To do this properly:
- calculate exact collision times for your circles instead of rounding to the next frame:
- if your objects are moving in more than 1D, this requires root-finding.
- resolve collisions in order, as follows:
- stop the simulation at the aforementioned exact collision time.
- resolve the physics of the circles in this first collision.
- recalculate to determine any collisions due to the new trajectories.
- restart the simulation.
- repeat until you reach end-of-frame without a collision.
- any other unscheduled change in physics will also require updating upcoming collisions.
You may notice that this has the potential for lots of computation. It can be particularly nasty in cases where your balls lose kinetic energy and end up resting on each other -- if your physics makes this likely, you will need to add some sort of threshold for "resting contact" (which, unfortunately, can complicate your physics enormously).
Update, in response to comments: I want to make clear that my answer ignores one of your assumptions -- you can't handle collisions accurately if you pretend that there isn't any time between frame boundaries. The collisions don't happen at the frame boundaries; in general, the collisions will happen between the frame boundaries, so your computations need to reflect that.
If you assume that all motion between frames is linear (i.e., your simulation does all acceleration on the frame boundaries), then determining whether, where, and when there is a collision is actually pretty simple. It reduces your interframe "simulation" to practically nothing -- you can solve your equations in closed form, even if your simulation is 2D or 3D:
posAB = posA - posB [relative vector between circles A and B]
velAB = velA - velB [relative velocity between circles A and B]
posAB(t) = posAB(0) + t * velAB [relative vector as a function of time]
rAB = rA + rB [sum of radii of the two circles]
collision happens when distance(t) = abs(posAB(t)) == rAB
-> rAB^2 = | posAB(t) |^2 = | posAB(0) + t * velAB |^2
-> t^2 * |velAB|^2 + t * 2*posAB(0).velAB + |posAB(0)|^2 - rAB^2 == 0
solve quadratic equation for t:
- if discriminant is negative, there is no collision.
- if collision times are outside current timestep, there is no current collision.
- otherwise, smallest t should be the correct collision time.
- watch out for cases like 2 circles coming *out* of collision...
Finally, it sounds like you're trying to do premature optimization. Better to make things work right, then make them fast; you won't know your actual bottlenecks until you have running code. I also think you are, in fact, underestimating the power of modern computers. Of course, you can always add enough objects to bog down your computer, but I think you will be surprised how many it takes...