There are a couple of ways that you can approach the task of translating touch movement into rotation of a 3-D object: set up a trackball, or use scaled pixel displacements to map to rotation.
I do the latter in this OpenGL ES 2.0 sample application, where I perform rotation of a cube in response to the displacement of your finger in X and Y. In this case, I use the touch point coordinate differences to map directly to rotation, using code like the following:
GLfloat totalRotation = sqrt(xRotation*xRotation + yRotation*yRotation);
CATransform3D temporaryMatrix = CATransform3DRotate(currentCalculatedMatrix, totalRotation * M_PI / 180.0,
((xRotation/totalRotation) * currentCalculatedMatrix.m12 + (yRotation/totalRotation) * currentCalculatedMatrix.m11),
((xRotation/totalRotation) * currentCalculatedMatrix.m22 + (yRotation/totalRotation) * currentCalculatedMatrix.m21),
((xRotation/totalRotation) * currentCalculatedMatrix.m32 + (yRotation/totalRotation) * currentCalculatedMatrix.m31));
This roughly treats a movement of one point on the screen as one degree, which seemed to work well for my needs. You can scale this up or down to adjust the sensitivity of rotation.
The CATransform3D I use here is converted to an OpenGL model view matrix through a helper function and passed into my shaders as a matrix uniform.
A trackball is another way of handling this rotation, and Bill Dudney supplies an example of that in his Core Animation sample here. You could lift his trackball implementation and do the same CATransform3D conversion I do in my application to generate the appropriate model view matrix from that code.