Knapsack algorithm for two bags

I've found thread which provides pseudo-code for knapsack algorithm with 2 knapsacks. I've tried implement it in C++, but it doesn't work as suppose. Here's code:

``````#include <cstdio>
#define MAX_W1 501
#define MAX_W2 501

int maximum(int a, int b, int c) {
int max = a>b?a:b;
return c>max?c:max;
}

int knapsack[MAX_W1][MAX_W2] = {0};

int main() {
int n, s1, s2, gain, weight; // items, sack1, sack2, gain, cost

scanf("%d %d %d", &n, &s1, &s2);

// filing knapsack
for (int i = 0; i < n; i++) {
scanf("%d %d", &gain, &weight);

for (int w1 = s1; w1 >= weight; w1--) {
for (int w2 = s2; w2 >= weight; w2--) {
knapsack[w1][w2] = maximum(
knapsack[w1][w2],                 // we have best option
knapsack[w1 - weight][w2] + gain, // put into sack one
knapsack[w1][w2 - weight] + gain  // put into sack two
);
}
}
}

int result = 0;

// searching for result
for (int i = 0; i <= s1; i++) {
for (int j = 0; j <= s2; j++) {
if (knapsack[i][j] > result) {
result = knapsack[i][j];
}
}
}

printf("%d\n", result);

return 0;
}
``````

For instance for following input:

``````5 4 3
6 2
3 2
4 1
2 1
1 1
``````

I have output:

``````13
``````

Obviously it's wrong because I can take all items (1,2 into first bag and rest to second bag) and sum is 16. I would be grateful for any explanation where I get pseudo-code wrong.

I made little update since, some people have problem with understanding the input format:

1. First line contains 3 numbers as follows number of items, capacity of sack one, capacity of sack two
2. Later on there are n lines where each contains 2 numbers: gain, cost of i-th item.
3. Assume that sacks cannot be larger than 500.
-

The algorithm you're using appears incorrect, because it will only consider cases where the object happens to fit in both sacks. I made the following changes to your code and it operates correctly now:

``````#include <algorithm>

using std::max;

int max3(int a, int b, int c) {
return max(a, max(b, c));
}
``````

and

``````for (int w1 = s1; w1 >= 0; w1--) {
for (int w2 = s2; w2 >= 0; w2--) {
if (w1 >= weight && w2 >= weight) // either sack has room
{
knapsack[w1][w2] = max3(
knapsack[w1][w2],                 // we have best option
knapsack[w1 - weight][w2] + gain, // put into sack one
knapsack[w1][w2 - weight] + gain  // put into sack two
);
}
else if (w1 >= weight) // only sack one has room
{
knapsack[w1][w2] = max(
knapsack[w1][w2],                 // we have best option
knapsack[w1 - weight][w2] + gain  // put into sack one
);
}
else if (w2 >= weight) // only sack two has room
{
knapsack[w1][w2] = max(
knapsack[w1][w2],                 // we have best option
knapsack[w1][w2 - weight] + gain  // put into sack two
);
}
}
}
``````
-
Appreciate your answer as it was first correct and give explanation why algorithm was incorrect. In fact when I think about it I really miss that case. – abc Nov 28 '13 at 9:41
What would happen when none of the sack has enough capacity (though >0) to fit the weight. I think that case needs to be considered. – rohan-patel Mar 19 at 23:14

Here is modification to code to make it work:-

``````#include <cstdio>
#define MAX_W1 501
#define MAX_W2 501

int maximum(int a, int b, int c) {
int max = a>b?a:b;
return c>max?c:max;
}

int knapsack[MAX_W1][MAX_W2] = {0};

int main() {
int n, s1, s2, gain, weight; // items, sack1, sack2, gain, cost

scanf("%d %d %d", &n, &s1, &s2);

// filing knapsack
for (int i = 0; i < n; i++) {
scanf("%d %d", &gain, &weight);
// need to fill up all the table cannot stop if one sack is full because item might fit in other
for (int w1 = s1; w1 >= 0; w1--) {
for (int w2 = s2; w2 >= 0; w2--) {
int val1=0,val2=0;
if(weight<=w1)
val1 = knapsack[w1 - weight][w2] + gain;
if(weight<=w2)
val2 = knapsack[w1][w2 - weight] + gain;

knapsack[w1][w2] = maximum(
knapsack[w1][w2],                   // we have best option
val1,              // put into sack one
val2               // put into sack two
);

}
}
}

// No need to search for max value it always be Knapsack[s1][s2]
printf("%d\n", knapsack[s1][s2]);

return 0;
}
``````
-
+1 for optimization when it comes to finding answer in array. – abc Nov 28 '13 at 9:43