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Can someone please give a thorough explanation of what the average case runtime of bogosort would be?

Psuedocode for the algorithm:

while not isInOrder(deck):
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2 Answers 2

There are n! permutations, only one of which is correct (assuming distinct elements). So in a hand-waving sense, you would expect to select the right answer after about O(n!) iterations.* But each shuffle/check operation is itself O(n). Hence O(n.n!) overall.

* To be precise, you can model as a geometrically-distributed random variable with parameter p = 1/n!. The expected value of such a variable is 1/p = n!.

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Assuming uniform distribution it would take n!/2 attempts in average, not n!, not that it changes the complexity –  icepack Mar 2 '13 at 18:26
@icepack: Ah, good call! –  Oliver Charlesworth Mar 2 '13 at 18:27
@icepack why n!/2? –  Jan Dvorak Mar 2 '13 at 18:28
@icepack I disagree. The expected number of attempts is n! –  Jan Dvorak Mar 2 '13 at 18:31
@icepack: After some brief revision of something I last touched 10 years ago, it turns out it is n!. The expected value of a geometrically-distribution variable is 1/p. –  Oliver Charlesworth Mar 2 '13 at 18:42

The average number of attempts to perform an operation is inverse to the probability each attempt succeeds.

There are n! ways to shuffle n elements. If all elements are distinct, only one way produces a sorted output. Thus, the probability of a sorting shuffle is 1/n! and the average number of attempts is n!.

Each shuffle takes O(n) time (assuming Fisher-Yates shuffle or anything equally reasonable).

Thus, the time complexity is O(n!*n).

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O((n+1)!)=O(n!*n) –  icepack Mar 2 '13 at 18:35
@icepack not sure about the equality, but O((n+1)!) is a superset of O(n!*n). I didn't think it worth including in the answer. –  Jan Dvorak Mar 2 '13 at 18:36
@JanDvorak: Yep, they're equivalent, (n+1)! = (n+1)n! = (n! + n.n!). –  Oliver Charlesworth Mar 2 '13 at 18:38
last step: n*n! < n*n!+n! < 2n*n! –  Jan Dvorak Mar 2 '13 at 18:40
Just take limit of (n + 1)! / n.n! for n approaches inf, the result is a finite number (1), so they are equivalent classes of functions. –  nhahtdh Mar 2 '13 at 19:24

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