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I am doing a project in which I need to check whether a bool array 'vector' is linearly independent of the columns of the 'matrix'. In MATLAB it can be done by finding the rank of the augmented matrix [matrix vector] using the command rank(gf([matrix vector])). 'gf' because the matrix is Boolean. But how to do it in C++. This is what I have tried:

#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "engine.h"
#define  BUFSIZE 256

int main()
{
Engine *ep;
mxArray *M = NULL, *V = NULL, *result = NULL;
bool matrix[4][4]={1,1,1,0,0,1,1,0,0,1,0,0}, vector[4][1]={1,1,1,1};
double *rank;

if (!(ep = engOpen("\0"))) {
    fprintf(stderr, "\nCan't start MATLAB engine\n");
    return EXIT_FAILURE;
}

V = mxCreateDoubleMatrix(4, 1, mxREAL);
M = mxCreateDoubleMatrix(4, 4, mxREAL);
memcpy((void *)mxGetPr(V), (void *)vector, sizeof(vector));
memcpy((void *)mxGetPr(M), (void *)matrix, sizeof(matrix));
engPutVariable(ep, "V", V);
engPutVariable(ep, "M", M);

engEvalString(ep, "R = rank(gf([M V]));");
result = engGetVariable(ep, "R");
engClose(ep);
rank = mxGetPr(result);
printf("%f", *rank);

printf("Done with LI\n");
mxDestroyArray(M);
mxDestroyArray(V);
mxDestroyArray(result);
engEvalString(ep, "close;");
}

The above code works and I am getting the desired results. But it runs very slow. Can anyone suggest me a way to make it fast? Or suggest some other way to find the rank of a boolean matrix. Some libraries are out there, but they seem to have functions only for int or double matrices.

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Running Matlab from C++ just for this appears to be overkill to me. I'd suggest to use a library that you can directly call from C++. Matlab is actually implemented on top of a pile of C and FORTRAN libraries, I'm pretty sure if you look at those you'll find what you need. Matlab's rank is based on svd, which in turn appears to be based on QR-factorization. – Concerning boolean: A bool is just a value-restricted int, isn't it? So you could use an int-matrix algorithm. –  A. Donda Oct 8 '13 at 18:46
    
No, a bool isn't just a value-restricted int. The operations are entirely different. The operations involving int are different from that of those involving bool. Therefore for finding the rank of int matrix we use rank(matrix), while for finding the rank of a Boolean matrix we use rank(gf(matrix)) in MATLAB. "I'm pretty sure if you look at those you'll find what you need." Could you please be a bit clear on what does "those" refer to? Does it mean the C implementation of rank function? –  Sonu Kr Mishra Oct 8 '13 at 19:48
    
For example: If you consider M=[1 0 1; 0 1 1; 1 1 0] as int, then its rank is 3, while if you consider it as bool, then its rank is 2. –  Sonu Kr Mishra Oct 8 '13 at 19:55
    
Ok, I missed the part about gf before, and I have to say I don't know what a Galois field is. I suspect gf() involves more than a type cast, and I guess the rank of a Galois field is conceptually related to but different from the normal notion of rank of matrix. Anyway, gf/rank appears to be implemented directly in Matlab code, just type edit gf/rank in the command window. Doesn't look too complicated, maybe you can translate this into C++ yourself? –  A. Donda Oct 8 '13 at 20:05
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2 Answers 2

up vote 1 down vote accepted

You can find the rank of the Boolean Matrix by finding rank in the Galois Field of 2 (as you are doing in your Matlab code), which is essentially mod 2 arithmetic.

The code below finds the rank of the Boolean Matrix using the same idea by using Gauss Elimination with partial pivoting.

#include <iostream>
#include <vector>

using namespace std;

class BooleanMatrix{
    vector< vector<bool> > mat; //boolean matrix
    int n, m;           //size of matrix nxm
    int rank;           //rank of the matrix

    public:

    /*Constructor
     * Required Parameters:
     * M ==> boolean matrix
     * n ==> number of rows
     * m ==> number of columns
     */
    template <size_t size_m>
    BooleanMatrix(bool M[][size_m], int n, int m){
        this -> n = n;
        this -> m = m;
        for (int i = 0; i < n; i++){
            vector<bool> row(m);
            for (int j = 0; j < m; j++) row[j] = M[i][j];
            mat.push_back(row);         
        }
        gaussElimination();
    }

    /* Does Gauss Elimination with partial pivoting on the matrix */
     void gaussElimination(){
        rank = n;
        for (int i = 0; i < n; i++){
            if (!mat[i][i]){
                int j;
                for (j = i+1; j < n && !mat[j][i]; j++);
                if (j == n){
                       rank--;
                       continue;
                }
                else
                    for (int k = i; k < m; k++){
                        bool t = mat[i][k];
                        mat[i][k] = mat[j][k];
                        mat[j][k] = t;
                    }
            }
            for (int j = i+1; j < n; j++){
                if (mat[j][i]){
                    for (int k = i; k < m; k++)
                        mat[j][k] = mat[j][k] - mat[i][k];
                }
            }
        }
    }

    /* Get the row rank of the boolean matrix
     * If you require the rank of the matrix, make sure that n > m.
     * i.e. if n < m, call the constructor over the transpose.
     */
    int getRank(){
        return rank;
    }
};

int main(){
    bool M1[3][3] = {   {1, 0, 1},
                {0, 1, 1}, 
                {1, 1, 0}   };
    BooleanMatrix booleanMatrix1(M1, 3, 3);
    cout << booleanMatrix1.getRank() << endl;   

    bool M2[4][4] = {   {1,1,1,0},
                {0,1,1,0},
                {0,1,0,0},
                {1,1,1,1}   };
    BooleanMatrix booleanMatrix2(M2, 4, 4);
    cout << booleanMatrix2.getRank() << endl;   
}

This gives result as expected for both the case. The algorithm should work well for all practical purposes. Trivial improvements & application specific changes could be made to suit as per your requirements.

I haven't tested it thoroughly though. If anybody finds any bug, please edit the answer to correct it.

Hope this helps.

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The above solution(LU Decomposition with Guass Elimination) runs in O(n^3). A better/faster solution can be obtained using Singular Value Decomposition(SVD). This is the default way Matlab finds Numerical rank of a matrix. –  Jayant Dec 13 '13 at 5:05
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A simple solution is to solve the least square problem where operators are defined in the boolean sense:

min_x |matrix * x - vector|^2

Then, if vector is in the span of column vectors of the matrix, the solutions's residual error should be very small.

share|improve this answer
    
It appears the OP does not mean "rank" in the regular linear algebra sense... –  A. Donda Oct 8 '13 at 20:20
    
pretty sure that when matrix multiplication and vector subtractions are defined in the boolean sense, the solution still works. –  prgao Oct 8 '13 at 20:27
    
fine, but how do you obtain the least squares solution? is there pinv in the boolean sense? –  A. Donda Oct 8 '13 at 21:29
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