# Near Sorting Algorithms - When to use?

From time to time I browse the web and look for interesting algorithms and datastructures to put into my bag of tricks. A year ago I came across the Soft Heap data-structure and learned about near sorting.

The idea behind this is that it's possible to break the O(n log n) barrier of compare based sorts if you can live with the fact that the sort algorithm cheats a bit. You get a almost sorted list but you have to live with some errors as well.

I played around with the algorithms in a test environement but never found a use for them.

So the question: Has anyone ever used near sorting in practice? If so in which kind of applications? Can you think up a use-case where near sorting is the right thing to do?

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There are a lot of "greedy" heuristics where you periodically select the minimum of a set. The greedy heuristic is not perfect, so even if you pick the minimum you aren't guaranteed to get to the best final answer. In fact, the GRASP meta-heuristic, you intentionally introduce random error so that you get multiple final solutions and select the best one. In that case, introducing some error in your sort routine in exchange for speed would be a good trade off.

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This is a total flying guess, but given the inherent subjectivity of "relevance" measures when sorting search results, I'd venture that it doesn't really matter whether or not they're perfectly sorted.

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Nice! I'd vote you up twice if I could. :-) –  Jason Cohen Oct 20 '08 at 22:02

Just speculating here, but one thing I imagine is database query optimization.

A database query in a declarative language such as SQL has to be translated into a step-by-step program called an "execution plan". One SQL query can typically be translated to a number of such execution plans, which all give the same result but can have very varying performance. The query optimizer has to find the fastest one, or at least one that is reasonably fast.

Cost-based query optimizers have a "cost function", which they use to estimate the execution time of a given plan. Exhaustive optimizers go through all possible plans (for some value of "all possible") and select the fastest one. For complicated queries the number of possible plans may be prohibitively large, leading to overly long optimization times (before you even begin the search in the database!) so there are also non-exhaustive optimizers. They only look at some of the plans, perhaps with a random element in choosing which ones. This works, since there is usually a large number of "good" plans, and it might not be that important to find the absolutely best one -- it is probably better to choose a 5-second plan instead of the optimal 2-second plan, if it requires several minutes of optimization to find the 2-second plan.

Some optimization algorithms use a sorted queue of "promising" (partial) plans. If it doesn't really matter if you find the absolutely best plan, maybe you could use an almost-sorted queue?

Another idea (and I'm still just speculating) is a scheduler for processes or threads in a time-sharing system, where it might not be important if a certain process or thread gets its timeslot a few milliseconds later than if strictly sorted by priority.

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+1, I like the DB planning optimisation example. With process scheduling I would guess it is more complicated, since without guarantees on exactly "how and how much" the result fails to be perfectly sorted you could wind up with process starvation. –  j_random_hacker Oct 22 '09 at 8:26

A common application for near-sorting is when a human is doing the pairwise comparison and you don't want to have to ask them as many questions.

Say you have a lot of items you'd like a human to sort via pairwise comparison. You can greatly reduce the number of comparisons you need them to do if you're willing to accept that ordering won't be exact. You might, for example, not care if adjacent items have been swapped a long as the preferred items are at the top.

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Anywhere

1. you are supposed to react fast,
2. you are not promising exact behavior to the client,
3. but internally you have some rules

you can use it. How about "not so strict" rule-based priority queue? Where would that be useful? Maybe thread/process/resource scheduling. In thread/process scheduling you are really not promising any one thread is going to go first, second, or last, but generally you want to give everyone some chance. You might want to enforce loose rule so it's preemptive, prioritized, blabla..

A resource schedule example would be responding to pizza delivery or shipping boxes of books to people etc. You can't use it where deterministic result is expected, but there are lots of example in real life where things are not so deterministic/predictable.

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O(n log n) is already pretty fast. I don't think anyone would ever start out using a near-sort algorithm. You would start out with code that just does a complete sort (since your programming language of choice likely provides a `sort` function and not a `nearsort` function), and when you found empirically that the sort was taking too long, you would start to question whether your data really needs to be fully-sorted, and consider using a near-sort.

Basically, you would never even consider using a near sort unless you first discovered sorting to be a severe bottleneck in your program.

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