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I wonder, can binary search be applied on a 2D array?

  • What would the conditions on the array be? Sorted on 2D??
  • What would be the time complexity for it?
  • How would the algorithm change the boundary of the search (minX,maxX,minY,maxY) ??

Edit:

Binary Search on 1D maintains 2 pointers minX and maxX.. It selects the middle index (minX+maxX)/2 and compare it with the search value, if greater then change maxX, else change minX... until minX>=maxX

Pseudo code for normal binary seacrh:

 min := 1;
  max := N; {array size: var A : array [1..N] of integer}
  repeat
    mid := min + (max - min) div 2;
    if x > A[mid] then
      min := mid + 1
    else 
      max := mid - 1;
  until (A[mid] = x) or (min > max);

Thanks

share|improve this question
    
Is there anything in particular you're trying to achieve? –  NPE Dec 13 '10 at 14:53
    
My first recommendation would be to get your 1D algorithm worked out. There may be a few bounds problems. Consider an array of size 1. Here min = 1 and max = 1. Then mid := min + (max - min) div 2 results in mid = 0 (assuming integer arithmetic). Then who knows what A[mid] equates to (given A is indexed as: 1..N). –  NealB Dec 13 '10 at 16:23
    
@NealB That is just the code in Wikipedia... It does not matter it is just for demonstration.. –  Betamoo Dec 14 '10 at 12:45
    
Just took a second look... My mistake: mid := min + (max - min) DIV 2 results in 1, which is just fine. –  NealB Dec 14 '10 at 15:57
    
In my case I have a list of 2D points where X=pressure and Y=temperature. Given an input targetKey (X,Y) I need to find the nearest one to the targetKey in the data set. At first I thought I could use a BinarySearch, implementing a custom comparer on the type, which compares the distance between two points. However this won't work, since it would require the list to be re-sorted in the order of the distance from the targetKey before running every Binary Search. A better solution is to use a quadtree. FYI, a C# implementation is here: link –  dodgy_coder Aug 12 '11 at 2:27

2 Answers 2

I thought about this problem last year... So, I'd choosed this approach:

Consider your 2D-array represents points in a plane. For example, your element A[i][j] represents a point with x = i and y = j. To use binary search on the plane I sort all points using this condition:

point p1 < p2 if and only if:

  • (x-coordinate of p1) < (x-coordinate of p2)
  • (x-coordinate of p1) = (x-coordinate of p2) and (y-coordinate of p1) < (y-coordinate of p2)

Othwerwise p1 >= p2.

Now, if we look to our 2D-array, elements in 2nd row should be greater than elements in 1st row. In same row elements sorted as usual (according to their column number).

In another words:

  • A[i][j] > A[k][j] if and only if (i>k). (in different rows and in same column)
  • A[i][j] > A[i][k] if and only if (j>k). (in the same row and different columns)

Consider your array has N rows and M columns. Now you should (temporarly) transform your 2D array to 1D array using this formula (T - temporary array):

for i:=0 to N-1 do
    for j:=0 to M-1 do
        T[i*N + j]:= A[i][j];

Now you have 1D array. Sort it in usual way. And now you can search in it using simple binary search algorithm.

Or you can transform your sorted array back to 2D array using this formula:

for i:=0 to N*M-1 do
    A[i div N][i - (i div N)*N]:= T[i];

And use two binary searches:

One search by x-coordinate (by rows in our meaning), another one by y-coordinate (by columns in our meaning) for elements in same row.

In another words, when you calculate mid = mid + (max - min) div 2, you can compare element A[mid][0] with your key-element(in your code it has x name) and when you find row with your element, you can call another binary search in this row (binary search in A[mid]).

Complexity for both methods:

  • for simple binary search in trasformed array: log(N*M)
  • for two binary searches in 2D array: log(N) for outer search (in rows) + log(M) for inner search (in columns).

Using the properties of logarithm function we can simplify last expression: log(N) + log(M) = log(N*M).

So, we proved, that both methods has same complexity and doesn't matter, which one to use.

But, if it's not hard to you, I suggest you simply transform your array to 1-D and use simple binary search (it's very simple and easy to debug and check).

share|improve this answer

Binary search requires that your array be sorted. Sorting, in turn, requires a total ordering relationship on the array elements. In 1-D it's fairly easy to understand what this means. I think you will have to define a 1-D index into your 2-D array and ensure that the array elements are sorted along that index.

You have a variety of 1-D indexing schemes to choose from, essentially any space-filling curve will do. The obvious ones which come to mind are:

  • Start with the first element, read along each row, at the end of each row go to the first element in the next row.
  • Same, replace row by column.
  • A diagonalisation, in which you read each diagonal in turn.

Like @Bart Kiers, I don't understand your 2nd point.

share|improve this answer
    
Please take a look on the modified question.. –  Betamoo Dec 12 '10 at 13:22
    
I looked at the modified question. Now the point I don't understand is 3rd not 2nd. –  High Performance Mark Dec 12 '10 at 14:53

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