I'm trying to derive a CATransform3D that will map a quad with 4 corner points to another quad with 4 new corner points. I've spent a little bit of time researching this and it seems the steps involve converting the original Quad to a Square, and then converting that Square to the new Quad. My methods look like this (code borrowed from here):

``````- (CATransform3D)quadFromSquare_x0:(float)x0 y0:(float)y0 x1:(float)x1 y1:(float)y1 x2:(float)x2 y2:(float)y2 x3:(float)x3 y3:(float)y3 {

float dx1 = x1 - x2,    dy1 = y1 - y2;
float dx2 = x3 - x2,    dy2 = y3 - y2;
float sx = x0 - x1 + x2 - x3;
float sy = y0 - y1 + y2 - y3;
float g = (sx * dy2 - dx2 * sy) / (dx1 * dy2 - dx2 * dy1);
float h = (dx1 * sy - sx * dy1) / (dx1 * dy2 - dx2 * dy1);
float a = x1 - x0 + g * x1;
float b = x3 - x0 + h * x3;
float c = x0;
float d = y1 - y0 + g * y1;
float e = y3 - y0 + h * y3;
float f = y0;

CATransform3D mat;

mat.m11 = a;
mat.m12 = b;
mat.m13 = 0;
mat.m14 = c;

mat.m21 = d;
mat.m22 = e;
mat.m23 = 0;
mat.m24 = f;

mat.m31 = 0;
mat.m32 = 0;
mat.m33 = 1;
mat.m34 = 0;

mat.m41 = g;
mat.m42 = h;
mat.m43 = 0;
mat.m44 = 1;

return mat;

}

- (CATransform3D)squareFromQuad_x0:(float)x0 y0:(float)y0 x1:(float)x1 y1:(float)y1 x2:(float)x2 y2:(float)y2 x3:(float)x3 y3:(float)y3 {

CATransform3D mat = [self quadFromSquare_x0:x0 y0:y0 x1:x1 y1:y1 x2:x2 y2:y2 x3:x3 y3:y3];

float a = mat.m11,      d = mat.m21,    /* ignore */            g = mat.m41;
float b = mat.m12,      e = mat.m22,    /* 3rd col*/            h = mat.m42;
/* ignore 3rd row */
float c = mat.m14,      f = mat.m24;

float A =     e - f * h;
float B = c * h - b;
float C = b * f - c * e;
float D = f * g - d;
float E =     a - c * g;
float F = c * d - a * f;
float G = d * h - e * g;
float H = b * g - a * h;
float I = a * e - b * d;

// Probably unnecessary since 'I' is also scaled by the determinant,
//   and 'I' scales the homogeneous coordinate, which, in turn,
//   scales the X,Y coordinates.
// Determinant  =   a * (e - f * h) + b * (f * g - d) + c * (d * h - e * g);
float idet = 1.0f / (a * A           + b * D           + c * G);

mat.m11 = A * idet;     mat.m21 = D * idet;     mat.m31 = 0;    mat.m41 = G * idet;
mat.m12 = B * idet;     mat.m22 = E * idet;     mat.m32 = 0;    mat.m42 = H * idet;
mat.m13 = 0       ;     mat.m23 = 0       ;     mat.m33 = 1;    mat.m43 = 0       ;
mat.m14 = C * idet;     mat.m24 = F * idet;     mat.m34 = 0;    mat.m44 = I * idet;

return mat;

}
``````

After calculating both matrices, multiplying them together, and assigning to the view in question, I end up with a transformed view, but it is wildly incorrect. In fact, it seems to be sheared like a parallelogram no matter what I do. What am I missing?

UPDATE 2/1/12

It seems the reason I'm running into issues may be that I need to accommodate for FOV and focal length into the model view matrix (which is the only matrix I can alter directly in Quartz.) I'm not having any luck finding documentation online on how to calculate the proper matrix, though.

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Update: I've tried porting a few algorithms now and end up with a parallelogram every single time. There's got to be something I'm forgetting, but I'm at a loss. – sevenflow Feb 1 '12 at 18:07
Here is an other way to achieve this: stackoverflow.com/questions/9470493/… Let me know if this helps. – MonsieurDart Mar 27 '12 at 8:31