Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am trying to call the Matlab "sort" function from a Mex file, but seem to be having a problem. Any help in debugging this error would be greatly appreciated.

Here is the C code for the MEX file:

#include "mex.h"
#include "math.h"

static void array_range(double * array, const unsigned int array_rows, const unsigned int array_cols, int val, const int incr) {
    unsigned int row;
    unsigned int col;

    for (row = 1; row <= array_rows; row++) {
        for (col = 1; col <= array_cols; col++) {
            array[((row) - 1) + array_rows * ((col) - 1)] = val;
            val += incr;
        }
    }
}

static double mean_over_row(double * array, const unsigned int array_rows, const unsigned int array_cols, const unsigned int row) {
    double sum = 0;
    unsigned int count = 0;
    unsigned int col;

    for (col = 1; col <= array_cols; col++) {
        sum += array[((row) - 1) + array_rows * ((col) - 1)];
        count++;
    }

    return sum / count;
}

static void max_over_row(double * array, const unsigned int array_rows, const unsigned int array_cols, const unsigned int row, double * maxd, unsigned int * maxi) {
    unsigned int col;

    *maxd = array[((row) - 1) + array_rows * ((1) - 1)];
    *maxi = 1;

    for (col = 2; col <= array_cols; col++) {
        const double val = array[((row) - 1) + array_rows * ((col) - 1)];
        if (val > *maxd) {
            *maxd = val;
            *maxi = col;
        }
    }
}

static void top_n_outlier_pruning_block(double * X, const unsigned int X_rows, const unsigned int X_cols, const unsigned int k, const unsigned int N, const unsigned int block_size, double * O, double * OF) {
    const mwSize n = X_rows;
    const mwSize O_rows = 1;
    const mwSize O_cols = N;
    const mwSize OF_rows = 1;
    const mwSize OF_cols = N;

    unsigned int c = 0;
    unsigned int count = 0;

    while (n - count > 0) {
        const mwSize B_rows = 1; 
        const mwSize B_cols = block_size; 
        mxArray * B_matlab = mxCreateDoubleMatrix(B_rows, B_cols, mxREAL); 
        double * B = mxGetPr(B_matlab);
        array_range(B, B_rows, B_cols, count + 1, 1);
        count += block_size;

        unsigned int sizeB;
        if (count <= n)
            sizeB = block_size;
        else
            sizeB = n - (count - block_size);

        const mwSize neighbours_rows = sizeB; 
        const mwSize neighbours_cols = k; 
        mxArray * neighbours_matlab = mxCreateDoubleMatrix(neighbours_rows, neighbours_cols, mxREAL);
        double * neighbours = mxGetPr(neighbours_matlab);
        const mwSize neighbours_dist_rows = sizeB; 
        const mwSize neighbours_dist_cols = k; 
        mxArray * neighbours_dist_matlab = mxCreateDoubleMatrix(neighbours_dist_rows, neighbours_dist_cols, mxREAL); 
        double * neighbours_dist = mxGetPr(neighbours_dist_matlab);
        const mwSize score_rows = 1; 
        const mwSize score_cols = sizeB; 
        mxArray * score_matlab = mxCreateDoubleMatrix(score_rows, score_cols, mxREAL); 
        double * score = mxGetPr(score_matlab);

        unsigned int l = 1;
        unsigned int i;
        unsigned int j;
        unsigned int col;
        for (i = 1; i <= n; i++) {
            for (j = 1; j <= sizeB; j++) {
                const unsigned int B_j = (unsigned int) B[((1) - 1) + B_rows * ((j) - 1)];

                if (i != B_j && B_j != 0) {

                    double sum_of_squares = 0;
                    for (col = 1; col <= X_cols; col++)
                        sum_of_squares += pow(X[((i) - 1) + X_rows * ((col) - 1)] - X[((B_j) - 1) + X_rows * ((col) - 1)], 2);
                    unsigned int d = sqrt(sum_of_squares);

                    if (l > 1 && l <= (k + 1) && neighbours[((j) - 1) + neighbours_rows * ((l - 1) - 1)] == 0)
                        l--;
                    else if (l < k && neighbours[((j) - 1) + neighbours_rows * ((l) - 1)] != 0)
                        l++;

                    if (l <= k) {
                        neighbours[((j) - 1) + neighbours_rows * ((l) - 1)] = i;
                        neighbours_dist[((j) - 1) + neighbours_dist_rows * ((l) - 1)] = d;
                        if (l == k) {

