Would you say modern version of fisher yates is the most unbiased shuffling algorithm? How would you explain that each element in the array has a probability of 1/n being in its original spot?
Given a perfect pseudo-random number generator (the Mersenne Twister is very close), the Fisher-Yates algorithm is perfectly unbiased in that every permutation has an equal probability of occurring. This is easy to prove using induction. The Fisher-Yates algorithm can be written recursively as follows (in Python syntax pseudocode):
Each index has an equal probability of being selected as
Edit: The algorithm has been mathematically proven to be unbiased. Since the algorithm is non-deterministic, the best way to test whether an implementation works properly is statistically. I would take an array of some arbitrary but small size, shuffle it a bunch of times (starting with the same permutation as input each time) and count the number of times each output permutation occurs. Then, I'd use Pearson's Chi-square Test to test this distribution for uniformity.
the (Modern, aka "Knuth") Fisher–Yates shuffle is
What else could we want out of an algorithm (well, yeah, when the number of permutations grows huge, one may try something else, but most cases do not involve such huge counts) ?
' just noticed that this answer responds to the title of the question, not its content. (Which is why it is good to have these two parts of the question to match better...)