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I understand the principles of asymptotic notation, and I get what it means when something is O(1) or O(n2) for example. But what does O(log n) mean? or O(n log n) for example?

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possible duplicate of What would cause an algorithm to have O(log n) complexity? –  templatetypedef Feb 8 '12 at 19:15
that's a lotta downvotes! and there is a CLEAR difference between 'what does log mean?' and 'what kinds of algorithms have O(log n) complexity.' –  SirYakalot Feb 8 '12 at 19:21
@templatetypedef Not an exact duplicate; that question seems to implicitly assume knowledge of what a logarithm actually is and focuses on types of problems exhibiting particular asymptotic behaviors. –  Michael McGowan Feb 8 '12 at 19:24
@SirYakalot- if you look at my answer to that other question, it goes through several different examples of algorithms with logs in their complexity and shows what high-level structures result in logarithms arising. I think it's the answer you're looking for. –  templatetypedef Feb 8 '12 at 19:25
maybe it does answer this one to come extent, but this still isn't a duplicate. –  SirYakalot Feb 8 '12 at 19:28

3 Answers 3

up vote 2 down vote accepted

Check: en.wikipedia.org/wiki/Big_O_notation

Remeber that log increases slowly than a an exponential function. So, if you have an algorithm that is n^2 and other, that doing the same, has a logarithmic function, the last would be more efficient (in general term, not always!).

To evaluate the complexity of a function (or algorithm) you must take in consideration the execution in time and space, mainly. You can evaluate a function or algorithm with other parameters, but, initially, those two would be OK.

EDIT: http://en.wikibooks.org/wiki/Data_Structures/Asymptotic_Notation

Also, check the sorting algorithms. Will give great insight about complexity.

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so, like bisection search that increases 'the oposite of exponentially' - ah, is that what it means. logarithmically == the oposite of exponentially? –  SirYakalot Feb 8 '12 at 19:22
@SirYakalot : indeed, they have an inverse relations. But when applied in the context of algorithms, the relation is not that trivial. Is not like you can make the same algorithm in two different ways and get one with exponential measure and the other way logarithmic (at least, I'm not aware of) (check the sorting ones and the search ones, you will see interesting things) –  Kani Feb 8 '12 at 19:24

log is a mathematical function. It is the inverse of exponentiation - log (base 2) of 2^n is n. In practice, it is better than n^c for any positive c (including fractional c such as 1/2 (which is square root)). Check wikipedia for more info.

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so it's the opposite of a power? –  SirYakalot Feb 8 '12 at 19:18
@SirYakalot it is the opposite of exponentiation (ie 2^n). It is not the opposite of n^2 (for this, you want sqrt(n)). With exponentiation, the time it takes doubles (or gets multiplied by some other number > 1) with each additional element we process. Here, every unit of time doubles the amount data you can process. Think a binary search - one additional run of the loop doubles the size of the input that we can process. –  Retief Feb 8 '12 at 19:22
gotcha, thanks for explaining. –  SirYakalot Feb 8 '12 at 19:24

Log is short for "logarithm": http://en.wikipedia.org/wiki/Logarithm

Logarithms tell us for example how many digits are needed to represent a number, or how many levels a balanced tree has when you add N elements to it.

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sure but O(log n) isn't a number, it's just an abstract concept. –  SirYakalot Feb 8 '12 at 19:23
O(log n) is the set of functions of n that are bounded by A*log(n), for some constant A, as n grows without limit. So no, it's not a number, but it's not such an abstract concept either. You have to understand what "log" means to be able to discuss O(log n) meaningfully. –  Joni Feb 8 '12 at 19:28

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