I saw you use the glm library for matrix operations, so from the glm code the lookat implementation looks like this:

```
mat4x4 lookAt(vec3 const & eye, vec3 const & center, vec3 const & up)
{
vec3 f = normalize(center - eye);
vec3 u = normalize(up);
vec3 s = normalize(cross(f, u));
u = cross(s, f);
mat4x4 Result(1);
Result[0][0] = s.x;
Result[1][0] = s.y;
Result[2][0] = s.z;
Result[0][1] = u.x;
Result[1][1] = u.y;
Result[2][1] = u.z;
Result[0][2] =-f.x;
Result[1][2] =-f.y;
Result[2][2] =-f.z;
Result[3][0] =-dot(s, eye);
Result[3][1] =-dot(u, eye);
Result[3][2] = dot(f, eye);
return Result;
}
```

You first normalize the vectors you will use(**f** is the direction you look at, **u** the up and **s** is the right vector). Then to make sure the **up vector** is perpendicular to the **direction** and **right vectors** you recalculate it as their cross product, because when you give an **up vector** you can't make sure its perpendicular to the **eye-center vector**(view direction), they're just form a plane which gives you the **right vector**.

The matrix is constructed from these. For more detail how does it works check the http://www.songho.ca/opengl/gl_transform.html page.
In short:this is a matrix which creates you a new coordinate system, so the coloumns are the axises. Then at the last coloumn the translation matrix is applied.

(Look at the identity matrix:

```
AXIS TRANSFORM
x y z transl.
1, 0, 0, 0
0, 1, 0, 0,
0, 0, 1, 0
0, 0, 0, 1
```

This gives you the standard coordinate system with no translation.)

Then you multiply this with projection and model matrixes (p*v*m), the order is important.
When you write your implementation make sure you use coloumn major matrixes, because of opengl, or transpose them.

I hope it helps.