# Calculate the sum of elements in a matrix efficiently

In an interview I was asked if I was given an n*m matrix how to calculate the sum of the values in a given sub-matrix (defined by top-left, bottom-right coordinates).

I was told I could pre-process the matrix.

I was told the matrix could be massive and so could the sub-matrix so the algo had to be efficient. I stumbled a bit and wasn't told the best answer.

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is the matrix known to be sparse? –  Carl Feb 17 '10 at 1:42
@Moron a quadtree where each node contains the sum of its children would support relatively easy update, but not nearly as easy summing as the simple answer from Alan. –  phkahler Feb 17 '10 at 1:59
@Moron: The question begins with "In an interview I was asked". So no, not homework, unless there exist situations where homework somehow consists of interviews... –  ShreevatsaR Feb 17 '10 at 2:01
@ShreevatsaR: Oops! :) –  Aryabhatta Feb 17 '10 at 2:13
Matrix can be sparse or dense, he mentioned that it needs work for any case. –  slippytoad Feb 17 '10 at 3:02

This is what Summed Area Tables are for. http://en.wikipedia.org/wiki/Summed_area_table

Your "preprocessing" step is to build a new matrix of the same size, where each entry is the sum of the sub-matrix to the upper-left of that entry. Any arbitrary sub-matrix sum can be calculated by looking up and mixing only 4 entries in the SAT.

EDIT: Here's an example.

For the initial matrix

``````0 1 4
2 3 2
1 2 7
``````

The SAT is

``````0 1 5
2 6 12
3 9 22
``````

The SAT is obtained using S(x,y) = a(x,y) + S(x-1,y) + S(x,y-1) - S(x-1,y-1),

where S is the SAT matrix and a is the initial matrix .

If you want the sum of the lower-right 2x2 sub-matrix, the answer would be 22 + 0 - 3 - 5 = 14. Which is obviously the same as 3 + 2 + 2 + 7. Regardless of the size of the matrix, the sum of a sub matrix can be found in 4 lookups and 3 arithmetic ops. Building the SAT is O(n), similarly requiring only 4 lookups and 3 math ops per cell.

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@phkahler: Disagree with the remark about trivia. –  Aryabhatta Feb 17 '10 at 2:17
Thanks Alan! I've never heard of a Summed Area Table and I've been programming for 18 years. I slept/drank through University though (my bad). –  slippytoad Feb 17 '10 at 3:04
I have been using this idea for several years and never heard of the name "summed area tables" either – the poorly written Wikipedia article suggests that it's a name specific to the computer vision/graphics field. The idea itself is fairly natural to someone who's familiar with dynamic programming, though – too natural to deserve a name, perhaps. –  ShreevatsaR Feb 17 '10 at 3:45
See my updated answer if you don't believe this works. This is pretty simple intro-to-algorithms stuff here. –  Alan Feb 18 '10 at 1:44
wow. this is why i visit StackOverflow everyday. –  moogs Feb 18 '10 at 2:05

Create a new matrix where entry `(i,j)` is the sum of elements in the original matrix that have lower or equal `i` and `j`. Then, to find the sum of the elements in the submatrix, you can just use a constant number of basic operations using the corners of the submatrix of your sum matrix.

In particular, find the corners top_left, bottom_left, top_right and bottom_right of your sum matrix, where the first three are just outside the submatrix and bottom_right is just inside. Then, your sum will be

``````bottom_right + top_left - bottom_left - bottom_right
``````
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In that case, my misunderstanding lies with what is defined as "preprocessing". You still require the same number of additions, no matter what. I understand when this approach can be useful, but the question provided no further information about the problem context. –  Steve Tjoa Feb 17 '10 at 1:54
There wasn't really a context, just a requirement that the addition be faster than simply looping and adding. Preprocessing was suggested but not to the extent that extreme amounts of memory or storage are used (e.g. pre-summing every possible matrix and storing it in an x/y index). –  slippytoad Feb 17 '10 at 3:17
Hi Peter, shouldn't the last 'botton-right' be 'top-left' ? –  pranay Aug 23 '12 at 2:08

This should work. You always have to go through each element in the submatrix to do the addition and this is the simplest way.

*note that the following code may not compile but it's right in pseudocode

``````
struct Coords{
int x,y;
}

int SumSubMatrix(Coords topleft, Coords bottomright, int** matrix){
int localsum = 0;
for( int i = topleft.x; i <= bottomright.x; i++ ){
for(int j = topleft.y; j <= bottomright.y; j++){
localsum += matrix[i][j];
}
}
return localsum;
}
```
```

Edit: An alternative pre-processing method is to create another matrix from the original containing the row or column sums. Here's an example: Original:

```0 1 4
2 3 2
1 2 7
```

Row Matrix:

```0 1 5
2 5 7
1 3 10
```

Column Matrix:

```0 1 4
2 4 6
3 6 13
```

Now, just take the endpoint x values and subtract the start point values, like so (for rows based):

``````
for( int i = topleft.y; i >= bottomright.y; i++ ){
localsum += matrix2[bottomright.x][i] - matrix2[topleft.x][i];
}
```
```

Now, it's either O( n ) or O( m )

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Which matrix is matrix2? –  slippytoad Feb 17 '10 at 3:22