I need an algorithm which can parse a 2D array and return the largest continuous rectangle. For reference, look at the image I made demonstrating my question.

Generally you solve these sorts of problems using what are called scan line algorithms. They examine the data one row (or scan line) at a time building up the answer you are looking for, in your case candidate rectangles. Here's a rough outline of how it would work. Number all the rows in your image from 0..6, I'll work from the bottom up. Examining row 0 you have the beginnings of two rectangles (I am assuming you are only interested in the black square). I'll refer to rectangles using (x, y, width, height). The two active rectangles are (1,0,2,1) and (4,0,6,1). You add these to a list of active rectangles. This list is sorted by increasing x coordinate. You are now done with scan line 0, so you increment your scan line. Examining row 1 you work along the row seeing if you have any of the following:
As you work along the row you will see that you have a new active rect (0,1,8,1), we can grow one of existing active ones to (1,0,2,2) and we need to remove the active (4,0,6,1) replacing it with two narrower ones. We need to remember this one. It is the largest we have seen to far. It is replaced with two new active ones: (4,0,4,2) and (9,0,1,2) So at the send of scan line 1 we have:
You continue in this manner until you run out of scan lines. The tricky part is coding up the routine that runs along the scan line updating the active list. If you do it correctly you will consider each pixel only once. Hope this helps. It is a little tricky to describe. 


I like a region growing approach for this.
...would be a thorough, but maybe notthemostefficient way to go about it. I suppose you need to answer the philosophical question "Is a line of points a skinny rectangle?" If a line == a thin rectangle, you could optimize further by:
Use the first method to check your work. I think Knuth said "...premature optimization is the root of all evil." HTH, Perry ADDENDUM:Several edits later, I think this answer deserves a group upvote. 


A straight forward approach would be to do a loop through all the potential rectangles in the grid, figure out their area, and if it is greater than the current highest area, select it as the highest:
Then you simply need to find the potential rectangles.
This will duplicate a lot of work (for example you will reevaluate a lot of subrectangles), but it should give you an answer. Edit An alternate approach might be to start with a single square the size of the grid, and "subtract" occupied squares to end up with a final set of potential rectangles. There might be optimization opportunities here using quadtrees, and in ensuring that you keep split rectangles "in order", top to bottom, left to right, in case you need to recombine rectangles farther down in the algorithm. If you are actually starting out with rectangular data (for your "populated grid" set), instead of a loose pixel grid, then you could easily get better perf out of a rectangle/region subtracting algorithm. I'm not going to post pseudocode for this because the idea is completely experimental, and I have no idea if the perf will be any better for a loose pixel grid ;) Windows system "regions" and "dirty rectangles", as well as general "temporal caching" might be good inspiration here for more efficiency. There are also a lot of zbuffer tricks if this is for a graphics algorithm... 


Use dynamic programming approach. Consider a function S(x,y) such that S(x,y) holds the area of the largest rectangle where (x,y) are the lowestrightmost corner cell of the rectangle; x is the row coordinate and y is the column coordinate of the rectangle. For example, in your figure, S(1,1) = 1, S(1,2)=2, S(2,1)=2, and S(2,2) = 4. But, S(3,1)=0, because this cell is filled. S(8,5)=40, which says that the largest rectangle for which the lowestright cell is (8,5) has the area 40, which happens to be the optimum solution in this example. You can easily write a dynamic programming equation of S(x,y) from the value of S(x1,y), S(x,y1) and S(x1,y1). Using that you can obtain the values of all S(x,y) in O(mn) time, where m and n are the row and column dimension of the given table. Once, S(x,y) are know for all 1<=x <= m, and for all 1 <= y <= n, we simply need to find the x, and y for which S(x,y) is the largest; this step also takes O(mn) time. By keeping addition data, you can also find the sidelength of the largest rectangle. The overall complexity is O(mn). To understand more on this, Read Chapter 15 or Cormen's algorithm book, specifically Section 15.4. 

