I'm working on writing my own COLLADA importer. I've gotten pretty far, loading meshes and materials and such. But I've hit a snag on animation, specifically: joint rotations.

The formula I'm using for skinning my meshes is straight-forward:

```
weighted;
for (i = 0; i < joint_influences; i++)
{
weighted +=
joint[joint_index[i]]->parent->local_matrix *
joint[joint_index[i]]->local_matrix *
skin->inverse_bind_pose[joint_index[i]] *
position *
skin->weight[j];
}
position = weighted;
```

And as far as the literature is concerned, this is the correct formula. Now, COLLADA specifies two types of rotations for the joints: local and global. You have to concatenate the rotations together to get the local transformation for the joint.

What the COLLADA documentation does not differentiate between is the joint's local rotation and the joint's global rotation. But in most of the models I've seen, rotations can have an id of either `rotate`

(global) or `jointOrient`

(local).

When I disregard the global rotations and only use the local ones, I get the bind pose for the model. But when I add the global rotations to the joint's local transformation, strange things start to happen.

This is without using global rotations:

And this is with global rotations:

In both screenshots I'm drawing the skeleton using lines, but in the first it's invisible because the joints are inside the mesh. In the second screenshot the vertices are all over the place!

For comparison, this is what the second screenshot *should* look like:

It's hard to see, but you can see that the joints are in the correct position in the second screenshot.

But now the weird thing. If I disregard the inverse bind pose as specified by COLLADA and instead take the inverse of the joint's parent local transform times the joint's local transform, I get the following:

In this screenshot I'm drawing a line from each vertex to the joints that have influence. The fact that I get the bind pose is not so strange, because the formula now becomes:

```
world_matrix * inverse_world_matrix * position * weight
```

But it leads me to suspect that COLLADA's inverse bind pose is in the wrong space.

So my question is: in what space does COLLADA specifies its inverse bind pose? And how can I transform the inverse bind pose to the space I need?