Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

I have to find a diagonal difference in a matrix represented as 2d array and the function prototype is

int diagonal_diff(int x[512][512])

I have to use a 2d array, and the data is 512x512. This is tested on a SPARC machine: my current timing is 6ms but I need to be under 2ms.

Sample data:


The difference is:

|4-2| + |5-6| + |9-5| + |9-9| + |4-8| + |3-8| = 2 + 1 + 4 + 0 + 4 + 5 = 16

In order to do that, I use the following algorithm:

int i,j,result=0;
for(i=0; i<4; i++)
    for(j=0; j<4; j++)

return result;

But this algorithm keeps accessing the column, row, column, row, etc which make inefficient use of cache.

Is there a way to improve my function?

share|improve this question
Did you benchmark or profile this? How big are the real matrices? Any 4 by 4 matrix will fit in the cache and it's irrelevant what order you access the items in. – André Caron Oct 12 '11 at 2:46
Even if you do this 50,000,000 times per second, not even a low-end modern CPU will break a sweat. Even the function call to abs() will get optimized away as intrinsic by most compilers (including GCC and VC++.) – Jonathan Grynspan Oct 12 '11 at 2:49
the size of array is 512x512 and I have to use a 2D array. the interface specifications is fixed, I just have to fill in the diagonal_diff(int x[512][512], int y[512][512]) – Christoper Hans Oct 12 '11 at 3:12
the function is tested on a SPARC and my current timimng is 6ms, i need to be under 2ms – Christoper Hans Oct 12 '11 at 3:16
Are the aggressive compiler optimizations -- e.g. "-O6" -- being used? – user166390 Oct 12 '11 at 3:27

3 Answers 3

up vote 7 down vote accepted

EDIT: Why is a block oriented approach faster? We are taking advantage of the CPU's data cache by ensuring that whether we iterate over a block by row or by column, we guarantee that the entire block fits into the cache.

For example, if you have a cache line of 32-bytes and an int is 4 bytes, you can fit a 8x8 int matrix into 8 cache lines. Assuming you have a big enough data cache, you can iterate over that matrix either by row or by column and be guaranteed that you do not thrash the cache. Another way to think about it is if your matrix fits in the cache, you can traverse it any way you want.

If you have a matrix that is much bigger, say 512x512, then you need to tune your matrix traversal such that you don't thrash the cache. For example, if you traverse the matrix in the opposite order of the layout of the matrix, you will almost always miss the cache on every element you visit.

A block oriented approach ensures that you only have a cache miss for data you will eventually visit before the CPU has to flush that cache line. In other words, a block oriented approach tuned to the cache line size will ensure you don't thrash the cache.

So, if you are trying to optimize for the cache line size of the machine you are running on, you can iterate over the matrix in block form and ensure you only visit each matrix element once:

int sum_diagonal_difference(int array[512][512], int block_size)
    int i,j, block_i, block_j,result=0;

     // sum diagonal blocks
    for (block_i= 0; block_i<512; block_i+= block_size)
        for (block_j= block_i + block_size; block_j<512; block_j+= block_size)
            for(i=0; i<block_size; i++)
                for(j=0; j<block_size; j++)
                    result+=abs(array[block_i + i][block_j + j]-array[block_j + j][block_i + i]);

    result+= result;

     // sum diagonal
    for (int block_offset= 0; block_offset<512; block_offset+= block_size)
        for (i= 0; i<block_size; ++i)
            for (j= i+1; j<block_size; ++j)
                int value= abs(array[block_offset + i][block_offset + j]-array[block_offset + j][block_offset + i]);
                result+= value + value;

    return result;

You should experiment with various values for block_size. On my machine, 8 lead to the biggest speed up (2.5x) compared to a block_size of 1 (and ~5x compared to the original iteration over the entire matrix). The block_size should ideally be cache_line_size_in_bytes/sizeof(int).

share|improve this answer
On my particular machine, this runs 50% faster than the non-cache aware (Blastfurnace's) version with blocksize = 8, which is the fastest I can get. Also comes in at just under half a millisecond to execute. – Mike Bantegui Oct 12 '11 at 5:35
this method works! thanks a lot ! there are few results error, caused by: result+=result; in line 12 and: result+= value+value; in line 22. I changed it to use single result rather than double (which is what @MSN did) and it works perfectly. – Christoper Hans Oct 12 '11 at 9:16
On my test, block_size = 16 is the fastest I can get. The method goes ~80% faster than original one. – Christoper Hans Oct 12 '11 at 9:28
@ChristoperHans, are you saying there is overflow (yes) or that the result is incorrect? I tested this locally with the naive version you posted and they came out with the same value. – MSN Oct 12 '11 at 15:37
Mathematically, MSN's solution produces the correct result by counting each pair twice. Blastfurnace's solution actually produces a result that's exactly half of what the naive solution should output. – Mike Bantegui Oct 13 '11 at 2:45

If you have a good vector/matrix library like intel MKL, also try the vectorized way.

very simple in matlab: result = sum(sum(abs(x-x')));

I reproduced Hans's method and MSN's method in matlab too, and the results are:

Elapsed time is 0.211480 seconds.  (Hans)

Elapsed time is 0.009172 seconds.  (MSN)

Elapsed time is 0.002193 seconds.  (Mine)
share|improve this answer

With one minor change you can have your loops only operate on the desired indices. I just changed the j loop initialization.

int i, j, result = 0;
for (i = 0; i < 4; ++i) {
    for (j = i + 1; j < 4; ++j) {
        result += abs(array[i][j] - array[j][i]);
share|improve this answer
I did that but that doesn't improve much.I also try to copy the column to another 1-dimenstional array before the comparison. timed about 4ms – Christoper Hans Oct 12 '11 at 3:44
the i != j is unnecessary here. Because you initialize j = i + 1, j can never be equal to i. – Mike Bantegui Oct 12 '11 at 4:51
@Mike Bantegui, you are correct and I feel a little bit foolish. Thanks. – Blastfurnace Oct 12 '11 at 5:08

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.