# 0-1 Knapsack algorithm

Is the following 0-1 Knapsack problem solvable:

• 'float' positive values and
• 'float' weights (can be positive or negative)
• 'float' capacity of the knapsack > 0

I have on average < 10 items, so I'm thinking of using a brute force implementation. However, I was wondering if there is a better way of doing it.

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Did you really mean solvable, or solvable efficiently? – BlueRaja - Danny Pflughoeft Nov 14 '11 at 17:12
If you don't need an exact answer, you might look into simulated annealing.. – Mike Christensen Nov 14 '11 at 17:13
2^10 is 1024. Definitely brute force it, even if there is a "better" way it will almost certainly be far slower. – Doug McClean Nov 14 '11 at 17:18
So, what's the difference between the "positive values" and the "weights"? What is it you're trying to hit? – McKay Nov 14 '11 at 17:23
@McKay: Each item has a value and a weight. We want to maximise the sum of the values such that the sum of the weights is <= knapsack capacity. – j_random_hacker Nov 14 '11 at 17:45

This is a relatively simple binary program.

I'd suggest brute force with pruning. If at any time you exceed the allowable weight, you don't need to try combinations of additional items, you can discard the whole tree.

Oh wait, you have negative weights? Include all negative weights always, then proceed as above for the positive weights. Or do the negative weight items also have negative value?

Include all negative weight items with positive value. Exclude all items with positive weight and negative value.

For negative weight items with negative value, subtract their weight (increasing the knapsack capavity) and use a pseudo-item which represents not taking that item. The pseudo-item will have positive weight and value. Proceed by brute force with pruning.

``````class Knapsack
{
double bestValue;
bool[] bestItems;
double[] itemValues;
double[] itemWeights;
double weightLimit;

void SolveRecursive( bool[] chosen, int depth, double currentWeight, double currentValue, double remainingValue )
{
if (currentWeight > weightLimit) return;
if (currentValue + remainingValue < bestValue) return;
if (depth == chosen.Length) {
bestValue = currentValue;
System.Array.Copy(chosen, bestItems, chosen.Length);
return;
}
remainingValue -= itemValues[depth];
chosen[depth] = false;
SolveRecursive(chosen, depth+1, currentWeight, currentValue, remainingValue);
chosen[depth] = true;
currentWeight += itemWeights[depth];
currentValue += itemValues[depth];
SolveRecursive(chosen, depth+1, currentWeight, currentValue, remainingValue);
}

public bool[] Solve()
{
var chosen = new bool[itemWeights.Length];
bestItems = new bool[itemWeights.Length];
bestValue = 0.0;
double totalValue = 0.0;
foreach (var v in itemValues) totalValue += v;
SolveRecursive(chosen, 0, 0.0, 0.0, totalValue);
return bestItems;
}
}
``````
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I think pruning is possibly bad idea? It adds overhead (in checking), and doesn't save much time, but it does depend on how likely overfill is, especially if you also have to put items into bins based on positive negative weight. – McKay Nov 14 '11 at 17:46
Thank you so much for this! How would the algorithm change if an additional constraint is to be fulfilled: limit the selection to up to 5 items out of the total number of items ? Thanks again. – alhazen Nov 14 '11 at 19:25
@j_random_hacker: Check again, there is no subtraction. The prior value is restored from the call stack (the caller has an unmodified copy). – Ben Voigt Nov 14 '11 at 19:48
@alhazen, that's just a second kind of "weight". Add a `currentCount` parameter and a `countLimit` field. – Ben Voigt Nov 14 '11 at 19:51
@BenVoigt So I updated my code, and now it's actually solving this version of knapsack. And I'm getting "better" values than you, i.e. I'm fitting things of higher values in my sack than you are, when we're running on the same set. Maybe I'm doing something wrong? Maybe you are? Care to look mine over. It should be rather simple. Yours will take further deconstructing to ensure that it's covering all paths. – McKay Nov 14 '11 at 21:04

