What is the clearest explanation of what computer scientists mean by "the naive implementation"? I need a good clear example which will illustrate — ideally, even to nontechnical people — that the naive implementation may technically be a functioning solution to the problem, but practically be utterly unusable.
closed as not constructive by bmargulies, WATTO Studios, David Stratton, Lucifer, Jon Lin Oct 3 '12 at 6:10As it currently stands, this question is not a good fit for our Q&A format. We expect answers to be supported by facts, references, or expertise, but this question will likely solicit debate, arguments, polling, or extended discussion. If you feel that this question can be improved and possibly reopened, visit the help center for guidance. If this question can be reworded to fit the rules in the help center, please edit the question. 


I'd try to keep it away from computers altogether. Ask your audience how they find an entry in a dictionary. (A normal dictionary of word definitions.) The naive implementation is to start at the very beginning, and look at the first word. Oh, that's not the word we're looking for  look at the next one, etc. It's worth pointing out to the audience that they probably didn't even think of that way of doing things  we're smart enough to discount it immediately! It is, however, about the simplest way you could think of. (It might be interesting to ask them whether they can think of anything simpler, and check that they do really understand why it's simpler than the way we actually do it.) The next implementation (and a pretty good one) is to start in the middle of the dictionary. Does the word we're looking for come before or after that? If it's before, turn to the page half way between the start and where we are now  otherwise, turn to the page half way between where we are now and the end, etc  binary chop. The actual human implementation is to use our knowledge of letters to get very rapidly to "nearly the right place"  if we see "elephant" then we'll know it'll be "somewhere near the start" maybe about 1/5th of the way through. Once we've got to E (which we can do with very, very simple comparisons) we find EL etc. 


StackOverflow's Jeff Atwood had a great example of a naive algorithm related to shuffling an array. 


another naive implementation would be the use of recursion in computing for an integer's factorial in an imperative language. a more efficient solution in that case is to just use a loop. 


What's the most obvious, naive algorithm for exponentiation that you could think of?
It doesn't handle negative exponents, though. Remembering that
It's actually possible to compute
This takes advantage of the fact that 


I took the time to read your question a little closer, and I have the perfect example.
Try Bogosort!



"Naive implementation" is almost always synonymous with "bruteforce implementation". Naive implementations are often intuitive and the first to come to mind, but are also often O(n^2) or worse, thus taking too long too be practical for large inputs. Programming competitions are full of problems where the naive implementation will fail to run in an acceptable amount of time, and the heart of the problem is coming up with an improved algorithm that is generally much less obvious but runs much more quickly. 


Doing it the most straightforward, least tricky way available. One example is selection sort. In this case naive does not mean bad or unusable. It just means not particularly good. Taking Jon Skeet's advice to heart you can describe selection sort as:
It is easy to do and easy to understand, but not necessarily the best. 


Let's say that someone figures out how to extract a single field from a database and then proceeds to write a web page in PHP or any language that makes a separate query on the database for each field on the page. It works, but will be incredibly slow, inefficient, and difficult to maintain. 


Naive doesn't mean bad or unusable  it means having certain qualities which pose a problem in a specific context and for a specific purpose. The classic example of course is sorting. In the context of sorting a list of ten numbers, any old algorithm (except pogo sort) would work pretty well. However, when we get to the scale of thousands of numbers or more, typically we say that selection sort is the naive algorithm because it has the quality of O(n^2) time which would be too slow for our purposes, and that the nonnaive algorithm is quicksort because it has the quality of O(n lg n) time which is fast enough for our purposes. In fact, the case could be made that in the context of sorting a list of ten numbers, quicksort is the naive algorithm, since it will take longer than selection sort. 


Determining if a number is prime or not (primality test) is an excellent example. The naive method just check if n mod x where x = 2..square root(n) is zero for at least one x. This method can get really slow for very large prime numbers and it is not feasible to use in cryptography. On the other hand there are a couple of probability or fast deterministic tests. These are too complicated to explain here but you might want to check the relevant Wikipedia article on the subject for more information: http://en.wikipedia.org/wiki/Primality_test 


Naive implementation is:



Bubble sort over 100,000 thousand entries. 


The intuitive algorithms you normally use to sort a deck of cards (insertion sort or selection sort, both O(n^2)) can be considered naive, because they are easy to learn and implement, but would not scale well to a deck of, say, 100000 cards :D . In a general setting, there are faster (O(n log n)) ways to sort a list. Note, however, that naive does not necessarily mean bad. There are situations where insertion sort is a good choice (say, when you have an already sorted big deck and few unsorted cards to add). 


(Haven't seen a truly naive implementation posted yet so...) The following implementation is "naive", because it does not cover the edge cases, and will break in other cases. It is very simple to understand, and can convey a programming message.
It will:
You could make it more "mature" by adding these features. 


A O(n!) algorithm.
This will perform fine with small sets and then exponentially worse with larger ones. Another might be a naive Singleton that doesn't account for threading.
If two threads access that at the same time it's possible for them to get two different versions. Leading to seriously weird bugs. 

