# Puzzle Game Android DFS algorithm

I have a android application called Islands and bridges also known as Hashiwokakero

The application uses A 2 Dimensional array that spawns the Islands randomly everytime the user restarts the game It form a Matrix with number from 0 to 4 where 0=null and 1-4 = Island There can be 2 bridges comming out of one Island to connect the other , The map at the moment is not solvable. To solve the game the user needs to connect the islands using bridges so if an island = 4 it needs 4 connection to it if an island = 2 it needs 2 connection and so on..

in my research i found out that the best algorithm to solve the game is to use Depth first search - article

I have looked at different question on here but can't seem to find a solution as my array is of type `String` rather than `integer`.

QUESTION how can apply a DFS algorithm to connect the islands?

here is a screenshot of my application. This the function to create a easy map 4x4 matrix:

``````private void InitializeEasy() {
Random rand = new Random();
String[][] debug_board_state = new String;
setCurrentState(new State(WIDTH_EASY));
for (int row = 0; row < debug_board_state.length; row++) {
for (int column = 0; column < debug_board_state[row].length; column++) {
debug_board_state[row][column] = String.valueOf(rand.nextInt(5));

}
}

for (int row = 0; row < debug_board_state.length; row++) {
for (int column = 0; column < debug_board_state[row].length; column++) {
System.out.print(debug_board_state[row][column] + " ");
}
System.out.println();
}
for (int row = 0; row < WIDTH_EASY; ++row) {
for (int column = 0; column < WIDTH_EASY; ++column) {
for (int colNum = column - 1; colNum <= (column + 1); colNum += 1) {

getCurrentState().board_elements[row][column] = new BoardElement();
getCurrentState().board_elements[row][column].max_connecting_bridges = Integer.parseInt(debug_board_state[row][column]);
getCurrentState().board_elements[row][column].row = row;
getCurrentState().board_elements[row][column].col = column;

if (getCurrentState().board_elements[row][column].max_connecting_bridges > 0) {
getCurrentState().board_elements[row][column].is_island = true;
}
}
}
}
}
``````
• Wouldn't it be easier to start building the board one island at a time using valid moves so that a solvable solution exists? May want to look through: gamedev.stackexchange.com – Morrison Chang Aug 3 '18 at 14:39
• So,just to make sure you are saying that i should build one island at a time checking the connection then build next one do the same and so on? – Wojtek T Aug 3 '18 at 14:43
• Correct. Right now if I understand your game rules correctly the size 4 islands at the edges make the board unwinnable as it can at most have 3 connections. – Morrison Chang Aug 3 '18 at 14:46
• Yes thats correct, I could use a hardcoded array to make this work but my goal is to spawn the map at random. – Wojtek T Aug 3 '18 at 14:50
• If you want to add 'dead ends' to get a interesting board, add those at the end after you have created solvable board. Good luck. – Morrison Chang Aug 3 '18 at 14:53

DFS could be applied to the game state.

Pseudo algorithm:

1. pick a random (or by some other criterium) island that still needs bridges
2. build a bridge between this island and one of its neighbors (obviously a neighbor that also needs a bridge)
3. push the new state of the game (for instance the connectivity matrix of this graph) on a stack
4. if the game contains inconsistencies, pop 1 item from the stack
5. go back to step 1, using the top of the stack as the current state

As I mentioned, this is a piece of pseudo-code. You will need to refine it to handle edge-cases. You should also think about strategies to prevent the branching factor from becoming too large.

example (not thoroughly tested, not thoroughly debugged):

``````int[][] STARTING_CLUES = {
{2, 0, 0, 3, 0, 3},
{0, 1, 4, 0, 4, 0},
{0, 0, 0, 0, 0, 0},
{3, 0, 3, 0, 2, 0},
{0, 0, 0, 1, 0, 2},
{2, 0, 4, 0, 2, 0}
};

void search(){

Map<Point, List<Direction>> remainingOptions = new HashMap<>();

Stack<Land> gameTree = new Stack<>();
gameTree.push(new Land(STARTING_CLUES));

while(true){

Land state = gameTree.peek();
int[] p = state.lowestTodo();
if (p == null)
System.out.println("solution found");

// move to next game state
int r = p;
int c = p;
System.out.println("expanding game state for node at (" + r + ", " + c + ")");

List<Direction> ds = null;
if(remainingOptions.containsKey(new Point(r,c)))
ds = remainingOptions.get(new Point(r,c));
else{
ds = new ArrayList<>();
for(Direction dir : Direction.values()) {
int[] tmp = state.nextIsland(r, c, dir);
if(tmp == null)
continue;
if(state.canBuildBridge(r,c,tmp, tmp))
}
remainingOptions.put(new Point(r,c), ds);
}

// if the node can no longer be expanded, and backtracking is not possible we quit
if(ds.isEmpty() && gameTree.isEmpty()){
System.out.println("no valid configuration found");
return;
}

// if the node can no longer be expanded, we need to backtrack
if(ds.isEmpty()){
gameTree.pop();
remainingOptions.remove(new Point(r,c));
System.out.println("going back to previous decision");
continue;
}

Direction dir = ds.remove(0);
System.out.println("connecting " + dir.name());
remainingOptions.put(new Point(r,c), ds);

Land nextState = new Land(state);
int[] tmp = state.nextIsland(r,c,dir);
nextState.connect(r,c, tmp, tmp);
gameTree.push(nextState);

}

}

public static void main(String[] args) {
new Main().search();
}
``````

