I've been noticing answers on stack overflow that use terms like these, but I don't know what they mean. What are they called and is there a good resource that can explain them in simple terms?
That notation is called Big O notation, and is used as a shorthand to express algorithmic complexity (basically how long a given algorithim will take to run as the input size (n) grows)
Generally speaking, you'll run into the following major types of algorithims:
Generally you can get a rough gauge of the complexity of an algorithim by looking at how it's used. For example, looking at the following method:
There's a few things that have to be done here:
There's a few operations that run in constant time here (the first two and the last), since the size of x wouldn't affect how long they take to run. As well, there are some operations that run in linear time (since they are run once for each entry in x). With Big O notation, the algorithim is simplified to the most complex, so this sum algorithim would run in O(n)
From Wikipedia page:
If you don't won't to drill into details you can very often approximate algorithm complexity by analizing its code:
Sometimes it is not so simple to estimate function/algorithm big O notation complexity in such cases amortized analysis is used. Above code should serve only as quickstarter.
The answers are good so far. The main term to web search on is "Big O notation".
The basic idea behind the math of "someformula is O(someterm)" is that, as your variable goes to infinity, "someterm" is the part of the formula that dominates.
For example, assume you have
This is called the Big O notation and is used to quantify the complexity of algorithms.
O(1) means the algorithm takes a constant time no matter how much data there is to process.
O(n) means the algorithm speed grows in a linear way with the amount of data.
and so on...
So the lower the power of n in the O notation the better your algorithm is to solve the problem. Best case is O(1) (n=0). But there is an inherent complexity in many problems so that you won't find such an ideal algorithm in nearly all cases.