I am taking now the big O in ICS202 course, and I really find some dificulty to figure it out from a code, Is there any videos,web pages or blogs that can help me with that?
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Generally the big O notation describes how a function behaves when problem size increases. Wikipedia has a good introduction, but the topic is also a staple in nearly every CS book. In the following example I'll talk exclusively about the time complexity of the functions, you can also apply this to other resources, e.g. memory. When analysing code to figure out what its limiting behaviour is you should look for patterns that are dependent of the problem size (in the following examples this is always N – think of it as input to a method which can be variable). For example, code that does not depend on it at all is always O(1):
This also holds if we do several such things:
Technically this is O(1 + 1 + 1), so O(3). But constant factors can be discarded (due to how f ∈ O(g) is defined), so we end up at O(1) anyway. Once you have loops involved this changes, of course, e.g. the following code will be O(N) because the loop counts up to N:
Things get fun when we have multiple loops and nest them:
Here we have two nested loops. The inner one demonstrates what I pointed out before about constant factors: It only runs to ^{N}/_{2}. So technically the inner loop has the complexity O(½ · N). But since constant factors can be discarded this results in O(N) as well. So the two nested loops give us an initial complexity of O(N^{2}). But there's also a second loop after the nested ones. So technically we arrive at O(N^{2} + N) for the whole snippet. Mathematically this notation is defined as “the function grows slower than what is written inside the O(...) for all x greater than a certain x_{0}”. Since N always grows slower than N^{2} there is always a larger x_{0} for which N^{2} is greater than N^{2} + N. So for sums of complexities you can leave out summands that grow too slow to be significant (this gets a bit tricky for more complex things though, so just take this explanation as a very rough approximation). For many simple algorithms you can get away with just polynomials, but more complex ones may result in things like O(2^{N}) (those are computationally hard problems) or O(log N) (many good sorting algorithms), etc. Try figuring out how the code actually approaches a problem, what the problem size is (sometimes it's more than one number, e.g. graph algorithms often have complexities that depend on the number of edges and/or nodes) and what function might describe the code's limiting behaviour. Simple loops up to the problem size are easy. Recursion often is a little harder to figure out, although there are also common patterns, such as how much the problem size is reduced in each step. Let's take a look at a few actual algorithms and see how they perform. Bubble sortPseudocode of Bubble sort is the following (taken from Wikipedia):
The problem size is readily apparent: It's the size of the list. A glance at the code tells us there are two nested loops (1 and 2). The inner one is fairly obvious because it always runs through the whole list minus the last element, so it's O(N − 1). Then there is a swap of two numbers (3) which is constant, therefore we can ignore it for our purposes^{1}. To figure out how long the outer loop has to run we have several options: The list could be sorted from the start. The inner loop therefore runs once through the whole list, determines that nothing has been swapped and the outer loop terminates after having run once. However, if the list is sorted in reverse initially we get a different picture. Recall how Bubble sort works – it always swaps adjacent elements when they are out of order. So for the last element to arrive a its proper place with a reversesorted list we have to swap it with its neighbour N − 1 times. And then there is every other option in between. So depending on the initial conditions the outer loop has very different behaviour^{2}. Let's just focus on the worst case for now, which means the outer loop runs N − times which leaves us with the following complexity for everything: O((N − 1) · (N − 1) · 1) which are, in order, the outer loop (1), the inner loop (2) and the swap (3), all nested in each other which is why they are multiplied. We can simplify this to O(N^{2} − 2*N* + 1) which can be further simplified (according to the rules I noted earlier) to O(N^{2}). Factorial, recursiveA simple recursive method of calculating factorials is the following (I omitted error checking, e.g. for negative arguments, for simplicity):
As said before, recursion is a little different than simple loops but it's still not too hard. Recursion works by breaking a problem into smaller problems until we arrive at a point where the answer is immediately obvious or can be computed through other means (the terminating condition). In this case the terminating condition is n = 0 where we know the answer already. How the problem is broken into smaller parts differs, though. In this case we can see that each step reduces the problem size by 1. So to solve a problem of size n (i.e. calculating n!) we need n steps. So it's not very hard to see that this is O(n) again. Binary searchBinary search finds an element in a sorted list by exploiting the fact that we can infer quite quickly where the element has to be in that list:
Here the problem size is the length of the array again. Binary search works by looking in the middle of the subarray one is currently looking at and then deciding whether the element to search for is either in the upper or lower half. Since the array is sorted that works. This means that for each recursion step the problem size halves (because we throw away one half each time). For an array of length 16 we need at most 5 steps (since the terminating condition looks for i_{max} < i_{min}), for 32 it's 6 steps, etc. Since the problem size halves this puts the complexity at O(log_{2}n), the binary logarithm of the array size. If the size would reduce to a tenth each step we'd have O(log_{10}n) – however, all those are essentially identical in behaviour which is why the base is usually omitted in writing: O(log n). Footnotes1 Note though, that even though some things may be constant they could still be very expensive – don't take the big O notation as the final word on realworld performance of an algorithm. For example Quicksort is an algorithm with O(log N) but for small problem sizes it is more expensive than Insertion sort (an O(N^{2}) algorithm), which is why many Quicksort implementations use Insertion sort for the last few unsorted numbers simply because it is faster, although, of course, Quicksort itself scales much better to large problem sizes. However, none of this applies in case of the mentioned swap above, it's just to point out that for the big O notation constants are irrelevant; in the real world they are often not. 2 Another reason why one complexity alone is a very poor measure of how good an algorithm is. Quicksort has a worst case complexity of O(N^{2}) (for a sorted list) but performs very well in almost all other circumstances. 




