# A* Algorithm Bug

I tried creating the A* algorithm in java and I have this strange bug. I know the A* doesn't always find the best path, but here it seems to go against reason and choose a worse path, and I can't find the bug in the code causing this. It seems to find the optimal solution on other maps I created. Here is a picture of the bug, and a printout of the nodes

Here is (part of) the code that I used.

``````import java.util.Iterator;
import java.util.PriorityQueue;
import java.util.Queue;

// Matt Bellis 7/31/2011
// A* Algorithm

public class AStar {
private PriorityQueue<Node> openQ;
private Queue<Node> closedQ;
private int [][] map;
private int startX, startY, endX, endY;
private Node endNode;

public AStar(int[][]map, int startX, int startY, int endX, int endY) {
openQ = new PriorityQueue<Node>();
this.map = map;
this.startX = startX;
this.startY = startY;
this.endX = endX;
this.endY = endY;
endNode = new Node(endX, endY, 0, null); // for calculating the manhattan distances later
}

private int manhattanDist(Node curr, Node target) {
int cX, tX, cY, tY;
cX = curr.getX();
tX = target.getX();
cY = curr.getY();
tY = target.getY();
return 10*(Math.abs(cX - tX)+Math.abs(cY - tY));
}
private boolean onClosedList(Node node) {
if(closedQ.isEmpty() == true)
return false;
Iterator<Node> it = closedQ.iterator();
while(it.hasNext()) {
Node nodeCheck = it.next();
if(nodeCheck.getX() == node.getX() && nodeCheck.getY() == node.getY())
return true;
}
return false;
}
private boolean checkAndReplaceOpen(Node node, Node curr, boolean diag) { // true means replaced
Iterator<Node> it = openQ.iterator();
while(it.hasNext()) {
Node nodeCheck = it.next();
if(nodeCheck.getX() == node.getX() && nodeCheck.getY() == node.getY()) {
// they are the same node, check to see the g cost
if(node.getG() < nodeCheck.getG()) { //entered node is better path
if(diag == true)
node.setG(curr.getG()+14);
else
node.setG(curr.getG()+10);
node.setF(node.getG() + node.getH());
node.setParent(curr);
return true;
}
return false;
}
}
return false;
}
int x = node.getX();
int y = node.getY();
//System.out.println("Node: "+node);
//System.out.println("Right: "+map[y][x+1]);
if((x+1)< map[y].length && map[y][x+1] !=1) {
Node newNode = new Node(x+1, y, map[y][x+1], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+10);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, false) == false)
}
}
//System.out.println("Left: Y:"+y+" X:"+(x-1));
if((x-1) >= 0 && map[y][x-1] !=1 ) {
Node newNode = new Node(x-1, y, map[y][x-1], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+10);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, false) == false)
}
}
//System.out.println("Up: "+map[y+1][x]);
if((y+1) < map.length && map[y+1][x] !=1) {
Node newNode = new Node(x, y+1, map[y+1][x], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+10);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, false) == false)
}
}
//System.out.println("Down: "+map[y-1][x]);
if((y-1) > 0 && map[y-1][x] !=1) {
Node newNode = new Node(x, y-1, map[y-1][x], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+10);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, false) == false)
}
}

// top right
if((y+1) < map.length && (x+1) < map[y].length && map[y+1][x+1] !=1) {
Node newNode = new Node(x+1, y+1, map[y+1][x+1], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+14);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, true) == false)
}
}
// top left
if((y+1) < map.length && (x-1) >= 0 && map[y+1][x-1] !=1) {
Node newNode = new Node(x-1, y+1, map[y+1][x-1], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+14);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, true) == false)
}
}
// bottom left
if((y-1) > 0 && (x-1) >= 0 && map[y-1][x-1] !=1) {
Node newNode = new Node(x-1, y-1, map[y-1][x-1], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+14);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, true) == false)
}
}
// bottom right
if((y-1) >= 0 && (x+1) < map[y].length && map[y-1][x+1] !=1) {
Node newNode = new Node(x+1, y-1, map[y-1][x+1], node);
if(onClosedList(newNode) == false) {
newNode.setG(node.getG()+14);
newNode.setH(manhattanDist(newNode, endNode));
newNode.setF(newNode.getG()+newNode.getH());
if(checkAndReplaceOpen(newNode, node, true) == false)
}
}
}
private Node solve() {
Node startNode = new Node(startX, startY, 0, null);
startNode.setH(manhattanDist(startNode, endNode));
startNode.setF(startNode.getG() + startNode.getH());
while(openQ.isEmpty() == false) { // keep going until the queue is empty, or you find the end node
Node currNode = openQ.remove();
if(currNode.getX() == endX && currNode.getY() == endY) {
return currNode;
}
}
System.out.println("No solution found!");
}
}
while(pathr.isEmpty() == false)
return path;
}
Iterator<Node> it = list.iterator();
while(it.hasNext())
System.out.println(it.next());
}
}
``````
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I haven't read the code, but are sure it's not giving you an optimal solution? If going one diagonal is the same "distance" as a vertical or horizontal move than the solution you showed is also optimal. (I saw the manhattan distance, which is quite odd, but I don't know if it is your true distance measure.) –  toto2 Aug 3 '11 at 22:54
I realized my comment is the same as @Hakon's answer. –  toto2 Aug 3 '11 at 23:12
I should mention that the cost to move diagonal is 14, the rest cost 10. –  Matt Bellis Aug 3 '11 at 23:22

