# Most efficient way to search a sorted matrix?

I have an assignment to write an algorithm (not in any particular language, just pseudo-code) that receives a matrix [size: M x N] that is sorted in a way that all of it's rows are sorted and all of it's columns are sorted individually, and finds a certain value within this matrix. I need to write the most time-efficient algorithm I can think of.

The matrix looks something like:

``````1  3  5
4  6  8
7  9 10
``````

My idea is to start at the first row and last column and simply check the value, if it's bigger go down and if it's smaller than go left and keep doing so until the value is found or until the indexes are out of bounds (in case the value does not exist). This algorithm works at linear complexity O(m+n). I've been told that it's possible to do so with a logarithmic complexity. Is it possible? and if so, how?

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could you possibly share an example of data? Surely you were given a sample. –  jcolebrand Nov 9 '10 at 20:25
"all of its rows are sorted and all of its columns are sorted individually": What does this mean? –  TonyK Nov 9 '10 at 20:32
the values in every row are sorted and the values in every column are sorted –  Bob Nov 9 '10 at 20:38
I think he means that the value in the top left (1,1) will be the smallest, and the value at the bottom right (n,m) will be the largest. The rows and columns are both sorted. –  Sagar Nov 9 '10 at 20:40
@sagar but that's not the example given by the professor. otherwise he had the fastest method above (check the end of the row first, then proceed) additionally, checking the end of the middlest row first would be faster, a bit of a binary search. –  jcolebrand Nov 9 '10 at 20:42

``````a ..... b ..... c
. .     . .     .
.   1   .   2   .
.     . .     . .
d ..... e ..... f
. .     . .     .
.   3   .   4   .
.     . .     . .
g ..... h ..... i
``````

and has following properties:

``````a,c,g < i
a,b,d < e
b,c,e < f
d,e,g < h
e,f,h < i
``````

So value in lowest-rigth most corner (eg. `i`) is always the biggest in whole matrix and this property is recursive if you divide matrix into 4 equal pieces.

So we could try to use binary search:

1. probe for value,
2. divide into pieces,
3. choose correct piece (somehow),
4. goto 1 with new piece.

Hence algorithm could look like this:

``````input: X - value to be searched
until found
divide matrix into 4 equal pieces
get e,f,h,i as shown on picture
if (e or f or h or i) equals X then
return found
if X < e then quarter := 1
if X < f then quarter := 2
if X < h then quarter := 3
if X < i then quarter := 4
if no quarter assigned then
return not_found
make smaller matrix from chosen quarter
``````

This looks for me like a O(log n) where n is number of elements in matrix. It is kind of binary search but in two dimensions. I cannot prove it formally but resembles typical binary search.

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The only problem with this is that the final matrix is of MxN size, and it doesn't look (at first glance) as tho this method scales that well. However, you may be on to something, maybe the folks at math.stackexchange.com can help you flush it out? –  jcolebrand Nov 9 '10 at 21:50
"if X < f then quarter := 2" - doesn't follow, unfortunately. Quarter 3 can contain values which are larger than e, but smaller than f. For instance, the 7 in the example input. –  Steve Jessop Nov 9 '10 at 22:13
@Steve Right ... My fault. I need to rethink... –  Michal Sznajder Nov 9 '10 at 22:43
It would be quite surprising if this was O(log n) when that is the optimal complexity for searching a sorted one-dimensional array, which is what we would have if the entire MxN matrix was sorted with all elements on line i smaller than all elements on i+1 for all lines. The complexity has to be worse than that. –  Martin May 5 '14 at 12:33

and that's how the sample input looks? Sorted by diagonals? That's an interesting sort, to be sure.

Since the following row may have a value that's lower than any value on this row, you can't assume anything in particular about a given row of data.

I would (if asked to do this over a large input) read the matrix into a list-struct that took the data as one pair of a tuple, and the mxn coord as the part of the tuple, and then quicksort the matrix once, then find it by value.

Alternately, if the value of each individual location is unique, toss the MxN data into a dictionary keyed on the value, then jump to the dictionary entry of the MxN based on the key of the input (or the hash of the key of the input).

EDIT:

Notice that the answer I give above is valid if you're going to look through the matrix more than once. If you only need to parse it once, then this is as fast as you can do it:

``````for (int i = 0; i<M; i++)
for (int j=0; j<N; j++)
if (mat[i][j] == value) return tuple(i,j);
``````

Apparently my comment on the question should go down here too :|

@sagar but that's not the example given by the professor. otherwise he had the fastest method above (check the end of the row first, then proceed) additionally, checking the end of the middlest row first would be faster, a bit of a binary search.

Checking the end of each row (and starting on the end of the middle row) to find a number higher than the checked for number on an in memory array would be fastest, then doing a binary search on each matching row till you find it.

