Well, bi-directional BFS works as follows:

**Algorithm behavior**: The vertex v that terminates the algorithm's run will be exactly in the middle between the source and the target.

This algorithm will yield much better result in most cases then BFS from the source [explanation why it is better then BFS follows], and will surely provide an answer, if one exist.

**why is it better then BFS from the source?**

assume the distance between source to target is `k`

, and the branch factor is `B`

[every vertex has B edges].

BFS will open: `1 + B + B^2 + ... + B^k`

vertices.

bi-directional BFS will open: `2 + 2B^2 + 2B^3 + .. + 2B^(k/2)`

vertices.

for large B and k, the second is obviously much better the the first.

**In your case:**

I am going to assume no obstacles in the matrix, for simplicity and show what happens:

```
iteration 0 (init):
front1 = { (0,5) }
front2 = { (4,1) }
iteration 1:
front1 = { (0,4),(1,5) }
front2 = { (4,0),(4,2),(3,1),(5,1) }
iteration 2:
front1 = { (0,3), (1,4), (2,5) }
front2 = { (3,0), (5,0), (4,3), (5,2), (3,2), (2,1) }
iteration 3:
front1 = { (0,2), (1,3), (2,4), (3,5) }
front2 = { (2,0), (4,4), (3,3), (5,3), (2,2), (1,1), }
iteration 4:
front1 = { (0,1), (1,2), .... }
front2 = { (1,2) , .... }
```

Now, we found out that the fronts intersects (1,2) - so we need to find the path by developing back the path, same as we would have developed using BFS:

```
path1: (0,5)->(0,4)->(0,3)->(0,2)->(1,2)
path2: (4,1)->(3,1)->(2,1)->(1,1)->(1,2)
```

From this we can conclude the path is:

```
(0,5)->(0,4)->(0,3)->(0,2)->(1,2)->(1,1)->(2,1)->(3,1)->(4,1)
```

Disclaimer: the algorithm description in the beginning of the answer is taken from another answer I once posted (I came to this question while googling for that question to reference another question...)