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I'm confused on how to create a function T(n) to measure computing time for a nested infinite loop. Here is the code:

x=1;
for(int i = 0;i<n-1;i++){
     for(int j = 1; j<=x; j++){
        cout << j << endl;
        x*=2;
     }
}

So the inner loop will go on forever, and I am stuck trying create the function to represent its computing time. I have written that its computing time is T(n) = [Summation i=0 until (n-2)] (2^j). 2^j represents the value of x with the current value of j from the inner loop. After discussing this with my peers, we definitely agree that the computing time is certainly not dependent on the value of n. We also could be completely over-thinking this as the loop is infinite and there is simply no way to express its computing time. Any help is greatly appreciated.

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1  
I'm thoroughly confused. You want the running time of an infinite loop? It's infinite. BTW, the outer loop is irrelevant, since the inner loop never completes. Also, it probably isn't infinite in practice, since x will eventually wrap if it's an integral type. –  Marcelo Cantos Oct 11 '11 at 22:47
    
Time complexity only makes sense on algorithms that terminate. –  Jeff Mercado Oct 11 '11 at 22:49
    
Yes I know the outer loop is irrelevant, and yes I know designing a computing algorithm for something like this makes no sense, but I need to try :) –  whittenc Oct 11 '11 at 23:02

2 Answers 2

Algorithm complexity is only defined for algorithms, which by (the most often accepted) definition must terminate. This process doesn't terminate (except "in practice" as Marcelo notes; i.e. as a program on a real machine vs. in theory on a theoretical Turing machine with an infinite tape and all the time in the world) so is not an algorithm. So it has no "algorithmic time complexity".

Trying to determine the algorithmic complexity for a non-algorithm is a futile exercise, as is trying to express its running time as a polynomial if it's an infinite process.

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Well, in the real world, you're not going to get an answer for obvious reasons, but in math... why not.

I'll write down the time equation of the function:

T(n) = n-1 * T(X) 

T(X) is the time for the inner loop. I'll expend it: X1 = initial value of x (in this case 1)

T(X) = T(X1 * 2) + 1 = T(X1 * 4) + 2 = ... = T(X1 * 2^j) + j

The end condition of this loop is when j >= X1 * 2^j + 1, so we want to solve:

j >= X1 * 2^j -> j = 2^j -> j <= log2(j).

The above equation has no solution in this Natural Numbers set range, but in Integer set it's easily solved with -1 (actually any integer smaller then 0).

So, the time complexity for T(n) would be (n-1) * (-1) = 1 - n.

I don't know what's useful about this, but I hope it'll do the trick for you.

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God no! Logarithm, in general, is not defined for any argument less than or equal to 0. –  andr Jan 14 '13 at 1:46
    
Log isn't defined under 0, but the way I see it, you can't define the time complexity of an infinite loop either. –  Neowizard Jan 14 '13 at 13:26
    
Well, then you should write just that instead of writing a mathematically wrong answer! This especially contradicts your first paragraph: but in math... why not. A better answer would be T(n) = +inf, because it certainly won't cause OPs confusion. –  andr Jan 14 '13 at 13:31
    
I disagree. The OP asked a question that is clearly irregular. So, I assume that an irregular approach would benefit the issue. This is just like the issue with sqrt(n) where n<0. You can't define it unless you change the rules a bit (adding the Complex number set). The definition of log2(n) for n<0 is just as logical as the question "when does infinity end?". You'll have to change the rules a bit in order to answer it. –  Neowizard Jan 15 '13 at 6:46
1  
I'm not against extending math. But in math, everything you add to it, must be consistent (correct) with all things that were there already. Your definition doesn't follow that, since it leads to a contradiction - considering that 2^x is strictly increasing in R, we obtain 0.5 = 2^-1 <= 2^log_2(-1) = -1. Hence this is not a (valid) math proof. Apart from that, time complexity is never < 0, which contradicts your result. Also, we have invariant: time complexity is always >= space complexity (Theta(1) here) which again isn't true for your result. –  andr Jan 15 '13 at 8:49

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