Actually big-O is only an upper bound, meaning you can say an `O(1)`

algorithm (or really any algorithm taking `O(n`^{2})

or less time) takes `O(n`^{2})

as well. To this end, let's switch over to big-Theta (Θ) notation, which is just a tight bound. See the formal definitions for more information.

If you only know about big-O, it's likely that you've (incorrectly) been taught that big-O is a tight bound. If so, you can probably just assume big-Theta means what you've been taught big-O means.

I will, for the rest of this answer, assume you asked about (or meant) big-Theta, not big-O. If not, as already mentioned, if talking about big-O, that would rather be an "anything goes" situation - the `O(n)`

one can be faster, the `O(n`^{2})

one can be faster or they can take the same amount of time (asymptotically) - one usually can't make particularly meaningful conclusions with regard to *comparing* the big-O of algorithms, one can only say that, given a big-O of some algorithm, that that algorithm won't take any longer than that amount of time (asymptotically).

Asymptotic complexity (which is what both big-O and big-Theta represent) completely ignores the constant factors involved - it's only intended to give an indication of how running time will change as the size of the input gets larger.

So it's certainly possible that an `Θ(n)`

algorithm can take longer than an `Θ(n`^{2})

one for some given `n`

- which `n`

this will happen for will really depend on the algorithms involved - for your specific example, this will be the case for `n < 100`

, ignoring the possibility of optimizations differing between the two.

For any two given algorithms taking `Θ(n)`

and `Θ(n`^{2})

time respectively, what you're likely to see is that either:

- The
`Θ(n)`

algorithm is slower when `n`

is small, then the `Θ(n`^{2})

one becomes slower as `n`

increases

(which happens if the `Θ(n)`

one is more complex, i.e. has higher constant factors), or
- The
`Θ(n`^{2})

one is always slower.

Although it's certainly *possible* that the `Θ(n)`

algorithm can be slower, then the `Θ(n`^{2})

one, then the `Θ(n)`

one again, and so on as `n`

increases, until `n`

gets very large, from which point onwards the `Θ(n`^{2})

one will always be slower, although it's greatly unlikely to happen.

To put it in slightly more mathematical terms:

Let's say the `Θ(n`^{2})

algorithm takes `cn`^{2}

operations for some `c`

.

And the `Θ(n)`

algorithm takes `dn`

operations for some `d`

.

This is in line with the formal definition since we can assume this holds for `n`

greater than 0 (i.e. for all `n`

) and that the two functions between which the running time is lies is the same.

In line with your example, if you were to say `c = 1`

and `d = 100`

, then the `Θ(n)`

algorithm would be slower until `n = 100`

, at which point the `Θ(n`^{2})

algorithm would become slower.

_{(courtesy of WolframAlpha)}.

`c*n`

steps to finish, where`c`

is some constant. So your algorithm is still O(n) for any number of constant iterations you make in the first loop. – ChronoTrigger Mar 23 '14 at 17:18`n`

> 100 then the first algorithm will take longer. – aquinas Mar 23 '14 at 17:20