# Memory Choke on Branch And Bound Knapsack Implementation

I wrote this implementation of the branch and bound knapsack algorithm based on the pseudo-Java code from here. Unfortunately, it's memory choking on large instances of the problem, like this. Why is this? How can I make this implementation more memory efficient?

The input on the file on the link is formatted this way:

`````` numberOfItems maxWeight
profitOfItem1 weightOfItem1
.
.
.
profitOfItemN weightOfItemN

import java.util.Comparator;
import java.util.PriorityQueue;

class ItemComparator implements Comparator {

public int compare (Object item1, Object item2){

Item i1 = (Item)item1;
Item i2 = (Item)item2;

if ((i1.valueWeightQuotient)<(i2.valueWeightQuotient))
return 1;
if ((i2.valueWeightQuotient)<(i1.valueWeightQuotient))
return -1;
else { // costWeightQuotients are equal

if ((i1.weight)<(i2.weight)){

return 1;

}

if ((i2.weight)<(i1.weight)){

return -1;

}

}

return 0;

}
``````

}

``````class Node
{
int level;
int profit;
int weight;
double bound;

}

class NodeComparator implements Comparator {

public int compare(Object o1, Object o2){

Node n1 = (Node)o1;
Node n2 = (Node)o2;

if ((n1.bound)<(n2.bound))
return 1;
if ((n2.bound)<(n1.bound))
return -1;

return 0;
}

}

class Solution {

long weight;
long value;

}

public class BranchAndBound {

static Solution branchAndBound2(LinkedList<Item> items, double W) {

double timeStart = System.currentTimeMillis();

int n = items.size();

int [] p = new int [n];
int [] w = new int [n];

for (int i=0; i<n;i++){

p [i]= (int)items.get(i).value;
w [i]= (int)items.get(i).weight;

}

Node u;
Node v = new Node(); // tree root

int maxProfit=0;
int usedWeight=0;

NodeComparator nc = new NodeComparator();
PriorityQueue<Node> PQ = new PriorityQueue<Node>(n,nc);

v.level=-1;
v.profit=0;
v.weight=0; // v initialized to -1, dummy root
v.bound = bound(v,W, n, w, p);

while(!PQ.isEmpty()){

v=PQ.poll();
u = new Node();
if(v.bound>maxProfit){ // check if node is still promising

u.level = v.level+1; // set u to the child that includes the next item

u.weight = v.weight + w[u.level];
u.profit = v.profit + p[u.level];

if (u.weight <=W && u.profit > maxProfit){
maxProfit = u.profit;
usedWeight = u.weight;
}

u.bound = bound(u, W, n, w, p);

if(u.bound > maxProfit){
}

u = new Node();
u.level = v.level+1;
u.weight = v.weight; // set u to the child that does not include the next item
u.profit = v.profit;
u.bound = bound(u, W, n, w, p);

if(u.bound>maxProfit)

}

}
Solution solution = new Solution();
solution.value = maxProfit;
solution.weight = usedWeight;

double timeStop = System.currentTimeMillis();
double elapsedTime = timeStop - timeStart;
System.out.println("* Time spent in branch and bound (milliseconds):" + elapsedTime);

return solution;

}

static double bound(Node u, double W, int n, int [] w, int [] p){

int j=0; int k=0;
int totWeight=0;
double result=0;

if(u.weight>=W)
return 0;

else {

result = u.profit;
totWeight = u.weight; // por esto no hace

if(u.level < w.length)
{
j= u.level +1;
}

int weightSum;

while ((j < n) && ((weightSum=totWeight + w[j])<=W)){
totWeight = weightSum; // grab as many items as possible
result = result + p[j];
j++;
}
k=j; // use k for consistency with formula in text

if (k<n){
result = result + ((W - totWeight) * p[k] / w[k]);// grab fraction of excluded kth item
}
return result;
}

}

}
``````
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try to ask a more concise question. It's really difficult to undertand what can be bad in these 100+ LOC. –  Roman Sep 19 '11 at 18:08