# Background

I am trying to code Dijkstra's algorithm in O(mlogn) time, where m is the number of edges and n is the number of nodes. I am using to find the shortest path between a given starting node and a given ending node. And I'm pretty new at this.

Here is the algorithm I have come up with:

Assume the graph is represented by an adjacency matrix and each node has a row index.

``````Initialize starting node distance to zero, and all other nodes to inifinity, in the heap.

Create a list of shortest paths, equal to the number of nodes in the graph, set to 0.

While the index of the node that corresponds to the minimum element in the heap
has no value in the list of shortest paths and heap has node distances, do:
Remove the minimum node distance from the heap, and bubble as necessary to fill the removed node.
Put the minimum node distance into the list of shortest paths at its row index.

For all nodes that were adjacent to the node with the minimum distance (that was just removed), do:
Update the distances in the heap for the current node, using the following calculation:
min((deleted node distance + adjacent edge weight), current node's distance)
Reorganize the heap to be a minimum heap.

Return value in the list of shortest paths at the location of the end node.
``````

This is O(mlogn) because you only update the distances once per edge.

"It takes linear time to initialize the heap, and then we perform m updates at a cost of O(log n) each for a total time of O(mlog n)." - http://www.cs.cmu.edu/~avrim/451f07/lectures/lect1011.pdf

# Problem

In order to update the distances from the starting vertex in the correct location in the heap, insertions to the heap must be key-value pairs - with the key being the node (row index) and the value being the distance.

There are lecture slides online that say each entry in a priority queue ADT is a key-value pair (otherwise, how could it prioritize?).

# Question

The methods for PriorityQueue have at most one parameter, so how do you insert a key associated with a value?

This must be done in a single file with a specific name (i.e. It is my understanding that I can't make a `KeyValuePair` class implementing `Comparator`).

I'd love to hear your thoughts.

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## 2 Answers

To use JDK's implementation of priority queue for your application, you can maintain a `Map<Key, Value>` in addition to `PriorityQueue<Value>`. In your case, `Key` represents a node and `Value` is an object that holds the shortest distance to a node. To update the distance to a node, you first look up its corresponding distance object in the map. Then, you remove the distance object from the priority queue. Next, you update the distance object. Finally, you insert the distance object back in the priority queue.

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@recprogrammer, I am unfamiliar with the Map interface. This might be a silly question but am I able to use a Map by importing java.util.*, and can I do it in one file with the filename Dijkstra.java (i.e. do I have to change the filename like I would have to change it for a class)? –  Jessicat Dec 3 '12 at 19:40
Yes, you can use the `Map` classes by simply importing `java.util.*` –  reprogrammer Dec 3 '12 at 19:42
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I appreciate the answers to my question and at the time I chose the Map answer because given my limited understanding of the language, it seemed easier for me to implement.

It turns out that I overlooked an important detail that made the problem much simpler than I thought it was: if I maintain an array of distances and insert the nodes into the heap (instead of the distances), to use as references to the distance array, I was able to sort the nodes based on their values.

In this implementation, I didn't need to contrive a key-value property after all. After updating the values in the distance array, I had to remove and re-add those specific nodes to the heap in order for the heap to stay current and sorted, as suggested by @reprogrammer.

Once I changed what I was putting into the heap, the algorithm was very similar to the one found on Wikipedia.

Here is the code I ended up using, in case anyone has the same problem. Note: the magic part is the creation of the PriorityQueue (which is similar to what was suggested by @stevevls):

``````import java.util.*;
import java.io.File; //Because files were used to test correctness.
import java.lang.Math;

public class Dijkstra{

//This value represents infinity.
public static final int MAX_VAL = (int) Math.pow(2,30);

/* Assumptions:
If G[i][j] == 0, there is no edge between vertex i and vertex j
If G[i][j] > 1, there is an edge between i and j and the value of G[i][j] is its weight.
No entry of G will be negative.
*/

static int dijkstra(int[][] G, int i, int j){
//Get the number of vertices in G
int n = G.length;

// The 'i' parameter indicates the starting node and the 'j' parameter
// is the ending node.

//Create a list of size n of shortest paths, initialize each entry to infinity
final int[] shortestPaths = new int[n];

for(int k = 0; k < n; k++){
shortestPaths[k] = MAX_VAL;
}

//Initialize starting node distance to zero.
shortestPaths[i] = 0;

//Make a Priority Queue (a heap)
PriorityQueue<Integer> PQ = new PriorityQueue<Integer>(n,
new Comparator<Integer>()
{
public int compare(Integer p, Integer q)
{
return shortestPaths[p] - shortestPaths[q];
}
} );

//Populate the heap with the nodes of the graph
for(int k = 0; k < n; k++){
PQ.offer(k);
}

//While the heap has elements.
while(PQ.size() > 0){

//  Remove the minimum node distance from the heap.
int minimum = PQ.poll();

//  Check if graph is disconnected, if so, return -1.
if(shortestPaths[minimum] == MAX_VAL)
{
return -1;
}
//  End node has been reached (i.e. you've found the shortest path), return the distance.
if( minimum == j){
return shortestPaths[j];
}

//  Take the current node and look through the row to see the vertices adjacent to it (neighbours)
for(int columnIt = 0; columnIt < n; columnIt ++){

//    Update the distances in the heap for the current node, using the following calculation:
//      min((deleted node distance + adjacent edge weight), current node's distance)

if(G[minimum][columnIt] > 0){

int sum = shortestPaths[minimum] + G[minimum][columnIt];

shortestPaths[columnIt]= Math.min(sum, shortestPaths[columnIt]);

if(shortestPaths[columnIt]==sum)
{
PQ.remove(columnIt);
PQ.offer(columnIt);
}
}
}
}
return -1;
}
``````

Thank you for your answers and advice.

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