# Find max sum path and trace its path in 2d matrix with obstacles

For example I have `2d matrix` like this:

``````.X..X..
2...2..
..X.1..
2.....X
``````

Starting at `(0,0)`, I can move down 1 cell or right 1 cell at a time, cell `X` is an obstacle. Find the path with maximum sum. The answer for the above input is: `DRRRRRD (D for down, R for right)` I could find the sum using `dfs` and a `DP-array` but I don't know how can I trace the optimal path with this approach.

``````public static int dfs(char[][] matrix, int i, int j, int[][] cache) {
if (cache[i][j] != 0) {
return cache[i][j];
}

if (matrix[i][j] != 'X' && matrix[i][j] != 'x' && matrix[i][j] != '.') {
cache[i][j] += Character.getNumericValue(matrix[i][j]);

}

int iDown = i + 1;
int jRight = j + 1;
int dirDown = cache[i][j];
int dirRight = cache[i][j];

if (iDown < matrix.length && matrix[iDown][j] != 'X' && matrix[iDown][j] != 'x') {
dirDown += dfs(matrix, iDown, j, cache);
}

if (jRight < matrix.length && matrix[i][jRight] != 'X' && matrix[i][jRight] != 'x') {
dirRight += dfs(matrix, i, jRight, cache);
}

cache[i][j] = Math.max(dirDown, dirRight);

return cache[i][j];
}
``````
• look up dp with path reconstruction 2 days ago

You can modify `dfs` to keep track of the path and have it return a pair of Integer (the sum) and a String representing the path:

``````import java.util.Map;
import java.util.Map.Entry;

class Main   {
public static void main(String[] args) {

char[][] matrix = {
{'.','X','.','.','X','.','.'},
{'2','.','.','.','2','.','.'},
{'.','.','X','.','1','.','.'},
{'2','.','.','.','.','.','X'}
};
Entry<Integer, String> result = dfs(matrix,0,0,new int[matrix.length][matrix.length],"");
System.out.println(result.getKey() +" "+ result.getValue());
}

//Entry is used as a container for an int-string pair
public static Entry<Integer, String> dfs(char[][] matrix, int i, int j, int[][] cache, String path) {
if (cache[i][j] != 0)
return Map.entry(cache[i][j], path);

if (matrix[i][j] != 'X' && matrix[i][j] != 'x' && matrix[i][j] != '.') {
cache[i][j] += Character.getNumericValue(matrix[i][j]);
}

int iDown = i + 1;
int jRight = j + 1;
Entry<Integer,String> resultDown = Map.entry(Integer.MIN_VALUE, ""); //initialize with lowest possible value
Entry<Integer,String> resultRight = Map.entry(Integer.MIN_VALUE, "");

if (iDown < matrix.length && matrix[iDown][j] != 'X' && matrix[iDown][j] != 'x') {
resultDown =  dfs(matrix, iDown, j, cache, path+"D");
}

if (jRight < matrix.length && matrix[i][jRight] != 'X' && matrix[i][jRight] != 'x') {
resultRight =  dfs(matrix, i, jRight, cache, path+"R");
}

if(resultDown.getKey()> resultRight.getKey())
return  Map.entry(cache[i][j]+resultDown.getKey(), resultDown.getValue());
else
return Map.entry(cache[i][j]+resultRight.getKey(), resultRight.getValue());
}
}
``````

A better and more Object Oriented approach is to define a `Node` object, for example:

``````    class Node {

private final char value;
private String direction;
private Node child = null;
private int sum = 0;

public Node(char value) {
this.value = value;
}

public String getDirection() {
return direction;
}

public void setDirection(String direction) {
this.direction = direction;
}

public Node getChild() {
return child;
}

public void setChild(Node parent) {
child = parent;
}

public char getValue() {
return value;
}

public int getSum() {
return sum;
}

and run dfs on a graph of `Node`s (for example `Node[][]`).