Using a quaternion, if I rotate my cube along an axis by 90 degrees, I get a different front facing cube side, which appears as a straight-on square of a solid color. My cube has different colored sides, so changing the axis it is rotated along gives me these different colors as expected.

When I try to rotate by an arbitrary amount, I get quite the spectacular mess, and I don't know why since I'd expect the quaternion process to work well regardless of the angle:

I am creating a quaternion from 2 vectors using this:

```
inline QuaternionT<T> QuaternionT<T>::CreateFromVectors(const Vector3<T>& v0, const Vector3<T>& v1)
{
if (v0 == -v1)
return QuaternionT<T>::CreateFromAxisAngle(vec3(1, 0, 0), Pi);
Vector3<T> c = v0.Cross(v1);
T d = v0.Dot(v1);
T s = std::sqrt((1 + d) * 2);
QuaternionT<T> q;
q.x = c.x / s;
q.y = c.y / s;
q.z = c.z / s;
q.w = s / 2.0f;
return q;
}
```

I think the above method is fine since I've seen plenty of sample code correctly using it.

With the above method, I do this:

```
Quaternion quat1=Quaternion::CreateFromVectors(vec3(0,1,0), vec3(0,0,1));
```

It works, and it is a 90-degree rotation.

But suppose I want more like a 45-degree rotation?

```
Quaternion quat1=Quaternion::CreateFromVectors(vec3(0,1,0), vec3(0,1,1));
```

This gives me the mess above. I also tried normalizing `quat1`

which provides different though similarly distorted results.

I am using the quaternion as a Modelview rotation matrix, using this:

```
inline Matrix3<T> QuaternionT<T>::ToMatrix() const
{
const T s = 2;
T xs, ys, zs;
T wx, wy, wz;
T xx, xy, xz;
T yy, yz, zz;
xs = x * s; ys = y * s; zs = z * s;
wx = w * xs; wy = w * ys; wz = w * zs;
xx = x * xs; xy = x * ys; xz = x * zs;
yy = y * ys; yz = y * zs; zz = z * zs;
Matrix3<T> m;
m.x.x = 1 - (yy + zz); m.y.x = xy - wz; m.z.x = xz + wy;
m.x.y = xy + wz; m.y.y = 1 - (xx + zz); m.z.y = yz - wx;
m.x.z = xz - wy; m.y.z = yz + wx; m.z.z = 1 - (xx + yy);
return m;
}
```

Any idea what's going on here?

`if (v0 == -v1)`

clause is supposed to work. If I want to rotate (1,0,0) onto (-1,0,0), how can a rotation around (1,0,0) ever produce the right orientation? For that matter, how can that work for any vector which is not perpendicular to the arbitrary (1,0,0) axis? – JasonD Mar 12 '13 at 9:58