                            score[((1) - 1) + score_rows * ((j) - 1)] = mean_over_row(neighbours_dist, neighbours_dist_rows, neighbours_dist_cols, j);
                        }
                    } else {
                        double maxd;
                        unsigned int maxi;
                        max_over_row(neighbours_dist, neighbours_dist_rows, neighbours_dist_cols, j, &maxd, &maxi);

                        if (d < maxd) {
                            neighbours[((j) - 1) + neighbours_rows * ((maxi) - 1)] = i;
                            neighbours_dist[((j) - 1) + neighbours_dist_rows * ((maxi) - 1)] = d;

                            score[((1) - 1) + score_rows * ((j) - 1)] = (score[((1) - 1) + score_rows * ((j) - 1)] * k - maxd + d) / k;
                            if (score[((1) - 1) + score_rows * ((j) - 1)] <= 0) {
                                double average = mean_over_row(neighbours_dist, j, neighbours_dist_rows, neighbours_dist_cols);

                                if (average > 0)
                                    score[((1) - 1) + score_rows * ((j) - 1)] = average;
                                else
                                    score[((1) - 1) + score_rows * ((j) - 1)] = 0;
                            }
                        }
                    }

                    if (l >= k && score[((1) - 1) + score_rows * ((j) - 1)] < c) {
                        B[((1) - 1) + B_rows * ((j) - 1)] = 0;
                        score[((1) - 1) + score_rows * ((j) - 1)] = 0;
                    }
                }
            }

            l++;
        }

        const mwSize BO_rows = 1; 
        const mwSize BO_cols = sizeB + 1; 
        mxArray * BO_matlab = mxCreateDoubleMatrix(BO_rows, BO_cols, mxREAL); 
        double * BO = mxGetPr(BO_matlab);
        for (col = 1; col < BO_cols; col++)
            BO[((1) - 1) + BO_rows * ((col) - 1)] = B[((1) - 1) + B_rows * ((col) - 1)];


        const mwSize BOF_rows = 1; 
        const mwSize BOF_cols = score_cols + OF_cols; 
        mxArray * BOF_matlab = mxCreateDoubleMatrix(BOF_rows, BOF_cols, mxREAL); 
        double * BOF = mxGetPr(BOF_matlab);
        for (col = 1; col <= score_cols; col++)
            BOF[((1) - 1) + BOF_rows * ((col) - 1)] = score[((1) - 1) + score_rows * ((col) - 1)];
        for (col = 1; col <= OF_cols; col++)
            BOF[((1) - 1) + BOF_rows * ((col + score_cols) - 1)] = OF[((1) - 1) + OF_rows * ((col) - 1)];

        mxArray * sort_outputs[2];
        mxArray * sort_inputs[2];
        sort_inputs[0] = BOF_matlab;
        sort_inputs[1] = mxCreateString("descend");
        mexCallMATLAB(2, sort_outputs, 2, sort_inputs, "sort");

        const mwSize newBOF_rows = mxGetM(sort_outputs[0]);
        const mwSize newBOF_cols = mxGetN(sort_outputs[0]);
        double * newBOF = mxGetPr(sort_outputs[0]);

        const mwSize index_rows = mxGetM(sort_outputs[1]);
        const mwSize index_cols = mxGetN(sort_outputs[1]);
        double * index = mxGetPr(sort_outputs[1]);

        const mwSize newBO_rows = BO_rows; 
        const mwSize newBO_cols = BO_cols; 
        mxArray * newBO_matlab = mxCreateDoubleMatrix(newBO_rows, newBO_cols, mxREAL); 
        double * newBO = mxGetPr(newBO_matlab);
        for (col = 1; col <= BO_cols; col++) {
            unsigned int mapped_index = (unsigned int) index[((1) - 1) + index_rows * ((col) - 1)];
            newBO[((1) - 1) + newBO_rows * ((col) - 1)] = BO[((1) - 1) + BO_rows * ((mapped_index) - 1)];
        }

