I'm working on an assignment where I must solve the classic knapsack 0-1 problem 4 different ways (greedy, brute force, dynamic prog, branch n bound). I am working on my branch n bound and what I would like some help on is spatially optimizing my code. My branch n bound is a best first implementation using a priority queue. Our given test cases are "easy20," "easy50," "easy200," "hard50," and "hard200." The number designates how many knapsack items and easy/hard designates the difficulty. My algorithm runs almost instantly for all test cases under 200. When I try to run easy200 or hard200, I run out of heap space. And that is with flags to increase my heap space. So here is my code below, any hints on how to optimize my space usage are appreciated.

```
public class KnapsackBNB {
// manifest in descending order by value:weight ratio
private List<KnapsackItem> sortedManifest;
private KnapsackItem[] manifest;
private boolean[] solution; // true entries are items giving best value
private int actualCapacity; // size of knapsack
private int availableCapacity; // current capacity on hand
private int maxEarnings; // max profit given by greedy solution
public KnapsackBNB(int numItems, int capacity, KnapsackItem[] manifest) {
this.manifest = manifest;
actualCapacity = capacity;
availableCapacity = actualCapacity;
maxEarnings = 0;
solution = new boolean[numItems];
sortedManifest = new ArrayList<KnapsackItem>();
}
public void solveBNB(KnapsackItem[] manifest) {
Node current, left, right;
KnapsackItem cur;
PriorityQueue<Node> queue = new PriorityQueue<Node>(1, new ComparatorBNB());
// insertion sort to order items based on descending value:weight ratios
insertSort(manifest, sortedManifest);
cur = sortedManifest.get(0);
// the upperBound is given by the remaining available capacity
// times the next highest value:weight ratio plus the cumulative
// value up to that point in the tree (cumValue for the root is 0)
current = new Node(0, 0, 0, 0);
current.upperBound = getUpperBound(0, actualCapacity, cur.getWeight(),
cur.getValue());
queue.add(current);
while (!queue.isEmpty()) {
current = queue.remove();
if (current.upperBound > maxEarnings) {
left = new Node(sortedManifest.get(current.level).getIndex(),
current.level + 1, current.cumValue +
sortedManifest.get(current.level).getValue(),
current.cumWeight +
sortedManifest.get(current.level).getWeight());
left.upperBound = getUpperBound(left.cumValue, actualCapacity -
left.cumWeight,
sortedManifest.get(current.level).getWeight(),
sortedManifest.get(current.level).getValue());
if (left.cumWeight <= actualCapacity &&
left.cumValue > maxEarnings) {
maxEarnings = left.cumValue;
availableCapacity = actualCapacity - left.cumWeight;
solution[left.index - 1] = true;
}
if (left.upperBound > maxEarnings)
queue.add(left);
right = new Node(0, current.level + 1, current.cumValue,
current.cumWeight);
// the last level of the tree has no more
// nodes to add to the queue
if (right.level == sortedManifest.size())
right.upperBound = right.cumValue;
else
right.upperBound = getUpperBound(current.cumValue,
actualCapacity - current.cumWeight,
sortedManifest.get(right.level).getWeight(),
sortedManifest.get(right.level).getValue());
if (right.upperBound > maxEarnings)
queue.add(right);
}
}
}
/**
* Comparator class to be used for priority queue to order knapsack
* items in descending order by their value:weight ratios.
*/
private class ComparatorBNB implements Comparator<Node> {
public int compare(Node a, Node b) {
if (a.upperBound < b.upperBound)
return 1;
else if (a.upperBound > b.upperBound)
return -1;
else
return 0;
}
}
/**
* Support function to calculate the upperBound
*/
private double getUpperBound(int cumValue, int currentCapacity, int weight,
int value) {
if (value == 0 || weight == 0 || currentCapacity < 0)
return 0;
else
return cumValue + currentCapacity *
((double) value / (double) weight);
}
/**
* Support function that takes the items from the manifest
* and sorts them in descending order by their value:weight ratios
* into an ArrayList.
*/
private void insertSort(KnapsackItem[] manifest,
List<KnapsackItem> sortedManifest) {
KnapsackItem nextItem; // next knapsack item being looked at
double curValPerWgt; // value:weight ratio of current knapsack item
double nextValPerWgt; // value:weight ratio of next knapsack item
boolean added;
// insertion sort to order items based on descending value:weight ratios
sortedManifest.add(manifest[0]);
for (int i = 1; i < manifest.length; i++) {
added = false;
nextItem = manifest[i];
nextValPerWgt = (double) nextItem.getValue()
/ (double) nextItem.getWeight();
for (int j = 0; j < sortedManifest.size(); j++) {
curValPerWgt = (double) sortedManifest.get(j).getValue()
/ (double) sortedManifest.get(j).getWeight();
if (curValPerWgt <= nextValPerWgt) {
sortedManifest.add(j, nextItem);
added = true;
break;
}
}
if (!added)
sortedManifest.add(nextItem);
}
}
// node class to be used for state space tree
private class Node {
int index; // index referencing which knapsack item
int level; // which level the node is at
int cumValue; // cumulative value of all knapsack items up to this
int cumWeight; // cumulative weight of all knapsack items up to this
double upperBound; // theoretical best value if we proceed w/ this node
public Node (int index, int level, int cumValue, int cumWeight) {
this.index = index;
this.level = level;
this.cumValue = cumValue;
this.cumWeight = cumWeight;
}
}
```

}