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My issue is more semantic than functional, As the code does seem to implement the deQueue and enQueue functions correctly.

The reheapDown and reheapUp functions are being used incorrectly, And i believe the issue lies in my heap function

package priqueue;

public class Hosheap{
  private Patient[] elements;
  private int numElements;

  public Hosheap(int maxSize)
    elements= new Patient[maxSize];

  public void ReheapDown(int root,int bottom)
    int maxChild;
    int rightChild;
    int leftChild;

    if (leftChild<=bottom)
        if(elements[leftChild].getPriority() <= elements[rightChild].getPriority())

  public void ReheapUp(int root,int bottom)
    int parent;

 public void Swap(int Pos1, int Pos2)
   Patient temp;
   temp = elements[Pos1];

 public Patient getElement(int e)
   return elements[e];

 public void setElement(Patient p, int n)

The idea is to rearrange a simple priority queue system so when a patient object is removed, ReheapUp or down correctly rearranges the queue, Which the code does not accomplish. Should i also include the priority queue code, Or is this already too lengthy?

I am using NetBeans IDE 6.0.1, If that helps.

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You can check out this simple but efficient implementation here… . – Dimitris Feb 21 '14 at 13:27

3 Answers 3

Depending on your usage requirements, the answer relating to TreeSets will most probably do what you want.

However if you really need a queue, as opposed to a sorted collection, then the inbuilt PriorityQueue may be of use.

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As stated, It is a Priority queue i am looking to use.The only issue is correct detection of removed or added variables, And reheapUp or down being used to arrange the answers in a GUI – Stumbler Mar 16 '09 at 12:47

Not exactly answering your question, but with Java you may want to look into the built-in Collection classes. You can get priority queue behavior but using a TreeSet (a type of ordered-set) and implementing a custom Comparator for Patient instances. Depending what you're trying to achieve, this may be preferable. It would look something like this:

In ...

class Patient implements Comparator { 
public int compareTo(Patient other) {
    return getPriority() > other.getPriority() ? 1 : 0;

Then in the place you want to use the queue

Set<Patient> queue = new TreeSet<Patient>();
//traverse in order of priority
for(Patient p : queue) {
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Well..I have a for loop implemented to assign Priority rating and Name for each patient object in the Priority queue itself.I'm still looking for a simple way to do this, Without using treesets(Regretabbly, Not yet covered in my course) Any other potential solutions? – Stumbler Mar 16 '09 at 12:44

Here is a simple implementation of a PriorityHeap. I coded it up pretty quick so it may have some flaws but I have implemented the pushUp() and pushDown() logic.

import java.util.Random;

public class Heap {

    private Double[] data;
    private int lastItem;

    public Heap(int initialSize) {
        // to simplify child/parent math leave the first index empty
        // and use a lastItem that gives us the size
        data = new Double[initialSize];
        lastItem = 0;

    public void insert(Double d) {
        // double size if needed
        // should have a matching shrink but this is example code
        if (lastItem + 1 >= data.length) {
            Double[] doubled = new Double[data.length * 2];
            System.arraycopy(data, 0, doubled, 0, data.length);
            data = doubled;
        data[lastItem + 1] = d;

    public void pushDown(int index) {

        if (lastItem > 1) {

            int leftChildIndex = index * 2;
            int rightChildIndex = leftChildIndex + 1;

            // assume that neither child will dominate (in priority) 
            // the item at index
            int indexToPromote = index;
            // there may not be a left child
            if (leftChildIndex <= lastItem) {

                Double leftChild = data[leftChildIndex];
                Double tmp = data[index];
                if (tmp.compareTo(leftChild) < 0) {
                    indexToPromote = leftChildIndex;

                // there might not be a right child
                if (rightChildIndex <= lastItem) {
                    Double rightChild = data[rightChildIndex];
                    tmp = data[indexToPromote];
                    if (tmp.compareTo(rightChild) < 0) {
                        indexToPromote = rightChildIndex;

            // did either child dominate the item at index
            // if so swap and push down again
            if (indexToPromote != index) {
                swap(index, indexToPromote);

    public void pushUp(int index) {
        if (index > 1) {
            // equivalent to floor((double)index/2.0d);
            // if item at index is greater than its parent
            // push the item up to until if finds a home
            int parentIndex = index >>> 1;
            Double parent = data[parentIndex];
            Double item = data[index];
            if (item.compareTo(parent) > 0) {
                swap(parentIndex, index);

    public Double removeTop() {
        // assume size is zero then examine other cases
        Double top = null;
        if (lastItem > 1) {
            // save the top item and take the bottom item and place it 
            // at the top the push the new top item down until it 
            // finds a home
            top = data[1];
            Double bottom = data[lastItem];
            data[1] = bottom;
        } else if (lastItem == 1) {
            top = data[1];
        return top;

    public int size() {
        return lastItem;

    private void swap(int index1, int index2) {
        Double temp = data[index1];
        data[index1] = data[index2];
        data[index2] = temp;

    public static void main(String[] args) {
        Heap heap = new Heap(4);
        Random r = new Random();
        for (int i = 0; i < 100000; i++) {
            Double d = Double.valueOf(r.nextDouble() * 100.0d);
        double max = Double.MAX_VALUE;
        while (heap.size() > 0) {
            Double top = heap.removeTop();
            if (top.doubleValue() > max) {
                System.out.println("bad ordering...");
            max = top.doubleValue();
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