Transferring an image from Matlab to an OpenCV IplImage

Question

I have an image in Matlab:

img = imopen('image.jpg')

which returns an uint8 array height x width x channels (3 channels: RGB).

Now I want to use openCV to do some manipulations on it, so I write up a MEX file which takes the image as a parameter and constructs an IplImage from it:

#include "mex.h"
#include "cv.h"

void mexFunction(int nlhs, mxArray **plhs, int nrhs, const mxArray **prhs) {
    char *matlabImage = (char *)mxGetData(prhs[0]);
    const mwSize *dim = mxGetDimensions(prhs[0]);

    CvSize size;
    size.height = dim[0];
    size.width = dim[1];

    IplImage *iplImage = cvCreateImageHeader(size, IPL_DEPTH_8U, dim[2]);
    iplImage->imageData = matlabImage;
    iplImage->imageDataOrigin = iplImage->imageData;

    /* Show the openCV image */
    cvNamedWindow("mainWin", CV_WINDOW_AUTOSIZE);
    cvShowImage("mainWin", iplImage);
}

This result looks completely wrong, because openCV uses other conventions than matlab for storing an image (for instance, they interleave the color channels).

Can anyone explain what the differences in conventions are and give some pointers on how to display the image correctly?

Answer 1

After spending the day doing fun image format conversions </sarcasm> I can now answer my own question.

Matlab stores images as 3 dimensional arrays: height × width × color
OpenCV stores images as 2 dimensional arrays: (color × width) × height

Furthermore, for best performance, OpenCV pads the images with zeros so rows are always aligned on 32 bit blocks.

I've done the conversion in Matlab:

function [cv_img, dim, depth, width_step] = convert_to_cv(img)

% Exchange rows and columns (handles 3D cases as well)
img2 = permute( img(:,end:-1:1,:), [2 1 3] );

dim = [size(img2,1), size(img2,2)];

% Convert double precision to single precision if necessary
if( isa(img2, 'double') )
    img2 = single(img2);
end

% Determine image depth
if( ndims(img2) == 3 && size(img2,3) == 3 )
    depth = 3;
else
    depth = 1;
end

% Handle color images
if(depth == 3 )
    % Switch from RGB to BGR
    img2(:,:,[3 2 1]) = img2;

    % Interleave the colors
    img2 = reshape( permute(img2, [3 1 2]), [size(img2,1)*size(img2,3) size(img2,2)] );
end

% Pad the image
width_step = size(img2,1) + mod( size(img2,1), 4 );
img3 = uint8(zeros(width_step, size(img2,2)));
img3(1:size(img2,1), 1:size(img2,2)) = img2;

cv_img = img3;

% Output to openCV
cv_display(cv_img, dim, depth, width_step);

The code to transform this into an IplImage is in the MEX file:

#include "mex.h"
#include "cv.h"
#include "highgui.h"

#define IN_IMAGE prhs[0]
#define IN_DIMENSIONS prhs[1]
#define IN_DEPTH prhs[2]
#define IN_WIDTH_STEP prhs[3]

void mexFunction(int nlhs, mxArray **plhs, int nrhs, const mxArray **prhs) {
    bool intInput = true;

    if(nrhs != 4)
        mexErrMsgTxt("Usage: cv_disp(image, dimensions, depth, width_step)");

    if( mxIsUint8(IN_IMAGE) )
        intInput = true;
    else if( mxIsSingle(IN_IMAGE) )
        intInput = false;
    else 
        mexErrMsgTxt("Input should be a matrix of uint8 or single precision floats.");

    if( mxGetNumberOfElements(IN_DIMENSIONS) != 2 )
        mexErrMsgTxt("Dimension vector should contain two elements: [width, height].");

    char *matlabImage = (char *)mxGetData(IN_IMAGE);

    double *imgSize = mxGetPr(IN_DIMENSIONS);
    size_t width = (size_t) imgSize[0];
    size_t height = (size_t) imgSize[1];

    size_t depth = (size_t) *mxGetPr(IN_DEPTH);
    size_t widthStep = (size_t) *mxGetPr(IN_WIDTH_STEP) * (intInput ? sizeof(unsigned char):sizeof(float));

    CvSize size;
    size.height = height;
    size.width = width;

    IplImage *iplImage = cvCreateImageHeader(size, intInput ? IPL_DEPTH_8U:IPL_DEPTH_32F, depth);
    iplImage->imageData = matlabImage;
    iplImage->widthStep = widthStep;
    iplImage->imageDataOrigin = iplImage->imageData;

    /* Show the openCV image */
    cvNamedWindow("mainWin", CV_WINDOW_AUTOSIZE);
    cvShowImage("mainWin", iplImage);
}