        for (col = 1; col <= BO_cols; col++)
            O[((1) - 1) + O_rows * ((col) - 1)] = BO[((1) - 1) + BO_rows * ((col) - 1)];

        for (col = 1; col <= BOF_cols; col++)
            OF[((1) - 1) + OF_rows * ((col) - 1)] = BOF[((1) - 1) + BOF_rows * ((col) - 1)];

        double c = OF[((1) - 1) + OF_rows * ((N) - 1)];
    }
}

void mexFunction(int nlhs, mxArray * plhs[], int nrhs, const mxArray * prhs[]) {
    if (nrhs != 4)
        mexErrMsgTxt("Four inputs required.");
    if (nlhs != 2)
        mexErrMsgTxt("Two outputs required.");

    if (!((!mxIsComplex(prhs[0]) && mxGetNumberOfDimensions(prhs[0]) == 2 && mxIsDouble(prhs[0])) && !mxIsSparse(prhs[0])))
        mexErrMsgTxt("Input X must be a real full 2D double array.");
    double * X = mxGetPr(prhs[0]);
    const size_t X_rows = mxGetM(prhs[0]);
    const size_t X_cols = mxGetN(prhs[0]);

    if(!(((!mxIsComplex(prhs[1]) && mxGetNumberOfDimensions(prhs[1]) == 2 && mxIsDouble(prhs[1])) && !mxIsSparse(prhs[1])) && mxGetNumberOfElements(prhs[1]) == 1))
        mexErrMsgTxt("Input k must be a scalar.");
    const unsigned int k = (unsigned int) mxGetScalar(prhs[1]);

    if(!(((!mxIsComplex(prhs[2]) && mxGetNumberOfDimensions(prhs[2]) == 2 && mxIsDouble(prhs[2])) && !mxIsSparse(prhs[2])) && mxGetNumberOfElements(prhs[2]) == 1))
        mexErrMsgTxt("Input N must be a scalar.");
    const unsigned int N = (unsigned int) mxGetScalar(prhs[2]);

    if(!(((!mxIsComplex(prhs[3]) && mxGetNumberOfDimensions(prhs[3]) == 2 && mxIsDouble(prhs[3])) && !mxIsSparse(prhs[3])) && mxGetNumberOfElements(prhs[3]) == 1))
        mexErrMsgTxt("Input block_size must be a scalar.");
    const unsigned int block_size = (unsigned int) mxGetScalar(prhs[3]);

    plhs[0] = mxCreateDoubleMatrix(1, N, mxREAL);
    plhs[1] = mxCreateDoubleMatrix(1, N, mxREAL);

    double * O = mxGetPr(plhs[0]);
    double * OF = mxGetPr(plhs[1]);

    top_n_outlier_pruning_block(X, X_rows, X_cols, k, N, block_size, O, OF);
}

The error that I get is *** glibc detected *** /usr/local/MATLAB/R2012a/bin/glnxa64/MATLAB: corrupted double-linked list: 0x00007fffc899c780 ***

Judging by the GDB backtrace, my function isn't even being called.

share|improve this question
2  
Can you post a minimal code snippet that reproduces the error? –  Ansari May 15 '12 at 5:27
    
I briefly went through the GDB stack. Maybe the output pointer is the problem? Maybe it doesn't point to enough available memory and something is getting overwritten. –  Ansari May 15 '12 at 5:39
    
I have edited my post. I found an error I made in indexing the arrays, but I am still getting a somewhat cryptic error message. I also made the source code a bit easier to read by evaluating the macro expansions that I had. –  Joshua Spence May 15 '12 at 8:53
    
The first thing that jumps out at me is that you are using array indexes starting at "1". I see you've put -1 throughout to deal with this, but this is just a disaster waiting to happen for when you forget. I would fix all your array indexing, then move forward. What is the cryptic error? –  Chris May 15 '12 at 17:56
    
Fixed the problem. @Chris, the 1-based indexing is to align the code with MATLAB-style indexing. The problem was accessing memory outside of the bounds of an array. More specifically BOF_cols was larger than OF_cols in the line ` for (col = 1; col <= BOF_cols; col++)`. –  Joshua Spence May 16 '12 at 3:05

Your Answer

 
discard

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

Browse other questions tagged or ask your own question.