Average Case Complexity of a function

What is the average case complexity of the following function given that the input is a set of independent uniform natural numbers.

``````def d(a):
for i in range(len(a)):
if a[i] == 0 or a[i] == 1:
for j in range(i+1, len(a)):
if not (a[j] == 0 or a[j] == 1):
swap(a, i, j)
break
``````

What do you think, how to approach this problem in mathematical terms?

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This question cannot be answered without specifying the distribution of the input numbers. –  larsmans Apr 5 '11 at 17:29
"random"(uniformly distributed) natural numbers is not enough? –  Sumer Cip Apr 5 '11 at 17:32
No. Distribued between what and what? Are those numbers independent or not? –  akappa Apr 5 '11 at 17:35
Ok I must admit I have lack of information here. When I say random natural number set, what I mean is that the set is independent, uniform set of numbers starting from 0 to infinity. No sure how to express this with a well math. vocabulary? –  Sumer Cip Apr 5 '11 at 17:39
If that's the case, then the probability of the inner execution of the loop is zero, so it's trivially O(n). –  akappa Apr 5 '11 at 17:42
show 2 more comments

Leaving out all the details, we get two nested loops, indicating a quadratic algorithm. Taking the `if` into account, such a small percentage of numbers actually execute the inner loop that the average case is effectively linear.

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Beware! Even if the probability is 0.0000001%, the average complexity is still O(n²): asymptotic complexity doesn't take into account how "tiny" constants are. –  akappa Apr 5 '11 at 17:23
@larsmans: the probability of what? –  akappa Apr 5 '11 at 17:26
@akappa: the probability of a 0 or a 1. But now that I think about it, the OP should have specified a distribution over natural numbers. –  larsmans Apr 5 '11 at 17:28
@akappa: That's not entirely true. Just for example, if code can only execute log(N) percent of the time, you get a logarithmic complexity. In this case, the OP's statement was "random natural numbers", which means probability of executing the inner loop is 0, and we get linear complexity. You're assuming non-zero probability of executing the inner loops, which would be correct only for a finite range of inputs (though for anything on a computer, the range must be finite, of course). –  Jerry Coffin Apr 5 '11 at 17:29
@larsmans: that's the point, he left the probability distribution unspecified. But I think it's realistic to assume that the distribution doesn't depend upon n (i.e., he gets a stream of random, independent, identically distributed numbers). –  akappa Apr 5 '11 at 17:31
show 8 more comments
``````for i in range(len(a)):
``````

The result will be the length of `a` multiplied with the average time for any index in `range(len(a))` (let's ignore the `break` for now).

``````if a[i] == 0 or a[i] == 1:
``````

Two accesses of the values of `a`, so let's add `2 * [time to retrieve a[i]]`. The probability that a value of `a`(an element of an infinite set, ℕ) is an element of any finite set(such as {0,1}) is infinitely close to zero. Since the further code inside takes finite time, we can safely ignore it.

Average case complexity: `2 len(a) [time to retrieve a[i]]``Θ(len(a))``O(len(a))`.

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@larsmans No, the distribution of values of `a` does not depend on its length. For example, [42] is a valid input. –  phihag Apr 5 '11 at 17:27
how can you say? We doesn't know anything about P(a = v), where v is a vector of numbers. –  akappa Apr 5 '11 at 17:34
@akappa We do know. We know the length of `a` and know each of its members is a random element of ℕ, which is an infinite set. The probability to draw a specific element of an infinite set is zero, therefore the probability of drawing multiple specific elements (i.e. v) is zero. –  phihag Apr 5 '11 at 17:44