# complexity about going from beginning to end and back through a vector

I am trying to be familiar with the complexity evaluation of algorithms. In general I think that is a good/elegant practice, but in the specific I need it to express time complexity of my C++ code.

I have a small doubt. Suppose I have an algorithm that just reads data from the beginning of a `std::vector` until the end; then it does the same starting from the end to beginning (so are 2 cycles for indexes "From 0 To N" followed by "From N To 0").

• I said to myself that the complexity for this stuff is O(2N): is this correct?
• Once I reached the beginning, suppose that I want to start reading again all data from beginning to the end (passing in total 3 times the vector): is the complexity O(3N)?

It is maybe a stupid doubt, but I would like to have someone opinion anyway about my thinking process.

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Big-O notation simply means:

f(n) = O( g(n) ) if and only if f(n) / g(n) does not grow to infinity as n increases

What you have to do is count the number of operations you're performing, which is f(n), and then find a function g(n) that increases at least as fast as f.

In your example of going one way and then back, the number of operations is f(n) = 2n because each element is read twice, so, you can choose g(n) = n. Since f(n) / g(n) = 2n / n = 2 obviously does not grow to infinity (it's a constant), you have an O(n) algorithm.

It's also an O(2n) algorithm, of course : since the "grow to infinity" property does not change when you multiply g(n) by a constant, any O( g(n) ) is also by definition an O( C g(n) ) algorithm for any constant C.

And it's also an O(n²) algorithm, because 2n / n² = 2 / n decreases towards zero. Big-O notation only provides an upper bound on the complexity.

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O(N), O(2N) and O(3N) are equivalent. Multiplying a constant factor to the function inside the O( ) won't change its complexity as "linear".

It is true, however, that each scan will perform N reads in either direction, i.e. it will perform 2N ∈ O(N) reads when scanning from start to end to start, and 3N ∈ O(N) reads when scanning from start to end to start to end.

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