# Priority Queue Issue

Am implementing the A* algorithm based on this tutorials:

``````create the open list of nodes, initially containing only our starting node
create the closed list of nodes, initially empty
while (we have not reached our goal) {
consider the best node in the open list (the node with the lowest f value)
if (this node is the goal) {
then we're done
}
else {
move the current node to the closed list and consider all of its neighbors
for (each neighbor) {
if (this neighbor is in the closed list and our current g value is lower) {
update the neighbor with the new, lower, g value
change the neighbor's parent to our current node
}
else if (this neighbor is in the open list and our current g value is lower) {
update the neighbor with the new, lower, g value
change the neighbor's parent to our current node
}
else this neighbor is not in either the open or closed list {
add the neighbor to the open list and set its g value
}
}
}
}
``````

Now i have two priority Queues for the open list and the closed list.

After moving a node from the open list to the closed list, i must generate its neighbours and check them one by one if they are also in the closed list and perform an operation as described above. The problem is i can only peek() only the head of the queue and compare to the generated neighbours. I can't access the rest of the nodes in the queue in order to compare them as well.

My questions is:

how can i compare the neighbours to the nodes in the closed list. Or should i use a different data structure for the closed list?

thanks

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PriorityQueue's main disadvantage is it is only guarantees "what is the first element", no guarantees on any other elements [except they are "bigger" then the first], so finding an element is an expansive operation.

You can use a TreeSet to store your states, and then finding the elements will be done in `O(logn)` time, instead the `O(n)` PriorityQueue offers. You can use the first() method to get the first [lowest] element. To modify an element, you will need first to remove the original [will probably require an additional `HashMap:State->value` to store the current value] and then to insert the new node, with its modified value
Note that you will probably have to rewrite `equals()` for your nodes.

Also note:Though both are `O(logn)`, each insert operation in a `TreeSet` is usually slower then its equivalent in `PriorityQueue`, so if your problem doesn't have to reopen states, this solution can actually be slower. However, in the general case, this is expected to be faster then the alternative, due to the shortened seek time.

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Store a value on each node that indicates if it is in the open list, closed list, or no list, then you don't have to go through the lists to see if it is or not.

And, as others have pointed out, you will probably get best results from implementing your own heap, as java's implementation apparently lacks the ability to update the key value on a node.

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thanks for your answer – Eddy Freeman Nov 23 '11 at 9:54
Highly inefficient. The iterator doesn't return the elements in order, so you are condemned to an O(n squared) comparison. – EJP Nov 23 '11 at 9:56
What will be the best option? – Eddy Freeman Nov 23 '11 at 9:57
@EJP How is the order of the lists relevant? You seem to be implying that the order is somehow important, but I think any method involving traversal of the lists would be highly inefficient. See above for another method. – Anthony Blake Nov 23 '11 at 10:08
@EJP And where does the O(n^2) come from? It's O(n).. None of what you said seems to make any sense. – Anthony Blake Nov 23 '11 at 10:18

What is the structure of your search space? If it's a path though a grid, you can use a grid to find a node "by positions". To update the F cost of the "potentially re-parented node" that is on the open-list you need operations that Java's standard PriorityQueue class does not support (namely UpdateKey, and the nodes have to know their index in the heap so UpdateKey can find them), so you'd have to roll your own heap (which is relatively easy).

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