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So, this is not my home work question, but it is taken from an ungraded homework of the coursera course on algorithms and data structures (which is now complete).

You are given an n by n grid of distinct numbers. A number is a local minimum if it is smaller than all of its neighbors. (A neighbor of a number is one immediately above, below, to the left, or the right. Most numbers have four neighbors; numbers on the side have three; the four corners have two.) Use the divide-and-conquer algorithm design paradigm to compute a local minimum with only O(n) comparisons between pairs of numbers. (Note: since there are n2 numbers in the input, you cannot afford to look at all of them. Hint: Think about what types of recurrences would give you the desired upper bound.)

Since the numbers are not in any order, I don't see how we can get away with any thing but O(n2) comparisons.

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Do it in O(log(n)) or O(n) ? – Words Like Jared Aug 30 '13 at 4:55
There are n^2 elements, so O(n) will be awesome. Of course, O(log(n)) would be brilliant if possible – Rohit Pandey Aug 30 '13 at 4:58
Also we need to be careful about what n is. Initially you said n was the number of rows and columns meaning there are n^2 numbers. Each number has roughly 4 neighbors so there are roughly 4*n^2/2 pairs, yes? Meaning in terms of m being the number of pairs if we are supposed to do it in O(m) then that's O(n^2). Also we're just computing a single local minimum - not the least element? – Words Like Jared Aug 30 '13 at 4:59
Yes, there might be some double counting in the 4*n^2/2, but I think it is still O(n^2). And yeah, we just want a single local minimum, not global. – Rohit Pandey Aug 30 '13 at 5:04
I have edited the title of this question to match its content. There is nothing about "log n" in here at all. The question is actually very clear. I don't know the answer yet, though. – Nemo Aug 30 '13 at 5:10
up vote 23 down vote accepted

We can adapt Words Like Jared's answer, by looking at how it can go wrong.

The idea in that answer -- which is a good one -- is to "roll downhill". This just means, if you are on an element, check if it is a local minimum. If so, you are done; otherwise, step to the smallest of its nearest neighbors. Eventually this must terminate because every step is to a smaller element, and that cannot go on forever in a finite array.

The problem with this approach is that the "rolling" can meander all over the place:

20 100 12  11 10 100  2
19 100 13 100  9 100  3
18 100 14 100  8 100  4
17  16 15 100  7   6  5

If you start at the upper left and "roll downhill", you will visit around half of the elements in the array. That is too many, so we have to constrain it a bit.

Start by examining the middle column and middle row. Find the smallest element among all of those and start there.

Roll one step "downhill" from there to enter one of the four quadrants. You will enter one of the quadrants, because the adjacent elements in the middle column and/or row are larger, so only one of the two adjacent quadrants could be "downhill".

Now consider what would happen if you "rolled downhill" from there. Obviously, you would eventually reach a local minimum. (We will not actually do this because it would take too long.) But, in the course of rolling around, you would never leave that quadrant... Because to do so, you would have to cross either the middle column or middle row, and none of those elements are smaller than where you started. Therefore that quadrant contains a local minimum somewhere.

Thus, in linear time, we have identified a quadrant that must contain a local minimum, and we have cut n in half. Now just recurse.

This algorithm takes time 2n + 2n/2 + 2n/4 + ..., which equals 4n, which is O(n) so we are done.

Interestingly, we did not use "rolling downhill" very much at all, except for the critical part: Proving that the algorithm works.


As Incassator points out, this answer is not entirely correct, because after you "just recurse" you might roll out of the quadrant again...

The simplest fix is to find the smallest element among the middle row, middle column, and boundary before you "roll downhill".

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But isn't it possible that a local minimum is in a quadrant that your greedy criterion doesn't take you to? That way will it be lost forever? – Rohit Pandey Aug 30 '13 at 5:29
We're looking for a local minimum not the minimum. – Words Like Jared Aug 30 '13 at 5:30
No, because you can always find it by "rolling downhill", and that cannot take you out of the quadrant where you started because it would have to cross either the middle column or middle row... And you are starting someplace smaller than all of those. – Nemo Aug 30 '13 at 5:31
"Roll one step "downhill" from there to enter one of the four quadrants." How do you make this precise.. lets say the top element is the lowest.. it is shared by 2 quadrants – Rohit Pandey Aug 30 '13 at 5:31
@Remo: My first comment on your answer was directed at Rohit, actually. :) Who cares if there's a local minimum in a quadrant that you're not in - you're looking for a not the. – Words Like Jared Aug 30 '13 at 5:37

The accepted answer by Nemo is nice but not fully correct:

Thus, in linear time, we have identified a quadrant that must contain a local minimum, and we have cut n in half. Now just recurse.

I am referring to "just recurse" bit. The problem is we cannot do that directly because on next iteration we might find a local minimum which is not a local minimum for original grid (x below means some arbitrary large numbers):

 x  x 39  x  x 50  x  x  x  x  x
 x  x 38  x  x 49  x  x  x  x  x
37 36 33 34 35 48  x  x  x  x  x
 x  x 32  x  1 10  x  x  x  x  x
 x  x 31  x  x 47  x  x  x  x  x
46 45 30 44 43 60 51 52 53 54 55
 x  x  2  x  x 56  x  x  x  x  x
 x  x  x  x  x 57  x  x  x  x  x
 x  x  x  x  x 58  x  x  x  x  x
 x  x  x  x  x 59  x  x  x  x  x

At first iteration we find 10 to be a minimum of middle row and middle column. We go to the left (as 1 is less than 10). So our next iteration is on upper-left quadrant. But now minimum of middle row and column is going to be 31 (or 30 if quadrant's borders are considered to be part of it). You will then conclude that it is a local minimum. But it is not for the full grid.