Yeah, brute force it. This is an NP-Complete problem, but that shouldn't matter because you will have less than 10 items. Brute forcing won't be problematic.

``````        var size = 10;
var capacity = 0;
var permutations = 1024;
var repeat = 10000;

// Generate items
float[] items = new float[size];
float[] weights = new float[size];
Random rand = new Random();
for (int i = 0; i < size; i++)
{
items[i] = (float)rand.NextDouble();
weights[i] = (float)rand.NextDouble();
if (rand.Next(2) == 1)
{
weights[i] *= -1;
}
}

// solution
int bestPosition= -1;

Stopwatch sw = new Stopwatch();
sw.Start();

// for perf testing
//for (int r = 0; r < repeat; r++)
{
var bestValue = 0d;

// solve
for (int i = 0; i < permutations; i++)
{
var total = 0d;
var weight = 0d;
for (int j = 0; j < size; j++)
{
if (((i >> j) & 1) == 1)
{
total += items[j];
weight += weights[j];
}
}

if (weight <= capacity && total > bestValue)
{
bestPosition = i;
bestValue = total;
}
}
}
sw.Stop();
sw.Elapsed.ToString();
``````
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That's NOT pruning. – Ben Voigt Nov 14 '11 at 18:34
Thanks for that. But I think your code returns the first valid combination that satisfies the constraints, rather than the one whose total value is as large as possible (and constraints satisfied of course). – alhazen Nov 14 '11 at 18:37
Would you be so kind as to perf-test my recursive solution, since you already have the test framework? – Ben Voigt Nov 14 '11 at 18:47
This code doesn't solve the knapsack problem I'm afraid: -1. Also it's both simpler and much faster to use bitwise operations than generating a binary digit string. In C you could just replace `if (splitOut[j] == '1')` with `if ((i >> j) & 1)`, I'm sure the syntax is similar in C#. – j_random_hacker Nov 14 '11 at 19:36
@j_random_hacker new code uses the new binary masking. – McKay Nov 14 '11 at 21:18

If you can only have positive values then every item with a negative weight must go in.

Then I guess you could calculate Value/Weight Ratio, and brute force the remaining combinations based on that order, once you get one that fits you can skip the rest.

The problem may be that the grading and sorting is actually more expensive than just doing all the calculations.

There will obviously be a different breakeven point based on the size and distribution of the set.

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``````public class KnapSackSolver {

public static void main(String[] args) {
int N = Integer.parseInt(args[0]); // number of items
int W = Integer.parseInt(args[1]); // maximum weight of knapsack

int[] profit = new int[N + 1];
int[] weight = new int[N + 1];

// generate random instance, items 1..N
for (int n = 1; n <= N; n++) {
profit[n] = (int) (Math.random() * 1000);
weight[n] = (int) (Math.random() * W);
}

// opt[n][w] = max profit of packing items 1..n with weight limit w
// sol[n][w] = does opt solution to pack items 1..n with weight limit w
// include item n?
int[][] opt = new int[N + 1][W + 1];
boolean[][] sol = new boolean[N + 1][W + 1];

for (int n = 1; n <= N; n++) {
for (int w = 1; w <= W; w++) {

// don't take item n
int option1 = opt[n - 1][w];

// take item n
int option2 = Integer.MIN_VALUE;
if (weight[n] <= w)
option2 = profit[n] + opt[n - 1][w - weight[n]];

// select better of two options
opt[n][w] = Math.max(option1, option2);
sol[n][w] = (option2 > option1);
}
}

// determine which items to take
boolean[] take = new boolean[N + 1];
for (int n = N, w = W; n > 0; n--) {
if (sol[n][w]) {
take[n] = true;
w = w - weight[n];
} else {
take[n] = false;
}
}

// print results
System.out.println("item" + "\t" + "profit" + "\t" + "weight" + "\t"
+ "take");
for (int n = 1; n <= N; n++) {
System.out.println(n + "\t" + profit[n] + "\t" + weight[n] + "\t"
+ take[n]);
}
}

}
``````
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Time Complexity is O(NW) and space complexity is also O(NW) – Arvind Telharkar Jan 23 at 19:45