# A* pathfinder gives Sub-optimal Path

I wrote a pathfinder in java and in most cases, it works pretty well. However, i found a scenario in which it goes wrong. The heuristic i use is supposed to be consistent, and a consistent heuristic means that the algorithm should always find the closest route to the nodes it expands, as far as i know.

Here is the picture of the issue:

The start node is green, the numbers just represent the length of the path from each particular node to the goal represented in red.

My heuristic class:

``````package heuristics;
import pathcomponents.Direction;

public class Heuristics {

public static int DO(int x1, int y1, int x2, int y2) {
int dx = Math.abs(x1 - x2);
int dy = Math.abs(y1 - y2);
int D, O;
if(dx > dy) {
D = dy;
O = dx - D;
}
else {
D = dx;
O = dy - D;
}
return D*Direction.D_COST + O*Direction.O_COST;
}

}
``````

Direction.D_COST = 14, Direction.O_COST = 10

The heuristic returns the following value: diagonal distance*14 + orthogonal distance*10.

The algorithm:

``````package pathfinders;

import pathcomponents.Direction;
import pathcomponents.Node;
import pathcomponents.Path;
import heuristics.Heuristics;

public class ProxyAStar {

static private boolean contains(LinkedList<Node> list, int x, int y) {
for(Node n : list)
if(n.getX() == x && n.getY() == y) return true;
return false;
}

public static Path buildPath(Node lcnode) {
int cost = lcnode.getG();
while(lcnode != lcnode.getParent()) {
int dx = lcnode.getX() - lcnode.getParent().getX();
int dy = lcnode.getY() - lcnode.getParent().getY();
lcnode = lcnode.getParent();
}
return new Path(path, cost);
}

public static Path search(boolean[][] map, int sx, int sy, int gx, int gy) {
openList.add(new Node(sx, sy, 0, Heuristics.DO(sx, sy, gx, gy), null));
while(!openList.isEmpty()) {
Node lcnode = openList.peekFirst();
for(Node n : openList) {
if(n.getCost() < lcnode.getCost()) {
lcnode = n;
}
}
int x = lcnode.getX();
int y = lcnode.getY();
if(x == gx && y == gy) {
return buildPath(lcnode);
}
openList.remove(lcnode);
for(int i = -1; i <= 1; ++i) {
for(int j = -1; j <= 1; ++j) {
int cx = x + i;
int cy = y + j;
if((i == 0 && j == 0) || map[cx][cy] == false)continue;
if(!contains(openList,cx,cy) && !contains(closedList,cx,cy)){
openList.add(new Node(cx, cy, lcnode.getG() + Heuristics.DO(x, y, cx, cy), Heuristics.DO(cx, cy, gx, gy), lcnode));
}
}
}
}
Node lcnode = closedList.peekFirst();
for(Node n : closedList) {
if(n.getH() < lcnode.getH()) {
lcnode = n;
}
}
openList   = null;
closedList = null;
return search(map, sx, sy, lcnode.getX(), lcnode.getY());
}
}
``````

Class Node has the usual G, H and F costs and a parent reference. When the constructor receives null as the parent parameter, it becomes its own parent. Thats why the path building loop stops when the condition "lcnode == lcnode.getParent()" is met in the buildPath function, since the first node expanded is parent to itself. The path is composed of Direction pieces, which consist of an x and y coordinate, each being either -1, 0, or 1. The reason for this is that i wanted the path to lead to the goal by relative coordinates. There is no map border checking, this is intentional. I substitute this by making the border nodes unwalkable.

Another picture:

This time it works out well. The difference has to do with the order i expand nodes around the last colsed node, since i search for the lowest cost closed node like this:

``````for(Node n : openList) {
if(n.getCost() < lcnode.getCost()) {
lcnode = n;
}
}
``````

If i change the inequality to "<=", the issue in the first picture is fixed and the second one gets messed up.

On a side note, I extended the A* a little so that if there is no path, it gets the lowest H cost node from the closed list and runs another search targeting that node. This way, it gets in proximity of the goal even if there is currently no path to the goal node.

I haven't included every class, I think the others are unrelated to this problem. If something is unclear i will inculde them, didn't want to make the question too long to read though.

As far as i know, theory dictates that a consistent heuristic guarantees node expansion with optimal cost, so i couldn't figure out yet how to fix the inaccuracy. Did i make any mistakes in the code? If not, how can i fix the problem?

EDIT: I included some of the missing code to make stuff clear:

class Direction:

``````package pathcomponents;
public class Direction {
public static final int D_COST = 14;
public static final int O_COST = 10;
public static int signum(int n) {
return (n < 0) ? -1 : ((n == 0) ? 0 : 1);
}
private final int x, y;
public Direction(int x, int y) {
this.x = signum(x);
this.y = signum(y);
}
public Direction(Direction source) {
this.x = source.x;
this.y = source.y;
}
public int getX() {return x;}
public int getY() {return y;}
}
``````

class Node:

``````package pathcomponents;
public class Node {
private final int    x, y;
private       int       G;
private final int       H;
private       int       F;
private       Node parent;
public Node(int x, int y, int G, int H, Node parent) {
this.x      =                                x;
this.y      =                                y;
this.G      =                                G;
this.H      =                                H;
this.F      =                            G + H;
this.parent = (parent == null) ? this : parent;
}
public int  getX()      {return      x;}
public int  getY()      {return      y;}
public int  getG()      {return      G;}
public int  getH()      {return      H;}
public int  getCost()   {return      F;}
public Node getParent() {return parent;}
public void setParent(Node parent, int G) {
this.parent = parent;
this.G      =      G;
F           = G +  H;
}
}
``````
-
Good question, but this is way too much code. You should trace through it with a debugger (or insert debug logging to print out the decision-making process) and figure out exactly where it deviates from your expectation, then if there's still something you don't understand, post a different question. –  Jim Garrison Sep 25 '13 at 16:14

