# Setting up an A* search

I am writing a small section of a program in which i have to write up a pathfinding algorithm. The function takes in what will be known as 'routes' that each define a start and end point in 2D space. The algorithm is required to find the shortest and most efficient (to a degree) path (from the origin) to take through these routes, minimising the total distance traveled overall.

I did a bit of research and started down a path that i thought might work. So far i have converted the routes into a directed graph which is all linked up as if it were an idealised road map. I then attempted to perform an A* search on this graph. The heuristic i used calculates the total distance of the 'routes' left to travel and the distance from start (G) value i used was just the cumulative distance traveled to get to the current point. This works for some input but others return no path at all and i cant seem to figure out why.

Is is possible that my heuristic is wrong and this is causing a miscalculation somewhere or is it more likely that the A* procedure itself is wrong? or am i just on completely the wrong track here?

I'll put the getPath function below (written in Java) just in case that helps.

``````public ArrayList<Vector2> getPath()
{
PriorityQueue<SearchNode> openList = new PriorityQueue<SearchNode>(10, new SearchNodeComparator());
ArrayList<SearchNode> closedList = new ArrayList<SearchNode>();

map.startJobs();
searchDepth = 0;

SearchNode start = searchableGraph.getNode(new Vector2(0, 0));
int goalsLeft = map.getJobCount();

start.setDistanceTraveled(0);

while (openList.size() > 0)
{
SearchNode current = openList.peek();
searchDepth++;

if (map.isJobEndPoint(current.getValue()))
{
map.completeJob(current.getValue());
goalsLeft--;

}

if (reachedGoalState(current, searchableGraph.getNodes().size()))
{
return getFinalPath(current);
}
else
{
ArrayList<SearchNode> neighbours = getNeighbours(current);

for (int i = 0; i < neighbours.size(); i++)
{
SearchNode node = neighbours.get(i);
System.out.print("Inspecting node" + node.getValue().toString());

float distanceTraveled = current.getDistanceTraveled() + getDistance(current.getValue(), node.getValue());

float heuristic = heuristic(node);

if (!openList.contains(node) && !closedList.contains(node))
{

node.setDistanceTraveled(distanceTraveled);

node.setDistanceToGoal(distanceTraveled + heuristic);

node.setParent(current);

}
else if(openList.contains(node))
{
if (node.getDistanceTraveled() <= distanceTraveled)
{

node.setDistanceToGoal(distanceTraveled + heuristic);

node.setParent(current);
}

}
}

openList.remove(current);
}
}

return new ArrayList<Vector2>();
}
``````
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