Outline of the algorithm:

- Handle the cases where the planes of the circles are parallel or concurrent.
- Find the line of intersection of the planes of the circles.
- Find the intersections of the circles with this line.
- All the circle intersections with the line are on both planes. We can now do distance checks to see if the circles are linked.

Details:

I'll assume that the circles C1 and C2 are given by a center point (p1, p2), unit normal axis vector (n1, n2) and radii (r1, r2).

If n1 == k n2 for some scalar k, then the planes are parallel or concurrent. If they're concurrent this becomes the trivial 2d problem: check whether dist(p1, p2) < r1+r2.

Otherwise, the planes intersect at a line L. If the circles are linked, then they must both intersect L since linking implies that they mutually pass through each other's plane of definition. This gives you your first trivial rejection test.

L is given by a point q and a vector v. Finding v is easy: It's just the cross product of n1 and n2. q is a little trickier, but we can choose a point of nearest approach of the lines

```
l1(s) = p1 + s (v X n1)
l2(t) = p2 + t (v X n2)
```

These lines are perpendicular to v, n1 and n2, and are on the planes of C1 and C2. Their points of nearest approach must be on L.

You can refer to this post to see how to find the points of nearest approach.

Finally, the only way the circles can intersect is if they both have points on L. If they do, then consider the intersection points of C1 and L as they relate to C2. The circles are linked if there are two intersection points q11 and q12 of C1 and L and **exactly** one of them are inside of C2. Since L is on the plane of C2, this becomes a planar point-in-circle test:

```
IF dist(p1, q11) < r1 THEN
linked = (dist(p1, q12) > r1)
ELSE
linked = (dist(p1, q11) < r1)
ENDIF
```

Of course this pseudo-code is a little sloppy about handling the case that the circles actually intersect, but how that should be handled depends on your application.