wt[maxDenseIndex] || (val[i] / wt[i] == val[maxDenseIndex] / wt[maxDenseIndex] && wt[i] < wt[maxDenseIndex])) { maxDenseIndex = i; } } int[] dp = new int[W + 1]; int counter = 0; boolean breaked = false; int i = 0; // dynamic programming step for (i = 0; i <= W; i++) { for (int j = 0; j < wt.length; j++) { if (wt[j] <= i) { dp[i] = Math.max(dp[i], dp[i - wt[j]] + val[j]); } } if (i - wt[maxDenseIndex] >= 0 && dp[i] - dp[i - wt[maxDenseIndex]] == val[maxDenseIndex]) { counter += 1; if (counter >= wt[maxDenseIndex]) { breaked = true; break; } } else { counter = 0; } } if (!breaked) { return dp[W]; } else { int start = i - wt[maxDenseIndex] + 1; int times = (int)((W - start) / wt[maxDenseIndex]); int index = (W - start) % wt[maxDenseIndex] + start; return (times * val[maxDenseIndex] + dp[index]); } } // Driver Code public static void main(String[] args) { int W = 100; int[] val = { 10, 30, 20 }; int[] wt = { 5, 10, 15 }; System.out.println( unboundedKnapsackBetter(W, val, wt)); } } Python # Python Program to implement the above approach from fractions import Fraction # Function to implement optimized # Unbounded Knapsack algorithm def unboundedKnapsackBetter(W, val, wt): # Stores most dense item maxDenseIndex = 0 # Find the item with highest unit value # (if two items have same unit value then choose the lighter item) for i in range(1, len(val)): if Fraction(val[i], wt[i]) \ > Fraction(val[maxDenseIndex], wt[maxDenseIndex]) \ or (Fraction(val[i], wt[i]) == Fraction(val[maxDenseIndex], wt[maxDenseIndex]) and wt[i] < wt[maxDenseIndex]): maxDenseIndex = i dp = [0 for i in range(W + 1)] counter = 0 breaked = False for i in range(W + 1): for j in range(len(wt)): if (wt[j] <= i): dp[i] = max(dp[i], dp[i - wt[j]] + val[j]) if i - wt[maxDenseIndex] >= 0 \ and dp[i] - dp[i-wt[maxDenseIndex]] == val[maxDenseIndex]: counter += 1 if counter >= wt[maxDenseIndex]: breaked = True # print(i) break else: counter = 0 if not breaked: return dp[W] else: start = i - wt[maxDenseIndex] + 1 times = (W - start) // wt[maxDenseIndex] index = (W - start) % wt[maxDenseIndex] + start return (times * val[maxDenseIndex] + dp[index]) # Driver Code W = 100 val = [10, 30, 20] wt = [5, 10, 15] print(unboundedKnapsackBetter(W, val, wt)) C# // C# program to implement optimized Unbounded Knapsack // algorithm using System; public class GFG { // function to implement optimized Unbounded Knapsack // algorithm static int unboundedKnapsackBetter(int W, int[] val, int[] wt) { // find the item with highest unit value int maxDenseIndex = 0; for (int j = 1; j < val.Length; j++) { if (val[j] * 1.0 / wt[j] > val[maxDenseIndex] * 1.0 / wt[maxDenseIndex] || (val[j] * 1.0 / wt[j] == val[maxDenseIndex] * 1.0 / wt[maxDenseIndex] && wt[j] < wt[maxDenseIndex])) { maxDenseIndex = j; } } int[] dp = new int[W + 1]; int counter = 0; bool breaked = false; int x = 0; // dynamic programming step for (; x <= W; x++) { for (int j = 0; j < wt.Length; j++) { if (wt[j] <= x) { dp[x] = Math.Max(dp[x], dp[x - wt[j]] + val[j]); } } if (x - wt[maxDenseIndex] >= 0 && dp[x] - dp[x - wt[maxDenseIndex]] == val[maxDenseIndex]) { counter++; if (counter >= wt[maxDenseIndex]) { breaked = true; break; } } else { counter = 0; } } if (!breaked) { return dp[W]; } else { int start = x - wt[maxDenseIndex] + 1; int times = (W - start) / wt[maxDenseIndex]; int index = (W - start) % wt[maxDenseIndex] + start; return (times * val[maxDenseIndex] + dp[index]); } } static public void Main() { // Code int W = 100; int[] val = { 10, 30, 20 }; int[] wt = { 5, 10, 15 }; Console.WriteLine( unboundedKnapsackBetter(W, val, wt)); } } // This code is contributed by karthik. JavaScript // JavaScript program to implement optimized Unbounded Knapsack algorithm // Function to implement optimized // Unbounded Knapsack algorithm function unboundedKnapsackBetter(W, val, wt) { // Stores most dense item let maxDenseIndex = 0 // Find the item with highest unit value // (if two items have same unit value then choose the lighter item) for (let i = 1; i < val.length; i++) { if (val[i] / wt[i] > val[maxDenseIndex] / wt[maxDenseIndex] || (val[i] / wt[i] === val[maxDenseIndex] / wt[maxDenseIndex] && wt[i] < wt[maxDenseIndex])) { maxDenseIndex = i; } } let dp = new Array(W + 1).fill(0); let counter = 0; let breaked = false; for (var i = 0; i <= W; i++) { for (let j = 0; j < wt.length; j++) { if (wt[j] <= i) { dp[i] = Math.max(dp[i], dp[i - wt[j]] + val[j]); } } if (i - wt[maxDenseIndex] >= 0 && dp[i] - dp[i - wt[maxDenseIndex]] === val[maxDenseIndex]) { counter += 1; if (counter >= wt[maxDenseIndex]) { breaked = true; break; } } else { counter = 0; } } if (!breaked) { return dp[W]; } else { let start = i - wt[maxDenseIndex] + 1; let times = Math.floor((W - start) / wt[maxDenseIndex]); let index = (W - start) % wt[maxDenseIndex] + start; return (times * val[maxDenseIndex] + dp[index]); } } // Driver Code let W = 100; let val = [10, 30, 20]; let wt = [5, 10, 15]; console.log(unboundedKnapsackBetter(W, val, wt)); // This code is contributed by lokeshpotta20. Output300Time Complexity: O( N + min(wt[i], W) * N)Auxiliary Space: O(W) Comment More infoAdvertise with us Next Article Analysis of Algorithms Z zhangyijun396 Follow Improve Article Tags : Dynamic Programming Mathematical DSA knapsack Practice Tags : Dynamic ProgrammingMathematical Similar Reads Basics & PrerequisitesLogic Building ProblemsLogic building is about creating clear, step-by-step methods to solve problems using simple rules and principles. It’s the heart of coding, enabling programmers to think, reason, and arrive at smart solutions just like we do.Here are some tips for improving your programming logic: Understand the pro 2 min read Analysis of AlgorithmsAnalysis of Algorithms is a fundamental aspect of computer science that involves evaluating performance of algorithms and programs. 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