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I'm studying the running time of programs and have come across the Big O notation. One is asked to prove that T(n) is O(f(n)) by proving that there exists integer x and constant c > 0 such that for all integers n >= x, T(n) <= cf(n).

The examples I've seen prove this by "picking" values for x and c. I understand that you can plug values into the equation and see if they are correct, but is there a way to actually calculate x or c? Or, at least, some rules of thumb on how to pick them so one isn't plugging in values endlessly?

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The values come from an examination from the algorithm T. For example, when you have a simple loop:

for (i=0; i < n; ++i) {
  sum += i;

then you perform the operations i<n, ++i and sum+=i n times, and i=0 once. So f(n)==n, c==4 (for the four operations, elevating the "once" to "n times" for correctness of values), x==1 (for n==0, you still perform i=0 and i<n, so the formula would not work). This gives you an O(n) performance (linear in the number of inputs).

For the nested loops:

for (i=0; i < n; ++i) {
  for (j=0; j<n; ++j) {
    sum += j;

The calculations are similar, with f(n)==n^2, giving you O(n^2).

So there is no cut-n-dry way of telling the exact values of c and x, but most of the time the hard part is coming up with f -- and the "smallest" of that too (an O(n^2) algorithm is also an O(n^3) algorithm according to the definition you provided, but you want to characterize that algorithm with O(n^2) instead of O(n^3)). The ordering of fs is based on their growth when n approaches infinity: f(n)=n^3 grows slower than f(n)=2^n, even if for small ns the former is larger than the latter.

Note that in theory the actual values of x and c become irrelevant as n approaches infinity, that is why they don't show up in the O(n) notation itself. This does not mean, however that for (relatively) small values if n, the number of instructions are not much larger than f(n) (e.g. you have 1000 instructions within the for loop).

Also, the O(n) notation gives you worst performance, which might be much higher than what you observe in real life (average-case cost) or in the overall usage of a data structure (amortized cost), for example.

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