The definition of Big-O[*]:
For two functions
O(g(n)) if and only if there exist numbers
c such that:
for all n > M, |f(n)| <= c * |g(n)|
|x| is the absolute value of
So from this definition it is easy to see that the function
O(n): just take
c = 3 and any positive
M you please.
Explanations in terms of "rate of growth" are pretty much waffle (or actually, they're the motivation for the above definition), but they might help form an intuitive idea of how Big-O works.
Why allow a constant factor? Why not define that
O(g) only if
|f(x)| < |g(x)| for
n > M? A couple of reasons - firstly because of the "rate of growth" waffle/motivation: what we're really saying with big-O notation is what happens when you double
n, triple it, etc. Secondly because the idea of an "operation" isn't clear-cut. Adding 1 to an integer doesn't take the same amount of time as a comparison, or a jump. It doesn't even necessarily take the same number of CPU instructions. So what are you going to measure in? Seconds? CPU cycles? On what CPU, running at what speed, with what bus bandwidth? What if algorithm A is very slightly faster on x86, whereas algorithm B is very slightly faster on ARM? Then would the time of either of them be Big-O(the time of the other one)?
For abstract analysis we need ways to compare algorithms that aren't rooted in any particular hardware, and Big-O is one of those tools.
So, it's irrelevant to the big-O complexity of an algorithm whether it does three constant-time operations per loop, or a million. They still contribute
O(n) time, just pick a big enough
If you do
log(n) operations per loop (looping
n times) then you're no longer
O(n), because for any
log(n) > c for big enough
n. Hence there doesn't exist any
c to satisfy the condition.
n * log n is not
[*] as it applies to the complexity of an algorithm -- Big-O is also used when approaching limits other than infinity, but we don't care about that.