This question already has an answer here:

Problem: Given a matrix in which each row and each column is sorted, write a method to find an element in it.

It is a classic interview question, here is my solution

boolean F(int[][] matrix, int hs, int he, int ws, int we)
    if (hs > he || ws > we) 
        return false; 

    int m = (hs + he) / 2; 
    int n = (ws + we) / 2;

    if (matrix[m][n] == t)
        return true;
    else if (matrix[m][n] < t)
        // find the ele in the same row, right to [m][n]
        F(m, m, n + 1, we);

        // find the ele in the same col, upper to [m][n]
        F(m + 1, he, n, n);

        // find the ele in the area, where i>m,j>n 
        F(m + 1, he, n + 1, we);       
    else if (matrix[m][n] > t)
        // very similar to previous part

The running time of the algorithm is log(m) + log(n). I am looking for an algorithm that is more efficient, or with concise code.

Having more comments, I come up with following code:

// return target recurrence in the matrix
int F(int[][] m, int rs, int re, int cs, int ce, int t){
   int r1 = rs, r2 = re;
   int c1 = cs, c2 = ce;
   int r=0 , c = c1;

   while( r1 < r2 && c1 < c2 ){
   // find the last element that <= t in column c
     r  = FlastLess( r1, r2, c, t)

     if( r == -1 ) break;

       // find the first ele in the row that is >=t
       c = FfirstGreater( r, c1, c2, t);

       if( c == -1)  break;
         r2 = r; 
         c1 = c; 
       }// else    
     }// else 
   }// while
}// f

Here is the link to function F1 and F2 Find the first element in a sorted array that is greater than the target

void FlastLess(int s, int e, int t){
  int l = s, h = e;
  while( l != h ){
     int mid = (l+h)/2;
     if( mid >=  t) high = mid - 1; 
     else {
       if( high < t) low= mid + 1;
       else low = mid;

 void FfirstGreater(int s, int e, int t){
  while(l < h){
    mid = (l+h)/2;
    if ( mid <=  t) low = mid+1;
    else high = mid;


marked as duplicate by Dukeling algorithm Jan 2 '18 at 12:37

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

  • I could be wrong, but binary search might be as fast as you can get it. – user456814 Jul 6 '11 at 21:24
  • I'm not sure your method works. Imagine a matrix whose first row is [0,10,20,..,90] and the next row is [1,11,21,..,91] up to [9,19,29,...,99]. In this case each row and column is ordered. Now you start from 55, and you're looking for 72. 72 > 55 but it's not in the bottom half of the matrix. If you're looking for 19, it's not in the top half. Maybe I didn't understand the algorithm. I also don't understand how you have consecutive "return" statements - it's unreachable code. – Omri Barel Jul 6 '11 at 21:49
  • @secureFish consider new answer . And let me know it is right . – Imposter Sep 27 '12 at 10:12
  • FYI: This data structure is also known as Young tableau. – Giovanni Botta Mar 12 '14 at 14:33

Start in the bottom-left corner of your matrix. Then go to the right until you find the exact number (done), or until you find a number that is bigger.

Then you go upwards in the matrix until you find the exact number (done), or until you find a number that is too small.

Then again you move to the right, ... and so on until you found the number or until you reach the right-side or top of your matrix.

The following images contain some examples, using an Excel table showing the target number in green, and the path that is followed in yellow.

enter image description here

enter image description here

In the last example we look for 207, which isn't in the matrix:

enter image description here

This is just the algorithm. The coding is left for you as an exercise :-)

EDIT: When starting on the bottom row, a binary search might give a better starting point. For the rest of the algorithm it probably doesn't matter.

