# Finding maximum size sub-matrix of all 1's in a matrix having 1's and 0's

Suppose you are given an mXn bitmap, represented by an array M[1..m,1.. n] whose entries are all 0 or 1. A all-one block is a subarray of the form M[i .. i0, j .. j0] in which every bit is equal to 1. Describe and analyze an efficient algorithm to find an all-one block in M with maximum area

I am trying to make a dynamic programming solution. But my recursive algorithm runs in O(n^n) time, and even after memoization I cannot think of bringing it down below O(n^4). Can someone help me find a more efficient solution?

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How exactly did you manage to create O(n^n) algorithm here? Even straightforward solution (check all n^4 rectangles and verify each) will run in O(n^6). –  Nikita Rybak Sep 27 '10 at 21:45

An O(N) (number of elements) solution:

``````A
1 1 0 0 1 0
0 1 1 1 1 1
1 1 1 1 1 0
0 0 1 1 0 0
``````

Generate an array `C` where each element represents the number of 1s above and including it, up until the first 0.

``````C
1 1 0 0 1 0
0 2 1 1 2 1
1 3 2 2 3 0
0 0 3 3 0 0
``````

We want to find the row `R`, and left, right indices `l` , `r` that maximizes `(r-l+1)*min(C[R][l..r])`. Here is an algorithm to inspect each row in O(cols) time:

Maintain a stack of pairs `(h, i)`, where `C[R][i-1] < h ≤ C[R][i]`. At any position cur, we should have `h=min(C[R][i..cur])` for all pairs `(h, i)` on the stack.

For each element:

• If `h_cur>h_top`
• Push `(h, i)`.
• Else:
• While `h_cur<h_top`:
• Pop the top of the stack.
• Check whether it would make a new best, i.e. `(i_cur-i_pop)*h_pop > best`.
• If `h_cur>h_top`
• Push `(h, i_lastpopped)`.

An example of this in execution for the third row in our example:

``````  i =0      1      2      3      4      5
C[i]=1      3      2      2      3      0
(3, 4)
S=         (3, 1) (2, 1) (2, 1) (2, 1)
(1, 0) (1, 0) (1, 0) (1, 0) (1, 0)
(0,-1) (0,-1) (0,-1) (0,-1) (0,-1) (0,-1)
``````

`i=0, C[i]=1`) Push `(1, 0)`.
`i=1, C[i]=3`) Push `(3, 1)`.
`i=2, C[i]=2`) Pop `(3, 1)`. Check whether `(2-1)*3=3` is a new best.
The last `i` popped was 1, so push `(2, 1)`.
`i=3, C[i]=2`) `h_cur=h_top` so do nothing.
`i=4, C[i]=3`) Push `(3, 4)`.
`i=5, C[i]=0`) Pop `(3, 4)`. Check whether `(5-4)*3=3` is a new best.
Pop `(2, 1)`. Check whether `(5-1)*2=8` is a new best.
Pop `(1, 0)`. Check whether `(5-0)*1=5` is a new best.
End. (Okay, we should probably add an extra term C[cols]=0 on the end for good measure).

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+1. I wasn't able to quite follow your reasoning (especially what `h` is exactly), but I see now that for each row, you're effectively calling a linear-time algorithm for finding the largest rectangle under a histogram whose baseline is that row. That "subroutine" seems to match algorithm #4 here: blog.csdn.net/arbuckle/archive/2006/05/06/710988.aspx –  j_random_hacker Dec 20 '10 at 5:14

Here's an `O(numCols*numLines^2)` algorithm. Let `S[i][j] = sum of the first i elements of column j.`

I will work the algorithm on this example:

``````M
1 1 0 0 1 0
0 1 1 1 0 1
1 1 1 1 0 0
0 0 1 1 0 0
``````

We have:

``````S
1 1 0 0 1 0
1 2 1 1 1 1
2 3 2 2 1 1
2 3 3 3 1 1
``````

Now consider the problem of finding the maximum subarray of all ones in a one-dimensional array. This can be solved using this simple algorithm:

``````append 0 to the end of your array
max = 0, temp = 0
for i = 1 to array.size do
if array[i] = 1 then
++temp
else
if temp > max then
max = temp
temp = 0
``````

For example, if you have this 1d array:

``````1 2 3 4 5 6
1 1 0 1 1 1
``````

you'd do this:

First append a `0`:

``````1 2 3 4 5 6 7
1 1 0 1 1 1 0
``````

Now, notice that whenever you hit a `0`, you know where a sequence of contiguous ones ends. Therefore, if you keep a running total (`temp` variable) of the current number of ones, you can compare that total with the maximum so far (`max` variable) when you hit a zero, and then reset the running total. This will give you the maximum length of a contiguous sequence of ones in the variable `max`.

Now you can use this subalgorithm to find the solution for your problem. First of all append a `0` column to your matrix. Then compute `S`.

Then:

``````max = 0
for i = 1 to M.numLines do
for j = i to M.numLines do
temp = 0
for k = 1 to M.numCols do
if S[j][k] - S[i-1][k] = j - i + 1 then
temp += j - i + 1
else
if temp > max then
max = temp
temp = 0
``````

Basically, for each possible height of a subarray (there are `O(numLines^2)` possible heights), you find the one with maximum area having that height by applying the algorithm for the one-dimensional array (in `O(numCols)`).

Consider the following "picture":

``````   M
1 1 0 0 1 0 0
i  0 1 1 1 0 1 0
j  1 1 1 1 0 0 0
0 0 1 1 0 0 0
``````

This means that we have the height `j - i + 1` fixed. Now, take all the elements of the matrix that are between `i` and `j` inclusively:

``````0 1 1 1 0 1 0
1 1 1 1 0 0 0
``````

Notice that this resembles the one-dimensional problem. Let's sum the columns and see what we get:

``````1 2 2 2 0 1 0
``````

Now, the problem is reduced to the one-dimensional case, with the exception that we must find a subsequence of contiguous `j - i + 1` (which is `2` in this case) values. This means that each column in our `j - i + 1` "window" must be full of ones. We can check for this efficiently by using the `S` matrix.

To understand how `S` works, consider a one-dimensional case again: let `s[i] = sum of the first i elements of the vector a`. Then what is the sum of the subsequence `a[i..j]`? It's the sum of all the elements up to and including `a[j]`, minus the sum of all those up to and including `a[i-1]`, meaning `s[j] - s[i-1]`. The 2d case works the same, except we have an `s` for each column.

I hope this is clear, if you have any more questions please ask.

I don't know if this fits your needs, but I think there's also an `O(numLines*numCols)` algorithm, based on dynamic programming. I can't figure it out yet, except for the case where the subarray you're after is square. Someone might have better insight however, so wait a bit more.

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+1 good solution (and I don't think O(n*m) complexity can be achieved in general case, this is probably as good as it gets) BTW, lower-left value of S in your example seems to be wrong. Also, I think you might get more upvotes if explain main idea more clearly (although it's difficult to do with words, idea is more 'visual'). –  Nikita Rybak Sep 27 '10 at 21:40
@Nikita Rybak - thanks for your input, I corrected the mistake in `S` and tried to better explain the idea. –  IVlad Sep 27 '10 at 22:13
Somebody told me that this problem can be solved in O(n^2logn) also. Anyone for O(n^2logn)? –  Akhil Sep 27 '10 at 22:27