Knapsack dynamic programming works on the principle of using a table to store the answers to solved subproblems. If you come into a subproblem again, all you have to do is look up the answer in the table. As a result, dynamic programming-designed algorithms are incredibly efficient.
By the end of this article, you will be able to understand how to solve the problem of 0-1 and fractional knapsack using dynamic programming with the necessary details and practical implementations.
Problem Statement for the Knapsack Problem
The Knapsack Problem is used to explain both the problem and the solution. It derives its name from the limited number of things that may be carried in a fixed-size knapsack. We are given a set of items with varying weights and values; the goal is to store as much value as possible into the knapsack while staying within the weight limit.
Now, let us look at the Dynamic Programming Based Solution to Solve the problem of 0-1 Knapsack.
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Dynamic Programming Based Solution to Solve the 0-1 Knapsack Problem
We must follow the below given steps:
- First, we will be provided weights and values of n items, in this case, six items.
- We will then put these items in a knapsack of capacity W or, in our case, 10kg to get the maximum total value in the knapsack.
- After putting the items, we have to fill this knapsack, but we can't break the item. So, we must either pick the entire item or skip it.
- Sometimes this may even lead to a knapsack with some spare space left with it.
So, this is how we solve the 0-1 knapsack using dynamic programming. Now let's implement this solution through a simple C++ code.
Implement the Dynamic Programming Based Solution to Solve the 0-1 Knapsack Problem
We are given the weight of a collection of items {6, 3, 3, 2, 2, 2} and a knapsack of capacity W=10. We have to fill this knapsack, considering it as 0-1 knapsack.
Code:
// A c++ program to solve 0-1 Knapsack problem using dynamic programming
#include <bits/stdc++.h>
using namespace std;
// A function to returns a maximum of two numbers
int max(int X, int Y)
{
if(X>Y)
return X;
else
return Y;
}
// A function to returns the maximum value
// that can be stored in a knapsack of W=10
int knapSack(int W, int wt[], int val[], int n)
{
int i, w;
vector<vector<int>> K(n + 1, vector<int>(W + 1));
// Build table K[][] in bottom up manner
for(i = 0; i <= n; i++)
{
for(w = 0; w <= W; w++)
{
if (i == 0 || w == 0)
K[i][w] = 0;
else if (wt[i - 1] <= w)
K[i][w] = max(val[i - 1] +K[i - 1][w - wt[i - 1]], K[i - 1][w]);
else
K[i][w] = K[i - 1][w];
}
}
return K[n][W];
}
int main()
{
int val[] = { 300, 150, 120, 100, 90, 80 };
int wt[] = { 6, 3, 3, 2, 2, 2 };
int W = 10;
int n = sizeof(val) / sizeof(val[0]);
cout << knapSack(W, wt, val, n);
return 0;
}
This method has a time complexity of O(N*W).
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Dynamic Programming Based Solution to Solve the Fractional Knapsack Problem
We have to follow the below given steps to solve the fractional Knapsack Problem:
- Similar to the 0-1 Knapsack Problem, we will be given weights and values of n items, in this case, six items.
- We will put these items in a knapsack of capacity W or, in our case, 10kg to get the total maximum value in the knapsack.
- Then, we have to fill this knapsack, but unlike 0-1 knapsack, we can even break an item to get the maximum value of the knapsack.
- In this case, to fill the knapsack, we will break the 3kg item into 2kg and 1kg items.
Now let's implement this solution through a simple C++ code.
Implement the Dynamic Programming Based Solution to Solve the Fractional Knapsack Problem
We will be provided with the weight of a collection of items {6, 3, 3, 2, 2, 2}. We are given a knapsack of capacity W=10 and we have to fill this knapsack, considering it as a fractional knapsack.
Code:
//A C++ program to illustrate a
//fractional Knapsack Problem solution using dynamic programming
#include <bits/stdc++.h>
using namespace std;
// A structure to define Item
struct Item {
int val, wt;
// Constructor
Item(int val, int wt)
{
this->val=val;
this->wt=wt;
}
};
//A function to sort Item according to Val/wt ratio
bool cmpsort(struct Item X, struct Item Y)
{
double R1 = (double)X.val / (double)X.wt;
double R2 = (double)Y.val / (double)Y.wt;
return R1 > R2;
}
// Main greedy function to solve the problem
double fractionalKnapsack(int W, struct Item arr[], int N)
{
// sorting Item on basis of ratio
sort(arr, arr + N, cmpsort);
// Uncomment to see new order of Items with their
// ratio
/*
for (int i = 0; i < N; i++)
{
cout << arr[i].val << " " << arr[i].wt << " :
"
<< ((double)arr[i].val / arr[i].wt) <<
endl;
}
*/
int curWt = 0; // Current weight in knapsack
double finalval = 0.0;
// Iterating through all Items
for (int i = 0; i < N; i++) {
// If adding Item won't overflow, add it completely
if (curWt + arr[i].wt <= W) {
curWt += arr[i].wt;
finalval += arr[i].val;
}
// If we can't add the current Item, add fractional of it
else {
int rem = W - curWt;
finalval += arr[i].val
* ((double)rem
/ (double)arr[i].wt);
break;
}
}
// Returning final value
return finalval;
}
int main()
{
int W = 10; // Weight of knapsack
Item arr[] = { { 300, 6 }, { 150, 3 }, { 120, 3 }, { 100, 2 }, { 90, 2 }, { 80, 2 } };
int n = sizeof(arr) / sizeof(arr[0]);
cout << "Maximum value we can obtain = "
<< fractionalKnapsack(W, arr, n);
return 0;
}
With this, we have come to an end of this article. We will now look at what could be your next steps to conquer dynamic programming problems.
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Next Steps
Your next stop in mastering dynamic programming problems should be the Longest Common Substring Problem. The Longest Common Substring Problem involves determining the longest string which is a substring of two or more strings. There are several solutions to the problem.
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