  • you are saying from the bottom_left from the matrix as you illustrated. I think we still can use binary search to speed up. Here is my thought. For the column, we find the first element that equals or greater than target; if fails, we move right of the same row, still looking for the first equal/greater element than target; if yes, move back in the same column and find the first element that is less than the target; if yes, move right and continue previous algorithm, if no, we might exit. It still can be log(m), log(n). BTW, I like your graph very much – SecureFish Jul 6 '11 at 22:06
  • Very nice. But you should edit your answer to start in the "bottom left" rather than "bottom right"... I wonder if this approach is optimal? Even if you used a binary search throughout this algorithm, you might wind up just "walking the diagonal", so it would not help the worst-case performance. – Nemo Jul 6 '11 at 22:14
  • @Nemo, corrected the typo, thanks. This approach is probably not optimal, but the worst case is O(n+m). The OP's question contains an algorithm that he claims is faster, but is incorrect according to you. Probably some additional binary searches could improve performance. – Patrick Jul 7 '11 at 6:25
  • For optimization, i think that you can start from top-left corner also. Also, a better way to visualize this would be, by assuming that top-left is a root of BST and left and right children are down and right elements, then you can continue this way. – Priyank Bhatnagar Jul 7 '11 at 8:38
  • 1
    @logic_max: That does not work because the "left and right children" can be in either order. Again, the elements along the diagonal are totally unsorted. So I believe the optimal algorithm requires at least O(length of diagonal). – Nemo Jul 7 '11 at 17:16

Your algorithm may be O(log m + log n), but it also gives the wrong answer.

Suppose you search for "4" in the following matrix (where the upper-left is row=0, col=0):

0 1 4
1 2 5
2 3 6

Your algorithm starts by looking at the 2 in the center. Since 4 is greater than 2, you proceed to search the same row (not there), same column (not there), and the lower-right corner (not there). Whoops.

The constraint that each row and column is sorted is actually pretty weak. In particular, the elements along the diagonal could be in any order.

I think the correct approach is to do a binary search on the first and last column to narrow down a range of possible rows. Then do binary search on the first and last of those rows to narrow down the possible columns. And so forth.

Not sure how to analyze the performance of this one...

  • very good test case. – SecureFish Jul 6 '11 at 21:53

Here's what I would try. Given an m by n matrix A, compare the value X with the entry A(m/2,n/2) (use floors if necessary).

If A(m/2,n/2) == X, done.

If A(m/2,n/2) < X, then there are 3 smaller matrices to check:

A(1:m/2, 1:n/2) 
A(1:m/2, n/2+1:n) 
A(m/2+1:m, 1:n/2) 

If A(m/2,n/2) > X, , then there are 3 smaller matrices to check:

A(m/2:m, n/2:n) 
A(1:m/2, n/2+1:n) 
A(m/2+1:m, 1:n/2) 

You can eliminate two of them (not always) by comparing the value to the smallest value in the corresponding matrix (the upper left value). Then you recursively try to find the value in each of the remaining matrices.

The complexity of this is approximately O((n*m)^0.8).

A row and column sorted matrix is a special case of a Young tableau. I did a google search for searching a Young tableau and found this article which gives 3 nice approaches (the first (and worst) of which is the one I described above).

  • (off-topic) Hey @PengOne, did you ever take a look at this question? It seemed like the kind of thing you might be able to figure out :-). – Nemo Jul 6 '11 at 22:32
  • @Nemo: Interesting. Thanks! – PengOne Jul 6 '11 at 22:51

For a comparison based algorithm, O(lg(m) + lg(n)) queries is optimal.


For a comparison based query, each query can only have two results: true or false. An obvious extension of this is that for N queries you can have at most 2N results. Therefore, using N queries, you can only locate elements in a matrix with at most 2N elements.

How many queries then are required to search an m x n matrix? Just solve for N.

2N = mn
lg(2N) = lg(mn)
N = lg(m) + lg(n)

Therefore lg(m) + lg(n) queries is optimal.

Non-comparison based queries

That proof is conclusive, but only for comparison based queries. If you query the matrix in a way that doesn't involve comparisons then you can get near-constant time if you know the distribution of values. I won't give you an algorithm, but I would suggest looking at Radix sort as it contains the kind of non-comparison based techniques that are required to beat the lg(m) + lg(n) lower bound.


Reading the previous comments I came up with this algorithm. It basically suppose that by starting in the upper-right corner, the matrix can be used as a BST with some "loops" (we don't care about this loops).

