Say you want to rotate A toward B.

Take the cross product AxB = C and normalize it.

~~Now break A into two components, one parallel to C and one normal:~~

```
...
```

~~Now construct a vector normal to A and C (with the right sense):~~

```
...
```

~~Now you can construct the rotated vector:~~

```
...
```

**EDIT**

I feel like an idiot. The correct (and more simple) derivation is

```
F = C x A
G = cos(theta) A + sin(theta) F
```

**EDIT:**

This works by simple geometry. C is normal to the plane containing A and B. F is in the plane, and normal to A. So any vector in the plane is a linear combination of A and F; that is, any vector Z in the plane can be constructed as Z = aA + bF, where a and b are numbers, and any such sum will be in the plane. F also has the same magnitude as A, so if we construct

```
G = cos(theta) A + sin(theta) F
```

what we get is a vector with the same magnitude, but separated from A by an angle theta. (This is not immediately obvious, but if you play around with it a little you'll see that it works.)

Using your example:

```
A = (2, 3, 3) (magnitude = 4.69)
B = (2, -3, -2)
C = AxB = (3, 10, -12) (magnitude = 15.906)
Now normalize:
C = (0.189, 0.629, -0.754) (magnitude = 1.0)
F = CxA = (4.149, -2.075, -0.692) (magnitude = 4.69)
theta = 20 degrees
G = cos(theta) A + sin(theta) F = (3.299, 2.109, 2.583) (magnitude = 4.69)
```

G is in the same plane as A and B (normal to C), and the angle between A and G is 20 degrees. (The angle between A and B is 124.7 degrees, the angle between G and B is 104.7 degrees.)