Given an 2-D Array of n*n elements:
- all rows are sorted
- all columns are sorted
1 5 7 2 6 8 3 9 10
convert it to a 1-D sorted array. Is there a solution better than
Well it can't be less than
The algorithm to do this is a standard k-way merge, which has a complexity of
Turning your 2D array into a sorted 1D array is
You can use a function f(x,y) = (f(x),f(y)) to reduce the complexity and flatten the 2d array. It's also reorder the 1d array. Since it's a function it's more like a hashing algorithm and maybe not what you are looking for?
You should post your
i have a time: O(n*n log(2n)) space O(2n) algorithm.
basic idea would be as follows
a would be the smallest element for sure. Because elements are row wise and column wise sorted, the next smallest element will be min( a, a ). say, a is smallest of the two, next candidate will be min(a,a,a)
And so on,
pick the smallest of the candidate elements, print it. push the element to right and bottom of the smallest element as potential candidates. (check for out or bound.) Do this till no more candidate element exist.
The candidate elements can be maintained using heap (top is min element) But u need to make sure u dont push the same element twice. (y could be right of x and bottom of z). Before u push to heap u need to know if the element is already pushed.
Both these requirements are gracefully handled by set (which is ordered) (i code in c++)
Storing index in the set will allow me to push the next candidate elements to candidate Ds easily.
a sample implementation is here: http://ideone.com/w208Af
You could do this in O(n). I disagree that this is impossible to do faster then n^2 because in this case n*n=n because when you are talking time complexity you are referring to the number of elements in the list. Here is O(n) solution where n = min-max. For this to work you need to know the lowest number and highest number that could be in the list. You don't need to know what they are just the lowest and highest possible.
I think this would be the approach I would take:
1) start with the first row - "1 5 7". We know that at the start, the rows are sorted, so we are guaranteed that the left-most element is the least, with no comparisons needed. Output the 1, and shift the first column up, giving us "2 5 7".
2) Now compare the first two elements. As long as the first element is less than the second, keep outputting the first element and shifting its respective column up. That gives us output of 2 and 3 with the resulting array being "5 7" (since the first column is now empty).
3) Continue doing the same thing with the remaining two colums. This will give us output of 5 and 6 before we run into the first case where something's different - our array will contain "9 7" at this point.
4) In this case, we'll output the value from the last column and shift that one up, giving us "9 8" after outputting 7. We again have the case where the first element is greater, so we'll output the second and shift that column up, leaving us with "9 10".
Haven't analyzed it thoroughly, but I think that's O(N), as there's a maximum of N comparisons due to the assumptions you can make about the relations between the individual columns.