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well the diagonals do appear to be sorted, didn't notice that before. but the sort is not by diagonals, it is simpler. every row by itself is sorted and every column by itself is sorted. but like you said reading a row doesn't give any information about the next row. –  Bob Nov 9 '10 at 20:38
nor a column about the next column. You can make no assumptions about the speed of finding an element, without iterating over every one. I'm trying to look for the fastest possible method of finding a value. An O(n) seems like the fastest, but if you're going to do what I suggested, that's only valid if you're looking for lots of the values. Otherwise, if you just parse it once, then it's faster to just for loop it twice on the MxN with an early abort on found. –  jcolebrand Nov 9 '10 at 20:39
but as soon as you need to find two values, mine way given in the answer is faster than a double for loop –  jcolebrand Nov 9 '10 at 20:40
that's also what I think. I think that O(n) is good enough in this case, I can't see any way to find it with a better complexity without adding another data structure. and i also do not need to search twice, in the assignment it states that if the value appears more than once I still need to find only one instance of it. –  Bob Nov 9 '10 at 20:42
EDITED my post. –  jcolebrand Nov 9 '10 at 20:42

in log M you can get a range of rows able to contain the target (binary search on the first value of rows, binary search on last value of rows, keep only those rows whose first <= target and last >= target) two binary searches is still O(log M)
then in O(log N) you can explore each of these rows, with again, a binary search!

that makes it O(logM x logN)

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my answer already has that, and he already suggested it. –  jcolebrand Nov 9 '10 at 20:57
You can do one binary search, just keep the lower pointer on the left side, and the upper pointer on the right side. Everything between the two at the end is the set of rows to explore. –  Kevin Stricker Nov 9 '10 at 20:58
to simplify math let's assume that the size is NxN. now let's take a bad case: let's say that all values in the first row are smaller that 10 and all values in the last row are bigger than 100 and i'm looking for a target=50. in this case i can't eliminate any row so I still have to binary-search n rows and that will give me O(n*logn) –  Bob Nov 9 '10 at 21:11
@Bob ~ Yeah, we know, but you would then be starting the binary search from the last row to the first. You do know binary searches right? en.wikipedia.org/wiki/Binary_search_algorithm –  jcolebrand Nov 9 '10 at 21:17
I second Bob, this answer is incorrect and deserves a down-vote. Worse case complexity is still O(M.Log(N)), the first search could very well return the whole set of rows. –  Rabih Kodeih Aug 13 '13 at 15:36
``````public static boolean find(int a[][],int rows,int cols,int x){
int m=0;
int n=cols-1;
while(m<rows&&n>=0){
if(a[m][n]==x)
return1;
else if(a[m][n]>x)
n--;
else m++;
}

}
``````
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what about getting the diagonal out, then binary search over the diagonal, start bottom right check if it is above, if yes take the diagonal array position as the column it is in, if not then check if it is below. each time running a binary search on the column once you have a hit on the diagonal (using the array position of the diagonal as the column index). I think this is what was stated by @user942640

you could get the running time of the above and when required (at some point) swap the algo to do a binary search on the initial diagonal array (this is taking into consideration its n * n elements and getting x or y length is O(1) as x.length = y.length. even on a million * million binary search the diagonal if it is less then half step back up the diagonal, if it is not less then binary search back towards where you where (this is a slight change to the algo when doing a binary search along the diagonal). I think the diagonal is better than the binary search down the rows, Im just to tired at the moment to look at the maths :)

by the way I believe running time is slightly different to analysis which you would describe in terms of best/worst/avg case, and time against memory size etc. so the question would be better stated as in 'what is the best running time in worst case analysis', because in best case you could do a brute linear scan and the item could be in the first position and this would be a better 'running time' than binary search...

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Here is a lower bound of n. Start with an unsorted array A of length n. Construct a new matrix M according to the following rule: the secondary diagonal contains the array A, everything above it is minus infinity, everything below it is plus infinity. The rows and columns are sorted, and looking for an entry in M is the same as looking for an entry in A.

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This is in the vein of Michal's answer (from which I will steal the nice graphic).

Matrix:

``````  min ..... b ..... c
.       .       .
.  II   .   I   .
.       .       .
d .... mid .... f
.       .       .
.  III  .   IV  .
.       .       .
g ..... h ..... max
``````

Min and max are the smallest and largest values, respectively. "mid" is not necessarily the average/median/whatever value.

We know that the value at mid is >= all values in quadrant II, and <= all values in quadrant IV. We cannot make such claims for quadrants I and III. If we recurse, we can eliminate one quadrant at each level.

Thus, if the target value is less than mid, we must search quadrants I, II, and III. If the target value is greater than mid, we must search quadrants I, III, and IV.

The space reduces to 3/4 its previous at each step:

n * (3/4)x = 1

n = (4/3)x

x = log4/3(n)

Logarithms differ by a constant factor, so this is O(log(n)).

``````find(min, max, target)
if min is max
if target == min
return min
else
else if target < min or target > max
else
set mid to average of min and max
if target == mid
return mid
else
find(b, f, target), return if found
find(d, h, target), return if found

if target < mid
return find(min, mid, target)
else
return find(mid, max, target)
``````
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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) {

//some error checking
if (!matrix[0] || !matrix[0].length){
return false;
}
if (!el || isNaN(el)){
return false;
}

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;

}
``````
-

Sorry, this is wrong. Imagine a 4X4 matrix where the first row and first column both look like `1 2 3 10`, and you're requested to look for 7. You would say that it's on the 3rd row and 3rd col, but this isn't so. 7 could be at `(2, 2)` and all the rest of the cells can be 999... –  ihadanny Apr 13 at 16:35