What are realworld problems where a recursive approach is the natural solution besides depthfirst search (DFS)?
(I don't consider Tower of Hanoi, Fibonacci number, or factorial realworld problems. They are a bit contrived in my mind.)
What are realworld problems where a recursive approach is the natural solution besides depthfirst search (DFS)? (I don't consider Tower of Hanoi, Fibonacci number, or factorial realworld problems. They are a bit contrived in my mind.) 

closed as too broad by Dukeling, templatetypedef, Josiah Hester, Soner Gönül, Stefan Steinegger Nov 4 '13 at 8:25There are either too many possible answers, or good answers would be too long for this format. Please add details to narrow the answer set or to isolate an issue that can be answered in a few paragraphs.If this question can be reworded to fit the rules in the help center, please edit the question. 


There are lots of mathy examples here, but you wanted a real world example, so with a bit of thinking, this is possibly the best I can offer: You find a person who has contracted a given contageous infection, which is non fatal, and fixes itself quickly( Type A) , Except for one in 5 people ( We'll call these type B ) who become permanently infected with it and shows no symptoms and merely acts a spreader. This creates quite annoying waves of havoc when ever type B infects a multitude of type A. Your task is to track down all the type Bs and immunise them to stop the backbone of the disease. Unfortunately tho, you cant administer a nationwide cure to all, because the people whom are typeAs are also deadly allergic to the cure that works for type B. The way you would do this, would be social discovery, given an infected person(Type A), choose all their contacts in the last week, marking each contact on a heap. When you test a person is infected, add them to the "follow up" queue. When a person is a type B, add them to the "follow up" at the head ( because you want to stop this fast ). After processing a given person, select the person from the front of the queue and apply immunization if needed. Get all their contacts previously unvisited, and then test to see if they're infected. Repeat until the queue of infected people becomes 0, and then wait for another outbreak.. ( Ok, this is a bit iterative, but its an iterative way of solving a recursive problem, in this case, breadth first traversal of a population base trying to discover likely paths to problems, and besides, iterative solutions are often faster and more effective, and I compulsively remove recursion everywhere so much its become instinctive. .... dammit! ) 


A real world example of recursion 


How about anything involving a directory structure in the file system. Recursively finding files, deleting files, creating directories, etc. Here is a Java implementation that recursively prints out the content of a directory and its subdirectories.



Quicksort, merge sort, and most other Nlog N sorts. 


Matt Dillard's example is good. More generally, any walking of a tree can generally be handled by recursion very easily. For instance, compiling parse trees, walking over XML or HTML, etc. 


Recursion is often used in implementations of the Backtracking algorithm. For a "realworld" application of this, how about a Sudoku solver? 


Surely that many compilers out there use recursion heavily. Computer languages are inherently recursive themselves (i.e., you can embed 'if' statements inside other 'if' statements, etc.). 


Recursion is appropriate whenever a problem can be solved by dividing it into subproblems. Algorithms on trees and sorted lists are a natural fit. Many problems in computational geometry (and 3D games) can be solved recursively using binary space partitioning (BSP) trees, fat subdivisions, or other ways of dividing the world into subparts. Recursion is also appropriate when you are trying to guarantee the correctness of an algorithm. Given a function that takes immutable inputs and returns a result that is a combination of recursive and nonrecursive calls on the inputs, it's usually easy to prove the function is correct (or not) using mathematical induction. It's often intractable to do this with an iterative function or with inputs that may mutate. This can be useful when dealing with financial calculations and other applications where correctness is very important. 


Disabling/setting readonly for all children controls in a container control. I needed to do this because some of the children controls were containers themselves.



Recursion is used in things like BSP trees for collision detection in game development (and other similar areas). 


People often sort stacks of documents using a recursive method. For example, imagine you are sorting 100 documents with names on them. First place documents into piles by the first letter, then sort each pile. Looking up words in the dictionary is often performed by a binarysearchlike technique, which is recursive. In organizations, bosses often give commands to department heads, who in turn give commands to managers, and so on. 


Famous Eval/Apply cycle from SICPHere is the definition of eval:
Here is the definition of apply:
Here is the definition of evalsequence:



Parsers and compilers may be written in a recursivedescent method. Not the best way to do it, as tools like lex/yacc generate faster and more efficient parsers, but conceptually simple and easy to implement, so they remain common. 


I have a system that uses pure tail recursion in a few places to simulate a state machine. 


