Anyway, I find out in the project info that if n<100, then O(n^2) is
more efficient, but if n>=100, then O(n*log2n) is more efficient.

Let us start by clarifying what is `Big O`

notation in the current context. From (source) one can read:

**Big O notation is a mathematical notation** that describes the limiting
behavior of a function when the argument tends **towards a particular
value or infinity**. (..) **In computer science,** big O notation is used to classify algorithms
according to how their run time or space requirements grow **as the
input size grows**.

`Big O`

notation does not represent a function but rather a set of functions with a certain asymptotic upper-bound; as one can read from source:

Big O notation characterizes functions according to their growth
rates: different functions with the same growth rate may be
represented using the same `O`

notation.

Informally, in computer-science time-complexity and space-complexity theories, one can think of the `Big O`

notation as a categorization of algorithms with a certain worst-case scenario concerning time and space, respectively. For instance, `O(n)`

:

An algorithm is said to take linear time/space, or O(n) time/space, if its time/space complexity is O(n). Informally, this means that the running time/space increases at most linearly with the size of the input (source).

and `O(n log n)`

as:

An algorithm is said to run in quasilinear time/space if T(n) = O(n log^k n) for some positive constant k; linearithmic time/space is the case k = 1 (source).

Mathematically speaking the statement

Which is better: O(n log n) or O(n^2)

is not accurate, since as mentioned before `Big O`

notation represents a set of functions. Hence, more accurate would have been "does `O(n log n)`

contains `O(n^2)`

". Nonetheless, typically such relaxed phrasing is normally used to quantify (for the worst-case scenario) how a set of algorithms behaves compared with another set of algorithms regarding the increase of their input sizes. To compare two classes of algorithms (*e.g.*, `O(n log n)`

and `O(n^2)`

) instead of

Anyway, I find out in the project info that if n<100, then O(n^2) is
more efficient, but if n>=100, then O(n*log2n) is more efficient.

you should analyze how both classes of algorithms behaves with the increase of their input size (*i.e.,* n) for the worse-case scenario; analyzing `n`

when it tends to the infinity

As @cem rightly point it out, in the image "`big-O`

denote one of the asymptotically least upper-bounds of the plotted functions, and does not refer to the sets `O(f(n))`

"

As you can see in the image after a certain input, `O(n log n)`

(green line) grows slower than `O(n^2)`

(orange line). That is why (for the worst-case) `O(n log n)`

is more desirable than `O(n^2)`

because one can increase the input size, and the growth rate will increase slower with the former than with the latter.