i have following problem

assume that we have a 9*8 matrix

A matrix is said to have a "saddle point " if some position is the smalles value in its row and the largest value in its column . IN symbols , a[i][j] is a saddle point if

a[i][j]=min a[i][k]  ==max a[k][k]
1<=k<=8      1<=k<=9

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what seems to be a problem? –  Unreason Jun 17 '10 at 13:52
What have you achieved so far? Where do you have problems? –  Petar Minchev Jun 17 '10 at 13:52

Given MxN matrix, this is O(MN), which is optimal.

INIT rowMin = [ +Infinify ] xM
INIT colMax = [ -Infinity ] xN

FOR r = 1..M
FOR c = 1..N
rowMin[r] = MIN(rowMin[r], mat[r][c])
colMax[c] = MAX(colMax[c], mat[r][c])

FOR r = 1..M
FOR c = 1..N
IF mat[r][c] == rowMin[r] == colMax[c]

### Why is this optimal?

Because there are MxN values, and they each need to be looked at, so for your answer to be certain (i.e. not probabilistic), the lowerbound is O(MN).

### Can this be optimized further?

You can optimize this a bit. It'll still be O(MN), but instead of finding the maximum/minimum values, you find their indices instead. This can make the second phase O(M) in the best case (i.e. when there's a unique min/max in a row/column).

Note that in the worst case, there are O(MN) saddle points: that's when the numbers in the array are all equal.

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I think you have a bug at line 2 of the code (-Infinity?); even though I don't get the ... x M nor ... x N notation –  Unreason Jun 17 '10 at 14:16
I'm pretty sure O(MN) is not optimal. –  Nick Johnson Jun 17 '10 at 14:25
@unreason: yep, bug. Fixed. The notation is short for [1,1,1] = [1]x3 –  polygenelubricants Jun 17 '10 at 14:25
@Nick: there are O(MN) values. How can you answer this without looking at each one of them? –  polygenelubricants Jun 17 '10 at 14:26
Sorry, you're right - I misread it as being greater than the number of values in the array, somehow. Still, your last loop is suboptimal - see my answer for an O(min(m, n)) solution for the last part. I see you've already alluded to the possibility, but it's really not hard to implement, either. –  Nick Johnson Jun 17 '10 at 14:46

Naive solution is to:

• find smallest values of all rows
• find largest values of columns
• see if any of them are at the same position
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In a nutshell:

1. Iterate through each row, finding the column number of the smallest value in that row.
2. Iterate through each column, finding the row number of the largest value in that column.
3. Iterate through either rows-mins or column-maxes, checking if the corresponding cell is also the max in the other array.

Here's an implementation in Python:

"""Finds saddle points in a, a 2 dimensional array.

Args:
a: A 2 dimensional array in row-major (y, x) order.
Returns:
A list of (x, y) location of the saddle points.
"""
# Holds a (value, column) tuple of the min value and its column for each row.
row_mins = [min((a[row][col], col) for col in range(len(a[row]))) for row in range(len(a))]
# Holds a (value, row) tuple of the max value and its row for each column.
col_maxes = [max((a[row][col], row) for row in range(len(a))) for col in range(len(a[0]))]

ret = []
for row, (row_min, col) in enumerate(row_mins):
if col_maxes[col][1] == row:
ret.append((row, col))
return ret
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I don't understand python, but you said that your second phase is O(min(M,N)), and yet you claim to return all saddle points. In the worst case, every point is a saddle point, so the second phase would have to be O(MN). How do you explain this? (+1, by the way) –  polygenelubricants Jun 17 '10 at 15:01
You're quite right - it will return at most one saddle point per row (or column, if you reverse the final loop). This may or may not be a significant issue, depending on the application, since in the common case (an array without many repeated values), there can only be one saddle point. –  Nick Johnson Jun 17 '10 at 15:27