# Finding the shortest path nodes with breadth first search

I am running breadth first search on the above graph to find the shortest path from `Node 0` to `Node 6`.

My code

``````public List<Integer> shortestPathBFS(int startNode, int nodeToBeFound){
boolean shortestPathFound = false;
Set<Integer> visitedNodes = new HashSet<Integer>();
List<Integer> shortestPath = new ArrayList<Integer>();

while (!queue.isEmpty()) {
int nextNode = queue.peek();
shortestPathFound = (nextNode == nodeToBeFound) ? true : false;
if(shortestPathFound)break;
System.out.println(queue);
Integer unvisitedNode = this.getUnvisitedNode(nextNode, visitedNodes);

if (unvisitedNode != null) {
shortestPathFound = (unvisitedNode == nodeToBeFound) ? true : false;
if(shortestPathFound)break;
} else {
queue.poll();
}
}
return shortestPath;
}
``````

I need to track down the nodes through which the BFS algo. traversed to reach node 6, like `[0,3,2,5,6]`. For that I have created a List named `shortestPath` & trying to store the previous nodes of the visited nodes, to get the list of nodes. Referred

But it doesn't seem to work. The shortest path is `[0,3,2,5,6]`

In the list what I get is `Shortest path: [0, 0, 0, 0, 1, 3, 3, 2, 5]`

It's partially correct but gives the extra `1` .

If I again start from the first element `0` of the `shortestPath` list & start traversing & backtracking. Like `1` doesn't has an edge to `3`, so I backtrack & move from `0` to `3` to `5`, I will get the answer but not sure if that's the correct way.

What is the ideal way to getting the nodes for the shortest path?

• See the second answer here: stackoverflow.com/questions/8379785/… Jan 22, 2017 at 10:45
• The second answer explains how to run a BFS on a weighted graph Jan 22, 2017 at 10:48
• It says: All edges have same weight or no weight. You can assume that all your edges have the same weight Jan 22, 2017 at 10:50
• yes that's assumed that all the edges have same weight. Now how will you get the nodes? A node x has 3 nodes further with same weight. Which one will you traverse? How do you know which is the best one. Besides my question is completely different from what the answer is trying to say. Please read my question again. I am not looking for the shortest path, that BFS will by default look for, I am looking to print the nodes for the shortest path. Did you get it? Jan 22, 2017 at 10:56
• By saving the parent node whenever you visit a child node. Suppose you start at 0. BFS may visit first 8, 3 and 1. You save the their parent as 0. Then you visit for example 4, 2 and 7. Their parents will be 8, 3 and 1 and so on. When you reach the target you iterate the parents back to the source. Jan 22, 2017 at 11:26

Storing all the visited nodes in a single list is not helpful for finding the shortest path because in the end you have no way of knowing which nodes were the ones that led to the target node, and which ones were dead ends.

What you need to do is for every node to store the previous node in the path from the starting node.

So, create a map `Map<Integer, Integer> parentNodes`, and instead of this:

``````shortestPath.add(nextNode);
``````

do this:

``````parentNodes.put(unvisitedNode, nextNode);
``````

After you reach the target node, you can traverse that map to find the path back to the starting node:

``````if(shortestPathFound) {
List<Integer> shortestPath = new ArrayList<>();
Integer node = nodeToBeFound;
while(node != null) {
node = parentNodes.get(node);
}
Collections.reverse(shortestPath);
}
``````
• This may not work if the graph is not a tree (has loops) Jan 15, 2018 at 6:04
• @c0der The graph may contain loops, but the shortest path will not. We ensure that no node is visited twice by storing every processed node in `visitedNodes` and only putting unvisited nodes to the queue. Jan 15, 2018 at 23:59

As you can see in acheron55 answer:

"It has the extremely useful property that if all of the edges in a graph are unweighted (or the same weight) then the first time a node is visited is the shortest path to that node from the source node"

So all you have to do, is to keep track of the path through which the target has been reached. A simple way to do it, is to push into the `Queue` the whole path used to reach a node, rather than the node itself.
The benefit of doing so is that when the target has been reached the queue holds the path used to reach it.
Here is a simple implementation :

``````/**
* unlike common bfs implementation queue does not hold a nodes, but rather collections
* of nodes. each collection represents the path through which a certain node has
* been reached, the node being the last element in that collection
*/
private Queue<List<Node>> queue;

//a collection of visited nodes
private Set<Node> visited;

public boolean bfs(Node node) {

if(node == null){ return false; }

queue = new LinkedList<>(); //initialize queue
visited = new HashSet<>();  //initialize visited log

//a collection to hold the path through which a node has been reached
//the node it self is the last element in that collection
List<Node> pathToNode = new ArrayList<>();

while (! queue.isEmpty()) {

pathToNode = queue.poll();
//get node (last element) from queue
node = pathToNode.get(pathToNode.size()-1);

if(isSolved(node)) {
//print path
System.out.println(pathToNode);
return true;
}

//loop over neighbors
for(Node nextNode : getNeighbors(node)){

if(! isVisited(nextNode)) {
//create a new collection representing the path to nextNode
List<Node> pathToNextNode = new ArrayList<>(pathToNode);
}
}
}

return false;
}

private List<Node> getNeighbors(Node node) {/* TODO implement*/ return null;}

private boolean isSolved(Node node) {/* TODO implement*/ return false;}

private boolean isVisited(Node node) {
if(visited.contains(node)) { return true;}
return false;
}
``````

This is also applicable to cyclic graphs, where a node can have more than one parent.

• no, the only difference is what neighbour nodes to consider as good (weighted is just more general case). For current node `N` and current distance from root `R` being `d(R, N)`, a node `M` is on some shortest path from `R` to `N` iff `d(R, N) = d(R, M) + d(M, N)`. Jan 22, 2017 at 19:52