Let's say `acos`

gives you a value between 0 and pi.

Let's also say the vector from `s`

to `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 `v`

and `u`

. This vector is of course the cross product of the two: `u x v`

Let's see an example:

```
/ v
/
/\ alpha
/ )
------------ u
```

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 `u`

.

That is, in 3D, you have to compute `w = u x v`

and always rotate `v`

by `alpha`

counterclockwise with respect to `w`

. Alternatively, you can rotate `v`

by `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:

- Compute
`w = u x v`

- If
`w`

has positive z (the x and y will be zero)
- then,
`v`

should be rotated counterclockwise.
- else,
`v`

should be rotated clockwise.