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# Method to split a matrix into blocks of the small matrix

I have a problem and would like to know if anyone could offer an ideal solution.

Basically (small data) but, if I have a matrix like this:

``````     0 1 0 0
1 1 1 0
0 0 0 0
1 1 0 0
``````

I then need to split this matrix into blocks that are of the same size as the second matrix, in this case 2x2:

``````0 1
1 1
``````

I know it has something to do with the offsetX/Y values and these change depending on the size of the (small) matrix, I just don't know the calculation to calculate such results. I'm going to be passing the offsetX/Y to a function (with the vector) so I can calculate the sum of the particular block.

Thanks

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what do you want to do if its a 5x5 matrix? – chikuba Apr 17 '12 at 22:55
Hey - It's still a 1D matrix, so it could only split into blocks that are of simular size to the small matrix, in this case, into 2x2 matrices.. I was thinking something like this: const int ROW_BOUNDS = matrix1.size() - matrix2.size();const int COL_BOUNDS = matrix1.size() - matrix2.size(); if this makes any sense? – Phorce Apr 17 '12 at 22:59
just mean, what do you do with the reaming column and line? – chikuba Apr 17 '12 at 23:03
I don't fully understand what's supposed to be hard about your problem. Are you saying you want to try all possible sub-matrix sizes? or is it that your initial matrix is stored as a 1D array and that's why you don't know how to do bounds checking. – Jean-Bernard Pellerin Apr 17 '12 at 23:03

Mathematically you can split the matrix with a curve for example a z curve or a peano curve. That way you would also reduce the dimensional complexity. A z curve uses 4 quads to split a plane and resemble a quadtree.

Edit: I just learned that it's z-order curve and not z curve: http://en.wikipedia.org/wiki/Z-order_curve. A z curve is something 3d in bionformatics http://en.wikipedia.org/wiki/Z_curve??? LOL! I'm not a bioinformaticians nor am I in wikipedia but that sound to me like nonsense. A z-ordered curve can also cover a 3d area. Maybe wikipedia wants to say this? Here is a big picture of a 3d z-order curve http://en.wikipedia.org/wiki/File:Lebesgue-3d-step3.png. It's even on the wikipedia article?????

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Um... what? What does any of that have to do with an array slicing operation? – Li-aung Yip Apr 18 '12 at 1:16
@Li-aung Yip: Are you suggesting me drinking a beer? – Betterdev Apr 18 '12 at 8:40
``````import std.stdio : writeln;
void main(string[] args)
{
int m=4, n=4;
int[][] matrix = [[0, 1, 0, 0], [1, 1, 1, 0], [0, 0, 0, 0], [1, 1, 0, 0]];
int mm=2, nn=2;
int sum;
for(int x=0; x<m; x+=mm)
for(int y=0; y<n; y+=nn)
sum += summation(matrix, x, y, mm, nn);
writeln(sum);
}
int summation(int[][] matrix, int offsetx, int offsety, int m, int n)
{
int sum;
for(int x=offsetx; x<offsetx+m; x++)
for(int y=offsety; y<offsety+n; y++)
sum += matrix[x][y];
return sum;
}
``````

Unless you're looking for something else? your question is vague when it comes to explaining what you're asking for.

(this compiles in D, since it's the only thing I have access to atm, use it as a guide to convert to C++)

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You're right- it's absolutely nothing like C++. – Puppy Apr 17 '12 at 23:03
figured as much, but all he needs is the pseudo-code – Jean-Bernard Pellerin Apr 17 '12 at 23:05
Then put something that is remotely like pseudocode, instead of just "The most horrific something-like-C you could possibly imagine". – Puppy Apr 17 '12 at 23:08
That is remotely like pseudocode. D is actually a really interesting language. Change the import to #include <iostream>, switch the main declaration, change the writeln(x) to std::cout << x << std::endl;, change the variable int[][] matrix = ... to std::array<std::array<int, 4>, 4> = {{0, 1, 0, 0}, {1, 1, 1, 0}, {0, 0, 0, 0}, {1, 1, 0, 0}};, and you have valid c++ – Robert Mason Apr 18 '12 at 0:24
oh, and the type of summation's first argument. – Robert Mason Apr 18 '12 at 0:24

In order to split your matrix in situ (that is, without copying it), you want a representation that can handle both the original and the split pieces -- which will make it easier to define recursive algorithms, and so forth:

``````template <class elt> class MatRef {
elt* m_data;
unsigned m_rows, m_cols;
unsigned m_step;

unsigned index(unsigned row, unsigned col)
{
assert(row < m_rows && col < m_cols);
return m_step * row + col;
}

public: // access
elt& operator() (unsigned row, unsigned col)
{
return m_data[index(row,col)];
}

public: // constructors
MatRef(unsigned rows, unsigned cols, elt* backing)  // original matrix
: m_rows(rows)
, m_cols(cols)
, m_step(cols)
, m_data(backing)
{}
MatRef(unsigned start_row, unsigned start_col,
unsigned rows, unsigned cols, MatRef &orig) // sub-matrix
: m_rows(rows)
, m_cols(cols)
, m_step(orig.m_step)
, m_data(orig.m_data + orig.index(start_row, start_col))
{
assert(start_row+rows <= orig.m_rows && start_col+cols <= orig.m_cols);
}
};
``````

The original matrix constructor assumes its `backing` argument points to an array of data elements which is at least `rows*cols` long, for storing the matrix data. The dimensions of the matrix are defined by data members `m_rows` and `m_cols`.

Data member `m_step` indicates how many data elements there are from the start of one row to the start of the next. For the original matrix, this is the same as `m_cols`. Note that the `m_cols` of a sub-matrix may be smaller than that of the original matrix it refers to -- that's how a sub-matrix "skips" elements of the original matrix that are not part of the sub-matrix. For this to work properly, `m_step` will necessarily be the same as in the original matrix.

Regardless of whether the matrix is skipping elements, data member `m_data` always points to the first element of the matrix. The `assert()` in the sub-matrix constructor ensures that each new sub-matrix fits inside the matrix it is derived from.

I'm not sure if this counts as an "interesting algorithm", but it is an efficient and convenient way to define and access submatrices.

-
The "step" is sometimes called the "stride". Also this representation is understood by BLAS and LAPACK, which can be useful if you plan to do non trivial linear algebra. – Alexandre C. Apr 23 '12 at 22:20