I think this is a very good question and there is no silver bullet. I will just tell you about my experience.

I wrote an algorithm to find the nearest set of points between two cylinders in 3D space. This is a very complex problem and the input space is huge.

In order to test my code, at first I just generated some canonical cases, which were fairly axis aligned, so that the "correct" result was obvious. But that was too weak.

Then I was able to "beef up" the canonical cases by applying random transformations. This helped a bit.

Then I thought about writing another duplicate algorithm and implementation, but that was ridiculously hard, and there is no way to know if both algorithms might exhibit the same bug. However, for another problem this might be feasible, such as with brute-force: not efficient, but very simple to understand and verify.

Then I thought about the properties of the solutions set. For instance the separating vector must be a local minima, so I should be able "look around" each end point of the solution (for a small epsilon) and determine if the solution is a local minima.

Then I started to think about the topological properties of the function mapping the input to the output. In this case I know that the separation distance should vary smoothly. So I chose a random input and small delta, and then compare the output with and without the delta applied. If the algorithm is correct, then difference in the output should be small.

By combining all these techniques I was able to get high confidence in the code.