One idea, making use of binary search.

**The basic idea:**

Start off in the top-left corner. See if a 1x1 square would work.

- If it will work, increase the sides lengths of the square by 1 and repeat.
- If it won't work, move right and repeat. If you've reached the right-most position, move to the next line.

**The native approach:**

We can simply check every possible cell of every square at each step, but this is fairly inefficient.

**The optimized approach:**

When increasing the square size, we can just do a binary search over the next row and column to see if that row / column contains an obstacle at any of those positions.

When moving to the right, we can do a binary search for each next column to determine if that column contains an obstacle at any of those positions.

When moving down, we can do a similar binary on each of the columns in the target position.

**Implementation note:**

To start off, we'd need to go through all the rows and columns and set up arrays containing the positions of the obstacles for each of them, which we can use for the binary searches.

**Running time:**

We do 2 binary searches to increase the square size, and the square size is maximum the size of the grid, so that is fairly small (`O(min(m,n) log max(m,n))`

) and gets dominated by the below.

Beyond that, for each position, we do a single binary search on a column.

So, for a grid with `m`

columns and `n`

rows, the overall complexity is `O(mn log m)`

.

But note how little we're actually searching below when the grid is sparse.

**Example:**

For your example:

```
012345678901234567890123456
0...........................
1....o......................
2............o..............
3...........................
4....o......................
5...............o...........
6...........................
7......o..............o.....
8..o.......o................
```

We'd first try a 1x1 square in the top-left corner, which works.

Then a 2x2 square. For this, we do a binary search for the range `[0,1]`

on the row 1, which can be represented simply by `{4}`

- an array of a single position corresponding to where the obstacle is. And we also do a binary search for the range `[0,1]`

on the column 1, which contains no obstacles, thus an empty array - `{}`

.

Then a 3x3 square. For this, we do a binary search for `[0,2]`

on the row 2, which contains 1 obstacles at position 12, thus `{12}`

. And we also do a binary search for `[0,2]`

on the column 2, which contains an obstacle at position 8, thus `{8}`

.

Then a 4x4 square. For this, we do a binary search for `[0,3]`

on the row 3 - `{}`

. And for `[0,3]`

on column 3 - `{}`

.

Then a 5x5 square. For this, we do a binary search for `[0,4]`

on the row 4 - `{4}`

. And for `[0,4]`

column 4 - `{1,4}`

.

Here is the first one we actually find. In the range `[0,4]`

, we find `4`

in both the row and the column (we only really need to find one of them). So this indicates a fail.

From here we do a binary search on column 4 (again - not really necessary) for `[0,4]`

. Then binary search columns 5-8 for `[0,4]`

, none of them found, so a square starting at position `5,0`

is the next possible candidate.

So from here we try to increase the square size to 5x5, which works, then 6x6 and 7x7, which works.

Then we try 8x8, which doesn't work.

And so on.

**I know binary search, but how does yours work?**

So we're basically doing a range search within a set of values. This is fairly easy to do. First search for the starting value of the range, then the end value. If we get to the same point, there are no values in the range.

We don't really care what values exist in the range, just whether or not there are any.

square, not rectangle. – Julien Fouilhé Dec 2 '13 at 19:47