We can rectify this unfortunate defect in variety of ways. I solved it like this:

At each iteration in addition to the grid itself we keep track of current minimum candidate (that is the 1 in the example above after first iteration; in the initial state we can say minimum candidate is plus infinity). We calculate minimum of middle row and column and compare it to minimum candidate. If the latter is smaller we recurse into the quadrant containing minimum candidate. Otherwise we forget previous candidate and only then check whether new middle row/column minimum is actually a local minimum. And if not then recurse as usual to whatever quadrant we slope down from it (and track new minimum candidate).

Alternatively, you can modify the procedure as described in this presumably MIT lecture: at each iteration instead of looking at middle row/column you can look at middle row/column and grid boundary. Then the algorithm once again is correct.

You choose which way you like.

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I think this is actually really easy.

Turn the problem into 3-D one to see why the algorithm works. Put the matrix on a table. Pretend there are pillars extending out of each cell and that the height of the pillar is directly proportional to its value. Put a ball on any pillar. Have the ball always fall onto the adjacent pillar that is the lowest altitude until it is at a local minimum.

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Very nice analogy. – Rohit Pandey Aug 30 '13 at 5:06
This gives the right answer, but it is too slow. The ball might roll down the first column, two steps right, up the third column, two steps right, down the fifth column... All the way until it lands in the opposite corner. (It is easy to construct an example where this happens.) That touches half the squares, and compares around four times that amount, which is O(n^2), not O(n). – Nemo Aug 30 '13 at 5:07
Sounds good, but is it O(log(N))? Probably, but it is worth adding complexity analysis to the answer I think. – Codie CodeMonkey Aug 30 '13 at 5:08
Don't accept it unless it's fast enough. I think Nemo has a good point. I'm still scratching my head. Hang on. – Words Like Jared Aug 30 '13 at 5:08
@bcorso: Fair enough, but in this case a worst-case O(n) algorithm actually exists. See my answer. (Also, when a problem like this says O(n) algorithm, I believe "worst case" is implied. If they are talking averages, they usually say so.) – Nemo Aug 30 '13 at 5:25

Well, this is how you divide and conquer it.

1) Divide the n x n matrix into four n/2 x n/2 sub matrices.

2) Keep dividing the sub matrices recursively until you end up with a 2 x 2 matrix

3) Check if any element of 2 x 2 matrix is a local Minimum.

Recurrence equation is : T(n) = 4*T(n/2) + O(1)

4*T(n/2) for 4 n/2 x n/2 sub matrices and O(1) for checking if 2 x 2 sub matrix has a local minimum

Master theorem says this is a O(n^2) worst case bound.

But I think we can get a best case O(n) bound,


if we exit the recursion stack after we have have found a local minimum in step 3.


private void FindlocalMin(matrix,rowIndex,colIndex,width){
    if(width == 1){ checkForLocalMinimum(matrix,rowIndex,colIndex); return;} //2x2 matrix
    FindlocalMin(matrix, (rowIndex + (width/2) + 1) ,colIndex,width/2);
    FindlocalMin(matrix,rowIndex, (colIndex + (width/2) + 1) ,width/2);
    FindlocalMin(matrix,(rowIndex + (width/2) + 1), (colIndex + (width/2) + 1) ,width/2);

private void checkForLocalMinimum(.........){
    if(found Local Minimum in 2x2 matrix){ exit recursion stack;} 

Here is a java implementation

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Sorry, this just piqued my interest so long after. I doubt the answers given though. Here is why.

To obtain O(n), the solution should guarantee that we will never walk back in our search, i.e. in U-turn fashion. However, since the numbers are all distinct (actually non-distinctness makes the problem tougher), this can happen.

Imagine a spiral staircase that starts at one corner as the highest point and then spirals inward and downward. If the staircase is square, then the center is the only local minima as well as the global minima. In that case since we are starting the center, we may just get lucky. However, the cross-section of staircase may be bit asymmetric, in which case the solution won't work. Because we can't avoid a U-turn during our search.

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My answer checked immediately adjacent above, below, left and right and moved that way. If instead you check the full length of above, below, left and right within your search space you get much better results. The problem with this approach lies in having the need to back up. If I understood this answer correctly (stackoverflow.com/questions/18525179/…) then they solve it by making it so you only have to go back at once one time by keeping track of a candidate. – Words Like Jared Apr 7 at 18:52
The end result is a O(n) algorithm I think - sometimes O(n) algorithms have a constant because of the way series converge. As long as you can guarantee you cut down enough of the search space so much each time that your series converges to a constant (1 + 1/2 + 1/4 + 1/8 + .. + 1/2^n + ... == 2 for example) you'll have a O(n) algorithm (albeit k * O(n) which is the set of O(n) algorithms). – Words Like Jared Apr 7 at 18:53
Imagine you had a sorted list that could reverse randomly, but not back-to-back and you tried to perform a binary search - you would have to back up to once each time (oh not the number, darnit it reversed on me again, let me check the other side it can't reverse back-to-back). I think that limiting the backups in that case still means the algorithm is log(n), but you might have to double your work. If you can bound your backing up enough - or U-turning as you called it, you can still have the same class of algorithms. – Words Like Jared Apr 7 at 18:58

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