I also wrote a utility class that handles the common operations on the piece of land on which bridges need to be built (like finding the next available island, checking whether a bridge can be built, etc)

``````public class Land {

private int[][] BRIDGES_TO_BUILD;

private boolean[][] IS_ISLAND;

public Land(int[][] bridgesToDo){
BRIDGES_TO_BUILD = copy(bridgesToDo);

int R = bridgesToDo.length;
int C = bridgesToDo.length;
IS_ISLAND = new boolean[R][C];
for(int i=0;i<R;i++) {
for (int j = 0; j < C; j++) {
IS_ISLAND[i][j] = bridgesToDo[i][j] > 0;
}
}
}

public Land(Land other){
BRIDGES_TO_BUILD = copy(other.BRIDGES_TO_BUILD);
int R = BRIDGES_TO_BUILD.length;
int C = BRIDGES_TO_BUILD.length;
IS_ISLAND = new boolean[R][C];
for(int i=0;i<R;i++) {
for (int j = 0; j < C; j++) {
IS_ISLAND[i][j] = other.IS_ISLAND[i][j];
}
}
}

public int[] next(int r, int c, Direction dir){
int R = BRIDGES_TO_BUILD.length;
int C = BRIDGES_TO_BUILD.length;

// out of bounds
if(r < 0 || r >=R || c < 0 || c >= C)
return null;

// motion vectors
int[][] motionVector = {{-1, 0},{0,1},{1,0},{0,-1}};
int i = Arrays.asList(Direction.values()).indexOf(dir);

// calculate next
int[] out = new int[]{r + motionVector[i], c + motionVector[i]};

r = out;
c = out;

// out of bounds
if(r < 0 || r >=R || c < 0 || c >= C)
return null;

// return
return out;
}

public int[] nextIsland(int r, int c, Direction dir){
int[] tmp = next(r,c,dir);
if(tmp == null)
return null;
while(!IS_ISLAND[tmp][tmp]){
tmp = next(tmp, tmp, dir);
if(tmp == null)
return null;
}
return tmp;
}

public boolean canBuildBridge(int r0, int c0, int r1, int c1){
if(r0 == r1 && c0 > c1){
return canBuildBridge(r0, c1, r1, c0);
}
if(c0 == c1 && r0 > r1){
return canBuildBridge(r1, c0, r0, c1);
}
if(r0 == r1){
int[] tmp = nextIsland(r0, c0, Direction.EAST);
if(tmp != r1 || tmp != c1)
return false;
if(BRIDGES_TO_BUILD[r0][c0] == 0)
return false;
if(BRIDGES_TO_BUILD[r1][c1] == 0)
return false;
for (int i = c0; i <= c1 ; i++) {
if(IS_ISLAND[r0][i])
continue;
return false;
}
}
if(c0 == c1){
int[] tmp = nextIsland(r0, c0, Direction.SOUTH);
if(tmp != r1 || tmp != c1)
return false;
if(BRIDGES_TO_BUILD[r0][c0] == 0 || BRIDGES_TO_BUILD[r1][c1] == 0)
return false;
for (int i = r0; i <= r1 ; i++) {
if(IS_ISLAND[i][c0])
continue;
return false;
}
}
// default
return true;
}

public int[] lowestTodo(){
int R = BRIDGES_TO_BUILD.length;
int C = BRIDGES_TO_BUILD.length;

int[] out = {0, 0};
for (int i=0;i<R;i++) {
for (int j = 0; j < C; j++) {
if(BRIDGES_TO_BUILD[i][j] == 0)
continue;
if (BRIDGES_TO_BUILD[out][out] == 0)
out = new int[]{i, j};
if (BRIDGES_TO_BUILD[i][j] < BRIDGES_TO_BUILD[out][out])
out = new int[]{i, j};
}
}
if (BRIDGES_TO_BUILD[out][out] == 0) {
return null;
}
return out;
}

private int[][] copy(int[][] other){
int[][] out = new int[other.length][other.length == 0 ? 0 : other.length];
for(int r=0;r<other.length;r++)
out[r] = Arrays.copyOf(other[r], other[r].length);
return out;
}

public void connect(int r0, int c0, int r1, int c1){
if(r0 == r1 && c0 > c1){
connect(r0, c1, r1, c0);
return;
}
if(c0 == c1 && r0 > r1){
connect(r1, c0, r0, c1);
return;
}
if(!canBuildBridge(r0, c0, r1, c1))
return;

BRIDGES_TO_BUILD[r0][c0]--;
BRIDGES_TO_BUILD[r1][c1]--;

if(r0 == r1){
for (int i = c0; i <= c1 ; i++) {
if(IS_ISLAND[r0][i])
continue;
}
}
if(c0 == c1){
for (int i = r0; i <= r1 ; i++) {
if(IS_ISLAND[i][c0])
continue;
• is `Direction` part of the `Path.Direction` or is it a sample class? – Wojtek T Aug 15 '18 at 14:57
• I am running the code, I generate the first row of the matrix, and the the program crashes, I am left with `Attempt to read from null array` error any idea? – Wojtek T Aug 16 '18 at 8:12