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I need to calculate the approximate amount of time an algorithm will take without actually running the code.

I cannot actually let the full algorithm run since it takes days or weeks to complete depending on hardware. The algorithm in logarithmic in nature. Following is an estimation of the algorithm. There is no logic included here of course.

We start with 2 raised to the power of [n] where [n] is large number.

int baseTwo = 2;
double log = 0D;
BigInteger number = 0;
double exponent = 5000000; // 5,000,000.

while (exponent > 0)
    number = BigInteger.Pow(baseTwo, (int) exponent); // [baseTwo]=2 raised to the power [exponent].
    number = this.ProcessNumber(number, baseTwo); // Returned number will be slightly smaller than what went in.
    exponent = BigInteger.Log(number, baseTwo); // The Base 2 Log to calculate the slightly decreased exponent (if exponent was 38762, then the result would be 38761.4234 for example).

private BigInteger ProcessNumber(BigInteger number)
    double rand = 0;
    BigInteger result = 0;

    rand = Random.Next(51, 100) / 100D; // Anywhere between 51% to 99%.
    result = number * rand; // [result] will always be less than [number] but more than half of [number].

    return (result);

Since the exponents are iterating towards zero, the time per iteration naturally decreases from one iteration to the next.

  • Given the execution time of the first and last iterations on my machine, is there a way to calculate the total time?
  • If not, we could take discreet ranges for [exponent] say 5,000,000, 4,500,000, 4,000,000, etc. and calculate from there?
share|improve this question
This seems more like a math problem than a programming problem. Take some samples, create a model, and use the model to predict a result. Microsoft Excel has some decent support for basic modeling if you don't happen to have access to specialized modeling software. – Servy Aug 13 '12 at 17:05
Where is i defined? Was that supposed to be exponent? – tlehman Aug 13 '12 at 17:15
I would take the advice from @Servy. Run a few experiments on reasonably sized data, plot it, and fit a curve to it. – jeff Aug 13 '12 at 17:58
Or use interpolation with polinoms and get some estimation expressed with the function – dvvrd Aug 13 '12 at 18:31
If you made a question about the actual problem that you've been posting little parts of for a month, perhaps we can speed it up. – harold Aug 13 '12 at 18:36
up vote 3 down vote accepted

Just the first and last iterations won't provide you with sufficient information, even if you know the limiting big-O efficiency of the algorithm, because there is no guarantee that the time per iteration will scale exactly to the limiting efficiency. For example, if your function was O(n^2) in the limit for large n (I know it isn't in this case - but this is just for the sake of illustation), but the actual time per step of real code was something like 1*log(n) + 10^-6*n + 10^-24*n^2, you might not see n^2 behaviour over the range of n you choose to look at. So you would have two points at the first and last iteration, but no way of knowing how to draw the line between them.

You could sample the data at regular intervals as you suggest, and then export it for fitting and/or numerical integration. But assumiong you only need to know the approximate total time (+/-10% perhaps) it should be suficient to do something along the lines of... Pseudo-code:

totaltime = 0;
for i := 0 to 5 do
  starttime = now;
  for j := 0 to 10 do
    run algorithm(i*10^6+j)
  endtime = now;
  totaltime := totaltime + 10^5*(endtime - starttime);
  writeln('10 iterations near ', i*10^6, ' takes ', endtime - starttime, ' seconds');
writeln('approximate time for complete algorithm to run is', totaltime);

.. and get an answer in less time than it has taken me to write this.

share|improve this answer

I'd suggest feeding your algorithm small but increasing inputs, and do a graph.

Curves on a graph can change all of a sudden, but they're probably still a better indicator than a lot of back-of-the-envelope calculations for something like this.

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