# Solving 8 puzzle using A* algorithm and Manhattan Heuristic [closed]

I have written a program to solve the 8 puzzle using the A* algorithm and the Manhattan heuristic but the programs doesn't seem to work correctly ( minimum number of moves ) for all the inputs and even for the correct output, the number of states expanded is much larger than what it should normally be.

My program has four classes:
Game State: To represent the Game
AStar: AStar algorithm
AStarList: A data structure for representing the open and closed lists. (I know that my data structure is very bad in terms of performance. I will improve it later on)
Utilities

Here is part of the code:

(Sorry for the large code size. I suspect that something is wrong with my AStar algorithm. So, you probably need not go through the other classes.)

AStar

``````public class AStar {

public static void solve(GameState gameStateToSolve) {
AStarList openList = new AStarList();
AStarList closedlList = new AStarList();
int iteration = 1;
while (!openList.isEmpty()) {
System.out.println((iteration++));
GameState current = openList.getNext();
if (current.isGoalState()) {
current.print();
return;
}
GameState children[] = current.expand();
for (int i = 0; i < children.length; i++) {
boolean presentInOpenList = openList.isPresent(children[i]);
boolean presentInClosedList = closedlList.isPresent(children[i]);
if (!presentInOpenList && !presentInClosedList) {
} else if (presentInClosedList && !presentInOpenList) {
if (closedlList.getCostOf(children[i]) > children[i].getMovementsCount()) {
closedlList.remove(children[i]);
}
} else if (presentInOpenList && !presentInClosedList) {
if (openList.getCostOf(children[i]) > children[i].getMovementsCount()) {
openList.remove(children[i]);
}
}
}
}
}

public static void main(String[] args) {
solve(new GameState(
new int[]{0,7,3,1,8,6,5,4,2},
new ArrayList<Integer>(),
GameState.NUMBERS_ARRAY));
}
}
``````

AStarList

``````public class AStarList {

ArrayList<GameState> list;

public AStarList() {
list = new ArrayList<>();
}

public boolean isPresent(GameState gameState) {
for (int i = 0; i < list.size(); i++) {
if (list.get(i).equals(gameState)) {
return true;
}
}
return false;
}

public void remove(GameState gameState) {
for (int i = 0; i < list.size(); i++) {
if (list.get(i).equals(gameState)) {
list.remove(i);
}
}
}

for (int i = 0; i < list.size(); i++) {
if (list.get(i).manhattanDistance() > gameState.manhattanDistance()) {
return;
}
}
}

for (int i = 0; i < list.size(); i++) {
if (list.get(i).equals(gameState)) {
list.remove(i);
}
if (list.get(i).manhattanDistance() > gameState.manhattanDistance()) {
return;
}
}
}

public boolean isEmpty() {
return list.isEmpty();
}

public GameState getNext() {
return list.remove(0);
}

public int getHeuristicOf(GameState gameState) {
for (int i = 0; i < list.size(); i++) {
if (list.get(i).equals(gameState)) {
return list.get(i).manhattanDistance();
}
}
throw new RuntimeException();
}

public int getCostOf(GameState gameState) {
for (int i = 0; i < list.size(); i++) {
if (list.get(i).equals(gameState)) {
return list.get(i).getMovementsCount();
}
}
return -1;
}
}
``````

GameState

``````public final class GameState1 {

public GameState1(GameState gameState) {
// creates a GameState exactly similar to the one passed
}

public GameState1(int[] array, ArrayList<Integer> movements, int type) {
//...
}

public int getMovementsCount() {
// returns number of movements made so far
}

public int[] getPositionsArrayOf(int[] numbersArray) {
//...
}

public int[] getNumbersArrayOf(int[] positionsArray) {
//...
}

public void move(int direction) {
//...
}

public GameState getStateOnMovement(int direction) {
//...
}

public boolean movePossible(int direction) {
//...
}

public int[] getPossibleMovements() {
//...
}

public GameState[] expand() {
//..
}

public boolean equals(GameState anotherState) {
// returns true if the board state is the same
}

public boolean isGoalState() {
// returns true if it is goal state
}

public void print() {
//...
}

public int numberOfInversions() {
// returns number of inversions
}

public boolean isSolvable() {
//returns true if solvable
}

public int manhattanDistance() {
// returns manhattan distance
}

}
``````

Sorry for the large code size. I suspect that something is wrong with my AStar algorithm. S0, you probably need not go through the other classes.

-

## closed as off topic by maba, UVM, nwinkler, hochl, kapaMar 13 '13 at 12:01

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Why was this closed? –  Ranjith - SR2GF Mar 13 '13 at 13:11

I haven't read the code exhaustively, but I think it might because you sort the open list just by the heuristic, not by the total cost function. As I'm sure you know...

``````f(x) = g(x) + h(x)
``````

Where `g(x)` is the path cost so far, and `h(x)` is the Manhattan distance.

In the method `AStarList.add()` try changing the line

``````if (list.get(i).manhattanDistance() > gameState.manhattanDistance()) {
``````

to

``````if (list.get(i).getCost() > gameState.getCost()) {
``````

Where `GameState.cost()` is

``````public int getCost() {
return getMovementsCount() + manhattanDistance();
}
``````

Edit: I also noticed that you handling of neighboring nodes looks a bit odd. You should never be removing anything from the closed list. Firstly you want discard the neighbor (i.e. `children[i]`) if the closed list already contains the same or shorter path to that node. Second if the neighbor is new (i.e. not present in open list) or if we have found a shorter path to the same node on the open list, then add it to the open list.

``````boolean presentInOpenList = openList.isPresent(children[i]);
boolean presentInClosedList = closedlList.isPresent(children[i]);

if (presentInClosedList && children[i].getMovementsCount() >= closedlList.getCostOf(children[i])) {
// Ignore this node
continue;
}

if (!presentInOpenList || openList.getCostOf(children[i]) > children[i].getMovementsCount()) {
It might be good to use a `Map` instead of a `List` for your open/closed lists, as you want to make sure you have a single unique entry for each (x,y) coordinate; the one with the lowest cost found so far.
Yes that's correct, though you might as well just use the `g(x)` cost in step 2, since the `h(x)` Manhattan distance will be the same for the same (x,y) coordinates. I think something else is wrong. Will edit post. –  Zutty Mar 13 '13 at 11:23