A* actually gives best path always if one requirement is met:

`h(x,s) <= G(x,s) foreach x` where:

`x` - some point

`h()` - heurestic function

`s` - stop point

`G()` - "oracle" function that gives you shortest distance between points (which is of course not known)

the trick is, that as always as heurestic function gives distances that are shorter or equal to magical function G() path will be the shortest. The one problem I see with your code, is that if you are fe. 1 diagonal jump from endpoint, your heurestic function will return 20 (mahnattan distance), while your actual cost G() is 14 (this is the cost of 1 diagonal jump) in your code. I don't know if this is the only bug, need to study the code further, but try fixing it by:

• Changing 14 to 20, so that it matches heurestic
• Use different metric, fe. euclidean.
-

For starters, as far as I know, A* always finds the best way...

I haven't looked over all of your code, but your manhatten function is concerning me. A* uses an "admissible heuristic", meaning the heuristic function may not overestimate the cost to travel to the target node. If it does, you are actually having an A algorithm, which may not find the best path.

To exclude that, let you manhatten function return 0, which is an admissible heuristic, because it doesn't overestimate. If your problem still occures with that, the problem is somewhere else.

If I see that correctly, your cost for a diagonal movement is 10, where the cost for any other movement is 14. Giving that, your manhattan function returns 10 for horizontal or vertical movement, which is fine (10 < 14) but 20 for diagonal movement, which is not fine (20 > 10). That might be the error.

-
It's not always optimal. You can fe. cripple your heurestic function so that it will give higher values for changing direction of movement, and your path will not be the shortest, but A* will make it more straight. It's great feature to implement in game, fe. for computing shortest path for vehicles, where you don't want them to take shortest path and drive left/right all the time :-) –  Marcin Deptuła Aug 3 '11 at 22:33
Yeah, of course, A* can be altered a lot by its heuristic function. But if I raise the cost for changing the direction, do I still have an admissible heuristic? Or do I rather have a normal heuristic, which just gives me a more smooth path? –  Shelling Aug 3 '11 at 22:36
Well, no, you have to use not admissible heuristic for this effect, that doesn't mean thought that you can't force A* not to give the shortest path, which was my only point. With admissible heuristic - you're right, A* finds the shortest path. Also, I think (and from your post I think that you're thinking the same), that the autor has problem, because his heuristic is not admissible, which resulted into proper, but not shortest path. –  Marcin Deptuła Aug 3 '11 at 22:40
I thought so, but giving A* a not admissible heuristic will not be an A* algorithm anymore. A* really is defined as a search algorithm using an admissible heuristic. That's actually the only thing I wanted to point out, on everything else I agree with you. BTW: Something I forgot to mention: If the heuristic function returns 0 for all cases, the A* algorithm will be transformed into a simple breadth-first algorithm, meaning it will check every node until it finds the target. –  Shelling Aug 3 '11 at 22:45
I don't think that giving not admissible heuristic makes A* not an A* anymore. Reference on wiki (en.wikipedia.org/wiki/A*_search_algorithm) - Properties section. Or the illustration above. Article there indicates, that you can use not admissible heuristic to achieve sub-optimal route, while still being A* algorithm. Also, you can choose h(x,s) = 0 for all cases, which will degenerate A* to Dijskta, but only in complexity, it's still A* algorithm afterall. If A* with non admissible heuristic is not A* anymore - how you would call such algorithm? (sorry for broken link - problems with *) –  Marcin Deptuła Aug 3 '11 at 22:50