1 4 9
5 6 10

    /  \
   4   10
  / \  /
 1   6
  \ /

This algorithm is the same as searching in a BST and is really easy to understand. The worst case run time is O( n + m ).

public static boolean search( int[][] matrix, int value )
    int rows = matrix.length;
    int columns = matrix[0].length;

    int i = 0;
    int j = columns - 1;

    while( i < rows
           && j >= 0 )
        if( matrix[i][j] == value )
            System.out.println( "Found at " + i + " " + j );
            return true;

        if( matrix[i][j] < value )

    return false;
  • Doesn't work for me :( – Mahib May 8 '15 at 19:15
boolean FindElem(int[][] mat, int elem, int M, int N) {
 int row = 0;
 int col = N-1;
 while (row < M && col >= 0) {
   if (mat[row][col] == elem) {
     return true;
   } else if (mat[row][col] > elem) {
   } else {
   return false;

I believe that your algorithm does not have the time bounds that you believe that it does.

To see this, for simplicity let's assume that your grid is an n x n square (let's call this size m). If I can derive a different time bound than O(log n) in this case, I can argue that what you have should not be correct.

In particular, notice that in the worst case you make three recursive calls to problems that are of size (n / 2) x (n / 2) = m / 4. This means that we have the recurrence

T(1) = 1
T(m) = 3T(m / 4) + O(1)

Using the Master Theorem, the runtime for this function would be O(mlog43) = O(n2 log43) = O(n log49) ≈ O(n1.5849625). This is ω(log n + log m); that is, it's asymptotically strictly greater.

As many other people have posted, there are several well-known algorithms that run in O(m + n) that are based by walking one step in the right direction at each step. Consequently, correctness aside, I would not advise using the algorithm you've posted.


Given elements in 2d array(be a[n][m]) are increasing horizontally and vertically . So for the given question we need to find the index of the element first. So if we can find the element in quicker way then we can optimize the solution . The question is how do we find it in efficient way. One approach is take the middle element of the matrix and check given element with it

if given element is lesser than middle element then our solution lies in matrix a[0][0] to a[n/2][m/2] because all elements to right and below are greater than middle (since given element is less than middle element) so we have reduced our search space from a[n][m] to a[n/2][m/2] which is one fourth of original size.

if given element is greater than middle element then our solution doesnt lies in matrices a[0][0] to a[n/2][m/2] because all elements to left and above are lesser than middle (since given element is greater than middle element) so our search space is total array minus a[0][0] to a[n/2][m/2] which is three-fourth of original size. Total array minus a[0][0] to a[n/2][m/2] means ,there will be three recursive call with array index

--------->a[0][m/2](start index) to a[n/2][m](end index)  
--------->a[n/2][0](start index) to a[n][m/2](end index)
--------->a[n/2][m/2](start index) to a[n][m](end index)

Now recursively call the same function based on our search space.

Time complexity of our function will as follows . NOTE: In time function n represents total number of element but not no of rows as mentioned .n=(no_of_rows)*(no_of_columns)

                _________________T(n/4)  if given element is less than middle of the array.
T(n)==========------------------- 1 if n=1 (if element found)
               \_________________3T(n/4) if given element is greater than middle element of array

so out time function will

T(n)=3T(n/4) or T(n)=T(n/4)

In worst case T(n)=3T(n/4)
               T(n)=3power(i)T(n/(4)poweri)     equation------> (1) 

But T(1)=1 (guessing given elemet is found in array)

so  n/(4power(i))=1
====> n=2power(2*i)
====> n=2power(2*i)
Talking log to base 2 on both sides (log[n])/2=i ====> i=log(sqrt(n))

substituting equation 1 we get

T(n)∈ θ( nlog sqrt(3) )..

To my knowledge this is the algorithm that takes minimum number of comparisons.


JavaScript solution:

//start from the top right corner
//if value = el, element is found
//if value < el, move to the next row, element can't be in that row since row is sorted
//if value > el, move to the previous column, element can't be in that column since column is sorted

function find(matrix, el) {

  var row = 0; //first row
  var col = matrix[0].length - 1; //last column

  while (row < matrix.length && col >= 0) {
    if (matrix[row][col] === el) { //element is found
      return true;
    } else if (matrix[row][col] < el) {
      row++; //move to the next row
    } else {
      col--; //move to the previous column

  return false;


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