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]
DECLARE saddlePoint(r, 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.