acos gives you a value between 0 and pi.
Let's also say the vector from
t is called
u. As you have already computed,
acos((v . u)/(|v| * |u|))
gives you an angle
alpha. Now in truth,
v could be
u rotated by
alpha to one or the other direction.
You probably need this in 2D, but I'll go on in 3D first.
The rotation should be around a vector that is perpendicular to both
u. This vector is of course the cross product of the two:
u x v
Let's see an example:
In this case,
u x v gives a vector towards the outside of your monitor. At the same time, you can see that the ration
alpha should take place counterclockwise to make
v parallel to
That is, in 3D, you have to compute
w = u x v and always rotate
alpha counterclockwise with respect to
w. Alternatively, you can rotate
alpha clockwise with respect to
-w (which is
v x u).
In 2D, I assume you want to rotate around
z and you don't know which direction. You can apply the same method as above:
w = u x v
w has positive z (the x and y will be zero)
v should be rotated counterclockwise.
v should be rotated clockwise.