McoStatus XyztoRgb::xyz2rgb(Monitor *monitor)
{
double k1, k2, k3;
Matrix phosmat(3);
Matrix phosmat2(3);
Matrix wcolmat(3, 1);
Matrix cmat(3);
Matrix ccolmat(3, 1);
memcpy((char*)&_monitor, (char*)monitor, sizeof(Monitor));
phosmat.setval(1, 1, _monitor.setup[3]);
phosmat.setval(2, 1, _monitor.setup[4]);
phosmat.setval(3, 1, (1.0 - _monitor.setup[3] - _monitor.setup[4]));
phosmat.setval(1, 2, _monitor.setup[5]);
phosmat.setval(2, 2, _monitor.setup[6]);
phosmat.setval(3, 2, (1.0 - _monitor.setup[5] - _monitor.setup[6]));
phosmat.setval(1, 3, _monitor.setup[7]);
phosmat.setval(2, 3, _monitor.setup[8]);
phosmat.setval(3, 3, (1.0 - _monitor.setup[7] - _monitor.setup[8]));
phosmat2 = phosmat;
//compute inverse phosphor matrix
phosmat.inv();
if( phosmat.get_status() != MCO_SUCCESS)
return MCO_SINGULAR;
//load white
// Matrix wcolmat(3, 1);
wcolmat.setval(1, 1, (_monitor.setup[1]/_monitor.setup[2]));
wcolmat.setval(2, 1, (_monitor.setup[2]/_monitor.setup[2]));
wcolmat.setval(3, 1, ((1.0 - _monitor.setup[1] - _monitor.setup[2])/_monitor.setup[2]));
//compute k1, k2, k3
ccolmat = phosmat*wcolmat;
ccolmat.getval(1, 1, &k1);
ccolmat.getval(2, 1, &k2);
ccolmat.getval(3, 1, &k3);
//load k1,k2,k3 and inverse
cmat.setval(1, 1, k1);
cmat.setval(2, 2, k2);
cmat.setval(3, 3, k3);
//compute the RGB to XYZ conversion matrix;
*_rgbtoxyzt = phosmat2*cmat;
//transvers of RGB to XYZ conversion matrix
_rgbtoxyzt->T();
//compute the xyz to rgb conversion matrix
//actually, it's the transverse of conversion matrix
*_xyztorgbt = *_rgbtoxyzt;
_xyztorgbt->inv();
if(_xyztorgbt->get_status() != MCO_SUCCESS)
return MCO_SINGULAR;
return MCO_SUCCESS;
}
//build rgb to xyz conversion
//return the value in rgbtoxyz and xyztorgb
//if return 0, ok, else something wrong in the conversion
McoStatus buildrgbxyz(double *monitor, double *xyztorgb, double *rgbtoxyz)
{
double k1, k2, k3;
Matrix phosmat(3);
Matrix phosmat2(3);
Matrix wcolmat(3, 1);
Matrix cmat(3);
Matrix ccolmat(3, 1);
Matrix rgbtoxyzmat(3);
Matrix xyztorgbmat(3);
phosmat.setval(1, 1, monitor[3]);
phosmat.setval(2, 1, monitor[4]);
phosmat.setval(3, 1, (1.0 - monitor[3] - monitor[4]));
phosmat.setval(1, 2, monitor[5]);
phosmat.setval(2, 2, monitor[6]);
phosmat.setval(3, 2, (1.0 - monitor[5] - monitor[6]));
phosmat.setval(1, 3, monitor[7]);
phosmat.setval(2, 3, monitor[8]);
phosmat.setval(3, 3, (1.0 - monitor[7] - monitor[8]));
phosmat2 = phosmat;
//compute inverse phosphor matrix
phosmat.inv();
//singular matrix or something strange happened
if( phosmat.get_status() != MCO_SUCCESS)
return MCO_SINGULAR;
//load white
wcolmat.setval(1, 1, (monitor[1]/monitor[2]));
wcolmat.setval(2, 1, (monitor[2]/monitor[2]));
wcolmat.setval(3, 1, ((1.0 - monitor[1] - monitor[2])/monitor[2]));
//compute k1, k2, k3
ccolmat = phosmat*wcolmat;
ccolmat.getval(1, 1, &k1);
ccolmat.getval(2, 1, &k2);
ccolmat.getval(3, 1, &k3);
//load k1,k2,k3 and inverse
cmat.setval(1, 1, k1);
cmat.setval(2, 2, k2);
cmat.setval(3, 3, k3);
//compute the RGB to XYZ conversion matrix;
rgbtoxyzmat = phosmat2*cmat;
//compute the xyz to rgb conversion matrix
xyztorgbmat = rgbtoxyzmat;
xyztorgbmat.inv();
//singular matrix or something strange happened
if(xyztorgbmat.get_status() != MCO_SUCCESS)
return MCO_SINGULAR;
//copy the conversion matrix to the data struct
rgbtoxyzmat.savestruct(rgbtoxyz);
xyztorgbmat.savestruct(xyztorgb);
return MCO_SUCCESS;
}