Here is the pseudo-code from wikipedia for A* with a consistent-heuristic:

``````1. while openset is not empty
2.     current := the node in openset having the lowest f_score[] value
3.     if current = goal
4.        return reconstruct_path(came_from, goal)
5.
6.     remove current from openset
8.     for each neighbor in neighbor_nodes(current)
9.        tentative_g_score := g_score[current] + dist_between(current,neighbor)
10.       if neighbor in closedset and tentative_g_score >= g_score[neighbor]
11.          continue
12.
13.       if neighbor not in openset or tentative_g_score < g_score[neighbor]
14.          came_from[neighbor] := current
15.          g_score[neighbor] := tentative_g_score
16.          f_score[neighbor] := g_score[neighbor] + heuristic_cost_estimate(neighbor, goal)
17.          if neighbor not in openset
19.
20. return failure
``````

The important line is 13 - if a neighbor of the current-node is already in the openset, you may need to update its g-score and parent-node.

This is true for both consistent and non-consistent heuristics. What a consistent heuristic gives you is not the ability to skip this check, but the ability to not have to re-queue nodes that have already been expanded (ie. that are in the closed-set).

``````LinkedList<Node> openList   = new LinkedList<Node>();
``````

`openList` should be a `PriorityQueue` ordered by `g(x) + h(x)`. You will get much better performance that way.

On a side note, I extended the A* a little so that if there is no path, it gets the lowest H cost node from the closed list and runs another search targeting that node.

There's no need to run a second search; see Tweaking AStar to find closest location to unreachable destination.

-
priority queue is a good idea, but i don't think the linked list messes up anything, since i run a search in the open list for the lowest cost member. Might be slower, but still finds the cheapest one. Also, whatever the heuristic was, the node would be a neighbour to its parent anyways, thats how expansion works. –  PEC Sep 25 '13 at 16:52
I checked the tweaking AStar link. That was my first idea, actually. However,since the goal node and the closest reachable node to the goal are at different locations, the heuristic is off by a little and you might get a sub-optimal path if you backtrack from the closest node without running another search with it being the goal node. –  PEC Sep 25 '13 at 17:00
@PEC I don't see where in your code you search for the lowest cost member. And your comment to the other answer ("58 appears in the open list before the node below it, so 58 gets picked and put in the closed list") suggests that you are either not doing that, or doing it incorrectly. 58 should not get expanded before the node below it, since it should have a higher f-value –  BlueRaja - Danny Pflughoeft Sep 25 '13 at 18:14
It doesn't have a higher f value, i wrote a little explanation above. Also, the search for the lowest f cost node happens in function "search" in class "ProxyAStar". It's the first for loop. –  PEC Sep 25 '13 at 18:32
i think you are right, Before when i tried to do that i didn't have the re-parenting part included in the code so i got a sub-optimal path. Now it seems to be working by just backtracking the closest node in the closed list. Thanks for the advice. –  PEC Sep 25 '13 at 19:33

Are you sure your heuristic is admissible? I did find the code:

``````if(dx > dy) {
D = dy;
O = dx - D;
} else {
D = dx;
O = dy - D;
}
return D*Direction.D_COST + O*Direction.O_COST;
``````

surprising.

In particular, let's suppose dx = 100, dy = 1. Then the real distance is 1000.05 (considering, as you did, each square with 10 length units) and your heuristic would estimate 1004, that is, it is not admissible (considering that you want to get the shortest path).

-
-1 this heuristic looks correct to me. Your example is incorrect, as the distance would not be 1000.05 (he is not allowing any-angle movement...) –  BlueRaja - Danny Pflughoeft Sep 25 '13 at 16:37
Since the algorithm only handles diagonal and orthogonal moves, H is at the worst scenario equal to the remaining distance in this grid map scenario. By that i mean distance by only diagonal and orthogonal steps. Am i supposed to make the inequality true for Euclidean distance? –  PEC Sep 25 '13 at 16:40
@PEC How is the true cost calculated? What is the real cost of a diagonal move and the real cost of a orthogonal move? It seems from the pictures that they have exactly the same cost (this is why you get a dependency on the order the nodes are evaluated and this would explain the difference between the first and last example) –  nonDucor Sep 25 '13 at 16:53
diagonal: 14, orthogonal: 10. I think i know what the issue is at the part where it goes wrong: basically, the "58" node and the one bellow it have the same F values, and "58" appears in the open list before the node bellow it (both get expanded from "72"), so "58" gets picked and put in the closed list, thus becoming the parent of "44". This way, "44" is reached by a suboptimal path. This problem is, though fixable by re-checking for better parent candidates, is not supposed to exist if the heuristic is consistent (monotone). –  PEC Sep 25 '13 at 17:11
@PEC - This is exactly the same thing I am thinking. And this would happen if both diagonal movements and orthogonal movements have the same real cost. I think that would be the result of "getG". Can you show this part of the code? –  nonDucor Sep 25 '13 at 17:29