Some great examples of recursion are found in functional programming languages. In functional programming languages (Erlang, Haskell, ML/OCaml/F#, etc.), it's very common to have any list processing use recursion. When dealing with lists in typical imperative OOPstyle languages, it's very common to see lists implemented as linked lists ([item1 > item2 > item3 > item4]). However, in some functional programming languages, you find that lists themselves are implemented recursively, where the "head" of the list points to the first item in the list, and the "tail" points to a list containing the rest of the items ([item1 > [item2 > [item3 > [item4 > []]]]]). It's pretty creative in my opinion. This handling of lists, when combined with pattern matching, is VERY powerful. Let's say I want to sum a list of numbers:
This essentially says "if we were called with an empty list, return 0" (allowing us to break the recursion), else return the value of head + the value of Sum called with the remaining items (hence, our recursion). For example, I might have a list of URLs, I think break apart all the URLs each URL links to, and then I reduce the total number of links to/from all URLs to generate "values" for a page (an approach that Google takes with PageRank and that you can find defined in the original MapReduce paper). You can do this to generate word counts in a document also. And many, many, many other things as well. You can extend this functional pattern to any type of MapReduce code where you can taking a list of something, transforming it, and returning something else (whether another list, or some zip command on the list). 


XML, or traversing anything that is a tree. Although, to be honest, I pretty much never use recursion in my job. 


Recursion is applied to problems (situations) where you can break it up (reduce it) into smaller parts, and each part(s) looks similar to the original problem. Good examples of where things that contain smaller parts similar to itself are:
Recursion is a technique to keep breaking the problem down into smaller and smaller pieces, until one of those pieces become small enough to be a pieceofcake. Of course, after you break them up, you then have to "stitch" the results back together in the right order to form a total solution of your original problem. Some recursive sorting algorithms, treewalking algorithms, map/reduce algorithms, divideandconquer are all examples of this technique. In computer programming, most stackbased callreturn type languages already have the capabilities built in for recursion: i.e.



Suppose you are building a CMS for a website, where your pages are in a tree structure, with say the root being the homepage. Suppose also your {userclientcustomerboss} requests that you place a breadcrumb trail on every page to show where you are in the tree. For any given page n, you'll may want to walk up to the parent of n, and its parent, and so on, recursively to build a list of nodes back up to the root of page tree. Of course, you're hitting the db several times per page in that example, so you may want to use some SQL aliasing where you look up pagetable as a, and pagetable again as b, and join a.id with b.parent so you make the database do the recursive joins. It's been a while, so my syntax is probably not helpful. Then again, you may just want to only calculate this once and store it with the page record, only updating it if you move the page. That'd probably be more efficient. Anyway, that's my $.02 


You have an organization tree that is N levels deep. Several of the nodes are checked, and you want to expand out to only those nodes that have been checked. This is something that I actually coded. Its nice and easy with recursion. 


In my job we have a system with a generic data structure that can be described as a tree. That means that recursion is a very effective technique to work with the data. Solving it without recursion would require a lot of unnecessary code. The problem with recursion is that it is not easy to follow what happens. You really have to concentrate when following the flow of execution. But when it works the code is elegant and effective. 


Calculations for finance/physics, such as compound averages. 





Parsing a tree of controls in Windows Forms or WebForms (.NET Windows Forms / ASP.NET). 


The best example I know is quicksort, it is a lot simpler with recursion. Take a look at: shop.oreilly.com/product/9780596510046.do www.amazon.com/BeautifulCodeLeadingProgrammersPractice/dp/0596510047 (Click on the first subtitle under the chapter 3: "The most beautiful code I ever wrote"). 


Ditto the comment about compilers. The abstract syntax tree nodes naturally lend themselves to recursion. All recursive data structures (linked lists, trees, graphs, etc.) are also more easily handled with recursion. I do think that most of us don't get to use recursion a lot once we are out of school because of the types of realworld problems, but it's good to be aware of it as an option. 


Multiplication of natural numbers is a realworld example of recursion:



Real world requirement I got recently: Requirement A: Implement this feature after thoroughly understanding Requirement A. 


Methods for finding prime numbers are recursive. Useful for generating hash keys, for various encryption schemes that use factors of large numbers. 


Anything program with tree or graph data structures will likely have some recursion. 


Write a function that translates a number like 12345.67 to "twelve thousand three hundred fortyfive dollars and sixtyseven cents." 

